JP2005303849A - Micro-antenna dual and method for constituting antenna element for micro-antenna dual - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To constitute a micro-antenna having a dual performance by resonating one antenna element (such as an exciter, a parasitic element or the like) to radio waves having two kinds of wavelengths. <P>SOLUTION: One surface of an exciter body 1 is covered with an antenna-side dielectric 3A while a part of the other surface is covered with a ground-side dielectric 3G to one exciter body 1. Accordingly, one exciter body 1 is resonated even to the radio waves having a lower frequency and even to the radio waves having a higher frequency, and the number of components for an antenna device is reduced. Consequently, a micro-dual antenna having a lightweight is obtained as the whole antenna device. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a dual-band micro-antenna and a method of configuring an antenna element that forms the dual-band micro-antenna, and is a technique that is effective when transmitting and receiving radio waves in the GHz band.

With the development of mobile phones, various technologies have been proposed to reduce the size and weight of antennas that transmit and receive GHz band radio waves.
Technology for coupling an exciter having an electrical length of ¼ wavelength and an antenna element having an electrical length of ¼ or ¾ wavelength via a capacitance in order to construct a small, lightweight and high-performance antenna. Is known.
As the antenna element, a rod shape, a helical shape, a strip shape and the like are widely used. A slot-type bow-tie antenna is also in practical use.
JP 2002-144213 A

Even in a wireless LAN (local area network), a small and lightweight antenna is desired.
However, since the frequency bands of radio waves for wireless LAN used in Japan are mainly 2.4 GHz band and 5 GHz band, a dual-band micro antenna that can transmit and receive radio waves of two types of wavelengths is available to cope with these. I need it.
The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a micro antenna dual capable of transmitting and receiving radio waves of two types of wavelengths (frequencies). Contribute to development.

The configuration of the inventive method according to claim 1 (see FIG. 2A) is a method of configuring an exciter for forming a dual-band microantenna.
A feeding end of an exciter body (1) made of a flat plate-like conductive material having a length is connected to a high-frequency circuit (2);
One surface of the exciter body (the lower surface in FIG. 2 (A)) is in contact with the antenna-side dielectric (3A), and the other surface is divided into two areas in a thoughtful manner.
An area close to the feed end (left half in the figure) is brought into contact with the ground-side dielectric (3G), so that the exciter body (1) is connected to the antenna-side dielectric (3A) and the ground-side dielectric in this area. (3G),
The area (right half) far from the feeding end of the other surface (lower surface) is exposed to air,
This exciter body (1) is made to resonate at a ¼ wavelength for high frequency radio waves (see symbol FH) and to be resonated at a ¼ wavelength (reference symbol FL) for low frequency radio waves. Features.

According to the above-described method of the present invention of claim 1, using the exciter body having a very simple structure (flat plate shape), two kinds of resonance states are revealed by involving a dielectric,
One exciter body can handle radio waves of two types of wavelengths.
As a result, the present invention can be applied to reduce the number of components of the micro antenna dual, thereby reducing the size and weight of the micro antenna dual.

The configuration of the inventive method according to claim 2 (see FIG. 4) is a method for configuring an exciter for forming a dual-band microantenna.
A feeding end of an exciter body (1) made of a flat plate-like conductive material having a length is connected to a high-frequency circuit (2);
The exciter body is divided into three zones in the lengthwise direction,
In the area close to the feeding end, one side of the exciter body is brought into contact with the ground-side dielectric (3G), and the other side is exposed to air.
In the area on the opposite side of the feeding end, the one surface of the exciter body is exposed to air, and the other surface is in contact with the tip-side dielectric (3T),
The intermediate area between the above two areas is obtained by sandwiching the exciter body between the ground side dielectric (3G) and the tip side dielectric (3T),
The exciter body (1) is made to resonate at a ¼ wavelength with respect to a high-frequency radio wave and to be resonated at a ¼ wavelength with respect to a low-frequency radio wave.

Also according to the method of the invention of claim 2 described above, as in claim 1, two types of resonance states are obtained by using a very simple structure (flat plate) exciter body and involving a dielectric. Let
One exciter body can handle radio waves of two types of wavelengths.
As a result, the present invention can be applied to reduce the number of components of the micro antenna dual, thereby reducing the size and weight of the micro antenna dual.

The configuration of the invention method according to claim 3 (see FIG. 6A) is a method of configuring an exciter or a parasitic element that is a component of a dual-band micro antenna.
While connecting the feeding end of the exciter body (1) made of a flat conductive material to the high frequency circuit (2),
Most of one surface of this exciter body is covered with “variable dielectric (9) exhibiting a high dielectric constant for low frequency radio waves and a high dielectric constant for low frequency radio waves”. ,
By exposing most of the surface opposite the one surface to air,
It is characterized by resonating at both low and high frequencies.

According to the method of the invention of claim 3 described above, two types of resonance can be achieved using an exciter body having a very simple structure (flat plate) by involving a special dielectric that changes the dielectric constant according to the frequency. Make the state appear,
One exciter body can handle radio waves of two types of wavelengths.
As a result, the present invention can be applied to reduce the number of component parts of the micro antenna dual, thereby reducing the size and weight of the micro antenna dual.

The configuration of the inventive method according to claim 4 (see FIG. 3B) is a method of forming a parasitic element for forming a dual-band microantenna.
One end of the parasitic element body (5) made of a flat plate-like conductive material having a length is grounded,
While making one side of the parasitic element main body contact the element side dielectric (6E), the other side is divided into two areas thoughtfully,
The ground-side area is in contact with the ground-side dielectric (6G), and in this area, the parasitic element body (5) is sandwiched between the element-side dielectric (6E) and the ground-side dielectric (6G). Turn on
The area far from the feeding end of the other surface is exposed to air,
The parasitic element body (5) is made to resonate with a ¼ wavelength with respect to a high frequency radio wave and resonate with a ¼ wavelength with respect to a low frequency radio wave.

According to the method of the invention of claim 4 described above, a parasitic element body having a very simple structure (flat plate shape) is used, and two resonance states are revealed by partially involving a dielectric, The parasitic element main body can cope with radio waves of two types of wavelengths.
In other words, one parasitic element is sufficient instead of the two antenna elements required for the dual antenna in the prior art.
As a result, the present invention can be applied to reduce the number of components of the micro antenna dual, thereby reducing the size and weight of the micro antenna dual.

The configuration of the inventive method according to claim 5 (see FIG. 5C) is a method of forming a parasitic element for forming a dual-band microantenna.
One end of the parasitic element body (5) made of a flat plate-like conductive material having a length is grounded,
The parasitic element body is divided into three zones in a thoughtful manner in the length direction,
In the area close to the ground end, one surface of the parasitic element body is brought into contact with the ground-side dielectric (3G), and the other surface is exposed to air.
In the area on the opposite side of the grounding end, the one surface of the parasitic element body is exposed to air, and the other surface is in contact with the tip-side dielectric (3T).
The intermediate area between the two areas is obtained by sandwiching the parasitic element body between the ground side dielectric (3G) and the tip side dielectric (3T),
The parasitic element body (5) is made to resonate with a ¼ wavelength with respect to a high frequency radio wave and resonate with a ¼ wavelength with respect to a low frequency radio wave.

Also according to the method of the invention of claim 5 described above, as in claim 4, the parasitic element main body having a very simple structure (flat plate shape) is used, and the dielectric is partially involved in two ways. Resonance state appears and one parasitic element main body can cope with radio waves of two types of wavelengths.
In other words, one parasitic element is sufficient instead of the two antenna elements required for the dual antenna in the prior art.
As a result, the present invention can be applied to reduce the number of components of the micro antenna dual, thereby reducing the size and weight of the micro antenna dual.

The configuration of the inventive device according to claim 6 (see FIG. 2B) is a dual-band microantenna that transmits and receives a radio wave with a high frequency FH and a radio wave with a low frequency FL.
A flat exciter body (1) having one end connected to the high-frequency circuit (2);
An antenna-side dielectric (3A) covering one surface of the exciter body;
A ground-side dielectric (3G) covering an area near the feeding point on the other surface of the exciter body;
A high-frequency parasitic element (4H) having one end grounded and resonating with a radio wave of frequency FH;
A low frequency parasitic element (4L) having one end grounded and resonating with a radio wave of frequency FL;
A coupling capacitance c is formed between the open end of the exciter body (1) and the open end of the high frequency parasitic element (4H),
A coupling capacitance c is formed between the open end of the exciter body (1) and the open end of the low frequency parasitic element (4L).

According to the above-described inventive device of claim 6, since one exciter body can resonate with radio waves of two types of high and low wavelengths,
High frequency radio waves are transmitted and received by the single exciter body and the high frequency parasitic element,
In addition, the single exciter body can also be used as a dual antenna by transmitting and receiving a low-frequency radio wave using this and a low-frequency parasitic element.
Instead of the two exciters required in the prior art dual antenna, “one exciter body partially involving a dielectric” is sufficient, so that the entire antenna device can be reduced in size and weight. it can.

The configuration of the inventive device according to claim 7 (see FIG. 5 (A)) is a dual-band micro antenna that transmits and receives a radio wave with a high frequency FH and a radio wave with a low frequency FL.
A flat exciter body (1) having one end connected to the high-frequency circuit (2);
A dielectric (3G) covering a part of the surface on one side of the exciter body;
A dielectric (3T) covering a part of the other side surface of the exciter body;
A high-frequency parasitic element (4H) having one end grounded and resonating with a radio wave of frequency FH;
A low frequency parasitic element (4L) having one end grounded and resonating with a radio wave of frequency FL;
A coupling capacitance c is formed between the open end of the exciter body (1) and the open end of the high frequency parasitic element (4H),
A coupling capacitance c is formed between the open end of the exciter body (1) and the open end of the low frequency parasitic element (4L).

Also according to the invention device of the seventh aspect described above, similarly to the sixth aspect, the single exciter body can resonate with radio waves of two types of high and low wavelengths.
High frequency radio waves are transmitted and received by the single exciter body and the high frequency parasitic element,
In addition, the single exciter body can also be used as a dual antenna by transmitting and receiving a low-frequency radio wave using this and a low-frequency parasitic element.
In this way, “one exciter main body partially involving a dielectric” is sufficient, so that the entire antenna device can be reduced in size and weight.

The configuration of the inventive apparatus apparatus according to claim 8 (see FIG. 5B) is a dual-band micro antenna that transmits and receives high frequency FH radio waves and low frequency FL radio waves.
A flat exciter body (1) having one end connected to the high-frequency circuit (2);
A dielectric (3G) covering a part of the surface on one side of the exciter body;
A dielectric (3T) covering a part of the other side surface of the exciter body;
A flat parasitic element body (5) having one end grounded,
A dielectric (6E) covering at least part of the surface on one side of the parasitic element body;
A dielectric (6G) covering a part of the other surface of the parasitic element body,
In addition, a coupling capacitance c is formed between the open end of the exciter body (1) and the open end of the parasitic element body (5).

According to the invention device of the eighth aspect described above, by using one exciter body and one parasitic element body having a very simple structure (flat plate shape), each of which is partially involved with a dielectric. It can function as a dual antenna by resonating with high frequency radio waves and low frequency radio waves.
By applying this claim 8, one exciter main body and one parasitic element main body are sufficient, so the number of components of the dual antenna is reduced, which is effective in reducing the size and weight and reducing the cost. .

The configuration of the inventive device according to claim 9 (see FIG. 1) is a dual-band micro antenna that transmits and receives a radio wave with a high frequency FH and a radio wave with a low frequency FL.
A dielectric block (7) having a rectangular parallelepiped or a shape similar to a rectangular parallelepiped,
A bent plate-like exciter body (1) disposed in contact with the bottom, side, and top surfaces of the dielectric block, and FIG. 1 (B) for distinguishing the top, bottom, side, and end surfaces. reference)
A parasitic element (4H) which is arranged in contact with the end face and top face of the dielectric block and which resonates with a radio wave having a high frequency FH;
It consists of a parasitic element (4L) that resonates with a radio wave of a low frequency FL, which is a bent flat plate arranged in contact with the side surface and the top surface of the dielectric block,
The parasitic element (4H) that resonates with a high frequency radio wave is grounded near the bottom of the “part in contact with the end face or side face of the dielectric block”,
Near the bottom of the parasitic element (4L) that resonates with the low-frequency radio wave (the part that is in contact with the side or end face of the dielectric block) is grounded,
“The part in contact with the top surface of the dielectric block” of the parasitic element (4H) that resonates with high frequency radio waves, and “the part in contact with the top surface of the dielectric block” of the exciter body (1) The electrostatic coupling capacitance c is configured between
“The part in contact with the top surface of the dielectric block” of the parasitic element (4L) that resonates with the low frequency radio wave, and “the part in contact with the top surface of the dielectric block” of the exciter body (1) An electrostatic coupling capacitance c is formed between the two.

According to the apparatus of the ninth aspect described above, using one dielectric block, the “partial involvement of the dielectric” with respect to one exciter body is revealed, and the one exciter body It is possible to resonate with radio waves of two types of high and low frequencies.
As a result, an antenna device in which one dielectric block mechanically supports one exciter body and two parasitic elements and fixes the relative positions of these antenna elements together. Form.
As described above, since the dielectric block supports the exciter body and the parasitic element, even if these antenna elements themselves are made of thin plates, mechanical strength can be obtained and they are practically used.
Further, it is possible to easily form the dielectric block from a substrate material and to configure the exciter body and the parasitic element with a conductive pattern. With this configuration, it is possible to contribute to the electronic equipment industry by supplying a high-quality and uniform product at low cost, which is suitable for industrial mass production.

The configuration of the invention device according to claim 10 (see FIG. 8) is a dual-band micro antenna that transmits and receives high frequency FH radio waves and low frequency FL radio waves.
An exciter body (1) having a rectangular parallelepiped shape or a rectangular parallelepiped-like shape and having a dielectric block (7) that is half-embedded in the dielectric block;
A parasitic plate element body (5) having a folded flat plate half-embedded in a dielectric block;
The exciter body (1) includes a portion (1S) whose one surface is in contact with the dielectric block and the other surface is exposed to air, and a portion (1W) whose both surfaces are in contact with the dielectric block. Consists of
The parasitic element body (5) has a part (5S) whose one surface is in contact with the dielectric block and the other surface is exposed to air, and a part (5W) whose both surfaces are in contact with the dielectric block. Consists of
And, one end of the exciter body (1) and one end of the parasitic element body (5) are opposed to each other to form an electrostatic coupling capacitance c.
The other end of the exciter body (1) can be connected to the high-frequency circuit (2), and the other end of the parasitic element body (5) can be grounded. .

Also according to the inventive device of claim 10 described above, the “partial involvement of dielectric” with respect to one exciter body is manifested using one dielectric block as in the case of claim 9, The single exciter body can be made to resonate with high and low frequency radio waves,
More than in the ninth aspect, it is easy to make a complicated part of the state of involvement of the dielectric with respect to each of the exciter body and the parasitic element. That is, a part of these antenna elements is in contact with the dielectric. At the same time, it is easy to sandwich the other part in the dielectric, and by complicating the involvement of the dielectric, there is a large degree of design freedom to deal with radio waves of two given frequencies. .
Furthermore, one dielectric block mechanically supports one exciter body and two passive elements, and forms a combined antenna device by fixing the relative positions of these antenna elements. To do.
As described above, since the dielectric block supports the exciter body and the parasitic element, even if these antenna elements themselves are made of thin plates, mechanical strength can be obtained and they are practically used.
Further, it is possible to easily form the dielectric block from a substrate material and to configure the exciter body and the parasitic element with a conductive pattern. With this configuration, it is possible to contribute to the electronic equipment industry by supplying a high-quality and uniform product at low cost, which is suitable for industrial mass production.

The structure of the inventive device according to claim 11 is as follows. (See FIG. 9) The micro antenna dual according to claim 9 or the dielectric block (7) of the micro antenna dual according to claim 10 has a mounting plate (12). As it is installed,
A coaxial cable (11) is connected to the micro-antenna dual exciter body (1) to form one independent assembly component.

According to the inventive device of the invention device of the eleventh aspect described above, the microantenna dual according to the present invention becomes one assembled assembly part and is easy to handle.
That is, since the mounting plate is provided, the work of mounting this on the circuit board of the wireless device is quickly and easily performed.
And since the coaxial cable is provided, the operation | work which electrically connects this antenna assembly with the high frequency circuit of a communication apparatus is easy.
In particular, since one assembly is formed in this way, it has market distribution as a product, and the antenna industry is divided from the manufacture of communication equipment to increase its independence.
As a result, communication device manufacturers can receive a high-quality, low-cost micro-antenna dual supply from a manufacturer specializing in antennas, and the development of the communication device industry is promoted.

According to the method of the invention of claim 1, two types of resonance states are made to appear by using a very simple structure (flat plate) exciter body and involving a dielectric,
One exciter body can handle radio waves of two types of wavelengths.
As a result, the present invention can be applied to reduce the number of components of the micro antenna dual, thereby reducing the size and weight of the micro antenna dual.

Also according to the method of the invention of claim 2, as in the case of claim 1, using an exciter body having a very simple structure (flat plate shape), two kinds of resonance states are revealed by involving a dielectric,
One exciter body can handle radio waves of two types of wavelengths.
As a result, the present invention can be applied to reduce the number of components of the micro antenna dual, thereby reducing the size and weight of the micro antenna dual.

According to the method of the invention of claim 3, by involving a special dielectric that changes the dielectric constant according to the frequency, two types of resonance states can be obtained using an exciter body having a very simple structure (flat plate shape). Let
One exciter body can handle radio waves of two types of wavelengths.
As a result, the present invention can be applied to reduce the number of component parts of the micro antenna dual, thereby reducing the size and weight of the micro antenna dual.

According to the method of the invention of claim 4, a parasitic element body having a very simple structure (flat plate shape) is used, and two kinds of resonance states are made to appear by partially involving a dielectric, so that one parasitic element The main body can handle radio waves of two types of wavelengths.
In other words, one parasitic element is sufficient instead of the two antenna elements required for the dual antenna in the prior art.
As a result, the present invention can be applied to reduce the number of components of the micro antenna dual, thereby reducing the size and weight of the micro antenna dual.

According to the method of the invention of claim 5, as in the case of claim 4, a parasitic element body having a very simple structure (flat plate shape) is used, and two kinds of resonance states are obtained by partially involving a dielectric. It is possible to deal with radio waves of two types of wavelengths by one parasitic element main body.
In other words, one parasitic element is sufficient instead of the two antenna elements required for the dual antenna in the prior art.
As a result, the present invention can be applied to reduce the number of components of the micro antenna dual, thereby reducing the size and weight of the micro antenna dual.

According to the invention device of claim 6, since one exciter body can resonate with radio waves of two types of high and low wavelengths,
High frequency radio waves are transmitted and received by the single exciter body and the high frequency parasitic element,
In addition, the single exciter body can also be used as a dual antenna by transmitting and receiving a low-frequency radio wave using this and a low-frequency parasitic element.
Instead of the two exciters required in the prior art dual antenna, “one exciter body partially involving a dielectric” is sufficient, so that the entire antenna device can be reduced in size and weight. it can.

Even with the inventive device of claim 7, as in claim 6, the single exciter body can resonate with radio waves of two types of high and low wavelengths.
High frequency radio waves are transmitted and received by the single exciter body and the high frequency parasitic element,
In addition, the single exciter body can also be used as a dual antenna by transmitting and receiving a low-frequency radio wave using this and a low-frequency parasitic element.
Instead of the two exciters required in the prior art dual antenna, “one exciter body partially involving a dielectric” is sufficient, so that the entire antenna device can be reduced in size and weight. it can.

According to the invention apparatus of claim 8, a high frequency is obtained by using one exciter body and one parasitic element main body having a very simple structure (flat plate shape) and partially involving a dielectric respectively. It can function as a dual antenna by resonating with radio waves and low frequency radio waves.
In the dual antenna according to the prior art, two antenna elements and one exciter are required. By applying this claim 8, one exciter body and one parasitic element are used. Since the main body is sufficient, the number of components of the dual antenna is reduced, which is effective in reducing the size and weight and reducing the cost.

According to the invention apparatus of claim 9, by using one dielectric block, the “partial involvement of the dielectric” with respect to one exciter main body is revealed, and the one exciter main body is made to be high and low. It can resonate with radio waves of two types of frequencies.
As a result, an antenna device in which one dielectric block mechanically supports one exciter body and two parasitic elements and fixes the relative positions of these antenna elements together. Form.
As described above, since the dielectric block supports the exciter body and the parasitic element, even if these antenna elements themselves are made of thin plates, mechanical strength can be obtained and they are practically used.
Further, it is possible to easily form the dielectric block from a substrate material and to configure the exciter body and the parasitic element with a conductive pattern. With this configuration, it is possible to contribute to the electronic equipment industry by supplying a high-quality and uniform product at low cost, which is suitable for industrial mass production.

According to the invention device of claim 10 as well, in the same way as in claim 9, one dielectric block is used to reveal "partial involvement of dielectric" for one exciter body, The exciter body can resonate with radio waves of two types of high and low frequencies.
More than in the ninth aspect, it is easy to make a complicated part of the state of involvement of the dielectric with respect to each of the exciter body and the parasitic element. That is, a part of these antenna elements is in contact with the dielectric. At the same time, it is easy to sandwich the other part in the dielectric, and by complicating the involvement of the dielectric, there is a large degree of design freedom to deal with radio waves of two given frequencies. .
Furthermore, one dielectric block mechanically supports one exciter body and two passive elements, and forms a combined antenna device by fixing the relative positions of these antenna elements. To do.
As described above, since the dielectric block supports the exciter body and the parasitic element, even if these antenna elements themselves are made of thin plates, mechanical strength can be obtained and they are practically used.
Further, it is possible to easily form the dielectric block from a substrate material and to configure the exciter body and the parasitic element with a conductive pattern. With this configuration, it is possible to contribute to the electronic equipment industry by supplying a high-quality and uniform product at low cost, which is suitable for industrial mass production.

According to the eleventh aspect of the present invention, the microantenna dual according to the present invention becomes one assembled assembly part, which is easy to handle.
That is, since the mounting plate is provided, the work of mounting this on the circuit board of the wireless device is quickly and easily performed.
And since the coaxial cable is provided, the operation | work which electrically connects this antenna assembly with the high frequency circuit of a communication apparatus is easy.
In particular, since one assembly is formed in this way, the product has market distribution as a product, and the antenna industry is divided from communication device manufacturing to increase its independence.
As a result, communication device manufacturers can receive a high-quality, low-cost micro-antenna dual supply from a manufacturer specializing in antennas, and the development of the communication device industry is promoted.

The inventor studied the interaction between the antenna element and the dielectric, and discovered three principles described below. And (B) is a schematic diagram of a dual-band antenna device using an exciter constructed by applying the first principle. Corresponds to the inventive device.
Reference numeral 1 indicates an exciter body formed of a thin plate of a conductive material. FIG. 2 shows the first principle, and FIG. 2A is a schematic cross-sectional front view showing a standing wave of radio waves having two types of frequencies. The substantial shape will be described later with reference to FIG.
(See FIG. 2 (A)) When the exciter body 1 is isolated in the air, its mechanical length and electrical length are substantially equal.
Similarly, an exciter body located in a substance having a dielectric constant of 1 has substantially the same mechanical length and electrical length. In the present invention, air includes a substance having a dielectric constant of approximately 1 (for example, being exposed to air means being in contact with a substance having a dielectric constant of 1).

One end of the exciter body 1 is connected to the output end of the high-frequency circuit 2. In the example of FIG. 2A, the left end of the exciter body is an input end, and the right end is an open end.
Almost all of one surface (lower surface in the figure) of the exciter body 1 is covered with the dielectric 3A.
In the present invention, the antenna element (for example, the exciter body or the parasitic element) is “abutting” on the dielectric and “covering with the dielectric”.
This dielectric 3A is named an antenna-side dielectric from the relationship with the structure of FIG. 1 described later. Similarly, the dielectric 3G is named a ground side dielectric.
As described above, the entire surface of one side (lower side) of the exciter body 1 is covered with the antenna-side dielectric 3A, but the opposite side (upper side) of the exciter body 1 is not covered with the ground-side dielectric 3G. The half near the input end is covered and the half near the open end is exposed to air (as described above, it may be covered with a material having a dielectric constant of 1).

According to one theory, when an elongated flat plate-like member is surrounded by a dielectric having a dielectric constant ε, its electrical length is reduced in inverse proportion to the square root of the dielectric constant ε, compared to the mechanical length. Is done.
In addition, when only one surface is in contact with a dielectric having a dielectric constant ε and the other surface is exposed to air, the electrical length is inversely proportional to the square root of (ε + 1) / 2 compared to the mechanical length. And shortened.
As shown in FIG. 2 (A), when both sides of the input end side are sandwiched with dielectrics, and about half of the open end side is covered only with one side of the dielectric,
When a low frequency radio wave is input, a ¼ wavelength standing wave rides as indicated by symbol FL, and when a high frequency radio wave is input, a ¾ wavelength standing wave occurs as indicated by symbol FH. get on.
Thus, one exciter body 1 exhibits dual characteristics.

The exciter body 1 shown in FIG. 2 (B) is the same member as in FIG. 2 (A) described above.
The dielectric 3A and the dielectric 3G are the same as in FIG.
A “high-frequency parasitic element 4H” that resonates with a quarter wavelength of a high-frequency FH radio wave and a “low-frequency parasitic element 4L” that resonates with a quarter-wave wavelength of a low-frequency FL radio wave. While providing
An electrostatic coupling capacitance c is formed between the open end of each parasitic element and the open end of the exciter body 1.
Thereby, a dual band antenna can be comprised using one exciter main body.

FIG. 3 is shown to explain an embodiment different from FIG. 2 described above, and FIG. 3 (A) is a reproduction of FIG. 2 (B) for comparison, FIG. 3 (B). Is a schematic view and corresponds to the inventive device of claim 8.
The exciter body 1 in FIG. 3A is obtained by resonating one antenna element with two types of frequencies based on the first principle described above with reference to FIG. .
If one exciter body can be operated dually according to the first principle, the same principle can be used to operate one passive element dually. In FIG. 3B, one side of the parasitic element body 5 is covered with the element side dielectric 6E, and a part of the other side is covered with the ground side dielectric 6G.
As a result, as can be understood from the figure, similar components are arranged symmetrically, one of which is viewed as one end connected to the high-frequency circuit 2 and the other as one end grounded. Can do. The open end of the exciter body 1 and the open end of the parasitic element body 5 were opposed to each other to form the electrostatic coupling capacitance c, and a micro antenna dual was obtained.
The symbol Im added to FIG. 3B will be described in detail later in comparison with FIG.

4A and 4B are views for explaining the second principle, in which FIG. 4A is a schematic view illustrating a basic structure, FIG. 4B is a cross-sectional view actually drawn, and FIG. 4C is a cross-sectional front view. Is a diagram in which standing waves of two types of frequencies are appended, and corresponds to claim 5.
(See FIG. 4A) The exciter body 1 is a conductive flat plate member. One end thereof is connected to the high-frequency circuit 2.
About half of the surface on one side (lower surface in the figure) of the exciter body 1 is covered with the ground side dielectric 3G, and about half of the open side of this one surface is exposed to air ( As defined above, it may be in contact with a substance having a dielectric constant of approximately 1).
Then, about half of the other surface (upper surface in the figure) of the exciter body 1 on the power feeding end side is exposed to air, and about half of the other surface on the open end side is covered with the tip-side dielectric 3T. is there.
The vicinity of the central portion of the exciter body 1 is sandwiched between the ground-side dielectric 3G and the tip-side dielectric 3T.

  A structure in which one side of a part of the exciter body 1 is covered with a dielectric and a part is sandwiched between the dielectrics, specifically, as shown in FIG. It is obtained by being embedded halfway in the dielectric block 7 (which will be described in detail later with reference to FIG. 8).

(Refer to FIG. 4C) As described above, the exciter body 1 is affected by the dielectric material in contact with the exciter body 1, but when the contact method is not uniform, “the mechanical length of the exciter body” The electrical length shortening rate relative to
A 1/4 wave standing wave FL of a low frequency radio wave and a 3/4 wavelength of a standing wave FH of a high frequency radio wave (in this way, one antenna element has two types of wavelengths). The phenomenon of resonating with radio waves is the second principle of the present invention).

FIG. 5 shows an embodiment to which the second principle of the present invention is applied. FIG. 5A is a schematic diagram of an embodiment in which this second principle is used alone, and corresponds to claim 7. FIG. Is a schematic diagram of an embodiment using both the second principle and the “first principle shown in FIG. 2”, and (C) is a schematic diagram of an embodiment using the second principle double. FIG.
The exciter body 1, the ground side dielectric 3G, and the tip side dielectric 3T shown in FIG. 5A are the same members as the components depicted in FIG. 4A. That is, it is a dual exciter to which the second principle is applied. A passive element 4L having a low frequency and a parasitic element 4H having a high frequency are arranged facing the open end of the exciter body 1 to form an electrostatic coupling capacitance c. Thereby, a micro antenna dual is configured,

The component part composed of the exciter body 1, the ground side dielectric 3G, and the tip side dielectric 3T shown in FIG. 5B can be obtained by simply bending the upper end of the exciter in FIG. In general, they are similar components. The members arranged symmetrically are the same members as the parasitic element body 5, the element-side dielectric 6E, and the ground-side dielectric 6G in FIG. 3B described above. That is, it is a dual parasitic element configured by applying the first principle.
If comprised in this way, a microantenna dual will be comprised by two small assembly components.

The left half of FIG. 5C is the same as the left half of FIG.
The right half of FIG. 5C is named the parasitic element main body 5, the ground side dielectric 3G, and the tip side dielectric 3T based on the function of each component, but the left half of FIG. The same members are arranged symmetrically.
That is, the first principle and the second principle described above can be applied to both the exciter and the parasitic element.
There are two types of exciters: an exciter based on the first principle and an exciter based on the second principle.
There are two types of parasitic elements, a parasitic element based on the first principle and a parasitic element based on the second principle.
By these combinations, 2 × 2 = 4 types of microantenna duals can be configured.

  In the embodiment of FIG. 3 (B) described above, a parasitic element according to the second principle can be obtained by removing the dielectric part denoted by reference symbol Im. A micro antenna dual can also be obtained by combining the parasitic element according to the second principle with the “exciter according to the first principle” shown in the left half of FIG.

FIG. 6 is a view for explaining the third principle, and FIG. 6A is a schematic cross-sectional view of an exciter in which standing waves of radio waves of two kinds of wavelengths are added, and corresponds to claim 3. To do. (B) is a schematic diagram of a dual antenna using this exciter.
When a dielectric is placed in radio waves, the dielectric constant changes depending on the frequency.
For example, when glass epoxy FR-4 is measured at a frequency of 1 MHz, the dielectric constant is about 4.7, but when measured at a frequency of 1 GHz, the dielectric constant is about 4.1.
Such a phenomenon has been known to those skilled in the art, but no technical creation has been made yet to actively utilize this phenomenon to obtain a new effect.

As shown in FIG. 6A, the inventor makes one surface of the exciter body 1 in contact with air and covers the other surface with the “variable dielectric material 9 whose dielectric constant changes depending on the frequency as described above”. The electromagnetic behavior was observed.
The variable dielectric 9 had a dielectric constant of 3.9 at 2.4 GHz and 2.3 at 5.2 GHz.
When a high frequency of 2.4 GHz is input from the high frequency circuit 2, a low frequency standing wave FL is formed, and when a high frequency of 5.2 GHz is input, a high frequency standing wave FH is formed. That is, one exciter body 1 showed dual performance.

Therefore, as shown in FIG. 6B, the present inventor connects the “exciter body 1 having one side covered with the variable dielectric 9” to the high frequency circuit 2 as in FIG. A parasitic element 4H having a low frequency and a parasitic element 4L having a low frequency are arranged and coupled by a capacitance c. Thereby, a micro antenna dual (ultra-small two-frequency antenna) was configured.
Since the simplest dual exciter as shown in FIG. 6A is obtained by the third principle of the present invention, this is referred to as “dual parasitic element created by applying the first principle”. The micro antenna dual can also be configured in combination with “a dual parasitic element created by applying the second principle”.
In addition, a dual parasitic element can be configured by applying the third principle. A dual performance antenna with an extremely simple structure can be obtained by a combination of two constituent members, one dual exciter and one passive element.

The first to third principles and the typical configuration of the dual micro antenna configured using these principles have been described above with reference to FIGS. Next, a substantial embodiment of the micro antenna dual will be described.
FIG. 1 shows an embodiment of the present invention, which embodies the configurations of claims 1, 6, and 9, and (A) is a perspective view schematically drawn. 10 is a perspective view showing the names of the surfaces of the dielectric block.
A dielectric block 7 having a rectangular parallelepiped (or a shape similar to a rectangular parallelepiped) is formed. For convenience of explanation
As shown in FIG. 1B, names of the top surface, the bottom surface, the side surface, and the end surface are determined. The XY plane is the circuit board surface of the wireless communication device, and Z is the “direction in which the antenna protrudes from the wireless communication device”.

The exciter body 1 is a bent flat plate-like conductive member, and is in contact with the bottom surface, the side surface, and the top surface of the dielectric block 7. If it is such a structure, it is a dual exciter body (FIG. 6A) to which the third principle is applied. When the dielectric block 7 is placed on the substrate 8, the bottom of the exciter body 1 is sandwiched between the dielectric block 7 and the substrate 8, and a dual exciter to which the first principle is applied (FIG. 2 ( A)).
In the embodiment of FIG. 1, a dual micro-antenna is constituted by a single exciter body 1 and two parasitic elements. Reference numeral 4H denotes a high-frequency parasitic element,
Reference numeral 4L denotes a low-frequency parasitic element.

7 is a chart for explaining the tuning characteristics of the microantenna dual according to the embodiment shown in FIG. 1, wherein (A) is a VSWR near 2.4 GHz, and (B) is near 5.2 GHz. VSWR.
It can be seen that the micro antenna (FIG. 1) of the embodiment has excellent tuning characteristics both at 2.4 GHz and at 5.2 GHz.

FIG. 8 is a schematic perspective view illustrating a substantial configuration in an embodiment different from that of FIG. 1 described above, which corresponds to claim 10 and is configured using claims 2 and 5.
Reference numeral 7 denotes a dielectric block.
The bent exciter main body 1 includes a portion 1S that contacts the top surface of the dielectric block 7, a portion 1W that is embedded in the dielectric block 7, and a portion 1S ′ that contacts the end surface of the dielectric block 7. It is made up. When this is compared with FIG. 4A, it is understood that this is a dual exciter utilizing the second principle.

The parasitic element 5 is similarly manufactured using the third principle, and includes a portion 5S in contact with the top surface, an embedded portion 5W, and a portion 5S ′ in contact with the end surface. Since it is such a structure, it turns out that it is a dual parasitic element.
In short, the embodiment of FIG. 8 is a dual micro-antenna comprising a combination of a dual exciter body 1 and a dual parasitic element body 5.
In this way, an excellent practical effect that radio waves of two kinds of wavelengths can be transmitted and received by two extremely simple antenna elements (exciter and parasitic element) can be obtained.

FIG. 9 is an external perspective view illustrating a state in which the micro antenna dual according to the present invention is configured as one product, and corresponds to claim 11.
The dielectric block 7, the exciter body 1, the low-frequency parasitic element 4L, and the high-frequency parasitic element 4H are the same components as in the embodiment shown in FIG.
A mounting plate 12 is fixed to the dielectric block 7 and a coaxial cable 11 is connected to the exciter body 1.
If the assembly as described above is configured, it can be quickly and easily attached to the substrate 8 using the mounting screw 13 and can be quickly and easily connected to the high-frequency circuit of the radio using the coaxial cable 11. can do.

Reference numeral 10 denotes a ground plate formed on the substrate 8, and 10a denotes a notch portion of the ground plate.
Such an assembly has market distribution as an independent product, and greatly contributes to the division and development of antenna manufacturers.
In the present invention, an independent assembly component refers to an assembly that is constructed so that a plurality of structural members are mechanically coupled and can function electrically to achieve a certain purpose.
On the other hand, wireless device manufacturers benefit from being able to receive a supply of high-quality antenna assemblies manufactured at antenna factories.

1 shows an embodiment of the present invention, and is a specific embodiment of the structure of claims 1, 6, and 9, and (A) is a perspective view schematically drawn and corresponds to claim 10. (B) is a perspective view showing names of surfaces of the dielectric block. The 1st principle in this invention is shown, (A) is the figure which attached the standing wave of the electromagnetic wave of two types of frequency to the typical cross section front view, Comprising: (B) ) Is a schematic diagram of a dual-band antenna device using an exciter constructed by applying the first principle, and corresponds to the inventive device of claim 6. FIG. 2 is a view for explaining an embodiment different from FIG. 2 described above, in which (A) is a reproduction of FIG. 2 (B) for comparison, and (B) is a schematic view. It corresponds to the invention device of 8. 2A and 2B are views for explaining a second principle of the present invention, in which FIG. 1A is a schematic view illustrating a basic structure, FIG. 1B is a cross-sectional view actually drawn, and FIG. Is a diagram in which standing waves of two types of frequencies are appended, and corresponds to claim 5. An embodiment to which the second principle of the present invention is applied is shown. (A) is a schematic diagram of an embodiment in which this second principle is used alone, corresponding to claim 7, and (B) is the first principle. 2 is a schematic diagram of an embodiment using both the principle 2 and the “first principle shown in FIG. 2”, and FIG. 2C is a schematic diagram of an embodiment in which the second principle is used double. . FIG. 2 is a diagram for explaining a third principle of the present invention, and FIG. 3A is a schematic cross-sectional view of an exciter in which standing waves of radio waves of two types of wavelengths are added, and corresponds to claim 3. (B) is a schematic diagram of a dual antenna using this exciter. FIG. 4 is a chart for explaining tuning characteristics of the microantenna dual according to the embodiment shown in FIG. 1, wherein (A) is a VSWR near 2.4 GHz, and (B) is a VSWR near 5.2 GHz. . FIG. 10 is a schematic perspective view illustrating a substantial configuration in an embodiment different from FIG. 1 described above, corresponds to claim 10, and is configured using claims 2 and 5. FIG. 14 is an external perspective view illustrating a state in which the micro antenna dual according to the present invention is configured as one product, and corresponds to claim 11.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Exciter main body 2 ... High frequency circuit 3A ... Antenna side dielectric 3G ... Ground side dielectric 3T ... Tip side dielectric 4H ... High frequency parasitic element 4L ... Low frequency parasitic element 5 ... Parasitic element main body
5S: Single-sided contact area
5W ... Double-sided contact (sandwiched) part
6E element-side dielectric
6G ... Ground side dielectric
7 ... Dielectric block
8 ... Board
9. Variable dielectric
10 ... Ground plate
10a ... notch in the main plate
11 ... Coaxial cable
12 ... Mounting plate
13 ... Mounting screw

Claims (11)

In a method of constructing an exciter for forming a dual-band microantenna,
A feeding end of an exciter body (1) made of a flat plate-like conductive material having a length is connected to a high-frequency circuit (2);
While one side of the exciter body is in contact with the antenna-side dielectric (3A), the other side is thoughtfully divided into two areas,
The area close to the feeding end is brought into contact with the ground-side dielectric (3G), and in this area, the exciter body (1) is sandwiched between the antenna-side dielectric (3A) and the ground-side dielectric (3G). Turn on
The area far from the feeding end of the other surface is exposed to air,
A method of constructing an antenna element, characterized in that the exciter body (1) is resonated at a quarter wavelength with respect to a high frequency radio wave and at a quarter wavelength with respect to a low frequency radio wave. . In a method of constructing an exciter for forming a dual-band microantenna,
A feeding end of an exciter body (1) made of a flat plate-like conductive material having a length is connected to a high-frequency circuit (2);
The exciter body is divided into three zones in the lengthwise direction,
In the area close to the feeding end, one side of the exciter body is brought into contact with the ground-side dielectric (3G), and the other side is exposed to air.
In the area on the opposite side of the feeding end, the one surface of the exciter body is exposed to air, and the other surface is in contact with the tip-side dielectric (3T),
The intermediate area between the above two areas is obtained by sandwiching the exciter body between the ground side dielectric (3G) and the tip side dielectric (3T),
A method of constructing an antenna element, characterized in that the exciter body (1) is resonated at a quarter wavelength with respect to a high frequency radio wave and at a quarter wavelength with respect to a low frequency radio wave. . In a method of configuring an exciter or parasitic element that is a component of a dual-band microantenna,
While connecting the feeding end of the exciter body (1) made of a flat conductive material to the high frequency circuit (2),
Most of one surface of this exciter body is covered with “variable dielectric (9) exhibiting a high dielectric constant for low frequency radio waves and a high dielectric constant for low frequency radio waves”. ,
By exposing most of the surface opposite the one surface to air,
A method of constructing an antenna element, characterized by resonating at both a low frequency and a high frequency. In a method of constructing a parasitic element for forming a dual-band microantenna,
One end of the parasitic element body (5) made of a flat plate-like conductive material having a length is grounded,
While making one side of the parasitic element main body contact the element side dielectric (6E), the other side is divided into two areas thoughtfully,
The ground-side area is in contact with the ground-side dielectric (6G), and in this area, the parasitic element body (5) is sandwiched between the element-side dielectric (6E) and the ground-side dielectric (6G). Turn on
The area far from the feeding end of the other surface is exposed to air,
The structure of the antenna element is characterized in that the parasitic element body (5) is resonated at a quarter wavelength with respect to a high frequency radio wave and at a quarter wavelength with respect to a low frequency radio wave. Method. In a method of constructing a parasitic element for forming a dual-band microantenna,
One end of the parasitic element body (5) made of a flat plate-like conductive material having a length is grounded,
The parasitic element body is divided into three zones in a thoughtful manner in the length direction,
In the area close to the ground end, one surface of the parasitic element body is brought into contact with the ground-side dielectric (3G), and the other surface is exposed to air.
In the area on the opposite side of the grounding end, the one surface of the parasitic element body is exposed to air, and the other surface is in contact with the tip-side dielectric (3T).
The intermediate area between the two areas is obtained by sandwiching the parasitic element body between the ground side dielectric (3G) and the tip side dielectric (3T),
The structure of the antenna element is characterized in that the parasitic element body (5) is resonated at a quarter wavelength with respect to a high frequency radio wave and at a quarter wavelength with respect to a low frequency radio wave. Method. In a dual-band micro antenna that transmits and receives high frequency FH radio waves and low frequency FL radio waves,
A flat exciter body (1) having one end connected to the high-frequency circuit (2);
An antenna-side dielectric (3A) covering one surface of the exciter body;
A ground-side dielectric (3G) covering an area near the feeding point on the other surface of the exciter body;
A high-frequency parasitic element (4H) having one end grounded and resonating with a radio wave of frequency FH;
A low frequency parasitic element (4L) having one end grounded and resonating with a radio wave of frequency FL;
A coupling capacitance c is formed between the open end of the exciter body (1) and the open end of the high frequency parasitic element (4H),
A micro antenna dual, wherein a coupling capacitance c is formed between an open end of the exciter body (1) and an open end of a low frequency parasitic element (4L). In a dual-band micro antenna that transmits and receives high frequency FH radio waves and low frequency FL radio waves,
A flat exciter body (1) having one end connected to the high-frequency circuit (2);
A dielectric (3G) covering a part of the surface on one side of the exciter body;
A dielectric (3T) covering a part of the other side surface of the exciter body;
A high-frequency parasitic element (4H) having one end grounded and resonating with a radio wave of frequency FH;
A low frequency parasitic element (4L) having one end grounded and resonating with a radio wave of frequency FL;
A coupling capacitance c is formed between the open end of the exciter body (1) and the open end of the high frequency parasitic element (4H),
A micro antenna dual, wherein a coupling capacitance c is formed between an open end of the exciter body (1) and an open end of a low frequency parasitic element (4L). In a dual-band micro antenna that transmits and receives high frequency FH radio waves and low frequency FL radio waves,
A flat exciter body (1) having one end connected to the high-frequency circuit (2);
A dielectric (3G) covering a part of the surface on one side of the exciter body;
A dielectric (3T) covering a part of the other side surface of the exciter body;
A flat parasitic element body (5) having one end grounded,
A dielectric (6E) covering at least part of the surface on one side of the parasitic element body;
A dielectric (6G) covering a part of the other surface of the parasitic element body,
A micro-antenna dual, wherein a coupling capacitance c is formed between the open end of the exciter body (1) and the open end of the parasitic element body (5). In a dual-band micro antenna that transmits and receives high frequency FH radio waves and low frequency FL radio waves,
A dielectric block (7) having a rectangular parallelepiped or a shape similar to a rectangular parallelepiped,
A bent plate-like exciter body (1) disposed in contact with the bottom, side and top surfaces of the dielectric block;
A parasitic element (4H) which is arranged in contact with the end face and top face of the dielectric block and which resonates with a radio wave having a high frequency FH;
It consists of a parasitic element (4L) that resonates with a radio wave of a low frequency FL, which is a bent flat plate arranged in contact with the side surface and the top surface of the dielectric block,
The parasitic element (4H) that resonates with a high frequency radio wave is grounded near the bottom of the “part in contact with the end face or side face of the dielectric block”,
Near the bottom of the parasitic element (4L) that resonates with the low-frequency radio wave (the part that is in contact with the side or end face of the dielectric block) is grounded,
“The part in contact with the top surface of the dielectric block” of the parasitic element (4H) that resonates with high frequency radio waves, and “the part in contact with the top surface of the dielectric block” of the exciter body (1) The electrostatic coupling capacitance c is configured between
“The part in contact with the top surface of the dielectric block” of the parasitic element (4L) that resonates with the low frequency radio wave, and “the part in contact with the top surface of the dielectric block” of the exciter body (1) A micro-antenna dual, characterized in that an electrostatic coupling capacitance c is formed between the two. In a dual-band micro antenna that transmits and receives high frequency FH radio waves and low frequency FL radio waves,
An exciter body (1) having a rectangular parallelepiped shape or a rectangular parallelepiped-like shape and having a dielectric block (7) that is half-embedded in the dielectric block;
A parasitic plate element body (5) having a folded flat plate half-embedded in a dielectric block;
The exciter body (1) has a portion (1S and 1S ′) where one surface is in contact with the dielectric block and the other surface is exposed to air, and a portion (1W) where both surfaces are in contact with the dielectric block. And 1W ′),
The parasitic element body (5) has a part (5S) whose one surface is in contact with the dielectric block and the other surface is exposed to air, and a part (5W) whose both surfaces are in contact with the dielectric block. Consists of
And, one end of the exciter body (1) and one end of the parasitic element body (5) are opposed to each other to form an electrostatic coupling capacitance c.
The other end of the exciter body (1) can be connected to the high-frequency circuit (2), and the other end of the parasitic element body (5) can be grounded. , Micro antenna dual. The mounting plate (12) is attached to the dielectric block (7) of the micro antenna dual according to claim 9 or the micro antenna dual according to claim 10,
A micro antenna dual, characterized in that a coaxial cable (11) is connected to the exciter body (1) of the micro antenna dual to form one independent assembly part.

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