[go: up one dir, main page]

WO2020121452A1 - Dispositif lidar - Google Patents

Dispositif lidar Download PDF

Info

Publication number
WO2020121452A1
WO2020121452A1 PCT/JP2018/045744 JP2018045744W WO2020121452A1 WO 2020121452 A1 WO2020121452 A1 WO 2020121452A1 JP 2018045744 W JP2018045744 W JP 2018045744W WO 2020121452 A1 WO2020121452 A1 WO 2020121452A1
Authority
WO
WIPO (PCT)
Prior art keywords
optical
light
txopa
space
antenna elements
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Ceased
Application number
PCT/JP2018/045744
Other languages
English (en)
Japanese (ja)
Inventor
成君 金
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Taisei Technology Co Ltd
Original Assignee
Taisei Technology Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Taisei Technology Co Ltd filed Critical Taisei Technology Co Ltd
Priority to CN201880096931.2A priority Critical patent/CN112673273B/zh
Priority to JP2018566457A priority patent/JP6828062B2/ja
Priority to PCT/JP2018/045744 priority patent/WO2020121452A1/fr
Publication of WO2020121452A1 publication Critical patent/WO2020121452A1/fr
Anticipated expiration legal-status Critical
Ceased legal-status Critical Current

Links

Images

Classifications

    • GPHYSICS
    • G01MEASURING; TESTING
    • G01SRADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
    • G01S7/00Details of systems according to groups G01S13/00, G01S15/00, G01S17/00
    • G01S7/48Details of systems according to groups G01S13/00, G01S15/00, G01S17/00 of systems according to group G01S17/00
    • G01S7/481Constructional features, e.g. arrangements of optical elements

Definitions

  • the present invention generally relates to the field of remote sensing and distance measurement, and more particularly to a lidar (LiDAR, Light Detection and Ranging) for performing three-dimensional spatial mapping, object detection, object tracking, and object identification in an autonomous driving system in real time.
  • a lidar LiDAR, Light Detection and Ranging
  • the lidar device sends the search light to the space, scans the space, receives reflected return light generated by the search light being reflected by an object in the space, and determines the direction and distance of the object in the space. Detect.
  • An optical phased array (OPA, Optical Phased Array) is known as a device constituting such a lidar device.
  • OPA Optical Phased Array
  • the lidar device using the OPA can be configured at a higher speed and smaller than a lidar device using a mechanical beam scanning device.
  • an OPA configured by arranging a plurality of unit cells each including an optical coupler, a phase shifter, and an antenna element has been conventionally known (Patent Document 1). ).
  • Patent Document 1 an OPA configured by arranging a plurality of unit cells each including an optical coupler, a phase shifter, and an antenna element.
  • each unit cell is composed of many elements such as the above-mentioned optical coupler, the unit cell has a corresponding size. Therefore, there is a limit to reducing the arrangement interval of the unit cells, that is, the arrangement interval of the antenna elements, and the angle range of the beam steering of the search light is narrowed due to the size of the arrangement interval.
  • an OPA based on an optical integrated circuit is conventionally known (Non-patent document 1).
  • This OPA includes a bus waveguide for inputting light, a plurality of branch portions each formed of a thermal phase shifter and an evanescent coupler and provided on the bus waveguide, and the evanescent coupler. And a plurality of grating-based antenna elements for transmitting each of the plurality of lights branched by each to the space.
  • beam steering is performed along the extending direction of the antenna element by changing the wavelength of the input light.
  • a wider beam steering angle range is realized by overcoming the limitation of the beam steering angle range due to the arrangement pitch of the antenna elements without increasing the cost. Is required to do.
  • One aspect of the present invention is configured by a first optical phased array, and transmits diffracted light generated by light output from a plurality of first antenna elements forming the first optical phased array to space.
  • an optical receiver that is configured by a second optical phased array and that receives light coming from the space by a plurality of second antenna elements that configure the second optical phased array.
  • the optical receiver has a plurality of maximum sensitivity directions with respect to the direction of light coming from the space, the receiving sensitivity of the light being maximum, and the optical transmitter transmits the diffracted light adjacent to the space.
  • a first angle formed by the directions is different from a second angle formed by the adjacent maximum sensitivity directions in the optical receiver.
  • a phase shift controller that controls a first phase shifter included in the first optical phased array and a second phase shifter included in the second optical phased array.
  • the phase shift control unit controls the phase shift amount of the first phase shifter to change the sending direction of the main lobe of the diffracted light sent to the space by the optical transmitter, and at the same time, among the maximum sensitivity directions.
  • the phase shift amount of the second phase shifter is controlled so that the maximum sensitivity direction having the maximum sensitivity matches the sending direction of the main lobe.
  • the array interval of the first antenna elements and the array interval of the second antenna elements are set to different values.
  • the ratio between the first angle and the second angle is set so as to be expressed as a ratio of natural numbers that are relatively prime.
  • the ratio of the arrangement interval of the first antenna elements and the arrangement interval of the second antenna elements is set to be represented by a ratio of natural numbers that are mutually prime.
  • the optical transmitter includes a first optical component that forms an image conversion optical system for the diffracted light generated by the light output from the plurality of first antenna elements. Via the first optical component, the first angle being defined by the angle between adjacent diffracted lights that are delivered to the space via the first optical component.
  • the first optical component is composed of two convex lenses.
  • the first optical component includes two prisms forming an anamorphic prism pair.
  • the optical receiver receives light coming from the space by the plurality of second antenna elements via a second optical component forming an image conversion optical system,
  • the second angle is defined as an angle formed by adjacent maximal sensitivity directions defined in the space with respect to light coming from the space received via the second optical component.
  • the present invention it is possible to realize a wider beam steering angle range by overcoming the limitation of the beam steering angle range due to the arrangement pitch of the antenna elements in the lidar device using the OPA without increasing the cost. it can.
  • FIG. 1 is a diagram showing a configuration of a rider device according to a first embodiment of the present invention.
  • FIG. 2 is an explanatory diagram for explaining the operation of the rider device shown in FIG.
  • FIG. 3 is a diagram showing a configuration of a rider device according to a second embodiment of the present invention.
  • FIG. 4 is a diagram showing the configuration of the rider device according to the third embodiment of the present invention.
  • FIG. 5: is a figure which shows the structure of the conventional rider apparatus.
  • FIG. 6 is a diagram showing an example of characteristics of a conventional rider device.
  • FIG. 7 is a diagram showing an example of an optical phased array that can be used in the lidar device.
  • FIG. 8 is a diagram showing a configuration of a unit cell included in the optical phased array shown in FIG.
  • FIG. 9 is a diagram showing another example of the optical phased array that can be used in the lidar device.
  • the OPA is provided with an optical branching device for branching the input light into a plurality of lights, a plurality of waveguide lines for propagating each of the plurality of branched lights, and a plurality of waveguide lines provided for the waveguide lines. It is composed of a phase shifter that changes the phase of light propagating in the wave line, and an antenna element that is connected to each waveguide line and outputs the light propagating in the waveguide line.
  • the OPA is generally reciprocal and can be used not only in an optical transmitter that sends out a light beam that is a search light, but also in a receiver that receives the reflected return light of the light beam.
  • the light received by each of the antenna elements of the OPA is propagated to each waveguide line, the phase is changed by the phase shifter, and the optical branching device is used as an optical coupler (combiner).
  • An optical receiver can be configured by combining the light propagating through the waveguide line into one light and outputting the combined light.
  • the OPA is used as an optical transmitter and the phase shift amount in the phase shifter is adjusted so that diffracted light is sent out from the antenna element of the OPA toward space. Then, in this state, it is assumed that the OPA is used as an optical receiver and light is received from the antenna element while holding the phase shift amount of the phase shifter. Then, the light arriving from the same direction as the diffracted light transmission direction is received by each of the antenna elements, and then phase-shifted to the same phase by the phase shifter, and the signals are mutually strengthened and output in the optical coupler.
  • the Rukoto is assumed that the OPA is used as an optical transmitter and the phase shift amount in the phase shifter is adjusted so that diffracted light is sent out from the antenna element of the OPA toward space. Then, in this state, it is assumed that the OPA is used as an optical receiver and light is received from the antenna element while holding the phase shift amount of the phase shifter. Then, the light arriving from the same direction as the diffracted light transmission direction is received by each of the antenna elements
  • the optical receiver has a maximum reception sensitivity with respect to the light coming from the transmission direction of the diffracted light. Further, the optical receiver has the maximum receiving sensitivity for the light coming from the direction of transmission of the main lobe having the maximum intensity among the diffracted lights.
  • an optical transmitter including an OPA functioning as a transmitter for transmitting a beam is referred to as TxOPA
  • an optical receiver including an OPA functioning as a receiver for receiving light is referred to as RxOPA. ..
  • the diffracted light, the main lobe, and the side lobes that would be generated by the light sent from the antenna element if the light was sent from the antenna element forming the RxOPA They are referred to as “diffracted light of RxOPA”, “main lobe of RxOPA”, and “sidelobe of RxOPA”, respectively.
  • the “far-field image of RxOPA” refers to a far-field image of the light transmitted from the antenna element when the light is transmitted from the antenna element forming the RxOPA 104. ..
  • the reception sensitivity of RxOPA is the loss received by the light received by the antenna element of the RxOPA before being output from the optical coupler via the phase shifter and the optical coupler of the RxOPA.
  • the reciprocal that is, the reciprocal of the ratio of the amount of light output from the optical coupler to the total amount of light that reaches the antenna element from the same direction).
  • a rider device that performs three-dimensional space mapping or the like can be generally realized by the configuration shown in FIG.
  • the rider device 500 shown in FIG. 5 includes TxOPA 502 and RxOPA 504 configured by OPA, and a light source 506.
  • the TxOPA 502 includes a phase shift unit 514 including an optical splitter 510 that splits light from the light source 506, and a plurality of phase shifters 512 that shift the phases of the respective lights split by the optical splitter 510, and a phase shift unit.
  • An antenna unit 518 in which a plurality of antenna elements 516 for emitting each light output from 514 to the space are arranged.
  • the RxOPA 504 also includes an antenna unit 528 in which antenna elements 526 for receiving light propagating in space are arranged, and a phase shift unit 524 including a plurality of phase shifters 522 for respectively shifting the phases of the light received by each antenna element 526. And an optical coupler 520 for combining and outputting the lights output from the phase shift unit 524.
  • the lidar device 500 also includes a photodetector 530 that receives the light output from the RxOPA 504, a steering control unit 532 that controls the operation of the phase shift units 514 and 524 of the TxOPA 502 and RxOPA 504, and a light source 506. And a control device 536 that controls the steering control unit 532 and receives the output of the photodetector 530 to perform a data generation process for, for example, spatial mapping.
  • the light source 506 is, for example, a pulse laser, and the control device 536 measures the distance to an object in space by, for example, the time of flight (TOF) method.
  • TOF time of flight
  • the optical signal from the light source 506 is incident on the TxOPA 502.
  • the steering control unit 532 operates the phase shifter 512 of the phase shift unit 514 to cause the plurality of arranged antenna elements 516 forming the antenna unit 518 of the TxOPA 502 to emit diffracted light toward the space and also to diffract the diffracted light. Beam steering is performed by changing the delivery direction to the space.
  • the steering control unit 532 controls the phase shifter 522 of the phase shift unit 524 of the RxOPA 504 so that the diffracted light of the RxOPA 504 is directed in the same direction as the diffracted light that the TxOPA 502 is currently sending.
  • the RxOPA 504 has the maximum receiving sensitivity for the light coming from the sending direction of the main lobe of the TxOPA 502 and the maximum receiving sensitivity for the light coming from the sending direction of the sidelobe of the TxOPA 502.
  • the arrangement intervals of the antenna elements 516 and 526 are set so that diffracted light adjacent to the steering angle range of the main lobe does not enter. Both are designed to be as narrow as possible, and as a result, they are designed to have the same arrangement interval p.
  • FIG. 6 is a diagram showing exemplary characteristics of the TxOPA 502 and RxOPA 504 shown in FIG.
  • the upper part of FIG. 6 shows the case where the optical phase difference generated in each optical path (each channel) from the optical input end of the optical branching device 510 to each optical output end of the antenna element 516 is zero for the TxOPA502.
  • FIG. 8 is a diagram showing a distribution of reception sensitivity of the RxOPA 504 with respect to the direction of light coming from space at that time. Further, in the lower part of FIG. 6, when the diffracted light having the light intensity distribution shown in the upper part of FIG. 6 is transmitted to the space, and the reflected return light from the space is received by the RxOPA 504 having the receiving sensitivity distribution shown in the middle part of FIG. 6 is a diagram showing a distribution of the total sensitivity of the rider device 500 in each direction in the space viewed from the rider device 500.
  • the abscissas of the upper, middle, and lower tiers are axes that indicate each direction in the XZ plane (the vertical direction in FIG. 5) by the sine value of the angle ⁇ with respect to the Z axis. ..
  • the vertical axis in the upper part of FIG. 6 is the normalized light intensity obtained by normalizing the intensity of the light transmitted from the TxOPA 502 with the maximum intensity of the main lobe.
  • the vertical axis in the middle of FIG. 6 is the normalized reception sensitivity obtained by normalizing the reception sensitivity of the RxOPA 504 by the maximum reception sensitivity value.
  • the vertical axis in the lower part of FIG. 6 is the normalized total sensitivity obtained by normalizing the total sensitivity of the lidar device 500 with its maximum value.
  • the light intensity portions 602, 604, 606, 608, 610, 612 other than the portions correspond to side lobes (diffracted light beams having a diffraction order other than zero).
  • ⁇ 0 is the center wavelength of the light output from the light source 506, and p is the array pitch of the antenna elements 516.
  • the receiving sensitivity of the RxOPA 504 shown in the middle part of FIG. 6 has the maximum portions 620 at the same positions as the light intensity parts 600, 602, 604, 606, 608, 610, 612 corresponding to the diffracted light of the TxOPA 502 in the upper part of FIG. 6, respectively. It has 622, 624, 626, 628, 630, and 632, and has a maximum portion 620 at which the reception sensitivity is maximum at the same position as the light intensity portion 600 corresponding to the main lobe of the TxOPA 502.
  • this lidar device 500 when the same phase shift is generated in each channel of the TxOPA 502 and each channel of the RxOPA 504 and the directions of the diffracted light of the TxOPA 502 and the RxOPA 504 are changed in the same manner, the light in the upper stage of FIG.
  • the intensity portion 600 and the like and the maximum portion 620 and the like in the middle of FIG. 6 are shifted in the same direction by the same amount. Further, in response to this, the maximum portions 640 and the like in the lower part of FIG. 6 are also shifted by the same amount in the same direction.
  • the maximum portion 640 of the total sensitivity when the main lobe is used is within the shift range in the horizontal direction in the figure.
  • the range of the beam steering is limited to the range of Expression (1) so that the maximum portions 642 and 644 of the total sensitivity for the adjacent side lobes do not enter.
  • the allowable range of the steering angle ⁇ is ⁇ max to + ⁇ max , and as a result, the maximum allowable range of the steering angle ⁇ is the array pitch of the antenna elements 516 and 526. Limited by the size of p.
  • the beam steering on the YZ plane also depends on the array pitch in the Y-axis direction of the antenna elements 516 and 526, similarly to the above.
  • the steering angle range is limited.
  • FIG. 7 is a diagram showing a part of the configuration of such an OPA 700
  • FIG. 8 is a diagram showing a configuration of a unit cell 710 forming the OPA 700.
  • each unit cell 710 (each of the 16 parts shown by the dotted ellipse in the figure) outputs a part of the light propagating through the row-direction bus waveguide 708 from the adjacent row-direction bus waveguide 708 to the evanescent coupler 800 (described later).
  • a column direction control wire 712 and a row direction control wire 714, which are current paths, are connected to each unit cell 710, and a phase shifter 806 (described later) included in each unit cell 710 is selectively energized.
  • each unit cell 710 includes an evanescent coupler 800 coupled to the row-direction bus waveguide 708, an antenna element 802, a waveguide 804 connecting the evanescent coupler 800 and the antenna element 802, and the waveguide 804.
  • the column direction electrodes 808 and the row direction electrodes 810 are connected to the column direction control wires 712 and the row direction control wires 714, respectively.
  • the OPA 700 shown in FIG. 7 can generate a controllable linear phase tilt along the row and/or column directions and can operate as an OPA with controllable beam steering in the XZ and YZ planes. ..
  • each unit cell 710 has many additional elements (phase shifter 806, waveguide 804, evanescent coupler 800) in addition to the antenna element 802, its size is sufficient. It cannot be made smaller. As a result, in the OPA 700 of Patent Document 1, the unit cell 710 (specifically, the antenna element 802 included in the unit cell 710) cannot be arranged with a sufficiently small pitch p in both the X direction and the Y direction. ..
  • the arrangement pitch of the unit cells 710 realized in the OPA 700 is about 9 ⁇ m, and when beam steering is performed using light with a center wavelength of 1550 nm, the allowable range of the steering angle ⁇ that can be used for the beam steering is From the formula (1), it is limited to ⁇ 5°.
  • FIG. 9 is a diagram showing the configuration of the OPA 900 according to Non-Patent Document 1.
  • the OPA 900 includes a bus waveguide 902 for inputting light, and a portion 904 that is provided on the bus waveguide 902 and is composed of thermal phase shifters and evanescent couplers that are alternately cascade-connected.
  • the light branched by the evanescent coupler is connected to the antenna unit 908 in which the antenna elements of the grating base are arranged via the waveguide line unit 906.
  • the thermal phase shifter controls the phase increment of the light sequentially input to the arrayed antenna elements, and also controls the wavelength of the light input to the bus waveguide 902 to generate a two-dimensional beam.
  • a steering function is provided.
  • a plurality of grating-based antenna elements forming the antenna unit 908 of the OPA 900 are extended in the Y direction shown in FIG. 5, and the plurality of antenna elements are arranged in the X direction. It can be configured by
  • the plurality of antenna elements forming the antenna unit 908 are configured as waveguides formed on the substrate, and the array pitch of the antenna elements (the array pitch in the X direction) is the waveguides formed as described above. Equal to the array pitch of.
  • the allowable minimum value of the array pitch of the waveguides is limited by the optical confinement strength of the waveguides. If the optical index confinement strength is increased by increasing the refractive index difference between the substrate and the waveguides, the array pitch of the antenna elements is increased. Can be narrowed. However, there is a limit to the difference in refractive index that can be realized depending on the substrate material and the like, and it is difficult to reduce the array pitch from several ⁇ m to a large extent. Therefore, in the beam steering of the OPA 900 in the X direction, the steering angle range may be limited to about several degrees, as in the case of the OPA 700 described above.
  • the OPA900 requires a wavelength tunable laser having an extremely wide wavelength tunable range as shown below, which significantly increases the cost of the entire lidar device. Can be done. Conversely, in the OPA 900, it may be difficult to realize a practical beam steering range in the Y direction without a significant increase in cost.
  • the steering angle ⁇ y of the main lobe emitted from the antenna unit 908 (the deflection angle of the main lobe in the YZ plane with respect to the Z axis) is It is calculated from equation (2).
  • n E is the effective refractive index of the waveguide constituting the antenna element
  • p g is a grating pitch which is provided to each antenna element.
  • FIG. 1 is a diagram showing a configuration of a rider device according to a first embodiment of the present invention.
  • the lidar device 100 includes a light source 106, a TxOPA 102 that outputs the output light of the light source 106 to the space, and an RxOPA 104 that receives reflected return light that is reflected back from an object in the space among the light sent from the TxOPA 102.
  • a photodetector 130 that detects the light output from the RxOPA 104.
  • the light source 106 is, for example, a pulse laser.
  • the TxOPA 102 includes an optical splitter 110 that splits the output light of the light source 106, a phase shift unit 114 that includes a plurality of phase shifters 112 that shift the phases of the lights split by the optical splitter 110, and a phase shift unit.
  • An antenna unit 118 in which a plurality of antenna elements 116 for emitting each light output from 114 to the space are arranged.
  • the antenna elements 116 are two-dimensionally arrayed, for example, along the X-axis and the Y-axis in the drawing so that the mutual intervals have an array pitch (arrangement interval) p T in the XY plane defined by the X-axis and the Y-axis. Has been done.
  • the RxOPA 104 includes an antenna unit 128 in which antenna elements 126 that receive the reflected return light are arranged, a phase shift unit 124 that includes a plurality of phase shifters 122 that shift the phase of the light received by each antenna element 126, and a phase shift unit 124. And an optical coupler 120 that combines the lights output from the shift unit 124 into one and outputs the combined light.
  • the antenna elements 126 are two-dimensionally arrayed, for example, along the X-axis and the Y-axis in the drawing so that the mutual intervals have an array pitch (array interval) p R in the XY plane defined by the X-axis and the Y-axis. Has been done.
  • the directions of the plurality of diffracted lights of the RxOPA 104 are the maximum sensitivity directions in which the respective reception sensitivities are maximized. That is, the RxOPA 104 is configured to have a plurality of maximum sensitivity directions with respect to the direction of the light coming from the space, which maximizes the reception sensitivity of the light.
  • the TxOPA 102 is an optical transmitter including a first optical phased array, and diffraction generated by light output from a plurality of first antenna elements forming the first optical phased array. It corresponds to a light transmitter that sends light to space.
  • the first optical phased array includes an optical splitter 110, a phase shift unit 114 including a phase shifter 112 which is a first phase shifter, an antenna unit 118 including an antenna element 116 which is a first antenna element, It corresponds to the part including.
  • the RxOPA 104 is an optical receiver including a second optical phased array, and is an optical receiver that receives light coming from a space by a plurality of second antenna elements forming the second optical phased array. It corresponds to a bowl.
  • the second optical phased array includes an optical coupler 120, a phase shift unit 124 including a phase shifter 122 that is a second phase shifter, an antenna unit 128 including an antenna element 126 that is a second antenna element, It corresponds to the part including.
  • the TxOPA 102 and the RxOPA 104 can be configured using the OPA described in Patent Document 1, for example. That is, the TxOPA 102 is configured such that the antenna elements 802 shown in FIG. 8 as the antenna elements 116 are two-dimensionally arranged in the XY plane at intervals (arrangement pitch) p T in the X and Y directions shown in FIG. Similarly, the RxOPA 104 is configured such that the antenna elements 802 shown in FIG. 8 as the antenna elements 126 are two-dimensionally arranged in the XY plane at intervals (arrangement pitch) p R in the X and Y directions shown in FIG.
  • phase shifter 112 of the TxOPA 102 is composed of a phase shifter 806 which is a thermal phase shifter including a heater provided on the waveguide 804 as shown in FIG. 8, for example.
  • phase shifter 122 of the RxOPA 104 is composed of a phase shifter 806 including a heater provided on the waveguide 804 as shown in FIG. 8, for example.
  • optical branching device 110 of the TxOPA 102 and the optical coupler 120 of the RxOPA 104 are both the column-direction bus waveguide 704 and the row-direction bus waveguide 704 for propagating the light from the light source 106 as shown in FIGS. 708 and evanescent couplers 706 and 800.
  • the configuration of the TxOPA 102 and the RxOPA 104 described above is an example, and the present invention is not limited to this.
  • the antenna units 118 and 128 of the TxOPA 102 and the RxOPA 104 are arbitrary as long as the antenna elements 116 and 126 for transmitting and receiving light are two-dimensionally arrayed in the illustrated XY plane at array pitches p T and p R , respectively. It may have a structure of.
  • the phase shift units 114 and 124 are not limited to the above, and are provided in each optical path that propagates the light branched by the optical branching device 110 and each optical path that propagates the light received by the antenna element 126. It can be configured by a phase shifter having an arbitrary configuration described above.
  • the optical branching device 110 and the optical coupler 120 are not limited to the above, and as long as they have the function of branching the input light and the function of multiplexing the input light and combining them into one light, respectively. In, the optical branching device and the optical coupler operating according to any configuration or principle can be used.
  • the rider device 100 also includes a control device 134 and a steering control unit 132 that is a phase shift control unit.
  • the steering control unit 132 controls the operation of the phase shifters 112 and 122 of the TxOPA 102 and the RxOPA 104 under the control of the control device 134.
  • the control device 134 synchronizes the optical pulse output operation of the light source 106 with the operation of the phase shifter 112 of the TxOPA 102 and the phase shifter 122 of the RxOPA 104, and performs space mapping and the like based on the signal from the photodetector 130. Data generation processing and the like.
  • the lidar apparatus 100 causes the steering control unit 132 to cause a desired phase shift in the phase shifters 112 and 122 under the control of the control device 134, and the emission direction of the main lobe of the TxOPA 102 and the maximum reception of the RxOPA 104 are received.
  • the beam steering is performed by changing the directions to the X direction and/or the Y direction in the drawing while maintaining the state in which the sensitivity directions are oriented in the same direction.
  • the lidar device 100 performs beam steering with the main lobe of the TxOPA 102 and receives the reflected return light from the irradiation direction of the main lobe of the TxOPA 102 with the RxOPA 104.
  • the lidar apparatus 100 measures the time from the light source 106 emitting a light pulse until the reflected return light of the light pulse is received via the RxOPA 104 by the control device 134, thereby irradiating the main lobe of the TxOPA 102.
  • the distance to the object existing in the direction is calculated by the time-of-flight method.
  • the lidar device 100 sequentially detects the reflected return light coming from the emission direction of the main lobe of the TxOPA 102 that sequentially changes according to the beam steering operation, and detects the distance to the object in the sequentially changing direction. , For example, data for space mapping etc. is generated.
  • the array pitch p T of the antenna elements 116 of the TxOPA 102 and the array pitch p R of the antenna elements 126 of the RxOPA 104 have different values, and for example, in Expression (6), It is set to have a relationship.
  • N 1 /M 1 is an irreducible function
  • M 1 and N 1 are relatively prime natural numbers.
  • the lidar device 100 has an array pitch of the antenna elements 116 of the TxOPA 102 more than that of a conventional rider device (for example, the rider device 500) configured by using TxOPA and RxOPA in which the array pitch of the antenna elements is the same value p.
  • Beam steering can be performed by changing the steering angle ⁇ of the main lobe of the TxOPA 102 in a wider range without reducing p T with respect to p. This will be described below.
  • the lidar device 100 is configured such that the array pitch p T of the antenna elements 116 of the TxOPA 102 and the array pitch p R of the antenna elements 126 of the RxOPA 104 have different values. There is. Therefore, the first angle formed by the directions of the adjacent diffracted light beams transmitted by the TxOPA 102 to each other and the second angle formed by the directions of the adjacent diffracted light beams of the RxOPA 104, that is, the second maximum angle formed by the adjacent maximum sensitivity directions are mutually formed. It is different.
  • the TxOPA 102 and the RxOPA 104 are controlled so that the directions of the main lobes of the TxOPA 102 and the RxOPA match, the direction of the side lobe adjacent to the main lobe becomes different between the TxOPA 102 and the RxOPA 104. That is, since the reception sensitivity of the RxOPA 104 transmitted from the TxOPA 102 in the direction of the adjacent side lobes does not have a maximum value, reception of light coming from the direction of the adjacent side lobes is suppressed. As a result, the steering angle range of the main lobe of the TxOPA 102 is not limited by the angle between the main lobe and the side lobes adjacent to the main lobe, and a wider steering angle range can be used.
  • the difference ⁇ T between the deflection angles (angles with respect to the Z axis) of the adjacent diffracted lights of the TxOPA 102 and the difference ⁇ R between the deflection angles of the adjacent diffracted light of the RxOPA 104 are respectively expressed by It is represented by (7) and equation (8).
  • equation (9) is established from the equations (6), (7), and (8).
  • the ratio of the first angle formed by the directions of the adjacent diffracted light beams transmitted by the TxOPA 102 to each other and the second angle formed by the adjacent maximum sensitivity directions of the RxOPA 104 are mutually disjoint. It is set to be expressed as a ratio of natural numbers.
  • Expression (9) can be expressed as Expression (10).
  • the directions of the main lobes of the TxOPA 102 and the RxOPA 104 are the same, the direction of the M 1- th sidelobe counted from the mainlobe of the TxOPA 102 and the direction of the N 1- th sidelobe of the RxOPA 104 counted from the mainlobe. However, it will be the first match. In other words, reception of the reflected light of the 1st to M 1 ⁇ 1st side lobes in the TxOPA 102 is suppressed in the RxOPA 104.
  • alpha max allowable variation range - ⁇ max ⁇ + ⁇ max of the steering angle alpha of the main lobe of TxOPA102 becomes possible determined by equation (11).
  • the arrangement pitch p T of the antenna elements 116 of the TxOPA 102 constituting the rider apparatus 100 is set to the arrangement pitch p of the TxOPA 502 of the conventional rider apparatus 500. Even if it does (that is, without setting the array pitch p T to a value smaller than p), the allowable angle range of the beam steering of the rider apparatus 100 is improved to M times the allowable angle range of the conventional rider apparatus 500.
  • the upper part of FIG. 2 is a diagram showing an example of a far-field image of the light transmitted from the antenna unit 118 of the TxOPA 102, and the middle part of FIG. 2 is a diagram showing the light reception sensitivity distribution in the RxOPA 104.
  • the lower part of FIG. 2 is a diagram showing the distribution of the total sensitivity in the lidar device 100, which is obtained as the product of the light intensity and the receiving sensitivity shown in the upper part and the middle part of FIG. 2, respectively.
  • the horizontal axis in FIG. 2 is the sine value sin ⁇ of the angle ⁇ with respect to the Z-axis direction on the XZ plane.
  • the vertical axis in the upper part of FIG. 2 is the normalized light intensity normalized by the maximum light intensity
  • the vertical axis in the middle part of FIG. 2 is the normalized reception sensitivity normalized by the maximum reception sensitivity
  • the vertical axis in the lower part of FIG. 2 is the total sensitivity. It is the normalized total sensitivity normalized by the maximum value of.
  • the arrangement pitch p T of the antenna element 116 of the TxOPA 102 is reduced by controlling the phase shifters 112 and 122 so that the direction of the main lobe of the TxOPA 102 and the direction of the main lobe of the RxOPA 104 match.
  • the change range of the beam steering angle ⁇ of the main lobe of the TxOPA 102 can be expanded to M times, that is, 6 times, as compared with the conventional lidar device.
  • the rider device 100 operates as follows.
  • beam steering is performed in the X-axis direction in the figure.
  • a dimensional beam steering operation can be performed.
  • the control device 134 of the lidar apparatus 100 controls the light source 106 to generate light pulses at regular time intervals. Further, the control device 134 instructs the steering control unit 132 to change the deflection angle ⁇ (steering angle ⁇ ) in the X direction of the main lobe sent from the TxOPA 102 to the space to perform beam steering. More specifically, the steering control unit 132 makes the phase of the light emitted from each antenna element 116 have a linear phase inclination according to the deflection angle ⁇ along the X axis, and the deflection angle ⁇ . The phase shifter 112 is controlled so that the time shifts in a predetermined pattern within a predetermined steering angle range.
  • the linear phase inclination according to the deflection angle ⁇ is expressed by the equation (12) as the phase shift amount generated in each optical path (each channel) from the optical input end of the optical branching device 110 to the output end of each antenna element 116. ) Can be implemented by setting each phase shifter 122 so that
  • the control device 134 also instructs the steering control unit 132 to control the phase shifter 122 so that the main lobe of the RxOPA 104 has the same deflection angle ⁇ as the main lobe of the TxOPA 102.
  • the steering control unit 132 causes the phase shift amount generated in each optical path (each channel) from the optical receiving end of each antenna element 126 to the optical output end of the optical coupler 120 to follow the equation (13).
  • Each phase shifter 122 is set to.
  • the phases ⁇ T (u) and ⁇ R (u) to be generated in each channel corresponding to the antenna elements 116 and 126 having the same index value u are calculated by equation (14).
  • phase shift generated in each channel of the RxOPA 104 needs to be p R /p T times the phase shift generated in each channel of the TxOPA 102.
  • the control device 134 further controls the main lobes of the TxOPA 102 and the RxOPA 104 in the same direction as described above, and the optical pulse output from the light source 106 and transmitted from the TxOPA 102 as the main lobe is received from the main lobe direction of the RxOPA 104.
  • the time to reach the object is measured, and the distance to the object existing in the main lobe direction is calculated.
  • the control device 134 can generate data for spatial mapping within the beam steering range of the main lobe of the TxOPA 102, for example.
  • the arrangement pitch p T of the antenna units 118 of the TxOPA 102 and the arrangement pitch p R of the antenna units 128 of the RxOPA 104 are configured to have the relationship of Expression (6). Not limited to, even when the array pitches p T and p R simply have different values, the side lobe directions of the TxOPA 102 and the RxOPA 104 are made different, and the allowable range of the steering angle of the main lobe of the TxOPA 102 is the same as above. Can be expanded.
  • the beam emitting portion of the antenna element 116 of the TxOPA 102 and/or the RxOPA 104 By arranging optical components such as a lens, which form the image conversion optical system, at the beam arrival portion of the antenna element 126, the substantial array pitch p converted from the diffracted light emitted from the TxOPA 102 via these optical components.
  • the allowable range of the steering angle of the main lobe of the TxOPA 102 can be expanded.
  • the first angle formed by the directions of the adjacent diffracted light beams that the TxOPA 102 sends to the space is, when the diffracted light beams of the TxOPA 102 are sent to the space through the optical components forming the image conversion optical system, It is defined by the angle between adjacent diffracted lights that are sent out into space through the optical component.
  • the second angle formed by the adjacent maximal sensitivity directions in the RxOPA 104 is the same as that before passing through the optical component when the RxOPA 104 receives light from the space via the optical component that constitutes the image conversion optical system. It is defined as an angle formed by adjacent maximal sensitivity directions in the space.
  • the first angle and the second angle are set to different values (for example, the ratio between the first angle and the second angle is relatively prime). If it is set to be a ratio of natural numbers), the allowable range of the steering angle of the main lobe of the TxOPA 102 can be expanded by the same principle as described above.
  • FIG. 3 is a diagram showing a configuration of a rider device 300 according to the second embodiment of the present invention.
  • the same components as those of the rider device 100 according to the first embodiment shown in FIG. 1 are denoted by the same reference symbols as those of FIG. 1, and the description of the rider device 100 described above is cited.
  • the same components as those of the rider device 100 according to the first embodiment shown in FIG. 1 are denoted by the same reference symbols as those of FIG. 1, and the description of the rider device 100 described above is cited.
  • the lidar device 300 has the same configuration as the lidar device 100, except that an optical unit 346 forming an image conversion optical system is arranged on the light transmission side of the antenna unit 118 of the TxOPA 102.
  • the image conversion optical system configured by the optical unit 346 in the present embodiment is, for example, a two-lens system having an image magnification K 1 configured of two convex lenses 342 and 344 having focal lengths f 1 and f 2 , respectively. It is composed of.
  • the lidar device 300 having the above-described configuration includes the optical unit 346 having the image magnification K 1 on the light transmission side of the TxOPA 102, the TxOPA 102 is substantially located at the distance f 2 from the lens 344 to the right side in the drawing. It functions as an OPA having the antenna elements 316 arranged at a 1- times arrangement pitch K 1 ⁇ p T. Therefore, by configuring the optical unit 346, the TxOPA 102, and the RxOPA 104 so that K 1 ⁇ p T ⁇ p R , the TxOPA 102 sends the light to the space like the lidar device 100 according to the first embodiment.
  • the first angle formed by the adjacent diffracted lights and the second angle formed by the adjacent maximum sensitivity directions in the space in the RxOPA 104 are made different from each other to reduce p T without reducing the main lobe of the TxOPA 102.
  • the allowable range of the steering angle can be expanded.
  • the optical unit 346, the TxOPA 102, and the RxOPA 104 are configured so that the image magnification K 1 and the array pitches p T and p R satisfy the expression (15).
  • N 2 /M 2 is an irreducible function
  • M 2 and N 2 are natural numbers that are relatively prime.
  • the image magnification K 1 is given by the equation (16) using the focal lengths f 1 and f 2 of the two lenses 342 and 344 forming the optical unit 346.
  • the difference ⁇ R in the sine values of the deflection angles of the adjacent diffracted lights (that is, the adjacent receiving sensitivity maximum directions) in the RxOPA 104 is expressed by the same formula as in the lidar device 100. It is given in (8).
  • alpha max allowable variable range - ⁇ max ⁇ ⁇ max of the steering angle alpha of the main lobe to be sent from the optical unit 346 to space is given by Equation (19).
  • the allowable range of the steering angle of the main lobe output from the TxOPA 102 and transmitted to the space is expanded without reducing the array pitch p T of the antenna elements 116 of the TxOPA 102. can do.
  • the substantial array pitch of the antenna elements 116 of the TxOPA 102 viewed from the light output side of the optical unit 346 is the array pitch p T of the TxOPA 102 itself and the image magnification K 1 of the optical unit 346. , K 1 p T , the degree of freedom in design can be further improved as compared with the rider device 100.
  • the rider device 300 operates as follows.
  • beam steering is performed in the X-axis direction in the figure.
  • a dimensional beam steering operation can be performed.
  • the rider device 300 operates in the same manner as the rider device 100 described above, but the operation of the steering control unit 332 is slightly different from that of the steering control unit 132.
  • the steering control unit 332 performs beam steering by changing the deflection angle ⁇ (steering angle ⁇ ) of the main lobe sent from the TxOPA 102 to the space in the X direction. More specifically, the steering control unit 332 causes the phase of the light emitted from the virtual antenna element 316 formed by image conversion to have a linear phase inclination according to the deflection angle ⁇ along the X axis.
  • the phase shifter 112 is controlled so that the deflection angle ⁇ changes with time in a predetermined pattern within a predetermined steering angle range.
  • the linear phase tilt corresponding to the deflection angle ⁇ is expressed by the equation (20) as the phase shift amount generated in each optical path (each channel) from the optical input end of the optical branching device 110 to the output end of each antenna element 116. It is realized by setting each phase shifter 122 so as to comply with (4).
  • phase shift amount generated in each channel of the RxOPA 104 by the phase shifter 122 so that the main lobe of the RxOPA 104 has the same deflection angle ⁇ as described above is given by the equation (13) as in the case of the rider device 100. ..
  • phase shift generated in each channel of the RxOPA 104 needs to be p R /(K 1 ⁇ p T ) times the phase shift generated in each channel of the TxOPA 102.
  • the rider device 300 is configured using the TxOPA 102 and the RxOPA 104 having the array pitches p T and p R different from each other, but the present invention is not limited to this.
  • the array pitches p T and p R may have the same value as long as the expression (15) is satisfied. That is, the lidar device 300 may be configured by using TxOPA and RxOPA in which the antenna elements are arranged at the same interval, instead of the TxOPA 102 and RxOPA104.
  • the substantial array pitch of the antenna elements 116 of the TxOPA 102 is expanded by the optical unit 346 that is the image conversion optical system configured by the two-lens system.
  • an anamorphic prism pair is used as the image conversion optical system to expand the substantial array pitch of the antenna elements 116 in the one-dimensional direction.
  • FIG. 4 is a diagram showing a configuration of a rider device 400 according to the third embodiment of the present invention. 4, the same components as those of the rider device 100 according to the first embodiment shown in FIG. 1 are assigned the same reference numerals as those shown in FIG. 1, and the description of the rider device 100 described above is cited. And
  • the lidar device 400 has the same configuration as the lidar device 100, but an optical unit 446 composed of an anamorphic prism pair composed of two prisms 442 and 444 is arranged on the light transmission side of the antenna unit 118 of the TxOPA 102. Is different.
  • the anamorphic prism pair including the two prisms 442 and 444 is configured to magnify the image in the X direction shown in the figure. Therefore, the beam steering of the main lobe of the TxOPA 102 in the Y direction in the drawing is the same as that of the rider device 100 according to the first embodiment shown in FIG.
  • the TxOPA 102 is substantially the same as the light output side of the prism 444. It functions as an OPA having antenna elements 416 arranged at a distance D from the output surface (right side in the drawing) to the left side in the drawing at an array pitch K 2 ⁇ p T of K 2 times. Therefore, by configuring the optical unit 446, the TxOPA 102, and the RxOPA 104 so that K 2 ⁇ p T ⁇ p R , in the X direction, similarly to the rider device 100 according to the first embodiment, the first unit.
  • a first angle formed by adjacent diffracted light beams transmitted by the TxOPA 102 to a space and a second angle formed by adjacent maximum sensitivity directions in the space on the RxOPA 104 are formed by a second angle.
  • the rider device 400 operates similarly to the rider device 100, and the allowable range of the steering angle of the main lobe of the TxOPA 102 is expanded without reducing pT as in the rider device 100.
  • the optical unit 446, the TxOPA 102, and the RxOPA 104 are configured so that the image magnification K 2 , the array pitch p T , and p R satisfy the expression (22).
  • the beam steering of the main lobe of the TxOPA 102 in the Y direction in the drawing is performed in the first embodiment shown in FIG. It is similar to the rider device 100 according to the embodiment. Therefore, the beam steering in the X direction in the figure will be described below.
  • N 3 /M 3 is an irreducible function
  • M 3 and N 3 are natural numbers that are relatively prime.
  • ⁇ R is the difference between the sine values of the deflection angles of the adjacent diffracted lights (that is, the adjacent receiving sensitivity maximum directions) in the RxOPA 104, and ⁇ R is the same as that of the lidar device 100. It is given by equation (8).
  • equation (24) is obtained.
  • alpha max allowable variable range - ⁇ max ⁇ ⁇ max of the steering angle alpha of the main lobe to be sent from the optical unit 446 to space is given by equation (25).
  • the main lobe output from the TxOPA 102 and transmitted to the space is output without reducing the array pitch p T of the antenna elements 116 of the TxOPA 102.
  • the allowable range of the steering angle can be expanded.
  • the substantial array pitch of the antenna elements 116 of the TxOPA 102 in the X direction viewed from the light output side of the optical unit 446 is the array pitch p T of the TxOPA 102 itself and the image magnification of the optical unit 446. Since it is given by the product of K 2 and K 2 p T , the degree of freedom in design can be further improved as compared with the rider device 100.
  • the image magnification K 2 can be determined from the geometric shape and arrangement of the prisms 442 and 444 forming the anamorphic prism pair in the optical unit 446 according to the conventional technique.
  • the distance D that defines the position of the substantial antenna element 416 formed by the presence of the optical unit 446 is determined from the image magnification K 2 and the distance from the antenna element 116 to the prism 442 according to the related art. obtain.
  • the rider device 400 specifically operates as follows.
  • the rider device 400 operates in the same manner as the rider device 100 described above, but the operation of the steering control unit 432 is different from that of the steering control unit 132.
  • the steering control unit 432 changes the deflection angle ⁇ (steering angle ⁇ ) in the X direction of the main lobe sent from the TxOPA 102 to the space via the optical unit 446 in the same manner as the steering control unit 132.
  • the phase of the light emitted from the antenna element 116 via the optical unit 446 has a linear phase inclination according to the deflection angle ⁇ along the X axis, and the deflection angle ⁇ is within a predetermined steering angle range.
  • the phase shifter 112 is controlled so that it changes with time in a predetermined pattern.
  • the linear phase tilt corresponding to the deflection angle ⁇ is expressed by the equation (26) as the phase shift amount generated in each optical path (each channel) from the optical input end of the optical branching device 110 to the output end of each antenna element 116. It is realized by setting each phase shifter 122 so as to comply with (4).
  • phase shift generated in each channel of the RxOPA 104 needs to be p R /(K 2 ⁇ p T ) times the phase shift generated in each channel of the TxOPA 102.
  • the rider device 400 is configured using the TxOPA 102 and the RxOPA 104 having the array pitches p T and p R different from each other, but the present invention is not limited to this.
  • the array pitches p T and p R may have the same value as long as the expression (22) is satisfied. That is, the lidar device 300 may be configured by using TxOPA and RxOPA in which the antenna elements are arranged at the same interval, instead of the TxOPA 102 and RxOPA104.
  • the antenna element 116 of the TxOPA 102 and the antenna element 126 of the RxOPA 104 are arranged in the XY plane at the same arrangement pitches p T and p R in the X and Y directions. Is not limited.
  • the antenna element 116 of the TxOPA 102 and the antenna element 126 of the RxOPA 104 may be configured to have different array pitches in the X direction and the Y direction.
  • the first angle formed by the adjacent diffracted lights transmitted by the TxOPA 102 to the space and the second maximum sensitivity direction formed by the adjacent RxOPA 104 in the space are formed by the second angle.
  • the allowable range of the steering angle in the X direction and the Y direction of the main lobe of the TxOPA 102 can be expanded together without reducing the arrangement pitch in the X direction and the Y direction.
  • the array pitches of the antenna elements of the TxOPA 102 and the RxOPA 104 are different from each other (for example, their ratio is different from each other, taking into consideration the image magnification of the optical components that can be provided in the light emitting portion of the TxOPA 102 and the light receiving portion of the RxOPA 104).
  • the allowable range of the steering angle of the main lobe of the TxOPA 102 can be expanded.
  • the TxOPA 102 and the RxOPA 104 are described as being configured using OPA having reciprocity for the sake of simplicity, but the present invention is not limited to this.
  • the RxOPA 104 may be one in which light propagates in one direction from the antenna element 126 to the optical output end of the optical coupler 120.
  • the maximum sensitivity direction is defined for each channel from each antenna element 126 to the optical output end of the optical coupler 120 in consideration of virtual diffracted light when light is virtually propagated in the opposite direction.
  • the range of beam steering can be expanded by using the same configuration as each of the above-described embodiments.
  • the TxOPA 102 and the RxOPA 104 are configured by using the OPA 700 as disclosed in Patent Document 1, for example, but the present invention is not limited to this.
  • the TxOPA 102 and the RxOPA 104 can be configured using the OPA 900 disclosed in Non-Patent Document 1.
  • the TxOPA 102 and the RxOPA 104 are configured by aligning the extending direction of the antenna elements of the blending base with the Y direction in FIG. 1 so that the antenna elements are arranged in the X direction of FIG.
  • the arrangement pitch of the antenna elements in the TxOPA 102 and the RxOPA 104 is set to p T and p R , respectively, and the beam steering in the X direction is expanded in the allowable angle range of the beam steering by the same configuration as that of each of the above-described embodiments. be able to.
  • FIGS. 3 and 4 are drawn assuming that the optical units 346 and 446 forming the image conversion optical system have image magnifications K 1 and K 2 that are larger than 1, respectively.
  • the image magnifications K 1 and K 2 may have values smaller than 1.
  • the image conversion optical system can be any optical system as long as it has a function of performing image conversion in at least a one-dimensional direction.
  • the lidar device 100 and the like includes the TxOPA 102 that is an optical transmitter configured by an optical phased array.
  • the TxOPA 102 sends the diffracted light generated by the light output from the antenna element 116, which is the plurality of first antenna elements forming the optical phased array, to the space.
  • the lidar device 100 and the like include an RxOPA 104 which is an optical receiver including an optical phased array.
  • the RxOPA 104 receives the light coming from the space by the antenna element 126 which is the plurality of second antenna elements forming the optical phased array.
  • the RxOPA 104 which is an optical receiver, has a plurality of maximum sensitivity directions in which the reception sensitivity of the light is maximized with respect to the direction of the light coming from the space.
  • the first angle formed by the TxOPA 102 which is an optical transmitter, in the direction of adjacent diffracted light that is transmitted to the space, and the adjacent maximum sensitivity direction in the RxOPA 104, which is the optical receiver, form each other.
  • the second angle is different from each other.
  • the lidar device 100 and the like overcome the limitation of the beam steering angle range due to the angular interval between adjacent diffracted lights determined by the array pitch p T of the antenna elements 116 of the TxOPA 102 without increasing the cost, A wider beam steering angle range can be realized.
  • the lidar device 100 and the like include a phase shifter 112 that is a first phase shifter included in the optical phased array that configures the TxOPA 102, and a phase shifter 122 that is a second phase shifter included in the optical phased array that configures the RxOPA 104.
  • a steering control unit 132 or the like which is a phase shift control unit for controlling Then, the steering control unit 132 or the like which is the phase shift control unit controls the phase shift amount of the phase shifter 112 which is the first phase shifter to control the main lobe of the diffracted light which the TxOPA 102 which is the optical transmitter sends to the space. Change the sending direction.
  • the steering control unit 132 or the like which is a phase shift control unit, is a second phase shifter so that the maximum sensitivity direction having the maximum sensitivity among the maximum sensitivity directions matches the sending direction of the main lobe of the TxOPA 102.
  • the amount of phase shift of the phase shifter 122 is controlled.
  • the receiving sensitivity of the RxOPA 104 with respect to the reflected return light coming from the transmission direction of the main lobe of the TxOPA 102 can be always maintained at the maximum.
  • the arrangement interval p T of the antenna elements 116 that are the first antenna elements and the arrangement interval p R of the antenna elements 126 that are the second antenna elements are set to different values. .. According to this configuration, the first angle formed by the adjacent diffracted light beams transmitted to the space by the TxOPA 102 and the second angle formed by the adjacent maximum sensitivity directions of the RxOPA 104 are easily different from each other. can do.
  • the ratio between the first angle and the second angle is set so as to be represented by a ratio of natural numbers that are relatively prime.
  • the allowable angle range of the beam steering of the TxOPA 102 can be expanded by the magnification determined by the natural number, as shown in the equation (11), for example.
  • the ratio of the arrangement interval p T of the antenna elements 116 that are the first antenna elements and the arrangement interval p R of the antenna elements 126 that is the second antenna element is a ratio of natural numbers that are mutually prime. It is set to be represented. According to this configuration, the ratio between the first angle and the second angle can be easily set so as to be represented by a ratio of natural numbers that are relatively prime.
  • the TxOPA 102 which is an optical transmitter, forms diffracted light generated by the light output from the antenna elements 116, which are the first plurality of antenna elements, in the image conversion optical system. It is sent to the space through the lenses 342 and 344 or the prisms 442 and 444 which are the first optical component. Then, in the lidar devices 300 and 400, the first angle is defined by the angle between adjacent diffracted lights that are sent to the space via the first optical component.
  • the first angle is set using the image magnification of the image conversion optical system. Therefore, the degree of freedom in design is improved.
  • the first optical component is composed of two convex lenses 342 and 344. With this configuration, the image conversion optical system can be easily configured.
  • the first optical component is composed of two prisms 442 and 444 which form an anamorphic prism pair. With this configuration, the image conversion optical system can be easily configured.
  • the RxOPA 104 which is an optical receiver, receives the light coming from the space through the second optical component that constitutes the image conversion optical system, and the antenna elements 126 that are the second antenna elements. Can be received by.
  • the second angle is defined as an angle formed by adjacent maximal sensitivity directions defined in the space with respect to the light received from the space and received through the second optical component. ..

Landscapes

  • Engineering & Computer Science (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Radar, Positioning & Navigation (AREA)
  • Remote Sensing (AREA)
  • Variable-Direction Aerials And Aerial Arrays (AREA)
  • Optical Radar Systems And Details Thereof (AREA)
  • Optical Modulation, Optical Deflection, Nonlinear Optics, Optical Demodulation, Optical Logic Elements (AREA)
  • Radar Systems Or Details Thereof (AREA)

Abstract

La présente invention concerne un dispositif LiDAR qui comprend : un émetteur optique qui est configuré à partir d'un premier réseau phasé optique et émet, dans un espace, une lumière diffractée produite à partir d'une sortie de lumière provenant d'une pluralité de premiers éléments d'antenne composant le premier réseau phasé optique ; et un récepteur optique qui est configuré à partir d'un deuxième réseau phasé optique et utilise une pluralité de deuxièmes éléments d'antenne composant le deuxième réseau phasé optique pour recevoir la lumière provenant de l'espace. Le récepteur optique a une pluralité de directions de sensibilité maximale locale, chacune étant une direction d'arrivée de la lumière provenant de l'espace dans lequel la sensibilité de réception de lumière est à un maximum local. Un premier angle formé entre des directions adjacentes de lumière diffractée transmise dans l'espace par l'émetteur optique est différent d'un deuxième angle formé entre des directions de sensibilité maximale locale adjacentes du récepteur optique.
PCT/JP2018/045744 2018-12-12 2018-12-12 Dispositif lidar Ceased WO2020121452A1 (fr)

Priority Applications (3)

Application Number Priority Date Filing Date Title
CN201880096931.2A CN112673273B (zh) 2018-12-12 2018-12-12 激光雷达装置
JP2018566457A JP6828062B2 (ja) 2018-12-12 2018-12-12 ライダー装置
PCT/JP2018/045744 WO2020121452A1 (fr) 2018-12-12 2018-12-12 Dispositif lidar

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
PCT/JP2018/045744 WO2020121452A1 (fr) 2018-12-12 2018-12-12 Dispositif lidar

Publications (1)

Publication Number Publication Date
WO2020121452A1 true WO2020121452A1 (fr) 2020-06-18

Family

ID=71076028

Family Applications (1)

Application Number Title Priority Date Filing Date
PCT/JP2018/045744 Ceased WO2020121452A1 (fr) 2018-12-12 2018-12-12 Dispositif lidar

Country Status (3)

Country Link
JP (1) JP6828062B2 (fr)
CN (1) CN112673273B (fr)
WO (1) WO2020121452A1 (fr)

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20210095957A1 (en) * 2019-09-27 2021-04-01 Asml Holding N.V. Lithographic Apparatus, Metrology Systems, Phased Array Illumination Sources and Methods thereof
JP2022013729A (ja) * 2020-07-03 2022-01-18 三星電子株式会社 向上したsn比を有するライダー装置
WO2023219880A1 (fr) * 2022-05-11 2023-11-16 Analog Photonics LLC Gestion de performance de réseau à commande de phase optique sur la base de distributions d'intensité angulaire
WO2025006461A3 (fr) * 2023-06-28 2025-04-17 Analog Photonics LLC Configurations de réseau pour direction de faisceau optique

Families Citing this family (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN115685136A (zh) * 2021-07-30 2023-02-03 北京万集科技股份有限公司 光学相控阵芯片及相控阵激光雷达
CN115685220B (zh) * 2021-07-30 2025-10-31 武汉万集光电技术有限公司 目标探测方法、opa激光雷达及计算机可读存储介质
CN116413737A (zh) * 2021-12-31 2023-07-11 上海新微技术研发中心有限公司 一种激光雷达及其控制方法
US12009604B2 (en) * 2022-07-20 2024-06-11 Cisco Technology, Inc. Visual antenna aiming

Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2016508235A (ja) * 2013-01-08 2016-03-17 マサチューセッツ インスティテュート オブ テクノロジー 光フェーズドアレイ
JP2017072532A (ja) * 2015-10-09 2017-04-13 富士通株式会社 距離測定装置、距離測定方法、距離測定プログラムおよびテーブルの作成方法
JP2017083467A (ja) * 2016-12-27 2017-05-18 アクト電子株式会社 鉄道車両速度計測方法及びその計測装置
WO2018165633A1 (fr) * 2017-03-09 2018-09-13 California Institute Of Technology Réseau d'émetteurs-récepteurs optiques co-primes
JP2018156059A (ja) * 2017-03-15 2018-10-04 パナソニックIpマネジメント株式会社 光スキャンシステム

Family Cites Families (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN108896978B (zh) * 2018-06-27 2022-01-04 上海交通大学 基于奈奎斯特脉冲的集成激光雷达

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2016508235A (ja) * 2013-01-08 2016-03-17 マサチューセッツ インスティテュート オブ テクノロジー 光フェーズドアレイ
JP2017072532A (ja) * 2015-10-09 2017-04-13 富士通株式会社 距離測定装置、距離測定方法、距離測定プログラムおよびテーブルの作成方法
JP2017083467A (ja) * 2016-12-27 2017-05-18 アクト電子株式会社 鉄道車両速度計測方法及びその計測装置
WO2018165633A1 (fr) * 2017-03-09 2018-09-13 California Institute Of Technology Réseau d'émetteurs-récepteurs optiques co-primes
JP2018156059A (ja) * 2017-03-15 2018-10-04 パナソニックIpマネジメント株式会社 光スキャンシステム

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20210095957A1 (en) * 2019-09-27 2021-04-01 Asml Holding N.V. Lithographic Apparatus, Metrology Systems, Phased Array Illumination Sources and Methods thereof
US11994808B2 (en) * 2019-09-27 2024-05-28 Asml Holding N.V. Lithographic apparatus, metrology systems, phased array illumination sources and methods thereof
JP2022013729A (ja) * 2020-07-03 2022-01-18 三星電子株式会社 向上したsn比を有するライダー装置
JP7699966B2 (ja) 2020-07-03 2025-06-30 三星電子株式会社 向上したsn比を有するライダー装置
WO2023219880A1 (fr) * 2022-05-11 2023-11-16 Analog Photonics LLC Gestion de performance de réseau à commande de phase optique sur la base de distributions d'intensité angulaire
US12461423B2 (en) 2022-05-11 2025-11-04 Analog Photonics LLC Managing optical phased array performance based on angular intensity distributions
WO2025006461A3 (fr) * 2023-06-28 2025-04-17 Analog Photonics LLC Configurations de réseau pour direction de faisceau optique

Also Published As

Publication number Publication date
JPWO2020121452A1 (ja) 2021-02-15
JP6828062B2 (ja) 2021-02-10
CN112673273B (zh) 2024-03-12
CN112673273A (zh) 2021-04-16

Similar Documents

Publication Publication Date Title
JP6828062B2 (ja) ライダー装置
US11971589B2 (en) Photonic beam steering and applications for optical communications
US11448729B2 (en) Optical deflection device and LIDAR apparatus
US12429746B2 (en) Optical beam scanning based on waveguide switching and position-to-angle conversion of a lens and applications
JP2022109947A (ja) チップスケール波長分割多重通信LiDARを操作する方法と波長分割多重通信LiDARシステム
CN114731208B (zh) 波长选择开关
JP2023120335A (ja) 周波数変調連続波光を検出および距離測定のためのスイッチング可能なコヒーレントピクセルアレイ
López et al. Planar-lens enabled beam steering for chip-scale LIDAR
Phare et al. Silicon optical phased array with high-efficiency beam formation over 180 degree field of view
JP7076822B2 (ja) 光受信器アレイ、及びライダー装置
US12019268B2 (en) Serpentine optical phased array with dispersion matched waveguides
JP6513884B1 (ja) 光フェーズドアレイ、及びこれを用いたlidarセンサ
KR20200094789A (ko) 레이저 빔의 편향을 위한 장치
JP6942333B2 (ja) 光偏向デバイス、及びライダー装置
WO2023284399A1 (fr) Dispositif de commande de faisceau et procédé de commande de faisceau
US20240410987A1 (en) SWITCHED PIXEL ARRAY LiDAR SENSOR AND PHOTONIC INTEGRATED CIRCUIT
JP6513885B1 (ja) 光集積回路、並びにこれを用いた光フェーズドアレイ及びLiDARセンサ
CN109444851B (zh) 激光发射机构及相控阵激光雷达
JP2018173537A (ja) 光導波路素子及びレーザレーダ
CN114994908A (zh) 一种透镜辅助的二维光束扫描装置
US11543730B1 (en) Phase shifter architecture for optical beam steering devices
JPWO2020115856A1 (ja) レーザレーダ装置
KR20240018320A (ko) 스캐닝 장치 및 라이다 장치

Legal Events

Date Code Title Description
ENP Entry into the national phase

Ref document number: 2018566457

Country of ref document: JP

Kind code of ref document: A

121 Ep: the epo has been informed by wipo that ep was designated in this application

Ref document number: 18943170

Country of ref document: EP

Kind code of ref document: A1

NENP Non-entry into the national phase

Ref country code: DE

122 Ep: pct application non-entry in european phase

Ref document number: 18943170

Country of ref document: EP

Kind code of ref document: A1