JP2005115794A - Guide light unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To simplify an installation and construction work and improve a system operating rate in a simple system configuration so that a guide light system can be constituted without a center system in consideration of circumstances that installation of power source and stoppage of the center system are required during the installation and construction work in order to transmit control signals from the center system in the guide light system having vehicle detecting sensors separated from luminescent objects providing display to a driver and integratedly controlling the plurality of luminescent objects by processing information with the center system. <P>SOLUTION: Luminescent sections 11 and sensor sections 12 are provided in guide light units 1 to 4. Display of the luminescent sections 11 in the unit is autonomously controlled by detected information by the sensor sections 12 in the unit, and cooperative control in cooperation with sensor detected information can be carried out by obtaining the sensor detected information at an upstream side and radiating body controlling information by means of a radio LAN. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a guide light device that is installed along a road, detects a traveling vehicle, and controls display of a light emitting unit, thereby performing driving support and alerting of a driver.

  As a conventional technique, as described in [Patent Document 1], when fog is generated, the lighting direction is opposed to the vehicle traveling in the lane so that the front track in the traveling direction can be confirmed, and the vehicle is positioned at a low position on the road side of the lane. There are a plurality of illumination means arranged along the roadside, a speed sensor for measuring the vehicle speed of each vehicle, and an output of this speed sensor is inputted to calculate the inter-vehicle distance between the preceding vehicle and the following vehicle, There is a travel guide light device that changes the lighting state of the illumination means located between the preceding vehicle and the following vehicle in accordance with the inter-vehicle distance. In addition, as described in [Patent Document 2], the image of a vehicle traveling on a road with poor visibility such as a curve portion is measured by the image processing unit to measure the position, speed, traveling direction, and vehicle type of the vehicle to determine the risk level. The unit includes a guide light device that determines a risk level of the vehicle traveling over the center line from the measurement data and displays a display pattern corresponding to the risk level on the display unit.

  As described above, in [Patent Document 1] and [Patent Document 2], light emission configured by LEDs or the like on the road side for the purpose of preventing the deviation of the driving lane, maintaining the inter-vehicle distance, overspeed warning, etc. in a section with poor visibility. There has been proposed a guide light device that controls lighting display of a light emitter based on detection information of a speed and a position of a vehicle obtained by continuously installing a body and image-processing a speed sensor or an ITV camera image.

  The guide light device described in [Patent Document 1] and [Patent Document 2] is based on sensor information obtained from a sensor and video obtained from an ITV camera by installing a sensor and an ITV camera in addition to a light emitter. Therefore, a center facility for processing sensor information and video to control the light emitter and a signal line for sending a control signal are necessary, and there is a problem that the facility work becomes complicated. In addition, if the sensor, the ITV camera, or the center equipment fails, there is a problem that the light emitter cannot be controlled.

  In order to solve the problem of the signal line, as described in [Patent Document 3], a power supply unit that starts supplying power when a vehicle passing is detected by a detection unit that detects the vehicle passing; Provided with a plurality of control units interposed between each of a plurality of lighting units connected in multiple stages by feed wiring to the output of the supply unit, and each control unit is supplied with power from the power supply unit side as the previous stage side In addition, there is a lighting control device that performs a blinking control and the like in order to synchronize a plurality of lighting units without using a signal line so that power distribution to the subsequent stage of the power is started after a lapse of a certain time.

Japanese Patent Laid-Open No. 10-60834 JP 2001-209898 A JP 2001-203083 A

  In the conventional guidelight device described in [Patent Document 1] and [Patent Document 2], a sensor for detecting a vehicle is separately installed in addition to a light emitting body that displays to a driver, and the information is processed by a center facility. A type of centrally controlling a plurality of light emitters is common. For this reason, it is necessary to supply a control signal from the center equipment in addition to the power supply during the installation work, and the entire guide light device is stopped when the center equipment is stopped. In addition, in the device described in [Patent Document 3], by providing a plurality of power supply control units, synchronization between a plurality of lighting units can be performed without using a signal line, and sequential flashing control or the like can be performed. Although it has been proposed, there is a similar problem that if the sensor or the center equipment breaks down, the light emitter cannot be controlled.

  An object of the present invention is to provide a guide light device that can be controlled without providing a center facility.

  Another object of the present invention is to provide a guide light device capable of simplifying the installation work with a simple equipment configuration and improving the operating rate of the entire system.

  A sensor unit for detecting the position and speed of a vehicle traveling on the road in the housing, a light emitting unit for lighting display, a control unit for inputting information from the sensor unit to control lighting of the light emitting unit, a control unit, and a sensor By providing the power supply unit that supplies power to the light emitting unit and the light emitting unit, the light emitting unit can be autonomously controlled by the detection information of the sensor unit of its own device. Further, by providing a wireless LAN by a wireless communication unit, sensor detection information and light emission unit control information of the upstream guide light device are acquired, and coordinated control is performed together with the sensor detection information of the own device.

  According to the present invention, by securing a power source when installing a guide light device, it is possible to construct a guide light system that performs autonomous distributed cooperative control, and it is possible to control a light emitting unit without providing a center facility. There is an effect that expansion of the apparatus is easy.

  A guide light device that can be controlled without providing a center facility has been realized by providing a sensor unit, a light emitting unit, a control unit, and a power supply unit in the housing.

  An embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a perspective view showing the configuration of the guide light system of this embodiment, and FIG. 2 is a configuration diagram showing the internal structure of the guide light device.

  As shown in FIG. 1, a plurality of guide light devices 1 to 4 are installed at set intervals on the road side of the road on which the vehicle travels. In this case, the upstream side of the guide light device 2 is the guide light device 1, and the upstream side of the guide light device 3 is the guide light device 2 and the guide light device 1.

As shown in FIG. 2, these guide light devices 1 to 4 are provided with a light emitting unit 11 for performing color display on the front side and a sensor unit 12 for detecting the position and speed of a vehicle traveling on a road. The unit 12 and the light emitting unit 11 are connected to a control unit 13 provided at the center. A wireless communication unit 14 that performs wireless communication with other guide light devices is connected to the control unit 13, and the control unit 13 is provided in a pillar portion of the guide light device and supplies power to drive each unit. It is connected to the power line 16 via. The power storage unit 15 and the power line 16 are collectively referred to as a power supply unit. The power of the power supply unit is supplied to the light emitting unit 11, the sensor unit 12, and the wireless communication unit 14 via the control unit 13 or individually. The light emitting unit 11, the sensor unit 12, the control unit 13, and the wireless communication unit 14 are housed in a housing.

  The light emitting unit 11 is of a type capable of displaying red, green and orange colors by an LED, or a type capable of displaying full color and capable of displaying high brightness.

  The light emitting unit 11 includes a lens, a reflection plate, and a light shielding plate, and can adjust an irradiation angle. For example, a light source is disposed in the vicinity of the first focal point of the elliptical reflector to form a light source unit, and a light guide light incident end portion composed of one or a plurality of optical fibers is fixed to the housing with a mounting bracket, A drive mechanism is provided in the part or the mounting bracket so that the distance between the light source part and the light guide incident end surface can be varied to cope with changes in the type of light source and changes in the light guide.

  For the sensor unit 12, a millimeter wave radar, a camera image recognition sensor, or the like is applied, and these sensors change the millimeter wave irradiation direction or the zoom of the camera to change a sensing angle that is a range in which the vehicle is detected. Can be adjusted. It is also possible to improve detection accuracy by using a millimeter wave radar and a camera image recognition sensor in combination.

  The wireless communication unit 14 employs IEEE802.11 standard wireless LAN or PHS. By applying an IEEE802.11 standard wireless LAN, PHS, or the like, the guide light device can be configured at low cost. Each guide light device is set with an IP address or a network address. By setting information that can identify each guide light device, the number of information obtained via the wireless communication unit 14 can be increased. It is possible to determine whether the information is information on a downstream guide light device.

  The control unit 13 includes a microcomputer or the like, and checks whether there is information from the upstream guide light device through wireless communication of the wireless communication unit 14. When there is no information from another guide light device, autonomous control of the light emitting unit is performed based on sensor information of the guide light device itself. When there is information from the upstream guide light device by wireless communication of the wireless communication unit 14, the information from the upstream guide light device and the light emitting unit are cooperatively controlled. In this way, the control unit 13 controls the lighting / extinguishing display of the light emitting unit 11 based on information from the sensor unit 12 and the wireless communication unit 14. The lighting display control of the light emitting unit 11 provides the driver of the vehicle with information such as the degree of danger of the vehicle and the inter-vehicle distance from surrounding vehicles.

  Although FIG. 2 shows the case where the power storage unit 15 and the power line 16 are provided as the power source unit, the power storage unit 15 is not necessary when wiring work for the power line is performed, and a battery such as a solar cell or a fuel cell including the power storage unit 15 is provided. When using the power line 16, the power line 16 is not necessary.

  In the example shown in FIG. 1, four guidelight devices 1 to 4 are shown, but the number of guidelight devices is increased or decreased according to the road conditions and the purpose of display to the driver. When the road condition is installed in a section with poor visibility, for example, the guide light device is installed every 3 to 4 m, which is shorter than usual, so that the driver can continuously see the display of the light emitting unit.

  In the example shown in FIG. 1, the sensing angle 7 of the sensor unit 12 is adjusted to be larger than the irradiation angle 6 of the light emitting unit 11 of the guide light device 3 so that the autonomous control of the guide light device can be performed. In this case, the vehicle 10 is first detected in the sensing range 9, and then the driver who has reached the irradiation range 8 of the light emitting unit 11 visually recognizes the lighting display of the guide light device 3. Sensing information and lighting / extinguishing control information at this time are transmitted to the downstream guide light device 4 through wireless communication 5 to perform cooperative control.

  A control method of the guide light device configured as described above will be described with reference to FIG. FIG. 3 is a flowchart of control of the guide light device.

  First, let us consider a case where there is no information from the upstream guide light device received by the wireless communication unit 14. For example, by comparing the network address of the guide light device 1 and the network address of the guide light devices 2 to 4 from the network address of each guide light device shown in FIG. Therefore, the sensor information of the guide light device 1 itself is acquired 21 and control is performed using this sensor information without using those pieces of information.

  The display color is green if there is no special alert from the speed of the vehicle 10 and red if it is a warning, and the timing of reaching the irradiation range of the light emitting unit and the timing of leaving from the irradiation range are determined from the position and speed of the vehicle. 27 is performed. By the decision 27, the lighting control 28 and the extinguishing control 29 of the light emitting unit 11 are autonomously performed. In this way, the display color and display timing of the light emitting unit can be autonomously controlled from the detection information of its own sensor unit. The control information is transmitted 30 as communication information to the guide light device on the downstream side by wireless communication.

For example, when the guide light device 1 fails, the information received from the guide light device 1 is identified by the network address received by the guide light device 2 by the wireless communication unit 14, and the control unit 13 determines that the failure has occurred. As a result, communication information cannot be obtained from the guide light device 1 on the upstream side, and communication information from the guide light device 3 and the guide light device 4 is identified by the network address. The same autonomous control is performed without using the communication information known to be.

  Next, for example, the case where the guide light device 3 acquires communication information from the guide light devices 1 and 2 on the upstream side or the guide light device installed on the upstream side by the wireless communication unit 14 will be described. The communication information from the guide light device 2 includes sensor information and light emission control information 24 of the guide light device installed one upstream from the network address, and sensor information and light emission of the guide light device installed two upstream. Unit control information 23, or sensor information and light emitting unit control information 22 of a guide light device installed further upstream is acquired. Further, sensor information of the guide light device 3 itself is acquired. From the sensor information and the light emitting unit control information acquired from the upstream guide light device, it is possible to estimate the vehicle speed 25 at the upstream position in advance, and acquire the lighting timing of the upstream guide light device. In consideration of sensor information of the guide light device 3 itself, the lighting / lighting timing linked between the guide light devices is calculated 26 and determined 27, and the lighting control 28 and the lighting control 29 of the light emitting unit 11 are determined as the guide light device. In cooperation with each other. The control information is sequentially transmitted 30 as communication information to the downstream guide light device by wireless communication. By doing so, it is possible to predict the vehicle arrival timing with high accuracy by the guide light device on the downstream side, and to control the display color and the display timing.

  Here, when a guide light system is comprised with the guide light apparatus which performs autonomous control, the radio | wireless communication part 14 does not need to be provided.

  By setting it as the above structures, the guide light system which can perform autonomous dispersion | distribution and cooperative control can be constructed | assembled easily. Moreover, the construction of the guide light device can be easily performed, and the operating rate can be improved. In addition, it is possible to deal with an increase in the number of guide light devices by installing equipment and setting a network address, and it is not necessary to change the cable wiring or control software.

It is a perspective view which shows the structure of the guide light system which is one Example of this invention. It is a block diagram of the guide light apparatus of a present Example. It is a flowchart of control of the guide light apparatus of a present Example.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1, 2, 3, 4 ... Guide light apparatus, 5 ... Wireless communication, 6 ... Irradiation angle, 7 ... Sensing angle, 8 ... Irradiation range, 9 ... Sensing range, 10 ... Vehicle, 11 ... Light emission part, 12 ... Sensor part , 13 ... control unit, 14 ... wireless communication unit, 15 ... power storage unit, 16 ... power line.

Claims (5)

  A sensor unit that detects the position and speed of a vehicle traveling on a road in the housing, a light emitting unit that lights up, a control unit that inputs information from the sensor unit and controls lighting of the light emitting unit, and the control A guide light device having a power supply unit for supplying power to the sensor unit, the sensor unit, and the light emitting unit.   A sensor unit that detects the position and speed of a vehicle traveling on a road in the housing, a light emitting unit that lights up, a control unit that inputs information from the sensor unit and controls lighting of the light emitting unit, and the control A guide light device comprising: a wireless communication unit that is connected to the unit and performs wireless communication with another guide light device; and a power supply unit that supplies power to the wireless communication unit, the control unit, the sensor unit, and the light emitting unit.   The sensor unit and the light emitting unit are arranged so as to face a vehicle traveling on a road, and the angle range at which the sensor unit senses the vehicle is set larger than the irradiation angle of the light emitting unit. Item 3. A guide light device according to item 1 or 2.   The wireless communication unit receives the sensor detection information and light emitter control information of the upstream guide light device by wireless communication, and processes them by the control unit together with the detection information of its own sensor unit to display the display color of the light emitting unit The guide light device according to claim 2, wherein display timing is controlled in cooperation with an upstream guide light device. 5. The guide light device according to claim 4, wherein sensor detection information and light emitter control information are sequentially transmitted from the upstream guide light device to the downstream guide light device between the plurality of guide light devices.

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