JP6648564B2 - Light irradiation system for vehicles - Google Patents

Description

  The present invention relates to a system including an irradiation device such as a headlight mounted on a vehicle.

  In recent years, it has been studied to add various functions other than on / off of the lamp to the lamp of the vehicle. For example, Patent Literature 1 proposes a technique of controlling light irradiation to display information on a road surface.

JP 2015-123855 A

  In order for the lamp to perform functions other than turning on / off the light, the software that determines the light irradiation content to achieve the target function based on information obtained from the outside and that actually drives the lamp Used.

  Conventionally, the above-described software has been designed using a parameter or the like depending on a method of a lamp. Therefore, if there is a change in the structure of the lamp, it is necessary to largely modify the software without changing the function. In addition, when a new function is added, it is necessary to modify software for each type of lamp, even if the function is the same.

  An object of the present invention is to provide a technique capable of facilitating software design change.

  A first aspect of the present disclosure provides a light irradiation unit (51, 103, 121), an information acquisition unit (31), a generation unit (33, 95, 105), and an irradiation control unit (53, 101, 123). And a vehicle light irradiation system (1, 1a, 1b).

The light irradiator is provided in the vehicle, and irradiates the outside of the vehicle with light, and is configured to be capable of changing the light irradiation mode.
The information acquisition unit acquires at least one of information indicating an external environment of the vehicle and information indicating a traveling state of the vehicle.

The generating unit determines irradiation information indicating a state of light irradiated on each of a plurality of coordinates having a predetermined position as an origin, based on the information acquired by the information acquiring unit.
The irradiation control unit controls light irradiation by the light irradiation unit based on the irradiation information determined by the generation unit.

  According to such a configuration, the light irradiation mode is determined as the irradiation information, and the light irradiation is performed based on the irradiation information. In other words, since both the step of determining the irradiation information and the step of executing the irradiation information are less likely to be affected by the specific contents of the other step, it is easy to change the software design to realize such a step. Will be able to

  A second aspect of the present disclosure is a control device (13, 91, 111) including an information acquisition unit (31) and a generation unit (33, 95, 105). The information acquisition unit acquires at least one of information indicating an external environment of the vehicle and information indicating a traveling state of the vehicle. The generation unit determines irradiation information indicating a state of light irradiated on each of a plurality of coordinates having a predetermined position as an origin, based on the information acquired by the information acquisition unit.

According to such a configuration, a part of the above-described vehicle light irradiation system according to the first aspect of the present disclosure can be configured.
Note that the reference numerals in parentheses described in this column and in the claims indicate the correspondence with specific means described in the embodiment described below as one aspect, and denote the technical scope of the present invention. It is not limited.

It is a block diagram showing the composition of the light irradiation system for vehicles of a 1st embodiment. FIG. 2A is a side view illustrating the driver coordinate system, and FIG. 2B is a plan view illustrating the driver coordinate system. FIG. 3 is a diagram illustrating a coordinate system projected on a two-dimensional plane. It is a figure explaining the method of generating irradiation information from individual support information using an individual pattern which shows individual support information, and an irradiation pattern which shows irradiation information. It is a block diagram showing the composition of the light irradiation system for vehicles of a 2nd embodiment. It is a block diagram showing composition of a light irradiation system for vehicles of a 3rd embodiment. FIG. 9 is a diagram illustrating a method of generating irradiation information from individual support information using an individual pattern including a drawing pattern indicating drawing information and an irradiation pattern.

Hereinafter, embodiments for carrying out the invention will be described with reference to the drawings.
[1. First Embodiment]
[1-1. Constitution]
The vehicle light irradiation system 1 shown in FIG. 1 is a system that is mounted on a vehicle and irradiates light to the outside of the vehicle, and includes an information output unit 11 including a plurality of sensors and communication devices, a control device 13, a lamp, 15.

  The information output unit 11 includes a camera 21, a LIDER 22, a RADAR 23, a vehicle-to-vehicle / road-to-vehicle communication receiver 24, a rain sensor 25, a steering angle sensor 26, a vehicle speed sensor 27, an acceleration sensor 28, and the like.

  The camera 21 is an imaging device provided in a vehicle, and may use, for example, a known CCD image sensor or CMOS image sensor. The camera 21 photographs the periphery of the vehicle at a predetermined time interval (for example, 1/15 s) and outputs the photographed image to the control device 13.

The LIDER 22 and the RADAR 23 are devices that irradiate a laser beam or an electromagnetic wave and acquire a reflected wave thereof. The detection signal of the reflected wave is output to the control device 13.
The vehicle-to-vehicle / road-to-vehicle communication receiver 24 receives a signal transmitted from a vehicle existing around the vehicle or a roadside device installed on the road and indicating information such as the presence of the vehicle or the like and the state of the road. This is a device that outputs to

  The rain sensor 25 is a sensor that detects raindrops outside the vehicle. The steering angle sensor 26 is a sensor that measures the steering angle of the steering wheel. The vehicle speed sensor 27 is a sensor that detects the traveling speed of the vehicle. The acceleration sensor 28 is a sensor that detects acceleration applied to the vehicle. The detection signals of these sensors are output to the control device 13.

  The control device 13 is mainly configured by a known microcomputer having a CPU (not shown) and a semiconductor memory such as a RAM, a ROM, and a flash memory. Various functions of the control device 13 are realized by the CPU executing a program stored in a non-transitional substantive recording medium. In this example, the above-described semiconductor memory corresponds to a non-transitional substantial recording medium storing a program. In addition, by executing this program, a method corresponding to the program is executed. The number of microcomputers constituting the control device 13 may be one or more.

  The control device 13 includes an information acquisition unit 31 and a generation unit 33 as a configuration of functions realized by a CPU executing a program. The method for realizing these elements constituting the control device 13 is not limited to software, and a part or all of the elements may be realized using hardware in which a logic circuit, an analog circuit, or the like is combined.

The information obtaining unit 31 includes an external environment recognizing unit 41 that obtains information indicating the external environment of the vehicle, and a vehicle running state recognizing unit 43 that obtains information indicating the running state of the vehicle.
The external environment recognizing unit 41 receives output signals of the camera 21, the lidar 22, the RADAR 23, the vehicle-to-vehicle / road-to-vehicle communication receiver 24, and the rain sensor 25, and obtains obstacles such as other vehicles and people outside the vehicle and road shapes. And the environment outside the vehicle, such as weather. As a method for recognizing these, a known technique can be adopted, and thus the description is omitted.

  The host vehicle traveling state recognition unit 43 receives output signals of the steering angle sensor 26, the vehicle speed sensor 27, and the acceleration sensor 28, and recognizes a steering angle, a vehicle speed, an acceleration, and the like as the traveling state of the vehicle. Of course, a configuration for recognizing other vehicle states may be used.

  The generation unit 33 generates, based on the information acquired by the information acquisition unit 31, irradiation information that is information indicating a state of light emitted to each of a plurality of coordinates having a predetermined position as the origin, and 15 is output.

  Details of the coordinates described above will be described later. Further, the above-mentioned light state means an on / off state of light irradiation, a color state, a brightness state, and the like for each coordinate, which are visually recognized. By changing such a state, a change in the light irradiation mode by the light irradiation unit 51 described later is realized. Note that, in the present embodiment, the state of the light irradiated on each coordinate included in the irradiation information is only the ON / OFF state of the light irradiation.

The generation unit 33 includes a support function unit group 45 and an integration unit 47.
The support function unit group 45 is a group of a plurality of support function units. The support function unit is driving assistance by light irradiation, and is a state of light emitted to each of a plurality of coordinates each having a predetermined position as an origin for realizing driving assistance for different purposes. Generate individual support information.

  The above-mentioned driving assistance means improving the safety and convenience of the driver of the vehicle, but indirectly improving the safety and convenience of the people and vehicles existing around the vehicle. Includes those that benefit the driver of the vehicle.

  In the present embodiment, the support function unit includes a driver's visibility securing application (hereinafter, visibility securing application) 46a and another vehicle anti-glare application (hereinafter, other vehicle anti-glare application) 46b.

  The visibility securing application 46a is a main function of the lamp 15, which irradiates the road surface in front of the vehicle with light, and includes information such as a steering angle and a traveling speed acquired by the own vehicle traveling state recognizing unit 43, and an external environment recognizing unit 41. Is determined based on information such as the shape of the traveling road and the presence of other vehicles, which are obtained by the above.

  For example, the center position is moved to the left or right according to the steering angle or the curve of the road, or the center position is set to a position farther from the own vehicle according to the magnitude of the traveling speed on condition that there is no other vehicle facing the vehicle. It is possible.

The other-vehicle anti-glare application 46b determines a position at which light is not emitted according to the position of the other vehicle acquired by the outside-of-vehicle environment recognition unit 41.
The visibility securing application 46a and the other-vehicle anti-glare application 46b generate the above-described light irradiation and non-light irradiation patterns as individual support information indicating the state of light irradiated on each coordinate.

  The coordinates in the present embodiment employ a driver coordinate system that is a coordinate having the origin at the position of the driver's viewpoint. The origin of the coordinates is vehicle-specific information determined by the position of the seat or the like, but may be configured to be able to be changed automatically or manually.

  As shown in FIGS. 2A and 2B, the driver coordinate system is a coordinate system having the origin at a position D where the viewpoint of the driver of the vehicle is located. For example, any of (i) a three-dimensional orthogonal coordinate system and (ii) a coordinate system projected onto a two-dimensional plane can be adopted as the coordinates used when actually generating the individual support information.

  The three-dimensional orthogonal coordinate system of (i) described above indicates coordinates of light irradiation by coordinates in a three-dimensional space. When this coordinate system is used, it becomes easy to use the support function unit using information in the depth, that is, the z-axis direction. For example, it is convenient to irradiate light so as to emphasize an obstacle whose position information is obtained from outside the vehicle by a method such as inter-vehicle communication or road-to-vehicle communication.

  Further, the coordinate system projected onto the two-dimensional plane (ii) is a coordinate system in which the coordinates of the area 58 to be irradiated with light are shown as coordinates on a predetermined two-dimensional plane 59, as shown in FIG. is there. It should be noted that the road 57 in the figure is only shown for easy understanding of the positional relationship with the two-dimensional plane 59.

  The two-dimensional plane can be set at a position where the driver can visually recognize the two-dimensional plane. When such two-dimensional plane coordinates are used, the light irradiation mode can be set as a view from the driver, which is convenient when displaying information such as characters as in a third embodiment described later. Good. In addition, arbitration with a system that cooperates with light irradiation to the outside of the vehicle, for example, another system that displays information on a windshield such as an AR-HUD, can be easily performed. When expressed by projection on a two-dimensional plane, the vertical and horizontal angles from the vanishing point may be used as units, or the length in the xy plane, which is a two-dimensional plane set at the depth z, may be used as a unit. It may be.

  Note that the coordinates used for the irradiation information and the individual support information described above are not limited to the driver coordinate system, and a coordinate system having origins at various positions can be used. For example, a lamp coordinate system having the position of the lamp as the origin may be used.

  The integration unit 47 generates irradiation information to be output to the irradiation control unit 53 described later based on the plurality of individual support information generated by each of the plurality of support function units. Since the individual irradiation information and the irradiation information are information using the coordinates of the same coordinate system, they can be easily combined. If the state of the light emitted at the same coordinates is different, arbitration is performed according to the priority set for each support function unit.

Specific examples of the individual support information and the irradiation information will be described.
The individual patterns 71 and 73 and the irradiation pattern 75 shown in FIG. 4 are diagrams schematically showing individual support information and irradiation information generated in a coordinate system projected on a two-dimensional plane.

  The individual pattern 71 is a diagram showing the individual support information determined by the visibility securing application 46a, and shows an irradiation area 77 for which irradiation is requested. On the other hand, the individual pattern 73 is a diagram showing the individual support information determined by the other vehicle anti-glare application 46b, in which non-irradiation is required, in other words, it is actively required not to irradiate light. A non-irradiated area 79 is shown.

  The integration unit 47 generates an irradiation pattern 75 by combining and adjusting the two irradiation patterns described above. In the two support function units described above, since the other vehicle anti-glare application 46b has a higher priority, the non-irradiation area 79 remains in the irradiation pattern 75 without disappearing. The irradiation information corresponding to the irradiation pattern 75 is output to the irradiation control unit 53.

The lamp 15 is a device provided in a vehicle, and includes a light irradiation unit 51 and an irradiation control unit 53.
The light irradiating section 51 irradiates light to the outside of the vehicle, and is configured to be able to change the light irradiation mode. The light irradiation mode is a state that is visually recognized, and is a state based on various elements that change the color, brightness, and intensity of the range of light irradiation, the whole or part of the irradiation range, or the like. . That is, the change in the irradiation mode means that the state visually recognized changes, for example, a change in the light irradiation range, the ON / OFF of the light irradiation in the whole or a part of the irradiation range. Switching, change of color, change of brightness, change of the state over time, change of the change speed, and the like.

In the present embodiment, only a change in the light irradiation range and a change in ON / OFF of light irradiation in the whole or a part of the irradiation range are realized.
The light irradiation unit 51 includes a lamp 61 as a light source, a switching actuator 62 for performing an operation of switching between a high beam and a low beam, a swivel actuator 63 for horizontally changing the direction of irradiation light, and a light-shielding plate actuator for blocking a part of the irradiation light. 64.

The irradiation control unit 53 includes a lamp coordinate conversion unit 53a and a lamp light distribution control unit 53b, and controls light irradiation by the light irradiation unit 51 based on the irradiation information output from the generation unit 33.
The lamp coordinate conversion unit 53a changes the coordinates indicated in the obtained irradiation information into a lamp coordinate system based on the coordinates of the lamp mounting position and the coordinates of the driver's viewpoint position, which are information unique to the vehicle. The lamp coordinate system is a coordinate system used when the lamp light distribution control unit 53b controls light irradiation. That is, by converting the coordinates of the driver coordinate system into the coordinates of the lamp coordinate system, the lamp light distribution control unit 53b can execute irradiation control. The origin of the lamp coordinate system is not particularly limited, but the mounting position of the lamp can be used as the origin. When there are a plurality of lamps, the position between them, for example, the center of gravity, can be set as the origin.

  The lamp light distribution control unit 53b is configured to turn on / off the lamp 61 and switch the actuator based on the coordinates converted into the lamp coordinate system by the lamp coordinate conversion unit 53a and information on whether to irradiate the coordinates with light. Control such as switching between a high beam and a low beam by 62, adjustment of a swivel angle by a swivel actuator 63, adjustment of a light shielding position by a light shielding plate actuator 64, and the like are executed.

[1-2. effect]
According to the first embodiment described in detail above, the following effects can be obtained.
(1a) In the vehicle light irradiation system 1, the control device 13 generates irradiation information indicating a state of light irradiated to each of the plurality of coordinates, and outputs the information to the lamp 15. With such a configuration, even if the structure of the lamp 15 is added or changed, the irradiation information output from the control device 13 does not need to be largely changed. Therefore, even if there is a change in the structure of the lamp 15 or a change in the lamp 15 itself, a software design change of the control device 13 can be easily realized.

  (1b) Even if a new support function unit is added by the control device 13, if the irradiation information is output to the lamp 15, the lamp 15 can control the light irradiation based on the irradiation information. That is, even if the function is added to the control device 13, it is not necessary to largely change the software for controlling the lamp 15, so that the design change of the software and the addition of the support function unit can be easily realized.

(1c) As long as the lamp can perform irradiation based on the irradiation information, the lamp itself can be easily changed.
(1d) Since the plurality of functions provided by the plurality of support function units are respectively output as individual support information having the same dimension as the irradiation information, the integration unit 47 can easily integrate them. In addition, at the time of integration, priorities due to functions, safety, and the like are assigned, so that integration can be performed according to the priorities and the irradiation pattern can be set to an appropriate state.

  Conventionally, since a plurality of support function units output using different control parameters or the like, special software for controlling the lamp 15 based on the information is required, but as described above. In the present embodiment, such software is not required.

[2. Second Embodiment]
[2-1. Differences from First Embodiment]
In the second embodiment, the description of the configuration common to the first embodiment will be omitted, and the description will focus on the differences. The same reference numerals as in the first embodiment denote the same components, and refer to the preceding description.

The vehicle light irradiation system 1a according to the second embodiment includes an information output unit 11, a control device 91, and a lamp 93, as shown in FIG.
In the control device 91, the generation unit 95 includes, as the support function unit group 45a, a target recognition support application (hereinafter, a target recognition support application) 46c in addition to the visibility securing application 46a and the other vehicle anti-glare application 46b, An anti-glare application for other vehicles (hereinafter, an anti-glare application for other vehicles in rainy weather) 46d.

  The target recognition support application 46c determines the position to be irradiated with light in order to emphasize the position of the target on or near the road detected by the external environment recognition unit 41. Here, the target is an obstacle to the running of the vehicle such as another vehicle, an object, or a person detected by the outside environment recognition unit 41.

  When the outside environment recognition unit 41 detects that it is raining, the light reflected by the wet road surface reaches the driver of the other vehicle according to the position of the other vehicle when the external environment recognition unit 41 detects that the vehicle is in rainy weather In order not to irradiate light, a position where light is not irradiated is determined.

The lamp 93 includes an irradiation control unit 101 and an LED matrix 104 as a light irradiation unit 103.
The LED matrix 104 uses a plurality of LEDs as light sources, and can control the amount of light for each LED. That is, since the LED matrix 104 has a high degree of freedom in setting the irradiation range and the light amount, it is possible to suitably realize the support function units such as the target recognition support application 46c and the anti-glare application for other vehicles in rainy weather.

  The lamp light distribution control unit 105 included in the irradiation control unit 101 controls the driving of the LED matrix 104 based on the pattern generated by the lamp coordinate conversion unit 53a. Specifically, the amount of light is adjusted for each LED constituting the LED matrix 104.

[2-2. effect]
According to the second embodiment described in detail above, effects similar to the effects (1a) to (1d) of the above-described first embodiment can be obtained.

[3. Third Embodiment]
[3-1. Differences from First Embodiment and Second Embodiment]
In the third embodiment, the description of the configuration common to the first and second embodiments will be omitted, and the description will focus on the differences. Note that the same reference numerals as those in the first embodiment and the second embodiment denote the same components, and refer to the preceding description.

  The vehicle light irradiation system 1b of the third embodiment not only performs light irradiation for visibility support and the like, but also performs drawing with light for notifying information. As shown in FIG. 6, the vehicle light irradiation system 1b includes an information output unit 11, a control device 111, and a lamp 113.

  In the control device 111, the generation unit 115 includes, as the support function unit group 45b, the visibility securing application 46a, the other vehicle anti-glare application 46b, the target recognition support application 46c, the other vehicle anti-glare application 46d in rainy weather, and the driver An information notification application (hereinafter, information notification application) 46e is provided. Each support function unit of the support function unit group 45b generates individual support information in a coordinate system projected on a two-dimensional plane set at a position visually recognized by the driver when the driver is facing the front of the vehicle.

  The information notification application 46e receives a request for information notification using the lamp 113 output from the navigation system 3 and the driving assistance system 5 mounted on the vehicle, and illuminates characters, patterns, figures, and the like by irradiating the vehicle with light. Drawing information, which is individual support information for realizing driving support to be displayed outside, is generated. Examples of the notification request include a numerical value of the speed limit, a pattern showing a turn-by-turn arrow, a long graphic for emphasizing the traveling lane, and the like, but are not limited to these.

  The processing by the integration unit 47 will be described. The individual pattern 141 illustrated in FIG. 7 is a diagram illustrating the individual support information determined by the target recognition support application 46c, and illustrates an emphasis area 142 where emphasis is performed by light irradiation. The individual pattern 143 is a diagram showing the individual support information determined by the other vehicle anti-glare application 46d in rainy weather, and shows the non-irradiation area 144 where non-irradiation is requested.

  The integrating unit 47 first generates the irradiation pattern 145 by combining and arbitrating the above-described four individual patterns. Next, the drawing information generated by the information notification application 46e is combined with the generated irradiation pattern 145.

  The drawing pattern 151 and the drawing pattern 153 are diagrams illustrating the drawing information generated by the information notification application 46e. The drawing pattern 151 shows a character 152 indicating a speed limit, and the drawing pattern 153 shows a lane emphasis symbol 154 for emphasizing a driving lane detected by the driving assistance system 5. The combined irradiation pattern 156 is generated by combining the character 152 and the lane emphasis design 154 with the irradiation pattern 145. FIG. 9 is a diagram showing irradiation information output to the lamp 113 with the combined irradiation pattern 156.

  In this way, based on the individual support information generated by all the support function units of the support function unit group 45b, the integration unit 47 generates irradiation information reflecting the individual support information. If the emphasis, dimming, and non-irradiation areas overlap, arbitration is performed based on the priority set for each support function unit. The integrating unit 47 first integrates the individual support information generated by the support function unit other than the information notification application 46e, and then integrates the drawing information generated by the information notification application 46e.

  When it is assumed that the visibility of the drawing information is poor, a visual assistance process for adjusting the irradiation information so as to improve the visibility is performed. For example, when a bright character or the like is to be drawn in a bright area, the visibility of the character or the like deteriorates. Therefore, it is conceivable to improve the visibility of the character or the like by setting a non-irradiation area around the character or the like. Can be

The lamp 113 is a device provided in the vehicle, and includes a light irradiation unit 121 and an irradiation control unit 123.
The light irradiation unit 121 includes a digital mirror device (hereinafter, DMD) 131, a DMD light source 132 that is a light source of the digital mirror device, a scanning mirror 133, and a laser 134.

  A display device capable of projecting an image is configured by the DMD 131 and the DMD light source 132. In addition, a scanning display device that displays an image by irradiating a predetermined position with laser light by the scanning mirror 133 and the laser 134 is configured.

  The lamp coordinate conversion unit 53a included in the irradiation control unit 123 converts the irradiation information into information of a lamp coordinate system, and the lamp light distribution control unit 125 performs a DMD 131, a DMD light source 132, a scanning mirror based on the converted information. 133, controls the operation of the laser 134.

[3-2. effect]
According to the third embodiment described in detail above, the following effects are obtained in addition to the effects (1a) to (1d) of the above-described first embodiment.

(3a) In the vehicle light irradiation system 1b of the present embodiment, information can be notified to the driver by illuminating light to form characters, figures, patterns, and the like.
(3b) Since the information notification application 46e forms characters and the like displayed for the purpose of notifying the driver in two-dimensional coordinates close to the view viewed from the driver's viewpoint, the irradiation light visible to the driver is provided. Can be reduced.

  (3c) The integration unit 47 first integrates the individual support information generated by the support function units other than the information notification application 46e, and then integrates the drawing information that is the individual support information generated by the information notification application 46e. I do. At this time, a visual assistance process for improving the visibility of characters and the like is performed as necessary. Therefore, the driver can easily recognize the displayed characters, figures, and patterns.

[4. Other Embodiments]
The embodiments for carrying out the present invention have been described above. However, the present invention is not limited to the above-described embodiments, and can be implemented with various modifications.

  (4a) In the above embodiment, the light irradiation units 51, 103, and 121 have been exemplified. However, if the light irradiation units 51, 103, and 121 are configured to irradiate light to the outside of the vehicle and change the light irradiation mode, the light irradiation units other than the above embodiment may be used. A configuration using a lamp having a light irradiation unit may be used.

The direction in which light is emitted is not limited to the road surface as long as it is outside the vehicle, and the target may be directly irradiated with light.
(4b) In the above-described embodiment, the configuration in which the information acquisition unit 31 acquires both the information indicating the external environment of the vehicle and the information indicating the traveling state of the vehicle has been described, but a configuration in which only one of them is acquired. It may be.

  (4c) In the above embodiment, the configuration in which the generation units 33, 95, and 121 have a plurality of support function units has been exemplified, but the number is not particularly limited and may be one. In that case, the integration unit 47 may not be provided.

  (4d) The function of one component in each of the above embodiments may be assigned to a plurality of components, or the function of the plurality of components may be exerted by one component. Also, a plurality of functions of a plurality of components may be realized by one component, or one function realized by a plurality of components may be realized by one component. Further, a part of the configuration of the above embodiment may be omitted. Further, at least a part of the configuration of the above-described embodiment may be added to or replaced with the configuration of another above-described embodiment. In addition, all aspects included in the technical idea specified only by the language described in the claims are embodiments of the present invention.

  (4e) In addition to the above-described vehicle light irradiation system 1, 1a, 1b, control devices 13, 91, 111 constituting the system, a program for causing a computer to function as the control device, and a semiconductor memory storing the program The present invention can also be realized in various forms, such as a non-transitional actual recording medium such as a recording medium and a light irradiation method.

1, 1a, 1b vehicle light irradiation system, 31 information acquisition unit, 33, 95, 105 generation unit, 47 integration unit, 51, 103, 121 light irradiation unit, 53, 101, 123 irradiation control Department

Claims (4)

A vehicle light irradiation system (1, 1a, 1b) including a lamp (15) and a control device (13) configured to transmit information to the lamp,
A light irradiating unit (51, 103, 121) that is provided in the vehicle and irradiates light to the outside of the vehicle and is configured to change an irradiation mode of the light;
An information acquisition unit (31) for acquiring at least one of information indicating an external environment of the vehicle and information indicating a traveling state of the vehicle;
A generating unit configured to generate irradiation information, which is information indicating a state of light emitted to each of a plurality of coordinates having a predetermined position as an origin, based on the information acquired by the information acquiring unit; 105),
An irradiation control unit (53, 101, 123) that controls irradiation of light by the light irradiation unit based on the irradiation information generated by the generation unit ;
The generation unit includes:
A plurality of support function units that generate individual support information that is information indicating a state of light emitted to each of a plurality of coordinates each having the predetermined position as an origin for realizing driving assistance for different purposes ( 46a, 46b, 46c, 46d, 46e);
An integration unit (47) configured to generate the irradiation information output to the irradiation control unit based on the plurality of individual support information generated by each of the plurality of support function units;
The irradiation control unit is configured to control irradiation of light by the light irradiation unit based on the irradiation information generated by the integration unit,
The light irradiation unit and the irradiation control unit are provided in the lamp,
The vehicle light irradiation system, wherein the information acquisition unit and the generation unit are provided in the control device. The vehicle light irradiation system according to claim 1 ,
For the vehicle, the integrating unit generates the irradiation information by integrating the plurality of individual support information generated by each of the plurality of support function units according to a priority order set for each of the plurality of support function units. Light irradiation system. The vehicle light irradiation system according to claim 1 or 2 ,
At least one of the plurality of support function units is configured to perform driving assistance for displaying at least one of a character, a picture, and a graphic outside the vehicle by irradiating light. A vehicle light irradiation system that generates drawing information as support information. The vehicle light irradiation system according to any one of claims 1 to 3 , wherein
The vehicle light irradiation system, wherein the predetermined position is a position of a viewpoint of a driver of the vehicle.

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