JP6776979B2 - Antenna device - Google Patents

Description

The present invention relates to an antenna device that realizes directivity in a predetermined direction by using a non-feeding element.

Conventionally, the Yagi antenna (registered trademark) is known as an antenna having directivity. The Yagi antenna is realized by using a feeding element that functions as a radiator and a non-feeding element that functions as a reflector. Generally, the feeding element in the Yagi antenna needs to have a length equivalent to half the wavelength (that is, λ / 2) of the radio wave to be transmitted and received, and the non-feeding element needs to have a length of λ / 2 or more. Become.

Further, the reflecting element needs to be arranged so as to face the radiating element at a distance of about λ / 4. This is because if the distance between the radiating element and the reflecting element is set to λ / 4 or less, the resonance current having a phase difference of 90 ° is not induced in the reflecting element, and the characteristics as a directional antenna cannot be obtained. In response to such a problem, Patent Document 1 discloses a configuration in which the distance between the radiating element and the reflecting element is reduced to about λ / 8 by forming the reflecting element into a bent shape. However, the linear distance from one end to the other end of the bent shape of the non-feeding element needs to be λ / 2.

Japanese Unexamined Patent Publication No. 2011-71832

In the configuration of Patent Document 1, the linear distance from one end to the other end of the non-feeding element formed in a bent shape needs to be λ / 2.

The present invention has been made based on this circumstance, and an object of the present invention is an antenna device provided with a non-feeding element for forming directivity, and the length of the non-feeding element is transmitted and received. An object of the present invention is to provide an antenna device capable of shortening the target radio wave to less than half a wavelength.

The present invention for achieving the object is a substrate (1), a flat plate-shaped conductor arranged on the substrate and a main plate (4) that provides a ground potential, and a linear one. A first linear element (5) whose end is connected to the main plate via a feeding portion (3) and whose other end is an open end, and a predetermined distance from the main plate so as to be capacitively coupled to the main plate. The second linear element (6), which is a linear conductor arranged at the same time, is provided, and the total length of the second linear element is two minutes of the target wavelength, which is the wavelength of the radio wave to be transmitted and received. It is set to less than 1 and is connected to an inductor (7) that provides a predetermined inductance, and the inductance provided by the inductor is the capacitance formed between the main plate and the second linear element. Due to the series resonance, the current flowing in the first linear element and the current whose phase is 90 ° out of phase are set to the value flowing in the second linear element, and the first linear element becomes the second linear element. It is characterized in that the resonant current is arranged so as to flow in a direction parallel to the vector of the exciting current.

In the above configuration, the inductor arranged in the non-feeding element provides the capacitance formed between the non-feeding element and the main plate and the inductance that resonates at the operating frequency. Therefore, even if the length of the non-feeding element is set to be shorter than half the wavelength of the radio wave to be transmitted / received (hereinafter, λ), the current is excited to the non-feeding element at the operating frequency. Further, the inductor is set so that a current having a phase shift of 90 ° with respect to the current flowing through the first linear element flows through the non-feeding element. As described above, according to the above configuration, even if the length of the non-feeding element is set to less than λ / 2, the resonance current is excited with a phase shift of 90 °, so that it can function as a reflector. That is, the length of the non-feeding element can be shortened to less than half the wavelength of the radio wave to be transmitted and received.

The reference numerals in parentheses described in the claims indicate, as one embodiment, the correspondence with the specific means described in the embodiments described later, and limit the technical scope of the present invention. is not.

It is a top view of the antenna device 100. It is a schematic diagram of the antenna device 100. It is a figure which shows the result of simulating the operation of the antenna device 100. It is a figure for demonstrating the operation of the antenna device 100. It is a figure which shows the result of simulating the operation of the antenna device 100. It is a figure which shows the result of having analyzed the directivity of the antenna device 100. It is a figure which shows an example of the usage mode of the antenna device 100. It is a figure which shows the modification of the structure of the antenna device 100. It is a figure which shows the modification of the structure of the antenna device 100. It is a figure which shows the cross section in line 10-10.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The antenna device 100 according to the present embodiment is configured to transmit and receive radio waves of a predetermined frequency (hereinafter, target radio waves). The antenna device 100 may be provided for only one of transmission and reception. The operating frequency of the antenna device 100 (in other words, the frequency of the target radio wave) may be appropriately designed, and is set to 930 MHz as an example here. Of course, the operating frequency may be appropriately designed, and other embodiments may be, for example, 300 MHz, 760 MHz, 1.575 GHz, 2.4 GHz, 5.9 GHz, or the like. Hereinafter, the wavelength of the target radio wave is also referred to as the target wavelength. In the present embodiment, the frequency of the target radio wave is 930 MHz, so the target wavelength is 322 mm.

<Configuration of antenna device 100>
Hereinafter, a specific configuration of the antenna device 100 will be described. As shown in FIG. 1, the antenna device 100 includes a substrate 1, a wireless circuit module 2, a feeding unit 3, a main plate 4, a feeding element 5, a non-feeding element 6, and an inductor 7. Note that FIG. 1 is a diagram (that is, a top view) schematically showing the appearance of the antenna device 100 when viewed from above.

The substrate 1 is a flat plate-like member made of an electrically insulating material such as a resin (for example, a glass cloth base material epoxy resin). A main plate 4, a feeding unit 3, a feeding element 5, a non-feeding element 6, and an inductor 7 are arranged on one side of the substrate 1, and a wireless circuit module 2 is arranged on the other side. For convenience, hereinafter, the surface of the substrate 1 on which the main plate 4 and the like are arranged is referred to as a front surface, and the surface on the opposite side thereof is referred to as a back surface. The direction from the back surface to the front surface of the substrate 1 corresponds to the upward direction for the antenna device 100.

The shape of the substrate 1 may be of a size and shape necessary and sufficient for arranging members such as the main plate 4. In the present embodiment, as an example, the substrate 1 is formed in a rectangular shape, but the shape of the substrate 1 may be circular (including an ellipse) or other polygonal shape. The material of the substrate 1 may be a material having a desired relative permittivity.

The wireless circuit module 2 is a circuit module that performs predetermined processing (for example, noise removal, amplification, demodulation) on a received signal, and performs predetermined processing related to signal transmission. The processing related to signal transmission is, for example, generation / modulation of a transmission signal. The wireless circuit module 2 is realized by using an analog circuit element, a digital circuit element, an IC, or the like. Of course, the wireless circuit module 2 may be realized as a computer by using a CPU, an MPU, or the like. The wireless circuit module 2 is driven by electric power supplied from a power source (for example, a battery) (not shown).

The wireless circuit module 2 is connected to each of the power feeding element 5 and the main plate 4 via a power feeding line (hereinafter, feeding line) (not shown). The feeder line may be realized by using a coaxial cable or may be a microstrip line. In this embodiment, as an example, it is assumed that the feeding line is realized by using a coaxial cable. That is, the wireless circuit module 2 is connected to the power feeding element 5 via the inner conductor of the coaxial cable, and is connected to the main plate 4 via the outer conductor of the coaxial cable.

The power feeding unit 3 has a configuration in which each of the main plate 4 and the power feeding element 5 is connected to a feeding line (specifically, a coaxial cable). The feeding unit 3 includes a feeding point where the inner conductor of the coaxial cable and the feeding element 5 are connected, and a grounding point where the outer conductor of the coaxial cable and the main plate 4 are connected. The electrical connection between the members may be realized by using conductive pins or vias. The power feeding unit 3 is arranged at a corner of the main plate 4 as shown in FIG. The corner portion of the main plate 4 on which the feeding portion 3 is arranged corresponds to the feeding corner portion according to the claim. The feeding unit 3 may include an impedance matching circuit, a filter circuit, and the like.

The main plate 4 is a plate-shaped conductor member made of a conductor such as copper. The plate shape here also includes a thin film shape such as a foil. The main plate 4 is electrically connected to the outer conductor of the coaxial cable at the feeding unit 3 to provide a ground potential (in other words, a ground potential) in the antenna device 100.

The shape of the main plate 4 viewed from above (hereinafter referred to as the planar shape) may be appropriately designed. Here, as an example, it is assumed that the planar shape of the main plate 4 is set to a rectangular shape (in other words, a rectangle other than a square) having a long side and a short side. As another aspect, the planar shape of the main plate 4 may be another polygonal shape (for example, a square or a hexagon). Further, it may be circular (including an ellipse). Of course, the shape may be a combination of a straight portion and a curved portion. Further, the shape in which the corners of the rectangle are rounded or notched, and the shape in which the concave portion, the protruding portion, and the notched portion are provided in a part of the edge portion of the rectangle are also included in the rectangular shape. ..

Hereinafter, for convenience, the configuration of the antenna device 100 will be described by appropriately introducing the concept of a three-dimensional coordinate system having X, Y, and Z axes orthogonal to each other. The X-axis is an axis parallel to the short side of the main plate 4, and the Y-axis is an axis orthogonal to the X-axis in a plane parallel to the main plate 4 including the X-axis. The Y-axis corresponds to an axis parallel to the long side of the main plate 4. The Z axis is orthogonal to each of the X axis and the Y axis, and the direction from the back surface to the front surface of the substrate 1 is the positive direction.

The length L3x of the short side of the main plate 4 may be appropriately designed within a range equal to or longer than the length of the non-feeding element 6 described later. Here, as an example, it is assumed that the length is set to about 1/10 of the target wavelength (that is, 32 mm). Further, it is assumed that the length L3y of the long side of the main plate 4 is set to a value obtained by subtracting the interval La described later from the length of about one-eighth of the target wavelength (that is, 40 mm). Here, as an example, it is assumed that the interval La is set to 3.2 mm, and the length L3y of the long side of the main plate 4 is set to about 37 mm.

In this embodiment, as an example, the dimensions of each member are described assuming that the target radio wave is not affected by the wavelength shortening effect of the substrate 1 and the like. If the wavelength of the target radio wave is shortened by the substrate 1 or the like, the dimensions of each member may be designed based on the shortened wavelength. For example, when the wavelength of the target radio wave is shortened by the substrate 1 or the like, the length L3x of the short side of the main plate 4 may be a length of 10 1 of the shortened wavelength. That is, the length L3x of the short side of the main plate 4 may be electrically one tenth of the target wavelength. The electrical length here corresponds to an effective length in consideration of the fringing electric field and the wavelength shortening effect of the dielectric.

One of the four corners of the main plate 4 is provided with a grounding point that is directly or indirectly connected to the outer conductor of the coaxial cable. The indirectly connected configuration includes a configuration connected via an impedance matching circuit, a filter circuit, or the like, or a configuration connected by electromagnetic coupling. In any case, the main plate 4 may be electrically connected to the outer conductor of the coaxial cable so as to provide a ground potential. Here, as an example, it is assumed that the power feeding portion 3 (more specifically, the ground contact point) is arranged at the lower left corner portion in the drawing among the four corner portions provided by the main plate 4. In the drawing, the lower left corner corresponds to a corner connecting the long side on the positive direction side of the X axis and the short side on the negative direction side of the Y axis.

The power feeding element 5 is a linear conductor member made of a conductor such as copper. The linear shape here also includes a shape having a predetermined width (for example, a strip shape). The power feeding element 5 corresponds to the first linear element according to the claim. The power feeding element 5 includes an X-axis parallel portion 51 that is parallel to the X-axis and a Y-axis parallel portion 52 that is parallel to the Y-axis. The X-axis parallel portion 51 and the Y-axis parallel portion 52 are connected at right angles at the ends, forming an L-shape / inverted L-shape as a whole.

That is, the power feeding element 5 is a linear conductor element formed in an L-shape / inverted L-shape. The power feeding element 5 corresponds to, for example, a configuration in which a linear monopole conductor element is bent at a right angle (including a substantially right angle) in the middle (referred to as a right angle portion). The X-axis parallel portion 51 corresponds to the power supply connection portion according to the claim, and the Y-axis parallel portion 52 corresponds to the extension portion according to the claim.

In the power feeding element 5, the end of the X-axis parallel portion 51 is connected to the main plate 4 via the feeding portion 3, and the Y-axis parallel portion 52 is the edge of the main plate 4, which corresponds to one side of a rectangle. It is arranged on the substrate 1 so as to face the portion (hereinafter referred to as the edge portion). That is, the Y-axis parallel portion 52 corresponds to a configuration in which the Y-axis parallel portion 52 is arranged to face the edge portion of the main plate 4. The X-axis parallel portion 51 can also be regarded as a linear conductor member extending parallel to the X-axis by a predetermined length starting from a connection point with the feeding portion 3. Further, the Y-axis parallel portion 52 can also be regarded as a linear conductor member extending at a right angle from the end portion of the X-axis parallel portion 51 that is not connected to the feeding portion 3.

The end of the Y-axis parallel portion 52 that is not connected to the X-axis parallel portion 51 is an open end. For convenience, of the four sides of the main plate 4, the edge portion facing the Y-axis parallel portion 52 is referred to as a feeding element facing portion 41. The power feeding element facing portion 41 corresponds to the first edge portion according to the claim.

The range indicated by parallelism here is not limited to strict parallelism. An inclination of about 30 degrees may occur. The same applies to the opposite. The range pointed to by the right angle is also not limited to the exact right angle (ie 90 °). An inclination of about 30 degrees may occur.

The length of the feeding element 5 may be appropriately designed within a range of less than half of the target wavelength. Further, from the viewpoint of miniaturization, it is preferable that the wavelength is set to 1/4 or less of the target wavelength. In the present embodiment, as an example, it is assumed that the total length of the power feeding element 5 is set to about 1/6 of the target wavelength.

The ratio of the length L1x of the X-axis parallel portion 51 and the length L1y of the Y-axis parallel portion 52 in the feeding element 5 may be appropriately designed. In the present embodiment, as an example, it is assumed that the length L1x of the X-axis parallel portion 51 is set to 7 mm, and the length L1y of the Y-axis parallel portion 52 is set to 45 mm. If the X-axis parallel portion 51 is sufficiently short, the current flowing through the Y-axis parallel portion 52 induces a current in the feeding element facing portion 41 in the direction opposite to the current flowing in the Y-axis parallel portion 52 so that they cancel each other out. Acts on. As a result, the direction of the current (hereinafter, resonance current) that flows when the feeding element 5 resonates can be set in a direction parallel to the X-axis direction.

Further, if the X-axis parallel portion 51 is long, the distance between the Y-axis parallel portion 52 and the feeding element facing portion 41 is increased by that amount, and the size of the antenna device 100 is increased. However, if the X-axis parallel portion 51 is too short, the Y-axis parallel portion 52 and the feeding element facing portion 41 are capacitively coupled, and it becomes difficult to concentrate the current on the X-axis parallel portion 51. In view of such circumstances, the length of the X-axis parallel portion 51 is preferably set to 1/100 or more and 1/10 or less of the target wavelength.

The non-feeding element 6 is a linear conductor member made of a conductor such as copper. The non-feeding element 6 corresponds to the second linear element according to the claim. The non-feeding element 6 is arranged so as to face the short side of the main plate 4 at a predetermined interval La. More specifically, the non-feeding element 6 of the present embodiment has the short side (hereinafter, the non-feeding element facing portion) located in the positive direction of the Y axis (in other words, the right side of the drawing) among the two short sides of the main plate 4. ) 42 is arranged so as to face it. The non-feeding element facing portion 42 corresponds to the second edge portion according to the claim.

It is assumed that the distance La between the non-feeding element 6 and the non-feeding element facing portion 42 is set to a length in which the main plate 4 and the non-feeding element 6 are capacitively coupled. As a result of various tests, the inventors have found that if the interval La is 1/50 or less of the target wavelength, the main plate 4 and the non-feeding element 6 are capacitively coupled at the operating frequency. That is, the interval La may be appropriately designed within a range of 1/50 or less of the target wavelength. In this embodiment, it is assumed that the interval La is set to 3.2 mm. As a result, the distance Lb from the X-axis parallel portion 51 to the non-feeding element 6 becomes equivalent to one quarter (that is, 40 mm) of the target wavelength.

It is assumed that the length L6 of the non-feeding element 6 is set to a length of about 1/10 of the target wavelength (that is, 32 mm). An inductor 7 that provides a predetermined inductance is interposed in the middle of the non-feeding element 6. In the present embodiment, as an example, it is assumed that the inductor 7 is arranged at the center of the non-feeding element 6.

The inductance provided by the inductor 7 resonates in series with the capacitance formed between the main plate 4 and the non-feeding element 6, so that a current 90 ° out of phase with the feeding element 5 flows through the non-feeding element 6. Is set to. The inductance provided by the inductor 7 may be set to, for example, 67 nH. As described above, the inductance value of the inductor 7 and the distance La between the non-feeding element 6 and the main plate 4 function as parameters for adjusting the phase difference between the current flowing through the feeding element 5 and the current flowing through the non-feeding element 6.

The state in which the phases of the current flowing through the feeding element 5 and the current flowing through the non-feeding element 6 are out of phase by 90 ° is not limited to the state in which the phase difference is exactly 90 °. The state in which the current flowing through the feeding element 5 and the phase flowing through the non-feeding element 6 are out of phase by 90 ° may be deviated from 90 ° within the range in which the non-feeding element 6 operates as a reflector for the feeding element 5. If the deterioration of the gain is allowed to some extent, the state where the phase difference is 60 ° to 120 ° is also included in the state where the phase difference is 90 °.

Further, in the present embodiment, as an example, the embodiment in which the inductor 7 is inserted in the central portion of the non-feeding element 6 is disclosed, but the present invention is not limited to this. The inductor 7 may be arranged at a position deviated from the central portion of the non-feeding element 6. For example, the inductor 7 may be arranged at one end of the non-feeding element 6.

FIG. 2 is a schematic view of the antenna device 100. L shown in FIG. 2 represents the inductance provided by the inductor 7, and C represents the capacitance provided by the distance La between the non-feeding element 6 and the main plate 4. In addition, λ in the figure represents the target wavelength.

The non-feeding element 6 is connected to the inductor 7 that provides a predetermined inductance, and is arranged so as to face each other at a predetermined interval La from the main plate 4, so that the total length of the non-feeding element 6 is 8 minutes of the target wavelength. Even if it is 1 or less, a current that is 90 ° out of phase with the feeding element 5 at the operating frequency will flow. As a result, the antenna device 100 includes a first mode in which the feeding element 5 radiates the target radio wave and a second mode in which the non-feeding element 6 radiates the target radio wave. Hereinafter, the operation of the antenna device 100 when the phases are 0 °, 90 °, 180 °, and 270 ° will be described with the state in which the current is most induced in the feeding element 5 as the initial state (phase = 0 °).

FIG. 3 is a diagram showing a current distribution when the phase is 0 ° when the operation of the antenna device 100 is simulated. As the simulation model, a configuration in which a notch is provided in a part of the main plate 4 is adopted. The same current distribution is obtained even in a configuration without a notch.

When the phase is 0 °, the antenna device 100 operates as the first mode. Specifically, as shown in FIG. 4, a current flows through the power feeding element 5 from the power feeding unit 3 toward the open end. Further, an image current opposite to the current flowing in the Y-axis parallel portion 52 is generated in the power feeding element facing portion 41. As a result, the electric field component derived from the current flowing in the Y-axis parallel portion 52 and the electric field component derived from the image current flowing in the feeding element facing portion 41 cancel each other out, and the X-axis parallel portion 51 functions as the main radiation element. .. Since the current flowing through the X-axis parallel portion 51 at the time of resonance effectively contributes to the radiation of radio waves, the current flowing through the X-axis parallel portion 51 at the time of resonance corresponds to the resonance current according to the claim.

Further, when the phase is 90 °, the non-feeding element 6 resonates and a current flows in the positive direction of the X-axis. That is, the antenna device 100 operates as the second mode. FIG. 5 is a diagram showing the results of simulating the current distribution when the phase is 90 °. The composite vector of the currents distributed in the non-feeding element 6 corresponds to the direction parallel to the vector of the currents excited by the second linear element according to the claim. However, since the non-feeding element 6 is linear in the present embodiment, the direction parallel to the non-feeding element 6 corresponds to the direction parallel to the vector of the current excited to the second linear element according to the claim. To do.

When the phase is 180 °, a current flows through the feeding element 5 and the feeding element facing portion 41 in the direction opposite to that when the phase is 0 °. That is, when the phase is 180 °, the antenna device 100 operates as the first mode. When the phase is 270 °, the non-feeding element 6 resonates, a current flows in the negative direction of the X-axis, and radio waves are radiated. That is, the antenna device 100 operates as the second mode.

As described above, when the phase is 0 ° and 180 °, the resonance current is induced in the X-axis parallel portion 51, while when the phase is 90 ° and 270 °, the resonance current is excited by the non-feeding element 6. Since the X-axis parallel portion 51 and the non-feeding element 6 are in a posture of facing each other, the non-feeding element 6 functions as a reflector for the X-axis parallel portion 51. As a result, as shown in FIG. 6, the directivity is provided in the direction from the non-feeding element 6 toward the X-axis parallel portion 51 (that is, the Y-axis negative direction). Note that FIG. 6 is a diagram showing the results of analyzing the directivity in the configuration of the embodiment. According to the configuration of the embodiment, a gain of about 8 dB is obtained as the ratio of the levels radiated forward and backward (so-called FB ratio).

<Effect of embodiment>
Generally, in the Yagi antenna (registered trademark), the feeding element as a radiating element needs to have a length equivalent to half the wavelength (that is, λ / 2) of the radio wave to be transmitted and received, and no feeding as a reflector. The element needs to have a length of λ / 2 or more. On the other hand, according to the configuration of the present embodiment, the inductor 7 that provides the capacitance formed between the non-feeding element 6 and the main plate 4 and the inductance that resonates at the operating frequency is connected to the non-feeding element 6 (specifically, By interposing it in the central part), even if the length of the non-feeding element 6 is set to λ / 8 or less, the non-feeding element 6 is excited by a current whose phase is 90 ° out of phase with that of the feeding element 5. Can be made to.

Further, the portion of the feeding element 5 through which the resonance current flows is an X-axis parallel portion 51 parallel to the non-feeding element 6. In other words, the non-feeding element 6 is arranged in a posture parallel to the portion where the resonance current flows in the feeding element 5. Therefore, the non-feeding element 6 functions as a reflector for the feeding element 5. That is, according to the above configuration, the length of the non-feeding element 6 can be shortened to less than half the wavelength of the radio wave to be transmitted and received.

Further, in a general Yagi antenna, the feeding element and the non-feeding element need to be arranged so as to face each other with a distance of about λ / 4. This is because if the distance between the radiating element and the reflecting element is set to λ / 4 or less, the resonance current having a phase difference of 90 ° is not induced in the reflecting element, and the characteristics as a directional antenna cannot be obtained. On the other hand, in the present embodiment, by using the inductor 7 or the like as described above, the distance Lb of the portion where the feeding element 5 and the non-feeding element 6 face each other can be shortened to about λ / 8.

<Usage example of antenna device 100>
As shown in FIG. 7, for example, the antenna device 100 described above can be used by being attached to a handle 210, a front fork, or the like of a bicycle 200 in a posture in which the directivity is directed toward the front of the vehicle. According to such a mounting posture, the radio waves transmitted and received by the antenna device 100 are difficult to pass through the body of the occupant of the bicycle 200, so that the possibility that the communication performance becomes unstable due to the influence of the body of the occupant of the bicycle 200 can be reduced. .. The antenna device 100 can be used, for example, as a device that provides a function of performing wireless communication with another vehicle 300.

Of course, the antenna device 100 can be mounted not only on a bicycle but also on a motorized bicycle or an automobile. Further, it may be used by being attached to a stroller, a wheelchair, or the like. Further, it may be used by being attached to a pedestrian-worn item such as shoes or a belt.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications described below are also included in the technical scope of the present invention, and other than the following. Can be changed and implemented within the range that does not deviate from the gist.

The members having the same functions as the members described in the above-described embodiment are designated by the same reference numerals, and the description thereof will be omitted. Further, when only a part of the configuration is referred to, the configuration of the embodiment described above can be applied to the other parts.

[Modification 1]
In the above-described embodiment, the embodiment in which the wireless circuit module 2 is arranged on the back surface of the substrate 1 is disclosed, but the present invention is not limited to this. The wireless circuit module 2 may be mounted on the surface of the substrate 1 in the same manner as the main plate 4. Further, it may be arranged on the upper side of the main plate 4. Further, in the above-described embodiment, the configuration in which the wireless circuit module 2 is built in the antenna device 100 is disclosed, but the present invention is not limited to this. The wireless circuit module 2 may be provided outside the antenna device 100.

Further, the antenna device 100 may be built in the cycle computer. The cycle computer is a computer attached to the bicycle 200 to measure the traveling speed, mileage, cadence, etc. of the bicycle 200. When the antenna device 100 is built in the cycle computer, the antenna device 100 can also be used as a device for transmitting measurement data such as traveling speed to a mobile terminal carried by the user. The mobile terminal carried by the user refers to, for example, a smartphone or a wearable device.

[Modification 2]
In the above-described embodiment, the mode in which the power feeding element 5 is formed in an L-shape / inverted L-shape is disclosed, but the shape of the power feeding element 5 is not limited to the L-shape / inverted L-shape. For example, as shown in FIG. 8, the feeding element 5 may be on a straight line.

Further, in the above-described embodiment, the embodiment in which the non-feeding element 6 is arranged on the right side of the main plate 4 is disclosed, but the position of the non-feeding element 6 is not limited to the right side of the main plate 4. It may be arranged on the left side of the main plate 4. Further, as shown in FIGS. 9 and 10, the floor plate 4 may be arranged at a position above the right edge portion of the main plate 4 by a predetermined interval La. The separation between the main plate 4 and the non-feeding element 6 may be secured by the support member 8 realized by resin or the like. The non-feeding element 6 may be arranged at a position above the left edge of the main plate 4 by a predetermined interval La.

100 Antenna device, 1 board, 2 wireless circuit module, 3 feeding part, 4 main plate, 5 feeding element, 6 non-feeding element, 7 inductor, 200 bicycle, 300 other vehicle

Claims (5)

Substrate (1) and
A plate-shaped conductor arranged on the substrate and providing a ground potential, and a main plate (4).
A first linear element (5) that is linear, one end of which is connected to the main plate via a feeding portion (3), and the other end of which is an open end.
A second linear element (6), which is a linear conductor arranged at a predetermined distance from the main plate so as to be capacitively coupled to the main plate, is provided.
The second linear element is connected to an inductor (7) whose total length is set to less than half of the target wavelength, which is the wavelength of the radio wave to be transmitted and received, and which provides a predetermined inductance. Ori,
The inductance provided by the inductor is a current that is 90 ° out of phase with the current flowing through the first linear element due to series resonance with the capacitance formed between the main plate and the second linear element. , It is set to a value that excites the second linear element.
The antenna device is characterized in that the first linear element is arranged so that a resonant current flows in a direction parallel to a vector of a current excited by the second linear element. In claim 1,
An antenna device characterized in that the distance between the main plate and the second linear element is set to 1/50 or less of the target wavelength. In claim 1 or 2,
The first linear element includes a feeding connection portion (51) formed linearly with a predetermined length starting from a connection point with the feeding portion.
The second linear element is formed in a straight line and is arranged so as to be parallel to the power feeding connection portion.
An antenna device characterized in that the distance between the power feeding connection portion and the second linear element is set to one-fourth or less of the target wavelength. In claim 3,
The main plate is formed in a rectangular shape in which the length of each side is shorter than a quarter of the target wavelength.
The power feeding portion is arranged at one corner of the four corners of the rectangular main plate.
The first linear element is formed in an L-shape or an inverted L-shape.
In the first linear element, among the first linear elements formed in an L-shape or an inverted L-shape, an extension portion other than the power supply connection portion is a portion of the edge portion of the main plate. Among them, the feeding portion is arranged so as to face the first edge portion (41) corresponding to one side connected to the feeding corner portion which is the corner portion where the feeding portion is arranged.
The antenna device is characterized in that the second linear element is arranged to face the second edge portion (42), which is an edge portion connected at a right angle to the first edge portion. In any one of claims 1 to 4,
The total length of the first linear element is set to one-fourth or less of the target wavelength.
An antenna device characterized in that the total length of the second linear element is set to one-eighth or less of the target wavelength.

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