DE3908648A1 - Presentation of ultrasonic images - Google Patents

Abstract

Device for the three-dimensional presentation of ultrasonic images, in particular from inside the body of patients (PK), by means of a B scan ultrasonic device (US) whose transducer (TR) is fastened to a guide arm (F). According to the invention, an image-processing computer (R) is provided which generates three-dimensional images or images from any desired sectional planes from the stored images and the corresponding coordinates of the guide arm (F) and represents them on a screen (monitor M). <IMAGE>

Description

The invention relates to a three-dimensional device len representation of ultrasound images, in particular from the inside of patients.

X-ray or ultra are used for image display in medicine sound devices known. Often for spatial representation two devices used. But this is also the exact loading the absolute position of organs in the body is not quite correct easy, because the picture planes or the viewing angles never quite are freely selectable.

The object of the invention is to provide a device with the simple three-dimensional images from be lovely angles or pictures from any cut levels can be generated.

This object is achieved by a Vorrich device with the features of claim 1.

Embodiments of the invention are the subject of sub claims.

In a preferred embodiment, the guide arm is analog angle encoder. An analog-digital converter, which e.g. also in  PC can be integrated, digitizes the measured values. The Guide arm preferably has six degrees of freedom, that is it has 6 independent swivel joints, the stel lungs are registered.

All conventional mass storage devices are suitable as image storage A hard disk with at least 8 Mbytes can be used to be used.

The image processing computer preferably comprises an image processing system with an analog-digital interface for digitalizing the ultrasound images (access to standard video signal), a frame buffer for storing an ultrasound image in real time and an arithmetic logical unit for image processing. A personal computer (PC) , for example, is suitable as a system computer.

The device according to the invention is particularly for Medicine has been developed to produce three-dimensional images of the Preserve the inside of patients or to avoid the abso Determine lute location of organs. This problem occurs e.g. when puncturing or planning treatment on. Also for the representation of stones and other congress elements as well as to represent the area that a shock shaft cone e.g. lithotripsy is suitable the device.

The invention is also suitable for the material testing, e.g. the spatial location of blowholes or Cracks in sonographically diagnosable bodies be communicated. Even the surface analysis of difference materials in a sonogenic environment with the Device possible.

The handling of the device is based on a figure explained in more detail.

The figure schematically shows a patient couch PL with a patient body PK and in this an area of interest, for example a kidney. The guide arm F is attached to the patient bed PL , and the ultrasound transducer TR is located at the tip thereof. This is connected to a known ultrasound device US with a screen (monitor M) . The device according to the invention contains the components image memory BS and computer R , which here consists of an image processing system (BV) and a system computer (PC) . To convert the measurement signals of the guide arm F , an analog-digital converter ADC is easily seen. The positions of the cutting planes are determined in the computer R from the digitized signals of the analog angle transmitters and the known arm constants of the guide arm F.

The device according to the invention will be as follows serves:

To record a three-dimensional image, two-dimensional sectional images are recorded at defined time intervals during a free scanning movement of the transducer TR around the body to be examined (PK) . This means that the ultrasound transducer TR is pressed manually by the doctor or an auxiliary force onto the patient's body PK and swiveled (passes over one or more axes over the body). As a result, ultrasound images of various cutting planes are recorded. The operator observes the generated B-image in real time on the monitor M and only has to pay attention to a consistently good image of the object on the monitor M. The sectional images recorded during the scan movement (swivel movement) are stored in the external image memory BS . With the help of the guide arm F , which contains analog angle encoders, the position of the transducer TR and the position of the scan plane are determined and saved for each sectional image.

Any ultrasound device that has a standard video signal (CCIR, NTSC) can be used to record the ultrasound B-images. In the image processing system BV of the computer R , the image information of each two-dimensional sectional image can be digitized and manipulated in real time, for example using methods known per se for edge detection, contrast enhancement and filtering. These sectional images are stored in the image memory BS .

The three-dimensional image is generated after the completed scan movements from the recorded sectional images and the respective positions of the sectional planes. The position of the cutting plane is calculated by the computer PC from the signals of the analog angle encoder and the arm constants (length of the arm links, angle of rotation of the individual joints, signals of the joints in the calibration position) and saved on the plate with the respective sectional image. The three-dimensional image is calculated in the frame buffer of the image processing system BV and displayed on the monitor M. The viewpoint of the three-dimensional image can be selected and varied by the user. Through the three-dimensional image, any section planes can be placed and displayed on the monitor M.

The image processing system offers further possibilities for Image analysis, e.g. a calculation of the gray value distribution,  Contrast determinations, object recognition or edge detection tion, what all known routines from image processing work, image manipulation (real-time image processing such as image addition or subtraction, multiplication or Division, averaging, logical operations, input and output look-up tables), image measurement (determining Object size) or representations of pseudo colors (wrong color representation).

Claims (7)

1. Device for three-dimensional display of ultrasound images, in particular from inside the patient's body, with

• a B-scan ultrasound device (US) , the transducer (TR) of which is attached to a guide arm (F) , the coordinates (angles, paths) of the individual links to one another are registered,
• an image memory (BS) ,
• - An image processing computer (R) , which generates three-dimensional images or images from any sectional plane from the stored images and the associated coordinates of the guide arm (F) and displays them on a screen (monitor M) .

2. Apparatus according to claim 1, characterized in that the guide arm (F) has analog displacement sensors and analog angle sensors and that an analog-digital converter (ADC) is provided for digitizing the measurement signals of the individual joints. 3. Device according to claim 2, characterized in that the guide arm (F) has six degrees of freedom. 4. Device according to one of the preceding claims, characterized in that the image memory (BS) is a mass memory. 5. Device according to one of the preceding claims, characterized in that the image processing computer (R) an image processing system (BV) with analog-digital interface for digitizing the ultra sound images (access to standard video signal) a frame buffer for storing an ultrasound image in real time and a Arithmetic logical unit for image processing and has a personal computer (PC) as a system computer. 6. Use of a device according to one of the previously going claims in three-dimensional representation of body regions or the determination of the absolute Location of organs in medicine. 7. Use of a device according to one of the previously requirements in material testing.