Patent Publication Number: US-2020301011-A1

Title: Range finding device and range finding method

Description:
CROSS-REFERENCE TO RELATED APPLICATION 
     This application claims priority pursuant to 35 U.S.C. § 119(a) to Japanese Patent Application Nos. 2019-053171, filed on Mar. 20, 2019, and 2019-162233, filed on Sep. 5, 2019 in the Japan Patent Office, the disclosure of which is incorporated by reference herein in its entirety. 
     BACKGROUND 
     Technical Field 
     This disclosure relates to a range finding device and a range finding method. 
     Background Art 
     A range to an object existing in a range finding area can be detected or found using a method of emitting a laser beam toward the range finding area, receiving a reflection light reflected from the object existing in the range finding area, and calculating a distance to the object using a time difference between a start time when the laser beam is emitted and a time when the light reflected from the object is received. The range finding method is known as the time-of-flight (TOF) method or system. A range finding device that measures the range or distance to objects using the TOF system is referred to as a TOF camera or range finding camera. Further, the range finding device can be also referred to as an image capture apparatus or TOF camera. 
     In the range finding device (TOF camera) using the TOF method, the light-receiving level (the amount of received light) of the reflection light coming from the object is a critical factor. If the light receiving level is too low, the sensor output signal is not distinguishable from the noise signal, and if the light reception level is too high, the sensor output signal becomes saturated, with which the range or distance to object cannot be computed accurately. 
     One technology includes a light-receiving unit having a light receiving surface, and a lighting unit that emits the light, in which the intensity of light emitted from the lighting unit is controlled so that the light receiving surface receives the light amount of normal level to obtain an accurate range finding value. 
     This image capture apparatus (TOF camera) performs the exposure control based on the measured light amount of the target range finding area. That is, when the light-receiving unit measures the exposed light amount, if the measured light amount is equal to or greater than a given value (e.g., normal value), the intensity of light emitted from the lighting unit is reduced, and if the measured light amount is lower than the given value, the intensity of light emitted from the lighting unit is increased. However, this image capture apparatus (TOF camera) may not cope with a situation that the light intensity of the reflection light fluctuates or varies depending on a distance from the image capture apparatus (TOF camera) to a target object when the light is emitted from the lighting unit and then the light reflected from the object reaches the image capture apparatus (TOF camera). 
     SUMMARY 
     In one aspect of the present invention, a range finding device is devised. The range finding device includes a light-emitting unit including a plurality of light-emitting regions arranged in a two-dimensional array, configured to emit light from each of the plurality of light-emitting regions; an optical element configured to guide the light emitted from the light-emitting unit to a range finding area; a light-receiving unit configured to receive light reflected from a target object existing in the range finding area when the light emitted from the light-emitting unit hits the target object and reflects from the target object, the light-receiving unit being divided into a plurality of light receiving regions; and circuitry configured to control light emission amount of each of the plurality of light-emitting regions of the light-emitting unit respectively corresponding to the plurality of light receiving regions of the light-receiving unit; measure an amount of light received at each of the light receiving regions of the light-receiving unit; measure a distance to the target object for each of the light receiving regions of the light-receiving unit by measuring a time difference between a start time when the light is emitted from the light-emitting unit and a time when the light reflected from the target object is received by each of the light receiving regions of the light-receiving unit; cause each of the plurality of light-emitting regions of the light-emitting unit to emit the light with the same light amount as a preliminary light emission stage; control the light emission amount of each of the plurality of light-emitting regions of the light-emitting unit to be used for a main light emission stage corresponding to a range finding operation of the target object based on the amount of light received at each of the light receiving regions of the light-receiving unit that was measured at the preliminary light emission stage; and measure the distance to the target object for each of the light receiving regions of the light-receiving unit by performing the range finding operation at the main light emission stage. 
     In another aspect of the present invention, a method of finding a range to a target object is devised. The method includes emitting light from a light-emitting unit including a plurality of light-emitting regions arranged in a two-dimensional array; guiding the light emitted from the light-emitting unit to a range finding area using an optical element; receiving, using a light-receiving unit, light reflected from the target object existing in the range finding area when the light emitted from the light-emitting unit hits the target object and reflects from the target object, the light-receiving unit being divided into a plurality of light receiving regions; controlling light emission amount of each of the plurality of light-emitting regions of the light-emitting unit respectively corresponding to the plurality of light receiving regions of the light-receiving unit; measuring an amount of light received at each of the light receiving regions of the light-receiving unit; measuring a distance to the target object for each of the light receiving regions of the light-receiving unit by measuring a time difference between a start time when the light is emitted from the light-emitting unit and a time when the light reflected from the target object is received by each of the light receiving regions of the light-receiving unit; causing each of the plurality of light-emitting regions of the light-emitting unit to emit the light with the same light amount as a preliminary light emission stage; controlling the light emission amount of each of the plurality of light-emitting regions of the light-emitting unit to be used for a main light emission stage corresponding to a range finding operation of the target object based on the amount of light received at each of the light receiving regions of the light-receiving unit that was measured at the preliminary light emission stage; and measuring the distance to the target object for each of the light receiving regions of the light-receiving unit by performing the range finding operation at the main light emission stage. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       A more complete appreciation of the description and many of the attendant advantages and features thereof can be readily acquired and understood from the following detailed description with reference to the accompanying drawings, wherein: 
         FIG. 1  schematically illustrates a configuration of an optical system and a control system of a range finding device used for performing a range finding method according to an embodiment; 
         FIG. 2  schematically illustrates an example of a light-emitting surface of a laser light source arranging a plurality of light-emitting regions in a two-dimensional array, and a luminance distribution profile in a lateral direction and a luminance distribution profile in a longitudinal direction; 
         FIG. 3  illustrates a diagram illustrating a range to object detectable and a range to object not detectable when light emission amount of a laser light source is set to one given value; 
         FIG. 4  is a graph illustrating an example of light emission control of a laser light source based on an output of TOF sensor; 
         FIG. 5A  illustrates an example of output distribution at imaging regions of TOF sensor at a preliminary light emission stage when a laser light source emits a preliminary light; 
         FIG. 5B  illustrates an example of light emission amount of a laser light source at a main light emission stage when a laser light source emits a main light corresponding to the output distribution at imaging regions of TOF sensor when the laser light source emits the preliminary light; 
         FIG. 6  illustrates an example of flowchart of a normal or standard image capturing operation according to the embodiment; 
         FIG. 7  illustrates an example of flowchart of an image capturing operation when the image capturing operation is performed for multiple times according to the embodiment; and 
         FIG. 8  ( 8 ( a ),  8 ( b ),  8 ( c ),  8 ( d )) illustrates examples of timing charts used for describing a reason why a range finding accuracy deteriorates or range finding cannot be performed for a nearby object and a far-side object. 
     
    
    
     The accompanying drawings are intended to depict embodiments of the present invention and should not be interpreted to limit the scope thereof. The accompanying drawings are not to be considered as drawn to scale unless explicitly noted. 
     DETAILED DESCRIPTION 
     A description is now given of exemplary embodiments of the present inventions. 
     It should be noted that although such terms as first, second, etc. may be used herein to describe various elements, components, regions, layers and/or units, it should be understood that such elements, components, regions, layers and/or units are not limited thereby because such terms are relative, that is, used only to distinguish one element, component, region, layer or unit from another region, layer or unit. Thus, for example, a first element, component, region, layer or unit discussed below could be termed a second element, component, region, layer or unit without departing from the teachings of the present inventions. 
     In addition, it should be noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the present inventions. Thus, for example, as used herein, the singular forms “a”, “an” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise. Moreover, the terms “includes” and/or “including,” when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof. 
     Hereinafter, a description is given of a range finding apparatus and a range finding method according to an embodiment with reference to the drawings. 
     First Embodiment 
       FIG. 1  illustrates an example of a schematic configuration of a TOF camera  10  described as an example of range finding device according to first embodiment. As illustrated in  FIG. 1 , the TOF camera  10  includes, for example, a light-emitting unit  20  and a light-receiving unit  30 . The TOF camera  10  further includes, for example, a vertical cavity surface emitting laser (VCSEL)  21 , a lens  22 , a light emission control unit  50 , a determination unit  40 , a light measurement/control unit  60 , a light receiving lens  31 , and a light receiving sensor  32  (TOF sensor  32 ). As illustrated in  FIG. 1 , in the TOF camera  10 , the light-emitting unit  20  emits laser light of a rectangular wave or sine wave having a modulated frequency of some megahertz (MHz) to an object as projection light, and after the light-emitting unit  20  emits the laser light as the projection light to the object, the projection light hits and reflects from the object, and then the light-receiving unit  30  receives the light reflected from the object. 
     The light-emitting unit  20  includes, for example, a vertical cavity surface emitting laser (VCSEL)  21  as a light source. The VCSEL  21  includes a plurality of light-emitting regions arrayed two-dimensionally. The light emission control unit  50  controls the light emission operation of each one of the light-emitting regions of the VCSEL  21 . The light-emitting unit  20  further includes the lens  22  (an example of optical element) that adjusts (e.g., enlarge) an angle of view of the light emitted from each of light-emitting points or regions of the VCSEL  21  to a given required angle and then projects the projection light with the given angle of view. 
     The TOF camera  10  includes the determination unit  40 . The determination unit  40  controls the light emission control unit  50  to control the emission timing and the emission amount of light emitted by the light-emitting regions of the VCSEL  21 . 
     The light-receiving unit  30  includes, for example, the light receiving lens  31  and the light receiving sensor  32 . The light receiving lens  31  collects the light reflected from the object, and the light receiving sensor  32  receives the light collected by the light receiving lens  31  and performs the photoelectric conversion of the light. In the embodiment, the light receiving sensor  32  employs, for example, a time-of-flight (TOF) sensor. The light receiving sensor  32  is configured by arranging light receiving regions (e.g., sensor elements) in a two-dimensional pattern corresponding to the two-dimensional pattern of the light-emitting regions of the VCSEL  21 , and the detection signal of each sensor element is output individually. The sensor element is also referred to as the imaging element. 
     In this description, the TOF camera  10  includes the light-emitting unit having a plurality of light-emitting regions arranged in the two-dimensional array (e.g., laser light source unit), and the imaging element, in which an imaging face of the imaging element is divided into a plurality of discrete imaging regions (i.e., mesh pattern) by setting the number of discrete imaging regions same as the number of light-emitting regions and setting the same arrangement pattern for the light-emitting regions and the discrete imaging regions, and then the range of object is detected for each imaging region. In this description, the imaging region may be also referred to as light receiving region. 
     The detection signal of the light receiving sensor  32  is input to the light measurement/control unit  60 . The light measurement/control unit  60  performs statistical data processing of the sensor output value received from each detection region of the light receiving sensor  32  such as the TOF sensor, and functions as a region light intensity measurement unit that measures the light receiving level (the amount or quantity of received light) for each imaging region. The light measurement/control unit  60  also controls the light reception time, light reception sensitivity, timing or the like of the light receiving sensor  32 , which are synchronized with the light emission control of the light-emitting regions of the VCSEL  21 . 
     The region light intensity measurement unit also measures the light receiving level (light receiving amount) for each imaging region during a preliminary light emission stage of the laser light by the VCSEL  21 , and then a region light intensity control unit  41 , to be described later, controls the light emission amount at the time of performing the range finding of object (hereinafter, main light emission stage) based on the amount of light received by each of imaging regions during the preliminary light emission stage. 
     The determination unit  40  includes, for example, the region light intensity control unit  41 . The region light intensity control unit  41  determines the light emission amount of each light emission region of the VCSEL  21  and the light reception sensitivity of the light receiving sensor  32  during the image capturing operation based on the statistical sensor output data of each light receiving region of the light receiving sensor  32 . The determination unit  40  further includes, for example, a range finding unit  42 . The range finding unit  42  measures or calculates a distance to a target object for each imaging region by measuring the time difference between a time when emitting the laser beam from the VCSEL  21  and a time when receiving the light reflected from the object by the light receiving sensor  32  for each imaging region. 
     The range finding operation by the TOF camera  10  is equivalent to the known TOF camera operation using the general phase detection method. For example, the technology of the TOF camera described in JP-2018-077143-A can be used. Therefore, the detailed description of the range finding operation by the TOF camera  10  is omitted. 
     Hereinafter, a description is given of a two-dimensional arrangement of the sensor elements of the VCSEL  21  used as the light source unit of the light-emitting unit  20  with reference to  FIG. 2 .  FIG. 2  schematically illustrates a light-emitting surface of the VCSEL  21 , in which each circle (shaded circle) indicates each light-emitting region, and eight light-emitting regions are arranged in a longitudinal direction and a lateral direction, respectively, and thereby a total of 64 light-emitting regions are arranged two-dimensionally. Further, each light-emitting region includes a plurality of VCSEL elements arranged with an equal interval. 
       FIG. 2  also illustrates a luminance distribution profile in a lateral direction along the upper edge of the VCSEL elements, and a luminance distribution profile in a longitudinal direction along the left edge of the VCSEL elements. As to the luminance distribution profile, the dotted line indicates the luminance distribution profile of each VCSEL element, and the solid line indicates the luminance distribution profile when the entire VCSEL elements simultaneously emit the light. As indicated by the luminance distribution profile indicated by the solid line, when the entire elements simultaneously emit the light, the light emission become a substantially uniform surface emission. In other words, the arrangement interval of the elements are determined so as to achieve the uniform surface emission. The arrangement interval of the elements varies depending on specifications of the VCSEL element. For example, the arrangement interval of the elements is set to approximately 50 μm in scale. 
       FIG. 3  illustrates a relationship between an output of the light receiving sensor  32  and a range or distance to object (hereinafter, object distance) when the entire regions of the VCSEL  21  emit the light having the same intensity, and then the light receiving sensor  32  receives the light reflected from the object and outputs the detection signal. In  FIG. 3 , the horizontal axis represents the distance to object (object distance), and the vertical axis represents the output of the light receiving sensor  32  within an output range of levels “0 to 255.” The object exists within a field of view of the light receiving sensor  32 . 
     When a lateral direction of the light receiving surface of the light receiving sensor  32  is defined as X direction, a longitudinal direction of the light receiving surface of the light receiving sensor  32  is defined as Y direction, and a direction away from the light receiving surface of the light receiving sensor  32  is defined as Z direction, the light receiving surface becomes a X-Y plane. When a range finding area is viewed from the light receiving sensor  32 , the distance to the object from the discrete imaging regions on the X-Y plane of the light receiving sensor  32  may vary for each of the discrete imaging regions except that the object existing in the range finding area is a plane object parallel to the XY plane. 
     When the light set with a given uniform intensity is emitted from the TOF system toward the range finding area, the level of the reflection light becomes higher in an area where a nearby object is present, and the output level of the light receiving sensor  32  is saturated. 
     Further, the level of the reflection light becomes lower in an area where a far-side object is present, and the output signal of the light receiving sensor  32  is not distinguishable from the noise signal. That is, when the object distance position is too close to or too far from the TOF camera  10 , the range finding cannot be performed or the range finding precision deteriorates, and thereby the range of object detectable by performing the range finding operation is restricted. 
     Hereinafter, a description is given of this situation in detail with reference to  FIG. 3 . When the VCSEL  21  emits the light with the same light amount with respect to each of the pixels arranged in the array, as illustrated in  FIG. 3 , the light reflected by the far-side object is attenuated, and the output of the light receiving sensor  32  becomes smaller. In an example case of  FIG. 3 , the relationship between the sensor output and the object distance becomes non-linear when the object distance exceeds 7 m, and the range finding accuracy deteriorates, so that the output of the light receiving sensor  32  becomes invalid. Since the attenuation of the reflection light is small for the nearby object, the output of the light receiving sensor  32  becomes larger. 
       FIG. 8  illustrates examples of timing chart used for describing a reason why the range finding accuracy by the light receiving sensor  32  deteriorates or the range finding cannot be performed for a nearby object and a far-side object.  FIG. 8( a )  illustrates the light emission amount of the VCSEL  21  with respect to the timeline. The light emitting waveform is a rectangular waveform. 
       FIG. 8( b )  illustrates an output waveform of the light receiving sensor  32  when an object is at a middle range or intermediate distance, such as 1 m to 7 m. The received-light waveform is not a rectangular waveform, but becomes a sinusoidal waveform having a slight delay. An output determination threshold value is set for the light receiving sensor  32  to determine a point to measure a phase difference Δt of the light emission timing and the light reception timing. A time period to become the threshold value level is measured, and then the phase difference Δt is converted into distance information. A precise range finding can be performed for the object at the intermediate distance. 
       FIG. 8( c )  illustrates an output waveform of the light receiving sensor  32  when the object is at a near side or distance, such as within 1 m. When the object is at the near side, the output of the light receiving sensor  32  becomes larger and saturated, so that the rising of the waveform becomes steep. Therefore, a deviation error occurs in the time when the output of the light receiving sensor  32  becomes the determination threshold value (50% in this example case) compared to the ideal sinusoidal waveform of  FIG. 8( b ) . This deviation error is indicated in  FIG. 8( b )  as “E.” Since the deviation error “E” affects greater as the phase difference Δt becomes smaller (i.e., distance index becomes shorter as indicated in  FIG. 8( c ) ), the range finding error becomes greater when the output of the light receiving sensor  32  is saturated for the nearby object. Therefore, when the output of the light receiving sensor  32  is saturated, the range finding operation is not performed correctly. 
       FIG. 8( d )  illustrates an output of the light receiving sensor  32  when the object is at a far side or distance, such as 7 m or more. The amount of light received by the light receiving sensor  32  decreases as the object is at the far side. Therefore, the output of the light receiving sensor  32  does not exceed the determination threshold value required for the phase difference measurement, and the measurement of the phase difference Δt cannot be performed. In this case too, the range finding operation is not performed correctly. 
     As indicated in  FIG. 8 , the object distance that can be measured by emitting the light from the entire elements of the VCSEL  21  at the same time with the same light amount for one light emission operation is limited to a given range area. 
       FIG. 4  illustrates an example of the light emission control of the VCSEL  21  based on the output of the light receiving sensor  32 . In  FIG. 4 , the horizontal axis represents the output of the light receiving sensor  32 , and the maximum output level is 255 and the minimum output level is 0. The vertical axis represents the light emission amount of the VCSEL  21 , in which the maximum light emission amount is 3 watt [W]. 
     As illustrated in  FIG. 4 , the light-emission amount of the VCSEL  21  at the main light emission stage (second light emission stage) is controlled in accordance with the output of the light receiving sensor  32  when the same amount of light is emitted from the entire elements of the VCSEL  21  at the preliminary light emission stage (first light emission stage). 
     If the distance to object is far and the output of the light receiving sensor  32  becomes smaller at the preliminary light emission stage, and thereby the range finding operation cannot be performed, the light-emission amount of the VCSEL  21  at the main light emission stage is increased. By contrast, if the distance to the object is close and the output of the light receiving sensor  32  is saturated at the preliminary light emission stage, the light-emission amount of the VCSEL  21  at the main light emission stage is reduced. The region light intensity control unit  41  controls the light emission control unit  50  to control the light emission amount at the main light emission stage. 
       FIGS. 5A and 5B  illustrate examples of the light emission control of the VCSEL  21  according to the light amount value measured at each light receiving region of the light receiving sensor  32 .  FIG. 5A  illustrates an example of output distribution of the respective light-receiving regions of the light receiving sensor  32  at the preliminary light emission stage when the light receiving region of the light receiving sensor  32  is divided into 8×8 regions, in which the output distribution is drawn by changing patterns of the output distribution. Specifically, in accordance with the output of the light receiving sensor  32 , a region where the output is larger is expressed with a thin density shaded pattern while a region where the output is small is expressed with a thick density shaded pattern. In other words, the region expressed by the thin density shaded pattern indicates that the distance to the object in this region is close, and the region expressed by the thick density shaded pattern indicates the distance to the object in this region is far. 
     In  FIG. 5A , the region where the object is substantially at the infinity position is expressed by the thickest density shaded pattern, and the region where the object is present at the closest position, in other words, the region where the output of the light receiving sensor  32  becomes the maximum (the region where the output of the light receiving sensor  32  is saturated) is expressed by white without using the density shaded pattern. In  FIG. 5A , to simplify the description, five density shaded patterns including white are used, but is not limited thereto. The actual output of the light receiving sensor  32  can be categorized into a plurality of patterns. 
       FIG. 5B  illustrates an example of light emission amount of each region set for the VCSEL  21  when the output distribution of the light receiving sensor  32  at the preliminary light emission stage becomes the output distribution illustrated in  FIG. 5A , in which the light emission amount is drawn by changing patterns of the light emission amount. The thinner the density pattern, the greater the light emission amount. In accordance with the output distribution of  FIG. 5A , the region where the object is estimated to be at the near side, the light emission amount of the VCSEL  21  is controlled to be smaller, while the region where the object is estimated to be at the far side, the light emission amount of the VCSEL  21  is controlled to be greater. As similar to  FIG. 5A , in  FIG. 5B , to simplify the description, five density patterns including white are used, but is not limited thereto. The actual light emission amount of the VCSEL  21  can be categorized into a plurality of patterns. 
       FIG. 6  illustrates an example of flowchart of a normal or standard image capturing operation by setting a given standard sensitivity to the light receiving sensor  32 . 
     In step S 601 , the preliminary light emitting is performed prior to an image capturing operation. In step S 601 , the light emission amount of the VCSEL  21  is set to the same for the entire pixels so that the light emission amount is set to a uniform level for the entire regions of the VCSEL  21 . 
     In step S 602 , the reflection light is received and detected by the light receiving sensor  32  at the preliminary light emission stage. Since the light receiving sensor  32  includes the light receiving regions, each of which is the discrete light-receiving region as described above, a statistical value of each light receiving region is calculated from the sensor output value of the respective light receiving regions. 
     In step S 603 , the light emission amount at each region of the VCSEL  21  to be used for the main light emission stage (image capturing operation) is set based on the statistical value of each of the light receiving regions calculated in step S 602 . The light emission amount of the VCSEL  21  is set as described with reference to  FIGS. 5A and 5B . 
     In step S 604 , the main light emission stage is performed by emitting the light from the VCSEL  21  with the light amount set in step S 603 . 
     In step S 605 , the data of the light receiving sensor  32  is acquired in line with the light emission timing. 
     In step S 606 , the range finding processing is performed based on the data of the light receiving sensor  32  obtained in step S 605  to calculate distance information of the object existing within the angle of view set by the lens  22  (optical element). As described above, by setting the appropriate light emission amount for each of the light-emitting regions of the VCSEL  21 , the range of object detectable by performing the range finding operation can be improved. 
     Second Embodiment 
       FIG. 7  illustrates an example of flowchart of an image capturing operation with a higher sensitivity when the sensitivity of the light receiving sensor  32  is reset. Steps S 701  to S 705  in  FIG. 7  are the same as steps S 601  to S 605  in the flowchart of  FIG. 6 , and steps S 701  to S 705  are performed until acquiring the captured image data. 
     When the light is emitted at the main light emission stage, in step S 706 , the reflection light is detected by the light receiving sensor  32 , a statistical value of each light receiving region of the light receiving sensor  32  is calculated from the sensor output value of the respective light receiving regions of the light receiving sensor  32 , and then a region where the range finding cannot be performed due to too-small sensor output is detected as a sensitivity-increase-required region. 
     In step S 707 , the light-receiving sensitivity of the light receiving sensor  32  is increased at the sensitivity-increase-required region alone, detected in step S 706 . 
     In step S 708 , the light-emission amount is set for each light-emitting region of the VCSEL  21 . 
     In step S 709 , the light is emitted from each light-emitting region of the VCSEL  21  based on the light-emission amount set in step S 708 . 
     In step S 710 , the light is received at each light-receiving region of the light receiving sensor  32 . 
     In step S 711 , it is confirmed whether or not the sensitivity-increase-required region still exists. If the sensitivity-increase-required region still exists (S 711 : YES), the sequence returns to step S 707 , and then the sensitivity of the sensitivity-increase-required region is increased and then the range finding operation is performed again and the light is received by the light receiving sensor  32  again. If the sensitivity-increase-required region does not exist (S 711 : NO), the sequence proceeds to step S 712 . 
     In step S 712 , the image capturing operation is performed, and then the data detected by the light receiving sensor  32  is stored. 
     In the sequence described in  FIG. 7 , if the sensitivity-increase-required region still exists (S 711 : YES), the sequence from step S 707  is repeated and the image capturing operation is performed in step S 712  while setting an upper limit for the number of times of performing the image capturing operation to “N” times. 
     In step S 713 , the range finding processing is performed based on the data of the light receiving sensor  32  obtained in step S 712  to calculate the range or distance information of the object existing within the angle of view set by the lens  22  (optical element). 
     As described above, by setting the appropriate light emission amount for each light-emitting region of the VCSEL  21 , and the appropriate sensitivity for each light-receiving regions of the light receiving sensor  32 , the range of object detectable by performing the range finding operation can be further increased compared to the range finding operation of  FIG. 6 . 
     According to the above described embodiment, a range of object detectable by performing the range finding operation can be improved for far-side objects and nearby objects. 
     In the above-described embodiments, the VCSEL having the plurality of light-emitting regions arranged in the two-dimensional array is described as the laser light source unit having the plurality of light-emitting regions arranged in the two-dimensional array, but is not limited thereto. For example, any light source unit having a plurality of light-emitting regions arranged in a two-dimensional array can be used instead of the VCSEL. 
     Numerous additional modifications and variations are possible in light of the above teachings. It is therefore to be understood that, within the scope of the appended claims, the disclosure of this specification can be practiced otherwise than as specifically described herein. Any one of the above-described operations may be performed in various other ways, for example, in an order different from the one described above. 
     Each of the functions of the above-described embodiments can be implemented by one or more processing circuits or circuitry. Processing circuitry includes a programmed processor, as a processor includes circuitry. A processing circuit also includes devices such as an application specific integrated circuit (ASIC), digital signal processor (DSP), field programmable gate array (FPGA), system on a chip (SOC), graphics processing unit (GPU), and conventional circuit components arranged to perform the recited functions.