Classifications

• • G—PHYSICS
  • G02—OPTICS
  • G02F—OPTICAL DEVICES OR ARRANGEMENTS FOR THE CONTROL OF LIGHT BY MODIFICATION OF THE OPTICAL PROPERTIES OF THE MEDIA OF THE ELEMENTS INVOLVED THEREIN; NON-LINEAR OPTICS; FREQUENCY-CHANGING OF LIGHT; OPTICAL LOGIC ELEMENTS; OPTICAL ANALOGUE/DIGITAL CONVERTERS
  • G02F1/00—Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulating; Non-linear optics
  • G02F1/01—Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulating; Non-linear optics for the control of the intensity, phase, polarisation or colour 
  • G02F1/13—Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulating; Non-linear optics for the control of the intensity, phase, polarisation or colour  based on liquid crystals, e.g. single liquid crystal display cells
  • G02F1/1313—Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulating; Non-linear optics for the control of the intensity, phase, polarisation or colour  based on liquid crystals, e.g. single liquid crystal display cells specially adapted for a particular application
• • G—PHYSICS
  • G02—OPTICS
  • G02F—OPTICAL DEVICES OR ARRANGEMENTS FOR THE CONTROL OF LIGHT BY MODIFICATION OF THE OPTICAL PROPERTIES OF THE MEDIA OF THE ELEMENTS INVOLVED THEREIN; NON-LINEAR OPTICS; FREQUENCY-CHANGING OF LIGHT; OPTICAL LOGIC ELEMENTS; OPTICAL ANALOGUE/DIGITAL CONVERTERS
  • G02F1/00—Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulating; Non-linear optics
  • G02F1/29—Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulating; Non-linear optics for the control of the position or the direction of light beams, i.e. deflection
  • G02F1/292—Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulating; Non-linear optics for the control of the position or the direction of light beams, i.e. deflection by controlled diffraction or phased-array beam steering

Definitions

• LIQUID CRYSTAL LIGHT MODULATION ELEMENT LIQUID CRYSTAL LIGHT MODULATION DEVICE, AND DRIVING METHOD FOR LIQUID CRYSTAL LIGHT MODULATION ELEMENT
• the present invention relates to a liquid crystal light modulation device, a liquid crystal light modulation device provided with the liquid crystal light modulation device, and a method for driving the liquid crystal light modulation device constituting the liquid crystal light modulation device.
• An optical clock multiplexer (Optical Clock Multiplexer) is used to multiply a low-speed optical clock signal in an optical time division multiplexing (OTDM) system for optical communication.
• ODM optical time division multiplexing
• an optical carrier pulse of 10 GHz is divided into two systems, and each optical carrier pulse of each system is modulated by a data signal of 10 Gbit / second, for example.
• One of the two modulated carrier pulse waves is given a half-period ( ⁇ ) phase difference compared to the other modulated carrier pulse wave, for example, and then the modulated carrier pulse is synthesized.
• ⁇ half-period
• optical clock carrier wave
• the components of the optical clock multiplexer used for high-speed clock synthesis for ultra-high-speed optical time-division multiplexing include the smoothing of the clock signal strength after synthesis, and the minute phase that accompanies changes in the temperature of the clock multiplexer itself and external devices. Since it is very important to make the clocks equally spaced by correcting the deviation, it is necessary to correct the peak value and phase of the optical clock using an optical modulator.
• FIG. 36 is a diagram for explaining a configuration example for realizing an optical clock multiplexer for optical time division multiplexing.
• the optical clock multiplexer 100 includes an optical input port 102 and an output port 103.
• An optical signal input from the input port 102 is separated by the optical coupling / separation device 104.
• One of the separated optical signals is modulated by an optical modulator 101, the other optical signal is passed through a fixed delay device 106 with a fixed delay amount, and both optical signals are combined by an optical coupling separator 105.
• the optical signal combined by the optical coupler / separator 105 is output from the output port 103.
• the intensity of the optical signal And the phase amount are adjusted to multiply the optical clock used for optical time division multiplexing.
• FIG. 37 shows an example of an optical modulator used for wavelength division multiplexing using liquid crystal elements.
• This optical modulator for example, Patent Document 1 is known.
• This optical modulator is applied to R_OADM (Reconfigurable Optical Add / Drop Multiplexer).
• FIG. 37 shows a reflection type configuration example
• FIG. 37 (a) shows the z-y plane
• FIG. 37 (b) shows the x-z plane.
• An optical modulator 200 includes a spectroscope 202 (here, a diffraction grating) and an optical path between an input signal beam including a plurality of wavelengths and an input / output port 201 that outputs an output signal beam.
• An OPMC (Optical Phased Matrix Coupling) 203 is placed through cylindrical lenses 211, 212, and 213 that form parallel light.
• Patent Document 1 US Patent Publication 2006 / 0067611A1
• Patent Document 2 JP-A-6-51340 (paragraphs 0010, 0017, 0018)
• optical time division multiplexing method and the hybrid transmission method of wavelength division multiplexing and optical time division multiplexing have made use of the wide bandwidth available for optical fibers.
• intensity modulation and phase modulation of an optical signal are conventionally performed by individual adjustment devices.
• Patent Document 2 discloses that an optical addressing spatial modulator has a phase modulation element using liquid crystal and an intensity using liquid crystal by combining the phase modulation element with a polarizer. modulation The example which comprises an element is shown separately.
• FIG. 38 is a diagram schematically illustrating a configuration example of the optical modulation device disclosed in Patent Document 2, and is a schematic diagram for explaining a configuration example of an optical address type spatial light modulator.
• an optical addressing spatial modulator 300 includes an optical modulator (SLM) 301 composed of optically addressable phase modulation elements, and a phase that compensates the phase of the entire effective surface by an applied voltage.
• a compensator 302 composed of a modulation element is arranged on the optical path of the readout light.
• An optical modulator (SLM) 301 adjusts the phase pattern of the readout light with the address light, and a compensator 302 adjusts the overall phase of the readout light.
• the phase-modulated light passes through the polarizer 203 and is output as intensity-modulated light corresponding to the address light writing pattern.
• the optical modulator (SLM) 301 and the compensator 302 are configured as individual devices so that the alignment directions of the liquid crystals coincide with each other, and these devices are arranged on the optical path.
• an independent modulation element is prepared for each of the phase element for writing the optical pattern by the address light and the element for performing the overall phase modulation, These modulation elements are arranged in order on the optical path, and then the phase modulation amount is converted into intensity modulation by a polarizer.
• the phase modulation for performing the phase modulation and the intensity modulation element in which the polarizer is combined with the phase element having the same structure as the element since the intensity modulation can be converted using the phase modulation element, the phase modulation for performing the phase modulation and the intensity modulation element in which the polarizer is combined with the phase element having the same structure as the element.
• a configuration is possible in which each is prepared and arranged in order on the optical path. In this case, there is necessary to individually prepare elements that realize the respective functions (intensity modulation and phase modulation).
• the intensity modulation element for realizing the function of intensity modulation and the phase modulation element for realizing the function of phase modulation are provided, and these elements are arranged on the optical path, the number of elements increases. In addition to this problem, there is a problem that the chance of attenuation of signal intensity due to connection of each element to the optical path and a complicated phase shift that occurs during intensity modulation operation increases.
• the present invention solves the above-described problems, and adjusts both intensity modulation and phase modulation of an optical signal in a liquid crystal light modulation device, a liquid crystal light modulation device, and a liquid crystal light modulation device driving method.
• the purpose is to realize the function with one element.
• the present invention relates to a liquid crystal light modulation device for adjusting an optical signal, wherein at least one region is divided into two in one device, intensity modulation is performed in one region, and phase modulation is performed in the other region. It is to be configured. According to this configuration, since the region for intensity modulation and the region for phase modulation can be formed by dividing the region of one liquid crystal light modulation element, both the intensity modulation and the phase modulation of the optical signal are performed.
• the adjustment function can be realized individually with one element.
• the present invention can be applied to the second aspect of voltage application.
• a bias potential is formed in the liquid crystal layer of one element in addition to the gradient potential, and the coupling coefficient on the emission side is modulated by the gradient potential.
• intensity modulation is performed, and phase modulation is performed using a bias potential.
• the intensity modulation region and the phase modulation can be performed by adjusting the voltage distribution in the liquid crystal layer of one liquid crystal light modulation element, both the intensity modulation and the phase modulation of the optical signal are performed.
• the adjustment function can be realized with a single element.
• both the first and second voltage application modes described above can realize both the optical signal intensity modulation and phase modulation adjustment functions with a single element.
• the present invention has a plurality of forms such as a liquid crystal light modulation element, a liquid crystal light modulation device including the liquid crystal light modulation element, and a driving method for driving the liquid crystal light modulation element.
• Power S can be.
• the force is applied by applying the! / And deviation modes of the first mode of voltage application to the two regions and the second mode of voltage application to which a bias potential is applied.
• the liquid crystal light modulation element of the present invention includes a first substrate having a plurality of individual electrodes, a second substrate having a common electrode, and a liquid crystal sandwiched between the first substrate and the second substrate. A layer.
• This liquid crystal light modulation element has a configuration of a reflective liquid crystal light modulation element that returns emitted light to the incident light side, and a structure of a transmissive liquid crystal light modulation element that emits light without changing the emission direction. That's the power S.
• the reflective liquid crystal light modulation element has a first substrate as a transparent substrate, a second substrate as an opaque substrate, a second opaque substrate as a reflective surface, and light incident from the first substrate as a second substrate.
• the liquid crystal layer is made to reciprocate by being reflected by the substrate, and emitted from the first substrate, and intensity modulation and phase modulation are performed while incident light reciprocates through the liquid crystal layer.
• Another aspect of the reflective liquid crystal light modulation element is that light incident from the second substrate with the first substrate being an opaque substrate, the second substrate being a transparent substrate, and the first substrate being a reflecting surface. Is reflected by the first substrate to reciprocate the liquid crystal layer to be emitted from the second substrate, and intensity modulation and phase modulation are performed while the incident light reciprocates through the liquid crystal layer.
• the transmissive liquid crystal light modulation element uses the first substrate as a transparent substrate, the second substrate as a transparent substrate, and transmits light incident from the first substrate through the liquid crystal layer.
• the light is emitted from the second substrate, and intensity modulation and phase modulation are performed while the incident light passes through the liquid crystal layer.
• the liquid crystal light modulation element of the present invention performs light modulation by modulating the refractive index of the liquid crystal layer by applying a predetermined voltage to each individual electrode formed on the first substrate.
• the electrode formed on the first substrate is divided into at least two regions, the voltage application mode is different for each region, the intensity of light is modulated in the first region, and the second region is subjected to intensity modulation. Then, by modulating the phase of light, intensity modulation and phase modulation are performed by one element.
• a gradient voltage is applied to the first region, and a gradient is formed in the effective phase difference in the liquid crystal layer of the first region by applying the gradient voltage.
• a gradient is formed in the effective phase difference in the liquid crystal layer in the first region, the phase of the emitted light is shifted in the region, and a difference occurs in the time for the optical signal to move in the liquid crystal layer. Therefore, when the wavefront incident in parallel to the incident light surface of the liquid crystal light modulation element is emitted from the outgoing light surface, the direction in which the wavefront travels changes, and the traveling direction of the outgoing light changes.
• the coupling coefficient force to the optical coupling system provided on the outgoing side is reduced, so the light intensity of the outgoing light is attenuated with respect to the light intensity of the incident light, and thereby the optical signal Intensity modulation is performed.
• a predetermined constant voltage is applied to the entire second region, and a uniform effective phase difference is formed in the liquid crystal layer in the region by applying this constant voltage.
• the effective phase difference formed in the liquid crystal layer that modulates the phase of the emitted light changes the amount of optical delay emitted from the emission surface in order to control the movement time or phase of the light passing through the liquid crystal layer. As a result, the emitted light Is phase-modulated.
• the maximum phase difference [Phi Paiiotaipushiron'iotakai the effective phase difference of the liquid crystal layer is to have a relationship of ⁇ ⁇ ⁇ ⁇ 2 ⁇ at the maximum wavelength e max use of light for performing optical modulation. This relationship enables phase modulation for at least one wavelength while light passes through the liquid crystal layer.
• the phase difference exceeding one wavelength has periodicity, so the phase corresponding to a plurality of wavelengths can be adjusted by resetting each wavelength.
• ⁇ is the effective birefringence of the liquid crystal
• Anmax is the effective maximum birefringence of the liquid crystal
• ⁇ is the wavelength
• ⁇ max is the maximum wavelength used. Therefore, the thickness d of the liquid crystal layer can be determined by the effective maximum birefringence index Anmax of the liquid crystal constituting the liquid crystal device and the maximum wavelength of light used.
• the liquid crystal light modulation element of the present invention includes a first substrate having a plurality of individual electrodes, a second substrate having a common electrode, a first substrate, and a second substrate. And a liquid crystal layer sandwiched between the substrate and a light source to modulate the refractive index of the liquid crystal layer by applying a predetermined voltage to each individual electrode formed on the first substrate.
• the effective maximum birefringence of the liquid crystal is An max
• the maximum wavelength used is max
• m is an integer
• the thickness d of the liquid crystal layer is m max / An max ⁇ d.
• the intensity modulation is performed by applying a voltage obtained by adding a constant bias voltage to the gradient voltage to the electrode formed on the first substrate, and applying the gradient voltage to the effective level in the liquid crystal layer.
• the wavefront control of the outgoing light is performed and the traveling direction is adjusted, This is done by adjusting the coupling coefficient of the optical coupling system provided on the emission side.
• the phase modulation forms a constant effective phase difference in the liquid crystal layer by applying a bias voltage having a predetermined constant voltage, and is emitted from the outgoing light surface by this constant effective phase difference.
• a bias voltage having a predetermined constant voltage
• Phase-modulate the light By adjusting the phase of the emitted light uniformly within the region, Phase-modulate the light. Thereby, intensity modulation and phase modulation are performed by one element.
• the liquid crystal light modulation element of the second aspect includes a configuration of a reflective liquid crystal light modulation element that returns emitted light to the incident light side, and a structure of a transmissive liquid crystal light modulation element that emits light without changing the emission direction.
• the reflective liquid crystal light modulation element uses the first substrate as a transparent substrate, the second substrate as an opaque substrate, the second substrate as a reflection surface, and the light incident from the first substrate as the second substrate. Reflecting on the substrate causes the liquid crystal layer to reciprocate and exit from the first substrate, and intensity modulation and phase modulation are performed while the incident light reciprocates through the liquid crystal layer.
• the thickness d of the liquid crystal layer is set to max / A nmax ⁇ d, where m is 1.
• the first substrate is an opaque substrate
• the second substrate is a transparent substrate
• m is 1
• the first substrate is a reflective surface
• the light incident from the second substrate is reflected by the first substrate to reciprocate the liquid crystal layer to be emitted from the second substrate, and intensity modulation and phase modulation are performed while the incident light reciprocates through the liquid crystal layer.
• the transmissive liquid crystal light modulation element uses the first substrate as a transparent substrate, the second substrate as a transparent substrate, and transmits light incident from the first substrate through the liquid crystal layer. The light is emitted from the second substrate, and intensity modulation and phase modulation are performed while the incident light passes through the liquid crystal layer.
• the thickness d of the liquid crystal layer is 2 ⁇ max / ⁇ nmax ⁇ d, where m is 2.
• the liquid crystal light modulation element includes individual electrodes that drive the liquid crystal, and the plurality of individual electrodes are arranged in a one-dimensional arrangement in which the regions are arranged in the arrangement direction, or the first arrangement direction and the first arrangement direction of the regions.
• a two-dimensional array arranged in the second array direction orthogonal to each other can be used.
• the liquid crystal light modulation device of the present invention includes the above-described liquid crystal light modulation device of the present invention, and includes an incident port for entering incident light, an output port for emitting outgoing light, A first collimator element that is incident on the liquid crystal light modulation element as parallel light from the incident port, and a second collimator that combines the light from the liquid crystal light modulation element and emits the parallel light to the emission port.
• At least one of the first collimator element and the second collimator element can be replaced with an optical fiber.
• the liquid crystal light modulation element and the second liquid crystal light modulation element A second polarization conversion element for returning to the polarization direction of the converted polarized light can be provided between the collimator element and the collimator element.
• a first polarization conversion element that converts the polarization direction of one polarization by 90 ° is provided between the incident port and the first collimator element, and between the second collimator element and the emission port, A second polarization conversion element for returning to the polarization direction of the converted polarized light can be provided.
• a plurality of second collimator elements on the emission side can be provided, and light whose traveling direction has been changed by wavefront control can be distributed in the liquid crystal light modulation element.
• the first collimator element and the second collimator element can be a core expansion fiber, or a glass lens fused directly to the optical fiber. Further, a plurality of optical fibers can be used in place of the second collimator element.
• the liquid crystal light modulation element is a liquid crystal layer formed by a change in environmental temperature when at least a part of the first or second substrate is bonded and fixed to a thermoelectric conversion element by metal or resin and the same voltage profile is applied. Control so that the phase fluctuation in terms of wavelength is less than ⁇ / 10 of the maximum wavelength used.
• a configuration in which a spectroscope is provided on the optical path before and after the liquid crystal light modulation element may be used, and light modulation can be performed for each wavelength split by the spectroscope.
• the liquid crystal light modulation element has a two-dimensional arrangement in which the plurality of individual electrodes are arranged in a second arrangement direction orthogonal to the first arrangement direction of the region and the first arrangement direction.
• the wavelength split by the spectroscope can be incident in the arrangement direction. With this two-dimensional arrangement, intensity modulation and phase modulation can be performed for each wavelength.
• the plurality of individual electrodes are grouped into a plurality of groups, and the plurality of individual electrodes in each group are connected by a common collector electrode.
• a pair of signal electrodes are connected to both ends of the collector electrode, and in the group corresponding to the first region, a drive waveform of a different voltage is applied to the pair of signal electrodes, respectively, to the first region.
• a predetermined voltage is applied to the second region by applying a drive waveform of the same voltage to the pair of signal electrodes in the group corresponding to the second region. Apply a constant voltage.
• the second form can be used for driving.
• the plurality of individual electrodes are grouped into a plurality of groups, and each of the plurality of individual electrodes in each group is connected by a common collector electrode, and a pair of signal electrodes are provided at both ends of the collector electrode.
• a gradient electric potential is formed at a constant potential by connecting and applying a bias voltage of a constant voltage to a pair of signal electrodes to drive waveforms of different voltages.
• both optical signal intensity modulation and phase modulation adjustment functions can be realized by a single device.
• FIG. 1 is a diagram for explaining a schematic configuration and functions of a liquid crystal light modulation device of the present invention.
• FIG. 2 is a diagram for explaining a schematic configuration and functions of a reflective liquid crystal light modulation element of the present invention.
• FIG. 3 is a cross-sectional view showing the structure of the liquid crystal light modulation device of the present invention.
• FIG. 4 is a schematic diagram for explaining a first mode of light modulation (phase modulation and intensity modulation) by a liquid crystal light modulation element.
• FIG. 5 is a schematic diagram for explaining a second mode of light modulation (phase modulation and intensity modulation) by a liquid crystal light modulation element.
• FIG. 6 is a diagram for explaining a schematic configuration of a liquid crystal light modulation device 10A according to the present invention.
• FIG. 7 is a diagram showing a wavefront state seen from the side surface direction of the liquid crystal light modulation device 10 A of the present invention.
• FIG. 8 is a diagram showing a wavefront state of the liquid crystal light modulation device 10A according to the present invention as viewed from the upper surface direction.
• FIG. 9 is a diagram showing a wavefront state of the liquid crystal light modulation device 10A according to the present invention viewed from the upper surface direction.
• FIG. 10 is a diagram showing an equivalent optical path position of the liquid crystal light modulation device 10A of the present invention.
• FIG. 11 is a diagram for explaining a configuration in which incident light having a uniform polarization direction is input to an input port.
• FIG. 12 is a diagram for explaining a schematic configuration of a liquid crystal light modulation device 10B according to the present invention.
• FIG. 13 is a diagram showing a wavefront state of the liquid crystal light modulation device 10B according to the present invention as seen from the upper surface direction and the side surface direction.
• a diagram for explaining a schematic configuration of a liquid crystal light modulation device 10C of the present invention A diagram showing a wavefront state of the liquid crystal light modulation device 10C according to the present invention as seen from the upper surface direction and the side surface direction.
• FIG. 17 is a diagram for explaining a schematic configuration of a liquid crystal light modulation device 10D of the present invention.
• FIG. 18 is a diagram showing a wavefront state of the liquid crystal light modulation device 10D of the present invention as viewed from the top surface direction and the side surface direction.
• FIG. 19 is a diagram showing a configuration example of a two-dimensional liquid crystal light modulation device of the present invention.
• FIG. 20 is a diagram for explaining a reflection type configuration example of a liquid crystal light modulation device of the present invention.
• FIG. 21] is a diagram for explaining a reflection type configuration example of the liquid crystal light modulation device of the present invention.
• FIG. 22 is a diagram for explaining a configuration example of a TEC.
• FIG. 23 is a diagram for explaining a configuration example of a liquid crystal light modulation device of the present invention.
• FIG. 25 is an explanatory diagram showing the operation principle of the liquid crystal light modulation device of the present invention.
• FIG. 26 is a diagram for explaining the structure of the first composite electrode for forming the blazed diffraction grating of the liquid crystal light modulation element 1.
• FIG. 27 is a diagram for explaining a driving method of a liquid crystal light modulation element having a first composite electrode.
• FIG. 29 is a schematic diagram showing a phase distribution of a liquid crystal light modulation device of the present invention.
• FIG. 30 A diagram showing a waveform application period to signal electrode terminals arranged in one element grating.
• FIG. 30 is a diagram for explaining another structure of a composite electrode for forming a blazed diffraction grating. is there.
• FIG. 32 is a plan view showing the relationship between the first active region and the third composite electrode for realizing a blazed diffraction grating.
• FIG. 33 is a diagram for explaining a method of realizing an arbitrary deflection angle.
• FIG. 34 is a diagram for explaining a configuration example in which the liquid crystal light modulation device of the present invention is applied to an optical clock multiplier.
• FIG. 35 is a diagram for explaining light intensity modulation and phase modulation by VOAD11.
• FIG. 36 is a diagram for explaining a configuration example for realizing optical time division multiplexing.
• FIG. 37 is a diagram for explaining an example of an optical modulator using a liquid crystal element.
• FIG. 38 is a schematic diagram for explaining a configuration example of an optical address type spatial light modulator.
• liquid crystal light modulation device and the liquid crystal light modulation device of the present invention will be described in detail with reference to the drawings.
• FIG. 1 is a diagram for explaining a schematic configuration and functions of a transmissive liquid crystal light modulation device of the present invention.
• FIG. 1 (a) shows a schematic configuration of the liquid crystal light modulation element
• FIGS. 1 (b) and 1 (c) show the phase modulation and intensity modulation functions of the liquid crystal light modulation element.
• a liquid crystal light modulation element 1 has a schematic configuration in which a liquid crystal layer la is sandwiched between a first electrode lb and a second electrode lc, and light input from an input port 2
• Output port 3 (3a) has a function to adjust the phase of the signal and a function to adjust the intensity of the optical signal, and phase modulation or intensity modulation, or both phase modulation and intensity modulation adjustment.
• the intensity modulation is to adjust the intensity by attenuating the intensity of the input optical signal, and constitutes an optical attenuator (ATT).
• Phase modulation adjusts the phase by delaying the phase of the input optical signal, and constitutes a phase shifter.
• FIG. 1 (b) is a diagram for explaining the phase modulation function.
• the liquid crystal light modulation element 1 performs phase modulation by delaying the phase of the optical signal input from the input port 2. To output from output port 3.
• FIG. 1 (c) is a diagram for explaining the function of intensity modulation.
• the liquid crystal light modulation element 1 changes the traveling direction by deflecting the optical signal input from the input port 2, Intensity modulation is performed by attenuating the light amount of the optical signal coupled to output port 3. Note that the optical signal whose traveling direction is changed by the liquid crystal light modulating element 1 may be discarded or output to another output port 3.
• the optical signal input from input port 2 is output by liquid crystal light modulation element 1.
• the liquid crystal light modulation element 1 of the present invention adjusts the voltage applied to the first electrode lb, performs phase modulation by forming a constant potential in the liquid crystal layer la, and applies a gradient potential to the liquid crystal layer la.
• the intensity modulation is performed by changing the wavefront direction and adjusting the optical coupling coefficient on the output side.
• the liquid crystal light modulation element 1 of the present invention has been described with a configuration in which a plurality of individual electrodes are formed and the second electrode lc is used as a common electrode in order to apply a predetermined voltage profile to the first electrode lb.
• the first electrode lb may be a common electrode
• the second electrode lc may be a plurality of individual electrodes for applying a predetermined voltage profile.
• FIG. 2 is a diagram for explaining the schematic configuration and function of the reflective liquid crystal light modulation element of the present invention.
• FIG. 2 (a) shows the schematic configuration of the liquid crystal light modulation element
• FIGS. 2 (b) and 2 (c) show the phase modulation and intensity modulation functions of the liquid crystal light modulation element.
• the liquid crystal light modulation element 1 has the liquid crystal layer la sandwiched between the first electrode lb and the second electrode lc, and the second electrode lc is formed on the opaque substrate.
• the function of adjusting the phase of the optical signal input from the input port 2 and the function of adjusting the intensity of the optical signal are the same as in the transmission type light modulation element described above. And outputs an optical modulation signal that has undergone phase modulation or intensity modulation, or both phase modulation and intensity modulation, from input port 2 (2a to 2c).
• the intensity modulation adjusts the intensity by attenuating the intensity of the input optical signal and constitutes an optical attenuator (ATT).
• Phase modulation adjusts the phase by delaying the phase of the input optical signal, and constitutes a phase shifter.
• FIG. 2 (b) is a diagram for explaining the function of phase modulation.
• the liquid crystal light modulation element 1 uses the phase of the optical signal input from the input port 2 while reciprocating through the liquid crystal layer la. Delay Phase modulation and return to the input port 2 side.
• FIG. 2 (c) is a diagram for explaining the function of intensity modulation.
• the liquid crystal light modulation element 1 deflects while the optical signal input from the input port 2 reciprocates in the liquid crystal layer la. By changing the direction of travel, the light intensity of the optical signal coupled to input port 2 is attenuated to modulate the intensity.
• the optical signal whose traveling direction has been changed by the liquid crystal light modulation element 1 may be discarded or output to another input port 2.
• the liquid crystal light modulation element 1 can also be used as a switching element or a signal switching element that changes the input / output relationship when an optical signal input from the input port 2 is output to the input port 2 side.
• the voltage applied to the first electrode lb is adjusted to form a constant potential in the liquid crystal layer la.
• intensity modulation is performed by forming a gradient potential in the liquid crystal layer la, changing the wavefront direction, and adjusting the optical coupling coefficient on the emission side.
• the reflective liquid crystal light modulation element 1 has a plurality of individual electrodes for applying a predetermined voltage profile to the first electrode lb, and the second electrode lc is used as a common electrode.
• lb may be a common electrode
• the second electrode lc may be a plurality of individual electrodes for applying a predetermined voltage profile.
• LCOS liquid crystal on silicon
• FIG. 3 is a cross-sectional view showing the structure of the liquid crystal light modulation device of the present invention.
• the nematic liquid crystal layer II shown as an example of the liquid crystal layer includes an alignment layer 1D formed on the composite electrode 1C of the first transparent substrate 1B of the liquid crystal light modulation element 1, and a second transparent substrate 1H.
• the alignment layer 1F formed on the common electrode 1G is homogeneous so that the pretilt angle of the director 1E of p-type (positive) liquid crystal molecules is constant (usually less than 5 degrees from the substrate plane) when no electric field is applied. Orient.
• Fig. 3 (a) is an example of horizontal alignment (homogeneous alignment), in which incident polarized light is parallel to the array direction of the composite electrode 1C and parallel to the plane on which the director 1E moves by applying an electric field.
• Fig. 3 (b) shows an example of vertical alignment (homeotope pick alignment). An example is shown in which the director IE is parallel to the array direction of the electrode 1C and parallel to the plane on which the director IE moves when an electric field is applied.
• the configuration of Fig. 3 (b) is the same as the configuration of Fig. 3 (a) except that the nematic liquid crystal layer is n-type (negative type) and the initial orientation of director 1E is made perpendicular to transparent substrate 1B and transparent substrate 1H. It is.
• an obliquely deposited SiO film may be used for the alignment layer ID and IF to have a certain pretilt angle (usually 14 degrees or less from the substrate normal).
• the first transparent substrate 1B and the second transparent substrate 1H are connected to each other so that the nematic liquid crystal layer II maintains a predetermined constant thickness of several m to several tens of m. Secure through.
• tantalum pentoxide (Ta 2 O 3) or silicon dioxide is formed on at least one of the composite electrode 1C and the common electrode 1H to prevent the composite electrode 1C and the common electrode 1G from being short-circuited.
• a transparent insulating film such as (SiO 2) or silicon nitride (SiN) may be formed.
• the common electrode 1G formed on the second transparent substrate 1H may be a full-surface electrode made of a transparent conductive film.
• the structure of the composite electrode 1C will be described later.
• the film thickness is set to 50 nm or less, and the wavelength used is in the near infrared region.
• a thin film such as indium oxide (In 2 O 3), tin oxide (SnO 2), zinc oxide (ZnO), or titanium-added indium oxide (InTiO) can be used as the transparent conductive film.
• the antireflective coating 1A can be applied with a force S by using a coating made of a dielectric multilayer film of tantalum pentaoxide (Ta 2 O 3) and silicon dioxide (SiO 2), for example.
• a composite electrode 1C or a common electrode 1G may be formed on a first transparent substrate IB or a second transparent substrate 1H, although a refractive index matching layer is provided.
• the polarization direction (p-polarized light or s-polarized light) of the output light output is determined according to the relationship between the direction of the director 1E of the nematic liquid crystal layer II and the incident linearly polarized light. Therefore, it is important to adjust the incident linearly polarized light so that it is parallel to the direction of the crystal axis when applying a voltage that increases the anisotropy of the nematic liquid crystal layer II.
• FIG. 4 is a schematic diagram for explaining a first mode of light modulation (phase modulation and intensity modulation) by a liquid crystal light modulation element
• FIG. 5 is a diagram illustrating light modulation (phase modulation by a liquid crystal light modulation element).
• FIG. 6 is a schematic diagram for explaining a second mode of modulation and intensity modulation.
• Light modulation is performed by modulating the refractive index of the liquid crystal layer by applying a predetermined voltage to each individual electrode formed on the first transparent substrate of the liquid crystal light modulation element.
• This voltage application can be performed in two forms.
• the electrode formed on the first transparent substrate is divided into two regions, the voltage application state to each region is different, the light is phase-modulated in the first region, and the second region By modulating the intensity of light in the region, phase modulation and intensity modulation are performed with a single element.
• the horizontal axis is the direction in which the plurality of electrodes 1C formed on the first transparent substrate of the liquid crystal light modulation element are arranged.
• Area A and second area B are divided into two areas.
• the first area A and the second area B are each represented by one continuous area, but each area that does not necessarily need to be one continuous area may be divided into a plurality of parts. This includes what is actually divided into two parts.
• the vertical axis represents the thickness direction of the liquid crystal layer
• the solid line represents the phase modulation amount ⁇ and the refractive index anisotropy ⁇ ⁇ generated in the liquid crystal layer
• the one-dot chain line arrow is incident on the liquid crystal layer
• Light cl (Fig. 4 (a)), dl (Fig. 4 (b)) and outgoing light c2, c3 (Fig. 4 (a)), d2, d3 (Fig. 4 (b)) emitted from the liquid crystal layer Represents the ray direction!
• phase modulation amount ⁇ 2 ⁇ between the phase modulation amount ⁇ and the refractive index anisotropy ⁇ , where ⁇ is the wavelength of light passing through the liquid crystal layer and d is the thickness of the liquid crystal layer.
• ⁇ ⁇ -d / e the maximum effective modulation phase amount ⁇ 3 ⁇ 3 ⁇ 42 ⁇
• Anmax-d / lmax used as an element by the liquid crystal layer is set.
• a nmax is the effective maximum birefringence.
• the amount of phase modulation corresponds to a variable phase delay that occurs while passing through the liquid crystal layer.
• phase modulation will be described.
• the phase modulation is performed in the region indicated by the first region A in FIG.
• a uniform potential is formed by applying the same voltage to the electrode 1C provided in the first region A.
• the light cl which is parallel light incident on the incident surface of the first region A, is delayed by the uniform phase amount a while passing through the liquid crystal layer.
• the amount of light delay depends on the applied potential state. The relationship between the light delay amount and the potential will be described later. As a result, the outgoing surface force is emitted as phase-modulated outgoing light c2.
• intensity modulation is performed in the region indicated by the second region B in FIG.
• a gradient phase modulation bl is formed by applying a gradient voltage to the electrode 1C provided in the second region B.
• the light cl which is parallel light incident on the incident surface of the second region B, is delayed by the gradient phase modulation bl caused by the gradient potential while passing through the liquid crystal layer. Accordingly, there is a difference depending on the location when the light is emitted from the emission surface. As a result, the wavefront of the emitted light c3 is inclined and the traveling direction is changed. The relationship between the light traveling direction and gradient phase modulation will be described later.
• Fig. 4 shows the case of a phase modulation curve equivalent to a blazed diffraction grating. However, if the coupling coefficient with the optical coupling system can be adjusted, the blazed phase modulation curve will be finer! Superposition Another phase distribution that can adjust the coupling coefficient is good, but it goes without saying.
• the coupling coefficient to the output port becomes smaller and the amount of incident light is attenuated.
• the intensity-modulated emission light c2 is emitted from the emission surface.
• FIG. 4 (b) shows a configuration for deflecting the angle change of the emitted light beyond an angle limited by the full width of the second region B and the phase modulation amount.
• the driving method shown in FIG. 4 (b) is different from the driving method shown in FIG. 4 (a) in terms of the method of applying the gradient voltage in the second region B, but is formed on the first transparent substrate.
• the intensity modulation is performed by changing the coupling coefficient with the optical system on the side.
• a plurality of electrodes 1C are sectioned, and a gradient voltage is applied to each section to form a plurality of gradient phase modulations b2, and each gradient phase modulation b2 Therefore, the angle of the outgoing light d3 is changed beyond the angle limited by the full width of the second region and the phase modulation amount by modulating the pitch of each sawtooth modulation region to be small. Since the phase difference 2 ⁇ can be regarded as the same phase at adjacent electrode parts in the liquid crystal layer, the phase distribution of gradient phase modulation b2 is formed by resetting the voltage applied every cycle in the X-axis direction. be able to.
• a voltage obtained by adding a constant bias voltage to the gradient voltage is applied to the electrode formed on the first transparent substrate, and the effective phase in the liquid crystal layer is applied by applying the gradient voltage.
• a gradient is formed in the modulation amount, and the phase of the outgoing light emitted from the outgoing light surface is shifted within the region by the gradient of the effective phase modulation amount, thereby adjusting the traveling direction of the outgoing light and performing intensity modulation.
• the horizontal axis (X-axis) is the direction in which the plurality of electrodes 1C formed on the first transparent substrate of the liquid crystal light modulation element are arranged. In this form, unlike the above-described form, the area is not divided.
• the vertical axis represents the thickness direction of the liquid crystal layer
• the solid line represents the phase modulation amount ⁇ and the refractive index anisotropy ⁇ in the liquid crystal layer
• the one-dot chain line arrow is incident on the liquid crystal layer. The direction of the light gl and the light rays g2 and g3 emitted from the liquid crystal layer are shown.
• the configuration of the second embodiment shown in FIG. 5 is in the form of the thickness of the liquid crystal layer and the accompanying phase modulation amount ⁇ and refractive index anisotropy ⁇ compared to the configuration shown in FIG. It is different.
• the thickness of the liquid crystal layer the maximum phase modulation amount so that a two-fold 2 ⁇ D m ax of the first embodiment.
• ⁇ is the wavelength of light passing through this liquid crystal layer
• d is the liquid crystal layer
• the maximum phase modulation amount 2 ⁇ by the liquid crystal layer is set to 4 ⁇ ⁇ A nmax 'd / max or less.
• FIG. 5 shows an example of a gradient phase modulation amount el with a constant phase modulation amount fl added by applying a bias voltage and a gradient phase modulation amount e2 with a constant phase modulation amount f 2 added by applying another bias voltage. ! /
• phase modulation and intensity modulation are performed simultaneously, but phase modulation is performed by effective phase modulation of constant phase modulation amounts fl and f 2 generated by applying a bias voltage with a constant voltage within a predetermined region.
• This constant effective phase modulation amount uniformly delays the phases of the outgoing lights g2 and g3 emitted from the outgoing light surface in the region.
• the intensity modulation is performed by a gradient of effective phase modulation in the liquid crystal layer formed by applying a gradient voltage.
• This effective phase modulation gradient is obtained by adjusting the traveling direction of the outgoing light by shifting the phase of the outgoing lights g2 and g3 emitted from the outgoing light surface in a sawtooth shape within the region.
• Intensity modulation is performed by controlling the coupling coefficient with the system.
• a constant phase modulation amount fl or a constant phase modulation amount f 2 is given by applying a bias voltage to the electrode 1C.
• This phase modulation amount can be changed by changing the magnitude of the bias voltage applied to the electrode.
• both the phase modulation and the intensity modulation are performed in the same region in the region where the electrodes 1C are arranged. Therefore, the thickness of the liquid crystal layer requires both the thickness required for phase modulation and the thickness required for intensity modulation. Therefore, here, the thickness of the liquid crystal layer is set so that the maximum phase modulation amount is at least 2 ⁇ with respect to ⁇ shown in Fig. 4.
• a liquid crystal light modulation device can be configured using the liquid crystal light modulation element described above.
• the basic configuration of a liquid crystal light modulation device is a configuration in which spectroscopy (demultiplexing) is not performed (liquid crystal light modulation device 10A, 10C), and a configuration in which spectroscopy (demultiplexing) is performed (liquid crystal light).
• Modulator 10B is a configuration in which spectroscopy (demultiplexing) is not performed (liquid crystal light modulation device 10A, 10C), and a configuration in which spectroscopy (demultiplexing) is performed (liquid crystal light).
• the liquid crystal light modulation element receives incident light input from one input port at a time. Perform intensity modulation and phase modulation.
• FIGS. 6 is a diagram for explaining a schematic configuration of the liquid crystal light modulation device 10A.
• FIG. 7 shows a wavefront state seen from the side surface of the liquid crystal light modulation device 10A shown in FIG. 9 shows the wavefront state of the liquid crystal light modulation device 10A shown in FIG. 6 as viewed from above, and
• FIG. 10 shows the equivalent optical path position.
• the liquid crystal light modulation device 10A shapes the incident light input from the input port into a spot that irradiates a plurality of liquid crystal pixels with a collimator L1, and then enters the liquid crystal light modulation element 1.
• the liquid crystal light modulation element 1 a liquid crystal layer and an electrode are arranged, and the light from the collimator L1 enters.
• the light incident on the liquid crystal light modulation element 1 is emitted after being subjected to phase modulation or intensity modulation.
• the emitted light is collected into a circular spot by the collimator L2, and then emitted to the output port. Since this configuration does not perform spectroscopy, intensity modulation and phase modulation are not performed for each wavelength.
• the incident polarization direction, the liquid crystal director (major axis), and the output polarization direction are parallel, and the liquid crystal light modulation element 1 includes at least a one-dimensional liquid crystal cell layer.
• the width in the horizontal direction is equal to or greater than the width of the incident parallel beam.
• FIG. 7 shows a wavefront state when the liquid crystal light modulation device 10 A in FIG. 6 is viewed from the side surface direction.
• the position indicated by G is the position where the liquid crystal light modulation element 1 is installed.
• the incident light becomes a plane wave after passing through the lens of the collimator L1, and the incident position of G is constant regardless of the operation of the liquid crystal light modulation element 1.
• FIG. 8 and 9 show the wavefront state of the liquid crystal light modulation device 10A shown in FIG. 6 as viewed from above.
• SMFli, SMF2i, SMF3i three optical fibers
• SMFFlo, SMF2o, SMF3o three optical fibers
• one SMFli In the figure, the incident light is input from the optical fiber placed in the center, and is output from any one of the three optical fibers provided on the output port side.
• which optical fiber is output is determined by beam deflection by the liquid crystal light modulation element 1.
• Fig. 8 (a) shows a case where incident light is output from one incident side SMFli to the outgoing side SMFlo.
• the liquid crystal light modulation element 1 operates so as not to deflect the light beam, thereby coupling the output from the incident side SMFli to the emission side SMFlo.
• Fig. 8 (b) shows a case where incident light is output from one incident-side SMFli to the outgoing SMF2o.
• the liquid crystal light modulation element 1 performs the operation of deflecting the light beam in one direction (the downward direction in FIG. 8B), thereby coupling the output from the incident side SMFli to the output side SMF2o. Yes.
• FIG. 8 (c) shows a case where incident light is output from one incident-side SMFli to the outgoing SMF3o.
• the liquid crystal light modulation element 1 performs the operation of deflecting the light beam in one direction (upward in FIG. 8 (c)), thereby coupling the output from the incident side SMFli to the output side SMF3o. Yes.
• FIG. 10 shows the arrangement of the optical elements having the above-described configuration.
• the exit point of the SMFli on the incident side or the effective focal image of the collimated splitter described later is displayed on the SMFlo or collimated method on the exit side.
• a conjugate point of the effective focus image of the splitter a 4f single optical system coupled with 1: 1 is used.
• the In this configuration when the focal length of the collimator lenses L1 and L2 is f, the liquid crystal light modulation element 1 is arranged so that the distance from the lenses L1 and L2 is exactly f.
• any SMF or collimated splitter on the incident side can be coupled to any SMF or collimated splitter on the exit side.
• this spectroscopy demultiplexing
• the signals cannot be separated and individual control of the signals becomes impossible. Since there is a problem that crosstalk occurs between the signals input at one time, only one SMF on the incident side is used as input at a time.
• Fig. 9 (a) shows a case where incident light is output from one incident-side SMF 3i to the outgoing SMF 2o.
• the liquid crystal light modulation element 1 performs the operation of deflecting the light beam in one direction (the downward direction in FIG. 9 (a)), thereby coupling the output from the incident side SMF3i to the output side SMF2o. Yes.
• Fig. 9 (b) shows a case where incident light is output from one SMF 2i on the incident side to SMF 3o on the emission side.
• the liquid crystal light modulation element 1 performs an operation of deflecting the light beam in one direction (upward in FIG. 9B), thereby coupling the output from the incident side SMF2i to the output side SMF3o. Yes.
• FIG. 11 is a diagram for explaining a configuration in which incident light having the same polarization direction is input to the input port.
• the incident light with the polarization direction aligned in one direction is configured such that the light with the polarization direction aligned in one direction is emitted from the polarization maintaining optical fiber on the light source side, and the collimator with the polarization direction aligned in one direction.
• a collimated splitter having a data function and a splitter function for separating light can be attached to the tip of the optical fiber.
• FIG. 11 (a) shows a configuration in which light having the same polarization direction on the light source side is emitted from the polarization maintaining optical fiber.
• the optical fiber 28 is preferably a polarization-maintaining optical fiber, but may instead be, for example, a single mode fiber (SMF) or a multimode fiber (MM F). Since the polarization direction of light is aligned in advance in one direction on the light source side, light whose polarization direction is aligned in one direction is emitted from the end of the optical fiber 28. Na The spread of the outgoing light emitted from the end of the optical fiber 28 is determined by the NA value that depends on the optical fiber.
• FIG. 11 (a) shows a method of guiding two polarization components using different polarization-maintaining optical fibers. However, both polarizations are combined into a single polarization-maintaining optical fiber in advance to receive light.
• a configuration may be adopted in which the polarization is split into two polarization components at a predetermined ratio as required on the output side of the polarization maintaining fiber on the side.
• FIGS. 11 (b) and 11 (c) are configuration examples in which a collimated splitter is attached to the tip of an optical fiber.
• the collimated splitter 27 is an element having a collimator function for aligning the polarization direction in one direction and a splitter function for separating polarized light, and includes a collimator lens 27d and a birefringent crystal 27a.
• the light incident on the collimated splitter 27 becomes parallel light by the collimator lens 27d, and is separated into p-polarized light and s-polarized light by the birefringent crystal 27a depending on the polarization direction.
• the polarization direction is aligned by arranging a 90-degree polarization rotator 27c at the output end of the birefringent crystal 27a that outputs s-polarized light.
• the birefringent crystal 27a can use rutile, YV04, or the like, and the 90-degree polarization rotator 27c can use, for example, a half-wave plate or a Faraday rotator.
• phase difference compensation plate 27b due to a difference in optical path is arranged at the output end of the birefringent crystal 27a from which p-polarized light is output.
• This phase difference compensator 27b delays the phase of the light passing therethrough, and matches the optical path length with the other path, so that the phase force of the beam a by P-polarized light and the beam b by s-polarized light exit plane S So that they are in phase.
• the diffusion angle of the light emitted from the exit end plane S of the collimated splitter 27 is 2 X sin ⁇ 1 (NA) radians with respect to the apparent NA of the collimated splitter 27.
• FIG. 12 is a diagram for explaining a schematic configuration of the liquid crystal light modulation device 10B.
• FIG. 13 shows a wavefront state seen from the top surface direction and the side surface direction of the liquid crystal light modulation device 10B shown in FIG. Indicates an equivalent optical path position.
• the liquid crystal light modulation device 10B sees the incident light input from the input port in the wavelength resolution direction of the liquid crystal light modulation element 1, the liquid crystal light modulation device 10B collimates and shapes it with an anamorphic collimator L1 such as a cylindrical lens After that, a spot that is long in one direction when viewed in the diffraction grating formation axis direction Are collimated and shaped by the cylindrical lens L2 so that the optical signal is divided by the demultiplexing diffraction grating G1, and the wavelength-multiplexed optical signal is wavelength-resolved, and the wavelength decomposition of the liquid crystal light modulator 1 by the anamorphic collimator L3 Condensed in a line on the liquid crystal light modulation element 1 only in the direction
• a liquid crystal layer and electrodes are two-dimensionally arranged.
• the incident light is divided into two axes: a diffraction grating forming axis in the direction developed in a line by the anamorphic collimator L1 and the cylindrical lens L2, and a wavelength resolving direction axis perpendicular to this axis.
• the two-dimensional liquid crystal array has a configuration in which a one-dimensional array in the diffraction grating forming axis direction is arranged in the wavelength resolving direction axis direction.
• the light incident on the liquid crystal light modulation element 1 is subjected to phase modulation or light intensity modulation independently for each wavelength, and this phase modulation or light intensity modulation is performed. Thereafter, the emitted light is converted into parallel light by the cylindrical lens L4 in the wavelength resolving direction of the liquid crystal light modulation element 1, and then incident on the combined diffraction grating G2.
• the incident light is combined with a different wavelength by the synthetic diffraction grating G2, passes through the cylindrical lens L5, and is collected to form a circular spot by an anamorphic collimator L6 such as a cylindrical lens, and then to the output port. Emitted.
• an anamorphic collimator L6 such as a cylindrical lens
• the liquid crystal light modulation element 1 includes a two-dimensional liquid crystal cell layer, and the vertical and horizontal widths thereof are the width of the incident parallel beam to the liquid crystal light modulation element 1 and the wavelength-resolved light irradiation range. It must be greater than the width of the enclosure.
• FIG. 13 shows a wavefront state (and a light beam direction) when the liquid crystal light modulation device 10B shown in FIG. 12 is viewed from the top surface direction and the side surface direction.
• the position indicated by LC1 is the position where the liquid crystal light modulation element 1 is installed.
• FIG. 13 (a) shows a wavefront state when the liquid crystal light modulation device 10B is viewed from the upper surface direction
• FIG. 13 (b) shows a wavefront state when the liquid crystal light modulation device 10B is viewed from the side surface direction.
• incident light including different wavelengths ⁇ ⁇ , 12, and ⁇ 3 is incident on the input port, and the liquid crystal light modulator 1 performs light intensity modulation adjustment and phase modulation for each wavelength.
• FIGS. 13 (b) to 13 (d) show the state of each wavelength component as viewed from the side.
• FIG. 13 (b) shows the case of wavelength ⁇
• FIG. 13 (c) shows the case of wavelength 2
• FIG. 13 (d) shows the case of wavelength ⁇ 3!
• FIG. 14 shows the arrangement of the optical elements configured as described above.
• the arrangement of the optical elements of the liquid crystal light modulation device 10B is a 4f optical system arrangement equivalent to that shown in FIG. 10 when viewed from above (the top view in FIG. 14).
• the effective focus image position of the splitter is combined as a conjugate point of the focus of the SMF or collimated splitter on the exit side with 1: 1.
• the 4f optical system extends from the exit point of the SMF on the incident side or the effective focus image position of the collimated splitter to the liquid crystal light modulation element 1.
• the 4f optical system is arranged from the liquid crystal light modulator 1 to the SMF on the emission side or the focal point of the collimated splitter.
• the SMF exit point on the incident side or the effective focus image position of the collimated splitter is combined as a conjugate point on the liquid crystal light modulator 10B at a ratio of 1: 1, and the point on the liquid crystal light modulator 1 Are combined 1: 1 as the conjugate point of the focal point of the SMF or collimated splitter on the output side.
• the beam deflection direction by the liquid crystal diffraction grating and the spectral direction by the two diffraction gratings can be controlled separately.
• FIG. 15 is a diagram for explaining a schematic configuration of the liquid crystal light modulation device 10C.
• FIG. 16 shows a wavefront state of the liquid crystal light modulation device 10C shown in FIG. 15 as viewed from the top and side directions. .
• the liquid crystal light modulation device 10C has a structure in which only the cylindrical lenses L2 and L5 are arranged except for the branching diffraction gratings Gl and G2 in the configuration of the liquid crystal light modulation device 10B shown in FIG. Since the demultiplexing by the diffraction gratings Gl and G2 is not performed, light intensity modulation and phase modulation for each wavelength cannot be performed.
• FIG. 16 (a) shows the wavefront state (and the light beam direction) of the liquid crystal light modulator 10C as viewed from above
• Figs. 16 (b) to 16 (d) show the wavefronts of the liquid crystal light modulator IOC as viewed from the side. Indicates a state.
• FIG. 16 (e) is a configuration diagram when the ports are viewed from the input side and output side of FIG. 16 (b) when 9 ports are provided in 3 rows and 3 columns as inputs.
• FIG. 17 is a diagram for explaining a schematic configuration of the liquid crystal light modulation device 10D.
• FIG. 18 shows a wavefront state viewed from the top surface direction and the side surface direction of the liquid crystal light modulation device 10D shown in FIG.
• the liquid crystal light modulation device 10D has the same configuration as the liquid crystal light modulation device 10B shown in FIG.
• the configuration shows that the incident light is incident on the incident side with different wavelengths separated by different wavelengths. Since the optical configuration of the liquid crystal light modulation device 10D is the same as that of the liquid crystal light modulation device 10B shown in FIG. 12, the description thereof is omitted here.
• FIG. 18 (a) shows the wavefront state (and the light beam direction) of the liquid crystal light modulator 10D viewed from the top surface
• FIG. 18 (b) shows the wavefront state of the liquid crystal light modulator 10D viewed from the side surface.
• incident light having different wavelengths enters the input port at different positions in the upper surface direction of the lens L1.
• incident light having different wavelengths enters the input port at different positions in the upper surface direction of the lens L1.
• the wavefront state seen from the top surface direction shown in FIG. 18 (a) it appears to overlap on the modulation device surface of the liquid crystal light modulation element 1, but in the wavefront state seen from the side surface direction shown in FIG.
• the light is condensed on different lines for each wavelength on the modulation device surface of the liquid crystal light modulation element 1 by the demultiplexing diffraction gratings Gl and G2.
• light intensity modulation and phase modulation can be performed for each wavelength.
• each wavelength (or Can be controlled independently, but each wavelength cannot be controlled independently when there is an overlap with the wavelength multiplexed in each SMF.
• different wavelengths ⁇ ,, 1 2 and ⁇ 3 are input to SMF1, and different wavelengths 4 are input to SMF2.
• a spectral (demultiplexing) diffraction grating is used. Since optical signals are input to a one-dimensional array at different positions in the liquid crystal two-dimensional array, light intensity modulation, phase modulation, and demultiplexing can be performed independently by the liquid crystal device.
• FIG. 19 is a diagram illustrating a configuration example of a two-dimensional liquid crystal light modulation device.
• FIG. 19 shows an example of a transmissive configuration.
• the liquid crystal light modulation element 1 included in the liquid crystal light modulation device 10 has a configuration in which a liquid crystal layer and electrodes are two-dimensionally arranged, and can perform phase modulation and intensity modulation for each wavelength component.
• anamorphic collimator 11 that collimates and shapes incident light in a line shape on the surface of liquid crystal light modulation element 1, and spectrometer 12 that splits incident light into each wavelength component;! ⁇ ⁇ Is done.
• a coupler 14 On the output side of the liquid crystal light modulation element 1, a coupler 14, a anamorphic collimator 13, a polarization conversion element 16 for converting a polarization state, and an output port 3 are arranged.
• the anamorphic collimators 11 and 13 may be configured to be distributed from a plurality of lenses that are also disposed between the spectroscope 12 and the coupler 14 and the liquid crystal light modulation element 1 as in the configuration described in FIG.
• the input port 2 and the output port 3 may be configured by optical fibers.
• the above-described example is a transmissive configuration example, but may be a reflective configuration.
• 20 and 21 are diagrams for explaining a configuration example of a reflection type.
• FIG. 20 (a) is a diagram for explaining a schematic configuration of the one-dimensional liquid crystal light modulation device 10E
• FIG. 20 (b) is a diagram for explaining a schematic configuration of the two-dimensional liquid crystal light modulation device 10E.
• FIG. 20 (a) is a diagram for explaining a schematic configuration of the one-dimensional liquid crystal light modulation device 10E
• FIG. 20 (b) is a diagram for explaining a schematic configuration of the two-dimensional liquid crystal light modulation device 10E.
• FIG. 20 (b) is a diagram for explaining a schematic configuration of the two-dimensional liquid crystal light modulation device 10E.
• the one-dimensional liquid crystal light modulation device 10E causes the incident light input from the input port to enter the reflective liquid crystal light modulation element 1.
• the reflective liquid crystal light modulation element 1 is arranged in a liquid crystal layer and an electrode force dimension and includes a reflective surface (not shown).
• the light incident on the liquid crystal light modulation element 1 is phase-modulated or light-intensity-modulated before and after being reflected by the reflecting surface, and is emitted.
• the light emitted from the liquid crystal light modulation element 1 is returned to the input port side. In light intensity modulation, the discarded light is emitted in a different direction from the input port side.
• the two-dimensional liquid crystal light modulator 10F makes incident light ( ⁇ 1 to ⁇ ) input from an input port incident on a spectroscope (demultiplexer) 12 and is split by the spectroscope 12. Light having a wavelength;! To ⁇ is incident on the reflective liquid crystal light modulation element 1.
• the reflection type liquid crystal light modulation element 1 includes a liquid crystal and electrodes arranged in a two-dimensional manner and a reflection surface (not shown).
• the light incident on the liquid crystal light modulation element 1 is emitted after being subjected to phase modulation or light intensity modulation for each wavelength.
• the light emitted from the liquid crystal light modulation element 1 is returned to the input port side.
• light intensity modulation discarded light is The light is emitted in a different direction from the force port side.
• FIG. 21 is a diagram showing a configuration example of the two-dimensional reflective liquid crystal light modulation device 10F shown in FIG.
• the liquid crystal light modulation device 1 provided in the liquid crystal light modulation device 10F has a configuration in which a liquid crystal layer and electrodes are two-dimensionally arranged, and can perform phase modulation and intensity modulation for each wavelength component. .
• an input / output port 4 On the incident side and the emission side of the liquid crystal light modulation element 1, there are an input / output port 4, a polarization conversion element 15 for changing the polarization state, and incident light is collimated in a line on the surface of the liquid crystal light modulation element 1.
• An anamorphic collimator 11 for shaping and shaping, and a spectral coupler 17 for spectrally coupling or coupling incident light into each wavelength component;! To ⁇ are arranged.
• the input / output port 4 may be configured by an optical fiber.
• the anamorphic collimator 11 may be configured to be distributed from a plurality of lenses arranged between the spectral coupler 17 and the liquid crystal light modulation element 1 as in the configuration described in FIG.
• FIG. 22 is a diagram for explaining a configuration example of the TEC.
• TEC 5 can be configured by combining Peltier element 5a and heat sink 5b.
• the TEC 5 is provided with a Peltier device 5a provided on the back surface (surface opposite to the incident direction) of the substrate forming the reflective surface of the liquid crystal light modulation device 1 via the device coupling layer 5d.
• the heat sink 5b may be provided with the layer 5c interposed therebetween.
• the element bonding layer 5d and the bonding layer 5c can use a metal such as indium solder or a bonding agent made of epoxy / acrylic resin.
• an insulating layer such as alumina or aluminum nitride may be sandwiched.
• the optical clock to be handled becomes an ultra-high speed exceeding 160 Gbit / second, for example.
• the time interval between clocks is extremely short, and the liquid crystal layer and the surrounding optical Since the variation in the light transit time due to the phase change due to the temperature change of the member may greatly influence, it is extremely important to keep the liquid crystal temperature constant with respect to the external environment temperature.
• the liquid crystal light modulation element 1 has the same voltage profile with respect to the phase fluctuation in terms of the wavelength of the liquid crystal layer due to a change in the environmental temperature by being bonded and fixed to a thermoelectric conversion element such as the Peltier element 5a with a metal or resin. It is desirable to control so that it is less than or equal to the maximum wavelength used at the time of application.
• the configuration example shown in Fig. 23 (a) is a configuration example in which the input port 2 and the output port 3 are each configured by an optical fiber, and the liquid crystal light modulation element 1 of the present invention is disposed between the optical fibers.
• the optical fiber shown in the figure can have a collimator function by using a core expansion fiber or by fusing a small lens made of low-melting glass.
• the collimator 21 between the input port 2 and the liquid crystal light modulation element 1 is arranged in the configuration of FIG. 23 (a), and the liquid crystal light modulation element 1 and the output
• the collimator 23 is arranged between the port 3 and the port 3. 23A and 23B, parallel light can be incident on the liquid crystal light modulation element 1 by the collimator function of the optical fiber and the collimators 21 and 23.
• the polarization conversion element 25 is arranged between the input port 2 and the collimator 21 in the configuration example shown in FIG. 23 (b), and the collimator 23 and the output port are arranged.
• a polarization conversion element 26 is arranged between the three.
• the polarization conversion element maximizes the efficiency of the light modulation action in the liquid crystal layer in the liquid crystal light modulation element 1 by aligning the polarization state.
• the order of the collimator 21 and the polarization conversion element 25 and the collimator 23 and the polarization conversion element 26 may be interchanged! /.
• the configuration example shown in Fig. 23 (d) is a configuration example in which the output light intensity-modulated by the liquid crystal light modulation element 1 is output to a plurality of output ports 3, and a plurality of optical fibers are arranged at the output port 3. To do. According to this configuration, the output port 3 to be emitted can be selected by adjusting the deflection angle of the emitted light by intensity modulation.
• the spectroscope 22 is provided in front of the liquid crystal light modulation element 1, and the wavelength component obtained by performing the spectrum with the spectroscope 22 is obtained. Every phase modulation and This is a configuration example in which intensity-modulated light is output to a plurality of output ports 3, and a plurality of optical fibers are arranged at the output ports. According to this configuration, phase modulation and intensity modulation can be performed for each wavelength component, and further, the force S can be emitted from the selected output port 3.
• a coupler 24 is provided behind the liquid crystal light modulation element 1, and each wavelength component is coupled by the coupler 24.
• This is a configuration example for outputting to output port 3. According to this configuration, it is possible to perform phase modulation and intensity modulation for each wavelength component, and furthermore, it is possible to emit an optical component that is phase-modulated and intensity-modulated for each wavelength from the output port 3 as one optical signal. it can.
• FIG. 24 is a schematic diagram showing the basic principle of operation of the liquid crystal light modulation element.
• the liquid crystal light modulation element 31 when an external electric field is applied in a state where the director 32 is homogeneously oriented in a direction parallel to the Xz plane, the major axis direction of the director 32 is parallel to the electric field direction. It is assumed that p-type (positive-type) nematic liquid crystal is aligned.
• linearly polarized light 33 oscillating in a direction parallel to the X axis is incident on the liquid crystal light modulation element 31 in the z axis direction.
• the incident wavefront 34 before entering the liquid crystal light modulation element 31 is a plane.
• the incident wavefront 34 is converted into a plane wave outgoing wavefront 35 that is deflected by a predetermined angle ⁇ . Can be made.
• FIG. 25 is an explanatory diagram showing the operation principle of the liquid crystal light modulation device of the present invention.
• the plane on the emission side of the nematic liquid crystal layer 36 of the liquid crystal light modulation element 31 is the xy plane, and the liquid crystal is aligned so as to be parallel to the XZ plane.
• the incident linearly polarized light 33 enters the nematic liquid crystal layer 36 perpendicularly.
• the operating point is determined in advance so that the distribution 35 of the extraordinary refractive index n (X), which is a function of the position X, linearly changes between a and b at the pitch P of the element grating. Keep it.
• the thickness d of the nematic liquid crystal layer 36 is constant, the power refractive index n (x) varies linearly at the pitch P, and therefore the incident linearly polarized light 33 propagating in the nematic liquid crystal layer 36 is , Depending on the location, it will be modulated with different retardation ⁇ ⁇ ( ⁇ ) 'd.
• FIG. 26 is a plan view of a first composite electrode 55 having a first active region 60 with two diffraction grating regions of a first element grating 44 and a second element grating 48.
• the first element lattice 44 has a first individual electrode 51 to a first individual electrode 52.
• the second element lattice 48 has the second individual electrode 54 from the (N + 1) th individual electrode 53.
• the first individual electrode 51 to the second individual electrode 54 are formed of a transparent conductive film such as a metal having the above-described film thickness and resistance value.
• first individual electrode 51 to the second individual electrode 52 are grouped into a plurality of groups (two groups in Fig. 12) outside the first active region 60.
• the individual electrodes are connected by a common collecting electrode such as a bag made of the same material as the individual electrodes.
• the first individual electrode 51 to the second individual electrode 52 are connected by the first collector electrode 43 outside the first active region 60, and the N + 1 first individual electrode 53 is connected to the second one.
• the individual electrodes 54 are connected by the second collector electrode 47 in the same manner.
• the first signal electrode 41 and the second signal electrode 42 made of a low-resistance metal material such as Mo or Ag alloy are connected to both ends of the first collector electrode 43, respectively.
• the collector electrode is configured to have a linear resistance in the long side direction of the electrode by further reducing the film thickness formed by a film having a sheet resistance of several hundred to lk Q, or by narrowing the electrode width. Moyo! /
• the force showing only two diffraction grating regions, the first element grating 44 and the second element grating 48, is applied to the actual liquid crystal light modulator 1!
• a predetermined number of element lattices corresponding to the incident beam diameter must be formed in the active region 60.
• the width L of the first active region 60 is set to 400 ⁇ m to 1.5 mm.
• the individual electrodes of each element grating have an element grating pitch P of 30 m, which is desirable for line and space of 2 m or less, considering the wavelength of incident light.
• the width W of the first composite electrode 55 is preferably about 800 ⁇ m to 2 mm. Therefore, when the pitch P is 30 ⁇ , the number of element lattices is 27 to 67.
• the number of element grids is 8 to 20.
• the control signal from the drive circuit is used.
• the number of signal electrodes to be connected is 2M with respect to the number of element grids (M) by connecting to both ends of the first and second collector electrodes 43 and 47.
• M element grids
• Figure 27 shows the drive waveforms.
• the first drive waveform Va is applied to the first signal electrode 41
• the second drive waveform Vb is applied to the second signal electrode 42.
• the first drive waveform Va and the second drive waveform Vb have the same frequency and phase and differ only in voltage, and the second drive waveform Vb has a higher voltage than the first drive waveform Va.
• the common electrode 1G is set to 0 [V]. Therefore, since the potential is divided by the first collector electrode 43 formed of a linear resistance material such as a transparent conductive film, the first In the individual electrodes of the first element lattice 44 formed in the active region 60, the voltages applied to the first signal electrode 41 and the second signal electrode 42 are linearly divided according to the arrangement positions, respectively. .
• the individual electrodes are formed of a low resistance material as compared with the impedance of the nematic liquid crystal layer 36 in the longitudinal direction of the individual electrodes, they can be set to substantially the same potential. Furthermore, a period for applying the bias AC voltage to the common electrode 1G may be provided separately from the period 1 and the period 2 as necessary.
• the potential gradient due to the collector electrode will be described.
• the relationship between the potential gradient on the first collector electrode 43 in the first composite electrode 55 (FIG. 26) and the potential of each individual electrode will be described in detail.
• the potential distribution of the first collector electrode 43 that connects the first signal electrode 41 and the second signal electrode 42 is linear, as shown by the first potential distribution Vc in FIG.
• the potential distribution of the first collector electrode 43 is the potential distribution indicated by the second potential distribution Vd in FIG.
• point a corresponds to the position of the individual electrode connected to the first signal electrode 41
• point b corresponds to the position of the individual electrode connected to the second signal electrode 42. It corresponds.
• the drive waveform shown in FIG. 27 is a rectangular waveform with 50% duty
• the two first and second potential distributions Vc and Vd shown in FIG. 28 are alternately repeated in time. Therefore, the voltage applied to the nematic liquid crystal layer 36 via the common electrode 1G maintained at 0 [V] is changed to an alternating voltage at any individual electrode position, and a DC component is not added to the nematic liquid crystal layer 36. Absent. Since nematic liquid crystal has an effective direct response, V [V] is always applied as an effective value to the first signal electrode 41 side, and a voltage of V [V] is applied to the second signal electrode 42.
• the potential divided by the first collector electrode 43 is applied to each individual electrode.
• FIG. 29 is a schematic diagram showing the phase distribution of the liquid crystal light modulation device of the present invention.
• the pitch of the element lattice is P
• the maximum phase modulation amount in the case of ⁇ max phase modulation curve is one wavelength, or 2 ⁇ , at the distance of the pitch P of the element grating.
• FIG. 30 is a diagram showing a waveform application period to signal electrode terminals arranged in one element lattice.
• one frame is divided into period 1 and period 2 for driving.
• an alternating voltage drive signal with an average value of 0 is applied to the first signal electrode 41, and the second signal electrode 42 is connected to the common electrode.
• the period 1 is set to 0 [V] so as to be the same potential as 1G, and an alternating voltage drive signal is applied to the second signal electrode 42 so that the first signal electrode 41 becomes the same potential as the common electrode 1G.
• the drive is performed by alternately providing period 2 with 0 [V].
• the liquid crystal potential distribution generated in the element lattice in one frame obtained by adding period 1 and period 2 takes a value close to the effective value of each period.
• two waveforms with different amplitudes can be applied as the applied waveforms in period 1 and period 2.
• a waveform in which the effective value is controlled by the pulse width modulation may be used.
• a bias AC voltage can be applied to the common electrode if necessary! /.
• the second composite electrode 95 has collector electrodes arranged at both ends of a group of individual electrodes outside the first active region 60. Adopt the configuration to do.
• a third collector electrode 83 is disposed outside the first active region 60 at a position facing the first collector electrode 73, and a second collector electrode is disposed outside the first active region 60.
• a fourth collector electrode 87 is arranged at a position opposite to 77. Furthermore, the third collector electrode 83 is connected to the fifth signal electrode 81 and the sixth signal electrode 82 made of a low-resistance metal material such as Mo or Ag alloy, and the fourth collector electrode 87 is connected to the seventh signal electrode.
• the electrode 85 and the eighth signal electrode 86 are connected.
• the first signal electrode 71, the fifth signal electrode 81, the second signal electrode 81, The signal electrode 72 and the sixth signal electrode 82, the third signal electrode 75 and the seventh signal electrode 85, and the fourth signal electrode 76 and the eighth signal electrode 86 are short-circuited externally.
• the driving method described above can be applied to the driving method of the optical deflection apparatus using the second composite electrode 95 as it is.
• the structure of the second composite electrode 95 shown in Fig. 31 is that when the individual electrode is thin and long, the impedance force S of the individual electrode compared to the impedance at the driving frequency of the nematic liquid crystal layer, This is particularly effective when it becomes too large to be ignored.
• FIG. 32 is a plan view showing the relationship between the first active region 60 and the third composite electrode 63 for realizing a blazed diffraction grating.
• each individual electrode 6 In order to realize a blazed diffraction grating for performing optical deflection in the first active region 60, a predetermined voltage is applied to each individual electrode 6;! There is a need.
• the first individual electrode 61 to the Nth individual electrode 62 are separately formed as shown in FIG. 32, and each individual electrode is independently driven by a driving circuit such as an IC. A stepwise potential difference is generated in each individual electrode.
• each individual electrode can be independently applied with an arbitrary voltage by a direct drive circuit. Therefore, an arbitrary deflection angle can be realized when the modulatable amount can be as small as 2 ⁇ (one wavelength).
• the X-axis direction was defined as a direction orthogonal to the individual electrodes.
• each of the voltages for realizing the second phase modulation waveform Ph2 in the first active region 60 is measured.
• a VOAD (Variable Optical Attenuator and Delay) 111 is configured using the liquid crystal light modulation device of the present invention, and performs light intensity modulation, phase modulation, and demultiplexing for a plurality of wavelengths.
• An optical clock multiplier is configured.
• the optical clock multiplier 110 includes an input port 102 and an output port 103, and the optical signal input from the input port 102 is separated by the optical coupling separator 104.
• One of the separated optical signals is modulated by the VOAD 111, the other optical signal is passed through a fixed delay unit 106 with a fixed delay amount, and both optical signals are combined by an optical coupling / separating unit 105.
• the optical clock is multiplied by the predetermined phase difference set between the optical signal output from the optical coupling / separation device 104 and the optical signal output from the fixed delay device 106 and combined by the optical coupling / separation device 105.
• the optical signal is output from the output port 103.
• the VOAD 111 performs optical intensity modulation and phase modulation independently for each wavelength, so that the optical clock multiplier 110 performs wave height equivalent and phase compensation on the optical clock that is the signal carrier wave for each wavelength. Can be doubled.
• FIG. 35 is a diagram for explaining light intensity modulation and phase modulation by VOAD111.
• FIGS. 35 (a) to 35 (c) show a state in which two optical signals that perform optical clock multiplication are in a desirable state, and the phase relationship in which the optical intensities are equal is an equal phase difference.
• FIGS. 35 (d) to (g) show a state in which the light intensity is adjusted by light intensity modulation when the light intensity is non-uniform.
• a case is shown in which the optical signal is multiplied by the optical signal shown in FIG. 35 (d) and the optical signal shown in FIG. 35 (e).
• the optical intensity of the optical signal shown in Fig. 35 (e) is lower than the optical intensity of the optical signal shown in Fig. 35 (d)
• combining the two optical signals results in Fig. 35 (f).
• the light intensity of the multiplied optical signal becomes non-uniform.
• the VOAD 111 attenuates the optical intensity of the optical signal shown in Fig. 35 (d) to match the optical intensity of the optical signal shown in Fig. 35 (e). ⁇ times with uniform strength Form an optical signal.
• FIGS. 35 (h) to (k) show a state where the phase relationship is matched by phase modulation when a phase shift occurs.
• a case where the optical signal is multiplied by the optical signal shown in FIG. 35 (h) and the optical signal shown in FIG. 35 (i) is shown.
• the phase of the optical signal shown in FIG. 35 (i) is out of phase with respect to the phase of the optical signal shown in FIG. As shown in j), the phase interval of the multiplied optical signal becomes non-uniform.
• the VOAD 111 shifts the phase of the optical signal shown in FIG. 35 (h) to adjust the phase interval between it and the phase of the optical signal shown in FIG. 35 (i), as shown in FIG. 35 (k).
• a double optical signal having a uniform phase interval is formed.
• FIGS. 34 and 35 an example of an optical clock multiplier for generating a carrier wave that generates a double bit rate in one stage is illustrated. By using this value, it can be applied to wave height equivalence and phase adjustment of an optical clock multiplier with an arbitrary phase delay. It goes without saying that the configuration of the present invention is applicable even when optical clock multipliers are connected in cascade or in parallel, or when an optical amplifier, signal modulator, or the like is inserted midway! /.
• liquid crystal light modulation device of the present invention has been described with reference to the preferred embodiments, the liquid crystal light modulation device according to the present invention is not limited to the above-described embodiments. It goes without saying that various modifications can be made within the range.

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• Chemical & Material Sciences (AREA)
• Crystallography & Structural Chemistry (AREA)
• Optical Modulation, Optical Deflection, Nonlinear Optics, Optical Demodulation, Optical Logic Elements (AREA)
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