WO1987000027A1

WO1987000027A1 - Oximeter and oximeter system

Info

Publication number: WO1987000027A1
Application number: PCT/JP1986/000342
Authority: WO
Inventors: Kenji Hamaguri; Takao Sakai; Akio Yamanishi; Hitoshi Kamezawa
Original assignee: Minolta Camera Kabushiki Kaisha
Priority date: 1985-07-05
Filing date: 1986-07-03
Publication date: 1987-01-15

Abstract

The information on a living body, such as the degree of oxygen saturation in the arterial blood and the pulse rate, which are measured with an oximeter itself, can be stored along with the information on the measurement time in a memory device, such as an IC card, which is detachable from the oximeter itself. When the memory device is detached from the oximeter itself to be attached to a data analyzer provided separately from the oximeter itself, the stored information on the living body can be analyzed by the data analyzer, and the results of the analysis can be represented by means of a graph. When a printer, which is provided separately from the oximeter itself, is attached thereto, the information on the living body which has been measured can be printed. Furthermore when a transmitter unit for a telemetry unit is attached to the oximeter itself with a receiver unit therefor connected to the data analyzer which is provided separately from the oximeter itself, the information on the living body, which has been measured with the oximeter itself, can be transmitted to the data analyzer without passing through a cord.

Description

One one

Specification

Title of invention

Oximeter and Oximeter ♦ System technology

The present invention relates to an oximeter for non-invasively measuring oxygen saturation in blood and an oximeter system using the same. Background art

Oxygen saturation in the blood, in the O key sheet menu over data to measure Kiyoshie if arterial oxygen saturation (hereinafter S a O ₂ intends gutter), the measurement result I'm the following functions in the additional child It is known that it can be used more effectively.

(1) Preparative Les emission de functions; when lung攒能inspection, during bronchoscopy揷入, and if, etc. so that to monitor the respiratory condition of the patient during oxygen therapy, real data I changes in S a O ₂ ♦ Memory function.

(2) Day Taanara size b攒能; R time continuously measured S a 0 _2, analyzes the short time measurement result after the measurement function.

(3) Print-out function: A function to immediately print the measurement results of Sa〇a on the paper.

In order to achieve this function, a dedicated or general-purpose recorder is used for the conventional Oximeter, or the measured value is transferred to an external device such as a printer or a computer. In some cases, a terminal for outputting a digital signal is provided, and the measured value can be output to the external device through a connection cable. Such output terminals simply output the measured values that are continuously measured from time to time, so that the output can be used for trending and printing with an oximeter. An add function and a data analyze function can be added. To this day Taanara Lee's function was allowed to develop檨能, and the child is considered to cormorants by Ru can be measured for a long time the S a 0 ₂ of the patient during daily life. To do so, the oximeter must be configured to be portable.

However, when a data analysis function is added to a conventional system, separately from the oximeter itself, the memory means for recording the measured values and the data stored in the memory means are used. A means to analyze the data after collection is needed. Therefore, if a memory built in a computer, which is an external device, is used as a memory means, the main body of the oximeter and the computer can be connected at the time of data collection. The device to be measured must be carried, and the equipment to be carried is heavy and bulky, which is inconvenient. In addition, when connecting the oscillator and recorder, printer, or computer via the connection cable as described above, external noise is Or disconnection of the connection cable is likely to occur, and the reliability of the device is reduced.

On the other hand, since the integrated dedicated oximeter having the trend function and the data analysis function has a certain power, it is much larger and heavier. There is a deficiency that a wave measurer or 'wave carrier' cannot be used when collecting measurement data.

In addition, there is a commercially available device that can integrally connect an oximeter and a special-purpose printer via a connector. Perform continuous measurement of force f and R time. Since this is not the case, it is hardly possible for this commercial device to have a data analysis function.

S a 指標_2, which is an index of the respiratory condition, is measured for the following two main purposes. The first is to examine R-phase changes in the patient's condition. In this case, it is only carried out several times a day to as measurements of S A_〇 ₂ rather high. Measurements made for this purpose This is called spot measurement. S A_〇 ₂ Have another an object to measure is to constantly monitor whether there is abnormality in the patient during hand surgery and oxygen therapy. In this case, S a O ₂ must be measured continuously over the R time. This measurement is called continuous measurement.

Apparatus for measuring the S a O ₂ (O key sheet menu chromatography data), particularly non-invasive

Apparatus for measuring the S a 0 ₂ above has two purposes Nodea also useful in order to achieve respectively, conventionally, had example, if Sho 6 0 - proposed in 1 7 6 6 2 4 No., etc. ing. However, conventional devices are either dedicated to spot measurement or dedicated to continuous measurement, and there is no single device capable of performing both of the above purposes. Oximer dedicated to spot measurement only displays the measured values, so the operator must record the measured values in order to perform continuous measurements, and that record Since data analysis has to be performed based on the measured values, continuous measurement is indispensable. On the other hand, an oximeter dedicated to continuous measurement is not suitable for spot measurement because it has a power supply and data analyzer for continuous measurement, so the device itself becomes large in size.

Disclosure of the invention

The purpose of the present invention is to provide an oximeter that can be provided with a data analysis function and that can be carried by the subject. is there.

Another object of the present invention is to make it possible to easily analyze continuously measured data such as Sa02 in the form of '; Data * system is to be launched.

Still another object of the present invention is to provide a high-precision non-invasive oximeter having both the function suitable for spot measurement and the function suitable for continuous measurement described above. To do. Still another object of the present invention, various data not measured S a 0 ₂ only are stored at the time of measurement, Ki愫been de - performs display easily analyzed for diagnostics based on data The aim is to provide an oximeter system that can do this.

Further, another object of the present invention is to separate a data collection device for collecting data from a patient and a data analysis device for analyzing the collected data from each other so that data collection is performed. The data stored in the memory of the device can be used for data analysis and measurement data can be analyzed and displayed by the data analyzer. ♦ System To provide

The present invention relates to an oximeter for measuring the oxygen saturation of a spring to be measured, wherein the light emitting means projects light toward the measured object, and the light emitted from the light emitting means passes through the non-measured object. Light receiving means for receiving light, calculating means for calculating the oxygen flatness and pulse rate according to the output signal of the receiving means, and a warning value for setting a warning value for the oxygen flatness and a warning value for the pulse rate When the calculated oxygen saturation has a predetermined relationship with the set oxygen saturation warning value, and the calculated pulse rate has a predetermined relationship with the set pulse rate warning value. Warning means for outputting a warning signal when connected, time measuring means for measuring time, 凳 means, light receiving. Memorizable even when power is not connected to the stage, arithmetic means, and warning value setting means. At a predetermined time, based on the storage means and the timing means, the time A control means for storing the calculated oxygen plane flatness, the calculated pulse rate, the set oxygen saturation warning value, the set pulse rate 瞀 s-value, and the output of the warning means in the storage means. It is characterized by having.

BRIEF DESCRIPTION OF THE FIGURES

The eleventh eleventh is a circuit showing the oximeter body of the first embodiment of the present invention. Road map, Fig. 2 is an external front view, Fig. 3 is a circuit diagram showing the state where the oximeter body and the AC adapter are connected, Fig. 4 is an external front view showing the state, Fig. 5 is a circuit diagram showing a state where the data analyzer and the data analyzer of the main body are connected, Fig. 6 is an external front view showing the state, and Figs. 7 and 8 are data analyzers. FIG. 9 is a circuit diagram showing a state in which the oscillator main body and the printer are connected, and FIG. 10 is a bottom view of the appearance showing the state. Fig. 11 is a circuit diagram showing the state where the oscillator unit and the transmitting unit are connected. Fig. 12 shows the state where the receiving unit and the data analyzer are connected. Circuit diagram,

FIG. 13 to FIG. 16 are block diagrams showing various modes of the oximeter system of the second embodiment of the present invention, and FIG. A block diagram showing the configuration of the meter body, Fig. 18 is an electric circuit diagram showing the configuration of the rush current control unit, Fig. 1 S is a waveform diagram showing the output waveform of each unit, Figure 0 is a block diagram showing the configuration of the signal processing unit, Figure 21 is a waveform diagram showing the driving waveform of each L LI), and Figure 22 is the relationship between the output of the amplifier and the frequency. The graph shows that the output and frequency of the synchronous rectifier are the same as the output of the synchronous rectifier. : Graph showing output change with the parameter, FIG. 25 is a D-chart showing “LED driving frequency setting routine” of this embodiment, and FIG. 26 is R high. Pass filter I, の27 and 28 are waveform diagrams showing the operation, and FIG. 23 is a timing chart for explaining the crosstalk. FIG. 30 is a front view showing the configuration of the display unit and the operation unit of the main body of the present embodiment. FIG. 31 is a flowchart showing the operation of the book in the present embodiment. A chart showing the “alarm sound mode setting routine” is shown in Fig. 33. Fig. 34 shows the "AZD conversion routine" with 7 ports-the chart, Fig. 34 shows the "LED light quantity so-called regular routine"-Fig. 35 shows the "AZD conversion routine". FIG. 36 is a flow chart showing the “measurement stop routine”, and FIG. 36 is a flow chart showing the “measurement stop routine”. Fig. 38 shows the flow chart showing the "digital output 1 routine". Fig. 38 shows the flow chart showing the "digital output 1 routine". its "data Note Li ^ sense Lou Chi down" the shown to full b over Ji ya - DOO, 4 0 Figure full b Chiya one preparative indicating the "S a 0 ₂ stability determination Lou Ji emissions", Fig. 41 is a flow chart showing the "digital output 2 channels" and Fig. 42 is a flow chart showing the "pulse wave sound processing area". , 43 is a block diagram showing the configuration of the printer, Fig. 44 is a front view of the printer, and Fig. 45 is a flow diagram showing the operation of the printer. Fig. 46 shows an example of the printer's printout. Fig. 47 to Fig. 4S show the detailed operation of the printer. FIG. 50 is a circuit diagram showing a more detailed configuration of the data analyzer shown in FIG. 5, and FIG. 50 is an operation when the power of the data analyzer is turned on. FIG. 52 shows a π-chart representing an operation in the analysis mode, and FIG. 53 shows a storage state of the storage unit. f Explanation diagram, Fig. 54 is a flowchart showing the operation of the entire data reception routine, and Fig. 55 is a flowchart showing the operation of the analysis processing loop. The 5th Fig. 57 is an explanatory diagram showing the structure of the display unit, Fig. 57 is a flowchart showing the button input routine, and Fig. 58 is a flowchart showing the display routine. Rotate, Fig. 53 shows the data check routine. 7 Rotate, Fig. 60 shows the force-sol * digital value display routine. Fig. 7 shows the history chart creation routine. FIGS. 2A and 2B are explanatory diagrams showing an example of a displayed histogram.

BEST MODE FOR CARRYING OUT THE INVENTION

Hereinafter, a first embodiment of the present invention will be described.

Note that the oximeter in this embodiment can be provided with a trend function and a print analyzer function in addition to a portable data analysis function. In addition, output the real-time saturation information from the measuring means to the outside so that the telemetry function, that is, the function of transmitting and receiving the saturation information by radio can be added. It is composed of

In Figure 1, O key sheet menu over data body (A) is connected to the probe having a light projecting element Oyo shed 'receiving ¾ element - for calculating the S a 0 ₂ and pulse rate Te Control of the analog section (1), which outputs the analog signal, the analog section (1), the multiplexer (3), and the memory (6 and the parallel renorial conversion section (4)). Analog digital conversion (A / D conversion) of the output of the analog part (1), processing of the AZD conversion result, and memory of the processing result and the output of the clock part (5). ), And selects one of the output of the operation control unit (2) and the data stored in the memory (6). ♦ A multiplexer (3) input to the serial conversion unit and a parallel serial that converts the parallel signal output from the multiplexer (3) to a serial signal The display unit (7) that displays the output of the conversion unit (4) and the arithmetic control unit, the analog unit (1), the arithmetic control unit (2), the multiplexer (3), and the serial It consists of a Ralelle conversion section (4), a clock section (5), and a power supply section (8) for supplying power to the memory (G).

The power supply (8) has a built-in rechargeable battery and can supply power to the oximeter body (A) without using commercial power. One one

But Ru can and this cormorant row the measurement of S a0 ₂ and pulse rate carrying the old carboxymethyl menu over data body (A). If you connect an AC adapter or a data analyzer, which will be described later, to the oximeter itself, connect Yasuko (e)

(The power supply Yasuko is connected to (1), and it can be operated using commercial power, and the built-in battery is also charged.

Next, the operation of the oximeter body (A) will be described.

Ana π grayed section (1) is, S a0 _2, and outputs a signal for calculating the pulse rate and pulse waveform calculation control unit (2). Calculation control unit (2) is S a0 ₂ and AZD converts the output of the § analog section (1), calculates the pulse rate and pulse wave at predetermined time intervals. Calculation control unit (2) inputs the output or time of the clock unit (5) for each predetermined time, the S a0 _2, to Ki愫the pulse beats and time Note Li (6). The arithmetic and control unit (2) is provided with input terminals (a) and (b) for identifying which dedicated device the oximeter body (A) is connected to. Each part is controlled by the connected dedicated device, and the real-time SaO ₂ , pulse rate, time, and time are output from the arithmetic and control unit (2) according to the dedicated device. For, any of SaO ₂ , pulse rate, and time stored in the memory is selected by the multiplexer (3). ^ Force of multiplexed Selector Selector support (3) is Ri parallelogram Le signal der, which is converted to The serial signal parallelogram Resid real conversion unit (4), S a0 _2, pulse rate, time of de - Is output to the connected dedicated device via one connection signal line. Since the serial signal is output to the dedicated device in this manner, the number of connection signal lines for outputting to the zero-use device can be reduced, and the reliability of the system can be improved.

When the dedicated device is not connected to the oximeter (A), the multiplexer (3) and the parallel-to-serial converter (4) do not operate. This reduces power consumption and extends battery operation time. be able to.

The control according to each dedicated device will be described later with the description of the dedicated device.

The S a0 ₂ numbers, pulse rate and menu over Tahoe showing a pulse waveform S _aO-2 display portion of the display unit shown in FIG. 2, respectively therewith (3), the pulse rate display unit (1 0), the pulse It is displayed on the wave display section (11). MODE button (1 2) and the UP button (1 to 3) and DO WN Pota emissions (1 to 4) by operating the ∎ You can set the lower limit value of S a0 _2. When the MODE button (1 2) is pressed until "L" SAT "is displayed in the mode display (15), the set SaO ₂ lower limit is displayed on the SaO ₂ display (3). Is displayed. S _aO-2 lower value displayed on the UP Potassium switch (1 3) once pressed, the S a0 ₂ display unit (9) in this state is increased by 1 (%). UP Potassium switch (1 3) when the is pressed more than a predetermined time S A_〇 ₂ lower limit continues to increase continuous manner. The reduced by IJ_〇 VN Bo data switch (1 4) Press once S A_〇 _second display portion (9) S a0 ₂ lower value displayed on Ho 1 (%), D 0 W Po data down If U 4) is pressed for more than a predetermined time, S a 0: the lower limit value is continuously reduced. When returning to the measurement mode and displaying the measured value of the SaO pulse rate t, press the MODE button (1 2) until the display of the 乇 -mode display section (15) disappears. aO _: If the P button (13) and D〇 WN button (14) are not operated for more than a predetermined time after selecting the lower limit setting mode, the measurement mode is automatically set. When the measured value displayed on the display (3) is smaller than the set lower limit, “L 0 SAT” and Sa〇 on the mode display (15) are restored. : The value on the display (S) flashes and an audible alarm sounds.

The upper limit of the pulse rate can be obtained by pressing the M0DE button (12) until "HIP.R." is displayed on the mode display (15). With the upper limit of the pulse rate displayed on the display (10), press the up button.

Press (13) or DOWN button (14) to change and set. Press the lower limit of the pulse rate until the MODE button (12) is displayed in the mode display (15) until "L〇P.R" is displayed. The lower limit of the pulse rate is displayed in the pulse rate display section (10). By pressing the UP button (13) or the DOWN button (14) while the value is displayed, the value can be changed and set. When the M0DE button (12) is pressed until the mode display (15) disappears, the display returns to the measurement mode, and the pulse rate display (10) returns to the pulse rate display. The measured value of is displayed. If the UP button (13) or D〇WN button (14) is not operated for more than a predetermined time after selecting the mode for setting the upper or lower limit of the pulse rate, automatic Return to measurement mode. When the pulse rate is larger than the set upper limit, "HIP." On the mode display (15) and the pulse rate display

The measured value of (10) flashes and a beep sounds. When the pulse rate is smaller than the set lower limit, the mode display (15)

"L0P.R." and the measured value of the pulse rate display (10) blink, and the alarm sounds are pitted.

When the measured value of SaO 2 is smaller than or lower than the lower limit, or when the fixed value of the pulse rate is out of the range between the upper and lower limits, or when the measurement becomes impossible as described later. The alarm sound can be selected by pressing the ALARM button () 7). When “((♦))” is displayed on the alarm sound display section (16) In the above, a warning sound is emitted when the above-mentioned warning state is entered, and the warning sound is not emitted when "((♦)))" is not displayed. In addition, the volume of the warning sound, the mode display (15): When neither is displayed, that is, in the measurement mode, the UP button (13) or the D〇 WN button Press (14) to adjust. Press the UP button (13) to decrease the volume Increase and press the DOWN button (14) to decrease the volume. When adjusting the volume of the warning sound, the warning sound is output regardless of the warning sound generation setting, and the user can adjust while checking the volume. When the volume is adjusted, it is displayed on the set volume level pulse wave display section (11) so that the volume can be checked visually.

When the probe comes off the patient, or when the light transmitted through the part to be measured of the patient (and drops), the pulse wave is small, or when noise is generated due to the fluctuation of the part to be measured. since Do Ri reliable accuracy rather than evil of the measured value is lowered, the door-out is a measurement under capacity, is measured in the S a0 ₂ display unit (3) your good shed 'pulse rate display unit (1 0) The above-mentioned cause that is disabled is displayed, and a warning sound is emitted when a warning sound is set to sound.

The time of the built-in clock is adjusted using the TIME button (18), the UP button (13), and the D0VN'N button (14). When the TIME button (1 3) is pressed first, "TI Μ Ε" is displayed on the TI Μ display (2 1). The moon flashes on the SaO display (9), and the pulse rate In the display section (表示 is displayed at 1 en. In this τ state, t: p button

When the (IΊ) or 0WN button (14) is pressed, the Ά value on the Sa0 display (3) increases or decreases to the value you want to set.

: 1 S) is pressed and the value is set as a month;] The display stops and the day display flashes. When the UP button (ί3) or D〇W〇 button (14) is pressed to,,,, the value of □ in the pulse rate display section (10) increases or decreases, and reaches the desired value. TI Micromax E press port data switch (1 its value is set as the date, S _aO-2 display Oyo (S) 'pulse rate display unit (1 0) Nio during each and minutes are displayed in the At this time, the point is flashing, so press the same P button (13) or D〇W> ί button (14) to set the desired value and set the TI TI Press the button (18) to set the time.

BAD ORIGI AL —

Is set. Next, the minute is turned on, press the P button (13) or the D〇WN button (14) to set the value you want to set, and press the TIME button (18) to set the minute. There is set, the measured value of S _aO-2 and pulse rate are displayed respectively in the TIME display unit (2 1) display disappears Sa0 ₂ display section of (3) Oyo Pi pulse rate display unit (1 0) To return to measurement mode. Note that such a clock function may use a known clock circuit.

The oximeter (A) is provided with a pulse wave sound generating means synchronized with the pulse so that it can be confirmed whether or not the pulse wave is correctly detected. The generation and stop of the pulse wave sound can be switched by pressing the PULSE button (19). The display of the oximeter (A) uses liquid crystal, and the display cannot be seen in dark places such as at night. At this time, when the I GHT button (20) is pressed, the entire display is illuminated and each display can be checked.

When not using the AC adapter (B) or the data analyzer (C) with the battery charger (A), ie when operating from the built-in battery, the battery (display) 2 2) "BATT" is displayed. When the built-in voltage drops and needs to be recharged, the warning sound is emitted for a short time, and the "BATT" display flashes to warn the user of a warning. Can be prevented.

Fig. 3 shows a block diagram when the oximeter (A) and the AC adapter (B) are integrally connected, and Fig. 4 shows the appearance when they are connected. The AC adapter (B) is used to operate the oximeter (A) with the quotient power supply and to charge the battery built into the oximeter (A). In addition, S <ι0: Pulse rate can be output to a general-purpose recorder and a combi- ter to add a trend function.

(23) is a serial converter that converts a serial signal to a parallel signal.

BAD La Le Le conversion unit, (2 4) (2 5) each S a0 ₂ pulse rate, re g capacitor for temporarily storing the time, (2 6) each unit braking Gosuru controller of the AC adapter (B) , (2 7) is S A_〇 ₂ and pulse rate i te-safe i scan standards RS 2 3 2 di di capacitor Le output unit converts and outputs the output format of the C, (2 8) is S D ZA converter for outputting A_〇 ₂ and the pulse rate in analog signal, (2 S) is a power supply unit for supplying power to each unit, rectifying the commercial power source voltage inputted from (3 0) ho pin) The rectifier supplies power to the voltage section (29) and the power section (S) of the oximeter (A) via the terminals (e) and (f). The battery built in the power supply section (8) of the simulator (A) is also charged.

The operation when the oximeter (A) and the AC adapter (B) are combined will be described. Oximeter (A) from control unit (26) to terminal ^)) (<: Outputs a signal that identifies that the connected device is an AC adapter (B). In the oscillator (A), a multiplexer is selected so that the Sa〇 pulse rate output from the arithmetic control section (2) is input to the parallel-to-serial conversion section (4), and the parallelizer is selected. Only S: and the pulse rate are output from the serial conversion unit (4) to the ル C adapter;). Time data does not need to be output to the C adapter (B), and time data is not output to reduce power consumption. The above Sa〇 input to the AC adapter (B) and the pulse rate are not output. The data is converted to a parallel signal by a serial / parallel converter (23), and Sa S: is output to the first register (24) and the pulse rate is shifted to the second level. It is recorded in the register (25). The outputs of the first register (24) and the second register (25) are input to the parallel-to-serial conversion (27) via the control unit (26). S and the pulse rate are output to terminal 7 (g) in an output format conforming to the RS232C standard. Control unit

The Sa02 and pulse rate output from (26) are calculated by the DA converter.

BAD picture sound In (28), they are converted to analog signals (for example, voltage) and output to Yasuko (h) and).

Next, the operation when the oximeter (A) and the data analyzer (C) are integrally combined will be described. Fig. 5 shows the block diagram, and Fig. 6 shows the appearance of the connector. Day Taanara Lee The (C) is O key sheet S a 0 ₂ Oyo Pi graph the pulse rate in real time Lee Tsu Kdei spray Lee (3 7) for outputting either menu chromatography data (A) and graph I It is displayed and recorded on a pickup printer (49) to add a trend function. In addition, a data analyzer function can be added to analyze the measured values of SaO ₂ and pulse rate over R time, which was collected by the oximeter (A) alone.

The data analyzer (C) receives the serial signal output of the oximeter (A) via the terminal (d) and converts it to a parallel signal. The third register (3) temporarily stores the data of SaO: converted into parallel signals ^ by the serial / parallel converter (31). 2), 4th register (33) to temporarily store pulse rate data, 5th register (34) to record time data · time register, and 3rd register (3) 2), 4th register (33) and '5th register (3'i,' Sa 'written in'', pulse rate, time data are input. The arithmetic and control unit (35), which controls each unit as well as the control of each unit, and the S a O ₂ and pulse rate output from the performance control unit (35) are defined as time and A display section (37) that also displays graphs and digital data, S a〇 output by the computation control unit (35): a printer unit (33) that records pulse rate data in a graph with time, selection of a graph display method, The control unit (36) for selecting graph recording and the Sa'O output from the arithmetic and control unit (35), pulse rate, and time data Digital output for digital output according to RS232S standard

BAO ORIGINAL Part (3 3), arithmetic and control unit (3 5) S a0 ₂ outputted from analog output unit for analog output data of pulse rate (4 0), the output of rectifying the voltage of the commercial power supply The rectifier (4) supplies the power to the oscillator (A) via the terminals (e) and (f) and also supplies it to the power supply (41) of the data analyzer (C). 2) A power supply section (41) that stabilizes the output of the rectification section and supplies power to each of the above blocks.

The operation modes of the data analyzer (C) include a real-time mode and an analyze mode. Li Alta Lee Mumo - de in real time, the measured S a0 _2, a mode in the case of the pulse rate graph I click the display and graph recorded. Analyze mode is defined as an oximeter (A).

Data was collected over the ft hours stored in memory (6)

This is the mode for breaking the SaO ₂ , pulse rate, and time. Select the mode with the R button (43) or the Α button (ί4) of the control α (36). The real time mode is the R button (43)

Selected by pressing. The operation in the real-time mode will be described. Operation control unit (35) in real time mode

(A) (b) (c) through the data analyzer (C) force ^;

Although it is time mode, it is input to the arithmetic and control unit (2) of the stimulator (Λ), and the S / S button of the data analyzer (C) is used.

When (45) is pressed, the data of the Sa-: pulse rate and time output from the tomo-controller (2) are output by the oximeter (A). The conversion unit () performs parallel serial conversion and outputs

The multiplexer (3) is controlled so that it is output to the data analyzer (C). If the SZS button (-45) is not pressed, the parallel-to-serial conversion unit (4) does not perform the operation, so that power consumption can be saved. Data analyzer (C) serial via terminal (d)

Of the Sa0 pulse rate and time input to the

BAD QBIQINAt --

The serial signal is converted to a parallel signal and temporarily stored in the third register (32), the fourth register (33), and the fifth register (34), respectively. Is input to the next performance control unit (35). Arithmetic control unit S A_〇 _2, pulse rate input to the (35), the arithmetic and control unit (35) each display unit also time and Yoko轴in Note Once re in the storage and in the graph is displayed, the latest S a0 _2, are displayed by the number woo pulse rate Ho display unit. The S a0 _2, pulse rate and other measurements Tato example, if blood pressure, respiratory rate, brain waves, an electrocardiogram and also to record the de - to jar by data collection can be performed, Ana log output section (4 0) and S a0 ₂ and through de-di- data Le output unit (3 3), pulse rate data is output.

The horizontal glaze scale of the graph display can be selected according to the record speed button (46) in the control section (36). To record the measured values in the graph display together with the graph display, turn on the print switch (49) in the control section (36). The paper feed speed is selected using the record speed button (46). Sa0 ₂ , select the vertical axis of the pulse rate using the control α-button (36) with the first scale button (4 ヮ) and the second scale button (4S). . To finish the measurement, press the SZS button (45). S / S button (i5, 'When the measurement is completed by pressing it, the parameter * of the oximeter (A) will be changed so that the operation of the real conversion unit (4) stops. , (B) and (c), a signal is sent from the arithmetic control unit (35) of the data analyzer (C) to the arithmetic control unit of the oximeter (A). . With the above operation, trend monitoring of SaO ₂ and pulse rate can be performed. After the measurement in the real-time mode is completed, press the A button (44) to switch to the analysis mode, and it will be stored in the memory of the arithmetic and control unit (35). In this way, you can analyze the measured values.

Next, the operation in the analysis mode will be described. Analy ― —

The zoom mode is selected by pressing the A button (44). In the analyze mode, the arithmetic control unit (2) of the oscillator is informed of the analyze mode via the arithmetic control unit ^ terminal ^) ^) ^), and the arithmetic operation is performed. The SaO ₂ , pulse rate, and time over the dwell time recorded in the control unit (2) and the memory (6) are parallel and serial signals via the serial conversion unit (4). The multiplexer (3) is controlled so that the data is output to the data analyzer (C). The SaO ₂ , pulse rate, and time data stored in the memory (6) are converted to parallel signals by a terminal () through a serial ♦ parallel conversion unit (31). The 3rd register (32), the 4th register (33), and the 5th register (34) are temporarily stored and input to the KI and calculation control sections (35), respectively. When the contents of the memory (6) are all 0, a warning is displayed on the display (37). When the transfer of all data stored in the memory (6) is completed, the contents of the memory (6) are automatically cleared to prepare for the subsequent data collection.

滇箅 control section of the data analyzer (C) (35; 'into the internal memory — SaO: it was recorded), all data of pulse rate At the same time, the collected SaO: and the frequency distribution of the pulse rate are displayed, and the time required for data collection is displayed as fmeasurins time. is, S A_〇 :, pulse rate measurement i maximum value and the minimum value is displayed Day di 'data le. This at the left end of the collated diagram showing. S A_〇 ₂ and pulse rate graph display the force - Seo Rugaa is, mosquitoes over Seo Le positions S A_〇 _2, the value of the pulse rate is de di capacitor Le displaying each force -. the position of the source le first force one source Rubota down ( 50) or 2nd force — can be moved by operating the button (51), and when enlarging a part of the graph; Move the cursor to the position of the time that is being enlarged by the first cursor button (50) or the second cursor button (51),

Pressing the 1 button (52) moves the time at the cursor position to the middle of the display. Next, adjust the scale of the time sleeve with the large button (53) and the reduced button (54). The vertical glaze of SaO ₂ and the pulse rate displayed on the display (37) when enlarged is the first scale button (47) and the second scale button (8). Is selected. S A_〇 ₂ and the maximum and minimum values of the pulse rate that has been de-digital displayed in Figure 8, the maximum in the range displayed graph is the minimum value. Each frequency distribution is also a frequency distribution of data within the range displayed in the graph, and the measurement time within the range displayed in the graph is displayed.

rneasur i ng. t ί me is displayed. When hard-copying the display screen, turn on the print switch (43) in the control section and turn the print button (55) on. This is done by pressing. By the above operation, for example, Sa S: collected by the oximeter (A) alone for 24 hours, pulse rate data and time information can be easily disassembled, and the patient can be measured. No. 1 says that the data analysis function is extremely useful for the diagnosis of Byeon's respiratory condition.

Next, the operation when the printer (D) and the oximeter (A) # ^ are described. Fig. 3 and Fig. 10 show the block diagram and j: appearance at this time, respectively. The printer (D) is mainly used for spot measurements, ie not continuous-used to print the measured values during only one measurement. The printer (D) is connected to the serial signal output of SaO ₂ , pulse rate, and time from the parallelizer (4) of the oximeter (A). A parallel serial conversion unit (56) that converts the parallel signal into a parallel signal via the parallel signal, and stores the SaO _: pulse rate and time data converted into the parallel signal for each hour 6 Register (57), No. 7 re g data (5 8), the eighth re g data (5 9), their outputs incarcerated following input, The printer unit (61) to S A_〇 _2, pulse rate, time It consists of a control unit (60) for controlling to print, a printer unit (61) for printing Sa ₁₂ , pulse rate and time. Power to each part of the printer (D) is supplied from the oscillator (A) via the element (k). The Prin data (D), S a0 _2, pulse rate is professional - and to Shirushi宇the measured values to the automatic can that Tsu name to the state that can be correctly measured after blanking apparatus AUT 0 mode, flop can the Li te Prin provided et been to (D) preparative port data down (6 2) is pressed, the a Kino S A_〇 _2, MANUAL to Shirushi宇measurements of pulse rate mode - A mode switch (63) for selecting the mode and is provided.

AUT 0 can a mode is selected, after the blow over blanking is attached to the subject, S _aO-2, pulse rate number of data sequentially inputted to the control unit (6 0) is given Judgment is performed to determine whether or not it is stable within the range. If it is stabilized, it is determined that the measurement can be performed correctly, and the measured value at that time is printed together with the time at the Digitally printed in 1). In the above judgment, the control unit confirms that the A

(60) via the terminals (a), (b), and (c) to calculate the oximeter (A)

By notifying the control unit (2), the operation can be performed by the arithmetic control unit (2) of the oscillator (A). In this case, the operation of the parallel-to-serial conversion unit (4) is stopped until the measurement can be performed correctly, and when the measurement can be performed correctly, When

Sa0: Only the pulse rate can be sent to the printer (D), and power consumption can be saved. Measured when print button (62) is pressed when M A N U A L mode is selected

S a〇 ₂ and pulse rate are printed.

Next, the operation of the telemetry unit will be described. Monitor and monitor the patient's respiratory status during oxygen therapy with an intensive care device ^

BAD ORIGINAL Oximeters are often placed on a shelf on a betside monitor. At this time, the patient and the oximeter are connected by a probe cable. Such patients are also monitored for ECG, respiratory rate, blood pressure, etc., so they are filled with a bedside cable and ready to be used by doctors and nurses. Yes, there is a risk that the probe cable may fall off the patient. Therefore, the force f at which the telemetry unit of the present embodiment is used, this telemetry unit is composed of a transmission unit (E) and a reception unit (F). Ri, transmission Yuni' Doo (E) small fixed to Habe' de of O key sheet menu chromatography data (a) are integrally coupled, O key sheet menu over data S was measured by (a) a O ₂ The pulse rate data is transmitted from the transmission unit (-E) together with the time to the monitor unit and remotely transferred to the reception unit (F). Since the receiving unit (F) and the data analyzer (C) are integrally connected, the patient

S a O Pulse rate Ton monitor can be performed. At this time, the sending IS unit (E) (coupled to the oximeter (A)-'physical') fixed to the bed and the monitor-shelf receiving unit During (F), the connection cable is not required, and there is no choice but to be treated by the guru ^^, without getting caught on the cable, there is no accident;

The transmitting unit can be connected to the transmitter (A), the AC adapter (B), and the transmitting unit (E). - 'bodies to can also fix the binding to base head, S A_〇 ₂ of the patient over ft time using commercial power, the pulse rate motor two motor - that Ki de and child are.

Fig. 11 shows the configuration when the transmission unit (E) and the oximeter (A) are combined. The transmission unit (E) is connected to a modulator (64) that modulates the serial signal output of the parallel serial converter (4) of the oximeter (A). The output of the modulator (64) is received by light, radio waves, or ultrasonic waves. An output unit (65) for sending to the unit (F) and an oximeter (A)

The control unit (66) informs that the transmission unit (E) is connected to the control unit.

The oximeter (Α) is connected to the terminal D through terminals (a), (b) and (c).

Unit (66) recognizes that it is connected to the transmission unit (E) and outputs it from the arithmetic control unit (2).

S θ 2, pulse rate, and time data are converted to parallel serial data.

The multiplexer (3) is controlled so that the signal is transmitted from (4) to the transmission unit (E) via the terminal (d). 'Parallel serial converter

The output of (4) is amplitude-modulated by the modulator (64) and output from the output unit (65) to the receiving unit (F). The modulation in the modulator (64) may be FM modulation or phase modulation.

Fig. 1'2 shows the configuration when the receiving unit (F) is integrally connected to the data analyzer (C). Receiving Uni Tsu preparative (F) is transmitted Interview two Tsu preparative (E) S _a 〇 2 transmitted from the pulse rate, the reception section for converting及Hi 'time to receive and electrostatic Afl ^ (6 7) The control unit (A) sends a signal to the data analyzer (C) to identify that the reception unit (F) is connected to the data analyzer (C). S;:). Real-time mode must be selected until the data analyzer (C) has completed data approval

If the analysis mode is selected before the measurement data of SaO2 and pulse rate is collected, a warning is displayed on the display (37). The measured value and time of Sa〇 and the pulse rate converted to serial electrical signals by the receiving unit (67) are converted to a serial-parallel converter of the data analyzer (C).

(3 1); This is entered. Subsequent signals are sent to the oximeter

This is exactly the same as when (A) is combined with the data analyzer (C): physically. Fine A _-In the above embodiment, the signal for identifying the dedicated device connected to the oximeter (A) is transmitted separately to the line for transmitting the data of SaO ₂ , pulse rate, and time. Although it is provided, it is also possible to use a single bi-directional line that identifies the dedicated device and the line that sends SaO ₂ , pulse rate, and time data.

As described above, since the output of the dedicated oximeter system according to this embodiment is output from one signal line according to each dedicated device, the power consumption is small and the battery can be used for a long time. In addition to the above-mentioned operation, the main body of the oscillator and the dedicated device are integrally connected without a connection cable, and signals are transmitted and received only through the connector. Therefore, the influence of external noise is small and there is no failure such as a new connection cable, so that the reliability is high. In addition, the portable battery can be operated with a small footprint of the oscillometer itself; Sa0 ₂ measured over the R time, the pulse rate is stored, and the time of the If Since it has a memory that can be stored in memory, it is possible to accurately measure SaO: and pulse rate during daily operation of the patient or the subject, and after data collection, read the By setting the data in the data analyzer, the collected data can be easily broken. In addition, by combining each device with the small-sized oscillometer main body, you can select a combination that suits the required functions. Therefore, a system with high cost performance can be formed.

In this embodiment, the oscillator main body (A), the AC adapter (B), the data analyzer (C :), the printer (D), and the transmission The nit (E) is mechanically connected to the body by a connecting means (not shown), and for example, by a pin-junk connection! ) It is configured to be electrically connected without using a cable. In addition, these devices have a built-in micro computer, which

'-BAD ORIGINAL The operation as described above is performed.

In addition, as the oximeter dedicated to the portable data analyzer function, the display means and the real-time plane flatness information output means from the above-mentioned xymeter body (A) are reduced. With this configuration, the portability may be further improved.

Next, an oximeter system according to a second embodiment of the present invention will be described in detail with reference to the drawings. O key sheet menu over data ♦ S ystem in this embodiment, the power sale by being shown in the first FIG. 3, a measurement profile-loop (1 0 1), S A_〇 ₂ and pulse rate, etc. And a main body (103) having a function of outputting the data to an externally stored IC card (102) and outputting the data to an external device. Body

(103) is a special printer as shown in Fig. 1 '4.

(104), and in this state you can obtain a printout of the spot measurement values and the continuous measurement values stored in the main unit (103). I can do it. As shown in FIG. 15, the main body (10S) is a general-purpose information processing device such as a personal computer.

': Connected to 105), and it is possible to perform analysis processing of Sa02 and pulse rate measured in this state.

The IC card (1.02) inserted into the main body (103) is detachable, and the Sa card written on the IC card (102) can be removed. The data such as the pulse rate is analyzed by inputting the I 'two-card (102) into the dedicated processor (10S) shown in Fig. 16. You can do it.

The exchange of fl- between the main unit (103), the dedicated printer (104) and the ";: general information processing device (105)" is performed via a connector. However, infrared light or radio waves modulated by a signal may be transmitted and received wirelessly.

BAD 0 Lord 1 Fig. 17 shows the general configuration of the probe (101) and the main body (103). In FIG. 17, in the main body (103), a signal circuit (107) for processing the output of the light-receiving element (125) in the blower (101) described later, and a signal ^ A multiplexer (108) for selecting the output of the logic circuit (107), an AZD converter (109) for converting the output of the multiplexer (108) to a digital signal, sa0 ₂ and computation of pulse rate, and later displaying unit (1 1 3) or the operation unit (1 1 4) or the like rows of cormorants CPU controls (1 1 0), R 0 M (1 1 1), RAM (1 1 2), display section (1 13) for displaying the calculated SaO ₂ and pulse rate, etc., and operation section (1) for selecting the alarm level and measurement display mode 14), an audio output unit (1 15) for examining alarm sound and pulse sound, input / output of data with a specialized printer / data analyzer, and output of pulse waveform Output section (1 16), detachable IC card for recording measured values (1) The IC card input / output section (1 1 1 7), the time ff section (1 1 1 8), and the LED (1 2 0) (1 2 1) are transmitted and received. An ED drive section (119) for turning on the light, and a section (110) for supplying power to each section are provided. The probe (101) is detachably connected to the main body (103).

The probe (10 1) emits RL (approximately 660 πκι) and emits ED (1 2 — 1), with RL D D () 20) and 340 near ππη. The temperature detector (122) that outputs a signal corresponding to the temperature of the RLED (122) or IRLED (122), and the RLED (122) has a 9 0 0 η «ι is a harmful level output section (123) that outputs a signal f" corresponding to the nearby light emission intensity, a spot measurement probe or an irregular measurement probe- Output from the probe identification output unit (1, 4), RLED (120), and IRLED (122), which output a signal for discriminating whether or not the probe It consists of a light receiving element (125) that emits light and outputs a signal according to its intensity.

In this example, the power supply (110) is an NίCd battery (126) that supplies power to each part, and the RAM (111) is used when the power switch is off. ) And the clock section (118), a backup battery (127), an external power input section (128) for supplying power from the commercial power supply, and an overcharge prevention section (118). 2 3), overdischarge prevention section (130), main battery voltage detection section (1 3 1), backup battery voltage detection section

(1 3 2), inrush current control section (1 3 3), and constant voltage output section

(1 3 4).

Power to each section is supplied from the constant voltage output section (134). In the present embodiment, since the power supply uses a NiC bus / terimeter (126), the measurement can be performed even when the main body (103) is moved. Suitable for sport / port measurement. On the other hand, if the main unit (103) is to be installed and continuous measurement is to be performed, the AC power supply can be connected to the main unit (103) by connecting the AC adapter to the external power input (128). It can also be supplied. Charging of the CJ battery (12) is also performed via an AC adapter connected to the external power input section (12). Here, the C d vano battery (1 26) has a short life when overcharged, and is dangerous because it causes liquid leakage and temperature rise. In this embodiment, N d C When the main battery voltage detection unit (131) detects that the voltage of the battery (1226) has reached a predetermined value (first detection level); The charging current is suppressed to the level that is input to the overcharge prevention unit (1 2 3) and stops charging or overcharge does not occur.

When the dedicated printer (104) is connected to the main body (103), the AC adapter can be used to connect both the main body (103) and the dedicated printer (104). Can be configured to supply power to In order to operate the main unit (103) and dedicated printer (104) while charging the MiCd battery (126), an AC adapter with a large output capacity is required. In other words, the AC adapter becomes large. Therefore, in this embodiment, when the dedicated printer (104) operates, the dedicated printer (104) operates from the dedicated printer (102). By inputting a charge stop signal (135) to the battery and stopping charging during that time, it is possible to use an AC adapter with β output capacity.

Also, the NiCd battery (126) has a shorter life if overdischarged. Thus, in the present embodiment, the main battery voltage detection unit (131) detects that the voltage of the NiCd battery (126) has dropped below a predetermined level (second detection level). And the detection signal is sent to the CPU (110), and the CP (110) blinks all the segments of the display unit (113) described later, and performs a predetermined operation. A warning sound or the message "L w bat tery" is issued from the audio output unit (115) for a short time to notify the NiCd battery (126) of the voltage drop. Prompt charging. Even after this, if the NiCd battery (12G) is not charged and the main body (103) is operated, the voltage of the Cd battery (2G) is further increased. To ί≤; When the main battery voltage detector (131) detects that the voltage has fallen below a predetermined level (third detection level), the overdischarge prevention unit (130) operates. As a result, the power supply to the constant voltage output section (134) is stopped, and the overdischarge of the NiCd battery (126) is prevented.

Also, if the NiCd battery (126) is discharged with a large current due to a circuit failure or the like, there is a danger that its life will be shortened and the temperature will rise. You. Therefore, in this embodiment, it is instantaneous that the N; C d battery (126) is discharged with a large current due to a circuit failure or the like.

Les A current fuse (H) is inserted to prevent this from happening sometimes. Here, in order to reliably shut off a large current discharge in a short time, the current fuse

The rated current of (H) is desirable. However, in the conventional configuration, since a large-capacity capacitor that suppresses noise is connected to the constant-voltage output section (134), the power switch (136) is turned off. Then, a large inrush current flows instantaneously to charge the large-capacity capacitor, and the rating of the current fuse (ヒ) cannot be reduced to prevent this. There was a problem. Therefore, in this embodiment, it is possible to use a fuse having a current rating of β by suppressing the inrush current by the inrush current control unit (133). ing. Here, the suppression of the inrush current can also be realized by a constant voltage circuit having a current limiting function. However, such a circuit has a large current consumption and a large input / output voltage difference required for normal operation, and is not suitable for a battery-operated device such as the device of the present embodiment.

In Fig. 1S showing the specific grooves or the inrush current control section (.133) in this embodiment, (C;) (C;

C,) (C,) I Capacitors: Ρ:.) (R ■ :) are resistors, '' Q—), (Q 4), respectively. Indicates a transistor's transistor and (: C,) IC ₂ ) indicates a 3 end-regulator.

With such a configuration, the inrush current control unit (133) of the present embodiment is

Two constant voltage output unit (VC,) (VC ₂₎ have a large ^ amount co down Den Sa respectively (C) is Sesshibo, (C.) - Ru and its present芙施by the example lever, the power scan I Tsu switch (1 3 6) after on, the time constant of their large co down Den Sa (C JC C :) a and C ₄ ', Kemah The time constant of C · R and the time constant of C ₄ ♦ R are further differentiated by charging over each listening time.

BAD ORIGINAL It's in and this, two large can inrush current at the same time to the constant voltage output unit (VCJ (VC ₂₎ is prevented and this flowing.

Fig. 13 shows the voltage and current waveforms of each part of the circuit shown in Figs. First, when the power supply switch (136) is turned on, the input voltage W of the three-terminal regulator (Id IC) rises, and at the same time, the respective output voltage VAV As also becomes a predetermined value. It rises in voltage. the other hand, that Kemah in the capital run-di Star (Q ₃₎ and (Q ₄₎ each base voltage VB have VB ₂ is C ₃ * R, and C ₄ * R ₂ of It varies with the time constant, and until the transistors (Q ₃ ) and (Q ₄ ) are completely turned on, the charging currents of the capacitors (CJ and (C ₂ ) IC ^ I Cs since each gradual increase, not the this large inrush current flows. Further, since the time constant C ♦ constant C ₄ time Te R this Ku et Baie ♦ R ₂ is large, co down Den Sa (CJ (C ₂ Therefore, the time required to completely complete the charging of the) differs from each other, thus preventing a large inrush current from flowing simultaneously into the _two constant-voltage outputs (VCVC ₂ ).

Referring back to FIG. 17, when the power switch (136) is off, the time (1 IG) and the Π Λ: 1; Action ΪΓ- Τ: A backup battery (127) is provided in the power supply (i10ΰ) so that it can be read. Where the backup battery

When the voltage of (127) drops, when the power switch (136) is turned off, the Jf section (113) and RAM (;! I2) are normal. Operation is impossible. Therefore, a power supply unit (110): a backup battery power detector that detects a voltage drop in the backup battery (12) !! detection unit (132) is provided. When the voltage of the backup battery (丄 27) falls below the value of the battery, the battery voltage of the backup battery is sent to the CP (110). When the CPU (110) receives this backup power voltage 2; Warning of low battery voltage.

Next, before describing the signal processing circuit (107) in detail, the measurement source of aO ₂ in the present embodiment will be described. When light of wavelengths λ and λ ₂ is applied to a living body, the intensities I λ ,, Ι λ ₂ of the remarkable light passing through the living body are

I λ ^ = lo \ _l T t K ^ X ep (EX (d + mu d)

(1)

I λ z = I λ ₂ X Ί t λ ₂ X λ

exp i— g ₂ (EEX

HbO: Hb ^2- ^{+ E} HV ^{x (d +} A ^d "

It is represented by ().

However, here

I Λ.: Incident light intensity at Hamura λ

¾. 7

ΛKOO ': Narus acid navel σ-bin absorption ί-s-wave I¾ input: Extinction coefficient of oxidized hemoglobin

HbO

τ

Hemoglobin Absorption I

^ Hb wave R λ:; Hemoglobin absorption coefficient

Pashi

透過 t person, wave S λ, transmittance of tissue other than artery

Τ t people 艮透透透透透透透透

d Time average of arterial blood thickness

Ad Time variation of arterial blood layer thickness

PAD OB NAL S aO 2: Oxygen saturation of arterial blood.

Here, the IA tDC I λ ₂ DC I λ There I lambda ₂ DC certain min respectively, los the _{(I λ tDC / I λ t} ) and _{log (I λ 2 DC / I} λ 2) it each When IHI _2, ϋλ, Λ 'λ each is approximately ζ

Ad

ϋ ^{λ 1 = 81 (E} Hb0 ₂ ^{_ Ii} Hb) θΟ ~~ ^{+ E} Hb

(3)

^{λ λ 2 = S2 (E} Hb0 ₂ " ^E Hb) θ + E

Hb

It is represented by (4). Here, ϋλ ^ ϋλ ζ is los l At,

X

log I lambda be _two temporal fluctuation component (3) (4) is obtained. Change

1

A, I λ _t, I λ: each o厶1 temporal 'variation component,厶I o

Then, U λ ^, U λ 2 are respectively I λ i Ζ I λ, DC,

Δ I λ ₂ I λ: be determined as a DC (3) (4) equation is obtained, et al. It Te, (3) and (4) the Ri by the and the child to solve for S a 0 ₂

K, (U λ. / U λ: about ten

α 0, =

Λ 人 People: Γ + Κ

In (5), S a〇 2 is obtained. _{_{Here, K ,, K 2, K 3}} , K 4 each wavelength λ ,, λ:; is a constant that Kemah I'm in. In the present embodiment, waves R near 66 Ontti and near 34 Onoi are respectively expressed as λ .. and λ :.

Next, the main body (103) signal processing circuit in the present embodiment is described.

The configuration of (107) will be described with reference to FIG. In this embodiment, a light source having a wavelength of about 600 is used as the light source. RLEDs (10) and IRLEDs (11) that emit light having a wavelength near 94 O nm are used. Each LED (10) (11) has an LED driver (11 S) controlled according to the timing created by a timer built in C.pU (l10). ), And each is driven at a duty ratio of 1/2 as shown in FIG. The light emitted from each LED (120) (121) is attenuated through the living organism (155) and received by the light receiving element (125). The light-receiving element (125) outputs a current corresponding to the intensity of the light incident on the light-receiving element, and this output current is converted into a voltage by the current-voltage converter (137).

Here, body cormorants I below (1 0 3) sweep rate is to come and is set in the measurement mode one de pitch (S i) is connected to繙子(a _t), and one ¾ The output of the current-to-voltage converter (137) is amplified by the amplifier (138). The waveform of the output (AJ) of the amplifier (138) is shown in Fig. 21. The output of the amplifier (ί3S) is the R synchronous rectifier (133) and the IR synchronous rectifier (140). The R synchronous rectifier (1 3 3) amplifies the input (No. I) by a factor of 1, and ED (1 2 0) ) is the period of non-¾凳input signal ^ one 1 (Zofuku to come R synchronization蝥流¾ (1 3 3.) AR the output of the second 1 _0;. in be Similarly, IR synchronization Rectifier (140) IRLED

The input signal is amplified by a factor of 1 while (1 2 1) is emitting light, and the input signal is amplified by a factor of 1 during the period when IR LED (1 2 1) is not emitting light. The output of this IR synchronous rectifier (140) is shown in Fig. 21.

Indicated by AIR. Therefore, when the synchronous rectifiers (1339) (1440) forces are averaged over time, they are emitted from only the RLED (1200) and only the IRLED (1221), respectively. Living body

The intensity of light incident on the receiving element 25) through (155) I do. Therefore, the output of the R low-pass filter (141) and the output of the IR port-pass filter (142) are, respectively, the intensity of light passing through the living body at around 600 nm and the output of the filter. Corresponds to light intensity near 0 nm. In this way, when the signal due to the light incident on the light receiving element (125) is separated into signals corresponding only to the respective waves R, each LED

By appropriately selecting the driving frequency of (1 2 0) and (1 2 1), it is possible to remove the influence of disturbance light and noise caused by a commercial power supply superimposed through a living body.

Figure 22 shows the electrical spectrum of the output of the amplifier (138) when there is a signal due to disturbance light and noise due to the commercial power supply. SP indicates the by that signal component in the light from the LED (1 2 0) (1 2 1), SP 2 is the ambient light component of the low frequency, SP ₃ and SP ₄ is that by the fluorescent lamp or the like disturbances It shows the sum of the high-frequency components of light and the high-frequency components of noise caused by commercial power. fp is the driving frequency of each LED (1 2 0) (1 2 1). When the commercial power frequency is 60 Hz, the frequency is a multiple of 60 Hz, and the commercial power frequency is 50 Hz. It is an integral multiple of S 0 H z.

When the electric spectrum of the (13) output is as shown in Fig. 22, the output electric spectrum of the R synchronous rectifier (1S9) is shown in Fig. 23. Show. In FIG. 23, SP, 'indicates a signal component due to light from RLED (120), SP is a component due to SL light of frequency, and SP ₃ ' and SP are fluorescent lamps. Ff shows the sum of the noise caused by the external high-frequency component due to the above and the noise component caused by the high frequency or part of the noise caused by the commercial power supply. The ^ - to f _ni, _ is over f _P: that is a child, etc. correct frequency. As described above, since the noise component and the signal component due to t (from RLED (120)) have different frequencies, the noise component is reduced by the R port—path 7 filter (144). To remove Can be done. The same is true for extracting signal components due to light from IRLED (122). In this case, it is necessary to make it almost equal to fp ^ n, + fn ₂ ) no 2 to remove the noise efficiently. Therefore the frequency of the commercial power source 5 0 H each LEDU 2 0 in the case when the 6 0 Hz ₂₎ (1 2 1 must switch the driving frequency) Ru.

Therefore, in this embodiment, the frequency discriminating unit shown in FIG.

The CPU (110) determines the operating frequency of each LED (122) (122) in accordance with the output by determining the commercial power frequency used in (153). Set to a multiple of 0 + 30) H when the commercial power supply frequency is 6 OHz) or a sharp (when the commercial power supply frequency is 50 Hz). I do. Here, the frequency discriminator

Specifically, (153) is composed of a pass filter and a converter having a center frequency of about 55 Hz or 110 H2, and the quotient being used. A square wave of 50 Hz or e 0 Hz is applied to the CP (1 10) depending on 0 HI ^ 60 Hz.

Fig. 24: Band pass filter and comparator output change of frequency n separate part (153). Output of band 'and pass filter is commercial power frequency. The output of the comparator is a square wave of the same frequency as the output of the bandpass filter. ) Output a waveform in which the waveform of A1 in Fig. 21 is superimposed on the same sine wave as the output of the PAND BUS filter.

This is performed by the LED drive frequency setting routine which is started when (110) is interrupted by the rise or fall of the square wave from the frequency discriminator (15S). The flowchart of the LED driving frequency setting routine is shown in FIG. 25 and will be described. here, The LED drive frequency may be fixed at (common multiple of 60 and 50 + 25) Hz or (common multiple of 60 and 50-25) Hz. In this case, the frequency f separate part (153) is unnecessary.

First, in FIG. 25, when an interrupt occurs due to the rise or fall of the square wave from the frequency discriminator (153), the time T is set in step A to the CPU (110). At step B, the value stored in the memory address (LT 1) is stored as T 1, and the value stored at the memory address (LT 1) is read as T 1. Then, in step C,

1 X (τ-τ 1)

Then, the frequency of the commercial power supply is calculated by performing the calculation in step D, and in step D, it is determined whether or not the commercial power supply frequency is 50H. Here, if the frequency is 50 Hz, the operation proceeds to step E, and the LED driving frequency is set to 425 Uz Z. If the frequency is not 5 QH.Ϊ, the operation proceeds to step F to increase the LED driving frequency. Set to 5110H2. Then, in step G, the time T is returned to the address of the memo (L-chome 1): this is stored and the original π is returned.

Returning to the second 0 Figure, R port - output path full Note1 (1 I ¹ _) and IR port one pass off Lee Honoré motor (1 4 2), Ma Le Chi flop Selector Selector Sa A / D converted by the AZD converter (103) via (L0S):: input to the PU (110). CP u (l 10) finds the ratio of the output of the co-pass 7 <filter (1 -'4 1) to the output of the IR α -pass filter (1 42). The ED drive unit (113) is controlled so that the ratio falls within a predetermined range, and the light intensity of the RLED (120) and the light emission of the IRL DD (: 21) are controlled. Adjust the intensity. As a result, the signal-to-noise ratio of the output of the R-pass filter (141) and the S / ratio of the output of the IR port single-pass filter -2: become almost equal, and the signal processing is performed. S can be maintained in a favorable condition. IRLED (1 2 1)

BA Hi ORIGI AL The adjustment of the light amount is performed in an LED light amount adjustment routine in the AZD conversion routine in the operation flow of the main body of FIG. 31 described later. The A / P conversion routine and the LED light amount adjustment routine will be described later in detail with reference to FIGS. 33 and 34.

In FIG. 20, CPU (1 10) is the R port — bus filter

The gain of the amplifier (138) is adjusted so that the output of (141) and the output power of the IR low-pass filter (142) are within a predetermined range. The output of the Rn-pass filter (142) is connected to a signal line (SI) output to the outside of the main unit (103). In addition, the R lowpass filter (141) and IRD—NO. Su Hu Noreta

The output of (144) is connected to the R-log (144) and IR-log (144), respectively, and the R-high connected to the subsequent stage is connected. Pass Filter 1 (145), R High Pass Filter]!

(144), IR high-pass filter 1 (146), and IR high-pass filter 2 (14C) to input to the '.. Is done. Also, the output of the R high-pass filter I (1447) and the IR high-pass filter 2 (144 are output from the R inverting amplifier (144), respectively. Even if you use the IR-resonator (150), the multiplexer

(10G); two inputs. Here, R high pass 7 filter H

(144) Also, when the output of the IR high-pass filter H; 1]) is positive, those outputs are converted to A / D converters via the multiplexer (10G). When the output is negative, the output of each inverting amplifier (19) (150) is subjected to 'AZD conversion.

And

Π Core pass filter 1) and 11 Low pass filter: Output of 12), output of R high pass filter II (147), and R inverting amplifier (144) output, IR high-pass filter

BAD ORIGINAL 1 The output of (148) or the output of the IR inverting amplifier (150) is AZD-converted at a predetermined sampling time. Therefore, next, the operation of the R hyper X filter 1 (145) and the IR hyper filter I (146) will be described.

FIG. 26 shows a specific configuration of the R high-pass filter 1 (145) and the R high-pass filter] 1 (147). Here, the IR high-pass filters I (14G) and IR high-pass filters 1 (148) are also R high-pass filters 1 (145) and R high-pass filters, respectively. It has the same configuration as pass filter Π (147). In the second 6 view, R high passphrase Note1 1 (1 4 5), capacitor (C _5), resistor (R _3), the amplifier (AJ, and I by the CPU (1 1 0) consisting open 'switch's that closing is controlled (S _3). on the other hand, R high- pass off I filter] I (1 4 7) are likewise co Nden Sa (C _s), resistor (RJ, It consists of an amplifier (A ₂ ) and a switch / switch (S ₄ ) whose opening and closing are controlled by a CP switch (110).

In such a groove or the like, when the probe (101) is attached to the measuring section (1E5) of the raw copy, the intensity of the light incident on the light receiving element (-125) is reduced.増幅! Amplifies by changing to ¾ (13C) output and R high-pass filter II (14?) output. ; R high-pass equalization (45), I 様

, Pass filter 1 (146), R high pass filter! I (1 4 7) and IR c ί bus off I Noreta G (l 4 S) ³ constant magnitude, respectively

(Since it is set, the saturation state will continue for the period of τ; the grooves or their output \ R time. This is shown in Fig. 27 (A) (B) 2; 2 :: ( Λ) indicates the input signal ^ of the R high-pass filter ί (145), and the second square indicates the input state of the amplifier (A,) at the start of measurement ^ without a switch. Fig. 27 (A) and 2

5A0ORIGI AU 7 view and (B) to the power sale by clear and it bell, the free configuration sweep rate Tsu Chi (S _3), the strength rapidly changes in light incident on the light-receiving element (1 2 5) at the start of measurement come and be, co-for Nden support (C ₅₎ by Ri sudden variation in the time constant of not only eliminated 'to gradually, amplifier to eliminate (a,) or output due to the large gain is the saturation state of or It takes time for the output to be stable and measurable.

Therefore, in this embodiment, for each predetermined sampling time, the output of the AZD-converted R high-pass filter] I (147) and the R inverting amplifier U43) Output, IR high pass filter Π

If either the output of (14S) or the output of the IR inverting amplifier (150) exceeds a predetermined value for a predetermined time or more, as shown in Fig. 27 (E) to, CPU (1 1 0) is then through the output la Lee emissions (teeth) (1 _2), the sweep rate pitch (S j) and signal to only on-short time (S ₄₎ Send it. As a result, when an input signal is input as shown in FIG. 27 (A), the amplifier (A.) is turned on as shown in FIGS. 27 (C) and (D). The plane of the output of (Λ :) is released in a short time, and thereafter, the amplification Λ.)

It is possible to output a signal corresponding to Therefore, according to the present embodiment, the amplification ^ (A.:: Λ _) saturation state at the start of measurement is immediately released by the switch ': S). Also, the R co-gump (1 ■; 3) output: This is the noise that fluctuates at a frequency higher than the frequency of the signal, as shown in Fig. 2C (A). Is included, and the Konoise fluctuates at the R mouth level (1 4 3). Sword output level ÷. Therefore, in this laughing facility, the input signal of the S hi-ha filter was 4).

When the upper limit value and the “limit value” are at the middle level, Fig. 2 S

BAD ORIGINAL (C) a signal sweep rate I by the pitch from the CPU to the power sale good illustrated _{(1 1 0) (S 4} ) by instantly on, the low frequency formed Remind as the second 8 view (B) Minutes are reduced. Here, although the second 8 diagram (C) is the signal of one cycle day-out sweep rate Tsu Chi (S ₄₎ instantaneously 2 Caio down, once-out 1 cycle Nitsu sweep rate pitch (S ₄₎ It may be configured to turn on. Ie, the second 8 views (A) is shown the output-shaped] S that in the prior arrangement does not have a scan I pitch (S _4), and the time and the output level of the whole even It is rising. In contrast, Ho in this embodiment, the CPU (1 1 0) Gala Lee emissions (teeth) is turning on the sweep rate pitch (S ₄₎ through the Runode, second 3 view (B) Thus, the frequency component can be attenuated, and the measurement error due to the low frequency component of the output of the Rn amplifier (143) can be eliminated.

In addition, in this implementation of Kiyoshi, the R Hypass Finale

The integrated value during the period when the output of (144) is positive (Τμ) is SPR, and the integrated value during the period when the output of the high-pass filter H (47) is negative (Tm) is When you talk with S MR,

SS = (SPR / Τμ)-(S / Τm) (6) cancels low frequency component noise, that is, © frequency component What's the noise? It can be assumed that the spur and the period τ M are constant, and the S PR and 'S MR are signal components TJ _pR Jt and ^U MR ^{d L respectively.}

Τμ Τπ,

Noise components N dL and i! L

0 0

And think about U _MR dt + N ♦ Ttn

_S

:

T ρ Τ r «

Tp Tm

0 ^U PR ^DT ₀ ^U MR ^DT

T p T m

m, so that noise of low frequency components can be cancelled. However was, 'ί £ noise frequency components of the time in the period T p and the period T _ffl

When it can be regarded as a linear function, the noise components included in SPR and SMR,

Tp 1

N t dt = T p ² (8)

0 2

丄

N t dt = N Tai: (3)

0 2

And in this case,

S PR S M

= ―-', 10

ρ 'ί rn "

Thus, the noise component can be canceled. Here, SR and SMR are output for each predetermined sampling time: the output of the R high-pass 7 filter (1 4 7) that is ZD-converted. The output can be obtained by integrating the output of the R inverting amplifier (144) with the CP (110). In the period T p and the period T, the output of the R hyperfilter E (147) and the output of the R inverting amplifier (144) are A / ^κD- converted, respectively. It can be obtained from the number of times. Furthermore,

IR high-pass filter β (148) and IR inverting amplifier

BAD OB »G» MA The configuration and operation of (150) are exactly the same as those of the R high-pass filter Π (147) and the R inverting amplifier (143), and are performed during the period Τρ and the period Tm.と Assuming that the output of the R high-pass filter K (47) is SPIR and SMIR, respectively, the noise cancel is

S PIR S HIR

S SIR = (11)

Τ μ T m

(When the low-frequency noise component can be considered constant) or

S PIR S MIR

S S I R = (12)

T p-I fa-

(When the low-frequency noise component can be regarded as a linear expression of time). It should be noted that, if sweep rate pitch (S ₄₎ removal of'll go-between measurement error for the work of sufficient may be omitted the noise key catcher down cell that by the equation (11)

The level of arterial blood planarity (SaO :) is calculated by the signal from the RLED (120) and the IRLED (120) in the R synchronous rectifier (139) and IR rectifier (140). 1 2 1) There is no difference between the signal by light from

K, (S SR / S S ί R}-+ Κ 2 3 (S SR / S SIR)-+ K

Can be obtained by

However, the reception is completed (125) and the current-voltage converter

If the response speed of (13 7) is slow, the output of the R synchronous rectifier (13 S) is set to (No. 5 or-G G) by the t from IRLED (1 2 1). Mixed.

This will be described with reference to the timing chart of FIG. 2nd 9 In the figure, (1 9 2) and (1 9 3) are RLED (1 2 0),

It is a drive waveform of IRLEDU21). (194) is IRLED

This shows the output signal component of the amplifier (138) using only ^ from (122). Current-voltage converter (1 3 7) and amplifier

Since the response speed of (138) is not sufficiently fast with respect to the driving frequency of the LED (122) (122), the rising and falling of the output signal as shown in (134). Downhills are no longer sharp. This is R

When synchronous rectification is performed in the R synchronous rectifier (133) by the same timing signal as the drive waveform of the LED (120), the waveform shown in (135) is obtained. It is. Here, when the rising and falling edges of the signal shown in (1S4) are short, the average value of one cycle of the signal shown in (135) becomes zero, but (19) Since the signal shown in (4) is not sharp, the signal shown in (135) by the area shown by the diagonal lines in (135)

Ί Correction is negative. This is the crosstalk. Therefore, we need to find the exact S a 0 :: 2 needs to correct this crosstalk. The flow chart for measuring this crosstalk is the third

This is shown in Fig. 5 and described later.

In this laughter kiyoshi, immediately after the power of the main unit (103) and the power switch (136) are turned on, the CPU (110); Ji (S) your good: / scan fin switch (S:)! (S; each Po di tion _(a:) (] R2)

(bIR2), set the calibration signal part: 15 1) and the calibration signal part

2 (1 5 2) using the output of the measured stores click b be sampled over click, then scan-'-> Chi (S _t) (SJ (S) with its Rezorepo di tion (al) (bl); b I Rl) to be, set so, are corrected click be sampled over click that Ki馐earlier when determining the S a 0 _2.

First, the measurement of stork will be described. S in Fig. 35

At T1, the power switch (136) is first turned on and the switch is turned on.

BAD ORIGINAL After (S i) (s ₂ ) (s ₂ ′) is set to the concept of the crosstalk measurement, the calibration signal section 1 (1 5 1) and the calibration signal section 2 (1 5 2) outputs 0 V at the same time. At this time, the R low-pass filter (14 1)

1 R 'filter (144), R pass filter] I (144), R inverting amplifier (144), IR high-pass filter E (144) The output of the IR inverting amplifier (150) is subjected to first-order AZD conversion and stored as an offset voltage for each (ST3 to ST8). These are VOLR, VOLIR, VOHR, VORI, VOHIR, and V0IRI, respectively. Next, a signal having the same timing as the RLED drive signal is output to the calibration signal section (151) under the control of CPU (110) (STS). However, the response speed of the calibration signal unit 1 (151) is adjusted in advance so as to be equal to the response speed including the light receiving element (125) and the current-voltage converter (13). Have been. At this time, the R pass finalizer (1.4'1) and the IR pass 7 inverter (14

When the AZD conversion values of the output of 2) are stored as V CLRi and \ ^T CLIRI, respectively, V CLI IRI corresponds to the GST (SΤ10, SΤ11). Next, with S Τ 1 2, the calibration signal section 1 (1 5 1)

In addition to having the same two timings as the IRLϋD drive signal, a signal having the same amplitude as the output having the same timing as the ΠLID drive signal is output. At this time, the A / D conversion values of the R-mouth filter (14 1) Ϊ R π-pass filter (14 2) are assumed to be V CLR2 and V CLIR2, respectively. Write down.に corresponds to the stock t (S Ti S, ST 14).

Next, at S-c 15 and S-c 16, the stored A / D conversion values are subtracted from each other, and then i £ is performed. 0) Equation (21) is performed, and kD and; 5 Ask for.

Also, in ST 17, the 铰 correct ft number part 2 (15 2) has a predetermined period. The rectangular wave is output to the R high-pass filter 1 (45) and the IR high-pass filter 1 (46). R high pass filter at this time]!

(144), R inverting amplifier (144), IR high-pass filter]!

(148) and the AZD conversion value of the output of the IR inverting amplifier (150) are the same! ^ 、 Ji! ! , ^^ (ST 18 to ST 21). In ST22 to ST24, 1 ^ 1, 1 / \ 2, and 1 ^ 3 shown in equations (22), (23), and (24) described later are calculated from these values. Then, determine the value required for crosstalk correction. Then, the output of the dumping signal section 1 (151) and the output of the calibration signal section 2 (152) are set to 0 V in ST25.

Then, CP Ji (1 1 0) nest I pitch (S,) (S ₂₎ back on (S ₂ ') to, respectively it Pojishi ® emissions _{(a 2) (bR2) (} b I R2) Tsu (ST26) and return to the original flow.

When the measurement ends or, biological RLED (1 2 0) having passed through the measurement unit of (1 5 5) and IRLEDs (1 2 1) or these measured from light S a0 ₂ is ¾ line. At this time, the R-port one-pass filter (1441), IR Lono, and the Sino-Roller (1442), and the R-hyperfilter in the sampling time Π (1 i 7), R inverting amplifier (ΐ 49), ΐ R high-pass filter H (14 S), and AZD conversion of the output of IR inverting amplifier (.150) V LR (i), VLIR), V HR (i), VRI (i), V HIR (i) ′: 2 (i). Also, at a predetermined time T, the time when the output of the R high-pass filter Π (147) and the output of the IR high-pass filter 1 (144) is positive is denoted by Τ. μ, and the integration of the values obtained by subtracting \ '0HR and "\' OHίR (i) from VHR (;: 'and VHIR (i), respectively, during that time (the values are directly converted to SV PR , SVPIR.

Furthermore, at the predetermined time T, the outputs of the R high-pass filter (144 G) and the R high-pass filter (144 G) become negative. Suppose that a certain time is T, and the integrated value of the values obtained by subtracting VORI and VOIRI from VRI (Ί) and VIRI (i) at that time is one SVMR and one SMPIR, respectively.

S V PR = ∑ {VH (I)-V 0H} …… (14)

V HR (i)> 0

S V P I = ∑ {VHIR (i)-VOHIR} ー〜 (15)

V HR (i)> 0,

S V MR = -∑ VRI (i)-VORI} …… (16)

V HRCX 0

S V M I R = -∑ {V IRI (i)-VOIRI} …… (17)

VHIR (i) <0

It is. Then, the values obtained by canceling the low-frequency noise component with respect to SVPR, SVMR, SVPIR, and SVMIR are SVP, SVIR, respectively.

S V PR S V MR

S VR = …… (IS)

T ρ m

S \ ^r PIRSVMI ip T

Becomes — one,

kD = (V CLR1-V 0LR), z (V C1.IR2- V OLIR) (20)

^ = (V CLIR1-V OLiR) / ^. OR I) / '(V CH IR-V OH IR) (23) kA = (VCIRI-V 01 RI) / (V CH IR-V OH IR) (4)

V LR (i)-V OL

rD = (25)

V LI (ί)-V OLIR

Then, U λ i / U λ in Eq. (5) is expressed again as UR / IR. β one

U kD

(26)

U IR rA

rB-β one rB

kD

Is required. However, where

'D

β

k

• B = one-D (27)

rD

β

kD

1 1

_{. S v PR + -. ---} SV MR ♦ V LR (ί)

kAl * Tp l ♦ Tm

1 1

S V P I + S V M I R ♦ V L I R (i)

P kA3-T;

(2S)

It is. Therefore, S a 0: is obtained by the following equation using the above correction.

Puru

K (URUI; ^, K ji RZ UI) ² + K ₄

(29)

Here, the calibration signal 1 is used as the signal for measuring the cost.

. 5 1), instead of R LED (1 2 0), I R L E D

• 2 1) Each of them emits independently t) and receives the light

It is good to use the signal received in 25).

(When calculating S a〇 by Eq. 29, Κ., Κ :, K, Κ 4 are R

Ξ D (122) and IRLED (122) Depends on the peak wave, and this peak wave S shifts depending on the temperature of the LED.

BAD ORIGINAL I do. Here, since there is a certain relationship between the LED temperature and the peak wavelength, the shift of the peak wave ¾ can be obtained by measuring the LED temperature. Therefore, RLED

(1 2 0) Oyo the KKK _3, K ₄ measures the temperature of beauty IRLEDs (1 2 1) peak for each LED - I'm on the child correction Flip the shift of the peak wavelength, the measurement result Can be obtained with high accuracy. In this embodiment, the temperature of the RLED (122) is measured by the temperature measuring section (122), and the output is converted to AZD via the multiplexer (108) at predetermined time intervals. By doing so, the value of KKKK is corrected. Here, IRLED (1 2 1) to the teeth, such as this for measuring the temperature of the measures the temperature of only RLED (1 2 0) is, 9 4 0 _n, - _fl vicinity of the light - emitting IRLED (1 2 1) System oice of peak wave counter that by the temperature changes in the 'is good to such effect etc. ton ho on measurements of S a 0 _2.

In this embodiment, the temperature of the RLED (120) is measured by measuring the forward voltage of the RLED (120). According to this method, there is no need to provide a special sensor for temperature measurement, so that there is an advantage that the probe (101) can be reduced in size. Incidentally, MotoEmi the施冽measures the LED power temperature kappa,, K _2, the kappa _3, K ₄ has been shown the method for correcting, R L. ED vicinity ¾ heat body (1 ⁵⁵ 0) Provision, RLED

By setting the temperature of (120) to be constant, the peak of RLEE> (120) may be kept constant.

Also, LEDs that emit near 6 generally have G 60 nrn near the local%) t maxima; this has a submaximal around 900. Therefore, it is necessary to correct KK,, KK 3, and K ₄ according to the emission intensity of the RLED (120) around 660 and the emission around 300). Therefore, in this laughing example, 兗 BAD near S 0 0 of RLED (1 '2 0) The luminous intensity around 660 nta of the light intensity is measured in advance, and the corresponding value is output to the harmful light level output section of the probe (101).

Set as binary information in the multiple switches of (1 2 3), and the CPU (110) sets the set value immediately after the power switch (1 36) is turned on. And KK ₂ , K ₃ , and K ₄ are corrected.

Next, Fig. 30 shows the display unit (113) and the operation unit of the main unit (103).

The specific configuration of (114) will be shown. In Fig. 30, the display section

(111) consists of a liquid crystal display, and (157) is calculated.

S A_〇 _second display unit for displaying the S A_〇 ₂ measurements, a (1 5 8) is pulse rate display unit for displaying the computed pulse rate measurements. (159) is a pulse wave level meter, which lights according to the magnitude of the pulse wave. (1 6 0) is S a 0 ₂ changing tendency display unit showing the temporal change in S a 0 _2. Further, (16 1) is an alarm speaker mark, and (16 2) is an alarm box mark, each of which displays the mode of the alarm sound. I am.

That is, when the alarm sound is set to the mode of only the alarm sound (intermittent sound), the alarm speaker mark (161) lights up and the alarm sound is turned on. When no sound is heard or a combination of sound and warning sound (intermittent sound) is set, the alarm voice mark is set.

(16 2; is lit and the alarm sound is off. When the alarm sound mode is set, the alarm speaker mark (16 1) and the alarm Both the voice mark (1G2) and the light are off.

(166) is a measurement mode display mark for indicating that it is in the measurement mode, and (166) is a test for indicating that it is in the test mode.乇 — Display mark. (1 et 5) S a 0 is displayed when below the lower limit value is set S A_〇 ₂ measurements "lower warning Ma - Kudea Ri, (1 6 6) S aO-is that set : Display the lower limit of

S _a 〇: F limit warning value display section. Furthermore, (1 6 7) indicates the pulse rate

BAD ORIGINAL The pulse rate lower limit warning mark that is displayed when the value falls below the set lower limit value, (1 6 8) indicates the lower limit value of the set pulse rate. Section, (16S) is a pulse rate upper limit warning mark displayed when the pulse rate measured value exceeds the set upper limit value, and (170) is the upper limit value of the set pulse rate. This is the pulse rate upper limit warning value display section to be displayed. (1771) A watch clock colony.

With such a configuration, the power switch of the main body (103) can be used.

When (136) is closed, the "year" stored in the clock section (118) of the main unit (103) is displayed on the pulse rate display section (158). It is. Then after a predetermined time, S a 0 ₂ display unit "month" in (1 5 7), the pulse rate display unit (1 5 8) to "day" is displayed. After a predetermined time, the hour is displayed on the SaO ₂ display (157) and the pulse rate display (158) is displayed.

"Minute" is displayed, and the clock clock (17 1) lights. After a predetermined time, the main unit (103) enters the measurement mode, and the measurement mode display mark (ί163) lights up. However, if the mode switch (172) is already pressed when the power switch (136) is at a certain position, the B meter (1 1 G) is displayed in the order of 'year', 'month', 'day', 'hour', and '^'. After entering the test mode, the test mode processing that will be executed later is executed. — Test mode: Test mode — Test mode — Test mode — Test mode In this case, the test mode is defined by using the calibration signal section 1 (15 1) and the 较信 signal section 2 (15 2) inside the main unit. This mode is used to confirm that the electric circuit in this unit (103) is normal. If it is confirmed that the circuit is normal, the SaO display section (157) and the pulse rate display Part (15S); two "100" are displayed, and when an abnormality II is seen, "E" and the number BAD ORIGINAL Is shown. After confirming that the power circuit is normal in the test mode, press the mode switch (172) again to enter the measurement mode.

Also, if the memory clear switch (173) is pressed when the power switch (136) is closed, the data storage IC card (102) is pressed. ), The erase command is transferred, and the contents of the IC card (102) are erased. In addition, the case of the measurement data! ¾ will be described later.

When the power switch (13.6) is opened, the clock (11S) is not properly backed up by the built-in backup battery (127). For a predetermined period of time after the switch (136) is closed again, the clock common mark (171) does not blink or stays on. This is a function that allows the user to reset the clock section (11S). -Next, Sa〇: Low limit warning, pulse rate upper limit warning value, and pulse rate lower limit warning Sword setting method]. First, the mode switch

Pressing (1 7 2) only once switches to the S0 lower limit warning value setting mode, and the amplifier switch:: 1 7 4); r Set. At this time, the S lower limit warning mark (155) or the S 0 _lower limit warning value display section (166) is dotted. When the switch (175) is pressed, the warning value is incremented by one, and when the switch is kept pressed, the alarm value is incremented by 3; this is incremented. Down side switch

If you press G), a warning will be generated, and if you keep pressing it, the warning value will be automatically decremented. S d〇: When the mode alarm (1 7 2) is pressed after setting the limit warning value, the mode changes to the pulse rate lower warning value setting mode, and the pulse limit warning-mark is displayed. (1ΰ) or lower pulse rate warning ί Direct display (15) or 'blinking and up-down switch

BAD 0R 咖 A Similarly, the pulse rate lower limit warning value is set according to (174). When the mode switch (1Ί2) is pressed, the mode switches to the pulse rate upper limit warning value setting mode, and the pulse rate upper limit warning mark (169) and the pulse rate upper limit warning are displayed. The value display section (170) flashes, and the pulse rate upper limit is set in the same way by the up-down switch (174). Further, pressing the mode switch (17 2) terminates the above warning value setting mode. Incidentally, even during the set mode of the above warning value, the measurement and display of the S A_〇 ₂ and pulse rate is performed. In addition, if the up-down switch (174) is not operated for a predetermined time or more in each warning value setting mode, the setting of the warning value ends. The warning value set in this way is always stored in the RAM (112) backed up by the backup battery (127), so that the same warning value is always stored. When the value is used, it is not necessary to set the warning value every time the power switch (136) is closed.

Next, a method of setting the alarm sound mode will be described. Pressing the switch (1 7 2) while holding down the alarm switch (1 7 "7)" will turn on the alarm sound mode, and then turn off the sound or turn on the sound. And the alarm sound mode, ', the alarm sound only mode, the alarm sound power ^f-off mode, and ¾ mode; ALARM SWITCH (1 7 7) ALARM SWITCH (1 7 7) ALARM SWITCH (1 7 7) Pressing the UP / DOWN switch (T4) while holding down changes the volume of the alarm sound, and the alarm sound mode from the audio output section (1 15). An alarm corresponding to the alarm is generated, and the alarm volume is displayed on the pulse wave meter (153) Note that the volume is adjusted when the alarm sound is off. Otherwise, the alarm sound mode The mode switches between voice and warning sound, and the selected alarm sound mode and the set alarm Information on the volume is stored in the RAM (112) backed up by the backup battery (127). Therefore, even if the power switch (13, 6) is released once, the alarm sound mode selected previously and the set alarm volume are recorded on the main unit (103). . The selection of the alarm sound mode is performed by the “alarm sound mode setting step” shown in step # 3 of FIG. FIG. 32 shows a detailed flowchart of the “alarm sound mode setting step”. These descriptions will be described later.

Returning to Fig. 30, pressing the mode switch (172) while holding down the pulse switch (178) causes the pulse wave sound (to be synchronized with the pulse). Sound) can be turned on / off. Also, the volume of the pulse wave sound is the same as the adjustment of the alarm sound volume.

You can do this by holding down (1 7 8) and pressing the after-down switch (1 7 4).

Next, a method of setting the clock section (i 1 S) will be described. When the time switch (17S) shown in Fig. 30! 21 is pressed, the pulse rate display section

(15 3); This "year" is displayed as a dotted line, and the "year" can be set using the up-down switch 1000 (1Tt). Next, press the time switch (17 3), and the “Sa” :: display (15 7) will display “Month” and the “Pulse rate display section”: 15 3) will display “Day”. Is displayed, and S dO—display

The display of "month" in (157) flashes. The setting of the "month" is likewise done by the up-down switch (174). Next, when the time switch (173) is pressed, the "day" of the pulse rate display (153) flashes, and the up-down switch (174) is used. The "day" is set. When the time switch (17 3) is further pressed, "Sa": "Hour" is displayed on the display (157) and "Minute" is displayed on the pulse rate display (158). , The “hour” indication on the S a O ₂ display (157) lights. The "hour" setting is also made by the up down switch (174). When the time switch (173 _t ) is pressed further, "minute" flashes and the setting can be made in the same way. If you press the time switch (173) here, the time setting is completed and the mode returns to the measurement mode. If the up-down switch (174) is not operated for a predetermined time or more after the time switch (173) is turned on, the setting of the clock (113) is completed, Return to measurement mode.

The alarm mute switch (180) is used to temporarily stop the alarm sound or reduce the volume of the alarm sound after the alarm sound is generated. It is a switch to perform. The state in which the alarm sound is temporarily stopped or its volume is made extremely low is called the alarm mute state. The alarm mute state is released by (1) S a〇2 or when the pulse rate is released from the warning state. ( _{2) The} alarm mute switch (1 S0) or ' If it is pressed again, (2) if it has been more than a predetermined time since the alarm mute state, (2) an alarm sound is generated due to the first cause, and the alarm mute is generated. Pressing the Tosu Ino (1S0)-After entering the alarm mute state, if there are 51 warning states on the ffi field S, there are four cases The alarm sound is regenerated at the set volume if the alarm is in a warning state after canceling the alarm mate state. Figure 31 shows a flowchart of the operation of the main unit (10S). In FIG. 31, when the power switch (136) is turned on at step # 1 (hereinafter referred to as "stepping the step"), at # 2, the power is turned on in the main body (103). Nissharai's ni is performed. 2 In the initializing process, the memory is measured and the memory clear switch is turned on when the power switch (13S) is turned on. When the switch (1Ί3) is pressed, the memory of the IC card (102) is cleared and the display In (113), "year", "month", "day", "hour", and "minute" are sequentially displayed for a predetermined time as described above. Then, when the voltage of the backup battery (127) is reduced, and the backup battery voltage detection unit (132) sends a voltage drop signal to the CPU (110). The display section

The (1 1 3) clock indicator (1 7 1) lights up and the clock section

The user is prompted to set the time of (1 1 3).

When the power switch (1 3 6) is turned on and the mode switch (1 7 2) is not pressed in # 3, the measurement mode is executed and the switch is pressed. If it is, the test mode is set and the test mode processing is performed in # 4. After the test mode processing is completed, if the mode switch (17 2) is pressed with 5, the measurement mode is set.

In the measurement mode, depending on the state of the probe identification output section (124) of the probe (101) in # 6, the spot measurement mode is executed, or It is determined whether to execute the continuous measurement mode. When a probe for continuous measurement is connected to the main unit, the continuous measurement mode # 7 or lower is run. In the continuous measurement mode, first, at # 7, RLED (120) and IRLED (122) are driven to start emitting light. Next, in # 8, the alarm level setting step for setting the Sa0 alarm value, pulse rate upper limit alarm value, and lower limit alarm value is executed as in '; か. Is done. Then, in step 3, the alarm sound mode setting step of the 3 2! 21 indication is executed.

The alarm sound mode setting stage shown in Fig. 30 is used to set the alarm sound as an alarm sound when an alarm condition occurs. Use a warning sword to warn you, or make a setting to not generate alarm sounds. First, S1 in the 3rd ；; the mode switch (172), the alarm switch (177), and the force f ^ 'And S 2 only if pressed simultaneously Proceed to If both switches (1Ί2} (1777) are not pressed at the same time, return to the original flow. In S2, the RAM (1 1 2) The alarm sound mode set and stored in is read out, and in S3, it is determined whether or not the current alarm sound mode is the alarm sound 7 mode. In the case of the alarm sound off mode, proceed to S4 to set the alarm sound mode to the warning sound only mode, and press S5 to display (1). 1 3) Turns on the alarm mark (1 6 1) of the alarm, and saves in RAM (1 1 2) that this warning sound only mode has been set in S 6. To return to the original flow.

If it is determined in S3 that the current mode is not the alarm sound off mode, the process proceeds to S7 to determine whether or not the current alarm sound mode is a mode including only a warning sound. I do. Then, in the case of only the alarm sound mode, set the alarm sound mode to the alarm sound and voice mode with SG and set the alarm sound mode. Turn on the alarm mark (11) and the alarm mark (ie 2), and press s6 to confirm that the mode of this warning sound and voice has been set. Store in (1 1 2)-original 7 =-: Nil return. ^

Further: If this is determined in S7 to be the current sword alarm ^ 乇 — Do or '' a-sound -r: Mino mode ', then s: set to 0. Then, Arii is- 乇 ―

Set the ':' to the off-axis, and use S 1 を to set both the alarm speaker mark (1G1) and the alarm voice mark (G2). The alarm is turned off in S6, and the setting of the alarm § "off mode in S6 is stored in the RAM (: i2) and the original 7G is returned.

Next, at 10, when the time switch (17 s;) is pressed to set the time part (1ι)> time η 1, ^ Time setting-The chin is run and the time is set manually It is. Next, use the # 11 volume control routine to manually

-The setting of the generation or stop of the volume of the sound and the sound of the pulse wave is called | Next, at the 0 conversion step of # 12, the R port—pass filter (1441), IR lono, and 'filter (144) at predetermined sampling intervals , R High Pass Filter II

AZD conversion of the outputs of (144), IR high-pass filter I [(148), R inverting amplifier (149) and IR inverting amplifier (150) is performed successively. It is. Then, these A / D converted values are integrated by a predetermined number n of samples to calculate the SVR and SVIR. The detailed operation of this AZD conversion routine is shown in the α-chart of FIG. 33.

In Fig. 32, first, in (1), the output of the temperature detector (2 2) is AZD-converted and recorded as VTH, and then in (2), the output of the R low-pass filter (144) is output. A / D convert the output and write as \ 'LR), and then in ③ IR port — The output of the pass filter (144) is converted to AZD

V LIR (and then memorized as

V LR (originating Bruno of Π及Hi 'VLIR (ί) both LED using (1 2 0) (1 2 1); LED light amount adjustment Le adjusting the amount - enter the switch down.

This i. RD light intensity adjustment step is shown in FIG. S4. In Fig. 4, first, 3-1

IRA Τ = VLR (i) / VLIR () …… Calculates (30) to find the data IRAT. Then, in page 2, it is determined whether or not the second data IRAT is "2" or more. If it is "2" or more, the driving current of the IRLED (1 2 1) is increased by D-3. Set to 2x and return to the original AZD conversion routine. If it is determined in step 2 that the data IRAT power is not more than "2", the process proceeds to step S-4, and it is determined whether the data IRAT power is less than "1Z2". And If the data IRAT is less than "1Z2", proceed to step 5 and set the drive current of IRLED (1 2 1) to 1/2 and return to the original AZD conversion routine .

When the so-called 光量 step of LED light quantity shown in FIG. 34 is completed at ④ in FIG. 33, whether the switches (3 ₃ ) and 3 ₄ ) shown in FIG. 26 are turned on at ⑤ Determine whether or not. This judgment is R-Hino. Output of filter Π (147), output of R inverting amplifier (144), output of IR high-pass filter 1 (148), and output of IR inverting amplifier (150) either in-out capital of more than go-between a predetermined value cotton at a given time of the force, vinegar I 'down switch (S ₃₎ (which is configured to cormorants by Oh the main routine of the SJ. and its, ⑤ death I When Tsu on-Ji (S 3) (S ₄₎ is determined, the scan I pitch (S ₃₎ (S ₄₎ and is instantaneous on-both in ⑥, in ⑦ the proceeds. ⑦, It is determined whether or not the gain of the amplifier (1338) is to be changed, and if the gain of the amplifier (13S) is to be changed, the gain is set to a predetermined value with ⑧. If you do not want to change the gain, you can leave it as it is, and then A / D convert the output of the R high-pass 7 filter (144) to V HR (!). In ⑩, the output of the R inverting amplifier (144) is converted to AZD Then, it is stored as VRI (i), and in ®, the output of the IR high-pass filter 辽 (1 i S) is converted to ZD by

It is stored as VHIf;). In addition, © is an IR inverting amplifier.

The output of (150) is A / D converted and stored as VIPJ).

Then, © discriminates whether or not the Λ / D converted data has reached a predetermined number of samples, and performs steps from ② to © until the predetermined number of samples is reached. Return. When it is determined that the number of samples has reached the predetermined value in '©; when it has been reached, the error due to the fluctuation of the baseline is corrected in ® (noise canceling of the β frequency component described above), and in ©. The crosstalk is measured by the crosstalk measuring pin shown in Fig. 23 and 3 1 Return to the routine shown in the figure. Then, in # 13 in Fig. 31, it is determined whether the number of AZD-converted samples has reached a predetermined number n, and the operations from # 8 to # 12 are performed until the number reaches the predetermined clause _n. repeat.

When the number of samples reaches the predetermined number n, a calibration constant correction step is next executed at # 14. In this step, the output of the temperature detector (122) is subjected to AZD conversion, and the detected constants and the output of the harmful light level output unit (123) are used to calculate the calibration constants, and K in equation (29). _2, the correction of K ₃ and K ₄ are carried out. Further, in the present stearyl-up, which will be described later pulse wave sound punished ¾ Le - sets the frequency of the pulse wave sounds generated by Chin ^ Ji value to S a0 ₂ calc.

Their to, the S A_〇 ₂ based on the # 1 in 5 (29) is calculated, the pulse rate in the # 1 6 is calculated. Here, the calculation of the pulse rate is performed as follows. First, the pulse waveform is binarized by the pulse waveform shaping circuit (154), and the rising or falling time is temporarily stored in the RAM (112). Next, the period of the pulse waveform is obtained from the recorded time, and the pulse rate is obtained from its reciprocal. Further, the calculated SaO ₂ and pulse rate are displayed on the SaO display section (157) and the pulse rate S display section (15S), respectively. In the event that the Sue is changing at the second time, the upward or downward arrow of the Sa〇: change tendency display (160) is turned on according to the direction of the change. It is.

: In most cases, 1 is used to determine a warning condition. First, S aO and the pulse rate calculated from the AZD conversion result of the signal processing S unit (10 “7”) are correct (measured, so that it is determined whether there is any. N). When the amount of light received by the element (125) is larger or smaller than a predetermined value, that is, V LR (i) or V LIR (i) is a predetermined value. If it is larger or smaller, it is determined that the π-bub (101) is out of the measured area, or that the measured area is too thick to be measured. If the change in the pulse waveform is larger than a predetermined value, it is determined that the measured site has moved. If the change in the pulse waveform is smaller than the predetermined value, it is determined that the blood circulation at the measurement site is poor and measurement is impossible. The magnitude of the change in the pulse wave is determined by determining whether one or a combination of SVPR, SVMR, SVPIR, SVMIR, SVR, and SVIR in the equations (14) to (19) is a predetermined value. It is determined whether it is larger than the specified value or smaller than the specified value. If the SaO ₂ and the pulse rate cannot be measured as described above, the SaO ₂ display section (157) displays the causative force f “C”, “L”, “A” , "P" and so on.

Here, if it is determined that the unmeasurable state has continued for a predetermined time or more, the LEDs (120) and (122) are stopped from emitting light, and the power consumption is reduced by (S). At this time, each ED (120) (122) is turned on at a predetermined time interval to determine whether or not the measurement capability has returned to the state where normal measurement can be performed. This process is performed in the measurement pause routine shown in FIG.

In FIG. 36, at 100, it is determined whether or not the measurement ability state has continued for a predetermined time or more, and if it has continued for a predetermined time or more, the display proceeds to if 101 and the LED (1 20) (1 2 1) Stop driving, and set CP mode (1 10) to low power consumption mode with ^ 102. If the measurement disabled state does not continue for more than the specified time in # 100, return to 桉 1G in Fig. 31. From 102, proceed to # 103 to determine whether the measurement mode has been changed. If the measurement mode has been changed, proceed to # 6 in Fig. 31 and change it. If not, proceed to # 104 and wait for the specified time to elapse after the # 102 LED stops operating. After this predetermined time has elapsed, # 1 0 5 [ _{t] is} rubbed and the CPU (110) is set to the operation mode, and # 106 is used to turn on the LED (122) and (122). Start driving and proceed to # 8 in Fig. 31. The above is the operation performed in # 17 of FIG.

Next, the display step is executed at # 18 in FIG. The display scan Te Tsu Pudeho, # 1 7 warning determination scan Te Tsu can and unmeasurable state-flop has not been detected display the calculated value of S _aO-2及Hi 'pulse rate (1 1 3) To be displayed. When measurement is disabled, the display of S aO: and pulse rate on the display (113) is not updated, and "C", "L", "A",

The state where any of "P" is displayed is maintained. Then, when the main battery voltage detection unit (1311) is sending a detection signal indicating that the voltage of the main battery has fallen below the second detection level to the CP (1: 0). Repeatedly blinks all segments of the display section (丄 13) for a predetermined time, and emits a warning sound from the audio output section (115) only for a predetermined time.

Then, go to # 1 9 and you will see the alarm. ¾! In this step, SaO: lower limit warning, pulse rate lower limit warning, and pulse rate upper limit warning are determined. First, the calculated SaO and the set SaO: lower warning value are compared with it. If the calculated value is less than or equal to the lower warning value, Sa〇: lower warning alarm mark ( 16 5) and the S a〇 display (1 5 7) are turned off. The calculated pulse rate and the set pulse rate lower limit warning are compared with the set pulse rate upper limit alert value: The pulse rate is calculated to be less than or equal to the lower limit warning value or the upper limit alert value. If it is higher than S-ί, then the pulse rate lower limit warning mark (167) or the pulse rate upper limit warning mark; 1G3) and pulse rate ― _

The display (158) flashes. Furthermore, S _aO-2 If the calculated value is less than S A_〇 ₂ lower Medogi tell value, there Iho if pulse rate calculated value is out of range of the pulse rate lower warning value and the limit warning value (§ La chromatography Alarm state), or when it is determined in the warning determination step that the measurement is not possible, a warning sound or voice is issued according to the set alarm mode.

When the alarm sound mode is off, no warning sound is emitted. In other modes, an intermittent tone with the first frequency will be generated if measurement is not possible. Further, if the S _aO-2 limit is alerted, alarm sound mode only alarm sound - intermittent tone having a second frequency is found to occur in de, Ala - beam sound of the voice and alarm sound In the mode, a synthesized voice called "SaO, is low" and an intermittent sound having the second frequency are generated from the voice output unit (115) alternately. If the lower limit of the pulse rate is warned, in the alarm only mode, the alarm sound with the third frequency is generated and the alarm sound is emitted. In the source of the voice and the warning sound, a synthesized voice called "Pulse is low" and an intermittent sound having the third frequency are generated. Also, if the upper limit of the pulse rate is warned, in the mode in which the alarm sound is a ^ sound only, an intermittent § with the fourth frequency is generated-and the alarm sound is sounded. In the voice and warning sword mode, a synthesized speech such as "Pulse is." And an intermittent tone having the fourth frequency are generated.

For the alarm sound, the frequency and the interval between the intermittent sounds are fixed in the above description, but this can be made variable. For example, it is possible to vary the volume of the alarm sound, the frequency, or the interval between the diaphragm sounds in accordance with the difference between the setting warning and the measured value. As a result, the degree of danger or the tendency of the danger to become worse or recovering is indicated by sound. You can know. It is also possible to make the volume, frequency or intermittent sound interval of the alarm sound variable according to the time from the occurrence of the notification state or the occurrence of the under measurement function.

Further, an intermittent warning sound of a different frequency may be emitted depending on the cause of the measurement failure. That is, when “C” is displayed as the cause of measurement failure, the intermittent tone at the fifth frequency is displayed, when “L” is displayed, the intermittent tone at the sixth frequency is displayed, and “A” is displayed. The display may be configured such that an intermittent sound of the seventh frequency is generated when it is displayed, and an intermittent sound of the eighth frequency is generated when "P" is displayed. In addition, depending on the cause of the unmeasurable state, a warning may be issued by voice with respect to the cause. Further, depending on the cause of the under-measurement state, different alarm sounds may be emitted in different continuation states.

In the alarm processing step in Fig. 31 # 13, the following alarm mute processing is performed. If the alarm mute switch (1330) is pressed when the alarm status is 1 or indeterminate status, Stop sound production or set their volume very low and set them to alarm mute state. In the alarm mute state, the alarm speaker mark or the alarm voice mark is displayed according to the specified alarm and mode. Flashes. The alarm or non-measurement state is being selected; when the alarm mute state is set, the alarm mute switch (1 3 If 0; is pressed, the alarm sound or voice is displayed with the volume set in the alarm sound mode setting step, and the alarm sound is output. The alarm status or measurement ready status continues, and the alarm alarm status has already been set and another alarm status or measurement disabled status is set. When this occurs, the alarm mu-mut condition is resolved. Alarm sound mode — a beep or sound is emitted at the volume set in the alarm mode setting step. In addition, after the alarm state or measurement impossible state has occurred and the alarm mute state has been set, if the specified time has elapsed, or if the alarm state or measurement cannot be performed. The alarm mute state is released when the alarm goes off.

Here, the frequency of the alarm sound changes according to the amount of deviation between the set warning value and the measured value (calculated value), and when a predetermined time has elapsed from the occurrence of a warning state or the generation of an unmeasurable state. Fig. 37 shows the flowchart of the Fue embodiment when the volume of the alarm sound is increased. In a third 7 Figure, S _aO-2 under 'limit warning value one S _aO-2 measurements) is SaO: lower warning value and S _aO-: and Wa table warts or Ru frequency difference between the measured value, y (pulse rate Upper limit warning value-pulse rate measurement value), z (pulse rate lower limit warning value-pulse rate measurement value) Frequency that is higher than the upper and lower limit values of pulse rate and pulse rate measurement by difference from pulse rate measurement It is. The present embodiment Dehoa la - frequency during beam generation, cadence Nitsu, although the priority of the hands is the pulse rate lower limit warning Ru in summer and the first place, S _aO-2 lower limit warning or pulse rate limit warnings In addition, (AIF 1) has a flag that indicates whether it is in a false state or not. ■ and ■

It becomes "ί".

(AλίF) is a flag that is set to "1" in the alarm mute state. Further, (AIF 2) A La chromatography neglected-menu preparative process le over the subsidence - is activated ^ / lag (AIF ^lambda -: Ri COPYING Dea of ', (A ί F 3) Newフ A flag indicating that another alarm condition has been determined or canceled.

In Fig. 37, first, at 2'00, the content of the flag (AIF1) is copied to the flag (AIF2), and is used to determine whether or not the measurement is in the active state. AD dRiC?.! NAL Determine whether or not. If the measurement is not possible, the interrupt for pulse sound generation is prohibited at # 202, and it is determined at # 203 whether the alarm sound mode is off. In here, if in the case of a la over Muonmo over Dogao off the full opening Ichihe Li Turn-down and also, on the other hand alerts Muonmo not an Doka ^f O 7, # 2 0 The first to indicate the unmeasurable state at 4

The audio output unit is set to emit a warning sound with frequency f,

1, yes. Then, "08H" is set in the flag (AIF1) by # 205, and the process proceeds to 242 described later. Here, when the flag (AIF1) force is set to 08H ", it indicates the measurement ability state.

If it is determined in S201 that the measurement is not impossible, 20S

Prohibit interrupt for pulse wave sound generation, and use # 207

Judge whether the measured value of S a〇 is less than or equal to the S a 瞀₂ lower limit report value. Here, if the measured value of S a〇 ₂ is determined to be less than or equal to S a 0 _: lower warning value,

2C3 determines whether the AND signal between the flag (AIF1) and "01H" is "01 ι-ί" or not. That is, in the first step, it is determined whether or not the least significant bit (LS #) is "". Here, it does not matter whether or not the bit of # 1 is "". And this is "0 1

ΪΓ, ΪΓ, なければ t t なければなければなければなければなければなければなければなければなければ：：なければなければなければなければなければなければなければなければなければなければなければなければなければなければなければなければなければ. That ^ 2

0: Flag in 'Flag (AIF 1) ^, IF 2): Copy and proceed to S 2 1 1

# 2 i1 determines whether the alarm ^ mode is o7 or not.

If it is /, return to the flow. Must be off フ 2

Proceed to 1 2

f: = x (S dO lower limit report—S a〇 measured value)

Then, the second frequency is incremented, and # 213 is used to determine whether the alarm sound mode is the alarm sound only mode. And the alarm

BAD ORiGlNAL If the mode is an alarm only mode, set the audio output unit to emit an alarm at frequency f ₂ and period T ₂ at # 2 14. Hand, # 2 1 3 If it is determined not to be the mode of elbow Tsugeoto only, # 2 1 5 "S a0 _{2 is} low" alternately voice and beep sound period T ₂ in the frequency will leave Set the audio output section so that it is emitted to the user. Then, from # 2 14 or # 2 15, go to # 2 16 and set "0 1 Η" to lug 7 (AIF 1). That is, when a Flag (AIF 1) is "0 1 H" (least significant bit is "1"), and this the S _aO-2 measurements is below the S _aO-2 lower warning value Is shown.

# 2 0 when S _aO-2 measurement is not equal to or smaller than S A_〇 ₂ lower warning value at 7, Flag (AIF 1) advance to 2 1 7 "0 0 H" to re set Is done. Then, at # 2 1 8 the S a〇2 display

The blinking of (1 5 7) is released and # 2 13 determines whether the measured pulse rate is above the pulse rate upper limit. Here, if the measured pulse rate is equal to or higher than the upper limit, the display section is set so that the pulse rate display section (153) blinks at # 220. Then, in # 22], it is determined whether or not the alarm sound is one, and if the alarm sound mode is off, the cuff D is returned. Alarm sound mode must be smart

:,, ~ Ί—

T ~ ~ (1,. J

! '3 = y (pulse rate limit ¾-value per pulse rate measurement (direct)

From the third round; the number of skins is calculated.

In the case of 2 23, whether the alarm sound mode is a mode in which only an alarm sound is generated or not is determined. If the alarm sound mode is a mode in which only an alarm sound is generated, 2 2 4: rubbing The alarm sound of the periodic block is already set to the sound output at the frequency. If it is not the mode that generates a warning sound, proceed to S225 and set the sound output section so that "Pulse \ zhigh" and a warning sound with a frequency of T are generated alternately. I do. So

; :: Λ 'BAD ORIGINAjL In # 22, 7 lag (AIF 1) is replaced with "0 2H" and 7 lag.

Set to the OR signal with each bit of (AIF1). That is,

When passing through C, the flag (AIF 1) becomes “02H” with the OR signal of “00H” and “02H”, and # 2 When passing through 16, the OR signal of "01H" and "02H" becomes "03H".

# If the pulse rate measurement value does not exceed the pulse rate upper limit value in # 2 1 # 9

2 2 7: Rub it and determine if the measured pulse rate does not fall below the lower pulse rate warning value. If the measured pulse rate is lower than the lower pulse rate warning value, set the display so that the pulse rate display blinks in # 228, and press # 22S. Determines whether it is an alarm sound mode or a smart phone. Then, in case of the alarm sound mode, it returns to the original flow, and the alarm sound mode is turned off with # 2 29 '. If not, use # 2 3 0

= Pulse rate lower limit warning value-Pulse rate measurement value)

: The second frequency is exposed. Further, in # 231, it is determined whether or not the alarm sound mode is a mode for generating a warning ^. If the mode is the mode, proceed to step 232 to determine the frequency and period. _;

R

Warning ^ -Alarm sound mode is alarmed by 2 3 1

# 2 3 if not in mode that generates 2? , Suspend: and the frequency, ^]. Then, flag with S 2 S 4

'Λ: Set the OR signal of F1) and "04 0" to the flag (AIF1).

Lag (AIF1), +,

〜 ~ '' ½ ½

Place "0 0H" and "0H" and force signal ^

2: The place that passed through was “0: II” and ', G ■ ÷ H ”and OR.

Becomes "05H".

If the measured pulse rate falls below the lower pulse rate warning value at rr 7,

BAD 0RIGHMA If the flag (AIF1) is "01H", jump to the forest 24, otherwise, go to the forest 23, and the pulse rate display section (1 5 8) Release the blinking. Then, the pulse wave sound generation interrupting state is set in # 237, and the flags (AIF1) and (AIF2) are set to "0H" in # 238 and # 233, respectively. And reset the alarm sound at # 240, and set the alarm sound volume to the value set in the volume setting step at # 224. Return to the original flow.

Then, at 42, the alarm sound is started. # 2 4 2 to # 2 0 5, # 2 2 6, # 2 3 4 Then, in # 243, it is checked whether the flag (AMF) is "1" or not. The 7 lags (AMF) are set to "1" in the alarm mute state, so the flag (AMF) is set to "1" in # 243. If it is determined, it is in the alarm mute state. In this case, it is determined that the alarm mute switch (180 is pressed or not) is passed to the filter 2 and then the alarm is switched to 2-4. 'Status; distinguish whether the specified time has passed since resetting, and distinguish it from the alarm mute status in # 2445. The place where it is separated is ^ 2 4 6 in the flag 7 ^ (ΛIF 3), the flag (Λ IF 2) and the flag (AIF 1), and the exclusive exclusive signal of each bit. As a result, if the signal of the lag (AIF 1) does not change at 7 low from 200 to # 24, the new alarm state is established. If it has not occurred, the flag will be '0H', and the flag will be '0H' from # 200 to 2t2; the flag (AI Γ 1) If the signal changes, that is, a new alarm state occurs. Are place, ho, Flag (A I F 3) is shall not a "0 0 H".

BAD dRIGINAL In # 247, it is determined whether or not the flag (AIF3) is set to "0H". At this point, the flag (AIF 3) is reset to "0H": if it is C, it returns to the original flow; if not, it is flagged with # 248 (AIF 3). 3) It is determined whether the AND signal of the flag (AIF 1) is set to "00H".

As a result, when the number of causes of the alarm state is decreasing, this AND signal becomes “00H”, and when the number of causes is increasing, the AND signal becomes “00H”. H ". Here, it is determined whether or not the flag (AIF3) is set to “0H” in # 248 when the number of causes of the alarm condition is reduced. Will remain in alarm mute state, and if the number of causes is increasing,

-This is to cancel the state.

Next, in # 2443, the alarm voice mark or the alarm speaker mark. Here, to # 2 4 9

2) If it is determined that the Armmit switch has been pressed at ^, or # 2 4 5; the specified time has elapsed since the alarm mute state I will go to the place.

At 0, the volume of the two sounds is set to the value set by the volume setting routine, and the flag is set at Hayashi 251, \ MF) is set to "0"; As a result, the alarm mute state is released.

If the flag (AMF) is not “1” in 2 4 3, the alarm is muted. Since it is not 1, the alarm 2 52 It is determined whether the auto switch has been pressed. Then, the flag ': A / F is pressed;

In step S254, it is determined whether or not the alarm word-mode is a mode in which only an alarm sound is generated. If it is determined that the mode generates only a warning sound, the alarm is set at # 25 5

BAD ORIGINAL Set the peak mark so that it flashes. On the other hand, if it is determined that the mode is not the mode in which only the warning sound is generated in ^ 254, the alarm voice mark is set to blink in # 256 and # 25 is set. Set the volume of the alarm sound to the minimum in 7 and return to the original flow.

If it is determined in # 25 that the alarm switch is not pressed, the # 7 flag (AIF2) will no longer be "00H" in # 25S. It is determined whether or not a predetermined time has elapsed since then, and if the predetermined time has elapsed, the alarm sound volume is set to the maximum in step 25 3 and the flow is returned to the original flow. On. If the predetermined time has not elapsed since the flag (AIF 2) is no longer “0H” in # 2553, the flow as it is without passing through # 253 Return to.

笫 Return to Fig. 31. When the alarm is completed at # 13, as shown in Fig. S7, the digital output 1 step is performed at # 20. Be executed. In this step, S au 2 and the pulse rate measured at predetermined time intervals are externally and digitally connected via a serial interface of the input / output unit (116). And output. In addition, the second time, S a O: lower limit warning, direct upper limit warning, lower limit warning value, lower limit warning value, and original information when measurement is not possible are also output at the same time.

The detailed operation of this FIG. 31 # 20 is shown in the flowchart of FIG. 3ε.笫 In the SC, (ALF) is a flag that has the contents shown in Table 1 below according to the set alarm status and measurement capability status, and (DN) This flag is used to indicate the type of data to be input, as shown in the upper bit No. 2 above.

No

, Table 1

A L F | MSB ILSB! State 7 1 6 1 5 4! 3 2! Ten

S aO ^ S aO ₂ Low limit warning value 1 脈 Pulse rate Pulse rate high limit warning value

Pulse rate Pulse rate upper limit warning value

Unmeasurable source S = C

Cause of measurement failure = L Cause of measurement failure = A Cause of measurement failure = P

There is an event marker input;

I Table 2

D Ν MSB:! LSB Eleven

Output data 4 0

S aO lower warning furnace 1

On pulse rate ¾Warning value 2

Pulse rate f ¾ warning value; 1 1

BAD ORIGINAL In Table 1, “with event marker input” means that the event marker switch is pressed and the event mark stamp is specified. It indicates that

First, at # 300 in Fig. 38, the data of "Year", "Month", "Day", "Hour", and "Minute" of the clock section (118) are input / output sections of the CPU (110). It is output from (1 16). Next, the flag (DN) is set to “2” by # 301, and the memory that specifies the contents of the flag (ADR1) indicating the initial address of the memory is set by S302. Set the flag indicating the address (AD1). Then, it is determined whether or not the measurement is impossible in # 303, and if it is in the measurement-ready state, first in # 304, the cause is called a probe (101). It is determined whether or not it is "C" due to the disconnection of the connector connecting the main unit (103). If the cause is "C" due to the disconnection of this connector, the flag (ALF; is set to "10H") as shown in # 305. Set "(1 hexadecimal number). Here, 7 lags (ΛLF) are set to" 10 0 ". This is indicated by the binary number of S bit in Table L. If the cause of measurement failure is not “C” due to disconnection of the connector, proceed to 30 ■ i or S 06, and if the degree is the cause, '^ It is fixed whether or not it is “L” due to the lower leg, and if the cause is “L” due to the lower leg, the flag (# 307) is used. ALF) is set to "20H". Here, Table 20 shows that the flag (ALF) is set to "20H" in binary G-bit numbers. '

Update: If the cause of the measurement failure function is not "L" due to the light intensity lower leg, use # 30C to determine whether the cause is "Λ" due to finger shake. Is done. If the cause is "A" due to the movement of the finger, "40H" is set in 7 flags (ALF) in S30 and S3. Here, setting the flag (Λ LF) to “40H” is almost a binary number in Table 1. Is shown. In # 308, if the cause of the unmeasurable state is not "A" due to finger shaking, the cause is "P" due to weak pulse wave remaining. Set the flag (ALF) to "80H" to indicate the cause "P". Here, the fact that "80H" is set at the 7th lag (ALF) is shown in binary form in Table 1.

Next, in # 311 1, “2” is added to the flag (AD 1) and the flag is newly recorded as (AD 1). This is to specify the next address. Their to # 3 1 2 whether the changed lower warning value of S _aO-2 is is determined, off La altered S _aO-2 lower warning value in # 3 1 3 If it is changed ' (AD 1) at the specified address. In addition, add "1" to the 7th flag (AD1) at # 314 and specify the next address as a new flag (AD1). ) To "17" to make a new flag (DN). Here, the relation between adding "17" to the flag (DN) and Table 2 is to set the 5th pin from the bottom, i.e., to "1". Ri, which shows that it is a data of S A_〇 ₂ lower limit warning value. Also, add “1” to the T position of the flag (DN) 'Τ) bit to indicate that the data has increased.

',,

S3: 2 and below S Warning If the correction has not changed: Y, go to # 31G. In # 31S, it is determined whether or not the pulse rate upper limit warning has been changed. Then, if the pulse rate upper limit warning value has been changed, the pulse rate power upper limit warning that has been changed in step # 3 17 is stored in a predetermined location of the flag (AD1). # 3 13 Adds "1" to 7 lags (AD 1) and stores them in 7 lags (AD 1), and # 3 1 S adds "3 3" to flags (DN) And store it in a new flag (DN). Here, the operation of # 3 13 is performed by setting “1” to the 6th bit from the least significant bit in Table 2 and setting the pulse to “1”. This is to indicate that this is the data of the upper limit warning value, and to add "1" to the lower bit of the flag (DN) to indicate that the data has increased by one. ,

If the upper limit bud value of the pulse rate is not changed in # 3 16, proceed to # 3 20. In # 320, it is determined whether or not the pulse width lowering warning value has been changed. If the lower limit warning value of the pulse rate has been changed, the changed lower limit warning value of the pulse rate is written in the predetermined address of the flag (AD1) in # 321, and # 3221. Add “1” to the flag (AD 1) to add a new flag (AD 1), and add # 6 23 to the flag (DN) at # 32 3 to add a new 7 lag (DN) Store in Here, the # operation of # 32 23 is that, in Table 2, by setting "1" to the 7th bit from the least significant bit, it is the data of the lower limit of the number of beats. This is done to indicate that data has increased by one by adding "1" to the lower bit of the flag (DN).

If the lower warning value of the pulse rate has not been changed in # 32, then go to # 32 and from # 32. In # 32, it is determined whether or not the event marker switch, which is pressed when an event mark (191) as shown in Fig. 46 is to be printed, is pressed. Judged. If the event marker switch is pressed, add “08H” to the 7th lag (ALF) at # 3225 and store it in the new flag (ALF). This is to set the fourth bit from the least significant bit to "1".

Further, in # 3226, the contents of the flag (DN) are written at the address indicated by the flag (ADR1), and in # 3227, the contents of the flag (ALF) are written in the flag (ADR + 1). In the address indicated by, set the flag (0 1 1) to "0 1" 1 in # 3 28. Here, the flags (AD R + 1) and (DN 1) are set. Is the memory It indicates the address and the type of data. The operation of # 328 is performed by taking the AND signal of each bit of the flag (DN) and "0FH". 4 Set the reset signal to the flag (DN1). As a result, only the signal related to the number of data in the flag (DN 1) is left.

Then, the flag (ADR1), that is, the initial address is set in the flag (AD1) in # 32, and the contents of the address indicated by the flag (AD1) are output in # 3330. The operations of # 330 to # 3333 are for outputting the contents described in # 320 to # 327. In addition, the flag (8 0 1) is added with “1” in # 331, and the flag (0) is added. The flag (DN 1) is stored. This operation is to advance the next address from the flag (ADR1) and repeat the operation of outputting the data written at each address by the number of data while specifying the address.

Next, confirm that the content of the flag (DN 1) becomes “0” in # 3333, and repeat the operations from # 3330 to # 3332 until it becomes “0”. . And finally, the data set with # 3 3 4.

Outputs (F F H) and returns to the original flow.

Here, if the decision is. Ru not in the unmeasurable state # 3 0 3, # 3 3 5 Sa0 ₂ measurements Sa0 ₂ lower Tsugechi whether less der Luke willingly or not. Its to and also S _aO-2 measurements equal to or less than S _aO-2 under TenYoTsuge value, newly flag by adding "0 1 H" to the contents of the flag (ALF) in # 3 3 6 (ALF). This is to correspond to the upper part of Table 1.

# If the measured value of SaO ₂ is not less than the lower warning value of SaO _{2 in} 3 3 5, the flag (ALF) is not reset and the flow proceeds to 3 3 7. Is greater than or equal to the pulse rate upper limit warning value Is determined. Here, if the measured value of the warabi beat is equal to or greater than the warning value of the upper beat count, “0 2 H” is added to the content of the flag (AL F) at # 3 3 8 to newly add 7 lag (ALF). Squeak. This is to correspond to the second row from the top of Table 1.

If it is determined in # 3337 that the pulse rate is not higher than the pulsating rate, it is determined that it is not greater than the reported value.In step # 33, the pulse rate is less than the pulse rate warning. Is determined. Then, when it is determined that the value of the number of 蹶蹶 is less than the lower 脒 beat, the value of the flag (ALF) is added to “0 4 H” and a new flag is added. (AL F). Here, the meaning of adding "04H" to the contents of the flag (ALF) is to correspond to the third row in Table 1.

Then, the serial to a predetermined address of the # 3 4 1, flag S _aO-2 measurements (ADR 1 + 2) and carboxymethyl to a predetermined address of, # 3 4 2 In the pulse rate澍定value flag (ADR 1 + 3) Use. Further, in # 3 4 3, “4” is added to the content of the flag (AD 1) to newly set the flag (AD 1). This is to cross the address already recorded. Then, in # 3 4 4, “2” is added to the content of the flag (DN) and the flag is stored in a new flag (DN), and the process proceeds to # 3 12. Here, means adding a flag (Ji N) "?" Is, Sa0 ₂及Pi two data number of脲拍is Ri der to indicate that it has been added, therefore, this and the relationship between the table 2 There is no. Table 2 relates only to the upper 4 bits of the flag (DN). Adding "2" to the flag (DN) only affects the lower 4 bits of the flag (DN). Because. In this way, the operation of # 20 in FIG. 31 ends.

Also, in # 20 of Fig. 31, when each warning value is changed and when the power switch (136) is turned on, each set value of serial communication is changed to a serial interface. Input / output unit externally through the hood It is output as a digital signal from (1 16).

Next, # in 2 1, input and output measurements of Sa0 ₂及Pi脒拍number portion

Output as an analog signal from (1 16). Here, Sa0 ₂及Pi脒拍number in the case of non澳定, the output value of the analog signal becomes 0 V. If Sa0 ₂ «constant, pulse rate measurement value, time (output of built-in clock section (118)), alarm exhaustion, if measurement is impossible, the cause is # 22 The data is stored in the memory of the IC card (102) by the data memory processing routine.

Here, the data memory function will be described in more detail. Although in the following description are described in the IC card (1 0 2) and serial傢媒body, backup battery internal. RAM card, also applies to off n. _Y Beady disk or the like. It is also possible to incorporate EEPROM, bubble memory, and memory-backed-up RAM in the main unit to provide the same function.

In # 2 2, Sa0 ₂ and measurements of the pulse rate calculated by measuring for each predetermined time, the and also warning information indicating the measurement time and alarm state, IC card through the sheet re Arude data ¾ terminal Do

(10 2) is sequentially written. When all the memory in the IC mode (102) is used, the oldest data is erased from the oldest data and new data is written. In other words, the IC card (102) stores the latest data for the time determined by the memory capacity. Also, write data when the drowning impossible state is prolonged for a long time. Suspends the process. As a result, the memory in the IC card (102) can be saved.

Here, the main body (103) is provided with an event marker switch (not shown). When this switch is pressed, the A signal indicating that the event marker switch has been pressed is output as a digital signal from the output section (116), and the ic card (102) is notified to that effect. The data is transferred and can be used later for data analysis. Also, the time data need not necessarily be recorded for each set of translation data. In the present embodiment, the time is recorded on the IC card (102) when the transmission switch (136) of the main body (103) is turned on and every predetermined time. .

In this embodiment, the measurement of SaO ₂ and the number of beats is performed every 1 second, and their IC card (102) is recorded every 5 seconds. The time is written in the IC cart (102) every minute. The operation of the data memory step in this case is shown in FIG.

In Fig. 3 S, (T DM) and (Τ ΤΜ)

Sa0 is Menoka c te was to determine whether the serial use the data and time of _2, and the like. (ALF) is a flag in which each bit shown in Table 1 is set to "1" according to the alarm concept and the "undefined". (DNF) is a flag indicating whether it is carboxymethyl in IC card to the third power sale to Sa0 ₂ and what data is specific time other than pulse rate number by shown in the table below (1 0 2). Here, at a specific time, a flag (DNF) is set at a predetermined address of the IC card (102).

Are respectively SL值contents of (ALF),涠定data of Sa0 ₂ and pulse rate and the like for subsequent address is alkoxy. Further, (AD) (ADR) indicates the address of the memory of the IC card (102).

(Hereinafter the margin) Table 3

(Hereinafter the margin)

In Fig. 39, in # 400, first, the IC card

The addresses (AD) and (ADR) of (102) are made equal. Then, the flag (D _f NF) at # 4 0 1 "0 0 H " to be set. Then, “1” is added to the counter (TDM) at # 402, and at # 403, it is determined whether the count value of this counter (TDM) is less than “5”. I do. If the count of the counter (TDM) is "5" or more, the count value is set to "0" in # 404 and the flag (ALF) is set in # 405. Set “0 0 H.” Here, when the force point value of the counter (TDM) becomes “5” or more, it indicates that the condition has deteriorated for 5 seconds.

Next, in # 406, it is impossible to determine whether or not it is possible! ! I will be separated. Here, if it is impossible to measure] S, the process proceeds to # 407, and it is determined whether or not an unmeasurable situation due to the same cause is present for a predetermined time or more. Then, if the unmeasurable exhaustion due to the same cause is longer than a predetermined time, the flag (DNF) is set to “80H” in # 408. This is not shown in Table 3 but represents the unmeasured condition.

On the other hand, if the measurement failure due to the same cause has not occurred for more than the predetermined time in # 407, the cause of the measurement failure is determined in # 403 to # 415, and according to the cause, The flag (ALF) is set. This operation is similar to steps # 304 to # 310 in FIG. Then, "# 2" is added to the memory address (AD) of the IC card (2) at # 416. This is to set the address of next data to be used in addition to the flag (ALF) (DNF).

If # not the unmeasurable shaped virtual 4 0 6, # 4 Sa0 ₂ measurement嬗advance to 1 7 serial ¾ to a predetermined address of the flag (AD R + 2), the number of glands beats # 4 1 8 Te较I Extremely fixed value at specified address of flag (ADR + 3) Enter # 4 13 and add "4" to the memory address (AD) of the IC card (102). This is to set the storage address of data to be described next in addition to the flag (ALF) (DNF), SaO ₂ , and pulse rate.

Their above, in # 4 2 0, Sa0 ₂ ¾ Tei值is discriminated whether or not the following Sa0 ₂ below ¾ MedogiTsuge僮, flags in # 4 2 1 equal to or less than the lower Exhibition warning value ( AL F) is set to "01H". Here, setting the flag (ALF) to “01H” corresponds to setting “: I” to the least significant bit (LSB) in Table 1. ing. Further, in # 4222, it is determined whether or not the set number of lakes is equal to or larger than the upper limit warning sign. Then, if the pulse rate liming furnace is equal to or greater than the "beat rate upper limit warning", the flag (ALF) is set to "02H". This corresponds to "1" being set to the second bit from the least significant bit in Table 1.

# If the pulse rate is not equal to or higher than the beat count in # 42, then proceed to # 42 to determine if the measured pulse rate is less than or equal to the lower limit. If it is less than the pulse rate lowering warning value, "04H" is set to the 7th lag (ALF) with # 425. This is in contrast to Table 1 where "1" is set to the third bit from the lower 'bit'.

Then, in # 432, it is determined whether or not the event marker switch has been pressed during the immediately preceding 5 seconds. Here, if the event marker switch is pressed, the flag is set to # 4 2 7

(ALF) is set to "08 8", and if it is not pressed, the flag (ALF) is not set and the process proceeds to # 428. Here, the event marker switch is pushed when you want to print the event mark, and the flag (ALF) Setting "08H" to "1" is equivalent to setting "1" to the fourth bit from the low-order bit in Table 1. Then, in # 42, the contents of the flag (ALF) are written into the memory address (ADR + 1) of the IC card (102), and the process proceeds to # 432.

In # 4 2 9, it is determined whether the lower warning value of S aO ₂ has been changed! Separated. And if it was changed, it was changed in # 4 3 0

The S a0 ₂ lower Medogi Tsugechi is Ki值note to re address (AD) of the IC card (2), # 4 3 1 a flag with even flag (DNF) and (DNF) - "0 1 H " The OR signal for each bit is set, and "1" is added to the memory address (AD) of the IC * mode (2) in # 432. Here, the flag (DNF) and the OR signal for each bit of the original flag (DNF) and "01H" are set, and the fighter between Table 3 and Table 3 is described in Table 1. Corresponds to setting the upper bit (MS B.) to "1".

# 4 If the lower limit warning value of S _aO-2 has not been changed at 2 9, # 4 3 0 ~ # 4 3 2 such that through the Ku # proceeds to 4 3 3, changes the upper exhibition warning value of the pulse rate It is determined whether it has been performed. If it has been changed, the upper limit warning value of the number of beats changed in # 43 is written in the memory address (AD) of the IC card (102), and the number is changed in # 43. In the flag (DNF), each bit of the original flag (DNF) and the OR signal of "02H" are set, and the memory address (AD) of the IC card (2) is set in # 4336. ) To "1".

If the warning value is not changed in # 4 3 3, proceed to # 4 3 7 without going through # 4 3 4 to # 4 3 6. It is determined whether or not has been changed. If it has been changed, the lower limit of the pig beat rate (*) Is added to the memory address (AD) of (* 102), and "1" is added to the value of the memory address (AD) at # 439.

Next, in # 44p, the OR signal of each bit of the original flag (DNF) and "04H" is set in the flag (DNF), and then the flag (DNF) is set in the flag (DNF). Enter the address indicated by ADR). And

In # 4 4 1, "1" is added to the counter (TTM) that records the time, and

At # 4442, it is determined whether or not the count value of the counter (TTM) is less than "1 2". This operation is to determine whether or not one minute has passed.

Then, when the count value of the counter (Τ Τ になる) becomes “1 2” or more, the process proceeds to # 4 4 3 to change the counter value of the counter (Τ Τ ") to“ 0 ”. The clock is reset to # 4 4 and the "hour" data of the clock section (118) is written to the memory address (AD) of the IC card (102). 4 In step 5, add "1" to the memory address (AD). Further, in # 444, the "minute" data of the clock section (118) is recorded in the memory address (AD) of the IC card (102), and in # 444, this data is stored. Add "1" to the memory address (AD). Next, in # 448, an OR signal of each bit of the original flag (DNF) and "08H" is set to the flag (DNF). This is as shown in Table 3. Then, the contents of the flag (DNF) are written into the memory address (ADR) of the IC card (102) by using # 4443. Then proceed to # 4 5 1.

On the other hand, if the count value of the counter (TTM) has not reached “1 2” in # 4442, the count value is directly passed through # 4443 to # 4450. Proceed to 4 5 1. In # 451, "1" is added to the data described in the memory address (AD). Here, if the count value of the counter (TDM) is less than or equal to "5" in # 403, that is, even if 5 seconds are not present, go to # 4451. You. In addition, in # 452, it is checked whether the memory clear switch (17.3) has been pressed! ! And if pressed, # 4 5 3

(I C 1 C last address 1 A D R)

-1 0 0

I C 谡 end address

IC card (1 0 2) Note by re remaining amount calculated for display in S a 0 ₂ display unit, # 4 5 2 back Note Li The Clear Sui based on pitch (1 7 Wait for 3) to be pressed.

Accordingly, in this embodiment, pressing the Note Li The Clear sweep rate pitch (1 7 3) in Sakejo mode, the Sa0 ₂ display only while pressing (1 5 7), IC cards The remaining memory of (102) is displayed. This is the operation of the data memory processing step # 22 in FIG.

Then, in step # 23, a data damping step is executed. In this step, it is premised that the dedicated printer (104) is connected to the main unit (1'03), and the IC card set in the main unit (103) is assumed. Only when the dedicated link (104) requests the main body (103) to output a series of data recorded in the device (102), the IC force (102) is output. The series of data described in (1) is output to the dedicated printer (104) via the CPU (110) and the input / output unit (116). During this time, the number of beats display section (158) displays the time until the printing of the series of data is completed on the dedicated printer and (104).

Next, in # 24, it is determined whether or not the mode is set to an intermittent measurement mode (intermittent measurement mode). In intermittent measurement mode, it is measured with Sa0 ₂ and pulse rate of the same patient over time, used to also save power when there is no need to measure the communication较的. And intermittent mode The mode is executed when the intermittent mode switch (not shown) provided in the main body (103) is set to the ON state. When not in the intermittent mode, the program jumps to Π, and the operation of each unit is repeatedly executed according to the above flow. If it is set to intermittent mode, you will be asked if you want to proceed to # 25 to renew your location. Here, comes the predetermined time only Sa0 ₂ and厥拍number of calculations can not been executed, the program manager Npushi to [pi, the predetermined time only SaO ₂ glands number of beats calculated is performed, At # 26, the & LED (120) and ILED (122) stop emitting light, and at # 27, the CPU (110) is set to the low power consumption mode. At this time, only the glandular pulse rate is

The calculation and display of the number of beats may be performed by causing only (121) to emit light. In this case, the CPU (110) operates in the normal operation mode.

Next, in # 28, it is determined whether the LED has stopped emitting light and has been closed for a predetermined time, and if the predetermined time has elapsed, the CPU (110) is determined in # 29. After setting to normal operating mode, the program jumps to I.

The oximeter body (103) of this embodiment is used for both spot measurement and continuous measurement. Here, when used for spot measurement, measurement is often performed on many patients, although the measurement time per patient is short. Therefore, it is not necessary to operate the main unit (103) until the measurement of one patient is completed and the measurement of the next patient is completed, but one spot measurement is completed. It is troublesome to turn off the power switch (136) every time. Therefore, in the present embodiment, the probe identification output unit (124) of the probe σ- (101) is used for spot measurement or continuous measurement. Information that can be distinguished is set. Here, in this example, the discrimination of the sake determination mode by the probe (101) is set as binary information by a switch or the like. Their to measure Potan (not shown) is emitted by each LED only when pressed, is calculated Sa0 ₂ and the number of dark beats, are displayed and outputted.

Here, the operation at the time of drowning in the present example will be described with reference to the flowchart of FIG. First, after the power switch (1 3 6) is turned on and the above-described processing of # 1 to # 5 is executed, it is determined at # 6 whether the measurement is a spot measurement or a continuous measurement. If the probe (101) connected to (3) is for spot measurement, proceed to # 30 and set the CPU (110) to the low power consumption mode. At this time, RL ED (120) and IR ED (122) do not emit light. In this state, if it is determined that the control button (not shown) provided on the main body (103) is pressed in # 31, the processing below M is performed.

First, in # 32, the CPU (110) is in the normal measurement mode, and in # 33, RLED (120) and IRLED (122) are driven by the above driving waveform. It emits light, and the same A / D conversion processing step as in # 12 is executed in # 34, and the SVR and SVIR are obtained. Then, in # 35, it is determined whether or not the number of samples is not "π". If "ι" or more, the calibration constant correction step similar to # 14 in # 36, # 37 in a similar S έθ ₂ calculation step and # 1 5 # 1 6 similar glands beat number calculation step and at # 3 8, similar Medogi WARNING determining step and # 1 7 # 3 9, # 40 and # 1 8 If the number of samples is less than "η" in # 35, go back to # 34 and operate the AZD conversion step until the number of samples becomes "η" or more. return. # 1, S a0 ₂ it is determined whether stable. In this case, S a0 ₂ Liu Tei僮is compared with the previous S a0 ₂ ¾ Tei馕, as its difference is stable if within Tatte a predetermined given time, at that time in # 4 2 Hold the display of the Sa0 ₂ child and the pulse number plant of the present. A detailed box of this SaO ₂ stable separate step is shown in the flowchart of FIG.

In Fig. 40, first,

Five

D S = ∑ W (I) ♦ I S (I — 5) — S (I — 6) 1

1 = 1

(31) is calculated. Here, S (0) Ho (S-Xin) current S a0 ₂ shows the measured values, S (-: 1), S (- 2), S (- 3), S (- 4), S ( — 5) indicates a series of SaO ₂ measurements 值 from the present to the past, and W (I) is a weighting factor. Next, in # 5 0 1 this value

It is determined whether DS is equal to or less than a predetermined value. Here, if it is determined to be equal to or less than the predetermined value, # 5 0 S a0 ₂ advance to 2 is judged to be stable, be determined that S _aO-2 ho unstable if more than a predetermined value Return to the flow.

That is, when the S _aO-2 at # 4 1 back to the third 1 figure is determined to be stable, # 4 2 holes display of S a0 ₂ value and pulse rate value at that time in sul. In this embodiment, the display is held by judging the stability of SaO ₂ , but the stability may be judged by the pulse rate, and the stability of the lake constant may be judged in the same manner.

Then, proceed to # 4 3 for digital output in 2 steps.

"S a0 _2", "pulse rate", "year", "month", "date", the "time", "minute" and "Shirushi宇instruction to a dedicated pre-te (1 0 4)" Each data is input / output part

It is output as a digital signal from (1 16). This digital FIG. 41 shows a flowchart showing the operation of the two-step output of the step a.

In FIG. 41, first, at # 600, the CPU (llO) sends a print command to the dedicated printer (104) via the input / output unit (116). Next, the data set end signal (FFH) is output in # 601, and in # 602, the "year", "month", "day", "hour", and "minute" of the clock section (118) are output. Is gradually output via the input / output unit (1 16). Then, the flag (DN) is set to "2" in # 603. This indicates that two data, "month and day" and "hour and minute" were output. Then, at # 604, it is determined whether or not the state is undeterminable. If the state is undeterminable, wait until it is released. If not濺定impossible shape »outputs Sa0 ₂ data advance to # 6 0 5, and # 6 0 6 have较to return to the flow in the even outputs data pulse rate. Returning to FIG. 31, as described above, when the digital output 2 step of ^ 43 is completed, then, at # 44, RL ED (1 20) and ぴ I RL ED (1 2 1) Terminate the light emission, and 4 5

(1 1 0) goes to the low current consumption mode, returns to # 3.1 and continues this concept until the next time the measurement button is pressed or the mode is switched to the continuous measurement mode or the intermittent measurement mode: it ,:-That is, if it is not determined in step # 31 that the measurement button has been pressed, the flow advances to step # 46 to determine whether or not the spot measurement is to be performed. At this point, if the spot is still at the bottom, the process returns to # 31, but if the sake brewing mode has been changed, the process proceeds to # 47 to run the CPU (1110) in the operation mode. Set to and jump to I. In this embodiment, the probe identification output section (124) is provided in the probe, but a means for setting whether to perform the robot measurement or the continuous measurement may be provided in the main body (103).

Next, the low-frequency sound processing routine shown in FIG. 42 will be described. When the processing after Π or HI in FIG. 31 is being executed, an interrupt by either the rising or falling of the output of the pulse wave shaping circuit (154) is accepted. When this interrupt occurs, the pulse wave processing routine shown in FIG. 42 is executed. First, in # 7 0 0 3 1 diagram # 1 5 also rather occurrence of # 3 7 Sa0 ₂ set in the calculation step the frequency of the "wave sound is started, predetermined by # 7 0 1 Wait for the scheduled time. Then, when the predetermined time has elapsed, the pulse wave sound is stopped at # 702, and the flow returns to the original flow. However, when the above-mentioned alarm condition or the lake cannot be determined, or when the setting is made so as to stop the generation of the pulse wave sound, the interruption is prohibited and the * wave sound is not generated.

As a result, in cases other than the alarm state »and the“ unsettable state ”«, the warabi sound is generated in synchronization with either the rising or falling of the output signal from the rising and falling circuit (154). appear. Its frequency of the pulse wave sounds and changes in Ji ¾ to S aO _2. Therefore, it is possible to know the state of ( ₁₎ and SaO2 only by the 脒 -wave sound. Incidentally, by the the this changing the Du Ti ratio of S a0 ₂ to I One is the frequency of the pulse wave sound rather than脒波sound connexion also, Ru is possible to get the same effect. Or if you have configured in a very short period of cross-sectional较音than the pulse sound of waves in冁拍, the儸数of the cross-sectional铳音Ru can also this to change me by the S a0 _2.

In this embodiment, the volume of the tonal sound can be reduced by pressing the up-down switch (1Ί4) while pressing the pulse switch (178). Furthermore, generation of that sound and its stop can be switched by pressing the pulse switch (178).

Next, the dedicated printer (104) will be described. First, Fig. 43 conceptually shows the configuration of the dedicated printer (104). Fig. 4 3 In (181), data input / output ^ is used to receive data from the main unit (103) and to transfer instructions and the like to the main unit (103).

(1 8 2) 5 In (183), the control section controls the entire printer. (184) is a switch input unit for reading the state of each switch described later. (185) The printer control unit activates the printer in accordance with the driving command and data from the control unit (183). (186) is a printing unit for performing printing.

Next, FIG. 44 shows the operation unit of the printer (104) of this embodiment. In FIG. 44, (188) a feed switch, (188) a bullet switch, (189) a data dam switch,

(190) is a data interval selection switch.

Fig. 45 shows the operation flow of this printer. First, in # 800, it is checked whether a print command has been sent at the digital output 2 step of # 43 shown in Fig. 31 showing the operation of the main unit (103). Jumps to V when is sent. If the print command has not been sent, the print switch (188) or the data dump switch (1) of the switch input section (184) is output at # -8-801. It is known whether or not 8 9) is pressed.

Next, the operation when the bullet switch f188) is pressed will be described. When the print switch (188) is depressed, it proceeds to # 803 through # 801 and # 802, and from the printer (104) to the main unit (103). To send a charge stop signal. In this example, the printer (104) sends a charge stop signal to the main unit (103) from immediately before the start of the stamp to the end of the stamp.

The charging of the NiCd battery in (103) is stopped during that time. Further, the control unit (183) immediately issues a command to the data input / output unit (181) to receive data from the main unit (103). And # 8 0 Enter the patient name "NAM" at 4 and enter the patient ID number "IDN O." at # 805. Then, at # 806, the printer

The data input / output section (181) of (104) is a set of digital output from the main body (103) in one step (Fig. 31 # 20 and Fig. 38). Receive the data of. Its to, in control裤都(1 8 3) # 8 0 7, the received data Ri by data "year", "month", "date", "time", "minute", "Sa0 _2", Enter the "number of beats", "information on alarm status", "patient ID number", etc., and return to # 800.

Next, the operation when the data dumb switch (189) is pressed will be described. When the data dam switch (189) is pressed, the system proceeds from # 800 to # 800, # 800, # 808, and the control area (183) is used for data input / output. The memory data transfer instruction is transferred to the main unit via the module (181). When this command is received while the main unit (103) is tilted, the data dump step shown in Fig. 31 # 23 is executed, and the specified data is read from the IC card (102) to read the next data. Printer U04 4) Send the information. However, since the capacity of the storage section (182) of the dedicated printer (104) is smaller than that of the IC card (102), the transfer data is divided into a predetermined size. Transferred. Then, the control unit (183) of the printer (104) receives the data transferred at # 809: the data is received, and at # 810, the data is transferred from this data to the fourth unit. It is converted to the graph shown in the figure, and the print command is transmitted to the printer control »drive unit. The print unit (186) prints it with # 811 # 1.

Here, at the time of imprinting, the time elapsed by the time selected by the operation of the data interval selection switch (190) from the time when the data imprinted immediately before was measured Only prints the data at, otherwise it does not print. Here, the configuration of this data interval selection switch (190) and its configuration When the operation by the operation is described in detail, as shown in FIG. 42, this de-interval selection switch (130) can be manually operated to defeat "5 sec""10sec", It is set to one of the indicators of "1 iin" 5 鳙鳙 η ", and the time for the combined index is set.

Immediately before printing starts, the printer outputs a charge stop signal to the main unit (103), and resets the charge stop signal when printing is completed. When printing is completed, it is determined whether or not the data has been completed in # 812. If all the data has been printed, the process jumps to the start. If the data printing has not been completed, return to # 808 to start data reception again and repeat the same process. In the data dump mode, (1), the display of the main body (103)

(1 5 8) and the pulse wave level meter (1 5 7) show an indication of how long the seal will finish / end.

Figures 4.7 to 49 show more detailed charts of the operation of the special-purpose printer (104). In the present embodiment, Ube 186 of the dedicated printer (104) is a doll "., *" In which the heads of the eight swords are arranged in one row. In the data dump mode, Every 5 seconds from the data every 5 seconds returned to the IC card (100.2), the data interval is selected, and the selection switch (130) is set. The data is bit-upd every 0 seconds, 1 minute, or 5 minutes, and the bit-up data is 8 bits equal to the number of print heads. each gather min, head to the print corresponding to each data Shirushi宇position corresponding to the value of S a0 ₂ and pulse rate are turned on, the graph shown in the fourth 6 Figure is purine bets. Further, I Information on whether or not the vent marker switch has been pressed is stored in the flag (ALF) of the IC card (102). Bit 3 Runode been Ki值in (least significant bit 4 th bit) in a private Prin printer (1 0 4) the bit 3 of the flag (ALF) Manbete, it ¹ When "1", the event mark (19.1) shown in Fig. 46 is printed at the corresponding position. Further, it is determined whether or not the input data cannot be measured. Flag sent from main unit

It can be checked by the contents of (DNF).

In FIG. 47, first, in # 9000, it is determined whether or not an input command has been received from the input / output unit (116) of the main unit (103), and if it has been received, the process proceeds to # 903. If no data has been received, the process proceeds to step # 910, and it is determined whether or not the data dumb switch (189) has been pressed. Then, if this data dump switch (183) is pressed, jump to # 3332 in Fig. 48. If it is determined that the data dump switch (189) has not been pressed at # 301, then proceed to # 902 to determine whether the print switch (188) has been pressed. Is determined. If the print switch (188) is not pressed, the flow returns to # 300. If the print switch is pressed, the flow proceeds to # 903.

At # 903, a charge stop signal to stop charging the NiCd battery of the main unit (103) is sent to the main unit (103), and at # 904, the main unit (103) is charged. Input the data output from. Then, in # 905, the input data waits for the data set end signal (FFH), and the data set end signal (FFH) is set by step # 3334 in the main unit (103). When) is input, the process proceeds to # 906. In # 306, data of "year", "month", "day", "hour", and "minute" are received from the main unit (103), and in # 307, main unit (103) is received. The output indicating the used 7 lags (ALF) from is recorded in the memory address (DN 2) of the memory section (182). Further, in # 908, the data written in the memory address (DN2) and the key for each bit of "F0H" And record it at the memory address (DN 3).

Next, at # 903, the memory data (DN3) is changed to "0 0

"3 を whether it is H" or not.

0 8 causes the memory address (D N 3) recording data to not be "0 0 H"

Therefore, in this # 309, it is determined whether or not it is in a state where it is not possible to establish a link.

And, if it is not a constrained state, the memory address (DN3)

Since the data becomes "00H", proceed to # 310, and the output data from the main unit (103) is input.

Enter "S", and in # 91, the next input from the main unit

Record the force data as * PR *. Where

SaO ₂定 r The constant value is used, and “PR” is used as the dead heart rate.

Is done.

Furthermore, in # 913, the sentence "DATE" shown in Fig. 46 is displayed.

First, it is stamped, and then the data of "Year", "Month", "Day" is shown in # 9 14

Is stamped. Next, in # 9115, the characters "T I ME" shown in Fig. 46 are printed, and in # 31 16, the "hour" and "minute" data are printed.

Printed. Then, in # 9 17, “N AME” shown in Fig. 46

The character “■” is printed along with each patient's data.

r I Dv N O. "along with patient ID number data

Gis.

In # 9 1 9, the character “S aO ₂ ” is printed, and # 9

In 20, the data of the measured value of S aO ₂ marked as “S” is marked.

Is written. Furthermore, in # 321, it is called "PUL S E RA T E"

Thats the letter is stamped and marked as "PR" in # 922

9- Number measurement data is imprinted, and the charge stop signal is cleared at # 9 23.

And return to # 300.

On the other hand, the recording data of the memory address (DN 3) is “0 0 If it is not H ", it is impossible to measure. Therefore, the cause of the unmeasurable state is determined from the memory address (DN 3) famine in # 32, and # 92, # 32 The cause is determined by 6 and # 3 27. If the cause of the indeterminate alcohol condition is “C” due to the disconnection of the connector, “INOPC” is determined by # 32 8 If the cause is "L" due to insufficient light, enter "1 1 ^ 0 L" in # 3 23. Further, measurement failure 原因 may be caused by finger movement. In the case of "A", "INOPA" is printed with # 330, and in the case of "P" due to weak waves, "INOPP" is printed with # 931, in most cases. From # 3 2 8 to # 3 3 1, return to # 3 0 0.

If the data dumb switch (189) is pressed at # 910, proceed to # 932 in Fig. 48. In # 932 and # 933, the sentence "NAME" is printed with the patient name data, as in # 9117 and # 9118 in Fig. 47. The letters "IDN O." are printed with the patient ID number data. Further, the # 9 3 4, and a fourth 6 FIG illustrated Sa0 ₂ scale and pulse rate of the scan cable Le is Shirushi宇respectively.

Then, in # 3335, set "8" to the flag (CD). Next, in # 9336, the data set input routine is executed. A detailed box of this routine is shown in Figure 49.

In Fig. 43, first, a special-purpose printer

A data transfer instruction is sent from (104) to the main unit (103), and a flag (DNF) data is received from the main unit (103) at 1001. And, in # 1002, this received flag

The AND of each bit of the data of (DNF) and "08H" is calculated, and it is determined whether or not the calculated data becomes "00H". If the calculated data is "0H", then One one

Proceed to 1003 and set the flag (DN4) to "1". On the other hand, if the data calculated in # 1002 does not become "0H", proceed to # 1004 and set "3" in the flag (DN4).

Next, at # 1005, the number of "1" in the lower 3 bits of the flag (DN4) is written to the flag (DN5), and at # 1006, the flag is set.

The data of (D N4) and the data of the flag (D N5) are added, and this is newly classified as a flag (D N4). Further, in # 1007, the data of the flag (DNF) and the AND signal for each bit of "80H" are calculated, and it is determined whether or not the result of the calculation is "0H". I! Separate. If the result of this operation becomes "0H", "2" is added to the data of the flag (DN4) at # 1008, and a new flag is added.

(D N 4). This means that if the result does not become "0H" in # 1007, then go to # 1003 without passing through # 0108. ·

In # 1009, a data transfer instruction is sent from the dedicated printer (104) to the main unit (103).

"I '" is subtracted from the data of (DN4), and this value is newly added to the flag (DN4). Then, it is discriminated whether or not the data of the flag (DN 4) has become “0” by # 1 0 1 1. Until it becomes “0”, the data of # 1 0 3 and # 1 0 10 Repeat the action. When the data of the flag (DN4) becomes "0" at # 1011, the flow returns to the original flow shown in Fig. 48. In this manner, the data set input of the printer is completed at # 9336 in FIG.

Then, the data set entered in # 9337 is entered in the recording section (182), and # 9338 indicates whether the entered data indicates a measurement inability Is determined. If it does not indicate that measurement is not possible, the SaO ₂ measurement data entered in # 9339 Calculates and sets the position of the print head to be printed, and sets the number of beats entered using # 9 4 0. And set it, then go to # 942. On the other hand, if it is determined that it is undeterminable, set the corresponding print head so that it will not be turned on in # 941, and set "1" from the flag (CD) data in # 3342. "Is decremented and newly classified as a flag (CD).

For # 943 to # 945, the time interval selected by the data interval selection switch (130) is 5 seconds, 10 seconds, 1 minute, or 5 hours. The minutes are separated. Here, if the time interval is selected to be 5 seconds, it is determined whether or not the data of the flag (CD) is “0” in # 346. Here, if the data of the flag (CD) is not "0", the flow returns to # 336.

If the data of the flag (CD) is "0" at # 3 4 6, it is determined at # 9 5 1 whether or not to print the time, and if the time is to be printed, it is written at # 9 52. Enter the latest time among the multiple data sets and go to # 35.3. If the time is not printed, go to # 953 without passing through # 952.

In # 9553, it is determined whether or not all of the data of 8 stubs are in the indeterminate state due to the same cause. Their to, if not all of the same unmeasurable due fourth 6 Figure shown by turning on the print heads of the # 9 4 7 8儻in Shirushi宇positions corresponding to the S _aO-2 measurements to plot a graph showing changes of S a0 _2, first and on- further head in # 3 4 8 to eight printing is Shirushi宇position versus ¾ each臊拍number measuring爐4 6 The graph showing the state of change in the number of beats shown in the figure is plotted. Further, in # 943, it is determined whether or not the event marker switch has been pressed. Turn on the print head corresponding to the print mark at the print position, print the event mark at the desired position, and proceed to # 9667.

Conversely, if all data of 8 points are of the same undetermined cause in # 95, # 954-# 9556 will determine the undetermined cause, and # 9557- # 96 Performs printing according to the cause determined by any of 0.

In addition, if the time interval is selected to be 10 seconds in # 944, set the flag (CDP) to ¹ in # 361, and use # 9662 to set the data set input route shown in Fig.49. Run the chin. Then, at # 3663, "1" is subtracted from the data of the flag (CDΡ), and at # 9664, whether the data of the flag (CDΡ) is "0" or not! ! Separate. Then, in # 364, it is determined whether the data of the flag (CD #) is "0" or not, and if it is not "0", the process returns to # 344. Therefore, the flag (CD #) is set to "0". Until the operation of # 9 4 4 and # 3 6 1 ~ # 3 6 3 is repeated.Next, if the time interval is selected to 1 minute at # 9 4 5, then the flag at 9 6 5 (CDP) is set to "59", and if the time interval is set to 5 minutes, the flag (CDP) is set to "299" by # 9666. From 965 or # 366, proceed to the # 962 data set input routine.

Proceed to # 367 from any of # 950, # 957 to # 960, and determine whether or not all data sets have been received from the main unit (103). If the reception of the data set has not been completed, the process returns to # 9305, and the steps after # 335 will be repeated until the reception of all data sets is completed. Then, when the reception of all data sets is completed, the process proceeds to # 966, and returns to “start j” in FIG. 47.

As described in detail above, the oximeter system of this example When measuring the oxygen saturation of the arterial blood of the patient, the set value is recorded in a non-volatile storage means attached to the main body, so that the brewer can use the brewer's plant every time. This eliminates the need for recording, and reduces the need for continuous measurement, and also eliminates the need for the main body used for measurement to have the function of analyzing the measurement element, and is therefore small and small. Suitable for lake setting. Therefore, according to the present invention, it is possible to provide a non-invasive oximeter which is suitable for both measurement and robot measurement. Further, according to the oximeter system of the present flag example, it is possible to easily analyze a large number of interpolated data in real time or after the measurement is completed. You.

Fig. 50 shows the data analyzer (C) shown in Fig. 5 in a more detailed box. The data analyzer (C) is connected between the serial-parallel exchange unit (31) and the arithmetic control unit (35). 14 parts (200) and an image processing part (201) and an image recording part between the display part (37) and the arithmetic control part (35).

(202) is provided. The image recording unit (202) has a matrix-like notation system corresponding to each pixel of the display unit (37). Writing is performed from the arithmetic control unit (35). This is performed according to the command sent to the management unit (201). The memory mounting part (203) is a part for mounting the memory in which the data measured by the oximeter body (A) is written.

Next, the operation of the data analyzer (C) will be described in detail. The operation modes of the data analyzer (C) include a real-time mode and an analyze mode. This mode is selected by the R button (43) or the A button (44) in the control section (36). Fig. 51 is a flow chart of a series of operations performed when the electric field is turned on in the data analysis (C). In # D1, initialization of the computation-controlled area (35), image processing section (201), printer section (38), etc. Is performed. In # D2, it is determined whether the mode is the analysis mode or the real-time mode. This 别 is A button

(4 4) is pressed: It is determined whether or not, and if it is pressed, go to # D3. The analysis mode * is processed in # D3, and after a series of processing is completed, the flow returns to # D2 and repeats another mode.

If it is determined in step # D2 that the A button (44) has not been pressed, the operation proceeds to step # D4 to perform the processing in the real-time mode, and then returns to step # D2.

Next, the analysis mode will be described. Figure 52 shows the flow chart. First, in # D10, the oximeter body

A data transfer command is sent to (A). As shown in Fig. 53, the data is stored and recorded in the storage unit of the oximeter body (A). Therefore, when the data from DNF to one byte before the next DNF is regarded as one data set The difference in the number of bytes comes out. Therefore, in the all data reception routine of # D11, the S value of the data set is kept constant and the data is written to the storage unit (200). That is, in the all data reception routine of FIG. 54, the input of the data set is performed in accordance with the aforementioned flowchart of FIG. 43 at # D20. The data group length is a maximum of 3 bytes as shown in Fig. 53. For DN4 calculated by # D20,

DN 4 = Number of data (including DNF)-1 to (32) holds, so to unify the data group length, write "0 0 H" for (8-DN 4) in # D22.する Insert into the part (200). This data group length does not extend to 9 bytes, and can be changed according to the way of using the oximeter body (A).

Next, in # D23, it is determined whether or not all data has been transmitted, and if all data has been transmitted and if not a data end, # D20 is entered. Returns and repeats until all data has been sent. When the transmission of all data is completed, the process returns to # D12 in FIG. 52 to disable data reception. As a result, no new data is sent even if the oximeter body (A) returns to the normal state, so the data analyzer (C) alone can analyze the data. You can do it. #D 13 is a loop of the analysis process. The loop is executed until the R button (4 3) is pressed, and the process is skipped if the R button (4 3) is pressed. Move on to

FIG. 55 is a flowchart showing a detailed operation of the analysis processing loop of FIG. 52 # D13. The operation will be described below. First, # D30 to # D37 are initial screen displays. Screen S a0 ₂ of graph display, Warabi beats of graph display, heat scan is from preparative grams etc. are summer, S a0 ₂ graph display unit and a to example 5 6 FIG pulse數graph display unit Set the display area of 500 X 600 pixels like this. The horizontal direction is defined as the i-coordinate as shown, and the <¾ direction is defined as the j 痤 target. It is assumed that the S aO ₂ display section (a) has about 200 × 600 pixels and the karyo beat display section (b) has about 300 × 600 pixels. # D 3 0 In the display position of the force Ichiso Le to the center of the S _aO-2 display unit (a) and pulse rate display section (b), cursoring Le display ί廋標ie and before cursoring Le Display ί Set the coordinate pre ic to "3 0 0". In # D31, the scale of the horizontal sleeve is initialized. The mode of the time scale on the horizontal sleeve is divided into five stages. Table 4 shows the parameters for setting the mode.

(Hereinafter the margin) Table 4

Table 6

Msap R N

PRN: P rint flag

S S 1: S a O 2 S cale 1 flag

S S 2: S aO 2 S cale 2 flag

P R 1: P R Scale 1 flag

P R 2: P R S cale 2 flag

P R 3: P R S cale 3 flag

M / R: M / R flag

ESC: Escape flag In Table 4, “Dyspinter” indicates the interval at which points are displayed on the screen, and “ModeO” prints dots every 50 pixels. In this case, 12 data will be inserted on the extra side, and since the time between the sake determination data is 5 seconds, data of 5 seconds X 12-60 seconds is displayed. . The same applies to other modes. In "Mode l", "Display lnterval" is 10, so 5 minutes of data are displayed on the full screen, and in "Mode 2", 10 minutes of data are displayed on the full screen. In "Mode 3", 50 minutes of data is displayed on the full screen,

In "Mode 4", 100 minutes of data is displayed on the full screen.

"Data Interval" in Table 4 is, for example, "Mode 4" because the number of pixels in the time sleeve (襆牖) direction is 600 with respect to the data number of 1200. This is a parameter for extracting and displaying 600 data by subtracting data every other data. Therefore, it is not necessary to thin out in the mode of “number of data pixels”.

Set "DataInterval = 1".

Returning to FIG. 55, in # D32, the cursor position S indicating the cursor position S (hereinafter referred to as C.C.) is set to "300" in the center of the screen. In # D33, the vertical sleeve scale is initialized.璲 Sleeve scale: 3 & 0 ₂ display: 50% 100%, 80% ~: 100% 2 steps, pulse rate display: 20 bp 25 0 bp 50 0 bp 150 bp 100 bpa 250 bpa can be specified from among three levels, which are selected by operating the first scale button (47) and the second scale button (48), respectively. Table 5 shows the parameters for setting the sleeve scale.

Here, since the number of pixels縱of S a0 ₂ graph display unit of the fifth 6 view (a) is the _{2 0 0, "S a0 2} 5 0 Z 1 0 0" mode of the fifth table is selected Thus, 1% of SaO ₂ is for 4 pixels. "S a0 ₂ If the 8 0 1 0 0 "mode is selected, 1% of Sa0 ₂ will be opposed to 10 pixels. The same applies to the pulse rate, and the pulse rate display section (fa ) Is 300, so in the "PR20 / 250" mode, display 0 ~ 30 Obp 鱅 for convenience, set din to 1, and set "PR In the "50Z150" mode, the gain is set to 3, and in the "PR100 / 2500" mode, the din is set to 2. The offset is used to calculate the display coordinates. It shows the lowest value (5 O bpe in “S a0 ₂ 5 0 1 0 0” mode) in the parameter in mode. # D 3 3 sets the initial mode to “S a0 ₂ 5 0 Z 1 0 0 mode ", and" PR 2 0 Z 2 5 0 " is set to mode, for determination of di spray routine to be described later, their respective" S a0 ₂ S cale 1 flag "" Set the PRS ca 1 e 1 flag ".

In # D34, the total number of data sets of 9 bytes recorded in the memory (200), Total Data, is calculated. In # D35, the total number of data sets, Total Data, is calculated from the total data number. Calculate the measurement time Total Measure Ti * e. That is,

as t A ddress— Head A

+ 1

Total Data-

9

ー (33)

Total Measure Ti ae = Total Data X 5 (sec) "'(34) Here," Last Address "is the last key in which the data of the storage part (200) is used. Indicates the dress address,

"Head Address" indicates the first address where data is recorded.

Next, in # 0336, the DNF key of the data set at the center of the liquor set data is displayed in Send the dress to the display routine as "C enter D ata". That is,

01 a 1 Data

C enter D ata = 9 X + Head Address

Two

•• '(35).

After performing the initial setting described above, by performing the de-spray Lee routine in # D 3 7, the initial screen display, i.e. S a0 ₂ graphs Display, pulse rate 'graphical display, cursor display, digital It displays a priest and a histogram. Details of this display routine will be described later. Then, after the initial screen is displayed, a button input is accepted with # D38. Here, the interaction between the button and the rooster surface is explained. The screen can be moved left and right with the first and second cursor buttons (50 and 51) shown in Fig. 6. it can. In addition, the digital plant display shows the position indicated by the cursor.

S a0 _2,脒拍number, alarm information, and the like are digitally displayed. The MZ R button (52) is a button for moving the graph so that the cursor position is lost in the screen. it can. The enlargement button (53) and the reduction button (54) are used to enlarge and reduce the image centering on the center of the screen in the five-stage port shown in Table 4. In addition, the first scale Pota emissions (4 to 7) is changed over to the jar good of Table 5 the scale Lumpur S a0 ₂ in two stages, the second scale port Tan (4 8) the first the scale number of濂拍Return to 3 stages as shown in Table 5. Further, when the print button (55) is pressed, a hard copy of the screen is performed, and the analysis screen can be printed.

Fig. 57 shows the flow chart of button input. The flag that indicates the screen color in the analyze mode is “Sys tea Flags”. I do. Table 6 shows the details of the "System Flags". In Fig. 57, # DB1 clears all "Syste 鳙 F1ags". Next, in #D] B2, check whether the R button (43) was pressed. If it was pressed, set the Escape flag in # DB3 and set # D39 in # 55. Go. # If the 1 button (4 3) is not pressed at 0 82, move to Ritsu DB 4, and check if the MZ R button (5 2) is pressed. If so, # MZR flag at DB 5 And proceed to DB6 as it is if it is not pressed. # In DB 6, check whether the large button (53) has been pressed. If not, move to # DB 9. # 0 8 6 presses the large button (5 3). For example, go to #DB 7 and check “Mode Nuber”. This “Mode Nuber” corresponds to “Mode” in Table 4. If it is 0, it is “Mode 0”. If not 0, move to #DB 8 and destroy one "Mode N ueber" o

In # DB9, it is checked whether the reduction button (54) has been pressed, and if not, the process proceeds to # DB12. # If the reduction button (5 4) is pressed at D B 9, at # B 10

"Mode N uaber" is called. If there is 4, go to # DB1 2 and if it is 4, go to # DB1 1 and I "

Increase "Mode Number" by one and proceed to # DB12. # DB 1 the state of the 2 first scale port button (4 7) was checked and the "S aO 2 5 0 Z 1 0 0" S a0 2 S ea le i flag # DB 1 4 if mode Te If not # DB 1 2 with _{"S a0 2 5 0/1} 0 0" mode, proceeds to # DB 1 5 make a S a0 ₂ S cale ₂ flag advance to # DB 1 3. Hayashi DB 15 states the status of the second scale button (48). In the "PR 20 Z 250" mode, the PRS ea lei flag is set in #DB 16; If it is not in "PR 20/250" mode, it is determined in # DB17 whether it is in "PR 50/150" mode. If it is in "PR 50/150" mode, it is DB Set the PRS cale2 flag in 18 and set the PRS cale 3 flag in # DB19 if not in the "PR 50 150" mode.

# In DB20, it is determined whether or not the first cursor button (50) has been pressed. If the first cursor button (50) has been pressed, proceed to # DB21 and proceed to the first DB. Raise the cursor flag and move to # DB22 if it is not pressed. # DB 22 determines whether the second cursor button (5 1) has been pressed, and if so, sets the second cursor flag #DB 23. Here, if the second cursor button (5 1) is not pressed, the process proceeds to #DB 24, and it is determined whether the print button (55) is pressed. For example, set the Print flag at # DB25, and if it is not pressed, exit the button input routine and return to # DB39 in Fig. 55. Referring back to FIG. 55, in # D39 and thereafter, the display and the like are changed according to the set concept of "Systea Flags" after the button input routine. First, perform an Escape F1ag check to indicate that the R button (43) has been pressed at # D39, and if this flag is standing, escape from the analyze loop and analyze. Ends the process and moves to the real-time mode. If the Escape flag is not on at # D39, go to # D40 to determine whether the MR flag is on. If the MZR flag is on, the data of the current cursor position is displayed in the center of the screen. Then, at # D41, the DNF of the data set containing the data at the current cursor position is taken as the new "Center Data". That is, one

3 0 0-C.C.

C enter D ata = C enter D ata- 9 X

D l sp l ay In terva 1 t-(36) is calculated. In # D42, after moving the graph by operating the MZR button, set the cursor counter C.C. to "300" to move the cursor position to the center of the screen. I do.

If the MZR flag is not set at # D40, proceed to # D43 to determine whether the first cursor flag is set. Here, the cursor moves to the left if the 1st ir-sol flag is on, but the cursor counter CC needs to be changed. Stop about one solution there and move the graph itself to the right. # In D 4 4, to make C.C. one display position to the left, from C.C.

The value obtained by subtracting "Display Interva 1" is used as a new C.C. Then, if "C.C. = 0" in # D45, that is, if the cursor position is on the left side of the screen, move to # 046 and change to <.C.

Add "Display Interva J" and move the cursor back to the right. #

D 47 indicates "Center D is the head address of the recorded data (Head

Ad dress) or not ', and if "Center D ata" is the first address, keep the "Center D ata" as it is so as not to move the graph any further. # Go to D55. # If "Center Data" was not an address recently in # D47, proceed to # D48 and move the graph to the right. Replace "Center Data" with 9 in "Center D" ata ".

On the other hand, if it is determined in # D43 that the first cursor flag is not on, the process proceeds to # D49 to determine whether the second cursor flag is on. If the 2nd cursor lag is not on, Proceed to # D5 5 with * to move to the display. Here, if the second cursor lag is on, change the cursor cursor C .. to move the force cursor to the right, but if the cursor is on the right side of the screen * Stop one sol and shift the graph itself to the left. Hayashi If the second ^ —sol flag is on D 49, proceed to #D 50,

# In D50, "Display lnterval" is added to C.C. and the display position to the right by one is C.C. However, if it is determined in # D51 that CC is larger than "600", "Display Interva is destroyed by CC in # D52 and the cursor is returned one position to the left. Change the "Center Data" to shift the graph to the left, but before that, "D Center" at # D53 shows "Center Data" as the final set of recorded data.

Determine whether it is equal to the DNF address (that is, "Last Address"), and if so, stop shifting the graph and go to # D55 to display. # D 5 3 in "Center

If it is not, enter 9 to "Center D ata" to move the graph to the left in # D54, and make it a new "C enter D ata".

# Proceed to D55.

Next, a detailed description of the display routine # D55 for displaying the screen will be given. Figure 58 shows the flowchart of this routine.

In Fig. 58, in #D D1 to #D D9

Set the parameter according to "Mode Nuber". # If "Mode N uaber" is 4 in "DD 1"("Mode4"), proceed to #DD 2 and "D ata I nterval = 2 ⁿ according to Table 4.

Assuming that "D isplay Interva 1 = 1", go to # DD10. # If D D 1 is not "Mode N uaber = 4", # D D 3

Determines whether "Mode Nuber- 3"("Mode3") Then use # DD 4 as shown in Table 4 "D ata I nterval = 1"

Set "Display lnterval = 1", but must be "Mode 3"

If you go to # D D 5 "Mode N u« ber = 2 "(" Mode 2 ")

Is determined. And if it is "Mode2", enter # DD6 in Table 4

Therefore, set "Data Interval = 1" ^e Display Display uterva i -2, and if "Mode 2" is not set, proceed to # DD7 "Mode Nu» ber = 1 "(" Mode 1 "), Where" Mode l "

If so, proceed to # D D 8 and follow Table 4.

w D ata I nterval = 1 D isplay I nterval-1 0 "

If it is not "Model", it is "ModeO", so # D D9

Set "Data I nterval = 1" ^w D isplay I nterval = 5 0

To end the mode setting.

Next, set the parameter settings for scale mode in #D.

D 1 0 ~ # D L> 17 This setting is as shown in Table 5, and

# If S a0 ₂ S cale l flag is set at DD 10 0, # DD

1 1 S a0 ₂ offset the (a) 5 0, S a0 2 di down (n) to 4

And set, S a0 ₂ to not standing is S aO a S cale l flag

If the Scale2 lag is present, set B-80, P = -10 according to Table 5 with # DD12. In addition, P D at # D D 1 3

If the Scalel flag is set, PR offset at # DD14

(P) is set to 0, PR din (q) is set to 1, and: fr DD 15

If the RS caleS flag is on, 3 = 50, _£ } =

Set to 3, PR Scalel, 2 without flag

If the P R S ea le3 flag is on, # D D 15 to # D D

, 17 and set p = l 0 0 and q = 2.

Next, draw the left half of the screen with # D'D18 to # DD40.

First, Yokosuke's index i is set to 300 at # DD18. Next, in # DD13, set DNF AD = "C enter Data", and in # DD20, set "Scan counter" for data scanning.

Set the "Data Interv ^ il" attribute. Next, scan the SaO ₂傣 and 傣 beat values of the address you want to read out with #DD 21 and take them in, and calculate the screen display position in the direction. If you defeat it, it is assumed that a data set of 9 bytes is selected, and Sa0 ₂ ! Consider the case where [is 30%. If the scale of the SaO ₂璣 axis is 50% to 100%, the SaO ₂ display position js in the longitudinal direction will be as shown in FIG.

js = (S aO _2- ») Xn + S aO 2 Zero point-(37)

= (9 0-5 0) X 4 + 3 0 0

= 4 6 0

Becomes Similarly, the pulse rate display position jp is

jp = (PR -p) Xq + PR Zero point ~ (38). Here Sa0 ₂ Z ero points are three 0 0 Dare fifth 6 Figure at the position of the lowest limit of the S _aO-2 graph display (j Ken橒), PR Zero point PR graph display of S under ¾ It is 0 in Fig. 56 at the position (U coordinate). Fig. 59 is a flow chart of the above algorithm. First, the address next to the address DNFAD is checked at # DC1, and the setting is not possible at the holly DC2 (IN 0 P ). Here, the content of the address DNFAD + 1 is ALF indicating the alarm status, and Table 1 shows the meaning of each bit. Therefore, it is possible to determine whether measurement is impossible (IAD0Ρ) by taking the logical product of the contents of address DNFAD + 1 and “78 7”. # If measurement is not possible at DC 2 (IN 0 P), then at #DC 3, Sa0 ₂ display position 2 a>, PR display position-p, and the bottom of each graph display section as that point Display at S position.

# If DC 2 is not possible (IN 0 P), then # DC 4 ,

Sa0 ₂ To set the contents of the DNF AD + 2 address, to set the contents of the DNFAD + 3 address to PR. Next, it is determined whether or not SaO ₂ is displayed at #DC 5 ^ (If it is small, proceed to #DC 6 and set SaO ₂ = 鱅. It is determined whether or not is smaller than the display lower limit 鏟 p, and if it is smaller, P Rp is set at #DC 8. Next, at #DC 9 and #DC 10, respectively, Calculate the SaO ₂ display position js and the number of beats display position js, and exit from the data check routine in Fig. 59.

Then, go back to the 5 8 FIG # DD 2 2, putting i coordinate of cursoring Le at that time I sao ₂ 1, the js and J sao ₂ 1. Also, I put that when. Force one Sol j coordinates I pr 1, put jp to J pr 1 S aO ₂ and腴拍number of display痤標_{(I sao 2 1, J sao} 2 1) (I pr 1 and J pr 1) are obtained. Next, in # DD23, "Display Interva is destroyed from ί in order to find the god's mark of the position fi to the left of the display position. At this time, if ί-0, ir Jumps to # DD40 with ^ located on the left side of the screen.If i ≠ 0, it is on the screen, so it goes to # DD25 and scans the immediately preceding data. When ata I nterval = 2 ", the data must be decimated and the previous data is scanned. That is, S is subtracted from # DD 25 CD NFAD and 1 Only

Decrement "S can Counter". # D D 2 7

It is determined whether or not DNFAD is the head address (Head Address) of the recording data. If it is not the head address, the process goes to # DD28 and checks whether "S can Counter" is 0. If not 0, return to # DD25 and repeat the operations from # DD25 to # DD28 again. # If "Scan Counter" is 0 in DD 28, #DD 29 is 9 bytes of data from the DNF AD address at that time It performed Detachi click of the 5 9 FIG illustrated for the set, # DD 3 0 at the calculated js, the next display coordinates from _{jp (I sao 2 2, J} sao 2 2) (I pr2, J pr2) Ask for.

Next, at # DD31, a straight line is interpolated between the two points. 5 0 FIG smell Te, computing system裤部(3 5), the coordinates of two points regarding S _aO-2

_{(I sao 2 1, J sao} 2 1) (I sao 2 2, J sao 2 2), and the two points, the La Lee down instruction for linear interpolation between as a code signal image ½ sense When the image data is sent to the image recording unit (201), the image processing unit (201) writes the two-point min to the image recording unit (202) in a straight line. Both are displayed on the display section (37). In the same Didi, the calculation control unit (35) sends the coordinates (Iprl, Jpr-1) (Ipr2, Jpr2) and the line command of the two points that beat the pulse rate to the image unit (20). Send to 1) to display a straight line. When the% straight lines are displayed, return to # DD32 in Fig. 58.

# Coordinates (I sao ₂ 2, J _sa02 2) and coordinates for DD ₃₂

To make (I pr 2, J pr 2) the starting point of the next straight line

(I sao21, J sao21) — \ 丄 sao2 2 »J sao2 2),

(I pr 1, J pr 1) = (I pr 2, J r 2)

And # D D 3 3 for "S can Counter"

Set the "DataInterval" value, then return to # DD23 and continue to display until you reach the top left of the screen or the top of the data.

# If DNFAD becomes the first address of data in DD27, proceed to # DD34 to determine whether "S can Counter" is 0 or not. If it is not 0, display it. Jump to # DD40. # If "S can Counter" is 0 in DD34, # DD35 clicks on the data set according to the flow shown in Fig. 59 and proceeds to # DD36.痤標_{(I sao 2 2, J sao} 2 2) One —

(I pr2, Jpr2) is obtained, and is linearly complemented with #D D 37. Next, the i target is decremented by 1 at # DD38, and at # DD39

Turn off the screen for the part i 'where 1 ≤ i' ί. When it reaches the left side of the screen, it proceeds to # DD40 and records the DNFAD at that time as HDNF AD. Next, from # DD41 to # DD63, operations related to Yasushi Uchi from the center of the screen are the same as # DD18 to # DD40. # DD 4 1 to # DD 4 5 operate exactly the same as # DD 18 to # DD 22. # In DD 46, find the right display coordinate, and in #DD 47, judge whether it is right or left. Otherwise, scan the previous data from # DD 48 to # DD 51. You. # DD 5 2~ # DD 5 was Motoma' at _{6 (I sao 2 1, J} sao 2 1) (I sao 2 2, J sao 2 2) (I pr 1, J pr 1) (I pr 2, J pr 2) Complement the line and display it. From # DD57 to # DD62, if DNFAD becomes the address of the DNF in the Shin-end set, all parts between ί and 600 at that time are turned off. In # DD63, the DNFAD at that time is noted as LDNFAD, and used for drawing a histogram later described. #DD 6 3 Sa0 ₂及Pi脒拍number until is displayed graph, the horizontal sleeves in accordance with the shaved Lumpur graph in # DD 6 4, for displaying the維輔. Together with the analyzer Zumo soil, to be displayed on Rooster surface as a digital嫿measurements of Sa0 ₂及Pi滕拍number of cursor position and portions thereof with # DD 6 5. Further, # the DD 6 6, His preparative grams Sa0 ₂ graph display portion of the data in or out of the graph displayed on the current screen, the displayed right惻of PR graph display unit.

Fig. 60 shows the detailed flowchart of the Fig. 58 # DD65 cursor digital plant display routine. ^ One sol has various shapes, but in this embodiment, it is indicated by a straight line that cuts off the screen. In Fig. 60, # DCD 1 is the point of the previous cursor.

(preic, 0) Removes the straight line display represented by (preic, 5 0 0). Next, the current C.C. value is used as a new cursor expression index ic, and (ic, 0) (ic, 500) is used as the image processing unit in # DCD3.

Send to (201) to display the cursor.

Next, ic is written to preic in # DCD 4 to prepare for the next cursor display. # In DCD 5, calculate the S aO ₂ , 數 beats at the intersection of the ^ ^ sol and the graph. "Center Data at ^w

The address of the DNF is shown.In the center, ί = 300, so the address DNF of the DNF of the data set at the cursor position is

3 0 0-ic

D N F D = C enter Data- X 9

D l s 1 ay I nterva 1

~ (39) is calculated. If the contents of address DNFD + 1 are not checked and the measurement is impossible (INOP), “INOP” is displayed on the digital display.If the measurement is not possible (IN0P), DNFD + Since the content of address ₂ is the value of Sa0 _{2 and} the content of address DNFD + 3 is the value of the beat, these are converted to ASCII codes by #DCD 6 and displayed on the digital display, for example, SaO ₂ 9 7%, Pulse Rate 6 5 bpi ».

Here, the sentence display instruction can be realized by sending its coordinates, sentence code and sentence display instruction to the image processing unit (201). If the measurement is impossible (IN0P), the cause of the indetermination (IN0P) can be found by examining the contents of the address DNFD + 1, and the cause can be displayed on the screen in text. For example, from Table 1 above,

(D N F D + 1) A D 4 0 H ≠ 0

To (40) If so, the pulse wave is weak, indicating that the measurement is not possible, so the letter "P" may be displayed. In addition, since the data set contains information such as Sa0 ₂ and 警告 beat rate, upper warning 100%, pulse rate lowering warning 值, time, etc., these can be displayed simultaneously. It is.

Next, the histogram (frequency distribution) creation routine will be described with reference to the flowchart in FIG. In Fig. 61, each frequency memory is first cleared with # DH1. The frequency memo 1} 1 0 0% 5 0% for S a0 ₂ For example, 5 0% 6 0% 6 0% to 70%, 70% ~ 80%, 8 0 % To 90%, and

90% to 100% are divided into five equal parts to provide five frequency memories, and count the frequency of sake fixed price in each range. The same applies to the pig beat rate. 0 bp, ~ 250 bp, 0 bp ~ 50 bp, 50 bpa ~

100 bpa, 100 bpe ~ 150 bpa, 150 bpa ~ 200 bpa,

Five frequency memories are allocated to five pro-knocks of 200 bpe to 250 bpa. To check from the data on the left side of the display graph with # DH2, set the histogram pointer Q to HDNFAD. In # DH3, read the contents of address Q + 1. If measurement in # DH4 is impossible (IN0P), jump to # DH25. # DH 4 in the flow proceeds to unmeasurable (INOP) unless # DH 5, Q + 2 address Iberu the S a0 ₂ data of. # DH until 6 ~ # DH 1 4 is whether the S a0 ₂ data is entered in any frequency range of the above! To another, to Lee down click Li e n t the contents of the frequency Note Li in the range entering. For example, if S aO z = 7 5%, # DH 6, # DH 8, # DH 1 0, Hayashi DH 1 1 and willing, frequency Note Li S a0 ₂ 7 0 - fin click contents 8 0 Will be reset.

After the check at address Q + 2, go to #DH 15 to Q + Check the number of beats data at address 3. In this S a0 ₂ when the same method, # DH 1 in 6 to # DH 2 4 determines the data has been made, for example, pulse數is 2 0 0 bp鳙of i5 # DH 1 6, # DH 1 8, # DH20, # DH22 # DH24, and the contents of the frequency memory PR200-250 are incremented. Then, when the number of beats is completed, go to # DH25 and add 9 to the histogram pointer Q to point to the next DNF address. Here, if # DH26 is equal to or less than LDNFAD, return to # DH3 and repeat the data discrimination, and repeat the above operations until Q> LDNFAD. For each flow up to # DH26, the frequency distribution of data for the display screen is stored in each frequency memory.

In # DH27, the frequency distribution is graphed as shown in Fig. 62. Rather each of the 6 2 Figure, S aO ₂ = 5 0% of ¾ point H _t coordinates of (iH jH,) and when, the coordinates H ₂ (iH _2, jH ₂₎ is

_{_{(iH 2, jH 2) =}} ((iH, -k (S a0 2 5 0 - 6 0)), jH,)

'~ (41)

Can be calculated. Here, (S aO ₂ 5 0 — 6 0) indicates the content of the frequency memory S a0 ₂ 5 0 — 0, and k is a variable for indicating the size of the entire histogram in din. It is. The two points (iH jHJ H jH are obtained by the calculation of equation (41), so the coordinates of these two points and the width of the graph) and the line instruction are transferred to the image processing unit (201 ) Can be used to display a histogram.

Next, the process returns to # D56 in FIG. 56 to perform hard copy processing on the screen. If the Print flag is set in # D56, it is determined that the print button (55) has been pressed, and the process proceeds to # D57 to perform a hard copy on the screen. # In the case of D57, One one

(35) sends a command to the image processing unit (201) to send data for one line of the image recording unit. On the other hand, the image processing unit (201) sends the data of one line ^ to the storage unit (200) through the operation control unit (355). In the operation-controlled street (35), this one line of data is transferred to the printer section (38), and one line is printed. This operation can be repeated over the entire screen to perform hardcopy of the rooster face. In the case where the liquor measurement data is stored in a removable memory such as an IC card on the oximeter body, the same analysis can be performed by attaching the IC card to the data analyzer (C). In Fig. 50, (203) shows the memory mounting part, and only when the memory is mounted, the data recorded in the memory is sent to the arithmetic control part (35). send. (5) While this signal is being output, the memory control unit (3 5) attaches memory instead of sending a transmission request to the main unit in steps # D10 and # D11 in Fig. 52. Department

Read the data directly from (203) or the memory mounting part

Control is performed so that data is written from (203) to the memory (200).

Claims

— 1 1? — Billing ft

1. In an oximeter that determines the degree of elemental harmony of the measured object,

Den S and

A light emitting means for projecting light toward the predetermined house, which is exposed to the light,

A light receiving means connected to the S for receiving light emitted from the light emitting means and passing through the subject to be determined;

An arithmetic unit which is connected to the snow source and calculates the oxygen sum and the number of beats according to the output signal of the light receiving unit;

A warning value setting means, which is connected to the electric train, and sets a warning value for the oxygen concentration and the number of beats;

Connected to the power supply and calculated »element s ¾ 酸素 ¾ され酸素酸素酸素酸素酸素酸素酸素酸素酸素脉脉所定脉脉所定脉A warning means for outputting a warning signal when a predetermined relationship is established with the warning value of

A timing means for measuring time,

Recording means capable of recording even when power is not supplied to the light emitting means, the light receiving means, the calculating means, and the warning value setting means;

Based on the timekeeping means, the time, the calculated oxygen saturation, the calculated heart rate, the set oxygen harmony warning clerk, the set pulse rate warning value, and the warning at predetermined intervals Town control means for recording the output of the means on the means of use,

An oximeter characterized by having

2. The control means comprises: a power supply means for supplying power to the light emitting means, the light receiving means, the calculating means, and the warning value setting means when the power supply is not connected thereto; Detect output voltage of power supply 2. The oximeter according to claim 1, wherein the oximeter includes a voltage detection unit that performs the operation and a warning display unit that displays a warning when the detected voltage is equal to or less than a predetermined voltage.

3. The control means is set to the light-emitting means, light-receiving means, calculating means, warning value setting means, and warning value setting means when a predetermined period of time has passed since the power was connected. Only when the advertised guilty code is changed is the element! 2. The oximeter according to claim 1, wherein the oximeter is configured to record the warning value of the degree of harmony and the warning of the number of beats in the recording means.

4. The control means includes the oxygen fidelity imaged on the recording means when the light emitting means, the light receiving means, the calculating means, the warning setting means, and the bud notification means are connected to the electric device. 2. The oximeter according to claim 1, wherein the quasimeter is configured to set a quasi-warning warning and a low-beat beat warning に in the warning 值 setting means.

5. Oxygen by calculation means! An operation invalidity discriminating means for discriminating that the operation of the sum or the number of pulses is not possible or that the operation result is invalid, and the cause of the invalidity of the operation. Claims characterized in that it comprises: a cause identification means for identifying; and an operation inadequacy description step for causing the imaging means to use the identification result of the operation inadequacy determination means and the identification result of the cause identification means. The oximeter described in item 1.

6. When it is determined that the calculation by the calculation means is inappropriate for a predetermined time or more, the town control means sets the calculation result by the calculation means, the time of the timing means, and the warning value setting means. The warning value of the oxygen saturation and the number of beats, the output of the warning means, and the identification result of the cause identification means are not recorded on the imaging means. The oximeter according to item 5.

7. Event marker at the timing according to the specified manual operation An event marker input means for inputting an event marker and an event marker input when a manual operation for inputting an event marker is performed; 2. The stimulator according to claim 1, further comprising a marker writing means.

8. A plurality of warning means that can select one of them, a warning system that generates a warning based on the warning signal of the warning means according to the selected warning generating means, and a selected warning generation means Warning means for recording the means in the recording means, and when the power is turned on, a warning is generated by the notice generating means used in the recording means. The oximeter according to claim 1, wherein the oximeter is configured as follows.

9. A plurality of warning generating means, a first warning generating means for generating a display-only warning, a second warning generating means for generating a warning by a display and a warning sound, and a display and a message. 9. The oximeter according to claim 8, further comprising: third warning generating means for generating a warning by a message.

10. It has a volume setting means for setting the volume of the warning sound and the message, and a warning volume recording means for recording the set volume in the recording means, and is provided when the power is connected. 4. The oximeter according to claim 3, wherein the volume of the warning sound and the message is controlled by the volume used for the recording means. Meta.

9. The oximeter according to claim 8, further comprising a notice display means for displaying the selected warning generating means.

1 2. When the power supply is reconnected, the storage 2. The oximeter according to claim 1, further comprising: a separate unit for determining whether or not the determination is made, and a determination display unit for displaying a result of the determination.

13. The claim, wherein the means is detachable from an oximeter body including a power source, a light emitting means, a light receiving means, a calculating means, a warning setting means, a warning means, and a timing means. The oximeter according to item 1.

14. The oximeter according to claim 1, further comprising a storage capacity display means for performing a display corresponding to the capacity.

15. The oximeter according to claim 1, further comprising a storage capacity display means for displaying the storage capacity of the storage means with respect to an unrecorded storage capacity.

16. The oximeter according to claim 1, wherein the storage means is selected from one of an IC card, a magnetic card, a bubble memory, a battery built-in RAM board, and an EPROM.

1 7. A beat generator that generates a sound synchronized with the measured beat, and that beat that sets the volume of that beat :! It has a setting means and a pulse sound for recording the set volume in the recording means: a recording means, and when the electric field is connected, the pulse rate is set to the volume recorded in the recording means. 17. The oximeter according to claim 16, wherein the volume of the beat is controlled so as to be controlled.

18 8. Information on the oxygen fidelity and the number of beats calculated by the calculation means, the time of the time by the timekeeping means, the oxygen saturation and the pulse set by the warning value setting means 2. The oximeter according to claim 1, further comprising an output unit for outputting information on the warning value of the number to the outside.

1 9. The output means is configured to output the warning value information of the oxygen ffe and the * beat rate by the warning value setting means to the outside only when the power is connected. 19. The stimulator according to claim 18, wherein:

20. The output means outputs the information of the oxygen S relaxation rate and the warning value of the number of beats when the warning value of the set oxygen level or the warning value of the pulse rate is changed. 19. The oximeter according to claim 18, wherein the oximeter is configured to output to the outside.

2 1. The calculation improper determination means for determining that the calculation of oxygen degree or pulse rate by the calculation means is impossible or the calculation result is invalid, and the calculation thereof And a cause identification means for identifying a cause of the inappropriateness of the calculation means, and the output means also outputs to the outside the result of the determination by the calculation instability determining means and the result of the identification by the cause identification means. The oximeter according to claim 18, characterized in that:

2 2. Event marker input means for inputting an event marker at a timing corresponding to a predetermined manual operation, and output means for inputting the event marker 18. A system according to claim 18, wherein a signal indicating that the event marker has been input is output to the outside when a manual operation is performed to cause the event marker to be input. The described oximeter.

23. It has reading means for reading a large number of calculation results recorded in the notation means, and the output means is configured to output the information based on the read calculation result to the outside. The oximeter according to claim 18, wherein

24. Output time display means for displaying the time required for the output from the output means of the operation result written in the notation means. The oximeter according to claim 18, wherein:

2 5. The output means should output a signal based on the information to be output serially! 19. The oximeter according to claim 18, wherein the oximeter is configured as described above.

2 6. Measured versus house oxygen! In the oximeter that measures the degree of harmony,

A probe having light emitting means for projecting light toward the object to be measured, and light receiving means for receiving light emitted from the light emitting means and passing through the non-measurement object;

Calculating means for calculating the oxygen harmony degree and the knee beat rate based on the output signal of the light receiving means;

Display means for displaying the calculated oxygen degree and pulse rate; output means for outputting information based on the calculated oxygen | degree and pulse rate to the outside;

An oximeter having a measurement mode selection means for selecting one of a plurality of measurement modes.

27. Measurement mode selection means _: The first mode that measures oxygen saturation and pulse rate continuously, and the second mode that measures oxygen degree and pulse rate at regular time intervals Fx or fx can be selected, and the output means outputs the information on the calculated oxygen saturation and pulse rate to the outside, measured and calculated according to the selected measurement mode 27. The apparatus according to claim 26, wherein the display means is configured to display information of the oxygen saturation and the pulse rate measured and calculated according to the selected measurement mode. Oximeter.

28. A light emission stop means for stopping light emission of the light emission means when the calculation of the oxygen saturation and the pulse rate is not performed by the calculation means. The oximeter according to item 6.

29. It has a calculation command means for outputting a calculation command signal for commanding the calculation of the oxygen sum and the number of beats, and the measurement mode selecting means uses the oxygen calculation signal in response to the calculation street signal. 27. The oximeter _{β according} to claim 26, wherein the third mode for calculating the sum and the number of beats is selectable.

30. A stability discriminating means for judging whether the calculated oxygen saturation or the beat rate is stable when the third mode is selected by the measurement mode selecting means, and a stabilizing means. Claim 29. The apparatus according to Claim 29, further comprising stability display means for displaying when the oxygen saturation or pulse rate calculated by the sex determination means is determined to be stable. Oximeter described in section.

31. Stability The H means is characterized in that it is configured to determine whether or not the calculated oxygen saturation or pulse rate is stable based on a series of calculation results. The oximeter described in claim 30.

32. The probe has a first probe dedicated to the third mode, and a second probe dedicated to other modes, and has a calculation means, a display means, an output means, and a measurement mode. Each probe can be attached to and detached from the main body of the oximeter, and a measurement mode signal is output to each probe to indicate the approximate mode. A mode signal output means is provided, and the oximeter body reads the measurement mode signal output from the measurement mode signal output means of the attached probe and measures the measurement mode. 30. The oximeter according to claim 29, further comprising a measurement mode judging means for judging the difference.

3 3. In the oximeter that measures the biological information of the subject, First and second light emitting means for projecting light having first and second wavelengths different from each other toward a target to be determined;

A first light receiving means for receiving light emitted from the second light emitting means and passing through the subject to be conveyed;

Signal separating means for separating from the output of the light receiving means into a first ♦ second lake constant signal according to the first ♦ second wave;

Calculating means for calculating biological information of the subject based on the first and second measurement signals separated for each wavelength;

Light emission control means for controlling the light emission intensity of the first or second light emission means so that the ratio of the first drowning signal and the second drowning signal falls within a predetermined range;

An oximeter with

3 4. The first light emission is about 660 na, the second light emission is 940 _ηΐι , and the light emission control means controls the light emission intensity of the second light emission means. 34. The oximeter according to claim 33, wherein the oximeter is configured to perform the following.

3 5. The light emitting device operates the first light emitting device at the driving frequency f, (Hz) and the second light emitting device at the driving frequency f ₂ (Hz). The oximeter according to claim 33, wherein the frequency ₂ is set substantially as follows: f, = (common multiple of 60 and 50 + 25) Hz

f ₂ = (common multiple of 60 and 50 0 2 5) Hz

3 6. A frequency discriminating means which is connected to the output of the light receiving means and discriminates the commercial power frequency from the noise of the commercial power frequency superimposed on the means of the light receiving means. The first and second light emitting means are controlled in accordance with the commercial power frequency determined by the commercial power supply frequency. 33. The oximeter of claim 33.

3 7. When the commercial power frequency is 50 Hz, which is determined by the frequency determination means, the emission control means is approximately

25) Hz or approximately (an integral multiple of 50) 25) Hz is used as the g dynamic frequency of the first and second light emitting means, and by the frequency discriminating means! ! Another has been (integer times one 3 0 6 0) Hz H _Z or Oyo its (簦数times + 3 0 6 0) its utility frequency is Oyo in-out 6 O Hz Noto first and 36. The oximeter according to claim 36, wherein the oscillating frequency is the operating frequency of the light emitting means.

3 8. Compare the output of the bandpass filter, which controls only the predetermined frequency of the output of the light receiving means, and the output of the band-noise filter with the predetermined value. An oximeter according to claim 36, comprising: a comparator; and a power source frequency differentiating means for determining a commercial power frequency based on an output frequency of the comparator. Ta.

3 3. The light emission control means drives the first light emission means and the second light emission means at the same frequency and at a driving frequency which is out of phase by 1 Z 4 periods with respect to each other. The demultiplexing means uses the signals having the same frequency as the drive frequency of the first * second light emitting means and shifted in phase by 1 Z 4 cycles from each other as reference signals, and outputs the output of the light receiving means as the first signal. 34. The oximeter according to claim 33, further comprising first and second synchronous rectification means for dividing the measurement signal and the second measurement signal.

4 0. It has the same frequency characteristics as the output frequency characteristics of the light receiving means. 校正 The calibration signal output means that outputs a positive signal, and either the output of the light receiving means or the calibration signal of the calibration signal output means is input to the demultiplexing means. Input switching means, and the calibration signal is separated by the input switching means. When the signal having the same timing as the driving signal for moving the first light-emitting means into the S direction is input to the correction signal output means, the separating means outputs First ratio calculating means for calculating a ratio of the second determination signal to the first determination signal; and a second light emitting means in a state where the calibration signal is input to the separation means by the input switching means. The ratio of the first measurement signal to the second measurement signal output by the demultiplexing means when a signal having the same timing as the input signal for moving the signal is input to the calibration signal output means. And a correcting means for correcting the calculation result of the calculating means based on the ratio calculated by the first and second ratio calculating means. The oximeter of claim 33.

4 1. The first ratio calculating means calculates the ratio of the second measurement signal to the first measurement signal of the separating means when only the first light emitting means is driven, and the second ratio calculation means. The means calculates the ratio of the first measured signal to the second measured signal of the dividing means when only the second light emitting means is operated, and the correcting means calculates the ratio in accordance with the two calculated ratios. 41. The oximeter according to claim 40, wherein said oximeter is configured to correct a calculation result of said means.

4 2. 温度 Temperature detecting means for detecting the temperature of the first or second light emitting means, and wavelength shift calculating means for calculating a change in the emission wavelength of the first or second light emitting means from the detected temperature. 34. The oximeter according to claim 33, further comprising a calculation correction means for correcting the calculation result of the calculation means based on the change in the emission wavelength.

4 3. At least the first and second light emitting means and the temperature detecting means are blowers that are detachable from the oximeter body having the arithmetic means. The oximeter according to claim 42, wherein said oximeter is provided on a valve.

44 4. Fewer ^: At least one of the first and second light emitting means consists of a light emitting diode, and the temperature detecting means measures the voltage applied to this light emitting diode and determines the voltage. The oximeter according to claim 42, wherein the oximeter is configured to detect a temperature.

4 5. Emission intensity notation means that uses information on the emission intensity ratio of the first and second emission means at two specific wavelengths, and the useful emission intensity ratio The oximeter according to claim 33, further comprising: a correction unit configured to correct a calculation result of the calculation unit.

46. The oximeter according to claim 45, wherein at least one of said first and second light emitting means is a light emitting diode.

47. At least the 1st and 2nd light emitting means and light emitting intensity recording means are provided on a probe which is detachable from the oximeter body having the calculating means. The oximeter according to claim 45, characterized by this.

48. The oximeter according to claim 33, wherein the calculating means calculates the oxygen saturation or the pulse rate of the object to be measured.

49. In an oximeter that measures the oxygenation degree and the beat rate of the subject,

Oxygen saturation measuring means for measuring the oxygen harmony of the measured object, and 脲 pulse rate measuring means for measuring the pulse rate of the measured object;

Oxygen saturation warning value setting means for setting a warning value of the oxygen level, pulse rate warning value setting means for setting a pulse rate warning value, The measured oxygen saturation is compared with the set oxygen saturation warning, and the oxygen which generates an oxygen saturation warning signal when both of them are in a predetermined fighter.

A pulse rate reporting means for comparing the measured knee pulse rate and the set pulse rate warning value, and generating a pulse rate warning signal when both persons become a predetermined fighter;

Determines whether oxygen saturation or pulse rate cannot be measured or drowned oxygen saturation or pulse rate is invalid and cannot be measured if it is not possible or invalid Non-drowning discriminating means for generating a signal, and reporting means for issuing a chirp according to the sound and display selected from the plurality of sounds,

Warning sound selection means for selecting any of a plurality of sounds;

Warning sound display means for displaying a sound according to the selected warning sound; warning control means for activating the warning means in response to the oxygen harmony warning signal, the pulse rate warning signal—and the unmeasurable signal;

An oximeter characterized by having:

50. The alarm sound selection means is a first bud mode in which a sound message and a buzzer sound are generated in accordance with the content of the oxygen alarm signal, the pulse alarm signal, and the unmeasurable signal. Be configured to select between a second warning mode that only generates a warning sound and a third mode that does not generate a warning sound or an audible message. The oximeter according to claim 49, wherein the oximeter is characterized in that:

51. The warning means according to claim 49, wherein different warning sounds can be generated for each of the oxygen saturation warning signal, the pulse count warning signal, and the unmeasurable signal. The described oximeter.

5 2. The bud notification means includes an oxygen saturation warning signal, a pulse rate warning signal, The oximeter according to claim 51, wherein a warning sound having a different frequency can be generated for each of the unmeasurable signals.

5 3. Warning means oxygen!請求 A claim characterized in that, when the degree of harmfulness warning signal or the pulse rate warning signal is issued, a distinctive warning sound can be generated according to a difference between the measured value and the warning value corresponding to the signal. The oximeter according to item 49.

5. The warning means, when the oxygen level alert signal or the K beat rate chirp signal is issued, determines the volume, frequency and disconnection according to the difference between the measured value for that signal and the chirp signal. The oximeter according to claim 53, wherein a warning sound with a set interval can be generated.

5 5. When two or more of the oxygen saturation warning signal, the pulse rate warning signal, and the non-drownable signal are simultaneously generated, a priority is given to giving priority to the type of signal for generating the warning sound. The oximeter according to claim 53, further comprising a position determining means.

56. The oximeter according to claim 55, wherein the tongue determination means is given the highest priority to the oxygen saturation signal. .

57. The warning means according to claim 49, wherein a warning sound can be generated in which a volume, a frequency, and a break interval are set according to a time during which the warning is cut. Oximeter.

5 8. Oxygen! ¾ It is impossible to measure the degree of saturation or pulse rate.If it is determined that the measured oxygen saturation or pulse rate is invalid, it has a cause identification means to identify the cause and warns. An okey according to claim 49, wherein the means is capable of issuing a warning by means of a sound and a display determined based on the identified cause. [0027] One "['one PCT / JP86 / 00342 Simulator.

5 9. Oxygen feasibility or heart rate cannot be measured or the cause is determined when it is determined that the measured oxygen saturation or heart rate is invalid. 49. The method according to claim 49, further comprising a cause identification means, wherein the bud notification means is capable of generating a warning by a voice message determined according to the identified cause. Ta.

6 0. In an oximeter that drowns the biological information of the subject,

Light emitting means for projecting light toward the measured object;

Light receiving means for receiving light through the measured object;

A means for determining biological information based on the output of the light receiving means;

A measurement impossible determination means for determining whether measurement of biological information by the output of the light receiving means is impossible or invalid, and

A time measuring means for measuring a time during which the impairment is locked after it is determined that measurement is impossible or invalid;

Light emission stopping means for stopping light emission of the light emitting means when the time counting means has counted a predetermined time or more,

At predetermined intervals after the emission of the light emitting unit is stopped, the light emitting unit is caused to emit light only for a predetermined period of time to determine whether or not the measurement impossible or invalid state is released,

An oximeter characterized by having:

61. The oximeter according to claim 60, wherein the light emission control means is configured to cause the light emission of the light emission means to move in an arrowhead direction when the measurement impossible or invalid state is released.

62. The stimulator according to claim 60, wherein the biological information measuring means measures the oxygen f & sum or the pulse rate of the subject to be measured. ,

6 3. In an oximeter that determines the degree of oxygenation of the subject to be measured,

A change direction discriminating means for discriminating whether the measured oxygen S degree is increasing or decreasing with time, or

An oximeter characterized by comprising: display means for performing a display in accordance with the determined change direction.

6 4. In an oximeter that determines the oxygen saturation of the object to be measured,

Oxygen saturation measuring means for measuring oxygen saturation,

Pulse rate measuring means for measuring the pulse rate;

A pulse sound generating means for generating a disconnection sound in synchronization with the measured pulse rate;

Pulse sound control means for changing the duty ratio or the number of occurrences of the pulse sound according to the measured oxygen saturation;

An oximeter characterized by having:

6 5. Non-volatile notation, and '

Measuring means for non-invasively measuring signals from blood, memory attaching means with removable means, and writing of data corresponding to the measured signal to the attached memory means A main body having a writing means, wherein the recording means is detachable, and a data analyzer for performing a predetermined analysis based on data used in the attached recording means is provided. A characteristic oximeter system. 6 6. The main unit has printer connection means that can be connected to the dedicated printer, and the dedicated printer prints according to the signal transmitted through this printer connection means. The oximeter ♦ system according to claim 65, wherein the oximeter system is configured to perform the following.

6 7. The main unit has a connection means that can be connected to a general-purpose information processing device such as a personal computer, and the general-purpose information processing device receives signals transmitted through this connection means. The oximeter ♦ system according to claim 65, wherein the oximeter is configured to perform information processing based on the information.

6 8. The data recorded in the notation means are the data on the measured value of oxygen saturation, the data on the planting of the heart rate, the data on the reported value of oxygen saturation, and the setting. 6. The oxime according to claim 65, wherein the data includes data that bucks the warning value of the number of beats obtained, data on the cause of inability to determine sake *, and data on the measurement time. ♦ System.

6 9. In an oximeter that measures oxygen saturation and thats pulse rate in blood,

Measuring means for non-invasively measuring a signal from blood;

Non-volatile storage means;

Writing means for writing the data obtained by adding the measured signal to the 1S means;

An oximeter characterized by having

70. The storage means has a memory attachment means to which a non-volatile memory can be attached and detached, and the data is recorded in a memory which can be attached to and detached from the oximeter body. The oximeter according to claim 69, wherein the oximeter is characterized in that: 7 1. The data recorded in the notation means is the data on the oxygen saturation level, the data on the K-beat count, the data on the set oxygen saturation warning, and the data on the setting. The oximeter according to claim 63, comprising data on a warning value of the pulse rate, data on the cause of the unmeasurable condition 3 and data on the drowning time. .

7 2. The data writing to the recording means is configured to be repeated at intervals longer than the measurement intervals of oxygen | The oximeter according to claim 6, entitled "S".

73. The method according to claim 71, wherein the time interval PR for repeatedly writing data relating to the measurement time is longer than the time interval for repeatedly measuring the oxygen saturation and the pulse rate. Oximeter.

7 4. The data on the set oxygen saturation warning value and the set pulse rate warning value are stored only when the power switch of the main unit is turned on and when the set value is changed. The oximeter according to claim 71, characterized in that the oximeter is configured to be written into a means.

75. Claims characterized in that, if the measurement impossible idea continues for a predetermined time or more, the writing of the data relating to the cause of the measurement impossible idea is stopped. The oximeter described in Section 71.

7 6. Oxygen in the blood! A measuring means for outputting & information on the degree of oxygen in blood based on a measurement signal from the probe,

Clock means for outputting time information; A recording means for recording the harmony degree information and the time information together, an output means for outputting the recording information of the usage means from an external connector, and a portable means for supplying the above means to the above means. With electricity

An oximeter characterized by having:

77. The claim according to claim 76, wherein the output means is configured to output the record information and real-time harmony information from the transfer means. Xymeter.

7. 8. The output means is configured to selectively output real-time f & sum information from the measurement means and the recording information from the recording means from a common external connection Yasuko. The oximeter according to claim 76, which is characterized by the claims.

7 9. Measuring means and recording means! A parallel signal corresponding to the harmony degree information or the recording information is output, and the output means is configured to convert the parallel signal into a serial signal and output the signal. The oximeter according to claim 76, wherein:

8 0. An oximeter that analyzes the measured oxygen saturation in the blood

An oximeter body for continuously measuring oxygen saturation and pulse rate in blood;

A storage device that is detachably attached to the oximeter main body and that continuously uses information about the oxygen saturation and pulse rate measured continuously;

It has a mounting means capable of mounting a writing device, a reading means for reading information on oxygen saturation and the number of beats recorded on the recording device, and an analyzing means for analyzing the read information. An analysis device;

Oximeter ♦ system characterized by having.

8 1. The analyzer has connection means that can be connected to the oximeter main unit, and data can be exchanged directly with the oximeter main unit in real time. The oximeter ♦ system according to claim 80, wherein the system is awaited.

8 2. The oximeter body has oxygen fidelity warning value setting means for setting the oxygen level warning, pulse rate warning value setting means for setting the R pulse number warning value, and time information. Clock means to output the measured oxygen and the set oxygen! ¾ Compares with the harmony alert value and generates an oxygen saturation alert signal when both are in a predetermined relationship.Oxygen saturation alert means and the measured `` beat count and the set beat count warning Teng beat rate warning means that compares the values with each other and generates a beat rate warning signal when the two have a predetermined relationship, and it is impossible or impossible to measure the oxygen ffe sum or the beat rate Means for determining whether or not the obtained oxygen saturation or the number of brachii beats is invalid, and having an unmeasurable determination means for generating an unmeasurable signal when disabled or invalid.

The recording device is configured to measure the measured oxygen saturation signal according to the determined oxygen saturation, the measured pulse rate signal according to the measured pulse rate, and the oxygen level according to the set oxygen saturation warning value. A summation warning value signal, a pulse rate warning value signal according to the set pulse rate warning value, a time signal according to time information, an oxygen saturation warning signal, a pulse rate warning signal, and an unmeasurable signal are recorded. When you do

The oximeter ♦ system according to claim 80, wherein said analysis device performs analysis based on each signal recorded on said marking device.

83. The analysis device according to claim 80, wherein the analysis device has a graph display means for displaying the continuously measured oxygen f & sum degree on a single screen in a graph. Oximeter ♦ System. 84. The oximeter ^ 'system according to claim 83, wherein the graph display means is capable of shifting and displaying a designated portion.

8 5. The analyzer should have a frequency distribution calculating means for calculating a frequency distribution of the oxygen f degree, which is temporarily determined, and a frequency distribution displaying means for displaying the calculated frequency distribution on a screen. The oximeter ♦ system according to claim 80, characterized by the following.

86. The oxime according to claim 85, wherein the frequency distribution display means is characterized in that the frequency distribution displayed on the screen can be displayed in an enlarged or reduced size. Data ♦ System.

8 7. In an oximeter for continuously measuring biological information, a measuring means for measuring biological information,

A warning means for generating a chunk signal when the measured biometric information has a predetermined relationship with a predetermined chaplain level;

A warning sound generating means for giving buds by sound in response to the warning signal; a volume level of the warning sound generated from the warning sound generating means; a first volume level, and a second volume level lower than the first volume level. Volume selection means for selecting from a volume level of and

An oximeter characterized by having:

8. A control means for selecting a first volume level when a warning signal is canceled in a state where a warning sound is generated by the second volume level. Oximeter according to clause 87.

83. The oximeter according to claim 87, further comprising volume level display means for indicating that the second volume level is selected.

9 0. In an oximeter that measures multiple biological information, A means for measuring multiple biological information,

A glance means for generating a grey signal when each of a predetermined number of pieces of biological information has a predetermined relationship with a predetermined warning level;

An audible alarm generating means for generating an audible alarm when at least one alarm signal is squeezed;

The volume level of the warning sound generated from the warning sound generating means is defined as a first volume level having a predetermined volume and a second volume having a volume lower than the first volume level, including a state in which the warning sound is not generated. Volume selection means for selecting from a volume level of

In a situation in which a warning sound at the second volume level is generated, a warning signal is generated for a predetermined time after the warning sound at the second volume level is generated, or a new warning signal is generated. Volume control means for setting the first volume level at a time or when all warning signals are no longer generated,

An oximeter characterized by having:

91. The oximeter according to claim 90, further comprising volume level display means for indicating that the second volume level is selected.

9 2. In an oximeter that measures biological information,

Pulse wave signal detecting means for detecting a pulse wave signal of a living body,

Biological information calculating means for calculating biological information based on the detected pulse wave signal;

A plurality of amplifiers or buffers connected via a circuit including at least a capacitor;

Baseline fluctuation detection means for detecting the fluctuation of the base line of the pulse wave signal, and detecting the fluctuation of the capacitor for a predetermined time when the fluctuation of the base line is detected. Connecting means for connecting the output element to a predetermined voltage;

An oximeter characterized by having:

9 3. In an oximeter that transmits biological information,

A wave signal detecting means for detecting a pulse wave signal of a living body,

Biological information that calculates biological information based on the detected pulse wave signal

Arithmetic means;

At least several indirectly connected via circuits containing capacitors

Amplifier or buffer,

Capacitor output for a predetermined time synchronized with the pulse wave signal

Contact means for contacting a predetermined voltage;

An oximeter characterized by having:

3 4. In an oximeter that measures biological information,

An i-th timer that measures the time during which the detected pulse wave signal is positive

Steps and

Second measure to measure the time when the detected pulse wave signal is negative

Steps and

Pulse wave signal detection means and first * second time measurement means.

A noise remover that performs an operation to remove signal noise; and

An oximeter characterized by having:

9 5. The noise elimination means calculates the integrated value of the positive pulse wave signal and the pulse wave signal.

The percentage of time that is positive, and the integrated value and pulse wave signal of the negative pulse wave signal

The oximeter according to claim 34, further comprising means for calculating a ratio of time when the signal is negative.

9 6. The noise removal means

(Integrated value of positive 脲 wave signal) Z (time when pulse wave signal is positive) ² and

(Integrated value of negative pulse wave signal) Z (time when pulse wave signal is negative) ² and The oximeter according to claim S4, characterized by including means for calculating.

9 7. Rechargeable | In an ozone meter that uses a rechargeable battery as one

First voltage detection means for outputting a first detection signal when an output voltage of the battery falls below a predetermined first detection level;

A second voltage detecting means for outputting a second detection signal when an output voltage of the battery falls below a second detection level lower than the first detection level;

A warning means for issuing a bud in response to the first detection signal;

Power control means for stopping power supply from the battery in response to the second warning signal;

An oximeter characterized by having:

98. A means for warning, wherein the first detection signal provides a visual warning and a warning message and a warning message is issued. The described oximeter.

9 9. In an oximeter system for measuring biological information,

An oximeter body having measurement means for measuring biological information and being connectable to other devices;

A rechargeable battery stored in the

Power supply control means provided in the oximeter main body for charging the battery, supplying power to the measurement means, and supplying power to the device connected to the oximeter main body;

Operating state detecting means for detecting the operating state of the device controlled by the oximeter body;

Charging means for charging the battery; Charging stop means for stopping charging of the battery by the charging means when it is detected that the device connected to the oximeter body is operating;

An oximeter characterized by having:

100. In an oximeter for measuring biological information, a voltage output means for outputting at least one voltage,

Output control means for controlling the output of the voltage output means, including a time constant circuit;

An oximeter characterized by having

101. The oximeter according to claim 97, wherein the voltage output means have different time constants.