JP6270529B2 - Laser radar equipment - Google Patents

Description

  The present invention relates to a laser radar device, and more particularly, to a laser radar device that can detect an abnormality in a circuit on a light receiving side.

  Conventionally, by dividing and inputting a control voltage for controlling the gain of the power amplifier circuit to the comparator that detects an abnormality in the output level of the power amplifier circuit, and changing the failure detection level according to the N-stage output level, It has been proposed to improve failure detection accuracy (see, for example, Patent Document 1).

  By the way, although it is assumed that a plurality of amplification units for amplifying the received light signal are provided in the circuit on the light receiving side of the laser radar device, in Patent Document 1, it is considered to detect an abnormality in the amplification unit of the plurality of stages. Absent.

Japanese Utility Model Publication No. 3-28586

  The present invention has been made in view of such a situation, and makes it possible to easily and reliably detect an abnormality in a circuit on the light receiving side of a laser radar device.

The laser radar device of the present invention is a laser radar device that detects an object using laser light, a light projecting unit that projects laser light, a light receiving element that receives reflected light of the laser light, and a pulse-like inspection. a light emitting element for irradiating light to the light receiving element, and select the amplification of multiple amplifying sequentially with each variable gain received light signals from the light receiving element, from among the combinations of a plurality of predetermined gains one in order while setting the gain of each amplifying unit Te, each time to set the gain of each amplifying unit, based on the peak value of the amplified received signal by the amplification portion of the multiple when irradiated with inspection light receiving element, Each of the amplifying units, and the number of types of gain combinations is equal to the variable number of the amplifying unit having the largest variable number of gains, and each amplifying unit can set at least one gain. Two gain combinations It is included in the.

In the laser radar device of the present invention, the gain of each amplification unit is selected one by one from a predetermined combination of a plurality of gains, and each time the gain of each amplification unit is set, the inspection light is emitted. based on the peak value of the amplified received signal by the amplification portion of the multiple when irradiated to the light receiving element, the inspection of each amplification unit is performed.

  Therefore, it is possible to easily and reliably detect an abnormality in a circuit on the light receiving side of the laser radar device, particularly an abnormality in a plurality of stages of amplifiers.

  For example, the light projecting unit includes a drive circuit, a light emitting element, a light projecting optical system, and the like. This light receiving element is formed of, for example, a photodiode. This light emitting element consists of LED, for example. The amplifying unit includes, for example, various amplifiers, TIA, and the like. This inspection unit is configured by an arithmetic device such as a microcomputer and various processors, for example.

  The inspection unit can set the order of changing the gain combination so that the total value of the gain changes every time the gain combination is changed.

  As a result, it is possible to quickly and reliably detect an abnormality in which the gain of the amplification unit is not changed.

  The type of gain combination can be set so that the type of gain total value is minimized under the condition that the total value of gain is changed each time the gain combination is changed.

  As a result, the number of thresholds used for inspection can be reduced, and the possibility of inspection errors can be reduced.

  The upper limit of the difference between the minimum value and the maximum value of the gains of the combinations of the gains can be set based on the dynamic range of the A / D conversion unit that performs A / D conversion on the amplified received light signal.

  Thereby, the accuracy of inspection can be improved.

  The inspection unit can be inspected during a pause period in which the laser light projection is suspended between measurement periods in which the laser light is projected and the reflected light is measured.

  Accordingly, the amplification unit can be inspected while detecting the object with the laser beam.

  According to the present invention, it is possible to detect an abnormality in a circuit on the light receiving side of a laser radar device. In particular, according to the present invention, it is possible to easily and reliably detect an abnormality in a plurality of stages of amplification units on the light receiving side of the laser radar device.

It is a block diagram which shows one Embodiment of the laser radar apparatus to which this invention is applied. It is a block diagram which shows the structural example of a measurement light projector. It is a block diagram which shows the structural example of a test | inspection light emission part and a light-receiving part. It is a figure which shows the position of each detection area typically. It is a schematic diagram which shows the relationship between each light receiving element and each detection area. It is a block diagram which shows the structural example of a measurement part. It is a schematic diagram which shows the structural example of the function of a multiplexer. It is a block diagram which shows the structural example of the function of a calculating part. It is a flowchart for demonstrating a monitoring process. It is a flowchart for demonstrating an object detection process. It is a timing chart for explaining object detection processing. It is a figure for demonstrating the integration process of a light reception value. It is a figure which shows the example of the combination of the light receiving element allocated to each measurement period. 5 is a flowchart for explaining failure diagnosis processing 1; It is a flowchart for demonstrating an inspection light measurement process. It is a figure which shows typically the example of the measurement result of the light reception value in the failure diagnosis process 1. FIG. 7 is a flowchart for explaining failure diagnosis processing 2; It is a figure for demonstrating the specific example of the failure diagnosis process 2. FIG. It is a figure which shows typically the example of the measurement result of the light reception value in the failure diagnosis process 2. FIG. It is a figure for demonstrating the specific example of the failure diagnosis process 2. FIG. It is a figure for demonstrating the specific example of the failure diagnosis process 2. FIG. It is a figure for demonstrating the specific example of the failure diagnosis process 2. FIG. It is a block diagram which shows the structural example of a computer.

Hereinafter, modes for carrying out the present invention (hereinafter referred to as embodiments) will be described. The description will be given in the following order.
1. Embodiment 2. FIG. Modified example

<1. Embodiment>
{Configuration example of laser radar device 11}
FIG. 1 shows a configuration example of a laser radar device 11 which is an embodiment of a laser radar device to which the present invention is applied.

  The laser radar device 11 is provided in a vehicle, for example, and monitors the front of the vehicle. Hereinafter, an area in which an object can be detected by the laser radar device 11 is referred to as a monitoring area. Hereinafter, when it is necessary to distinguish a vehicle provided with the laser radar device 11 from other vehicles, the vehicle is referred to as a host vehicle. Further, hereinafter, a direction parallel to the left-right direction (vehicle width direction) of the host vehicle is referred to as a horizontal direction.

  The laser radar device 11 is configured to include a control unit 21, a measuring light projecting unit 22, an inspection light emitting unit 23, a light receiving unit 24, a measuring unit 25, and a computing unit 26.

  The control unit 21 controls each unit of the laser radar device 11 based on commands and information from the vehicle control device 12.

  The measurement light projector 22 projects measurement light, which is pulsed laser light (laser pulse) used to detect an object, onto the monitoring area.

  The inspection light emitting unit 23 emits inspection light used for inspection of the light receiving unit 24 and the measuring unit 25 and irradiates the light receiving unit 24.

  The light receiving unit 24 receives the reflected light or the inspection light of the measurement light, and detects the intensity (brightness) of the reflected light or the inspection light from different horizontal directions. Then, the light receiving unit 24 outputs a plurality of light receiving signals that are electrical signals corresponding to the intensity of reflected light or inspection light in each direction.

  The measurement unit 25 measures the light reception value for the reflected light from the light receiving unit 24 based on the analog light reception signal supplied from the light receiving unit 24, and supplies the digital light reception signal indicating the measured light reception value to the calculation unit 26. To do.

  The calculation unit 26 detects an object in the monitoring area based on the measurement result of the light reception value supplied from the measurement unit 25 and supplies the detection result to the control unit 21 and the vehicle control device 12. The calculation unit 26 controls the inspection light emitting unit 23, the light receiving unit 24, and the measuring unit 25 via the control unit 21 to inspect the light receiving unit 24 and the measuring unit 25.

  The vehicle control device 12 is configured by, for example, an ECU (Electronic Control Unit) or the like, and performs automatic brake control, a warning to the driver, or the like based on the detection result of the object in the monitoring area.

{Configuration example of measuring light projector 22}
FIG. 2 shows a configuration example of the measurement light projector 22 of the laser radar device 11. The measuring light projecting unit 22 is configured to include a drive circuit 101, a light emitting element 102, and a projecting optical system 103.

  The drive circuit 101 controls the light emission intensity and the light emission timing of the light emitting element 102 under the control of the control unit 21.

  The light emitting element 102 is composed of, for example, a laser diode (LD), and emits measurement light (laser pulse) under the control of the drive circuit 101. The measurement light emitted from the light emitting element 102 is projected onto the monitoring area via the light projecting optical system 103 constituted by a lens or the like.

{Configuration example of inspection light emitting unit 23 and light receiving unit 24}
FIG. 3 shows a configuration example of the inspection light emitting unit 23 and the light receiving unit 24 of the laser radar device 11. The inspection light emitting unit 23 is configured to include a drive circuit 151 and a light emitting element 152. The light receiving unit 24 is configured to include a light receiving optical system 201 and light receiving elements 202-1 to 202-16.

  Hereinafter, the light receiving elements 202-1 to 202-16 are simply referred to as the light receiving elements 202 when it is not necessary to distinguish them individually.

  The drive circuit 151 controls the light emission intensity and the light emission timing of the light emitting element 152 under the control of the control unit 21.

  The light emitting element 152 is made of, for example, an LED (Light Emitting Diode), and emits inspection light made up of pulsed LED light under the control of the drive circuit 151. The inspection light emitted from the light emitting element 152 is directly irradiated on the light receiving surface of each light receiving element 202 without passing through an optical system such as a lens.

  The light receiving optical system 201 is configured by a lens or the like, and is installed so that the optical axis faces the front-rear direction of the vehicle. The light receiving optical system 201 receives the reflected light of the measurement light reflected by an object or the like in the monitoring area, and makes the reflected light incident on the light receiving surface of each light receiving element 202.

  Each light receiving element 202 is composed of, for example, a photodiode (PD) having substantially the same performance. Each light receiving element 202 is perpendicular to the optical axis of the light receiving optical system 201 and parallel to the vehicle width direction of the host vehicle (that is, horizontal) at the position where the reflected light incident on the light receiving optical system 201 is collected. In the direction). Then, the reflected light incident on the light receiving optical system 201 is distributed and incident on each light receiving element 202 according to the incident angle in the horizontal direction to the light receiving optical system 201. Therefore, each light receiving element 202 receives reflected light from different directions in the horizontal direction among the reflected light from the monitoring region. Thereby, the monitoring area is divided into a plurality of areas (hereinafter referred to as detection areas) in a plurality of horizontal directions, and each light receiving element 202 individually receives the reflected light from the corresponding detection area. The light receiving element 202 photoelectrically converts the received reflected light into a light receiving signal having a current value corresponding to the amount of light received, and supplies the obtained light receiving signal to the measuring unit 25.

  Here, a specific example of the detection region of each light receiving element 202 will be described with reference to FIGS. 4 and 5. FIG. 4 schematically shows the position of each detection region when the host vehicle C provided with the laser radar device 11 is viewed from above. FIG. 5 schematically shows the relationship between each light receiving element 202 and each detection region when the light receiving unit 24 is viewed from above. In FIG. 5, only the light rays passing through the center of the lens of the light receiving optical system 201 out of the reflected light from each detection region are schematically shown for easy understanding of the drawing.

  The light receiving elements 202 are arranged in a line in the order of the light receiving elements 202-1, 202-2, 202-3... From the right in the traveling direction of the host vehicle C. On the other hand, the monitoring area of the laser radar device 11 is composed of detection areas A1 to A16 that radiate in front of the host vehicle C, and each detection area is a detection area from the left in the traveling direction of the host vehicle C. A1, A2, A3... Are arranged in this order. The light receiving element 202-1 receives the reflected light from the detection area A1, which is the left end in the monitoring area and indicated by the oblique line on the left front of the host vehicle C. The light receiving element 202-16 receives reflected light from the detection area A16, which is the right end in the monitoring area and indicated by the oblique line in front of the right side of the host vehicle C. Furthermore, the light receiving elements 202-8 and 202-9 receive the reflected light from the detection areas A8 and A9 indicated by the hatching in the center of the monitoring area.

  Each light receiving element 202 photoelectrically converts the inspection light from the light emitting element 152 into a light receiving signal having a current value corresponding to the amount of received light, and supplies the obtained light receiving signal to the measuring unit 25.

{Configuration example of measuring unit 25}
FIG. 6 shows a configuration example of the measurement unit 25 of the laser radar device 11. The measurement unit 25 is configured to include a selection unit 251, a current-voltage conversion unit 252, an amplification unit 253, and a sampling unit 254. The selection unit 251 is configured to include multiplexers (MUX) 261-1 to 261-4. The current-voltage conversion unit 252 is configured to include trans-impedance amplifiers (TIAs) 262-1 to 262-4. The amplification unit 253 is configured to include programmable gain amplifiers (PGA) 263-1 to 263-4. The sampling unit 254 is configured to include A / D converters (ADC) 264-1 to 264-4.

  The light receiving elements 202-1 to 202-4 are connected to the MUX 261-1, the light receiving elements 202-5 to 202-8 are connected to the MUX 261-2, and the light receiving elements 202-9 to 202-12 are connected to the MUX 261-3. The light receiving elements 202-13 to 202-16 are connected to the MUX 261-4. Further, MUX261-1, TIA262-1, PGA263-1, and ADC264-1 are connected in series, MUX261-2, TIA262-2, PGA263-2, and ADC264-2 are connected in series, and MUX261-3, TIA262- 3, PGA263-3 and ADC264-3 are connected in series, and MUX261-4, TIA262-4, PGA263-4 and ADC264-4 are connected in series.

  Hereinafter, when it is not necessary to individually distinguish the MUXs 261-1 to 261-4, the TIAs 262-1 to 262-4, the PGAs 263-1 to 263-4, and the ADCs 264-1 to 264-4, respectively. They will be referred to as MUX261, TIA262, PGA263, and ADC264.

  Each MUX 261 selects one or more light receiving signals supplied from the light receiving elements 202 connected thereto under the control of the control unit 21 and supplies the selected light receiving signals to the subsequent TIA 262. When each MUX 261 selects a plurality of light reception signals, the MUX 261 adds the selected light reception signals and supplies them to the TIA 262 at the subsequent stage.

  Each TIA 262 performs current-voltage conversion of the received light signal supplied from the MUX 261 under the control of the control unit 21. That is, each TIA 262 converts the received light signal as an input current into a received light signal as a voltage, and amplifies the voltage of the converted received light signal with a gain set by the control unit 21. Each TIA 262 supplies the amplified light reception signal to the subsequent PGA 263.

  Each PGA 263 amplifies the voltage of the light reception signal supplied from the TIA 262 with the gain set by the control unit 21 under the control of the control unit 21, and supplies the amplified signal to the ADC 264 in the subsequent stage.

  As described above, the TIA 262 and the PGA 263 form a two-stage amplifying unit, and the light reception signal is sequentially amplified with the set gain.

  Each ADC 264 performs A / D conversion of the received light signal. That is, each ADC 264 measures a light reception value by sampling an analog light reception signal supplied from the PGA 263 under the control of the control unit 21. Each ADC 264 supplies a digital light reception signal indicating a sampling result (measurement result) of the light reception value to the arithmetic unit 26.

  Hereinafter, a set of MUX 261, TIA 262, PGA 263, and ADC 264 connected in series is also referred to as a line.

{Configuration example of MUX261}
FIG. 7 schematically shows an example of the functional configuration of the MUX 261.

  The MUX 261 includes a decoder 271, input terminals IN1 to IN4, switch units C1 to C4, and an output terminal OUT1. One ends of the switch portions C1 to C4 are connected to the input terminals IN1 to IN4, respectively, and the other ends of the switch portions C1 to C4 are connected to the output terminal OUT1.

  Hereinafter, the input terminals IN1 to IN4 and the switch units C1 to C4 are simply referred to as the input terminal IN and the switch unit C when it is not necessary to distinguish them individually.

  The decoder 271 decodes the selection signal supplied from the control unit 21 and switches each switch unit C on / off individually according to the content of the decoded selection signal. Then, a light reception signal input to the input terminal IN connected to the switch part C that is turned on is selected and output from the output terminal OUT1. When there are a plurality of switch portions C that are turned on, a plurality of selected light reception signals are added and output from the output terminal OUT1.

  In addition, the switch part C can be comprised by either an electronic switch like a mechanical switch or a semiconductor switch, for example.

{Configuration example of calculation unit 26}
FIG. 8 shows an example of the functional configuration of the calculation unit 26.

  The calculation unit 26 is configured to include an integration unit 301, a detection unit 302, an inspection unit 303, and a notification unit 304. The detection unit 302 is configured to include a peak detection unit 311 and an object detection unit 312.

  The integrating unit 301 integrates the received light values of the same light receiving element 202 at each sampling time, and supplies the integrated value (hereinafter referred to as an integrated received light value) to the peak detecting unit 311. Further, the integrating unit 301 supplies the light reception value measurement result based on the light reception signal supplied from each ADC 264 to the inspection unit 303.

  The peak detection unit 311 detects the peak in the horizontal direction and the time direction (distance direction) of the intensity of the reflected light of the measurement light based on the integrated light reception value (the intensity of the reflected light) of each light receiving element 202, and obtains the detection result. It supplies to the object detection part 312.

  The object detection unit 312 detects an object in the monitoring region based on the horizontal and time direction (distance direction) distribution and peak detection result of the integrated light reception value (reflected light intensity), and controls the detection result. To the unit 21 and the notification unit 304.

  The inspection unit 303 controls each part of the laser radar device 11 via the control unit 21 and inspects the light receiving element 202, MUX 261, TIA 262, and PGA 263. Then, the inspection unit 303 detects the presence / absence of abnormality of the light receiving element 202, the MUX 261, the TIA 262, and the PGA 263 based on the measurement result of the light reception value with respect to the inspection light. The inspection unit 303 supplies the inspection result to the control unit 21 and the notification unit 304.

  The notification unit 304 supplies the detection result of the object in the monitoring area and the inspection result by the inspection unit 303 to the vehicle control device 12.

{Monitoring process}
Next, the monitoring process executed by the laser radar device 11 will be described with reference to the flowchart of FIG. Note that this processing is started when, for example, an ignition switch or a power switch of a vehicle provided with the laser radar device 11 is turned on, and is ended when the vehicle is turned off.

  In step S1, the inspection unit 303 sets the value of the failure flag to 0.

  In step S2, the inspection unit 303 performs pre-measurement failure diagnosis. Although detailed description of failure diagnosis before measurement is omitted, for example, failure diagnosis of the light receiving element 202 and the like is performed.

  In step S3, the inspection unit 303 sets the value of the variable m to 1.

  In step S4, the laser radar apparatus 11 performs an object detection process. Here, the details of the object detection processing will be described with reference to the flowchart of FIG.

  In step S51, each MUX 261 selects the light receiving element 202. Specifically, each MUX 261 selects a light reception signal to be supplied to the subsequent TIA 262 from among the light reception signals input to each MUX 261 under the control of the control unit 21. In the following processing, the light reception value of the light receiving element 202 that is the output source of the selected light reception signal is measured. In other words, the intensity of the reflected light from the detection region of the selected light receiving element 202 is measured.

  In step S52, the measurement light projector 22 projects measurement light. Specifically, the drive circuit 101 emits pulsed measurement light from the light emitting element 102 under the control of the control unit 21. The measurement light emitted from the light emitting element 102 is projected onto the entire monitoring region via the light projecting optical system 103.

  In step S53, the light receiving unit 24 generates a light reception signal corresponding to the reflected light. Specifically, each light receiving element 202 receives the reflected light from the detection region in the corresponding direction among the reflected light with respect to the measurement light projected in the process of step S52 via the light receiving optical system 201. Each light receiving element 202 photoelectrically converts the received reflected light into a light receiving signal that is an electrical signal corresponding to the amount of light received, and supplies the obtained light receiving signal to the subsequent MUX 261.

  In step S54, the measurement unit 25 samples the received light signal. Specifically, each TIA 262 performs current-voltage conversion of the light reception signal supplied from each MUX 261 under the control of the control unit 21 and amplifies the voltage of the light reception signal by the gain set by the control unit 21. To do. Each TIA 262 supplies the amplified received light signal to the subsequent PGA 263.

  Under the control of the control unit 21, each PGA 263 amplifies the voltage of the light reception signal supplied from each TIA 262 with the gain set by the control unit 21, and supplies the amplified signal to the subsequent ADC 264.

  Each ADC 264 performs sampling of the light reception signal supplied from each PGA 263 under the control of the control unit 21, and A / D converts the light reception signal. Each ADC 264 supplies the light reception signal after A / D conversion to the integration unit 301.

  The details of the sampling process of the received light signal will be described later with reference to FIG.

  In step S55, the integration unit 301 integrates the light reception values up to the previous time and the current light reception values. As a result, as will be described later with reference to FIG. 12, the received light values at the same sampling time of the received light signals from the same light receiving element 202 are integrated. Further, the integration unit 301 executes the integration process of the received light values in parallel for the received light signals output from the respective ADCs 264. Thereby, the integration of the received light values of the four light receiving elements 202 is performed individually in parallel.

  In step S56, the control unit 21 determines whether or not the light reception value has been measured a predetermined number of times (for example, 100 times). If it is determined that the received light value has not been measured a predetermined number of times, the process returns to step S52.

  Thereafter, the processes in steps S52 to S56 are repeatedly executed until it is determined in step S56 that the received light value has been measured a predetermined number of times. Thus, the process of projecting the measurement light and measuring the light reception value of the selected light receiving element 202 is repeated a predetermined number of times within a measurement period of a predetermined length described later. Further, the measured light reception values are integrated.

  On the other hand, if it is determined in step S56 that the light reception value has been measured a predetermined number of times, the process proceeds to step S57.

  In step S57, the control unit 21 determines whether or not the measurement period has been repeated a predetermined number of times (for example, four times). If it is determined that the measurement period has not been repeated a predetermined number of times, the process returns to step S51.

  Thereafter, the processes in steps S51 to S57 are repeatedly executed until it is determined in step S57 that the measurement period is repeated a predetermined number of times. That is, the measurement period is repeated a predetermined number of times within a detection period of a predetermined length described later. In addition, for each measurement period, a light receiving element 202 that is a target for measuring a light reception value is selected, and a detection region that is a target for measuring the intensity of reflected light is switched.

  On the other hand, if it is determined in step S57 that the measurement period has been repeated a predetermined number of times, the process proceeds to step S58.

  Here, a specific example of the processing of steps S51 to S57 will be described with reference to FIGS.

  FIG. 11 is a timing chart showing a specific example of the sampling process of the received light signal, and the horizontal axis of each figure in the figure shows time.

  The uppermost stage in FIG. 11 shows the emission timing of the measurement light. The detection periods TD1, TD2,... Are the minimum unit of the period for performing the object detection process, and the object detection process is performed once in one detection period.

  Each detection period includes four cycles of measurement periods TM1 to TM4 and a pause period TB. The measurement period is a minimum unit for switching the light receiving element 202 for measuring the light reception value. That is, the light receiving element 202 can be selected before each measurement period, while the light receiving element 202 cannot be changed during the measurement period. Therefore, the light reception value of the same light receiving element 202 is measured in one measurement period. Thereby, the detection area | region used as the object which measures the intensity | strength of reflected light per measurement period can be switched.

  The second row in FIG. 11 is an enlarged view of the measurement period TM2 of the detection period TD1. As shown in this figure, measurement light is projected a predetermined number of times (for example, 100 times) at a predetermined interval within a measurement period of one cycle.

  The third row in FIG. 11 shows the waveform of the trigger signal that defines the sampling timing of the ADC 264, and the fourth row shows the sampling timing of the received light signal in the ADC 264. The vertical axis in the fourth row indicates the value (voltage) of the light reception signal, and a plurality of black circles on the light reception signal indicate sampling points, respectively. Therefore, the time between adjacent black circles is the sampling interval.

  The control unit 21 supplies a trigger signal to each ADC 264 after a predetermined time has elapsed since the measurement light was projected. Each ADC 264 samples the received light signal a predetermined number of times (for example, 32 times) at a predetermined sampling frequency (for example, several tens to several hundreds of MHz) after a predetermined time has elapsed since the trigger signal was input. That is, each time the measurement light is projected, the received light signal selected by the MUX 261 is sampled a predetermined number of times at a predetermined sampling interval.

  For example, if the sampling frequency of the ADC 264 is 100 MHz, sampling is performed at a sampling interval of 10 nanoseconds. Therefore, the received light value is sampled at intervals of about 1.5 m in terms of distance. That is, the intensity of the reflected light from each point at intervals of about 1.5 m in the distance direction from the host vehicle in each detection region is measured.

  Each ADC 264 supplies a digital light reception signal indicating a sampling value (light reception value) at each sampling time with the trigger signal as a reference (the time when the trigger signal is input is 0) to the integration unit 301.

  In this way, each time the measurement light is projected, the light reception signal of each light receiving element 202 selected by the MUX 261 is sampled in parallel. That is, the light reception signals of the respective light receiving elements 202 selected by the MUX 261-1, MUX 261-2, MUX 261-3, and MUX 261-4 are paralleled by the ADC 264-1, ADC 264-2, ADC 264-3, and ADC 264-4, respectively. Sampling is performed. Thereby, the intensity of the reflected light in the detection region of each selected light receiving element 202 is measured in a predetermined distance unit.

  On the other hand, the pause period TB is set between the measurement period TM4 and the measurement period TM1 of the next detection period, and the projection of the measurement light and the measurement of the received light value are paused. Then, the object detection process based on the measurement result of the light reception value in the measurement periods TM1 to TM4 and the failure diagnosis processes 1 and 2 described later are executed during the suspension period TB.

  Next, a specific example of the light reception value integration process will be described with reference to FIG. FIG. 12 shows an example of integration processing for 100 received light signals output from a certain light receiving element 202 when measuring light is projected 100 times during a measurement period of one cycle. The horizontal axis in FIG. 12 indicates the time (sampling time) with the trigger signal input timing as a reference (time 0), and the vertical axis indicates the received light value (sampling value).

  As shown in this figure, for each measurement light from the first time to the 100th time, the received light signal is sampled at sampling times t1 to ty, and the received light values at the same sampling time are integrated. For example, the received light values at the sampling time t1 for each measurement light from the first time to the 100th time are integrated. In this manner, the received light values at the same sampling time of the received light signals from the same light receiving element 202 sampled within the detection period are integrated. This integrated value is used for subsequent processing.

  Here, when the light receiving signals from the plurality of light receiving elements 202 are added in the MUX 261, for example, the light receiving value of the light receiving signal obtained by adding the light receiving signals from the light receiving elements 202-1 and 202-2 is the light receiving element 202-1 or It is integrated separately from the light receiving value of the light receiving signal from only one of the light receiving elements 202-2. In other words, the light reception value of the light reception signal obtained by adding the light reception signals from the light reception elements 202-1 and 202-2 and the light reception value of the light reception signal from only one of the light reception elements 202-1 or 202-2. These are distinguished as light reception values obtained by sampling different types of light reception signals, and integrated separately.

  By performing this integration processing, even when the S / N ratio of the received light signal with respect to one measurement light is low, the signal component is amplified, and random noise is averaged and reduced. As a result, the signal component and the noise component can be easily separated from the light reception signal, and the light reception sensitivity can be substantially increased. Thereby, for example, the detection accuracy of a distant object or an object with low reflectivity is improved. In addition, the light reception sensitivity increases as the number of integration increases.

  Hereinafter, a set of measurement processing and integration processing performed a predetermined number of times (for example, 100 times) executed within one cycle of the measurement period is referred to as a measurement integration unit.

  FIG. 13 shows an example of a combination of the light receiving elements 202 selected by each MUX 261 in each measurement period. In this figure, MUXs 261-1 to 261-4 are abbreviated as MUX1 to MUX4. Further, the numbers in the squares in the figure indicate the numbers of the light receiving elements 202 selected by the MUXs 261-1 to 261-4. That is, the light receiving elements 202-1 to 202-16 are indicated by numbers 1 to 16, respectively.

  For example, in the measurement period TM1, the light receiving elements 202-1, 202-5, 202-9, and 202-13 are selected by the MUXs 261-1 to 261-4, and the light reception values of the selected light receiving elements 202 are measured. Done. In the measurement period TM2, the light receiving elements 202-2, 202-6, 202-10, and 202-14 are selected by the MUXs 261-1 to 261-4, and the light reception values of the selected light receiving elements 202 are measured. . In the measurement period TM3, the light receiving elements 202-3, 202-7, 202-11, and 202-15 are selected by the MUXs 261-1 to 261-4, and the light reception values of the selected light receiving elements 202 are measured. . In the measurement period TM4, the light receiving elements 202-4, 202-8, 202-12, and 202-16 are selected by the MUXs 261-1 to 261-4, respectively, and the light reception value of each selected light receiving element 202 is measured. .

  Therefore, in this example, the light reception values of all the light receiving elements 202 are measured within one detection period. In other words, the intensity of reflected light from all the detection areas in the monitoring area is measured within one detection period.

  Returning to FIG. 10, in step S58, the peak detector 311 performs peak detection. Specifically, the integrating unit 301 supplies the integrated received light value of each light receiving element 202 within one detection period to the peak detecting unit 311. The peak detection unit 311 detects the peak in the horizontal direction and the time direction (distance direction) of the intensity of the reflected light within the detection period based on the distribution of the integrated light reception value at each sampling time of each light receiving element 202.

  Specifically, the peak detector 311 detects the sampling time at which the integrated light reception value peaks for each light receiving element 202. That is, the peak detector 311 detects the peak in the time direction of the integrated light reception value of each light receiving element 202. Thereby, the point where the intensity of the reflected light peaks in the distance direction from the host vehicle is detected for each detection region. In other words, in each detection region, the distance from the host vehicle at a point where the intensity of the reflected light reaches a peak is detected.

  In addition, the peak detector 311 detects the light receiving element 202 (detection region) where the integrated light reception value peaks at each sampling time. That is, the peak detector 311 detects the horizontal peak of the integrated light reception value at each sampling time. Thereby, in the distance direction from the host vehicle, the horizontal position (detection region) where the intensity of the reflected light peaks at every predetermined interval (for example, about every 1.5 m) is detected.

  Then, the peak detection unit 311 supplies the detection result to the object detection unit 312.

  Note that any method can be adopted as the peak detection method of the peak detection unit 311.

  In step S59, the object detection unit 312 detects an object. Specifically, the object detection unit 312 detects other vehicles and pedestrians in the monitoring area based on the horizontal and temporal distributions and peak detection results of the received light value (reflected light intensity) within the detection period. The presence / absence of an object such as an obstacle, the type, direction, and distance of the object are detected. The object detection unit 312 supplies the detection result to the control unit 21 and the notification unit 304.

  Note that any method can be employed as the object detection method of the object detection unit 312.

  In step S60, the notification unit 304 notifies the object detection result to the outside as necessary. For example, the notification unit 304 periodically supplies the object detection result to the vehicle control device 12 regardless of the presence or absence of the object. Alternatively, for example, the notification unit 304 supplies the object detection result to the vehicle control device 12 only when there is a risk that the vehicle collides with an object ahead.

  Thereafter, the object detection process ends.

  Returning to FIG. 9, in step S <b> 5, the laser radar device 11 executes the failure diagnosis process 1. Here, the details of the failure diagnosis processing 1 will be described with reference to FIG.

  As described above, the failure diagnosis processing 1 and the failure diagnosis processing 2 described later are performed during the suspension period TB of FIG. Further, the failure diagnosis processing 1 and the failure diagnosis processing 2 can be executed in parallel with the processing of steps S58 to S60 in FIG. 10, for example.

  In step S <b> 101, each MUX 261 selects the light receiving element 202. Specifically, the inspection unit 303 instructs the control unit 21 to execute the failure diagnosis process 1. Then, one light reception signal supplied from each MUX 261 to the subsequent TIA 262 is selected one by one by the same process as Step S51 of FIG. At this time, the light reception signal to be selected is arbitrary, and any light reception signal may be selected. However, during execution of the failure diagnosis process 1, the selected light reception signal is fixed and never changed.

  In step S102, the control unit 21 sets gains of the TIA 262 and the PGA 263. Hereinafter, an example in which the gain of TIA 262 can be set from two types of values of 0 dB and 18 dB and the gain of PGA 263 can be set from three types of values of 6 dB, 24 dB, and 42 dB will be described. In this case, there are six types of combinations of gains of TIA 262 and PGA 263 in total.

  Then, for example, the control unit 21 sets the gain of each TIA 262 to 18 dB and sets the gain of each PGA 263 to 24 dB. As a result, the total gain of each pair of TIA 262 and PGA 263 is 42 dB.

  In step S103, the laser radar device 11 performs an inspection light measurement process. Here, the details of the inspection light measurement process will be described with reference to the flowchart of FIG.

  In step S <b> 151, each ADC 264 starts sampling under the control of the control unit 21. Each ADC 264 starts supplying a digital light reception signal indicating a sampling value (light reception value) to the integration unit 301.

  In step S152, the inspection light emitter 23 emits inspection light. Specifically, the drive circuit 151 emits pulsed inspection light from the light emitting element 152 under the control of the control unit 21. The inspection light emitted from the light emitting element 152 is directly irradiated on the light receiving surface of each light receiving element 202 without passing through the light receiving optical system 201.

  In step S153, each ADC 264 ends sampling under the control of the control unit 21. In addition, each ADC 264 stops the supply of the light reception signal to the integrating unit 301.

  In step S154, the inspection unit 303 acquires a measurement result. That is, the inspection unit 303 acquires the measurement result (sampling result) of the light reception value of each line by each ADC 264 from the start to the end of sampling from the integration unit 301. In addition, since the measurement of the light reception value with respect to the inspection light is performed only once, the light reception value is not integrated in the integration unit 301.

  Thereafter, the inspection light measurement process ends.

  Returning to FIG. 14, in step S <b> 104, the inspection unit 303 determines whether or not threshold value 1 <light reception value <threshold value 2.

  FIG. 16 schematically shows an example of the measurement result of the received light value. As shown in this example, after the pulsed inspection light is emitted, the received light value changes in a pulse shape, and a large peak appears. Then, the inspection unit 303 detects the peak of the light reception value of each line, and compares each detected peak with the threshold value 1 and the threshold value 2. If it is determined that at least one of the peaks of the light reception values of each line is the threshold value 1 or less or the threshold value 2 or more, the process proceeds to step S105.

  Note that the threshold 1 is set, for example, as a sum of gains of the TIA 262 and the PGA 263 is larger than 24 dB (total gain set in the process of step S106 described later) and 42 dB (processes of the steps S102 and S110). It is set to a standard value of the light reception value for the inspection light when it is set to a predetermined value (for example, 33 dB) smaller than the total gain). For example, the threshold value 2 is set to a standard value of the light reception value with respect to the inspection light when the sum of the gains of the TIA 262 and the PGA 263 is set to a predetermined value larger than 42 dB (for example, 51 dB).

  In step S105, the inspection unit 303 sets the value of the failure flag to 1. That is, the inspection unit 303 determines that a gain abnormality has occurred in at least one of the TIA 262 and the PGA 263 connected to the line in which the light reception value abnormality has occurred. Here, for example, an abnormality such as a gain not switching or a large gain error is assumed as an abnormality of the gain.

  Thereafter, the process proceeds to step S106.

  On the other hand, if it is determined in step S104 that the peaks of the light reception values of each line are all greater than the threshold 1 and less than the threshold 2, the process of step S105 is skipped, and the process proceeds to step S106.

  In step S106, the control unit 21 changes the gains of the TIA 262 and the PGA 263. For example, the control unit 21 sets the gain of each TIA 262 to 18 dB, and sets the gain of each PGA 263 to 6 dB. As a result, the total gain of each pair of TIA 262 and PGA 263 is 24 dB.

  In step S107, the inspection light measurement process is executed in the same manner as the process in step S103.

  In step S108, the inspection unit 303 determines whether or not the light reception value ≦ the threshold value 1 by the same process as in step S106. When it is determined that at least one of the peaks of the light reception values of each line is greater than the threshold value 1, the process proceeds to step S109.

  In step S109, the value of the failure flag is set to 1 by the same processing as in step S105.

  On the other hand, when it is determined in step S108 that the peaks of the light reception values of each line are all equal to or less than the threshold value 1, the process of step S109 is skipped, and the process proceeds to step S110.

  In step S110, the control unit 21 changes the gains of the TIA 262 and the PGA 263. For example, the control unit 21 sets the gain of each TIA 262 to 0 dB, and sets the gain of each PGA 263 to 42 dB. As a result, the total gain of each pair of TIA 262 and PGA 263 is 42 dB.

  In step S111, the inspection light measurement process is executed in the same manner as the process in step S103.

  In step S112, it is determined whether threshold value 1 <light-receiving value <threshold value 2 is satisfied by the same processing as in step S104. If it is determined that at least one of the peaks of the light reception values of each line is the threshold value 1 or less or the threshold value 2 or more, the process proceeds to step S113.

  In step S113, the value of the failure flag is set to 1 by the same processing as in step S105. Thereafter, the process proceeds to step S114.

  On the other hand, if it is determined in step S112 that the peaks of the light reception values of each line are all greater than the threshold value 1 and less than the threshold value 2, the process of step S113 is skipped, and the process proceeds to step S114.

  In step S114, the control unit 21 returns the gains of the TIA 262 and the PGA 263 to their original values. That is, the control unit 21 returns the gains of the TIA 262 and the PGA 263 to values before the execution of the failure diagnosis process 1.

  Thereafter, the failure diagnosis process 1 ends.

  By this failure diagnosis process 1, the gain of each TIA 262 and PGA 263 can be quickly inspected to detect an abnormality reliably. That is, there are two types of gains for TIA 262 and three types of gains for PGA 263, and there are a total of six types of gain combinations. In this process, all gains of each TIA 262 and PGA 263 are obtained with only three types of gain combinations. Can be inspected.

  For example, each TIA 262 and PGA 263 requires a predetermined time (for example, 100 μs) before the operation is stabilized after the gain is changed. Therefore, by reducing the types of gain combinations to be inspected, the time required for the failure diagnosis process 1 can be shortened. This makes it possible to reliably execute the failure diagnosis processing 1 and the failure diagnosis processing 2 within the suspension period.

  Note that the types and order of gain combinations for failure diagnosis are set based on the following conditions, for example.

  First, the types of gain combinations are set so as to include all the settable gains of the TIA 262 and the PGA 263. That is, the type of gain combination is set so that each settable gain of the TIA 262 and the PGA 263 is always included in one or more combinations.

  Further, the number of types of gain combinations is set to a value (that is, three types) equal to the variable number of the PGA 263 having a large gain variable number among the TIA 262 and the PGA 263. That is, the gain combination types are set so that the number of gain combination types is minimized under the condition that all of the settable gains of the TIA 262 and the PGA 263 are included.

  Furthermore, it is desirable to set the order of changing the gain combination so that the total value of the gain changes each time the gain combination is changed. Thereby, it is possible to quickly and reliably detect an abnormality in which the gains of the TIA 262 and the PGA 263 are not changed.

  Further, it is desirable to set the type of gain combination so that the type of the total value of gain is minimized under the condition that the total value of gain is changed every time the combination of gain is changed. For example, when three types of gain combinations are used for fault diagnosis, it is desirable to set the types of gain combinations so that there are two types of gain total values that are less than three types. By reducing the types of gain total values in this way, the number of threshold values used in the failure diagnosis process 1 can be reduced, and the possibility that a failure diagnosis error will occur can be reduced.

  Furthermore, it is desirable to set the type of gain combination so that the upper limit of the difference between the minimum value and the maximum value of the gains in each gain combination falls within a predetermined range. This upper limit value is set based on the dynamic range of the ADC 264, for example.

Specifically, for example, a 9 bits the number of bits of ADC264, the lower 3 bits is assumed to be the noise level, the dynamic range of ADC264 becomes ^{36dB (= 20log (2 9/} 2 3)). Further, when a variation of ± 3 dB is allowed in the measurement result of the received light value, the substantial dynamic range of the ADC 264 is 30 dB (= 36 dB−6 dB). In this case, it is desirable to set the type of gain combination so that the difference between the minimum value and the maximum value of the total gain value in each gain combination is 30 dB or less.

  In addition, it is desirable to set the order of changing the gain combination so that the difference between the total gain values before and after changing the gain combination is larger than the maximum variation of the light reception value measurement results. For example, in the above-described example, it is desirable to set the order of changing the gain combination so that the difference between the total gain values before and after the gain combination is greater than 6 dB.

  Then, the inspection unit 303 selects gain combinations one by one according to the order satisfying the above conditions from the plurality of gain combinations set as described above, The gains of the TIA 262 and the PGA 263 are set. The inspection unit 303 sets the gain based on the peak value of the light reception signal amplified by each TIA 262 and PGA 263 when the light receiving element 202 is irradiated with the inspection light via the control unit 21 every time the gain is set. Failure diagnosis of each TIA 262 and PGA 263 is performed.

  Returning to FIG. 9, in step S <b> 6, the laser radar device 11 executes the failure diagnosis process 2. Here, the details of the failure diagnosis processing 2 will be described with reference to FIG.

  In step S201, the inspection unit 303 sets the value of the variable n to 2.5−m × 1.5. In the first failure diagnosis process 2, since the value of the variable m is set to 1, the value of the variable n is set to 1.

  In step S202, each MUX 261 turns on the switch unit Cn and turns off the other switch units. Specifically, the inspection unit 303 instructs the control unit 21 to execute the failure diagnosis process 2. The control unit 21 turns on the switch unit Cn of each MUX 261 and turns off the other switch units.

  For example, in the first failure diagnosis process 2, since the value of the variable n is set to 1, the switch unit C1 of the MUX 261-1 is turned on and the switch units C2 to C4 are turned off as shown in FIG. Is done. Similarly, in the other MUX 261, the switch unit C1 is turned on and the switch units C2 to C4 are turned off.

  In step S203, the inspection light measurement process described above with reference to FIG. 15 is executed.

  For example, in the first failure diagnosis process 2, as shown in FIG. 18, the light reception value of the light receiving element 202-1 connected to the switch unit C1 of the MUX 261-1 is measured. Similarly, the light reception value of the light receiving element 202 connected to the switch unit C1 of the other MUX 261 is measured. When no abnormality occurs in particular, as schematically shown in FIG. 19, a pulsed peak corresponding to the inspection light appears in the measurement result of the received light value.

  Note that the decoder 271 of the MUX 261-1 is not shown in FIG. 18 and FIGS.

  In step S204, the inspection unit 303 determines whether inspection light is detected. Specifically, the inspection unit 303 detects the peak of the light reception value of each line measured by each ADC 264. If the peak value of at least one line is less than a predetermined threshold, the inspection light is detected in that line. The process proceeds to step S205.

  In step S205, the inspection unit 303 sets the value of the failure flag to 1. That is, the inspection unit 303 includes the switch unit C of the MUX 261 that is turned on in the process of step S202 in the line where the inspection light is not detected, the light receiving element 202 connected to the switch unit C, and the light receiving element. It is determined that there is a high possibility that an abnormality such as disconnection has occurred in at least one of the circuits from 202 to the MUX 261.

  Thereafter, the process proceeds to step S206.

  On the other hand, in step S204, the inspection unit 303 determines that inspection light has been detected in all the lines when the peaks of the light reception values of the respective lines are equal to or greater than the predetermined threshold value, and the process in step S205 is skipped. Advances to step S206.

  In step S206, the inspection unit 303 adds m to the value of the variable n. In the first failure diagnosis process 2, since the value of the variable m is set to 1, the value of the variable n is incremented by one.

  In step S207, the control unit 21 turns on the switch unit Cn of each MUX 261.

  For example, in the first process of step S207 of the first failure diagnosis process 2, since the value of the variable n is set to 2, in addition to the switch unit C1 of the MUX 261-1, as shown in FIG. Thus, the switch unit C2 is turned on. Similarly, in the other MUX 261, the switch unit C2 is turned on in addition to the switch unit C1.

  In step S208, the inspection light measurement process described above with reference to FIG. 15 is executed.

  For example, in the first process of step S207 of the first failure diagnosis process 2, the sum of the received light values of the light receiving elements 202-1 and 202-2 connected to the switch units C1 and C2 of the MUX 261-1 is calculated. Measured. Similarly, the added value of the light reception values of the light receiving elements 202 connected to the switch units C1 and C2 of the other MUX 261 is measured. When no abnormality occurs in particular, as shown at the right end of FIG. 20, the peak of the light reception value of each line is about twice the peak of the light reception value shown in FIG.

  In step S209, the inspection unit 303 determines whether or not the amount of change in the received light value is within a predetermined range. Specifically, the inspection unit 303 detects the peak of the light reception value of each line, and calculates the amount of change with respect to the peak of the light reception value measured last time. If the inspection unit 303 determines that the peak change amount of the light reception value of at least one line is not within the predetermined range, the process proceeds to step S210.

  In step S210, the inspection unit 303 sets the value of the failure flag to 1. That is, the inspection unit 303 is connected to the switch unit C of the MUX 261 newly set to ON in the process of step S207 and the switch unit C in the line where the change amount of the peak of the received light value does not fall within the predetermined range. It is determined that there is a high possibility that an abnormality such as disconnection has occurred in at least one of the light receiving element 202 and the circuit from the light receiving element 202 to the output terminal of the MUX 261.

  In step S211, the inspection unit 303 determines whether the value of the variable n is 1 or 4. If it is determined that the value of the variable n is not 1 or 4, the process returns to step S206, and then the processing of steps S206 to S211 until it is determined in step S211 that the value of the variable n is 1 or 4. Is repeated.

  For example, in the second process of step S207 of the first failure diagnosis process 2, the value of the variable n is set to 3, and the switches C1 to C3 of the MUX 261-1 are turned on as shown in FIG. The Then, an addition value of the light reception values of the light receiving elements 202-1 to 202-3 connected to the switch units C1 to C3 is measured. Similarly, the added value of the light receiving values of the light receiving elements 202 connected to the switch units C1 to C3 of the other MUX 261 is measured. Then, when no abnormality has occurred, as shown at the right end of FIG. 21, the peak of the light reception value of each line is about three times the peak of the light reception value shown in FIG. 18, and the light reception value shown in FIG. This is about 1.5 times the peak value. When it is determined that the peak change amount of the light reception value of at least one line is not within the predetermined range, the value of the failure flag is set to 1.

  Next, in the third process of step S207, the value of the variable n is set to 4, and the switch units C1 to C4 of the MUX 261-1 are turned on as shown in FIG. Then, an addition value of the light reception values of the light receiving elements 202-1 to 202-4 connected to the switch units C1 to C4 is measured. Similarly, the added value of the light reception values of the light receiving elements 202 connected to the switch units C1 to C4 of the other MUX 261 is measured. If no abnormality has occurred, the peak of the light reception value of each line is about four times the peak of the light reception value shown in FIG. 18 and the light reception shown in FIG. This is about twice the value peak and about 4/3 times the received light value peak shown in FIG. When it is determined that the peak change amount of the light reception value of at least one line is not within the predetermined range, the value of the failure flag is set to 1.

  On the other hand, if it is determined in step S211 that the value of the variable n is 1 or 4, the process proceeds to step S212.

  In step S212, the inspection unit 303 sets the value of the variable m to −m. As a result, in step S212 of the first failure diagnosis processing 2, the value of the variable m is set to -1, and in step S212 of the second failure diagnosis processing 2, the value of the variable m is set to 1. In addition, the value of the variable m is alternately set to 1 or -1.

  When the variable m is set to 1, as described above, the switch unit of each MUX 261 is turned on in the order of the switch unit C1, the switch unit C2, the switch unit C3, and the switch unit C4. Each time is turned on, the amount of change in the received light value with respect to the inspection light is determined. On the other hand, when the variable m is set to −1, each time the switch unit is turned on while the switch unit of each MUX 261 is turned on in the order of the switch unit C4, the switch unit C3, the switch unit C2, and the switch unit C1. In addition, the amount of change in the received light value with respect to the inspection light is determined.

  For example, when the switch unit C1, the switch unit C2, the switch unit C3, and the switch unit C4 are always turned on in this order, there is a possibility that the abnormality cannot be detected even if the switch unit C1 is not turned off. However, by switching the turn-on order of the switch parts alternately in this way, it is possible to reliably detect the abnormality when the switch part C1 is not turned off.

  Thereafter, the failure diagnosis process 2 ends.

  By this failure diagnosis processing 2, the state of the switch unit C of each MUX 261 is sequentially switched, and the abnormality of each light receiving element 202 and each MUX 261 is detected quickly and reliably by merely measuring the light reception value for the inspection light of each line. It becomes possible. In addition, the circuit configuration and processing can be simplified and more efficient than the case where failure diagnosis of each light receiving element 202 and each MUX 261 is performed individually.

  Further, since the abnormality determination is performed based on the relative change amount of the light reception value peak, not the absolute value of the light reception value peak, each light receiving element 202 and each An abnormality of the MUX 261 can be reliably detected. For example, when the number of light receiving elements 202 connected to the TIA 262 via the MUX 261 increases, the frequency characteristics of the TIA 262 temporarily deteriorate, but by performing a failure determination based on the amount of change in the peak of the received light value, Despite the deterioration of the frequency characteristics, the abnormality of the light receiving element 202 and the MUX 261 can be reliably detected.

  Note that the order of the failure diagnosis process 1 and the failure diagnosis process 2 can be switched.

  Returning to FIG. 9, in step S <b> 7, the inspection unit 303 determines whether or not the failure flag is “1”. If it is determined that the failure flag is not 1, that is, if no abnormality is detected in failure diagnosis processing 1 and 2, the processing returns to step S4.

  Thereafter, the processes in steps S4 to S7 are repeatedly executed until it is determined in step S7 that the failure flag is 1. That is, while performing the object detection process, the process of executing the failure diagnosis processes 1 and 2 is repeated during the pause period of each detection period.

  On the other hand, if it is determined in step S7 that the failure flag is 1, that is, if an abnormality is detected in at least one of the failure diagnosis processes 1 and 2, the monitoring process ends. At this time, the inspection unit 303 may notify the outside that an abnormality has been detected.

  As described above, in parallel with the object detection process, the light receiving side circuit of the laser radar device 11, that is, the light receiving element 202, the MUX 261, the TIA 262, the PGA 263, and the circuit connecting them are tested (failure diagnosis). It can be carried out.

<2. Modification>
Hereinafter, modifications of the above-described embodiment of the present invention will be described.

{Variation regarding device configuration}
The configuration of the laser radar device 11 is not limited to the example shown in FIG. 1 and can be changed as necessary.

  For example, it is possible to integrate the control unit 21 and the calculation unit 26 or to change the sharing of functions.

  Further, for example, the number of light receiving elements 202, MUX 261, TIA 262, PGA 263, and ADC 264 can be increased or decreased as necessary.

  Furthermore, for example, the number of light receiving elements 202 connected to one MUX 261 can be changed. For example, the number of light receiving elements 202 connected to each MUX 261 does not necessarily have to be the same. Furthermore, for example, the combination of the light receiving elements 202 connected to each MUX 261 is not limited to the example described above, and can be arbitrarily changed.

{Variant related to fault diagnosis}
The failure diagnosis processing 1 and the failure diagnosis processing 2 do not necessarily have to be performed every detection period, and may be executed once every predetermined number of detection periods, for example. Further, it is not always necessary to perform the failure diagnosis processing 1 and the failure diagnosis processing 2 continuously. For example, the frequency and timing of performing the failure diagnosis processing 1 and the failure diagnosis processing 2 are changed, and a detection period in which only one of them is performed is set. You may make it provide.

  In the above description, an example in which the amplification unit that amplifies the received light signal has two stages of TIA 262 and PGA 263 has been described. However, the above-described failure diagnosis processing 1 is performed even when the amplification unit has three or more stages. Can be applied.

  Regardless of the number of stages of the amplifying units, the types and order of gain combinations when performing the failure diagnosis processing 1 are set according to the above-described conditions. That is, the type of gain combination is set so as to include all of the gains that can be set for each amplification unit. In addition, the number of types of gain combinations is set to a value where the variable number of gains is equal to the variable number of the maximum amplifying unit.

  Furthermore, it is desirable to set the order of changing the gain combination so that the total value of the gain changes each time the gain combination is changed. Further, it is desirable to set the type of gain combination so that the type of the total value of gain is minimized under the condition that the total value of gain is changed every time the combination of gain is changed. Further, the combination of gains so that the upper limit of the difference between the minimum value and the maximum value of the total gain of each gain combination is less than or equal to the substantial dynamic range of the ADC that performs A / D conversion on the amplified received light signal. It is desirable to set the type. In addition, it is desirable to set the order of changing the gain combination so that the difference between the total gain values before and after changing the gain combination is larger than the maximum variation of the light reception value measurement results.

{Application example of the present invention}
The failure diagnosis processing 1 can be applied regardless of the presence or absence of MUX and the parallel number of the light receiving element and the amplifying unit, as long as the light receiving signal from the light receiving element is amplified by a plurality of stages of amplifying units. It is. For example, the failure diagnosis processing 1 can be applied to a laser radar apparatus in which one TIA 262, PGA 263, and ADC 264 are provided for each one of the light receiving elements 202 without using the MUX 261.

  Further, in the failure diagnosis process 2, two or more light reception signals are inputted, each light reception signal can be individually selected, and a laser radar provided with one or more MUXs that can add and output a plurality of light reception signals. Any device can be applied.

  Furthermore, the present invention can also be applied to a laser radar device used for other purposes than for vehicles.

[Computer configuration example]
The series of processes described above can be executed by hardware or can be executed by software. When a series of processing is executed by software, a program constituting the software is installed in the computer. Here, the computer includes, for example, a general-purpose personal computer capable of executing various functions by installing various programs by installing a computer incorporated in dedicated hardware.

  FIG. 23 is a block diagram illustrating a configuration example of hardware of a computer that executes the above-described series of processing by a program.

  In a computer, a CPU (Central Processing Unit) 601, a ROM (Read Only Memory) 602, and a RAM (Random Access Memory) 603 are connected to each other by a bus 604.

  An input / output interface 605 is further connected to the bus 604. An input unit 606, an output unit 607, a storage unit 608, a communication unit 609, and a drive 610 are connected to the input / output interface 605.

  The input unit 606 includes a keyboard, a mouse, a microphone, and the like. The output unit 607 includes a display, a speaker, and the like. The storage unit 608 includes a hard disk, a nonvolatile memory, and the like. The communication unit 609 includes a network interface or the like. The drive 610 drives a removable medium 611 such as a magnetic disk, an optical disk, a magneto-optical disk, or a semiconductor memory.

  In the computer configured as described above, the CPU 601 loads the program stored in the storage unit 608 to the RAM 603 via the input / output interface 605 and the bus 604 and executes the program, for example. Is performed.

  The program executed by the computer (CPU 601) can be provided by being recorded on a removable medium 611 as a package medium, for example. The program can be provided via a wired or wireless transmission medium such as a local area network, the Internet, or digital satellite broadcasting.

  In the computer, the program can be installed in the storage unit 608 via the input / output interface 605 by attaching the removable medium 611 to the drive 610. Further, the program can be received by the communication unit 609 via a wired or wireless transmission medium and installed in the storage unit 608. In addition, the program can be installed in the ROM 602 or the storage unit 608 in advance.

  The program executed by the computer may be a program that is processed in time series in the order described in this specification, or in parallel or at a necessary timing such as when a call is made. It may be a program for processing.

  The embodiments of the present technology are not limited to the above-described embodiments, and various modifications can be made without departing from the gist of the present technology.

DESCRIPTION OF SYMBOLS 11 Laser radar apparatus 12 Vehicle control apparatus 21 Control part 22 Measurement light projection part 23 Inspection light light emission part 24 Light reception part 25 Measurement part 26 Calculation part 102 Light emitting element 151 Drive circuit 152 Light emitting element 202-1 thru | or 202-16 Light receiving element 251 Selection unit 252 Current-voltage conversion unit 253 Amplification unit 254 Sampling unit 261-1 to 261-4 Multiplexer 262-1 to 262-4 Trans-impedance amplifier (TIA)
263-1 to 263-4 Programmable Gain Amplifier (PGA)
264-1 to 264-4 A / D converter 301 Integration unit 302 Detection unit 303 Inspection unit 304 Notification unit 311 Peak detection unit 312 Object detection unit

Claims (5)

In a laser radar device that detects an object using laser light,
A light projecting unit that projects the laser light;
A light receiving element for receiving the reflected light of the laser beam;
A light emitting element for irradiating the light receiving element with pulsed inspection light; and
An amplifier portion of the multiple amplifying sequentially with each variable gain received light signals from the pre-Symbol light receiving element,
Each time the gain of each amplifying unit is set while selecting the gain of each amplifying unit one by one from among a plurality of predetermined gain combinations, the light receiving element is irradiated with the inspection light based on the peak value of the received light signal amplified by the amplifying portion of the multiple time, and a test unit for inspecting each of said amplifying unit,
The number of types of combinations of gains is equal to the variable number of the amplifying units having the largest variable number of gains, and each gain that can be set by each amplifying unit is included in at least one of the gain combinations apparatus. The laser radar device according to claim 1, wherein the inspection unit sets an order of changing the gain combination so that a total value of the gain changes every time the gain combination is changed. The type of the combination of gains is set so that the type of the total value of gains is minimized under a condition that the total value of gains is changed every time the combination of gains is changed. Laser radar device. The upper limit of the difference between the minimum value and the maximum value of the total gain of each of the gain combinations is set based on the dynamic range of an A / D converter that performs A / D conversion on the amplified received light signal. The laser radar device according to any one of 1 to 3. 5. The inspection unit performs the inspection during a pause period in which the laser light projection is suspended between measurement periods in which the laser light is projected and the reflected light is measured. 5. The laser radar device described.

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