JP2008100682A - Light distribution control system of lighting fixture for vehicle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To always properly control an irradiation range in response to an advancing direction of a vehicle by adjusting responsiveness of irradiation range control with respect to steering in response to a shape of a curved path, in regard to a light distribution control system of a lighting fixture for a vehicle. <P>SOLUTION: In a lamp control circuit of the light distribution control system of a lighting fixture for a vehicle, road information indicating a shape of a running path slightly in front of the vehicle is inputted from a navigation control circuit 31 in step 108, and in step 110, a control map for determining a swivel angle of a headlight 10 is created on the basis of the inputted road information. In step 112, a steering angle is inputted from a steering angle sensor 22, in step 114, a swivel angle corresponding to the inputted steering angle is calculated on the basis of the control map, and in step 116, an optical axis direction of the headlight 10 is controlled such that it becomes the calculated swivel angle. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a light distribution control system that controls light distribution of, for example, a headlight of a vehicle.

Conventionally, as this type of system, for example, as disclosed in JP-A-62-77249, the irradiation range of a vehicular lamp attached to the front of a vehicle is determined and controlled according to the steering angle of the vehicle. In this way, there has been known one that always tries to ensure the driver's field of view well in accordance with the traveling direction of the vehicle while the vehicle is traveling. Further, for example, as disclosed in Japanese Patent Application Laid-Open No. 2-296550, the irradiation range of the vehicular lamp is determined and controlled based on the shape of the traveling path of the vehicle with reference to the road map stored in the map database. There was something that I tried to do.
JP-A-62-77249 JP-A-2-296550

  In the conventional system that determines the irradiation range of the vehicle lamp according to the steering angle, the irradiation range is simply controlled in conjunction with steering. In some cases, an unnecessary irradiation range was changed in conjunction with steering. On the other hand, in the conventional system in which the irradiation range is determined based on the shape of the traveling path of the vehicle, the inappropriate irradiation range is determined depending on the stored road map or the error of the current position of the vehicle specified on the road map. There was a change.

  An object of the present invention is to provide a light distribution control system for a vehicle lamp that adjusts the responsiveness of the irradiation range control to steering according to the shape of the curved road and always appropriately controls the irradiation range according to the traveling direction of the vehicle. There is to do.

  A feature of the present invention is that a light distribution control system for a vehicle lamp that determines and controls an optical axis direction of a vehicle lamp attached to a front portion of the vehicle according to a steering angle of the vehicle is irradiated according to the steering angle. When the range is determined, the shape of the travel path of the vehicle is acquired with reference to the road map stored in the map database provided in the vehicle navigation system, and the acquired travel path is a curved road The rate of change with respect to the steering angle in the optical axis direction is adjusted based on the turning degree of the curved path. In implementing the present invention, it is desirable to increase the rate of change of the optical axis direction with respect to the steering angle as the turning degree increases.

  According to the light distribution system for a vehicle lamp according to the present invention configured as described above, the responsiveness of the irradiation range control with respect to steering is adjusted according to the shape of the curved road while the vehicle is traveling on the curved road. The operability of the light distribution control system for the vehicular lamp is further improved.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. The vehicle lamp light distribution control system shown in FIG. 1 controls the irradiation range of a headlight 10 (vehicle lamp) attached to the front of a vehicle by a lamp control circuit 20 and is mounted on the vehicle. The navigation system 30 is partly used.

  The headlight 10 irradiates the front of the vehicle, and the irradiation range can be changed by swinging left and right by an actuator (not shown) to change the optical axis direction. In addition to the headlight 10, the lamp control circuit 20 includes a lighting switch 21 for instructing lighting of the headlight 10, a steering angle sensor 22 for detecting the steering angle of the vehicle, and a navigation control circuit 31 of the navigation system 30. Is connected. The navigation system 30 includes a GPS receiver (not shown), a direction sensor, and the like, and specifies the current position of the vehicle on the road map stored in the map database 32 as the vehicle travels. It provides guidance on the route to the ground. The lamp control circuit 20 executes a program corresponding to the flowchart shown in FIG. 2 according to input signals from the switches 21, sensors 22, and the control circuit 31 to control the irradiation range of the headlight 10.

  Next, the operation of the light distribution control system configured as described above will be described with reference to the drawings. Initially, when an ignition switch of a vehicle (not shown) is turned on, the lamp control circuit 20 starts executing the program at step 100 in FIG. 2, and first repeats the determination process at step 102 to turn on the lighting switch 21. Wait for it to be turned on. At this time, when the lighting switch 21 is turned on by the driver, the headlight 10 is turned on in step 104, and then the program is advanced to step 106 and subsequent steps to start controlling the irradiation range of the headlight 10. To do. At the time of the first lighting in step 104, the irradiation range of the headlight 10 is set to a neutral position suitable for straight traveling of the vehicle. Thereafter, while the lighting switch 21 is kept on, the lamp control circuit 20 repeatedly executes the processing of steps 106 to 116 under the determination of “YES” in step 106 to irradiate the headlight 10. Continue to control the range at any time.

  In step 108, road information representing the shape of the traveling road ahead of the vehicle is input from the navigation control circuit 31. The navigation control circuit 31 specifies the current position of the vehicle on the road map stored in the map database 32 after the ignition switch is turned on, and guides the driver of the route to the destination. The road information is output to the lamp control circuit 20 as needed.

  In step 110, a control map for determining the swivel angle (left and right swing angle of the optical axis) of the headlight 10 is created based on the input road information. As shown in FIGS. 3 to 10, the control map gives an appropriate swivel angle corresponding to the steering angle, and is a dead zone of the steering angle that maintains the swivel angle at the value “0”, that is, the headlight 10. The insensitive band of the steering angle that keeps the optical axis direction of the lens at the neutral position and the irradiation range at the neutral position and the rate of change of the swivel angle with respect to the steering angle are set based on the shape of the travel path of the vehicle. It has become.

  When the vehicle travel path is a straight road such as an expressway or a main national road, as shown in FIG. 3, the dead zone D of the steering angle that maintains the swivel angle of the headlight 10 at the value “0” is shown in FIG. Compared to that when driving on general roads shown in Fig. 2, it is set wider on both the left and right sides. Thereby, the responsiveness to the steering of the swivel angle control is suppressed. That is, it becomes difficult to change and control the irradiation range of the headlight 10 with respect to steering.

  When the vehicle traveling path is a curved road such as a curve or an intersection that turns right or left, as shown in FIGS. 4 and 5, the dead zone D of the steering angle that maintains the swivel angle of the headlight 10 at the value “0” is In addition, it is set narrow on the side of the vehicle turning direction on the curved road and wide on the side opposite to the turning direction. As a result, the responsiveness of swivel angle control with respect to steering in the turning direction of the vehicle is enhanced, and the irradiation range of the headlight 10 is easily changed and controlled with respect to steering in the same direction. Responsiveness of swivel angle control with respect to the steering to the opposite side is suppressed, and the irradiation range of the headlight 10 is hardly changed and controlled with respect to steering in the same direction.

  When the vehicle traveling path is a continuous curved path on both the left and right sides, as shown in FIG. 6, the dead zone of the steering angle that maintains the swivel angle of the headlight 10 at the value “0” is narrow on both the left and right sides. Set. In this embodiment, no dead band is provided. Thereby, the responsiveness to the steering of the swivel angle control is enhanced. That is, the irradiation range of the headlight 10 is easily changed and controlled with respect to steering.

  In addition, when the vehicle travel path is steeper than the curved path in FIGS. 4 and 5, as shown in FIGS. 7 to 9, the change rate of the swivel angle with respect to the steering angle is the turn of the curved path. It is set according to the degree (for example, a radius of curvature, a turning angle, etc.). As the degree of turning increases, that is, as the curve becomes steep, the rate of change of the swivel angle with respect to the steering angle is increased to increase the responsiveness to the steering of the swivel angle control, and the irradiation range of the headlight 10 with respect to steering is increased. Change control is facilitated.

  After creating the control map, the ramp control circuit 20 inputs a steering angle from the steering angle sensor 22 in step 112, and calculates a swivel angle corresponding to the input steering angle based on the control map in step 114. To do. In step 116, the direction of the optical axis of the headlight 10 is controlled so that the calculated swivel angle is obtained.

  On the other hand, if the lighting switch 21 is turned off during the repeated execution of the processing of steps 106 to 116, the lamp control circuit 20 determines that the headlight 10 is in step 118 based on the determination of “NO” in step 106. After that, the determination process of step 102 is repeatedly executed to wait for the lighting switch 21 to be turned on.

  As described above, in the above-described embodiment, the lamp control circuit 20 repeats the processes of Steps 106 to 116 to consider the shape of the traveling path of the vehicle and the irradiation range of the headlight 10 according to the steering angle. Is controlled from time to time. Therefore, it is possible to always appropriately control the irradiation range according to the traveling direction of the vehicle while avoiding unnecessary change of the irradiation range.

  If the vehicle travels on a straight road, the steering angle dead band D for maintaining the swivel angle of the headlight 10 at the value “0” is set wide on both the left and right sides, and the response of the swivel angle control to steering is increased. I try to suppress it. This avoids changing the irradiation range unnecessarily in conjunction with steering for a course correction or a lane change while the vehicle is traveling on a straight road.

  If the vehicle travels on a curved road, the steering angle dead band D for maintaining the swivel angle of the headlight 10 at the value “0” is set narrower on the turning direction side of the vehicle on the same curved road. The responsiveness to the steering of the swivel angle control is increased, and the responsiveness to the steering of the swivel angle control in the same direction is suppressed by setting widely on the opposite side of the turning direction. This makes it possible to control the irradiation range appropriately in conjunction with steering for turning while driving on a curved road of the vehicle, and unnecessary irradiation in conjunction with steering for correction steering or lane change. Changing the range is to be avoided.

  If the vehicle's travel path is a continuous curved path to the left and right sides, the swivel angle control is performed by setting the steering angle dead band for maintaining the swivel angle of the headlight 10 at the value “0” to be narrow on both the left and right sides. The response to steering is improved. As a result, while the vehicle is traveling on a continuous curved road, the irradiation range can be appropriately controlled by quickly responding to steering for turning.

  In addition, when the vehicle's travel path is a sharp curve, the responsiveness to swivel angle control is adjusted by setting the rate of change of the swivel angle with respect to the steering angle according to the degree of turning of the curved path. Like to do. As a result, the responsiveness of the irradiation range control to the steering is adjusted according to the shape of the curved road while traveling on the curved road of the vehicle, so that the light distribution control system of the vehicle lamp is easier to operate.

  Next, a modification of the above embodiment will be described with reference to the drawings. As shown in FIGS. 11 and 12, in this modification, dead zones D ′ and D ″ are provided even during return steering so that the swivel angle of the headlight 10 does not start to return immediately, and unnecessary irradiation is performed. It is intended to avoid changing the range.

  FIG. 11 is an explanatory diagram showing the relationship between the steering angle and the swivel angle when the vehicle is running on the right curve. In this case, as in the above-described embodiment, first, the steering angle dead band D for maintaining the swivel angle of the headlight 10 at the value “0” is set wider on the left side than on the right side (Dl> Dr). When the vehicle approaches a curve, when the steering is started and the steering angle to the right becomes larger than the dead band Dr (path 0 → 1), the optical axis of the headlight 10 starts to swing to the right. The swivel angle is increased in proportion to the height (path 1 → 2). At this time, a dead zone D 'is provided so that the swivel angle of the headlight 10 does not start to return immediately even when the steering is returned (path 2 → 3). Thereby, it is avoided that the irradiation range is unnecessarily changed in conjunction with steering for course correction or lane change. When the vehicle exits the curve and the return of steering becomes greater than the dead band D ', the swivel angle is decreased and returned to the value "0" as the steering is returned (path 3 → 4).

  If the steering angle to the left becomes larger than the dead zone Dl (route 0 → 5) when the steering is steered to the left side for course correction or lane change during the series of operations described above, the optical axis of the headlight 10 is moved to the left. Thereafter, the swivel angle is increased in proportion to the magnitude of the steering (path 5 → 6). At this time, a dead zone D ″ is provided so that the swivel angle of the headlight 10 is not immediately returned even when the steering is returned (path 6 → 7). Therefore, it is avoided that the irradiation range is changed unnecessarily in conjunction with the steering for the steering. Then, when the return of the steering becomes larger than the dead band D ″, the swivel angle is decreased and the value “ It is returned to “0” (path 7 → 8).

  FIG. 12 is an explanatory diagram showing the relationship between the steering angle and the swivel angle when the vehicle travels in a slalom (right, left, right continuous curve). In this case, as in the above embodiment, first, the dead zone D of the steering angle for keeping the swivel angle of the headlight 10 at the value “0” is set narrow on both the left and right sides. However, the dead zone D is not completely lost when entering the first right curve. When the vehicle approaches the first right curve, the steering is started, and when the steering angle to the right becomes larger than the dead zone D (path 0 → 1), the optical axis of the headlight 10 starts to swing to the right. The swivel angle is increased in proportion to the magnitude of the steering (path 1 → 2). At this time, a dead band D 'is provided so that the swivel angle of the headlight 10 is not immediately returned even when the steering is returned (path 2 → 3). Thereby, it is avoided that the irradiation range is unnecessarily changed in conjunction with steering for course correction or lane change. When the vehicle exits the first right curve and the return of steering becomes larger than the dead zone D ′, the swivel angle is decreased and returned to the value “0” as the steering returns (path 3 → 4). ). In this case, in order to enter the next left curve, the swivel angle is set to the value “0” when the steering angle becomes the value “0”.

  When the vehicle exits the first right curve and enters the left curve, the magnitude of the steering is immediately after the vehicle is steered to the left without passing through the dead zone that maintains the swivel angle of the headlight 10 at the value “0”. The swivel angle is increased in proportion to (path 4 → 5). At this time, a dead zone D ″ is provided so that the swivel angle of the headlight 10 is not immediately returned even when the steering is returned (path 5 → 6). Therefore, when the vehicle exits the left curve, if the return of the steering becomes larger than the dead band D ″, the swivel angle is subsequently increased as the steering is returned. Is reduced to the value “0” (path 6 → 7). In this case as well, the swivel angle is set to the value “0” when the steering angle becomes the value “0” in order to enter the next right curve.

  When the vehicle exits the left curve and enters the right curve again, the size of the steering is immediately after the vehicle is steered to the right without passing through the dead zone that maintains the swivel angle of the headlight 10 at the value “0”. The swivel angle is increased proportionally (path 7 → 8). The subsequent steps are the same as those in the first right curve (route 8 → 9, 9 → 10).

  In each of the above cases, the rate of change of the swivel angle with respect to the steering angle is set larger during the right steering than during the left steering (θl <θr). As a result, the responsiveness to the steering of the swivel angle control becomes higher at the time of right steering than at the time of left steering, and the irradiation range of the headlight 10 is easily changed and controlled with respect to the steering.

  Next, another modification of the present invention will be described. In this modified example, as indicated by a two-dot chain line in FIG. 1, an auxiliary lamp group 11 such as a fog lamp and a corner lamp is employed as a vehicular lamp in addition to the headlight 10. The illumination range of the vehicular lamp is controlled by controlling the turning on and off of the auxiliary lamp group 11 instead of the control in the optical axis direction.

  In this modification, the lamp control circuit 20 creates a control map for determining the lighting and extinguishing states of the auxiliary lamp group 11 in step 110 of FIG. In this case, first, the width of the dead zone of the steering angle in which the auxiliary lamp group 11 is all turned off and the irradiation range of the entire vehicular lamp is kept at the neutral position is set according to the travel path of the vehicle as in the above embodiment. To set. That is, when the vehicle traveling path is a straight road, the dead zone is set widely on both the left and right sides to suppress the response to steering of the lighting control of the auxiliary lamp group 11. When the vehicle traveling path is a curved road, the dead zone is set narrower on the side of the vehicle turning direction on the curved road to enhance the responsiveness of the lighting control of the auxiliary lamp group 11 to steering in the same direction. At the same time, it is set widely on the opposite side of the turning direction to suppress the responsiveness of the lighting control of the auxiliary lamp group 11 to the steering in the same direction. When the vehicle traveling path is a continuous curved path on both the left and right sides, the dead zone is set to be narrow on both the left and right sides, and the response to steering of the lighting control of the auxiliary lamp group 11 is enhanced.

  In the modification, the irradiation range is changed stepwise by partially turning on the auxiliary lamp group 11 as the steering angle increases. However, the vehicle travels on a sharp curve. If there is, the responsiveness to the steering of the irradiation range control is adjusted by adjusting the rate of change of the irradiation range with respect to the steering angle in accordance with the turning degree of the same curved path, as in the above embodiment.

  Then, after creating the control map, the ramp control circuit 20 inputs the steering angle from the steering angle sensor 22 in step 112, and assists corresponding to the input steering angle in step 114, as in the above embodiment. The lighting and extinguishing states of the lamp group 11 are calculated based on the control map, and the auxiliary lamp group 11 is controlled to be turned on and off so that the calculated state is obtained in step 116. Therefore, even in this modification, the irradiation range of the vehicular lamp is controlled according to the steering angle in consideration of the shape of the vehicle traveling path. It is possible to appropriately control the irradiation range according to the traveling direction of the vehicle.

1 is an overall schematic diagram of a light distribution control system for a vehicle lamp according to an embodiment of the present invention. It is a flowchart which shows the program run in the lamp control circuit of FIG. It is a control map which shows the relationship between the steering angle and the swivel angle of a headlight at the time of the straight road driving | running | working of the vehicle produced and referred in the said lamp control circuit. It is a control map which shows the relationship between the steering angle and swivel angle of a headlight at the time of the right curve driving | running | working of the vehicle produced and referred in the said lamp control circuit. It is a control map which shows the relationship between the steering angle at the time of the left curve driving | running | working of the vehicle produced and referred in the said lamp control circuit, and the swivel angle of a headlight. It is a control map which shows the relationship between the steering angle at the time of the continuous curve driving | running | working of the vehicle produced and referred in the said lamp control circuit, and the swivel angle of a headlight. It is a control map which shows the relationship between the steering angle and the swivel angle of a headlight at the time of the right sharp curve driving | running | working of the vehicle produced and referred in the said lamp control circuit. It is a control map which shows the relationship between the steering angle and the swivel angle of a headlight at the time of the left sharp curve driving | running | working of the vehicle produced and referred in the said lamp control circuit. It is a control map which shows the relationship between the steering angle and the swivel angle of a headlight at the time of the continuous steep curve driving | running | working of the vehicle produced and referred in the said lamp control circuit. It is a control map which shows the relationship between the steering angle at the time of the general road driving | running | working of the vehicle produced and referred in the said lamp control circuit, and the swivel angle of a headlight. FIG. 6 is an explanatory diagram illustrating a relationship between a steering angle and a swivel angle of a headlight when the vehicle is traveling on a right curve according to a modification of the embodiment. FIG. 10 is an explanatory diagram illustrating a relationship between a steering angle and a swivel angle of a headlight when the vehicle is traveling in a slalom according to the modified example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Headlight, 11 ... Auxiliary lamp group, 20 ... Lamp control circuit, 30 ... Navigation system, 32 ... Map database.

Claims (2)

In a vehicle light distribution control system for determining and controlling the optical axis direction of a vehicle lamp attached to the front of the vehicle according to the steering angle of the vehicle,
When determining the irradiation range according to the steering angle, the shape of the travel path of the vehicle is acquired with reference to a road map stored in a map database provided in the vehicle navigation system, and the travel path is a curved path. If it is, the rate of change with respect to the steering angle in the optical axis direction is adjusted based on the degree of turning of the curved road. The light distribution control system for a vehicular lamp according to claim 1, wherein a rate of change with respect to the steering angle in the optical axis direction is increased as the turning degree increases.

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