Liquid crystal optical modulation element, liquid crystal optical modulation ...

1. A liquid crystal spatial light modulator comprising,

a first substrate having multiple individual electrodes,

a second substrate having a common electrode,

a driving circuit driving the individual electrodes, and

a liquid crystal layer held between the first substrate and the second substrate,

the liquid crystal spatial light modulator performing spatial light modulation by applying a predetermined voltage to each of the individual electrodes formed on the first substrate in order to modulate a refractive index of the liquid crystal layer, wherein,

the electrodes formed on the first substrate are segmented into multiple regions including at least a first region and a second region, a mode for applying voltage in one region is made different from another, a wavefront direction is changed in the first region to adjust an optical coupling coefficient on an output side, so as to perform intensity modulation, and light is subjected to phase modulation in the second region, thereby achieving both the intensity modulation and the phase modulation, using only one element, and

wherein, gradient voltage is applied to the first region, and according to the application of the gradient voltage, a gradient is formed in an effective phase difference within the liquid crystal layer of the first region, and according to the gradient in the effective phase difference, the phase of the outgoing light being outputted from the light outputting surface is shifted, thereby adjusting a traveling direction of the outgoing light and adjusting an optical coupling coefficient, so as to perform the intensity modulation, and a predetermined constant voltage is applied to all over the second region, and with the application of the constant voltage, an effective phase difference is formed within the liquid crystal layer of the second region, and according to the effective phase difference, the phase of the outgoing light outputted from the light outputting surface is adjusted homogeneously within the region, so as to perform the phase modulation of the outgoing light.

2. The liquid crystal spatial light modulator according to claim 1, wherein,

as to a maximum phase difference φmax of the effective phase difference and a maximum usable light wavelength λmax being subjected to the spatial light modulation, there is a relationship of φmax≧2π.

3. The liquid crystal spatial light modulator according to claim 2, wherein,

as to a thickness dmax of the liquid crystal layer, there is a relationship of dmax>λmax/Δnmax (where Δnmax represents a maximum effective birefringence of liquid crystal, and λmax represents the maximum usable light wavelength).

4. A liquid crystal spatial light modulator comprising,

a first substrate having multiple individual electrodes,

a second substrate having a common electrode,

an driving circuit driving the individual electrodes, and

a liquid crystal layer held between the first substrate and the second substrate,

the liquid crystal spatial light modulator performing spatial light modulation by applying a predetermined voltage to each of the individual electrodes formed on the first substrate in order to modulate a refractive index of the liquid crystal layer, wherein,

as to a thickness d of the liquid crystal layer, there is a relationship of mλmax/Δnmax

a voltage obtained by adding a bias voltage being a constant voltage to a gradient voltage, is applied to the electrodes formed on the first substrate,

a gradient is formed in an effective phase difference within the liquid crystal layer by the application of the gradient voltage, the phase of outgoing light outputted from the light output surface is shifted within the region according to the gradient of the effective phase difference, and a wavefront direction is changed, thereby adjusting an optical coupling coefficient on the output side to perform intensity modulation,

the bias voltage being a predetermined constant voltage is applied to form a constant effective phase difference within the liquid crystal layer,

the phase of the outgoing light outputted from the light output surface is adjusted homogeneously within the region according to the constant effective phase difference, thereby performing phase modulation of the outgoing light, and then both the intensity modulation and the phase modulation are performed, using only one element.

5. The liquid crystal spatial light modulator according to claim 1, wherein, one-dimensional array is taken for arranging the multiple individual electrodes in an array direction of the region, or two-dimensional array is taken for arranging the multiple individual electrodes in a first array direction of the region and in a second array direction being orthogonal to the first array direction.

6. A liquid crystal spatial light modulator module comprising,

an input port for inputting incident light,

an output port for outputting outgoing light,

the liquid crystal spatial light modulator according to claim 1,

a first collimator for inputting the incident light from the input port into the liquid crystal spatial light modulator in a form of a parallel light, and

a second collimator for coupling the light from the liquid crystal spatial light modulator and outputting the coupled light in a form of parallel light to the output port.

7. The liquid crystal spatial light modulator module according to claim 6, wherein,

an optical fiber constitutes at least one of the first collimator and the second collimator.

8. The liquid crystal spatial light modulator module according to claim 6, wherein, a first polarization converting element is provided between the first collimator and the liquid crystal spatial light modulator, for converting one polarization direction by 90 degrees, and a second polarization converting element is provided between the liquid crystal modulation element and the second collimator, for resuming the polarization direction being converted.

9. The liquid crystal spatial light modulator module according to claim 6, wherein, a first polarization converting element is provided between the input port and the first collimator, for converting one polarization direction by 90 degrees, and a second polarization converting element is provided between the second collimator and the output port, for resuming the polarization direction being converted.

10. The liquid crystal spatial light modulator module according to claim 6, wherein, the number of the second collimator being provided is more than one.

11. The liquid crystal spatial light modulator module according to claim 10, wherein, the first collimator and the second collimator are Thermally-diffused Expanded Core (TEC) fibers.

12. The liquid crystal spatial light modulator module according to claim 10, wherein, the first collimator and the second collimator are glass lenses directly fusion-bonded to the optical fibers.

13. The liquid crystal spatial light modulator module according to claim 6, wherein, multiple optical fibers are provided instead of the second collimator.

14. The liquid crystal spatial light modulator module according to claim 13, wherein, at least a part of the first substrate or the second substrate is bonded to and fixed on a thermoelectric conversion element by using metal or resin, and when voltage of an identical profile is applied, a wavelength-converted phase fluctuation of the liquid crystal layer, caused by environmental temperature variation, is controlled to be equal to or less than λ/10 of the maximum usable light wavelength.

15. The liquid crystal spatial light modulator module according to claim 6 to, wherein, a spectrometer is provided on an optical path in front of or in the rear of the liquid crystal spatial light modulator and the spatial light modulation can be performed with respect to each wavelength that is spectrally distributed by the spectrometer.

16. The liquid crystal spatial light modulator module according to claim 15, wherein, multiple individual electrodes are arranged in a two-dimensional array where the electrodes are arranged in a first array direction of the region and in a second array direction being orthogonal to the first array direction, and a wavelength spectrally distributed by the spectrometer is allowed to enter the second array direction.

17. A method for driving the liquid crystal spatial light modulator according to claim 1, wherein, multiple individual electrodes are integrated into multiple groups, the individual electrodes within each of the groups are connected by a collector electrode being common, both ends of the collector electrode being connected to a pair of signal electrodes, respectively, in the group associated with the first region, drive waveforms of voltage being different from each other are applied to the pair of the signal electrodes, respectively, thereby forming a gradient voltage in the first region, and in the group associated with the second region, a drive waveform of identical voltage is applied to the pair of the signal electrodes, thereby applying a predetermined constant voltage to the second region.

18. A method for driving the liquid crystal spatial light modulator according to claim 4, wherein, multiple individual electrodes are integrated into multiple groups, multiple individual electrodes within each of the groups are connected by a collector electrode being common, and both ends of the collector electrode are connected to a pair of signal electrodes, respectively, and a bias voltage of a constant voltage is added to drive waveforms of voltage being different respectively for the pair of the signal electrodes, thereby forming a gradient potential on a constant electric potential.