JP2011193060A - Antenna - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a small non-film type antenna, which may not be indistinctive even in a vehicle, and has wide band characteristics capable of covering frequency bands of terrestrial digital broadcasting. <P>SOLUTION: The antenna includes a first element, a second element, and a plate. The first element includes a first feeding end, a first parallel transmission line, and a feeder. The second element includes a second feeding end, a second parallel transmission line, and a folded shape portion. The second feeding end is electrically connected to the plate set at ground potential. The first and second parallel transmission lines are mutually arranged parallel and the folded shape portion is arranged in the proximity of the plate set at ground potential to enable band-widening. Then, a meander form or a helical form is adopted for the folded shape portion. Thereby, the whole antenna can be made smaller. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a small broadband antenna.

  Currently, so-called film antennas are mainly used as terrestrial digital broadcast receiving antennas in vehicles, and an example thereof is described in Patent Document 1.

JP 2008-153738 A

  However, once a film antenna is pasted, it can hardly be replaced. As a result, delicate adjustment of the mounting position becomes impossible when adjusting the mounting position from the viewpoint of reception status and visibility, and excessive caution is required for the installation work for users and workers of car dealers. It takes a lot of time and demands. Thus, the film antenna has the property that it is very difficult for the user and the installation worker to handle.

  The film antenna is allowed to be installed to the point where it can easily enter the driver's field of view when installed on the windshield of the vehicle. Although the antenna element is processed very finely (about 0.5 to 1 mm in width), there are many users who are concerned about its presence during driving.

  Furthermore, once peeled off, the film antenna is almost impossible to reuse and must be discarded in most cases. Also from the environmental protection viewpoint of reducing waste, the property of having to dispose of it immediately if pasting fails is not preferable.

  Examples of the problem to be solved by the present invention include the above. SUMMARY OF THE INVENTION An object of the present invention is to provide a non-film type antenna having a wide band characteristic capable of covering the frequency band of terrestrial digital broadcasting, which is small so as not to stand out even when mounted on a vehicle.

  Invention of Claim 1 is an antenna, Comprising: The 1st electric power feeding end part, The 1st parallel transmission line part arrange | positioned extending along an antenna main-axis direction from the said 1st electric power feeding end part, A first element having a feeder portion extending in a direction opposite to the first feeding end from the end opposite to the first feeding end of the first parallel transmission line portion; and a second element A feed end portion, a second parallel transmission line portion disposed in parallel with the first parallel transmission path portion from the second feed end portion, and the second feed of the second parallel transmission line portion. A second element having a folded portion extending in the principal axis direction by being folded in a direction opposite to the feeder portion at an end opposite to the end, and a ground plane portion set to a ground potential. The folded shape portion includes the second parallel transmission line portion and the second parallel transmission line portion. The second being the base plate portion and electrically connected through a feeding end portion, the folded shape portion, characterized by having a portion of the meander shape or helical shape to at least a portion.

It is a figure which shows the structure of the antenna which concerns on the Example of this invention. It is a figure which shows typically the electrical connection and dimension of the antenna which concern on an Example. It is a figure which shows the structural example at the time of mounting the antenna which concerns on an Example. It is a graph which shows the characteristic of the antenna which concerns on an Example, and a comparative example. The structural example at the time of changing the length of a base-plate part is shown. The characteristic when changing the length of the main plate part is shown. The structural example at the time of changing the positional relationship of a meander shape part and a ground plane part is shown. The characteristic at the time of changing the positional relationship of a meander shape part and a ground plane part is shown. The modification of the shape of the antenna which concerns on an Example is shown. The structure of the modification which provided the amplifier circuit is shown.

  In a preferred embodiment of the present invention, the antenna includes a first feeding end, a first parallel transmission line portion arranged extending from the first feeding end along the antenna main axis direction, and the first feeding end. A first element having a feeder portion extending in a direction opposite to the first power supply end from an end opposite to the first power supply end of one parallel transmission line portion; and a second power supply end A second parallel transmission line portion disposed in parallel with the first parallel transmission path portion from the second feeding end portion, and the second feeding end portion of the second parallel transmission line portion. A second element having a folded portion that is folded back in the opposite direction to the feeder portion at the end opposite to the feeder portion and extends along the principal axis direction, and a ground plane portion that is set to a ground potential. The folded-shaped portion includes the second parallel transmission line portion and Via a serial second feeding end being connected to said base plate portion and electrically, the folded shape portion has a section of the meander shape or helical shape to at least a portion.

  The antenna includes a first element, a second element, and a ground plane portion. The first element includes a first feeding end, a first parallel transmission line portion, and a feeder portion. The second element includes a second feeding end, a second parallel transmission line portion, and a folded portion. The second power supply end is electrically connected to the ground plane portion set to the ground potential. By arranging the first and second parallel transmission line parts in parallel with each other, it is possible to increase the bandwidth. Further, by forming a meander shape or a helical shape in the folded shape portion, the entire antenna can be reduced in size.

  In one aspect of the antenna, the folded-back portion is electromagnetically coupled by arranging the meander-shaped or helical-shaped portion close to the ground plane portion. Thereby, the lower limit of the operating band of the antenna can be expanded, and further miniaturization can be achieved. In addition, due to the effect, the operating band of the antenna can be adjusted according to a desired band.

  In one aspect of the antenna described above, the electrical length of the folded portion is longer than the electrical length of the feeder portion. As a result, it is possible to prevent a reduction in the real part of the input impedance due to the downsizing, and impedance matching with the electric circuit part is facilitated at the feeding end. As a result, it is possible to ensure a good impedance matching state over a wide band.

  In another preferred example, the feeder portion has at least one folded shape portion. In another preferred example, the feeder portion has a meander-shaped or helical-shaped portion. Thereby, the overall length of the antenna can be further reduced.

  In another preferred example, the antenna includes an insulator substrate, the first element and the second element are disposed on one surface of the insulator substrate, and the ground plane portion is the insulator. It arrange | positions on the other surface of a board | substrate, and the said 2nd electric power feeding edge part and the said ground-plate part are electrically connected through the through hole formed in the said insulator board | substrate.

  In another aspect of the antenna, a circuit portion connected to the first element and the second element is provided, and a ground wiring of the circuit portion is electrically connected to the ground plane portion. In this aspect, a circuit portion to which a signal transmitted and received by the antenna is supplied is provided, and the ground plane portion set to the ground potential also serves as a ground substrate for the circuit portion. Thereby, it is not necessary to provide a ground substrate for the circuit part separately from the ground plane part of the antenna, and the antenna including the circuit part can be downsized and the structure can be simplified.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 shows a structure of an antenna 100 according to an embodiment of the present invention. FIG. 1A is a plan view showing the front surface of the antenna 100, and FIG. 1B is a rear view showing the back surface of the antenna 100. FIG. 1C is a cross-sectional view of the antenna 100 cut at a position of a through hole 5a described later.

  As illustrated, the antenna 100 includes an element 1, an element 2, a dielectric substrate 5, and a ground plane portion 6. Element 1, element 2, and ground plane portion 6 correspond to antenna elements.

  The element 1 is a single linear conductor, and is arranged along the main axis direction X that is the length direction of the antenna. The element 1 has a feeding end 1t formed at one end thereof. A portion of the element 1 having a predetermined length from the feeding end portion 1t is a parallel transmission line portion 1b, and a portion extending beyond that, that is, a portion extending to the side opposite to the feeding end portion 1t is a feeder portion 1a. . A portion of the element 1 on the power feeding end 1 t side is disposed on the dielectric substrate 5.

  The element 2 has a feeding end 2t formed at one end thereof. The power feeding end 2t is disposed close to the power feeding end 1t of the element 1. In addition, a portion of the element 2 having a predetermined length from the feeding end 2t is a parallel transmission line portion 2b. The parallel transmission line portion 2b of the element 2 has substantially the same length as the parallel transmission line portion 1b of the element 1, and is disposed on the dielectric substrate 5 in parallel with the parallel transmission line portion 1b of the element 1. In other words, the element 1 and the element 2 are arranged so that the portions of the predetermined lengths on the respective feeding end portions 1t and 2t side are parallel to each other, and the portions parallel to each other are parallel transmission line portions. 1b and 2b.

  The element 2 is bent twice at the end of the parallel transmission line portion 2b opposite to the feeding end 2t and is turned 180 degrees along the principal axis direction X. This folded portion is a folded shape portion 2a. That is, the folded portion 2a is substantially parallel to the parallel transmission line portions 1b and 2b, and extends in the direction opposite to the direction in which the feeder portion 1a of the element 1 extends along the main axis direction X. Further, the folded shape portion 2a has a meander shape in which a planar uneven shape is repeatedly formed as shown. In the example of FIG. 1, the folded-back portion 2 a has a meander shape almost entirely, but only a part of the folded-shape portion 2 a may have a meander shape.

  The dielectric substrate 5 can be formed of a printed circuit board base material such as FR4, for example. The dielectric substrate 5 has a rectangular flat plate shape, and the element 1 and the element 2 are arranged on the surface thereof as shown in FIG.

  As shown in FIG. 1B, a ground plane portion 6 is provided on the back surface of the dielectric substrate 5. The ground plane portion 6 is made of a conductor such as metal, for example. The ground plane portion 6 is electrically connected to the power feeding end 2 t of the element 2. Specifically, as shown in FIGS. 1A and 1C, a through hole 5a is provided in the dielectric substrate 5 at the position of the power feeding end 2t of the element 2, and the through hole 5a has a through hole 5a. The feeding end 2t and the ground plane portion 6 are electrically connected through a conductor provided on the surface.

  In the configuration of the antenna 100 described above, the element 1 corresponds to the first element of the present invention, the feeding end 1t corresponds to the first feeding end, and the parallel transmission line portion 1b corresponds to the first parallel transmission. It corresponds to the track part. The element 2 corresponds to the second element of the present invention, the feeding end 2t corresponds to the second feeding end, and the parallel transmission line portion 2b corresponds to the second parallel transmission line portion.

  FIG. 2A schematically shows an electrical connection state of the antenna 100. In the coaxial cable 11 through which transmission / reception signals flow, the signal line 11 s is electrically connected to the element 1, and the outer conductor (hereinafter referred to as “ground (GND) line”) 11 g is electrically connected to the element 2 and the ground plane portion 6. Connected to. Thereby, the element 1 is set to the signal potential, and the element 2 and the ground plane portion 6 are set to the ground potential. 2A schematically shows an electrical connection state of the antenna 100. In actuality, the signal line of the coaxial cable is connected to the feeding end 1t of the element 1 and is connected to the ground line. Is connected to the feeding end 2 t of the element 2. Note that the signal line and the ground line may be connected to the power supply end portions 1t and 2t, respectively, via a necessary amplifier circuit or the like. As described above, since the power supply end 2t of the element 2 is electrically connected to the ground plane portion 6 through the through hole 5a, the element 2 and the ground plane portion 6 are set to the ground potential.

  FIG. 2B shows an example of the dimensions of each part of the antenna 100. In this example, the antenna 100 of this embodiment is configured to receive terrestrial digital broadcasts. In this example, the total length of the antenna 100 is 233.5 mm, and the widths of the elements 1 and 2 are 2 mm. The length of the parallel transmission line portions 1b and 2b is 70 mm, and the gap between the lines is 1 mm. The length of the element 1 is 180 mm. The length of the folded shape portion 2a is 106 mm excluding the meandering portion of the meander shape portion, and the number of meander steps is six. The length of the main plate portion 6 is 56 mm. Considering the meandering portion of the meander shape portion, the electrical length of the folded shape portion 2a is longer than the electrical length of the feeder portion 1a. The antenna of the present invention can also be used for purposes other than receiving terrestrial digital broadcasts, and the dimensions of each part of the antenna in that case are determined appropriately based on the frequency band of the signal to be basically transmitted and received. Is done.

  FIG. 3A is an example of a configuration when the antenna 100 is actually mounted on a vehicle or the like. For example, the antenna 100 is attached to the vehicle in a state of being accommodated in an insulating case 8. The example of FIG. 3A is an example in which the antenna 100 is housed in the case 8 as it is, and the element 1, the element 2, and the dielectric substrate 5 are respectively fixed at predetermined positions inside the case 8. For convenience of explanation, it is assumed in FIG. 3A that the case 8 is made of a transparent resin and the inside can be seen through. The ground plane portion 6 provided on the back surface of the dielectric substrate 5 is not shown.

  FIG. 3B is another example of a configuration when the antenna 100 is actually mounted on a vehicle or the like. In this example, a large dielectric substrate 5x is used instead of the dielectric substrate 5 shown in FIG. That is, the dielectric substrate 5x is also used as the base material of the antenna 100. The elements 1 and 2 are arranged on the surface of the dielectric substrate 5x, and the ground plane portion 6 is arranged on the back surface of the dielectric substrate 5x. In FIG. 3B, for convenience of illustration, it is assumed that the dielectric substrate 5x is transparent, and the ground plane portion 6 formed on the back surface can be seen through from the front side. The power feeding end 2t of the element 2 and the ground plane portion 6 are brought into conduction through a through hole 5a provided in the dielectric substrate 5x. In this case, the entire outside of the dielectric substrate 5x is covered with an insulating protective case or the like so that the element 1, the element 2 and the ground plane portion 6 are not exposed.

  3A and 3B are merely examples of the configuration for mounting the antenna 100, and the antenna mounting method of the present invention is not limited to these.

  Next, features of the antenna 100 will be described. First, basically, the antenna 100 realizes a wide band by providing the parallel transmission line portions 1b and 2b in the elements 1 and 2.

  Further, by bringing a part of the folded shape portion 2a close to the ground plane portion 6, the meander-shaped portion of the folded shape portion 2a and the ground plane portion 6 are electromagnetically coupled in a good state. Thereby, the lower limit of the operating band of the antenna is expanded, and a good impedance matching state is ensured over a wide band.

  This point will be described with reference to FIG. FIG. 4A shows the voltage standing wave ratio (VSWR) characteristics of the antenna 100 of this embodiment and the antenna 100 when the ground plane portion 6 is removed. The solid line graph C1 shows the VSWR characteristic of the antenna 100 of this embodiment, that is, the antenna having the ground plane part 6, and the broken line graph C2 shows the VSWR characteristic when the ground plane part 6 is removed. In general, if the value of VSWR is “3” or less, it can be considered that the impedance matching state is good, and as shown by the solid line graph C1, the antenna 100 has a bandwidth of about 300 MHz from 510 MHz to 810 MHz. It shows a good characteristic in which the value of VSWR is “3” or less. On the other hand, as indicated by the broken line graph C2, when the ground plane portion 6 is removed, the impedance matching state is deteriorated over a wide band, and a singular point where the matching state is extremely bad is generated. As described above, in the antenna 100 according to the present embodiment, the foldable shape portion 2a and the ground plane portion 6 are disposed sufficiently close to each other so as to be electromagnetically coupled, thereby providing a stable VSWR characteristic over a wide band. Realized.

  Further, the overall length of the antenna is reduced by forming a meander shape in the folded shape portion 2a. In addition to this, the operating frequency band is adjusted by forming a meander shape in the folded shape portion 2a. A graph C3 in FIG. 4B shows the VSWR characteristics of the antenna when the folded shape portion 2a is not formed with a meander shape but is linear. As can be seen from comparison with the solid line graph C1 in FIG. 4A, when the meander shape is not formed in the folded shape portion 2a, the entire operation band is shifted to the high frequency side on the frequency axis. In this case, in order to return the operating band to the low band side without forming the meander shape, it is necessary to lengthen the length of the feeder portion 1a or the ground plane portion 6 of the element 1, resulting in the overall length of the antenna being increased. Increasing the size of the antenna. In this respect, in this embodiment, by forming a meander shape in the folded-back shape portion 2a, it is possible to reduce the size of the antenna and adjust the operating band to a desired frequency band.

  Next, the length of the main plate portion 6 in the main axis direction X will be described. FIGS. 5A to 5C show examples when the length of the main plate portion 6 is changed. 5A to 5C are rear views of the antenna 100 as viewed from the rear surface side, that is, the surface side on which the ground plane portion 6 is provided. Specifically, the main plate portion 6 is extended in the direction opposite to the feeder portion 1 a of the element 1 along the main axis direction X. FIG. 5A shows an example in which the length of the main plate portion 6 in the main axis direction X is 56 mm as in the antenna 100 shown in FIG. 1, and FIG. 5B shows an example in which the length of the main plate portion 6 is 76 mm. FIG. 5C shows an example in which the length of the main plate portion 6 is 96 mm. 5B and 5C, the dielectric substrate 5 is also extended in the principal axis direction X in order to extend the ground plane portion 6. However, the shapes and dimensions of the elements 1 and 2 are all the same. To do.

  FIG. 6 shows the VSWR characteristics when the length of the main plate portion 6 is changed as described above. Graph C4 shows the VSWR characteristics when the length of the main plate portion 6 is 56 mm as shown in FIG. 5A, and graph C5 shows that the length of the main plate portion 6 is 76 mm as shown in FIG. 5B. The VSWR characteristic in a certain case is shown, and the graph C6 shows the VSWR characteristic in the case where the length of the ground plane portion 6 is 96 mm as shown in FIG. As can be seen from the respective graphs, the lower limit of the operating band can be expanded to the low band side by lengthening the ground plane portion 6. That is, in the antenna of this embodiment, the lower limit of the operating band can be set to a desired frequency by adjusting the length of the ground plane portion 6. Although it is known that the lower limit of the operation band can be adjusted by changing the length of the feeder portion as in the case of a conventional monopole antenna, in this embodiment, the operation is also performed by the length of the ground plane portion 6 in addition to this. It becomes possible to adjust the lower limit of the band. In particular, since the antenna of this embodiment is intended for applications where downsizing is desired, it is possible to design to satisfy a desired operating band using two parameters, the length of the feeder portion and the length of the ground plane portion. This is very beneficial in that it is easy to design and increases the degree of freedom in the product shape.

  Next, the positional relationship between the meander shape portion of the folded shape portion 2a and the ground plane portion 6 will be described. Now, the meander shape has two steps, and the position is moved relative to the main plate portion 6. Note that the length of the folded shape portion 2a is fixed to 106 mm.

  A configuration example in this case is shown in FIGS. 7A to 7D are plan views seen from the front side of the antenna, but for the sake of convenience of explanation, the ground plane portion 6 provided on the back side of the antenna is also shown. Specifically, the antenna 100a illustrated in FIG. 7A is an example in which the meander-shaped portion is arranged away from the ground plane portion 6. The antenna 100b shown in FIG. 7B is an example in which the meander-shaped part and the ground plane part 6 are arranged close to each other in a direction perpendicular to the main axis direction X. An antenna 100 c shown in FIG. 7C is an example in which only one step of the meander-shaped portion is arranged side by side with the main plate portion 6 in the direction perpendicular to the main axis direction X. An antenna 100 d shown in FIG. 7D is an example in which both of the meander-shaped portions are arranged side by side with the main plate portion 6 in the direction perpendicular to the main axis direction X.

  The VSWR characteristics of the antennas 100a to 100d are shown in FIG. As can be seen by comparing the VSWR characteristics of each antenna, if the meander-shaped portion and the ground plane portion 6 are arranged adjacent to each other in a direction perpendicular to the main axis direction X, the meander-shaped portion and the ground plane portion 6 are electromagnetically connected. By combining with, the lower limit of the operating band can be expanded to the low frequency side. Therefore, the operating band of the antenna can be adjusted by adjusting the arrangement of the meander-shaped portion and the ground plane portion 6 to adjust the strength of electromagnetic coupling between them. Thereby, the freedom degree of design in the whole antenna can be increased.

  In the above example, the strength of electromagnetic coupling between the meander-shaped portion and the ground plane portion 6 is changed by changing the relative position between the meander-shaped portion and the ground plane portion 6. The same adjustment can be performed even if the (gap) is changed. For example, in the example of FIG. 7D, the position of the meander-shaped portion in the main axis direction X is not changed, and the folded-back shape portion 2a is moved in the direction perpendicular to the main axis direction X (the direction of the arrow Y in the figure). The interval between the shape portion and the ground plane portion 6 is increased. In this case, as the distance between the meander-shaped portion and the ground plane portion 6 is smaller, the strength of electromagnetic coupling between the meander-shaped portion and the ground plane portion 6 increases, and the lower limit of the operating band becomes wider on the low frequency side. Conversely, as the distance between the meander-shaped portion and the ground plane portion 6 increases, the strength of electromagnetic coupling between the meander-shaped portion and the ground plane portion 6 decreases, and the lower limit of the operating band moves to the high frequency side. Accordingly, as shown in FIGS. 7A to 7D, instead of or in addition to the adjustment of the relative positional relationship between the meander-shaped portion and the ground plane portion 6 in the main axis direction X, the meander-shaped portion and the ground plane portion 6. It is possible to adjust the operating band also by adjusting the distance between the two, and further freedom in design can be obtained.

[Modification 1]
Next, various modifications of the shape of the antenna 100 will be described. 9A to 9E show modified examples of the shape of the antenna 100. FIG.

  An antenna 100e shown in FIG. 9A is an example in which the end of the feeder portion 1a of the element 1 opposite to the feeding end 1t is folded. An antenna 100f shown in FIG. 9B is an example in which the tip of the feeder portion 1a of the antenna 100e shown in FIG. 9A is further formed in a meander shape. An antenna 100g shown in FIG. 9C is an example in which a meander shape is formed in the feeder portion 1a of the element 1. The antenna 100h shown in FIG. 9D is an example in which the tip of the feeder portion 1a of the element 1 is bent once in the vertical direction, and the bent portion has a meander shape. In these examples, the overall length of the antenna can be reduced by shortening the length of the feeder portion 1a.

  An antenna 100i shown in FIG. 9E is an example in which a helical shape is formed in the folded shape portion 2a instead of the meander shape. Although shown in a plan view in FIG. 9E, the helical shape is formed in a three-dimensional loop shape such as a coil. Even with this helical shape, the total length of the element 2 can be shortened as in the meander shape. In addition, by arranging the helically shaped portion close to the ground plane portion 6, it is possible to electromagnetically couple them and adjust the operating band.

[Modification 2]
Next, a modification in which an amplifier circuit is provided for the antenna will be described. FIG. 10A is a plan view showing the front surface of the antenna 100x including the amplifier circuit, FIG. 10B is a rear view showing the back surface of the antenna 100x, and FIG. 10C is a through hole of the antenna 100x. It is sectional drawing along the cross section which passes along 5a.

  As illustrated, an amplifier circuit 20 is provided on the surface of the dielectric substrate 5. The amplifier circuit 20 is disposed in proximity to the feeding end portions 1t and 2t of the antenna 100x, and has a role of amplifying (boosting) a signal received by the antenna 100x. The signal line 20 s of the amplifier circuit 20 is connected to the power supply end 1 t of the element 1, and the ground line 20 g of the amplifier circuit 20 is connected to the power supply end 2 t of the element 2. The signal amplified by the amplifier circuit 20 is output from the amplifier circuit 20 to a signal processing circuit or the like via a cable or the like (not shown).

  As shown in FIGS. 10B and 10C, a through hole 5 b is formed in the dielectric substrate 5 at a position below the amplifier circuit 20. A ground wiring (not shown) of the amplifier circuit 20 is electrically connected to the ground plane portion 6 through a conductor provided in the through hole 5b. That is, the ground plane portion 6 has a function as an antenna element set to the ground potential and also functions as a ground substrate of the amplifier circuit 20. As a result, the ground potential of the antenna and the amplifier circuit 20 can be made common, and it is not necessary to provide the ground substrate of the amplifier circuit 20 separately from the ground plane portion 6 that provides the ground potential of the antenna. Is possible. In the above example, one through hole 5b is provided for convenience of illustration, but in practice, a plurality of through holes 5b are provided to electrically connect the ground wiring of the amplifier circuit 20 and the ground plane portion 6. Is preferred.

  In the above example, the amplifier circuit 20 having the reception signal amplification function is provided, but instead, an electronic circuit for performing other processing such as signal processing may be provided, or the reception signal amplification function and other functions may be provided. An electronic circuit having both functions may be provided. In any case, by connecting the ground wiring of the electronic circuit to the ground plane portion of the antenna, the antenna and the ground of the electronic circuit can be shared, and the antenna can be downsized.

  The present invention can be used as a small antenna mounted on a portable device or the like. In particular, it can be suitably used for a terrestrial digital broadcast receiving antenna for a small portable device such as a portable TV and a portable game machine, in addition to a terrestrial digital broadcast receiving antenna installed on a window glass of an automobile.

DESCRIPTION OF SYMBOLS 1, 2 Element 1a Feeder part 1b, 2b Parallel transmission line part 1t, 2t Feeding end part 2a Folding shape part 5 Dielectric substrate 5a, 5b Through hole 6 Ground plane part 11 Coaxial cable 20 Amplifier circuit 100, 100a-100i Antenna

Claims (7)

A first feeding end portion; a first parallel transmission line portion arranged extending from the first feeding end portion along the antenna main axis direction; and the first feeding portion of the first parallel transmission line portion. A first portion having a feeder portion extending in an opposite direction to the first feeding end from an end opposite to the end;
A second feeding end portion, a second parallel transmission line portion arranged in parallel with the first parallel transmission path portion from the second feeding end portion, and the second parallel transmission line portion. A second element having a folded-back portion that is folded back in the direction opposite to the feeder portion at the end opposite to the feeding end portion of the two and extends along the main axis direction;
A ground plane portion set to a ground potential,
The folded shape portion is electrically connected to the ground plane portion via the second parallel transmission line portion and the second feeding end,
The antenna according to claim 1, wherein the folded portion has at least a portion having a meander shape or a helical shape.   2. The antenna according to claim 1, wherein the folded-shaped portion has the meander-shaped or helical-shaped portion disposed close to the ground plane portion and is electromagnetically coupled.   The antenna according to claim 1 or 2, wherein an electrical length of the folded-shaped portion is longer than an electrical length of the feeder portion.   The antenna according to any one of claims 1 to 3, wherein the feeder portion has at least one folded-back portion.   The antenna according to any one of claims 1 to 4, wherein the feeder portion has a meander-shaped or helical-shaped portion.   An insulator substrate, wherein the first element and the second element are disposed on one surface of the insulator substrate, the ground plane portion is disposed on the other surface of the insulator substrate, 6. The antenna according to claim 1, wherein the power feeding end portion and the ground plane portion are electrically connected through a through hole formed in the insulator substrate.   7. A circuit portion connected to the first element and the second element, and a ground wiring of the circuit portion is electrically connected to the ground plane portion. The antenna according to claim 1.

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