JP4556969B2 - Communication system and traffic signal controller - Google Patents

Description

  The present invention relates to a communication system and a traffic signal controller.

In recent years, an Intelligent Transport System (ITS) has been proposed for the purpose of promoting traffic safety and preventing traffic accidents. In this ITS, a communication device (infrastructure device) is installed on the road, and the information emitted from the antenna of this communication device is received by the in-vehicle device of the vehicle traveling on the road, and this information is utilized, It is possible to improve the safety of traveling of the vehicle (see Patent Document 1).
When such road-to-vehicle communication is performed wirelessly, from the viewpoint of securing the prospect of wireless communication, an arm is extended from the column installed on the sidewalk or the like to the roadway side, and the antenna of the communication device is mounted on this arm. Further, when the line of sight can be secured without providing the arm, an antenna can be attached to the support column.

Japanese Patent No. 2806801

In order to install the antenna of the communication apparatus on the road, it is not economical to provide a new support for the antenna, and it is not preferable from the viewpoint of the aesthetics of the road.
Therefore, since vehicle detectors, optical beacon heads, and the like are installed on the road, it is conceivable that an antenna is provided alongside a column or arm to which these are attached. However, even in this case, it is not preferable in terms of aesthetics.

  Accordingly, it is an object of the present invention to provide a new technical means that can eliminate the need for an antenna support column and that does not impair the beauty of the road.

  In order to achieve the above object, a communication system of the present invention includes a traffic signal lamp having a plurality of optical units having light emitters, a plurality of antennas incorporated in the traffic signal lamp, and control of wireless communication by the antenna. And a plurality of the antennas are separately incorporated into the plurality of optical units.

According to the present invention, the antenna can be made inconspicuous by incorporating the antenna into the traffic signal lamp, and a dedicated column for installing the antenna can be made unnecessary.
Furthermore, since a plurality of antennas are provided in the traffic signal lamp, it is preferable that the control unit is configured to perform diversity control.
In addition, the traffic signal lamp is installed on the road in consideration of visibility by the driver of the vehicle. For this reason, if this signal lamp is installed at a predetermined position on the road, it is possible to obtain a state of good visibility when performing wireless communication between the antenna and the in-vehicle device of the vehicle.

Further, it is preferable that at least one of the plurality of antennas is set to have a polarization different from that of the other antennas.
According to this, the polarization of the antenna can be switched and used in one traffic signal lamp.
Moreover, it is preferable that the plurality of antennas are incorporated in the traffic signal lamp with different positions in the height direction.

Moreover, it is preferable that the said control part has a position acquisition part which acquires the position information of a communicating party, and a change part which changes the directivity of the said antenna according to the said position information.
According to this, when the position acquisition unit acquires the position information of the communication partner, the changing unit can provide the antenna with directivity toward the communication partner.

  In addition, the traffic signal controller of the present invention includes the control unit of the communication system and a lamp control unit that turns on and off the traffic signal lamp, and the control unit is configured via the antenna. Signal information relating to the current and future display of the traffic signal lamp is transmitted to a vehicle traveling on a road where the traffic signal lamp is installed.

  According to the present invention, the antenna can be made inconspicuous by incorporating the antenna into the optical unit of the traffic signal lamp, and a dedicated column for installing the antenna can be made unnecessary.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[Overall configuration of communication system and overall configuration of traffic light]
FIG. 1 is a front view showing an embodiment of a communication system according to the present invention. The communication system includes a traffic signal lamp 1 (hereinafter simply referred to as a signal lamp), an antenna 4 provided in the signal lamp 1, and a control device 5 that controls wireless communication by the antenna 4. The traffic signal lamp 1 shown in FIG. 1 is for a vehicle installed on a road.
A support column 40 is installed on the side of a road such as a sidewalk, and an arm 41 is provided so as to protrude from the support column 40 to the roadway side, and the signal lamp 1 is attached to the arm 41.

The signal lamp device 1 includes a plurality (three in the illustrated example) of optical units 2 and a housing 3 in which these optical units 2 are incorporated. The three optical units 2 have red, yellow, and blue lamp colors. A eaves (not shown) is attached to each optical unit 2.
Moreover, the control apparatus 5 which performs control about the lamp light of the signal lamp device 1 and control for the radio | wireless communication mentioned later is attached to the support | pillar 40. FIG.

The installation structure of the signal lamp 1 may be other than that shown in the figure. Although not shown, the form of the column 40 and the arm 41 may be different, and the signal lamp 1 is installed on a pedestrian bridge. It may be. Further, the control device 5 may be provided in the housing 3 of the signal lamp device 1.
The control device 5 that controls lighting of the signal lamp 1 can be configured to perform wireless communication control via the antenna 4 described later (or a device that performs wireless communication control is built in the same housing. But can be a separate device. When separate, it is preferable that the device for performing the wireless communication control is installed in the vicinity of the control device for controlling the lighting of the signal lamp 1 or the like (the same column 40).

2, 3, and 4 are a perspective view, a front view, and a cross-sectional view of one optical unit 2. The optical unit 2 includes a light emitting diode 7 (hereinafter referred to as an LED) as a light emitter, a substrate 8 on which a plurality of LEDs 7 are mounted on a front surface 8a, a housing member 6, and a cover member 9. The substrate 8 has a wiring pattern formed on the front surface and the back surface thereof, and is connected to the terminal 37 of the LED 7. On the substrate 8, a plurality of LEDs 7 are arranged in a planar shape.
The LED 7 has a lens portion 38, and an LED element (not shown) is provided in the lens portion 38.

  The accommodating member 6 has a dish shape having a bottom portion (bottom wall) 6a and side portions (side walls) 6b erected from the peripheral edge of the bottom portion 6a, and is open forward. A cover member 9 is attached to the front portion that is the opening side. Thereby, the accommodation space part S is formed between the accommodation member 6 and the cover member 9, and LED7 and the board | substrate 8 are accommodated in this accommodation space part S. FIG. The substrate 8 is fixed to the housing member 6. Of the accommodation space S, the front space part S1 is the front space part S1 and the rear space part S2 is the rear space part S2.

  The cover member 9 has visible light permeability (transparent to visible light) and covers the plurality of LEDs 7 in the front. In this optical unit 2, the front is the light projecting side (the cover member 9 side), and the rear is the bottom 6 a side of the housing member 6.

  An antenna 4 is incorporated in the optical unit 2. That is, the signal lamp device 1 includes a plurality of optical units 2 and an antenna 4 incorporated in the optical unit 2. The antenna 4 of this embodiment is a patch antenna, and includes a patch element 11 and a ground element 12. That is, the patch element 11 and the ground element 12 are stored (accommodated) in the optical unit 2, that is, in the accommodating space S.

  FIG. 5 is a front view of the signal lamp device 1. In this figure, the signal lamp device 1 has three optical units 2a, 2b and 2c. In the illustrated embodiment, a plurality of (three in the illustrated example) antennas 4 a, 4 b, 4 c that are the same number as the optical unit 2 are provided in the signal lamp device 1. The antennas 4a, 4b, 4c are separately incorporated in the optical units 2a, 2b, 2c, respectively. Specifically, the first antenna 4a is incorporated in the left first optical unit 2a, the second antenna 4b is incorporated in the central second optical unit 2b, and the third antenna 4c is incorporated in the right third optical unit 2c. .

Thus, since one antenna 4 is incorporated in one optical unit 2 and another antenna 4 is incorporated in another optical unit 2, these antennas 4a, 4b and 4c are separated from each other. The signal lamp device 1 can be provided.
In the vehicular signal lamp, since the distance between the centers of the optical unit 2 is a predetermined value (generally about 40 cm), the antenna distance is the same (substantially the same) as the distance between the centers. In this state, the plurality of antennas 4a, 4b, and 4c can be set apart. The plurality of antennas 4 a, 4 b, 4 c constitute a set of antenna bodies, and the set of antenna bodies is provided in one signal lamp device 1. The communication system is configured as a multi-antenna system. The form and mounting structure of each antenna 4 will be described later.

FIG. 6 is a block diagram of the communication system of the present invention.
The control device 5 is composed of a programmable microcomputer having a CPU and a storage device 46, and performs control processing of wireless communication by the antennas 4a, 4b, 4c in addition to controlling the light of the optical units 2a, 2b, 2c. Specifically, since the plurality of antennas 4a, 4b, and 4c are incorporated in the optical units 2a, 2b, and 2c, the control device 5 controls the multi-antenna system using the plurality of antennas 4a, 4b, and 4c. For example, diversity control can be performed.
The control device 5 stores a program for executing each predetermined function in the storage device 46, and includes a main control unit 47, a position acquisition unit 48, and a change unit 49 as functional units to be executed by the program. Yes. Note that these functional units by the control device 5 will be described later.
FIG. 6 shows a case where the communication system is an adaptive array antenna system and a combined diversity system, which will be described later. In this case, the control device 5 includes a transmission / reception unit 61 for transmitting / receiving information, a combiner 62, and a transfer unit 63.

  The communication partner in this communication system is an in-vehicle device 50 of a vehicle or a light vehicle traveling on the road where the signal lamp 1 is installed. In this case, road-to-vehicle communication is possible. Further, as another communication partner, it is installed at another signal lamp 1 installed near (in the same intersection) near the installation position of the signal lamp 1, that is, at another signal lamp 1 or an adjacent intersection. An antenna 4 (and a control device 5) provided in a signal lamp (not shown). In this case, communication between the signal lamps 1 and 1, that is, communication between roads becomes possible. Still another communication partner may be a mobile terminal (mobile phone) owned by a pedestrian who passes by the roadside where the signal lamp 1 is installed.

[Function of control device 5]
The signal lamp 1 is provided with a plurality of antennas 4a, 4b, 4c. Since the plurality of antennas 4a, 4b, and 4c are provided side by side with a predetermined distance between them, the main control unit 47 of the control device 5 can perform space diversity. Specifically, the main control unit 47 selects and communicates with a strong antenna from the plurality of antennas 4a, 4b, and 4c.
In addition to such an antenna selection method, the main control unit 47 can employ a maximum ratio combining method.
As shown in the block diagram of FIG. 21, the control device 5 in the case of selective diversity includes a transmission / reception unit 64 for transmission / reception of information and a switch 65 for selection.

The communication system can also be configured as an adaptive array antenna system. For this purpose, the antennas 4a, 4b, 4c are arranged in an array to form an adaptive array antenna. The main control unit 47 can adaptively control the weighting of each antenna in accordance with the change in the radio wave environment (propagation environment) and the purpose of use to electrically change the directivity.
An operation in which the communication system performs wireless communication with a vehicle traveling on a road by the function of the control unit 5 will be described below.

FIG. 8 is a plan view of a road (intersection X) where the communication system of the present invention is provided. A signal lamp 1 is installed at an intersection X, and the signal lamp 1 is provided with an antenna 4. The vehicle C that travels toward the intersection X is equipped with an in-vehicle device 50 for communication.
The in-vehicle computer of the in-vehicle device 50 has a function of obtaining its position information by specifying its own position, such as a GPS function, so that the in-vehicle device 50 can acquire position information about the position of the vehicle C. it can. The position information may be one or both of coordinate information about latitude and longitude and lane information about the lane that is running. If the accuracy of the coordinate information is high, it will be clear which lane the vehicle is in, so the lane information may be omitted.

The in-vehicle device 50 transmits the position information to the antenna 4 of the signal lamp device 1 from an in-vehicle antenna (not shown) of the in-vehicle device 50. The in-vehicle device 50 further transmits travel information including speed information about the travel speed of the vehicle C. When the vehicle C changes the lane, the travel information may include lane change information about the planned lane change, or if the vehicle C is going to turn left and right, Information on the direction of travel may be included. Moreover, you may include the information regarding the travel time from a certain point to another point, the probe information regarding the traveling locus of a vehicle, etc.
Then, the position information and the travel information are received by the antenna 4 of the signal lamp 1, and the position acquisition unit 48 (see FIG. 6) of the control device 5 acquires the position information and the travel information.

  The position acquisition unit 48 can specify the position of the vehicle C after acquiring the information based on the acquired position information and travel information. Then, as shown in FIG. 8, the changing unit 49 (see FIG. 6) of the control device 5 dynamically changes the directivity of the antenna 4 from B1 to B2 according to the position information and the traveling information. . That is, the changing unit 49 controls the directivity in the direction of the vehicle C by controlling the phase and amplitude of the signals from the plurality of antennas 4.

The position acquisition unit 48 estimates the position of the vehicle C after the reception based on the position information and travel information received from the vehicle C, and the change unit 49 causes the antenna to follow the vehicle C that continues to travel. Directivity can be changed.
Or the control apparatus 5 can perform the said transmission / reception of the positional information between the vehicle equipment 50, and the said control by the position acquisition part 48 and the change part 49 repeatedly over multiple times. In this case, the control device 5 can change the antenna directivity so as to follow the vehicle C traveling based on the position information without receiving the traveling information.

As described above, the control device 5 can follow the vehicle C and move the antenna directivity in a direction having a horizontal component. For example, even if the vehicle C changes the lane to the right side to make a right turn, the control device 5 can move the antenna directivity in the horizontal direction (right lane side) by following this. Then, the control device 5 can change the antenna directivity directed to the road ahead of the antenna 4 to the directivity toward the center of the intersection X. As a result, as will be described later, predetermined information can be communicated between the road and the vehicle, and the gain of the road-to-vehicle communication can be increased.
Further, the changing unit 49 can control the null point in the direction of the interference wave to improve the communication quality.

The change of the antenna directivity by the control device 5 may be performed dynamically so as to continuously follow the traveling vehicle C. However, when it is not continuously followed (when it is not necessary to follow). The antenna directivity may be switched statically. For example, the antenna directivity may be switched depending on the time zone.
Alternatively, depending on the number of vehicles C when the control device 5 performs carrier sense with the in-vehicle device 50, the changing unit 49 determines whether to change the antenna directivity dynamically or statically. And make the change. For example, when there is one vehicle as a communication partner, the directivity may be dynamically changed so as to follow the vehicle, and when there are a plurality of vehicles, it may be changed statically.
In addition, the directivity can be changed in conjunction with the display of the traffic signal lamp 1. For example, in the case of an intersection with an arrow lamp, for example, if the right of traffic is given only to the right turn vehicle, the directivity can be narrowed down to the right turn lane, and if it is a green light, the far side from the intersection Directivity centered, and if it is a red signal, directivity centered around the intersection may be provided.

In the above embodiment, a plurality of antennas 4 are arranged in the horizontal direction in the signal lamp 1 installed horizontally as shown in FIG. 1, that is, the signal lamp 1 in which the optical units 2 are arranged in the horizontal direction. In addition to this, an arrow optical unit (not shown) is provided below the red, blue, and yellow optical unit 2 of the signal lamp 1 of FIG. Further, an antenna may be further incorporated. Further, an antenna can be incorporated into an optical unit such as a traffic information board.
In this case, a plurality of antennas are arranged in the vertical direction, and the control device 5 can move the antenna directivity in the vertical direction (vertical direction) using the antennas installed in the vertical direction. .
In this case, the position acquisition unit 48 determines whether the vehicle C exists in the distance or in the vicinity by comparing with the self antenna position, and the changing unit 49 determines whether the vehicle C exists in the vicinity or not. The antenna directivity can be changed in the vertical direction. In other words, the changing unit 49 can change the antenna directivity in the perspective direction from the antenna 4 to the vehicle C.

Moreover, although not shown in figure, when the signal lamp device 1 is attached vertically long, it becomes the structure by which the optical unit 2 was provided along with the up-down direction. By incorporating the antenna 4 in each of the optical units 2, the control device 5 can move the antenna directivity in the perspective direction (vertical direction). An example in which the signal lamp 1 is mounted vertically is the signal lamp 1 in the snow country region, for example.
When changing the directivity in the far and near directions, it is preferable that the control device 5 performs control to increase the transmission output for the far distance and lower the transmission output for the near area.

Information that can be transmitted from the control device 5 to the in-vehicle device 50 will be further described. This information can be transmitted to the vehicle by changing the antenna directivity so that the traveling vehicle follows the function of the control device 5.
The control device 5 (traffic signal controller) relates to the present and future display of the traffic signal lamp 1 with respect to a vehicle traveling on the road where the traffic signal lamp 1 is installed or a nearby road via the antenna 4. Signal information can be provided.
The signal information refers to information related to the current or future signal lamp color displayed by the traffic signal lamp 1, and includes information related to the scheduled duration of display of each signal lamp color, the display order, and the like.
For example, the currently displayed lamp color is a blue light and its scheduled duration is 5 seconds, the next displayed lamp color is a yellow signal and its scheduled duration is 8 seconds, and the next displayed lamp color. It is preferable to include information such as a right turn blue arrow light whose estimated duration is 5 to 10 seconds in a predetermined format. Note that only the currently displayed lamp color and its duration may be provided, or information for one cycle may be provided collectively. Further, in addition to these pieces of information, parameter information related to the control, information on a time zone in which the control is performed, and the like may be included at the point where the point sensitive control is performed.

Then, the vehicle-side computer on the vehicle side that has received the signal information estimates the time required to reach the stop line from the distance to the stop line and the traveling speed, acceleration, etc. of the vehicle, and after the required time has elapsed. Can be estimated. For example, even if a green signal is displayed at the present time, if the signal light color is predicted to be a red signal when arriving at the stop line, the in-vehicle computer is safely stopped before the stop line. Can be controlled. Conversely, if it can be determined that the vehicle can safely pass through the intersection unless the vehicle is decelerated, control may be performed to maintain the speed.
Further, the in-vehicle computer may perform not only control driven by the in-vehicle device but also operation for assisting the driving operation of the driver such as brake assist.
The in-vehicle computer may notify the vehicle occupant of the determination result by voice or image information. For example, a voice of “The signal will change soon and should be stopped” may be emitted to the driver, or may be displayed on the screen of the head-up display or the navigation device with characters or symbols.

  FIG. 9 is an explanatory diagram for explaining another function of the communication system. This communication system includes a plurality of signal lamps 1 installed at a certain intersection X, an antenna body including a plurality of antennas 4 incorporated in each of the signal lamps 1, and a control device 5. In addition, although the some control apparatus 5 may be provided so that the one control apparatus 5 may control one antenna body (one signal lamp device 1) (form of FIG. 9), a plurality of antenna bodies ( A plurality of signal lamps 1) may be controlled by one control device 5 (not shown). When a plurality of control devices 5 are provided, these control devices 5 may jointly perform the following control processing, or any one control device 5 may perform the control processing as a representative.

In FIG. 9, a set of antenna bodies provided in one signal lamp device 1 has a configuration capable of having a horizontal antenna directivity inclined in the horizontal direction with respect to the front. Specifically, the antenna body provided in one signal lamp device 1 is installed at the same intersection X in addition to the antenna directivity toward the front so that communication with the vehicle ahead is possible. It is the structure which can have the directivity of the horizontal direction which goes to the antenna 4 of this signal lamp device 1.
In order to obtain this configuration, the control device 5 can change the directivity by using the plurality of antennas 4 constituting a set of antenna bodies as described above. Thereby, it can be set as the structure which has the directivity of a horizontal direction. Alternatively, the directivity of one of the plurality of antennas 4 may be fixed in advance in the horizontal direction and the directivity of another antenna 4 may be set to the front.

  The communication system configured as described above can function as a relay communication unit for communication (vehicle-to-vehicle communication) between the vehicle C1 and the vehicle C2 respectively traveling on different roads connected to the intersection X. That is, the vehicle-mounted device (not shown) of the first vehicle C1 traveling on one road can wirelessly communicate with the antenna 4x of the first signal lamp 1x in front of the traveling direction. . Thereby, the antenna 4x can receive the information transmitted from the vehicle C1. The control device 5 transmits the received information from the antenna 4x to the antenna 4y in another second signal lamp 1y. At this time, the function having the antenna directivity in the horizontal direction is used. And the control apparatus 5 can transmit the said information to the vehicle equipment of the vehicle C2 which drive | works the front (other road) from the antenna 4y.

According to this, even if the line of sight between the vehicle C1 and the vehicle C2 is poor, the communication system provided at the intersection X is made to function as a relay communication unit so that the connection between the vehicle, the road, the road, and the vehicle Communication can be performed. Thereby, for example, in both the vehicles C1 and C2, the vehicle-mounted device 50 can notify the driver of the existence of the partner vehicle in advance, and an accident at the intersection X can be prevented.
Although the said embodiment includes communication with a vehicle (vehicle equipment) in a communication system, a communication system can be utilized for communication only between roads. That is, you may make this communication system function only about communication between the antenna 4x of the 1st signal lamp 1x and the antenna 4y of the 2nd signal lamp 1y.

Another function of the communication system will be described.
FIG. 10 is a front view showing another embodiment of the signal lamp device 1 in which the antenna 4 is incorporated. In this embodiment, a plurality of antennas 4 are incorporated in the optical unit 2 of the traffic signal lamp 1 with different positions in the height direction. That is, the plurality of antennas 4 are installed with their positions shifted in both the horizontal direction and the vertical direction.
Specifically, the first antenna 4a is incorporated in the horizontal center portion of the first optical unit 2a at the left end and in the upper portion in the vertical direction, and the horizontal center portion and vertical direction of the second optical unit 2b. The second antenna 4b is incorporated at the center of the third optical unit 2b, and the third antenna 4c is incorporated at the center in the horizontal direction of the third optical unit 2c and at the bottom in the vertical direction. In this case, the control device 5 can simultaneously change the antenna directivity in the horizontal direction and the vertical direction. In particular, when the signal lamp 1 (optical unit 2) is large, it is easy to adopt this configuration.

  Further, since the signal lamp device 1 is provided with a plurality of antennas, at least one of the plurality of antennas can be configured to have a polarization different from that of the other antennas. . FIG. 7 is a front view of the signal lamp device 1. In this figure, each of the plurality of antennas 4a, 4b, 4c is set to have a different polarization from the other antennas. Specifically, the polarization of the first antenna 4a is vertical, the polarization of the second antenna 4b is 45 ° oblique, and the polarization of the third antenna 4c is horizontal. Although not shown, one of the antennas 4a, 4b, 4c can be circularly polarized.

Thus, the main control unit 47 can perform polarization diversity by dividing the polarization in a set of antenna bodies. According to this, in one set of antenna bodies (a plurality of antennas 4a, 4b, 4c) incorporated in one signal lamp device 1, the polarization can be switched and used. For example, the main control unit 47 can perform communication by switching to an antenna with strong radio waves.
In addition, since the signal lamp device 1 is provided with a plurality of antennas, at least one of the plurality of antennas may be configured to have different directivity from other antennas. it can.

  As another function of the communication system, the main control unit 47 can perform various types of diversity such as transmission diversity, frequency diversity, and directivity diversity using the antennas 4a, 4b, and 4c. Alternatively, a MIMO system can be configured by the control device 5 and the plurality of antennas 4a, 4b, 4c. As shown in the block diagram of FIG. 22, the control device 5 in the case of a MIMO system includes an arithmetic processing unit 66 and a transmission / reception unit 67 for transmitting / receiving information.

As described above, the communication quality can be improved by performing diversity by the plurality of antennas 4a, 4b, 4c and the control device 5 that controls the wireless communication by the antennas 4a, 4b, 4c. In addition, communication limited to a specific area is possible by controlling the antenna directivity. Further, the gain can be improved except for the interference wave. Also, the antenna directivity can be changed over time.
Since the antenna 4 is incorporated in the optical unit 2, the antenna 4 can be made inconspicuous.

[Details of Antenna 4 (Part 1)]
2 to 4, the antenna 4 is a patch antenna, and includes a patch element 11 and a ground element 12. The patch element 11 is formed in a circular flat shape, and is supported and fixed by a support member 13 erected forward from the substrate 8. The support member 13 is made of an insulating member. The patch element 11 is provided in a range A from the cover member 9 to the front end 39 of the LED 7. In FIG. 4, the cover member 9 has a rear surface (back surface) 9a having a concave curved surface and a front surface 9b having a convex curved surface, and the patch element 11 is provided rearward from the rear surface 9a of the cover member 9. Yes. The outline of the patch element 11 may be a rectangle other than a circle (see FIG. 11).
Here, the cover member 9 is an uneven curved surface. However, if the signal lamp 1 is an LED lamp, it may be a flat surface.

  The ground element 12 is formed in a circular planar shape (flat plate shape), and is attached to the substrate 8 on the front surface 8 a of the substrate 8. For example, the ground element 12 is fastened to the housing member 6 together with the substrate 8 by screws. Alternatively, the ground element 12 may be supported and fixed by the support member 13 erected on the substrate 8. The ground element 12 is provided behind the patch element 11 and between the substrate 8 and the front end 39 of the LED 7 in the front-rear direction. The contour shape of the ground element 12 is larger than the contour shape of the patch element 11.

  As a result, the ground element 12 and the patch element 11 are provided in the front space S1, the patch element 11 is provided in the range A from the cover member 9 to the front end 39 of the LED 7, and the ground element 12 is the patch element 11. It will be in the state provided in the back. The ground element 12 and the patch element 11 are arranged to face each other in the front-rear direction, and the directivity of the antenna 4 alone is the direction from the signal lamp device 1 toward the front. That is, the light projecting direction by the optical unit 2 and the antenna directivity can be substantially matched, and the signal lamp 1 is installed at a position where the line of sight is good with respect to the vehicle. A good communication state can be obtained with an in-vehicle device (not shown).

In addition, in order to use the signal lamp 1 in which the antenna 4 is stored in an intelligent road traffic system (ITS) that performs radio communication between road vehicles, when the use frequency is set to 715 MHz to 725 MHz, the ground element 12 and the patch are used. The space | interval of the front-back direction with the element 11 can be set to 10-40 mm. This is the case where air is interposed between the ground element 12 and the patch element 11.
The distance between the ground element 12 and the patch element 11 in the front-rear direction is about 20 to 30 mm when the outer diameter of the patch element 11 is about 170 mm to 230 mm and the hole size is about 10 mm to 25 mm. Is preferred. Moreover, if the hole size is about 25 to 35 mm, about 10 to 25 mm is preferable. That is, the smaller the surface area of the patch element 11, the smaller the distance in the front-rear direction from the ground element 12, and the larger the surface area, the wider the distance from the ground element 12.

In the embodiment of FIG. 4, the patch element 11 can be disposed in front of the front end 39 even if the distance from the front surface 8a of the substrate 8 to the front end 39 of the LED 7 is small. It is easy to set the distance in the front-rear direction with the patch element 11 to a desired value.
When the ground element 12 and the patch element 11 are insulated only by air, the distance between them is about 20 to 30 mm, but a resin plate is provided as an insulating member between the ground element 12 and the patch element 11. In this case, since the dielectric constant between the two changes, the distance between the two can be made smaller than the above value. Examples of the insulating member include polyethylene, polyethylene terephthalate, fluororesin plate, glass epoxy, FRP, and polyacetal plate.
The ground element 12 and the patch element 11 may be arranged in parallel, but one or both of the patch element 11 and the ground element 12 are inclined with respect to the substrate 8 in order to adjust the antenna directivity. It may be arranged.

  Note that the signal lamp 1 is normally installed with the board 8 itself inclined slightly downward in view of visibility to the driver. Therefore, by attaching the patch element 11 and the ground element in parallel to the substrate 8, the directivity of the antenna 4 is also directed downward, but the purpose is to limit the radio communication area between road vehicles and increase the certainty. As an alternative, the substrate 8 may be tilted further downward.

In addition, since the ground element 12 and the LED 7 overlap with each other in the front-rear direction, a plurality of holes 14 are formed in the ground element 12 as openings through which the LED 7 (the lead wire of the LED 7) is inserted. The arrangement of the holes 14 is matched with the arrangement of the LEDs 7, and the ground element 12 has a mesh structure.
Thereby, LED7 can be inserted in the hole 14 of the ground element 12, and the ground element 12 can be installed in a predetermined position so that the ground element 12 may not interfere with LED7. And according to this form, since the ground element 12 is located behind the front end 39 of the LED 7, it is possible to prevent the ground element 12 from obstructing forward light emission (lamp light) by the LED 7.
As shown in the figure, the opening 7 formed in the ground element 12 can be arranged such that the LED 7 can be disposed so as not to interfere with the element by making a hole 14 in the element. However, although no hole is provided, for example, the conductor portion (conductor portion) of the element is arranged in a meandering manner (the conductor portion is arranged so as to be drawn in a single stroke), and the LED 7 is not interfered with the element. It can also be arranged.

A terminal portion 19 for connecting the coaxial cable 15 for the antenna 4 is attached to the housing member 6 (bottom portion 6a), and the coaxial cable 15 extending from the control device 5 of FIG. Can do. A coaxial cable 15 a extending from the terminal portion 19 to the rear space portion S <b> 2 is connected to the antenna 4. The coaxial cable 15a includes an inner conductor 15b, an insulator 15c, an outer conductor 15d, and a covering portion 15e. The inner conductor 15b of the coaxial cable 15a is connected to the patch element 11, and the outer conductor 15d is a ground element. 12 is connected. The inner and outer conductors 15b and 15d and the elements 11 and 12 (conductor portions of each element) can be connected and fixed by soldering, but methods other than soldering may be used.
A power cable (not shown) for the LED 7 extending from the control device 5 in FIG. 1 is connected to the LED substrate 8 via a terminal portion (not shown) attached to the bottom 6 a of the housing member 6. Yes.

  According to the above embodiment, the antenna unit is provided by the support member (mounting portion) 13 for providing the patch element 11, the ground element 12, and the patch element 11 in the range from the cover member 9 to the front end 39 of the LED 7. The antenna unit is built in the signal lamp device 1.

FIG. 11 is a perspective view of the optical unit 2 incorporating the antenna 4. For ease of explanation, the LED 7 is omitted from the illustration. The patch element 11 of the antenna 4 has a rectangular outline shape.
The patch element 11 in front of the front end 39 of the LED 7 has visible light transmission in the thickness direction (front-rear direction) of the patch element 11 so as not to impede the forward projection of the LED 7. (Transparent to visible light).

Here, the visible light transmissivity in the patch element 11 means not only the case where the conductor portion (conductor portion) of the patch element 11 is transparent or translucent, but the conductor portion constituting the patch element 11 is visible. Although the light is blocked, visible light passes through the portion of the patch element 11 where the conductor portion is not provided, and the visible light emitted behind the patch element 11 reaches the front of the patch element 11. .
Specifically, the patch element 11 is made of a conductor having an opening for transmitting visible light. That is, as shown in FIG. 11, the patch element 11 has visible light permeability by using the patch element 11 as a conductor having a mesh structure. Thus, in order to make the patch element 11 have a mesh structure, the patch element 11 can be formed by a conductive wire (a conductive wire is knitted).

For example, when the patch element 11 has a mesh structure with a conductor having a diameter (width) of 1 mm, the pitch (mesh spacing) of the conductor is set to a predetermined value (for example, 20 mm) in the vertical and horizontal directions. A mesh metal element can be obtained. When this pitch is 20 mm, the pitch is about 1/20 wavelength, the frequency used can be about 720 MHz, and the wavelength can be about 420 mm.
Further, the number of meshes (mesh roughness) of the patch element 11 can be changed and can be made coarse. For example, a mesh-like metal element obtained by dividing one surface of the patch element 11 into four can be used. In addition to this, although not shown, one surface may be divided into two parts or three parts.

The interval between meshes is not particularly limited, but is preferably 1/5 wavelength or less, and particularly preferably 1/10 wavelength or less. The smaller the mesh interval, the higher the frequency.
In order to secure the strength of the conducting wire, the diameter (width) of the conducting wire is preferably 0.5 mm or more, while it is preferably 2 mm or less in order to increase the light transmittance. However, when the conductor is manufactured by a method of vapor-depositing on a resin plate or the like, since there is little need to consider the strength, the width of the conductor may be 0.5 mm or less.

  Although not shown, the patch element 11 may be visible light transmissive by using a conductor having an outer frame structure (frame structure). This outer frame structure is a structure obtained by providing a conductive wire only in the contour portion of the patch element 11 having a planar shape.

  In addition, when the patch element 11 has a mesh structure or an outer frame structure, a mesh made of a metal film (metal thin film) may be formed on the surface of the plate member, in addition to using the conductive wires as described above. In this case, as shown by a two-dot chain line in FIG. 4, the plate member 16 having visible light transmission is provided between the cover member 9 and the front end 39 of the LED 7. Alternatively, the patch element 11 having a mesh structure or an outer frame structure may be formed on the back surface (front surface in the illustrated example). The plate member 16 is attached to the support member 13.

As the plate member 16, for example, a transparent resin plate can be used. The plate member 16 is preferably made of a material that sufficiently transmits visible light. For example, it is excellent in terms of strength even if it is thin, such as polycardate, acrylic, polyethylene terephthalate, and glass, and it is preferable because it is inexpensive.
As a specific example in the case where the plate member 16 is used, a fine mesh composed of a conductor portion having a line width of 10 μm and a pitch (mesh interval) of 100 μm may be formed on the surface of the plate member 16. Thus, when forming a fine mesh in the plate member 16, it is preferable that the line width is 1 μm or more and 50 μm or less, and the pitch is 50 μm or more and 1000 μm or less.
Note that the mesh shape is not limited to the quadrangular shape as illustrated, but may be a triangular shape or a honeycomb shape, and may be a radial shape (spider web shape) or the like as a whole.

  Further, in order to make the patch element 11 have visible light permeability, the patch element 11 can be formed from a thin film conductor (thin film metal) having visible light permeability. Then, by forming the thin film conductor on the plate member 16, the patch element 11 can be formed thin and in a predetermined shape. In this case, the thickness of the thin film conductor is preferably 1 μm or more and 100 μm or less, and thereby has visible light permeability.

  As a method for forming the patch element 11 on the plate member 16, there are the following methods. The patch element 11 is formed singly and is affixed to the plate member 16. In this case, the patch element 11 is bonded to the plate member 16 with an adhesive member (adhesive tape). Alternatively, the patch element 11 may be formed by performing metal deposition on the plate member 16. Alternatively, the patch element 11 may be formed on the plate member 16 by printing. Alternatively, the patch element 11 may be formed by performing metal plating on the plate member 16.

The ground element 12 is formed from a metal plate. The material of the patch element 11 and the ground element 12 is preferably a material having conductivity and high conductivity. For example, copper, a copper alloy such as brass, aluminum is preferable, and iron, nickel, or other metal is used. You can also. In addition, since a high-frequency current flows on the surface, the plate member 16 may be metal-deposited or metal-plated (gold or silver plating) (not shown).
The housing member 6 of the optical unit 2 is made of a steel plate, aluminum, or resin. The cover member 9 is a lens and is made of glass or resin.
Here, the cover member 9 is an uneven curved surface. However, if the signal lamp 1 is an LED lamp, the cover member 9 may be a flat plate such as flat glass instead of a lens.

  Another embodiment of the signal lamp with built-in antenna in which the antenna 4 is built in the optical unit 2 will be described. FIG. 12 is a cross-sectional view showing the optical unit 2 and the antenna 4 provided in the signal lamp. This signal lamp device is provided with an optical unit 2 and an antenna 4 as in the above-described embodiment. The optical unit 2 has a substrate 8 on which the LED 7 is mounted and a visible light transmitting LED 7 in front. And a cover member 9 for covering. The antenna 4 includes a patch element 11 provided in a range A from the cover member 9 to the front end 39 of the LED 7, and a ground element 12 behind the patch element 11. Visible light transmission.

The difference between the embodiment of FIG. 12 and the above-described embodiment (FIG. 4) is the attachment structure of the patch element 11 and the position of the ground element 12, and the other configurations are the same.
That is, the patch element 11 is formed on the rear surface 9 a of the cover member 9. That is, the patch element 11 is formed by being caught on the rear surface 9 a of the cover member 9. In this case, the patch element 11 has a curved surface shape along the concave curved surface of the cover member 9.
The ground element 12 is provided in front of the front end 39 of the LED 7.

In this case, the ground element 12 also has visible light transparency. By making the ground element 12 the same configuration as the patch element 11, it is possible to have visible light transparency. That is, the ground element 12 is made of a conductor having a mesh structure or an outer frame structure. The ground element 12 can be made of a thin film conductor having visible light permeability.
Further, as in the case where the patch element 11 of FIG. 4 is formed on the plate member 16, in FIG. 12, the optical unit 2 has a plate member 17 (two-dot chain line in FIG. 12) having visible light transmission. The ground element 12 can be formed on the front surface or the rear surface of the plate member 17. The method for forming the ground element 12 on the plate member 17 is the same as that for the patch element 11.

In the embodiment of FIG. 12, the ground element 12 is provided in front of the front end 39 of the LED 7. However, since the ground element 12 has visible light transmission, light is emitted forward from the front end 39 of the LED 7. It is possible to prevent obstruction of (lamp). In this case, the hole 14 necessary for the ground element 12 in FIG. 4 is not necessary.
As another form, circuit wiring (wiring pattern portion) formed on the LED substrate 8 can be used (also used) as the ground element.

In each of the above embodiments, the patch element 11 and the ground element 12 are provided in the front space portion S1 of the space portion S.
In the embodiment of FIG. 12, the patch element 11 is provided on the rear surface 9a of the cover member 9, but may be provided on the surface 9b (not shown). In this case, it is preferable to provide a protective cover sheet (not shown) on the patch element 11 formed on the surface 9b. This cover sheet has visible light permeability.

  When the patch element 11 is provided on the rear surface 9a (or front surface 9b) of the cover member 9 as described above, the patch element 11 is thinned in the same manner as the patch element 11 is formed on the plate member 16 in the embodiment of FIG. It becomes easy to form in a predetermined shape. Further, a separate member for forming the patch element 11 is not necessary.

As still another embodiment of the signal lamp with a built-in antenna, the ground element 12 in FIG. 12 may be disposed behind the front end 39 of the LED 7 and in front of the substrate 8 as shown in FIG.
Although not shown, the ground element 12 may be provided behind the substrate 8. In this case, the ground element 12 is supported and fixed by a second support member provided behind the substrate 8.

  The antenna 4 may further include a second patch element in addition to the ground element 12 and the patch element 11 (first patch element 11) (described with reference to FIG. 4). The second patch element is disposed between the first patch element 11 and the cover member 9. The second patch element is supported and fixed at a predetermined position by the support member 13. Alternatively, the second patch element may be provided on the rear surface 9a or the surface 9b of the cover member 9 (not shown). That is, this second patch element is also incorporated in the optical unit 2.

Thereby, the 1st patch element 11 and the 2nd patch element are provided facing the front-back direction. The first patch element 11 is a power feeding element that is fed by the coaxial cable 15a, while the second patch element is a parasitic element that is not fed by the coaxial cable 15a. In this way, by making the patch element into two layers, a broadband frequency characteristic can be obtained.
As another form, circuit wiring (wiring pattern portion) formed on the substrate 8 of the LED 7 may be used as the ground element. That is, the substrate 8 may be used as the wiring portion for the LED 7 and the ground element 10.

  In FIG. 7, the form in which each of the plurality of antennas 4 a, 4 b, 4 c is set to have a different polarization from the other antennas has been described. A specific configuration with various polarization directions will be described.

  In the form of FIG. 13, two opposing sides of the patch element 11 are in the left-right direction, and another opposing two sides are in the up-down direction. The feeding point of the coaxial cable 15a to the antenna 4 (patch element 11) is the upper edge and the center in the left-right direction (or the lower edge and the center in the left-right direction: that is, on the X axis). As a result, the surface of the electric field is vertical polarization (polarization in the X-axis direction). Although not shown, the feeding point of the coaxial cable 15a to the antenna 4 (patch element 11) is the right edge (or the left edge) and the center in the vertical direction (on the Y axis), so that the surface of the electric field Can be horizontal polarization (polarization in the Y-axis direction). Furthermore, the oblique polarization can be obtained by tilting the patch element 11 and its feeding point in FIG. 13 to 45 °.

  Further, the patch element 11 of the antenna 4 in FIG. 14 has two feeding points (coaxial cable 15a) on the X axis and the Y axis. In this case, a dual polarization patch antenna of vertical polarization and horizontal polarization can be obtained. Further, in this embodiment, by inputting a signal having the same amplitude and a phase difference of 90 ° to the two coaxial cables 15a, it can be used as a circularly polarized antenna. Moreover, it is good also as a structure which can switch these dynamically with a switch etc.

  The patch element 11 of the antenna 4 of FIG. 15 is provided such that two opposite sides and another opposite two sides are inclined. A feeding point (coaxial cable 15a) is provided at the center of each of the two adjacent sides. In this case, a patch antenna with dual polarization of + 45 ° polarization and −45 ° polarization can be obtained. Further, in this embodiment, by inputting a signal having the same amplitude and a phase difference of 90 ° to the two coaxial cables 15a, it can be used as a circularly polarized antenna.

  The patch element 11 of the antenna 4 in FIG. 16 has two opposite sides in the left-right direction and another two opposite sides in the vertical direction. A single feeding point (coaxial cable 15 a) is provided at the corner (on the diagonal line) of the patch element 11. In this case, a circularly polarized antenna can be used.

  The patch element 4 of the antenna 4 of FIG. 17 has a contour shape (hexagonal shape) obtained by linearly cutting a pair of diagonal portions from a rectangle. The feeding point to the patch element 11 by the coaxial cable 15a is on the Y axis. Thereby, it can be set as a circularly polarized antenna.

According to each embodiment described above, the antenna 4 having the patch element 11 and the ground element 12 is incorporated in the optical unit 2. 1 has three optical units 2, and an antenna 4 is incorporated in each optical unit 2. Thereby, the antenna 4 can be installed in the signal lamp 1 without making it conspicuous, and the aesthetic appearance of the road is not impaired.
And since the antenna 4 is incorporated in the optical unit 2 of the signal lamp device 1, a dedicated column for installing the antenna can be dispensed with. Moreover, although the patch element 11 is provided in front of the front end 39 of the LED 7, the patch element 11 has visible light permeability, and thus prevents the LED 7 from emitting light forward (lamp light). Can be prevented.
Further, since the antenna 4 is not in an exposed state (a protruding state), it is necessary to additionally consider the wind load received by the antenna 4 in the design of the support column 40 and the arm 41 (FIG. 1) for attaching the signal lamp 1. There is no. Further, it is not necessary to additionally consider rainproof, rustproof, and dustproof for the antenna 4.

  Further, since the traffic signal lamp 1 is installed on the road in consideration of visibility by the driver of the vehicle, the signal lamp of each embodiment is installed at a predetermined position on the road, so that the antenna 4 and the vehicle When performing wireless communication with the in-vehicle device, a state with a good view is naturally obtained. As a result, the antenna 4 incorporated in the optical unit 2 of the signal lamp 1 can be used in an intelligent road traffic system (ITS) that performs wireless communication between road vehicles and a good communication state is obtained.

[Details of Antenna 4 (Part 2)]
FIG. 18 is a cross-sectional view showing another embodiment of the optical unit 2 in which the antenna 4 is incorporated. The antenna 4 of this embodiment is a patch antenna as described above, and the patch element 11 is provided away from the substrate 8 forward, but is behind the front end 39 of the LED 7 (the front end 39 of the lens portion 38). Is located.
The ground element 12 is the same as that in the embodiment of FIG. 4, and is located between the substrate 8 and the front end 39 of the LED 7 in the front-rear direction and provided behind the patch element 11.

  In FIG. 18, since the patch element 11 and the LED 7 overlap with each other in the front-rear direction, the patch element 11 is formed with a plurality of holes 24 as openings through which the LED 7 is inserted. Furthermore, since the ground element 12 and the LED 7 overlap with respect to the position in the front-rear direction, the ground element 12 is formed with a plurality of holes 14 as openings through which the LED 7 (the terminal 37 of the LED 7) is inserted. The arrangement of the holes 24 and the holes 14 is the same as the arrangement of the LEDs 7, and the patch element 11 and the ground element 12 have a mesh structure.

  According to this embodiment, even if the antenna 2 is stored in the optical unit 2, the patch element 11 and the ground element 12 behind it are provided behind the front end 39 of the LED 7. It is possible to prevent the element 11 and the ground element 12 from obstructing forward light emission (lamp light) by the LED 7.

  In addition, the patch element 11 is provided behind the front end 39 of the LED 7 in order to prevent the patch element 11 and the ground element 12 from hindering forward light emission (lamp light). This “behind the front end 39” includes a case where the front-rear direction positions of the front surface 11a of the patch element 11 and the front end 39 of the LED 7 substantially coincide. This substantially coincidence refers to the case where the front-rear position of the front end 39 of the LED 7 is within the range of the patch element 11 in the thickness direction.

As another embodiment, although not shown (described with reference to FIG. 18), the ground element 12 may be provided behind the substrate 8. That is, the patch element 11 is provided in the front space portion S1 in the range A from the front surface 8a of the substrate 8 to the front end 39 of the LED 7, but the ground element 12 is provided in the rear space portion S2. .
According to this embodiment, in order to obtain the patch antenna 4 having desired performance, a predetermined wide space in the front-rear direction can be provided between the patch element 11 and the ground element 12. That is, as described above, since the use frequency is set to 715 MHz to 725 MHz, it is easy to secure the distance in the front-rear direction between the ground element 12 and the patch element 11 to a predetermined value (10 to 40 mm).

[Details of Antenna 4 (Part 3)]
19 and 20 are a front view and a sectional view showing another embodiment of the optical unit 2 in which the antenna 4 is incorporated. The antenna 4 of this embodiment is a balanced antenna.
In this embodiment, the antenna substrate 16 is provided between the cover member 9 and the front end 39 of the LED 7, and the antenna 4 is formed on the antenna substrate 16. A strip line 31 is further formed on the antenna substrate 16, and the strip line 31 is also incorporated in the optical unit 2.

  The illustrated antenna 4 is a dipole antenna fed with balanced two wires. The antenna 4 is composed of a line patterned as a thin film conductor on one surface side (rear surface side) of the antenna substrate 16, and as shown in FIG. 19, is balanced with the dipole portion 26 and the balanced feed line portions 27a and 27b. And a portion 28 for short-circuiting the power supply line. The dipole part 26 includes a pair of left and right antenna elements 26a and 26b. The balanced power supply line portions 27a and 27b and the portion 28 also serve as a strip line ground.

  The strip line 31 includes a line patterned as a thin film conductor on the other surface side (front surface side) of the antenna substrate 16. The strip line 31 is formed to extend linearly at a position on the other surface side of the antenna substrate 16 and on the back side of the feeder line portion 27b, and in the central portion between the antenna elements 26a and 26b of the dipole portion 26. The direction is reversed in a U shape, and is formed to extend linearly at a position on the other side of the antenna substrate 16 and on the back side of the feeder line portion 27a. The strip line 31, balanced feed line portions 27 a and 27 b, and the portion 28 constitute a balun (balance-unbalance conversion portion). That is, in this embodiment, the dipole antenna 4 and the balun have a balun integrated antenna in which the antenna substrate 16 is formed. Although not shown, the balun may be provided in a part different from the antenna substrate 16 or may be a separate balun type antenna.

  A terminal portion 19 for connecting the coaxial cable 15 for the antenna 4 is attached to the housing member 6 (bottom portion 6a), and the coaxial cable 15 extending from the control device 5 of FIG. Can do. A coaxial cable 15 a extending from the terminal portion 19 to the rear space portion S <b> 2 is connected to the antenna 4. The coaxial cable 15a includes an inner conductor (center conductor) 15b, an insulator (not shown), an outer conductor 15d, and a covering portion 15e. The center conductor 15b of the coaxial cable 15 is connected to the strip line 31. The outer conductor 15d is connected to the ground (feeding line portion 27b) (see FIG. 4, where FIG. 4 is a cross-sectional view of FIG. 3 viewed from below). The inner and outer conductors 15b and 15d and each part can be connected and fixed by soldering, but a method other than soldering may be used.

The antenna substrate 16 is formed of a circular flat plate, and is supported and fixed in front of the front end 39 of the LED 7 by a support member 13 erected forward from the LED substrate 8. The support member 13 is made of an insulating member. The antenna substrate 16 is disposed to face the LED substrate 8 in front.
The antenna substrate 16 is a dielectric substrate and is made of a material having visible light permeability. Specific examples of the material include glass, polycarbonate, acrylic, and polyethylene terephthalate. The antenna substrate 16 has a thickness of about 1 mm.

  In the signal lamp 1, the antenna 4 and the strip line 31 are provided in front of the front end 39 of the LED 7, so that the antenna 4 and the strip line 31 are not obstructed from projecting light forward of the LED 7. The antenna substrate 16 has visible light transmissivity in the direction penetrating from one surface to the other surface (front-rear direction). That is, the antenna substrate 16 on which the antenna 8 and the strip line 31 are formed has visible light transmittance in the thickness direction (front-rear direction) over the entire surface (transparent to visible light). .

  The structure for this will be described in detail. The antenna substrate 16 is transparent as described above and itself has visible light permeability. The antenna 4 and the strip line 31 on the antenna substrate 16 have a mesh structure so that they have visible light transmissivity. The structure for allowing the antenna 4 and the strip line 31 to transmit visible light is the same as that of the embodiment shown in FIGS. 2 to 4, and the antenna 4 and the strip line 31 can have a mesh structure. In this case, a mesh made of a metal film (metal thin film) is formed on one surface and the other surface of the antenna substrate 16. Further, since the antenna 4 and the strip line 31 have visible light permeability, they can be a thin film conductor (thin film metal) having visible light permeability.

Although not shown, the antenna 4 may be formed on the cover member 9. That is, the antenna 4 can be configured by a line formed with a pattern on the cover member 9. In this case, the cover member 9 is also used as the antenna substrate 16 in addition to a member for protecting the LEDs 7 and the like, the antenna 4 is formed on the rear surface 9a of the cover member 9, and the strip line 31 is formed on the front surface 9b. Is formed.
Also in this case, the antenna 4 and the strip line 31 can be a line having a mesh structure patterned on the rear surface 9a and the front surface 9b of the cover member 9, and can be a line made of a patterned thin film conductor. it can. As a result, the antenna 4 and the strip line 31 have visible light transparency in the front-rear direction.
In this case, it is preferable that a protective cover sheet is further provided on the strip line 31 formed on the surface 9b. This cover sheet has visible light permeability.

Moreover, the lamp of this invention is not limited to the said embodiment. For example, other types of antennas may be used.
Furthermore, the signal lamp incorporating the antenna may be for pedestrians as well as for vehicles. Further, the light emitter included in the signal lamp device may be a light bulb other than the LED. In each of the above embodiments, the ground element 12 is circular, but other than this, the ground element 12 may be rectangular. Moreover, although the said embodiment demonstrated the case where the antenna was each integrated about all the some optical units, there may exist what has not incorporated the antenna among some optical units.

It is a front view which shows one Embodiment of the signal lamp device of this invention. It is a perspective view of an optical unit. It is a front view of an optical unit. It is sectional drawing of an optical unit. It is a front view of a signal lamp device. It is a block diagram of the communication system of this invention. It is a front view of a signal lamp device. It is a top view of the road where the communication system of this invention is provided. It is explanatory drawing explaining the other function which the communication system of this invention has. It is a front view which shows other embodiment of the signal lamp device in which the antenna is integrated. It is a perspective view of an optical unit incorporating an antenna. It is sectional drawing which shows the optical unit and antenna with which another signal lamp device is provided. It is a front view which shows the optical unit and antenna with which another signal lamp device is provided. It is a front view which is another form and has shown the optical unit and the antenna. It is a front view which is another form and has shown the optical unit and the antenna. It is a front view which is another form and has shown the optical unit and the antenna. It is a front view which is another form and has shown the optical unit and the antenna. It is sectional drawing which shows other embodiment of the optical unit in which the antenna is integrated. It is a front view which shows another embodiment of the optical unit in which the antenna is incorporated. It is sectional drawing of FIG. It is a block diagram of the communication system of this invention. It is a block diagram of the communication system of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Traffic signal lamp 2 Optical unit 4 Antenna 5 Control apparatus (control part)
7 LED (light emitter)
47 Main control unit 48 Position acquisition unit 49 Change unit

Claims (6)

A traffic signal lamp having a plurality of optical units having a light emitter, a plurality of antennas incorporated in the traffic signal lamp, and a control unit for controlling wireless communication by the antenna,
The communication system, wherein the plurality of antennas are separately incorporated into the plurality of optical units.   The communication system according to claim 1, wherein the control unit is configured to perform diversity control.   The communication system according to claim 1, wherein at least one of the plurality of antennas is set to have a polarization different from that of other antennas.   The communication system according to any one of claims 1 to 3, wherein the plurality of antennas are incorporated in the traffic signal lamp with different positions in a height direction.   The said control part has a position acquisition part which acquires the position information of a communicating party, and the change part which changes the directivity of the said antenna according to the said position information. The communication system according to item. The control unit of the communication system according to any one of claims 1 to 5, and a lamp control unit for turning on and off the traffic signal lamp,
The control unit is configured to transmit signal information related to the display of the traffic signal lamp at present and in the future to a vehicle traveling on a road where the traffic signal lamp is installed via the antenna. A traffic signal controller characterized by

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