JP2024054457A - Planar Antenna Device - Google Patents

Abstract

[Problem] To provide a planar antenna capable of receiving terrestrial digital broadcasting, and maintain the performance of the planar antenna even when a metal conductor is placed close to the planar antenna. [Solution] A planar antenna 1 is provided in which a first planar antenna 1a and a second planar antenna 1b are arranged line-symmetrically on the same plane, spaced apart by a predetermined distance, and a metal conductor is arranged in front of the first antenna element 10a and the second antenna element 10b so as to block the space between the first planar antenna 1a and the second planar antenna 1b and to overlap a portion of the first antenna element 10a and the second antenna element 10b. In this way, even if the metal conductor overlaps a portion of the first antenna element 10a and the second antenna element 10b, the first antenna element 10a and the second antenna element 10b are not entirely covered with the metal conductor, and it has been confirmed that the performance of the planar antenna 1 is maintained. [Selected Figure] Figure 1

Description

The present invention relates to a planar antenna device that can maintain the performance of a planar antenna even when a metal conductor is loaded.

In recent years, there has been a demand for collecting environmental information for use in weather forecasting, etc., and it has been proposed to equip electronic devices installed outdoors with sensors that measure environmental information and wireless units that transmit the measured environmental information. In this case, a power storage element such as a secondary battery or a supercapacitor is usually installed as a power source for operating the sensor and wireless unit, and it is considered preferable to install a solar panel for charging this power storage element.
In a measurement system for an environmental information collection system that utilizes environmental information, in order to install many environmental observation sensors densely and over a wide area, it is necessary to prepare many wireless transmission units with built-in sensors and install them in predetermined locations, as well as to prepare many electronic devices equipped with wireless receiving units. Therefore, it has been proposed to mount sensors and wireless units on antennas that receive terrestrial digital broadcasting and are installed on the roofs or exterior walls of buildings.

JP 2022-048668 A

Patent Document 1 discloses a conventional antenna device 100 that is an antenna device for receiving terrestrial digital broadcasting and includes a sensor for detecting environmental information, a transmitter for collecting environmental information detected by the sensor and transmitting the collected environmental information signal, and a storage element for storing power supplied from a solar panel, and the sensor and transmitter are operated by the power supplied from the storage element. A perspective view of this conventional antenna device 100 is shown in FIG.
As shown in Fig. 19, a conventional antenna device 100 includes a vertically long box-shaped antenna cover 110 consisting of a front cover 111 and a rear cover 112, an antenna capable of receiving terrestrial digital broadcasting is built into the antenna cover 110, and a sensor board 120 including a sensor, a transmitter, and a storage element is built into the upper rear part of the antenna cover 110. The sensor includes one or more sensors that detect environmental information, the storage element stores power supplied from a solar panel 130, and the transmitter transmits the environmental information detected by the sensor to a monitoring center. The sensor and transmitter are operated by power supplied from the storage element.
The antenna built into antenna cover 110 is composed of a first antenna arranged from the center to the upper part of antenna cover 110 and a second antenna arranged from the center to the lower part of antenna cover 110, and solar panel 130 is attached to approximately the center of the front surface of antenna cover 110. As a result, solar panel 130 is attached between the first antenna and the second antenna, so that it has as little effect as possible on the operation of the first antenna and the second antenna.

However, since the solar panel 130 has a metallic electrode, if the solar panel 130 is enlarged in the above-described conventional antenna device 100, the solar panel 130 will be arranged to overlap with the first antenna and the second antenna, and this may result in electrical coupling between the solar panel 130 and the first antenna and the second antenna, or a change in impedance, which may significantly deteriorate the performance of the conventional antenna device 100. For this reason, there is a problem in that the size of the solar panel 130 cannot be enlarged, and there is a risk that the storage element cannot be sufficiently charged.
Therefore, the present invention aims to provide a planar antenna device that, for example, has a planar antenna capable of receiving terrestrial digital broadcasting, and can maintain the performance of the planar antenna even when a metal conductor is used in close proximity to the planar antenna.

The planar antenna device of the present invention comprises a first planar antenna including a first antenna element and a first rear element arranged at a predetermined interval behind the first antenna element, a second antenna element and a second rear element arranged at a predetermined interval behind the second antenna element, the second planar antenna being arranged in line symmetry at a predetermined interval on a plane on which the first planar antenna is arranged, and a metal conductor arranged in front of the first antenna element and the second antenna element so as to close the space between the first planar antenna and the second planar antenna and overlap a portion of the first antenna element and the second antenna element, the first antenna element having two feed points formed in a central portion, a first opening formed above the two feed points, and a second opening formed below the two feed points, and the second antenna element having two feed points formed in a central portion, a third opening formed above the two feed points, and a fourth opening formed below the two feed points.
In the planar antenna device of the present invention, the first opening portion to the fourth opening portion are substantially the same rectangular shape.
Furthermore, the metal conductor is arranged at a predetermined distance in front of the first antenna element and the second antenna element, so that the entirety of the first opening and the second opening, and the entirety of the third opening and the fourth opening are not blocked by the metal conductor.
Furthermore, in the planar antenna device of the present invention, the first opening portion to the fourth opening portion are each polygonal in shape.
Furthermore, in the planar antenna device of the present invention, the metal conductor is a plurality of metal conductors, the first opening and the second opening and the third opening and the fourth opening are not entirely blocked by the plurality of metal conductors, and the plurality of metal conductors are arranged in front of the first planar antenna and the second planar antenna at a predetermined distance.
Furthermore, in the planar antenna device of the present invention, the first planar antenna and the second planar antenna are housed in a resin box-shaped case, and the metal conductor is attached to the front of the case so that the first opening and the second opening and the third opening and the fourth opening are not entirely blocked.
Furthermore, in the planar antenna device of the present invention, the metal conductor is attached so as to fill the space between the first planar antenna and the second planar antenna and to overlap a portion of the front surface of the first antenna element and the second antenna element.
Furthermore, in the planar antenna device of the present invention, a plurality of fifth openings are formed in the first rear element and a plurality of sixth openings are formed in the second rear element, both side edges of the first rear element are bent toward the first antenna element to form a first raised portion, and both side edges of the second rear element are bent toward the second antenna element to form a second raised portion.
Furthermore, in the planar antenna device of the present invention, the device is housed in a resin box-shaped case consisting of a case main body and a case lid fitted into the case main body, and at least the case lid is formed from an optically transparent material.
Furthermore, in the planar antenna device of the present invention, a second metal conductor is attached to the front surface of the first rear element so that none of the plurality of fifth openings are blocked, and a third metal conductor is attached to the front surface of the second rear element so that none of the plurality of sixth openings are blocked.
Furthermore, in another planar antenna device of the present invention, a plurality of through holes are formed in the first antenna element and the second antenna element.
Furthermore, in the planar antenna device of the present invention, the metal conductor is a plurality of metal conductors, the first opening and the second opening, and the third opening and the fourth opening are not entirely blocked by the plurality of metal conductors, and the plurality of metal conductors are attached to the upper surfaces of the first planar antenna and the second planar antenna.
Furthermore, in the planar antenna device of the present invention, the shielding rate of the first opening and the second opening, and the third opening and the fourth opening, by the multiple metal conductors is 50% or less.
Furthermore, another planar antenna device of the present invention includes a first planar antenna including a first antenna element and a first rear element arranged at a predetermined interval behind the first antenna element, a second antenna element and a second rear element arranged at a predetermined interval behind the second antenna element, and arranged symmetrically with respect to the axis of the first planar antenna at a predetermined interval on a plane on which the first planar antenna is arranged, and a large number of metal conductors divided into a plurality of parts that are attached between the first planar antenna and the second planar antenna and attached to upper surfaces of the first antenna element and the second antenna element, the first antenna element having two feed points formed in a central portion, a first opening formed above the two feed points, and a second opening formed below the two feed points, the second antenna element having two feed points formed in a central portion, a third opening formed above the two feed points, and a fourth opening formed below the two feed points, and the first opening to the fourth opening are not blocked by the large number of metal conductors.

The planar antenna device of the present invention comprises a planar antenna in which a first planar antenna and a second planar antenna are arranged line-symmetrically on the same plane, spaced apart by a predetermined distance, and a metal conductor is arranged in front of or on the top of the first antenna element and the second antenna element so as to close the gap between the first planar antenna and the second planar antenna and to overlap a portion of the first antenna element and the second antenna element. In this way, even if the metal conductor overlaps a portion of the first antenna element and the second antenna element, the openings formed in the first antenna element and the second antenna element are not entirely covered by the metal conductor, and it has been confirmed that the performance of the planar antenna is maintained.
Therefore, even if a solar panel equipped with metallic electrodes is provided so as to overlap part of the first antenna element and the second antenna element, the performance of the planar antenna device is maintained, and the planar antenna device of the present invention can utilize a solar panel with an area that can generate sufficient power.

1 is a front view showing the configuration of a planar antenna device according to a first embodiment of the present invention; 1 is a side view showing the configuration of a planar antenna device according to a first embodiment of the present invention. 1 is a front view showing a configuration of a planar antenna in a planar antenna device according to a first embodiment of the present invention; FIG. 11 is a front view showing the configuration of a planar antenna device according to a second embodiment of the present invention. FIG. 11 is a side view showing the configuration of a planar antenna device according to a second embodiment of the present invention. FIG. 11 is a front view showing the configuration of a planar antenna in a planar antenna device according to a second embodiment of the present invention. 11A and 11B are front and side views showing the configuration of a rear element of a planar antenna in a planar antenna apparatus according to a second embodiment of the present invention. FIG. 11 is a perspective view showing the configuration of a planar antenna device according to a third embodiment of the present invention. FIG. 13 is a front view showing the configuration of a planar antenna device according to a fourth embodiment of the present invention. FIG. 13 is a front view showing the configuration of a planar antenna in a planar antenna device according to a fourth embodiment of the present invention. 13A and 13B are front and side views showing the configuration of a rear element of a planar antenna in a planar antenna apparatus according to a fourth embodiment of the present invention. FIG. 13 is a perspective view showing the configuration of a planar antenna device according to a fifth embodiment of the present invention. 13 is a table showing the VSWR frequency characteristics and VSWR values at each frequency in the planar antenna device according to the fifth embodiment of the present invention. 13 is a table showing the VSWR frequency characteristics and VSWR values at each frequency of the planar antenna of the planar antenna device according to the fifth embodiment of the present invention. FIG. 13 is an exploded perspective view showing the configuration of a planar antenna device according to a sixth embodiment of the present invention. 13 is a table showing the VSWR frequency characteristics and VSWR values at each frequency in the planar antenna device according to the sixth embodiment of the present invention. FIG. 13 is a front view showing the configuration of a planar antenna device according to a seventh embodiment of the present invention. FIG. 13 is a front view showing the configuration of a planar antenna device according to an eighth embodiment of the present invention. FIG. 13 is a front view showing the configuration of a planar antenna device according to a ninth embodiment of the present invention. FIG. 13 is a side view showing the configuration of a planar antenna device according to a ninth embodiment of the present invention. 13 is a table showing VSWR characteristics versus shielding ratio of an opening by a metal conductor in a planar antenna device according to a ninth embodiment of the present invention, and VSWR values at each shielding ratio. FIG. 11 is a front view showing the configuration of a conventional antenna device.

<Planar antenna device according to a first embodiment of the present invention>
The configuration of a planar antenna device 01 according to a first embodiment of the present invention will be described with reference to Fig. 1 to Fig. 3. Fig. 1 is a front view showing the configuration of the planar antenna device 01 of the first embodiment, Fig. 2 is a side view showing the configuration of the planar antenna device 01 of the first embodiment, and Fig. 3 is a front view showing the configuration of the planar antenna 1 in the planar antenna device 01 of the first embodiment.
As shown in these figures, a planar antenna device 01 according to a first embodiment of the present invention is composed of a planar antenna 1 and a rectangular metal conductor 18. In this case, the planar antenna 1 is capable of receiving terrestrial digital broadcasting, the receiving frequency band of the planar antenna 1 is set to 470 MHz to 710 MHz, and the metal conductor 18 is disposed in front of the planar antenna 1 at a predetermined distance.
The planar antenna 1 in the planar antenna device 01 of the first embodiment is composed of a first planar antenna 1a and a second planar antenna 1b of the same shape as shown in Figure 3, and the first planar antenna 1a and the second planar antenna 1b are arranged linearly symmetrically on the same plane, separated by a predetermined distance.

The configuration of the planar antenna 1 is shown in Fig. 3. The first planar antenna 1a is composed of a first antenna element 10a and a first rear element 16a, which are substantially square. The first antenna element 10a is made of a metal plate and has a first opening 11a having a horizontally long rectangular shape and a second opening 12a having the same shape as the first opening 11a, which are formed on the top and bottom. Between the first opening 11a and the second opening 12a, two feeding points, a first feeding point 13a and a second feeding point 14a, are formed facing each other at the substantially central portion of the first antenna element 10a. In addition, a substantially square first rear element 16a is arranged at a predetermined distance behind the first antenna element 10a. The first rear element 16a is made of a metal plate.
The second planar antenna 1b has the same shape as the first antenna element 10a, and the second antenna element 10b and the second rear element 16b constituting the second planar antenna 1b have the same shapes as the first antenna element 10a and the first rear element 16a, respectively. That is, the second antenna element 10b made of a metal plate has a third opening 11b having a rectangular shape elongated horizontally and a fourth opening 12b having the same shape as the third opening 11b formed on the top and bottom. Between the third opening 11b and the fourth opening 12b, two feeding points, a third feeding point 13b and a fourth feeding point 14b, are formed facing each other at approximately the center of the second antenna element 10b. In addition, the second rear element 16b, which is approximately square, is arranged at a predetermined distance behind the second antenna element 10b. The second rear element 16b is made of a metal plate.

The lower side of the first antenna element 10a and the first rear element 16a is arranged almost parallel to the upper side of the second antenna element 10b and the second rear element 16b. A power supply unit 17 is provided between the first antenna element 10a and the first rear element 16a and the second antenna element 10b and the second rear element 16b, which are arranged at a predetermined distance apart. As shown in FIG. 2, two first power supply lines 15a that supply power from the power supply unit 17 to the first antenna element 10a pass through the space between the rear surface of the first antenna element 10a and the front surface of the first rear element 16a, and supply power to two power supply points 13a and 14a from the rear surface of the first antenna element 10a. Similarly, two second feed lines 15b that feed power from the feed section 17 to the second antenna element 10b pass through the space between the rear surface of the second antenna element 10b and the front surface of the second rear element 16b, and feed power from the rear surface of the second antenna element 10b to two feed points 13b and 14b. The first feed line 15a and the second feed line 15b are made to be approximately the same length, and the first planar antenna 1a and the second planar antenna 1b are excited in phase from the feed section 17, making it possible to increase the gain of the planar antenna 1 in the forward direction.

The metal conductor 18 of the planar antenna device 01 according to the first embodiment is disposed in front of the planar antenna 1 at a predetermined distance so that the center point of the planar antenna 1 and the center point of the metal conductor 18 are substantially aligned. The metal conductor 18 is a vertically elongated rectangular shape, and its width is narrower than the width of the first antenna element 10a and the second antenna element 10b, and the vertical length of the metal conductor 18 is shorter than the vertical length of the planar antenna 1. In this case, the vertical length of the metal conductor 18 is set to a length such that the second opening 12a and the third opening 11b are blocked by the metal conductor 18 when viewed from above, but the first opening 11a and the fourth opening 12b are not completely blocked. By disposing the metal conductor 18 as described above, the size of the metal conductor 18 can be increased, and it has been found that the performance of the planar antenna 1 can be maintained even if the size of the metal conductor 18 is increased so that a predetermined range in front of the planar antenna 1 according to the first embodiment is blocked.
In other words, whether or not the metal conductor 18 is provided, the planar antenna device 01 of the first embodiment can maintain substantially the same performance as the planar antenna 1 .
Here, in the planar antenna device 01 of the first embodiment, the planar antenna 1 and the metal conductor 18 can be housed in a box-shaped case made of resin. When the planar antenna 1 and the metal conductor 18 are housed in the case, the devices provided on the metal conductor 18 can be protected from external forces such as wind and rain. For example, various devices such as sensors capable of acquiring environmental information, such as an illuminance sensor, an ultraviolet sensor, a temperature sensor, a humidity sensor, an air pressure sensor, and a rainfall sensor, a storage element such as a secondary battery, a transmitter capable of transmitting environmental information, an amplifier, and a splitter can be installed on the metal conductor 18. In addition, the range of the metal conductor 18 can be used as a solar panel equipped with a metal electrode. In this case, since the size of the metal conductor 18 can be increased, sufficient power generation can be obtained from the solar panel. The solar panel charges the storage element, and the operating power is supplied from the storage element to the sensor and the transmitter. In addition, the case may be made of a light-transmitting material to ensure the power generation efficiency of the solar panel. The planar antenna device 01 of the first embodiment is an antenna for receiving terrestrial digital broadcasting, and is installed on the roof or exterior wall of a building, making it possible to install devices that acquire and transmit environmental information over a wide area.

<Planar antenna device according to a second embodiment of the present invention>
Next, the configuration of a planar antenna device 02 according to a second embodiment of the present invention will be described with reference to Fig. 4 to Fig. 7. Fig. 4 is a front view showing the configuration of the planar antenna device 02 according to the second embodiment, Fig. 5 is a side view showing the configuration of the planar antenna device 02 according to the second embodiment, Fig. 6 is a front view showing the configuration of the planar antenna 2 in the planar antenna device 02 according to the second embodiment, Fig. 7(a) is a front view showing the configuration of the rear element 26 in the planar antenna 2 of the planar antenna device 02 according to the second embodiment, and Fig. 7(b) is a side view showing the configuration of the rear element 26.
4 and 5, a planar antenna device 02 according to a second embodiment of the present invention is composed of a planar antenna 2 and five rectangular metal conductors 28a, 28b, 28c, 28d, and 28e. In this case, the planar antenna 2 is capable of receiving terrestrial digital broadcasting, the receiving frequency band of the planar antenna 2 is set to 470 MHz to 710 MHz, and the metal conductors 28a to 28e are disposed in front of the planar antenna 2 at a predetermined interval.
The planar antenna 2 in the planar antenna device 02 of the second embodiment is composed of a first planar antenna 2a and a second planar antenna 2b of the same shape as shown in Figure 6, and the first planar antenna 2a and the second planar antenna 2b are arranged linearly symmetrically on the same plane, separated by a predetermined distance.

Figure 6 shows the configuration of the planar antenna 2. The first planar antenna 2a is composed of a first antenna element 20a with four corners that are C-chamfered to make the oblique sides at 45° and a first rear element 26a that is slightly horizontally long. The first antenna element 20a made of a metal plate has a first horizontally long opening 21a in the upper part and a second horizontally long opening 22a in the lower part that is polygonal and has a different shape from the first opening 21a. The width of the first opening 21a is shorter than the width of the second opening 22a, but the vertical width is wider than the second opening 22a. Between the first opening 21a and the second opening 22a, two feeding points, a first feeding point 23a and a second feeding point 24a, are formed facing each other at approximately the center of the first antenna element 20a. The first rear element 26a is arranged behind the first antenna element 20a at a predetermined distance. The first rear element 26a is made of a metal plate, and as shown in Figs. 7(a) and (b) as the rear element 26, the first rear element 26a is composed of a slightly horizontally elongated flat portion A and rising portions B formed by bending both side edges of the flat portion A toward the first antenna element 20a. The rising portions B make it possible to improve the performance of the first planar antenna 2a. Note that the first rear element 26a and the second rear element 26b have the same shape, so in Figs. 7(a) and (b), the first rear element 26a and the second rear element 26b are referred to as the rear element 26.

The second planar antenna 2b has the same shape as the first antenna element 20a, and the second antenna element 20b and the second rear element 26b constituting the second planar antenna 2b have the same shape as the first antenna element 20a and the first rear element 26a, respectively. That is, the second antenna element 20b made of a metal plate has a third opening 21b in a horizontally elongated shape at the top and a fourth opening 22b in a horizontally elongated shape at the bottom, which is a polygonal shape different from the third opening 21b. The width of the fourth opening 22b is shorter than the width of the third opening 21b, but the vertical width is wider than the third opening 21b. Between the third opening 21b and the fourth opening 22b, two feeding points, the third feeding point 23b and the fourth feeding point 24b, are formed facing each other at approximately the center of the second antenna element 20b. A second rear element 26b having the same shape as the first rear element 26a is arranged at a predetermined distance behind the second antenna element 20b. The second rear element 26b is made of a metal plate, and as shown as the rear element 26 in Figures 7(a) and (b), the second rear element 26b is composed of a slightly horizontally elongated flat portion A and rising portions B formed by bending both side edges of the flat portion A toward the second antenna element 20b. The rising portions B make it possible to improve the performance of the second planar antenna 2b.

The lower side of the first antenna element 20a and the first rear element 26a is arranged parallel to the upper side of the second antenna element 20b and the second rear element 26b, facing each other. A power supply section 27 is provided between the lower side of the first antenna element 20a and the first rear element 26a and the upper side of the second antenna element 20b and the second rear element 26b. As shown in Figures 5 and 6, two first power supply lines 25a that supply power from the power supply section 27 to the first antenna element 20a pass through the space between the rear surface of the first antenna element 20a and the front surface of the planar portion A of the first rear element 26a, and supply power from the rear surface of the first antenna element 20a to two power supply points 23a and 24a. Similarly, two second feed lines 25b that feed power from the feed section 27 to the second antenna element 20b pass through the space between the rear surface of the second antenna element 20b and the front surface of the planar portion A of the second rear element 26b, and feed power from the rear surface of the second antenna element 20b to two feed points 23b and 24b. The first feed line 25a and the second feed line 25b are made to be approximately the same length, and the first planar antenna 2a and the second planar antenna 2b are excited in phase from the feed section 27, making it possible to increase the gain of the planar antenna 2 in the forward direction.

The arrangement of the five metal conductors 28a, 28b, 28c, 28d, and 28e of the planar antenna device 02 according to the second embodiment will be described. The metal conductor 28a is disposed in front of the planar antenna 2, spaced apart by a predetermined distance so as to cover the upper part of the first antenna element 20a. In this case, the metal conductor 28a is disposed so that the vertical center line of the planar antenna 2 and the vertical center line of the metal conductor 28a are substantially aligned. The metal conductor 28a is formed in a horizontally elongated rectangular shape, and its length is shorter than the width of the first antenna element 20a. The vertical width of the metal conductor 28a is W1, which covers the upper part of the first antenna element 20a but does not completely cover the first opening 21a.
The metal conductor 28b is disposed in front of the planar antenna 2, spaced apart by a predetermined distance so as to cover a portion slightly below the center of the first antenna element 20a. In this case, the metal conductor 28b is disposed so that the vertical center line of the planar antenna 2 and the vertical center line of the metal conductor 28a are substantially aligned. The metal conductor 28b is formed in a horizontally elongated rectangular shape, and its horizontal length is longer than that of the metal conductor 28a but shorter than the horizontal width of the first antenna element 20a. The vertical width of the metal conductor 28b is set to W2, which covers a portion slightly below the center of the first antenna element 20a but does not completely cover the second opening 22a.

Furthermore, the metal conductor 28c is disposed in front of the planar antenna 2, spaced apart by a predetermined distance so as to overlap the lower part of the first antenna element 20a and the upper part of the second antenna element 20b. In this case, the metal conductor 28c is disposed so that the center point of the planar antenna 2 and the center point of the metal conductor 28c are substantially aligned. The metal conductor 28c is formed in a vertically elongated rectangular shape, and its horizontal length is L1, which is longer than the metal conductor 28a but shorter than the metal conductor 28b, and is shorter than the horizontal width of the first antenna element 20a and the second antenna element 20b, and the vertical length of the metal conductor 28c is L2. The length L2 is between the second opening 22a and the third opening 21b, and is the length L2 that overlaps the lower part of the first antenna element 20a and the upper part of the second antenna element 20b.
Furthermore, the metal conductor 28d has the same shape as the metal conductor 28b, and is arranged symmetrically with respect to the horizontal center line of the planar antenna 2. That is, the metal conductor 28d has a horizontally elongated rectangular shape, the horizontal length of which is longer than that of the metal conductor 28c but shorter than the horizontal width of the second antenna element 20b, and the vertical width of the metal conductor 28d is set to W2, which covers the upper part of the second antenna element 20b but does not cover the entire third opening 21b.
Furthermore, the metal conductor 28e has the same shape as the metal conductor 28a, and is disposed symmetrically with respect to the horizontal center line of the planar antenna 2. That is, the metal conductor 28e has a horizontally elongated rectangular shape, and its horizontal length is shorter than the metal conductors 28c and 28d and shorter than the horizontal width of the second antenna element 20a, and the vertical width of the metal conductor 28e is set to W1, which covers the upper part of the second antenna element 20b but does not cover the entire fourth opening 22b.

Here, an example of the dimensions of the five metal conductors 28a to 28e in the planar antenna device 02 of the second embodiment is given. The horizontal length L1 of the metal conductor 28c is about 170 mm, the vertical length L2 is about 205 mm, the vertical width W1 of the metal conductors 28a and 28e is about 60 mm, the vertical width W2 of the metal conductors 28b and 28d is about 40 mm, and the distance between the metal conductors 28a and 28b, or the distance between the metal conductors 28e and 28d, is about 80 mm. Also, the distance between the metal conductors 28b and 28c, or the distance between the metal conductors 28c and 28d, is about 15 mm.
By arranging the metal conductors 28a to 28e as described above, the combined area of the metal conductors 28a to 28e can be increased, and it has been found that the performance of the planar antenna 2 can be maintained even if a certain range in front of the planar antenna 2 in the second embodiment is blocked by increasing the area of the metal conductors 28a to 28e.
In other words, whether or not the metal conductors 28a to 28e are provided, the planar antenna device 02 of the second embodiment can maintain substantially the same performance as the planar antenna 2.
In the planar antenna device 02 of the second embodiment, the planar antenna 2 and the metal conductors 28a to 28e can be housed in a box-shaped case made of resin. When the planar antenna 2 and the metal conductors 28a to 28e are housed in the case, the devices provided on the metal conductors 28a to 28e can be protected from external forces such as wind and rain. For example, various devices such as sensors capable of acquiring environmental information, such as an illuminance sensor, an ultraviolet sensor, a temperature sensor, a humidity sensor, an air pressure sensor, and a rainfall sensor, a storage element such as a secondary battery, a transmitter capable of transmitting environmental information, an amplifier, and a splitter can be installed in at least one of the metal conductors 28a to 28e. Furthermore, the range of the metal conductors 28a to 28e can be used as a solar panel equipped with metal electrodes. In this case, the total area of the metal conductors 28a to 28e can be increased, so that sufficient power generation can be obtained from the solar panel. The solar panel charges the storage element, and the storage element supplies operating power to the sensor and the transmitter. The case may be made of a light-transmitting material to ensure the power generation efficiency of the solar panel. The planar antenna device 02 of the second embodiment is an antenna for receiving terrestrial digital broadcasting, and is installed on the roof or exterior wall of a building, making it possible to install devices that acquire and transmit environmental information over a wide area.

<Planar antenna device according to a third embodiment of the present invention>
Next, the configuration of a planar antenna device 03 according to a third embodiment of the present invention will be described with reference to Fig. 8. Fig. 8 is a perspective view showing the configuration of the planar antenna device 03 according to the third embodiment.
As shown in Fig. 8, a planar antenna device 03 according to the third embodiment of the present invention is composed of the planar antenna 2 shown in Fig. 6 and Fig. 7(a) and (b) housed in a box-shaped case 31, and a rectangular metal conductor 32 attached to the front surface of the case 31. In this case, as described above, the planar antenna 2 is capable of receiving terrestrial digital broadcasting, and the receiving frequency band of the planar antenna 2 is set to 470 MHz to 710 MHz.
The planar antenna 2 in the planar antenna device 03 of the third embodiment is the same as that in the planar antenna device 02 of the second embodiment, and therefore the description thereof will be omitted. The case 31 in which the planar antenna 2 is housed is composed of a vertically long case main body 31a and a case lid 31b which is fitted to the front of the case main body 31a to form a vertically long box shape. A protrusion having a triangular cross section is formed so as to protrude from the front of the case lid 31b, and a metal conductor 32 bent in an "L" shape so as to be in close contact with the front of this protrusion is attached to the center.
In this case, the vertical length of the metal conductor 32 is set to a length that blocks the second opening 22a and the third opening 21b of the planar antenna 2 in front, but does not block the entire front of the first opening 21a and the fourth opening 22b. By arranging the metal conductor 32 as described above, the size of the metal conductor 32 can be increased, and it has been found that the performance of the planar antenna 2 is maintained even if a predetermined range in front of the planar antenna 2 in the third embodiment is blocked by increasing the size of the metal conductor 32.
In other words, whether or not the metal conductor 32 is provided, the planar antenna device 03 of the third embodiment can maintain substantially the same performance as the planar antenna 2 .
Here, in the planar antenna device 03 of the third embodiment, various devices such as sensors capable of acquiring environmental information, such as an illuminance sensor, an ultraviolet sensor, a temperature sensor, a humidity sensor, an air pressure sensor, and a rainfall sensor, a storage element such as a secondary battery, a transmitter capable of transmitting environmental information, an amplifier, and a splitter can be installed on the metal conductor 32. In addition, the range of the metal conductor 32 can be used as a solar panel equipped with a metal electrode. In this case, since the size of the metal conductor 32 can be increased, sufficient power generation can be obtained from the solar panel. The solar panel charges the storage element, and the storage element supplies operating power to the sensor and the transmitter. Then, the planar antenna device 03 of the third embodiment is an antenna for receiving terrestrial digital broadcasting, and is installed on the roof or exterior wall of a building, so that a device for acquiring and transmitting environmental information can be installed in a wide area.

<Planar antenna device according to the fourth embodiment of the present invention>
Next, the configuration of a planar antenna device 04 according to a fourth embodiment of the present invention will be described with reference to Fig. 9 to Fig. 11. Fig. 9(a) is a front view showing the configuration of the planar antenna device 04 according to the fourth embodiment, Fig. 9(b) is a side view showing the configuration of the planar antenna device 04 according to the fourth embodiment, Fig. 10 is a front view showing the configuration of the planar antenna 3 in the planar antenna device 04 according to the fourth embodiment, Fig. 11(a) is a front view showing the configuration of the rear element 36 in the planar antenna 3 of the planar antenna device 04 according to the fourth embodiment, and Fig. 11(b) is a side view showing the configuration of the rear element 36.
As shown in these figures, the planar antenna device 04 of the fourth embodiment of the present invention is composed of a planar antenna 3 and a rectangular metal conductor 42. In this case, the planar antenna 3 is capable of receiving terrestrial digital broadcasting, and the receiving frequency band of the planar antenna 3 is 470 MHz to 710 MHz. The metal conductor 42 is a vertically long rectangle, and is attached on the planar antenna 3 so that the lower surface of the upper part is in close contact with the upper surface of the lower part of the first antenna element 20a, and the lower surface of the lower part of the metal conductor 42 is in close contact with the upper surface of the upper part of the second antenna element 20b. In other words, the metal conductor 42 is attached so that it closes the gap between the first antenna element 20a and the second antenna element 20b in the planar antenna 3, which are arranged at a predetermined interval, and the lower surface of the upper part and the lower surface of the lower part of the metal conductor 42 are in close contact with and overlap with the upper surface of the lower part of the first antenna element 20a and the upper surface of the upper part of the second antenna element 20b, respectively.
The planar antenna 3 in the planar antenna device 04 of the fourth embodiment is composed of a first planar antenna 3a and a second planar antenna 3b of the same shape, and the first planar antenna 3a and the second planar antenna 3b are arranged linearly symmetrically on the same plane, separated by a predetermined distance.

The first planar antenna 3a is configured with a rear element 36a with a different configuration instead of the rear element 26a in the first planar antenna 2a described above, but the other configurations are the same as those of the first planar antenna 2a, and the same components are given the same reference numerals. That is, the first planar antenna 3a is configured with a C-chamfered corner with a 45° oblique side, a vertically elongated first antenna element 20a, and a slightly horizontally elongated first rear element 36a, and the first antenna element 20a made of a metal plate is formed with a horizontally elongated first opening 21a that is polygonal, and a horizontally elongated second opening 22a that is polygonal in shape and different from the first opening 21a. The horizontal width of the first opening 21a is shorter than the horizontal width of the second opening 22a, but the vertical width is wider than the second opening 22a. Between the first opening 21a and the second opening 22a, two feeding points, a first feeding point 23a and a second feeding point 24a, are formed facing each other at approximately the center of the first antenna element 20a. As shown in FIG. 10, the horizontal length of the first antenna element 20a is L3, and the vertical length is L4. The first rear element 36a is arranged at a predetermined distance behind the first antenna element 20a. The first rear element 36a is made of a metal plate, and as shown as the rear element 36 in FIG. 11(a)(b), the first rear element 36a is composed of a slightly horizontally elongated planar portion A and rising portions B formed by bending both side edges of the planar portion A toward the first antenna element 20a. The rising portions B can improve the performance of the first planar antenna 3a. In addition, three openings C are formed at a predetermined interval at the top, center, and bottom of the planar portion A, and the three openings C can improve the reflection characteristics of the first rear element 36a. In addition, since the first rear element 36a and the second rear element 36b have the same configuration, in Figures 11 (a) and (b), the first rear element 36a and the second rear element 36b are referred to as the rear element 36.

The second planar antenna 3b is configured to include a rear element 36b having a different configuration instead of the rear element 26b in the first planar antenna 2b described above, but other configurations are the same as those of the first planar antenna 2b, and the same configurations are given the same symbols. The second planar antenna 3b has the same shape as the first planar antenna 3a, and the second antenna element 20b and the second rear element 36b constituting the second planar antenna 3b have the same shapes as the first antenna element 20a and the first rear element 36a, respectively. That is, the second antenna element 20b made of a metal plate has a third opening 21b that is horizontally elongated and polygonal, and the first antenna element 20a made of a metal plate has a fourth opening 22b that is horizontally elongated and polygonal and has a different shape from the third opening 21b. The width of the third opening 21b is shorter than the width of the fourth opening 22b, but the vertical width is wider than the fourth opening 22b. Between the third opening 21b and the fourth opening 22b, two feeding points, the third feeding point 23b and the fourth feeding point 24b, are formed facing each other at approximately the center of the second antenna element 20b. The second antenna element 20b also has a horizontal length L3 and a vertical length L4. A second rear element 36b having the same shape as the first rear element 36a is arranged at a predetermined distance behind the second antenna element 20b. The second rear element 36b is made of a metal plate, and as shown as the rear element 36 in Figures 11(a) and 11(b), the first rear element 36b is composed of a slightly horizontally elongated planar portion A and rising portions B formed by bending both side edges of the planar portion A toward the second antenna element 20b. The rising portions B can improve the performance of the second planar antenna 3b. In addition, three openings C are formed at a predetermined interval on the upper, central and lower parts of the flat portion A, and the three openings C make it possible to improve the reflection characteristics of the second rear element 36b.
The lower side of the first antenna element 20a and the first rear element 36a is arranged parallel to the upper side of the second antenna element 20b and the second rear element 36b, facing each other. A power supply unit 27 is provided in the space between the lower side and the upper side. As shown in Fig. 9(b) and Fig. 10, two first power supply lines 25a that supply power from the power supply unit 27 to the first antenna element 20a pass through the space between the rear surface of the first antenna element 20a and the front surface of the planar portion A of the first rear element 36a, and are fed from the rear surface of the first antenna element 20a to two power supply points 23a and 24a. Similarly, two second power supply lines 25b that supply power from the power supply unit 27 to the second antenna element 20b pass through the space between the rear surface of the second antenna element 20b and the front surface of the planar portion A of the second rear element 36b, and are fed from the rear surface of the second antenna element 20b to two power supply points 23b and 24b. The first feed line 25a and the second feed line 25b are made to be approximately the same length, and the first planar antenna 3a and the second planar antenna 3b are excited in phase from the feed section 27, making it possible to increase the gain of the planar antenna 3 in the forward direction.

The lower surface of the upper part of the metal conductor 42 of the planar antenna device 04 according to the fourth embodiment overlaps with the upper surface of the lower part of the first antenna element 20a, and the lower surface of the lower part of the metal conductor 42 overlaps with the upper surface of the upper part of the second antenna element 20b, and is attached in close contact with each other. In this case, the vertical center line of the planar antenna 3 and the vertical center line of the metal conductor 42 are arranged to almost coincide with each other. The metal conductor 42 is in a vertically elongated rectangular shape, and its horizontal length is L1 and its vertical length is L2. The length L1 is shorter than the horizontal width of the first antenna element 20a and the second antenna element 20b, and the length L2 is a length that covers the lower part of the first antenna element 20a and the upper part of the second antenna element 20b between the second opening 22a and the third opening 21b.

In the planar antenna device 04 of the fourth embodiment, the planar antenna 3 and the metal conductor 42 can be housed in a box-shaped case 41 made of resin. When the planar antenna 3 and the metal conductor 42 are housed in the case 41, the devices provided on the metal conductor 42 can be protected from external forces such as wind and rain. For example, various devices such as sensors capable of acquiring environmental information, such as an illuminance sensor, an ultraviolet sensor, a temperature sensor, a humidity sensor, an air pressure sensor, and a rainfall sensor, a storage element such as a secondary battery, a transmitter capable of transmitting environmental information, an amplifier, and a splitter can be installed in the metal conductor 42. In addition, the range of the metal conductor 42 can be used as a solar panel equipped with a metal electrode. In this case, since the size of the metal conductor 42 can be increased, sufficient power generation can be obtained from the solar panel. The solar panel charges the storage element, and the storage element supplies operating power to the sensor and the transmitter. In addition, the case 41 may be made of a light-transmitting material to ensure the power generation efficiency of the solar panel. The planar antenna device 04 of the fourth embodiment is an antenna for receiving terrestrial digital broadcasting, and is installed on the roof or exterior wall of a building, making it possible to install devices that acquire and transmit environmental information over a wide area.
Here, an example of the dimensions of each part of the planar antenna device 04 of the fourth embodiment will be given. The horizontal length L1 of the metal conductor 42 is about 170 mm, the vertical length L2 is about 205 mm, and the horizontal length L3 of the first antenna element 20a and the second antenna element 20b is about 200 mm, and the vertical length L4 is about 230 mm.
Since the metal conductor 42 is arranged as described above, the area of the metal conductor 42 can be increased, and even if the area of the metal conductor 42 is increased so that a specified area in front of the planar antenna 3 in the planar antenna device 04 of the fourth embodiment is blocked, the performance of the planar antenna 3 is maintained.
In other words, whether or not the metal conductor 42 is provided, the planar antenna device 04 of the fourth embodiment can maintain substantially the same performance as the planar antenna 3 .
In the planar antenna device 04 of the fourth embodiment, the installation range of the metal conductor 42 can be set to a range that does not cover the entire first opening 21a and the second opening 22a in the first antenna element 20a, and the entire third opening 21b and the second opening 22b in the second antenna element 20b. Furthermore, a plurality of metal conductors may be provided in addition to the metal conductor 42. In this case, the installation range of the increased metal conductor is set to a range that does not cover the entire first opening 21a to the fourth opening 22b.

<Planar antenna device according to the fifth embodiment of the present invention>
Next, the configuration of a planar antenna device 05 according to a fifth embodiment of the present invention will be described with reference to Fig. 12. Fig. 12 is a perspective view showing the configuration of the planar antenna device 05 according to the fifth embodiment.
12, a planar antenna device 05 according to the fifth embodiment of the present invention is a planar antenna device equipped with a box-shaped case 51 made of a resin case body 51a and a case lid 51b, instead of the case 41 in the planar antenna device 04 according to the fourth embodiment of the present invention. The planar antenna 3 housed in the case 51 is capable of receiving terrestrial digital broadcasting as described above, and the receiving frequency band of the planar antenna 3 is set to 470 MHz to 710 MHz.
The planar antenna 3 in the planar antenna device 05 of the fifth embodiment is as described above, so its description will be omitted, and the metal conductor 42 is mounted on the planar antenna 3 as described above. The resin case 51 in which the planar antenna 3 and the metal conductor 42 are housed is composed of a vertically long case main body 51a and a case lid 51b that is fitted to the front of the case main body 51a to form a vertically long box shape. A protrusion with a triangular cross section is formed so as to protrude from the front of the case lid 51b.

In the planar antenna device 05 of the fifth embodiment, the planar antenna 3 and the metal conductor 42 are housed in a resin box-shaped case 51, so that the devices provided on the metal conductor 42 can be protected from external forces such as wind and rain. For example, various devices such as sensors capable of acquiring environmental information, such as an illuminance sensor, an ultraviolet sensor, a temperature sensor, a humidity sensor, an air pressure sensor, and a rainfall sensor, a storage element such as a secondary battery, a transmitter capable of transmitting environmental information, an amplifier, and a splitter can be installed on the metal conductor 42. In addition, the range of the metal conductor 42 can be used as a solar panel equipped with a metal electrode. In this case, since the size of the metal conductor 42 can be increased, sufficient power generation can be obtained from the solar panel. The solar panel charges the storage element, and the operating power is supplied from the storage element to the sensor and the transmitter. In addition, if the case 51 is made of a light-transmitting material, the power generation efficiency of the solar panel can be ensured. In this case, if the case lid part 51b is made of a light-transmitting material, the case main body part 51a does not have to be made of a light-transmitting material. As a result, the planar antenna device 05 of the fifth embodiment is an antenna that receives terrestrial digital broadcasts and is installed on the roof or exterior wall of a building, making it possible to install a device that acquires and transmits environmental information over a wide area.

Since the metal conductor 42 is arranged as described above, the area of the metal conductor 42 can be increased, and even if the area of the metal conductor 42 is increased so that a predetermined range in front of the planar antenna 3 in the fifth embodiment is blocked, the performance of the planar antenna 3 is maintained.
In other words, whether or not the metal conductor 42 is provided, the planar antenna device 05 of the fifth embodiment can maintain substantially the same performance as the planar antenna 3 .
In the planar antenna device 05 of the fifth embodiment, the installation range of the metal conductor 42 can be set to a range that does not cover the entire first opening 21a and the second opening 22a in the first antenna element 20a, and the entire third opening 21b and the second opening 22b in the second antenna element 20b. Furthermore, a plurality of metal conductors may be provided in addition to the metal conductor 42. In this case, the installation range of the increased metal conductor is set to a range that does not cover the entire first opening 21a to the fourth opening 22b.

Next, the electrical characteristics of the planar antenna device 05 according to the fifth embodiment of the present invention are shown in Figures 13(a) and 13(b). Figure 13(a) is a graph showing the frequency characteristics of the voltage standing wave ratio (VSWR) in the frequency band of 470 MHz to 710 MHz, and Figure 13(b) is a chart showing the VSWR values for each frequency in the frequency band of 470 MHz to 710 MHz.
The receiving frequency band of the planar antenna device 05 of the fifth embodiment is set to 470 MHz to 710 MHz, and referring to Figures 13(a) and (b), a good VSWR value of about 2.1 to about 2.4 is obtained at 470 MHz to 550 MHz, and a better VSWR value of less than 2.0 is obtained at about 550 MHz to about 700 MHz. In particular, the best VSWR value of about 1.1 is obtained at 680 MHz. Thus, the planar antenna device 05 of the fifth embodiment can obtain a VSWR value of 2.5 or less at 470 MHz to 710 MHz.
Here, in order to verify the influence of the metal conductor 42, the electrical characteristics of the planar antenna 3 alone in the planar antenna device 05 of the fifth embodiment are shown in Figures 14(a) and 14(b). Figure 14(a) is a graph showing the frequency characteristics of the voltage standing wave ratio (VSWR) in the frequency band of 470 MHz to 710 MHz, and Figure 14(b) is a chart showing the VSWR values for each frequency in the frequency band of 470 MHz to 710 MHz.
14(a) and (b), VSWR values of about 1.7 to about 2.2 are obtained between 470 MHz and 550 MHz, and better VSWR values of less than 2.0 are obtained between about 550 MHz and about 700 MHz. In particular, the best VSWR value of about 1.2 is obtained at 680 MHz.
13(a) and (b) and the electrical characteristics shown in Fig. 14(a) and (b), the electrical characteristics of the planar antenna 3 alone shown in Fig. 14(a) and (b) show a slightly better VSWR value, but when observed across the entire frequency band, the electrical characteristics are almost the same, and it is found that there is no adverse effect due to the metal conductor 42. Therefore, as described above, whether or not the metal conductor 42 is provided, the planar antenna device 05 of the fifth embodiment can be obtained, in which the performance of the planar antenna 3 is almost the same.
The electrical characteristics of the planar antenna device 04 of the fourth embodiment are the same as those shown in FIGS.

<Planar antenna device according to the sixth embodiment of the present invention>
Next, the configuration of a planar antenna device 06 according to a sixth embodiment of the present invention will be described with reference to Fig. 15. Fig. 15 is an exploded perspective view showing the configuration of the planar antenna device 06 according to the sixth embodiment.
As shown in Fig. 15, the planar antenna device 06 of the sixth embodiment of the present invention is composed of a planar antenna 3 and three rectangular metal conductors 42a, 42b, and 42c. In this case, the planar antenna 3 is the same as the planar antenna 3 of the planar antenna device 04 of the fourth embodiment, and is capable of receiving terrestrial digital broadcasting, and the receiving frequency band of the planar antenna 3 is 470 MHz to 710 MHz. The metal conductor 42a is attached in close contact with the front surface of the planar portion A of the first rear element 36a, the metal conductor 42b is attached in close contact with the front surface of the planar portion A of the second rear element 36b such that the lower surface of the upper portion of the metal conductor 42b overlaps the upper surface of the lower portion of the first antenna element 20a and the lower surface of the lower portion of the metal conductor 42b overlaps the upper surface of the upper portion of the second antenna element 20b, and the metal conductor 42c is attached in close contact with the front surface of the planar portion A of the second rear element 36b.
The planar antenna 3 in the planar antenna device 06 of the sixth embodiment is composed of a first planar antenna 3a and a second planar antenna 3b of the same shape, as explained in the planar antenna device 04 of the fourth embodiment, and the first planar antenna 3a and the second planar antenna 3b are arranged symmetrically on the same plane, spaced apart by a predetermined distance. The configuration of the planar antenna 3 in the planar antenna device 06 of the sixth embodiment is as explained in the planar antenna device 04 of the fourth embodiment, and since the reference numerals of the respective parts constituting the planar antenna 3 in the planar antenna device 06 of the sixth embodiment are the same, detailed explanation of the planar antenna 3 will be omitted.

In addition, the metal conductor 42a of the planar antenna device 06 according to the sixth embodiment is attached in close contact with the front surface of the planar portion A of the first rear element 36a so as to close the upper and central openings C, and the metal conductor 42a is rectangular in size so as to close the upper and central openings C of the first rear element 36a. The metal conductor 42b closes the gap between the first antenna element 20a and the second antenna element 20b in the planar antenna 3, which are arranged at a predetermined distance from each other, and is attached so that the lower surface of the upper part and the lower surface of the lower part of the metal conductor 42b are closely overlapped with the upper surface of the lower part of the first antenna element 20a and the upper surface of the upper part of the second antenna element 20b, respectively, and the metal conductor 42b is rectangular in size so as to overlap the lower part of the first antenna element 20a and the upper part of the second antenna element 20b. The metal conductor 42c is attached in close contact with the front surface of the planar portion A of the second rear element 36b so as to close the opening C at the bottom and center, and the metal conductor 42c is rectangular in size so as to close the opening C at the bottom and center of the planar portion A of the second rear element 36b. In this case, the metal conductors 42a, 42b, and 42c are arranged so that the vertical center line of the planar antenna 3 and the vertical center lines of the metal conductors 42a, 42b, and 42c are approximately aligned.

In the planar antenna device 06 of the sixth embodiment, the planar antenna 3 and the three metal conductors 42a, 42b, and 42c are housed in a resin box-shaped case 51. The case 51 is similar to the case 51 of the planar antenna device 05 of the fifth embodiment, and is composed of a vertically long case main body 51a and a case lid 51b that is fitted to the front of the case main body 51a to form a vertically long box shape. A protrusion with a triangular cross section is formed to protrude from the front of the case lid 51b. By housing the three metal conductors 42a, 42b, and 42c inside such a case 51, the devices provided on the three metal conductors 42a, 42b, and 42c can be protected from external forces such as wind and rain. For example, at least one of the metal conductors 42a, 42b, and 42c can be provided with various devices such as sensors capable of acquiring environmental information, such as illuminance sensors, ultraviolet sensors, temperature sensors, humidity sensors, atmospheric pressure sensors, and rainfall sensors, storage elements such as secondary batteries, transmitters capable of transmitting environmental information, amplifiers, and splitters. Furthermore, the range of the metal conductors 42a, 42b, and 42c can be used as a solar panel equipped with metal electrodes. In this case, the total area of the metal conductors 42a, 42b, and 42c can be increased, so that sufficient power generation can be obtained from the solar panel. The solar panel charges the storage element, and the storage element supplies operating power to the sensor and the transmitter. In addition, if the case 51 is made of a light-transmitting material, the power generation efficiency of the solar panel can be ensured. In this case, if the case lid portion 51b is made of a light-transmitting material, the case main body portion 51a does not have to be made of a light-transmitting material. As a result, the planar antenna device 06 of the sixth embodiment is an antenna that receives terrestrial digital broadcasts and is installed on the roof or exterior wall of a building, making it possible to install a device that acquires and transmits environmental information over a wide area.

As described above, the three metal conductors 42a, 42b, and 42c are arranged, so that the area of the three metal conductors 42a, 42b, and 42c taken together can be increased. By increasing the area of the three metal conductors 42a, 42b, and 42c, the performance of the planar antenna 3 in the planar antenna device 06 of the sixth embodiment can be maintained even if a specified range in front of the planar antenna 3 is blocked.
In other words, whether or not the three metal conductors 42a, 42b, 42c are provided, the planar antenna device 06 of the sixth embodiment can maintain substantially the same performance as the planar antenna 3.
In addition, in the sixth embodiment of the planar antenna device 06, the installation range of the metal conductor 42a out of the three metal conductors 42a, 42b, 42c can be a range that does not cover the entire first opening 21a and the second opening 22a in the first antenna element 20a, and the entire third opening 21b and the second opening 22b in the second antenna element 20b.

Next, the electrical characteristics of the planar antenna device 06 according to the sixth embodiment of the present invention are shown in Figures 16(a) and 16(b). Figure 16(a) is a graph showing the frequency characteristics of the voltage standing wave ratio (VSWR) in the frequency band of 470 MHz to 710 MHz, and Figure 16(b) is a chart showing the VSWR values for each frequency in the frequency band of 470 MHz to 710 MHz.
The receiving frequency band of the planar antenna device 06 of the sixth embodiment is 470 MHz to 710 MHz, and referring to Figures 16(a) and 16(b), a good VSWR value of about 1.7 to about 1.9, less than 2.0, is obtained at 470 MHz to 580 MHz, a VSWR value of 2.0 is obtained at 590 MHz, and a good VSWR value of 1.7 to 2.0 is obtained at about 600 MHz to about 695 MHz. In this way, the planar antenna device 06 of the sixth embodiment can obtain a VSWR value of 2.2 or less at 470 MHz to 710 MHz.
14(a) and 14(b) which are the electrical characteristics of the planar antenna 3 alone, compared with the electrical characteristics shown in Fig. 16(a) and 16(b), it is found that the electrical characteristics are almost the same in all frequency bands, and no adverse effects due to the three metal conductors 42a, 42b, and 42c are observed. Therefore, whether or not the three metal conductors 42a, 42b, and 42c are provided, the planar antenna device 06 of the sixth embodiment can maintain almost the same performance as the planar antenna 3.

<Planar antenna device according to the seventh embodiment of the present invention>
Next, the configuration of a planar antenna device 07 according to a seventh embodiment of the present invention will be described with reference to Fig. 17. Fig. 17 is a front view showing the configuration of the planar antenna device 07 according to the seventh embodiment.
A planar antenna device 07 of the seventh embodiment of the present invention shown in Figure 17 replaces the first antenna element 20a and the second antenna element 20b in the planar antenna device 06 of the sixth embodiment with a first antenna element 40a and a second antenna element 40b having a different configuration, and the other configurations are similar to those of the planar antenna device 06 of the sixth embodiment.
That is, the planar antenna device 07 of the seventh embodiment of the present invention includes a box-shaped case 51 consisting of a case body 51a and a case lid 51b. The case 51 houses the planar antenna 4 and three rectangular metal conductors 42a, 42b, and 42c. In this case, the configuration of the planar antenna 4 except for the first antenna element 40a and the second antenna element 40b is the same as that of the planar antenna 3 of the planar antenna device 06 of the sixth embodiment, and is as described in the planar antenna device 06 of the sixth embodiment. In the planar antenna device 07 of the seventh embodiment, the components except for the first antenna element 40a and the second antenna element 40b are given the same reference numerals, and therefore detailed description of the planar antenna 4 except for the first antenna element 40a and the second antenna element 40b will be omitted. The planar antenna 4 is capable of receiving terrestrial digital broadcasting, and the receiving frequency band of the planar antenna 4 is set to 470 MHz to 710 MHz. Moreover, the metal conductors 42a, 42b, and 42c are as described in the planar antenna device 06 of the sixth preferred embodiment.

In the planar antenna device 07 of the seventh embodiment, the planar antenna 4 is composed of a first planar antenna 4a and a second planar antenna 4b of the same shape, and the first planar antenna 4a and the second planar antenna 4b are arranged on the same plane in line symmetry with a predetermined distance between them. The first planar antenna 4a is composed of a first antenna element 40a and a first rear element 36a arranged behind the first antenna element 40a with a predetermined distance between them. The first antenna element 40a is made of a vertically elongated metal plate, and has four corners that are C-chamfered to have 45° oblique sides, and has a first horizontally elongated opening 21a that is polygonal and a second horizontally elongated opening 22a that is polygonal and has a different shape from the first opening 21a. Furthermore, a large number of through holes 48a are formed on the entire surface so as to surround the first opening 21a and the second opening 22a. The second planar antenna 4b is composed of a second antenna element 40b and a second rear element 36b arranged at a predetermined distance behind the second antenna element 40b. The second antenna element 40b is made of a vertically long metal plate with four corners chamfered to have 45° oblique sides, and is provided with a third horizontally long opening 21b that is polygonal and a fourth horizontally long opening 22b that is polygonal and has a different shape from the third opening 21b. Furthermore, a large number of through holes 48b are formed on the entire surface so as to surround the third opening 21b and the fourth opening 22b.
In addition, the metal conductor 42a is attached in close contact with the front surface of the planar portion A of the first rear element 36a, the metal conductor 42b is attached in close contact with the front surface of the planar portion A of the first rear element 36a such that the lower surface of the upper part of the metal conductor 42b overlaps the upper surface of the lower part of the first antenna element 40a and the lower surface of the lower part of the metal conductor 42b overlaps the upper surface of the upper part of the second antenna element 40b, and the metal conductor 42c is attached in close contact with the front surface of the planar portion A of the second rear element 36b, as explained in the sixth embodiment of the planar antenna device 06.

In the planar antenna device 07 of the seventh embodiment, the three metal conductors 42a, 42b, and 42c are stored inside the case 51, so that the devices provided on the three metal conductors 42a, 42b, and 42c can be protected from external forces such as wind and rain. In addition, it is preferable for the planar antenna device 07 of the seventh embodiment to install various devices such as sensors capable of acquiring environmental information, such as an illuminance sensor, an ultraviolet sensor, a temperature sensor, a humidity sensor, an air pressure sensor, and a rainfall sensor, a storage element such as a secondary battery, a transmitter capable of transmitting environmental information, an amplifier, and a splitter, or to use the range of the metal conductors 42a, 42b, and 42c as a solar panel equipped with a metal electrode. That is, when the case 51 is made of a light-transmitting material, the light passing through the case 51 is irradiated to the metal conductor 42b, and also passes through the through hole 48a of the first antenna element 40a and the through hole 48b of the second antenna element 40b, and is irradiated to the solar panel having an electrode made of the metal conductor 42a attached to the front surface of the first rear element 36a and the solar panel having an electrode made of the metal conductor 42c attached to the front surface of the second rear element 36b. As a result, power can be efficiently generated by one or more solar panels having electrodes made of the metal conductors 42a, 42b, and 42c, so that sufficient power generation can be ensured. In this case, as long as the case lid 51b is made of a light-transmitting material, the case main body 51a does not need to be made of a light-transmitting material. The solar panel charges the storage element, and the storage element supplies operating power to the sensor and the transmitter. As a result, the planar antenna device 07 of the seventh embodiment is an antenna that receives terrestrial digital broadcasts and is installed on the roof or exterior wall of a building, making it possible to install a device that acquires and transmits environmental information over a wide area.

As described above, the three metal conductors 42a, 42b, and 42c are arranged, so that the area of the three metal conductors 42a, 42b, and 42c taken together can be increased. By increasing the area of the three metal conductors 42a, 42b, and 42c, the performance of the planar antenna 4 can be maintained even if a specified area in front of the planar antenna 4 in the planar antenna device 07 of the seventh embodiment is blocked.
In other words, whether or not the three metal conductors 42a, 42b, and 42c are provided, the planar antenna device 07 of the seventh embodiment can maintain substantially the same performance as the planar antenna 4. In this case, the electrical characteristics of the planar antenna device 07 of the seventh embodiment of the present invention are similar to the electrical characteristics of the planar antenna device 06 of the sixth embodiment shown in Figures 16(a) and 16(b).
The through hole 48a of the first antenna element 40a and the through hole 48b of the second antenna element 40b may be round as shown in the figure, but may also be polygonal. Instead of forming the through holes 48a, 48b in the first antenna element 40a and the second antenna element 40b, the first antenna element 40a and the second antenna element 40b may be formed into a mesh shape by forming a thin linear conductor by performing deposition printing or the like on a resin such as a film. Furthermore, in the planar antenna device 07 of the seventh embodiment, the installation range of the metal conductor 42a among the three metal conductors 42a, 42b, and 42c can be set to a range that does not cover the entire first opening 21a and the second opening 22a in the first antenna element 40a, and the entire third opening 21b and the second opening 22b in the second antenna element 40b.

<Planar antenna device according to the eighth embodiment of the present invention>
Next, the configuration of a planar antenna device 08 according to an eighth embodiment of the present invention will be described with reference to Fig. 18. Fig. 18 is a front view showing the configuration of the planar antenna device 08 according to the eighth embodiment.
A planar antenna device 08 according to an eighth embodiment of the present invention shown in Figure 18 replaces the metal conductor 42 in the planar antenna device 05 according to the fifth embodiment with a solar panel group consisting of solar panel units 62a, 62b, and 62c, and the other configurations are similar to those of the planar antenna device 05 according to the fifth embodiment.
That is, the planar antenna device 08 of the eighth embodiment of the present invention includes a box-shaped case 51 consisting of a case body 51a and a case lid 51b. The case 51 houses the planar antenna 3 and a solar panel group consisting of solar panel units 62a, 62b, and 62c. In this case, the configuration of the planar antenna 3 is the same as that of the planar antenna device 05 of the fifth embodiment, and is as described in the planar antenna device 05 of the fifth embodiment. Since the reference numerals of the various parts are the same in the planar antenna device 08 of the eighth embodiment, detailed description of the planar antenna 3 will be omitted. The planar antenna 3 is capable of receiving terrestrial digital broadcasting, and the receiving frequency band of the planar antenna 3 is 470 MHz to 710 MHz.

In the planar antenna device 08 of the eighth embodiment, a solar panel group consisting of solar panel units 62a, 62b, and 62c is mounted on the planar antenna 3. That is, a solar panel unit 62a consisting of 20 large and small rectangular solar panels is mounted on the front surface of the first antenna element 20a in the first planar antenna 3a, and a solar panel unit 62c consisting of 20 large and small rectangular solar panels is mounted on the front surface of the second antenna element 20b in the second planar antenna 3b. Furthermore, a solar panel unit 62b consisting of 15 rectangular solar panels is disposed between the first planar antenna 3a and the second planar antenna 3b. The solar panels in the solar panel unit 62a are mounted at positions that do not substantially block the first opening 21a and the second opening 22a of the first antenna element 20a, and the solar panels in the solar panel unit 52c are mounted at positions that do not substantially block the third opening 21b and the fourth opening 22b of the second antenna element 20b.
The first planar antenna 3a is composed of a first antenna element 20a and a first rear element 36a arranged at a predetermined interval behind the first antenna element 20a, while the second planar antenna 3b is composed of a second antenna element 20b and a second rear element 36b arranged at a predetermined interval behind the second antenna element 20b.

In the planar antenna device 08 of the eighth embodiment, the solar panel group consisting of the solar panel units 62a, 62b, and 62c is stored inside the case 51, so that the solar panel group consisting of the solar panel units 62a, 62b, and 62c can be protected from external forces such as wind and rain. In addition, the case lid portion 51b of the case 51 is made of a light-transmitting material, and light that passes through the case 51 is irradiated onto the solar panel group consisting of the solar panel units 62a, 62b, and 62c. This allows the solar panel group consisting of the solar panel units 62a, 62b, and 62c to generate power efficiently, and sufficient generated power can be secured. Meanwhile, various devices such as sensors capable of acquiring environmental information, such as illuminance sensors, ultraviolet sensors, temperature sensors, humidity sensors, air pressure sensors, and rainfall sensors, storage elements such as secondary batteries, transmitters capable of transmitting environmental information, amplifiers, and splitters can be installed on at least one solar panel of the solar panel units 62a, 62b, and 62c. In this case, the solar panel units 62a, 62b, and 62c charge the storage element, which supplies operating power to the sensor and transmitter. The planar antenna device 08 of the eighth embodiment is an antenna for receiving terrestrial digital broadcasting, and is installed on the roof or exterior wall of a building, making it possible to install a device that acquires and transmits environmental information over a wide area.

As described above, by arranging the solar panel group consisting of solar panel units 62a, 62b, and 62c, the area of the solar panel group consisting of the combined solar panel units 62a, 62b, and 62c can be increased, and the area of the electrodes provided on each of the solar panel groups consisting of the solar panel units 62a, 62b, and 62c can be increased, so that the performance of the planar antenna 3 in the planar antenna device 08 of the eighth embodiment can be maintained even if a specified range in front of the planar antenna 3 is blocked.
In other words, whether or not a solar panel group consisting of the solar panel units 62a, 62b, and 62c is provided, the planar antenna device 08 of the eighth embodiment can maintain substantially the same performance as the planar antenna 3.
In the planar antenna device 08 of the eighth embodiment, the planar antenna 3 may be replaced with the planar antenna 2 included in the planar antenna device 02 of the second embodiment. Also, the solar panels in the solar panel units 62a, 62b, and 62c may be replaced with metal conductors on which various devices can be installed.

<Planar antenna device according to the ninth embodiment of the present invention>
Next, the configuration of a planar antenna device 09 according to a ninth embodiment of the present invention will be described with reference to Figures 19 and 20. Figure 19 is a front view showing the configuration of the planar antenna device 09 according to the ninth embodiment, and Figure 20 is a side view showing the configuration of the planar antenna device 09 according to the ninth embodiment.
19 and 20, a planar antenna device 09 according to a ninth embodiment of the present invention is composed of a planar antenna 2 and five rectangular metal conductors 28a, 28b, 28c, 28d, and 28e. In this case, the planar antenna 2 is capable of receiving terrestrial digital broadcasting, the receiving frequency band of the planar antenna 2 is set to 470 MHz to 710 MHz, and the metal conductors 28a to 28e are attached in close contact with the upper surface of the planar antenna 2.
The planar antenna 2 in the planar antenna device 09 of the ninth embodiment is the planar antenna 2 described in the planar antenna device 02 of the second embodiment, so a detailed description will be omitted, but the planar antenna 2 is composed of a first planar antenna 2a and a second planar antenna 2b of the same shape, and the first planar antenna 2a and the second planar antenna 2b are arranged linearly symmetrically on the same plane, separated by a predetermined distance.

The configuration of the planar antenna device 09 of the ninth embodiment differs from the planar antenna device 02 of the second embodiment in the arrangement of the five rectangular metal conductors 28a, 28b, 28c, 28d, and 28e. That is, as shown in Fig. 20, in the planar antenna device 09 of the ninth embodiment, the metal conductor 28a is attached in close contact with the upper surface of the first antenna element 20a in front of the planar antenna 2 so as to cover the upper part of the first antenna element 20a and the upper part of the first opening 21a. In this case, the metal conductor 28a is arranged so that the vertical center line of the planar antenna 2 and the vertical center line of the metal conductor 28a are almost aligned. The metal conductor 28a is formed in a horizontally elongated rectangular shape, and its length is shorter than the width of the first antenna element 20a, and its width is set to cover the upper part of the first antenna element 20a and the upper part of the first opening 21a but does not cover the entire first opening 21a.
The metal conductor 28b is attached in close contact with the upper surface of the first antenna element 20a in front of the planar antenna 2 so as to cover a portion slightly below the center of the first antenna element 20a and the lower portion of the second opening 22a. In this case, the metal conductor 28b is arranged so that the vertical center line of the planar antenna 2 and the vertical center line of the metal conductor 28a are substantially aligned. The metal conductor 28b is formed in a horizontally elongated rectangular shape, and its horizontal length is longer than that of the metal conductor 28a but shorter than the horizontal width of the first antenna element 20a, and its width covers a portion slightly below the center of the first antenna element 20a and the lower portion of the second opening 22a but does not completely cover the second opening 22a.

Furthermore, the metal conductor 28c is formed in a vertically long rectangular shape, and is attached on the planar antenna 2 so that the lower surface of the upper part is in close contact with the upper surface of the lower part of the first antenna element 20a, and the lower surface of the lower part of the metal conductor 28c is in close contact with the upper surface of the upper part of the second antenna element 20b. That is, it closes the gap between the first antenna element 20a and the second antenna element 20b in the planar antenna 2, which are arranged at a predetermined interval, and is attached so that the lower surface of the upper part and the lower surface of the lower part of the metal conductor 28c are in close contact with and overlap with the upper surface of the lower part of the first antenna element 20a and the upper surface of the upper part of the second antenna element 20b, respectively. In this case, the planar antenna 2 and the metal conductor 28c are arranged so that their centers are approximately aligned with each other. The horizontal length of the metal conductor 28c is longer than that of the metal conductor 28a but shorter than that of the metal conductor 28b, and is shorter than the horizontal width of the first antenna element 20a and the second antenna element 20b. The vertical length of the metal conductor 28c is between the second opening 22a and the third opening 21b, and is long enough to overlap the lower part of the first antenna element 20a and the upper part of the second antenna element 20b.
Furthermore, the metal conductor 28d has the same shape as the metal conductor 28b, and is disposed symmetrically with respect to the horizontal center line of the planar antenna 2. That is, the metal conductor 28d has a horizontally elongated rectangular shape, and its horizontal length is longer than that of the metal conductor 28c but shorter than the horizontal width of the second antenna element 20b, and its width is set to cover the upper part of the second antenna element 20b but does not cover the entire third opening 21b.
Furthermore, the metal conductor 28e has the same shape as the metal conductor 28a, and is disposed symmetrically with respect to the horizontal center line of the planar antenna 2. That is, the metal conductor 28e has a horizontally elongated rectangular shape, and its horizontal length is shorter than the metal conductors 28c and 28d and shorter than the horizontal width of the second antenna element 20a, and has a width that covers the upper part of the second antenna element 20b but does not cover the entire fourth opening 22b.
As described above, in the planar antenna device 09 of the ninth embodiment, five rectangular metal conductors 28a, 28b, 28c, 28d, and 28e are attached in close contact with the upper surfaces of the first antenna element 20a and the second antenna element 20b. The metal conductors 28a, 28b, 28c, 28d, and 28e are insulated from the upper surfaces of the first antenna element 20a and the second antenna element 20b.

In the planar antenna device 09 of the ninth embodiment, the planar antenna 2 and five rectangular metal conductors 28a, 28b, 28c, 28d, and 28e are housed in a box-shaped case 51 consisting of the resin case body 51a and case lid 51b described above. When the planar antenna 2 and the metal conductors 28a, 28b, 28c, 28d, and 28e are housed in the case 51, the devices provided on the metal conductors 28a, 28b, 28c, 28d, and 28e can be protected from external forces such as wind and rain. For example, various devices such as sensors capable of acquiring environmental information, such as illuminance sensors, ultraviolet sensors, temperature sensors, humidity sensors, air pressure sensors, and rainfall sensors, storage elements such as secondary batteries, transmitters capable of transmitting environmental information, amplifiers, and splitters can be installed on the metal conductors 28a, 28b, 28c, 28d, and 28e. In addition, the range of the metal conductors 28a, 28b, 28c, 28d, and 28e can be used as a solar panel equipped with metal electrodes. In this case, the total area of the metal conductors 28a, 28b, 28c, 28d, and 28e can be increased, so that sufficient power can be generated from the solar panel. The solar panel charges the storage element, and the storage element supplies operating power to the sensor and the transmitter. Furthermore, if the case 51 is made of a light-transmitting material, the power generation efficiency of the solar panel can be ensured. In this case, as long as the case lid portion 51b is made of a light-transmitting material, the case main body portion 51a does not need to be made of a light-transmitting material. As a result, the planar antenna device 09 of the ninth embodiment is an antenna that receives terrestrial digital broadcasting, and is installed on the roof or exterior wall of a building, so that the device that acquires and transmits environmental information can be installed in a wide area.

Since the metal conductors 28a, 28b, 28c, 28d, and 28e are arranged as described above, the combined area of the metal conductors 28a, 28b, 28c, 28d, and 28e can be increased, and by increasing the area of the metal conductors 28a, 28b, 28c, 28d, and 28e, the performance of the planar antenna 2 can be maintained even if a specified range in front of the planar antenna 2 in the planar antenna device 09 of the ninth embodiment is blocked.
In other words, whether or not the metal conductors 28a, 28b, 28c, 28d, and 28e are provided, the planar antenna device 09 of the ninth embodiment can maintain substantially the same performance as the planar antenna 2.

In the planar antenna device 09 of the ninth embodiment, the upper part of the first opening 21a is blocked by the metal conductor 28a, the lower part of the second opening 22a is blocked by the metal conductor 28b, the upper part of the third opening 21b is blocked by the metal conductor 28d, and the lower part of the fourth opening 22b is blocked by the metal conductor 28e. The shielding rate, which is the ratio of the area of the first opening 21a to the fourth opening 22b blocked and shielded by the metal conductors 28a, 28b, 28d, and 28e, will be described below.
Fig. 21(a) shows a graph of VSWR characteristics when the shielding rate [%] of the first opening 21a to the fourth opening 22b blocked by the metal conductors 28a, 28b, 28d, and 28e in the planar antenna device 09 of the ninth embodiment is changed from 0% to 80%, and Fig. 21(b) shows a table showing the VSWR value at each shielding rate. In this case, the measurement frequency is 590 MHz, which is the center frequency of the receiving frequency band of the planar antenna 2, which is 470 MHz to 710 MHz.
21(a) and 21(b), the VSWR value deteriorates as the shielding rate increases, and a VSWR value of 2.5 or less is obtained until the shielding rate reaches about 50%, but when the shielding rate exceeds about 50%, the VSWR value exceeds 2.5. For example, when the shielding rate is 50%, a VSWR value of 2.48 is obtained, but when the shielding rate is 60%, the VSWR value is 2.60, when the shielding rate is 70%, the VSWR value is 2.72, and when the shielding rate is 80%, the VSWR value deteriorates to 3.77. For this reason, in the planar antenna device 09 of the ninth embodiment, it is preferable to set the shielding rate [%] of the first opening 21a to the fourth opening 22b shielded by the metal conductors 28a, 28b, 28d, and 28e to 50% or less so that a VSWR value of 2.5 or less is obtained.
21(a) and (b) are measured at a frequency of 590 MHz, but the VSWR characteristics are almost the same as those shown in Fig. 21(a) and (b) even at frequencies other than 590 MHz in the receiving frequency band of 470 MHz to 710 MHz. Also, in the planar antenna device 02 of the second embodiment, the VSWR characteristics with respect to the shielding ratio [%] of the first opening 21a to the fourth opening 22b shielded by the metal conductors 28a, 28b, 28d, and 28e are the same as those shown in Fig. 21(a) and (b), and it is preferable that the shielding ratio [%] be 50% or less in the planar antenna device 02 of the second embodiment.

The planar antenna device according to the embodiment of the present invention described above is composed of a planar antenna and a metal conductor disposed in front of the planar antenna, or a metal conductor attached to the upper surface of an antenna element constituting the planar antenna, and various devices such as sensors capable of acquiring environmental information, such as an illuminance sensor, an ultraviolet ray sensor, a temperature sensor, a humidity sensor, an air pressure sensor, and a rainfall sensor, as well as amplifiers and splitters can be installed on the metal conductor. When installing, a metal plate may be laid and the devices may be installed on the front and back sides of the plate, or individual devices may be installed separately. The metal conductor area may also be a solar panel. If the planar antenna is an antenna for receiving terrestrial digital broadcasting, the planar antenna device according to the embodiment of the present invention is installed on the roof or outer wall of a building, and therefore devices that acquire and transmit environmental information can be installed in a wide area.
In the planar antenna device according to the embodiment of the present invention described above, the metal conductor can be installed over a wide area of the planar antenna, which increases the degree of freedom in mounting the device. In addition, if the planar antenna device according to the embodiment of the present invention is equipped with a case that houses the entire device, the device can be installed inside the case, which provides the effect of protecting the device. Furthermore, by using the area of the metal conductor as a solar panel, power generation can be performed over a wide area, and larger power can be obtained.

01,0203,04,05,06,07,08,09 Planar antenna device, 1,2,3,4 Planar antenna, 1a,2a,3a,4a First planar antenna, 1b,2b,3b,4b Second planar antenna, 10a,20a,40a First antenna element, 10b,20b,40b Second antenna element, 11a,21a First opening, 11b,21b Third opening, 12a,22a Second opening, 12b,22b Fourth opening, 13a,23a First feeding point, 13b,23b Third feeding point, 14a,24a Second feeding point, 14b,24b Fourth feeding point, 15a,25a First feeding line, 15b,25b Second feeding line, 16a,26a,36a First rear element, 16b, 26b, 36b Second rear element, 17, 27 Power supply section, 18 Metal conductor, 26 Rear element, 28a, 28b, 28c, 28d, 28e Metal conductor, 31, 41, 51 Case, 31a, 51a Case body, 31b, 51b Case cover, 32 Metal conductor, 36 Rear element, 42 Metal conductor, 42a, 42b, 42c Metal conductor, 48a, 48b Through hole, 52a, 51b, 52c Solar panel unit, 100 Antenna device, 110 Antenna cover, 111 Front cover, 112 Rear cover, 120 Sensor board, 130 Solar panel, A Planar section, B Rising section, C Opening

Claims (14)

a first planar antenna including a first antenna element and a first rear element disposed at a predetermined distance behind the first antenna element;
a second antenna element and a second rear element arranged at a predetermined interval on the rear side of the second antenna element, the second planar antenna being arranged line-symmetrically at a predetermined interval on a plane on which the first planar antenna is arranged;
a metal conductor that fills a gap between the first planar antenna and the second planar antenna and is arranged in front of the first antenna element and the second antenna element so as to overlap a portion of the first antenna element and the second antenna element;
a first antenna element having two feed points formed in a central portion, a first opening formed above the two feed points, and a second opening formed below the two feed points; and a second antenna element having two feed points formed in a central portion, a third opening formed above the two feed points, and a fourth opening formed below the two feed points. The planar antenna device according to claim 1, characterized in that the first opening, the second opening, the third opening, and the fourth opening are substantially the same rectangular shape. The planar antenna device according to claim 2, characterized in that the metal conductor is disposed in front of the first antenna element and the second antenna element at a predetermined distance, and the first opening and the second opening, and the third opening and the fourth opening are not entirely covered by the metal conductor. The planar antenna device according to claim 1, characterized in that the first opening to the fourth opening are polygonal in shape. The planar antenna device according to claim 4, characterized in that the metal conductor is a plurality of metal conductors, the first opening and the second opening are not entirely covered by the plurality of metal conductors, and the third opening and the fourth opening are entirely not covered by the plurality of metal conductors, and the plurality of metal conductors are arranged in front of the first planar antenna and the second planar antenna at a predetermined distance. The planar antenna device according to claim 4, characterized in that the first planar antenna and the second planar antenna are housed in a resin box-shaped case, and the metal conductor is attached to the front of the case so that the first opening and the second opening and the third opening and the fourth opening are not entirely blocked. The planar antenna device according to claim 4, characterized in that the metal conductor is attached so as to fill the gap between the first planar antenna and the second planar antenna and to overlap a portion of the front surface of the first antenna element and the second antenna element. The planar antenna device according to claim 7, characterized in that a plurality of fifth openings are formed in the first rear element and a plurality of sixth openings are formed in the second rear element, both side edges of the first rear element are bent toward the first antenna element to form a first raised portion, and both side edges of the second rear element are bent toward the second antenna element to form a second raised portion. A planar antenna device according to claim 7 or 8, which is housed in a resin box-shaped case consisting of a case body and a case lid fitted to the case body, and at least the case lid is made of a light-transmitting material. The planar antenna device according to claim 8, characterized in that a second metal conductor is attached to the front surface of the first rear element so that none of the plurality of fifth openings are blocked, and a third metal conductor is attached to the front surface of the second rear element so that none of the plurality of sixth openings are blocked. The planar antenna device according to claim 10, characterized in that the first antenna element and the second antenna element have multiple through holes formed therein. The planar antenna device according to claim 4, characterized in that the metal conductor is a plurality of metal conductors, the first opening and the second opening are not entirely covered by the plurality of metal conductors, and the third opening and the fourth opening are entirely covered by the plurality of metal conductors, and the plurality of metal conductors are attached to the upper surfaces of the first planar antenna and the second planar antenna. The planar antenna device according to claim 13, characterized in that the shielding rate of the first opening and the second opening, and the third opening and the fourth opening, by the plurality of metal conductors is 50% or less. a first planar antenna including a first antenna element and a first rear element disposed at a predetermined distance behind the first antenna element;
a second antenna element and a second rear element arranged at a predetermined interval on the rear side of the second antenna element, the second planar antenna being arranged line-symmetrically at a predetermined interval on a plane on which the first planar antenna is arranged;
a number of metal conductors divided into a plurality of parts, the metal conductors being attached between the first planar antenna and the second planar antenna and being attached to upper surfaces of the first antenna element and the second antenna element;
a first antenna element having two feed points formed in a central portion, a first opening formed above the two feed points, and a second opening formed below the two feed points; and a second antenna element having two feed points formed in a central portion, a third opening formed above the two feed points, and a fourth opening formed below the two feed points, and the first opening to the fourth opening are not blocked by the multiple metal conductors.

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