JP3015919U - Compact magnetic loop antenna device for mobile phones - Google Patents

Abstract

(57) [Abstract] [Purpose] To provide a compact magnetic loop antenna device for a mobile phone, which can maintain stable communication in a place where the electric field strength is low. [Structure] A metal foil is applied to the film to form a strip shape, and the antenna parts 2a and 2b are symmetrically formed at both ends.
Is formed by bending. The two folding portions 3a and 4a and the two folding portions 3b and 4b form the tuning capacitors 5a and 5b. Between the antenna parts 2a and 2b, a strip-shaped metal foil feed line 6a,
6b is formed, and coupling circuits 7a and 7b are formed at the left and right ends of these feeders 6a and 6b, which are connected to the antenna portions 2a and 2b. The feed lines 6a and 6b are connected to the antenna units 2a and 2b with the same impedance as the antenna units 2a and 2b by increasing the feed impedance by the coupling circuits 7a and 7b. An adhesive is applied to one surface, and release paper is stuck on the adhesive.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a compact magnetic loop antenna device for a mobile telephone, which is attached to, for example, a mobile telephone and maintains stable communication in a place having a low electric field strength.

[0002]

[Prior art]

 Generally, when using a mobile phone, it is difficult to make a call even in the area where the electric field is low, such as in a valley of a building, in a car, or in a place where the electric field strength is low. It is required to maintain stable calls even in places, and repeater antennas, for example, are used as antenna devices for increasing sensitivity.

However, the repeater antenna exerts its effect only near the place where the repeater antenna is attached.

An external antenna connected to a mobile phone via a power supply line is also known.

However, since the external antenna has a large antenna shape, it is difficult to mount the external antenna on a mobile phone for portable use.

[0006]

[Problems to be solved by the device]

 As described above, the repeater antenna exerts its effect only near the installation location, and the external antenna has a problem that the antenna shape is large and it is difficult to attach it to the mobile phone body.

The present invention has been made in view of the above problems, and is a small size capable of increasing the sensitivity and maintaining a stable call in a place where the electric field strength is low, without modifying the mobile phone. The purpose of the present invention is to provide a compact magnetic loop antenna device for mobile phones.

[0008]

[Means for Solving the Problems]

 The compact magnetic loop antenna device for a mobile phone according to claim 1, wherein two antenna parts having symmetrical shapes and tuning capacitors formed at both ends, and a coupling circuit are formed at both ends, and both ends are connected to the above-mentioned 2 The antenna section and the feeder are connected with the same impedance, and the antenna section and the feeder are formed of a metal foil in a planar shape.

A compact magnetic loop antenna device for a mobile phone according to claim 2 is the compact magnetic loop antenna device for a mobile phone according to claim 1, which is formed by hot stamping a metal foil on a film. .

A compact magnetic loop antenna device for a mobile phone according to claim 3 is the compact magnetic loop antenna device for a mobile phone according to claim 1, which is formed by depositing a metal foil on a film.

A compact magnetic loop antenna device for a mobile phone according to claim 4 is the compact magnetic loop antenna device for a mobile phone according to claim 1, which is formed by metal-plating plastic.

[0012]

[Action]

 In the compact magnetic loop antenna device for a mobile phone according to claim 1, the two antenna parts in which the tuning capacitors are formed and the feeding line which forms the coupling circuit and is connected with the same impedance as the two antenna parts are provided. Since it is made of metal foil in a planar shape, it is a magnetic field detection type, and when a mobile phone is worn on the human body or is used near the human body, the equivalent magnetic dipole is parallel to the human body. Since a tenor is created and the equivalent circuit of the minute loop is an inductance circuit, a tuning capacitor that cancels this inductance is inserted for tuning, and the input impedance is adjusted by a coupling circuit with the same impedance as the two antenna sections. In this case, an image antenna with the same phase can be created, and since it is flat with metal foil, it can be used for mobile phones. Does not cause inconvenience in the compact be wearing.

A compact magnetic loop antenna device for a mobile phone according to claim 2 is the compact magnetic loop antenna device for a mobile phone according to claim 1, which is formed by hot stamping a metal foil on a film. Can be formed.

A compact magnetic loop antenna device for a mobile phone according to claim 3 is the compact magnetic loop antenna device for a mobile phone according to claim 1, which is formed by vapor-depositing a metal foil on the film, and thus is easily formed. it can.

The compact magnetic loop antenna device for a mobile phone according to claim 4 can be easily formed in the compact magnetic loop antenna device for a mobile phone according to claim 1, which is formed by metal-plating plastic. .

[0016]

【Example】

 An embodiment of a compact magnetic loop antenna device for a mobile phone according to the present invention will be described below with reference to the drawings.

In FIG. 1, reference numeral 1 is a compact magnetic loop antenna for mobile telephones, and this compact magnetic loop antenna 1 for mobile telephones is made of a film or plastic and made of gold, silver, copper or aluminum foil with a width of 5 to 7 mm. It is formed like a strip. The mobile telephone compact magnetic loop antenna 1 has antenna parts 2a and 2b formed symmetrically on the left and right sides, and these antenna parts 2a and 2b are circular with a diameter of 80 mm. The bent portions 3a, 4a, 3b, 4b formed by bending are formed at both ends of 2b. The two folded portions 3a, 4a and the two folded portions 3b, 4b form a tuning capacitor. 5a and 5b are formed.

In addition, between these antenna parts 2a and 2b, strip-shaped metal foil feeding lines 6a and 6b having a width of 5 to 7 mm are formed integrally with these antenna parts 2a and 2b, and these feeding lines are formed. Coupling circuits 7a and 7b are formed at both left and right ends connected to the antenna parts 2a and 2b of 6a and 6b.

The feeding lines 6a and 6b are connected to the antenna units 2a and 2b with the same impedance as the antenna units 2a and 2b by increasing the feeding impedance by the coupling circuits 7a and 7b.

Then, an adhesive (not shown) is applied to one surface of the compact magnetic loop antenna 1 for a mobile phone, and a release paper (not shown) is similarly attached on the adhesive.

In use, the release paper is peeled off and attached to the mobile phone 8 as shown in FIG.

The antenna parts 2a and 2b and the power supply lines 6a and 6b are not only flat ones made of metal foil such as gold, silver, copper or aluminum, but also metal foil is hot-stamped on the film, or The same effect can be obtained even if plastic is plated with metal.

Next, the operation of the above embodiment will be described.

The compact magnetic loop antenna 1 for a mobile phone is a magnetic field detection type, and when the mobile phone 8 is attached to the human body or is used near the human body, an equivalent magnetic dipole is parallel to the human body. As you can see, there are image antennas.

As shown in FIG. 3, the equivalent circuit of the minute loop is an inductance circuit in which the minute magnetic loop 11, the equivalent minute dipole 12 and the current I flowing in the minute magnetic loop are formed. Tuning is performed by tuning capacitors 5a and 5b that cancel the inductance component.

Further, since the radiation resistance is extremely low, the input impedance is adjusted by inserting and using an L tap or the like for power feeding.

Further, the minute loop is equivalent to the minute magnetic dipole and is of a magnetic field detecting type.

Furthermore, when the human body is worn or used near the human body, an image loop is formed, and a current having the same phase as that of the actual loop flows, but an electric field detection type dipole antenna has an opposite phase current. The small dipole is an electric field detection type, and an image antenna with an opposite phase can be formed, but in the case of a small loop, an image antenna with the same phase can be formed. As described above, in the case of the antenna of the mobile phone 8 which is attached to the human body or used near the human body, the influence (image) cannot be escaped, but the magnetic field detection type is effectively used in the above embodiment.

Further, the radiation resistance of the minute dipole decreases in proportion to the square of the antenna length, and the radiation resistance of the minute loop decreases in proportion to the square of the loop area (not the effective area). For example, a square minute loop with one side of 1 / 10λ has a small value of 3.12Ω. Of course, the efficiency is close to 100% as long as the radiation resistance is small, and the loss resistance is close to 0, which seems to be no problem. However, the impedance of a small antenna consists of this small radiation resistance and, conversely, a large reactance.

In the small dipole, the reactance is capacitive and increases in inverse proportion to the antenna length. Therefore, in order to cancel and match this capacitive reactance, a considerably large value of inductive reactance, that is, a coil is required, and in the small loop, on the contrary, the capacitive reactance that matches the inductive reactance, that is, the capacitor. Is required.

Further, in the small loop, loss resistance due to the conductor loss of the loop element portion occurs and a part of the electric wave is consumed, but in the small dipole, loss resistance due to the conductor loss of the coil also occurs and the antenna becomes smaller. Since the radiation resistance is small, the loss resistance value due to this will exceed the radiation resistance value. Even if the two are equal, the efficiency is 50%, so the loss resistance doubles to 33% and triple to 25%.

Therefore, it is quite difficult to make a coil having a high Q when actually manufacturing, and it is considered that the Q of a small coil is about 100 at most. For example, when the reactance is J2000Ω, the loss resistance of the coil alone becomes 2000/100 = 20Ω. Therefore, it must be prepared that the substantial gain of the inductance-loaded antenna, that is, the small dipole, will decrease considerably as the size gets smaller.

However, in the case of a small loop, since the conductor loss of the loop element only has to be considered as the loss resistance, the radiation resistance itself becomes considerably small, but the conductor loss becomes a value lower than this. Therefore, the substantial gain of the micro-loop is much more advantageous than the micro-dipole which is an inductance loaded antenna.

The small loop antenna does not need a radial or a coil, has the highest radiation efficiency among small antennas, is perfectly tuned in the frequency range used, and has excellent VSWR characteristics. It has a wide range of applications from high / low launch angles in the near / medium range to low launch angles / long range, has a gain close to that of a half-wave dipole, and has little effect from the ground in a vertical installation, and the magnetic field component is less than the electric field component compared to buildings It can be operated indoors, and the magnetic field component gives little interference to the electric field type antenna of the TV. In addition, since it is a non-installed antenna and does not require a ground plane, it is not affected by convection currents and causes little BCI or TVI. By forming this micro loop antenna in a planar shape, it can be directly bonded to the mobile phone 8. Since it can be used, it hardly feels bulky in use.

[0035]

[Effect of device]

 According to the compact magnetic loop antenna device for a mobile phone of claim 1, the two antenna parts in which the tuning capacitors are formed and the feed line which forms the coupling circuit and is connected with the same impedance as the two antenna parts are provided. Since it is made of metal foil in a flat shape, it can increase the sensitivity and maintain a stable call even in a place where the electric field strength is low. Radial and coil are not required, high radiation efficiency can be obtained, and the frequency range used can be improved. Among them, it is perfectly tuned, has excellent VSWR characteristics, has a wide range of applications from near / medium distance to long distance, has a gain close to a half-wave dipole, and has little influence from the ground in a vertical installation. Compared to the electric field component, the magnetic field component is less likely to be affected by buildings, etc., and can be operated indoors, and the magnetic field component gives less interference to the electric field type antenna. Since it is a non-installed antenna and does not require a ground plane, it is not affected by convection currents, causes less BCI and TVI, and can be used by directly adhering it to a mobile phone. .

According to the compact magnetic loop antenna device for a mobile phone according to claim 2, in addition to the compact magnetic loop antenna device for a mobile phone according to claim 1, the film is formed by hot stamping a metal foil on the film. , Easy to form.

According to the compact magnetic loop antenna device for a mobile phone of claim 3, in addition to the compact magnetic loop antenna device for a mobile phone of claim 1, the film is formed by depositing a metal foil on the film. It can be easily formed.

According to the compact magnetic loop antenna device for a mobile phone according to claim 4, in addition to the compact magnetic loop antenna device for a mobile phone according to claim 1, since it is formed by metal plating on plastic, it is easy. Can be formed into

[Brief description of drawings]

FIG. 1 is a plan view showing an embodiment of a compact magnetic loop antenna device for a mobile phone according to the present invention.

FIG. 2 is a perspective view showing a state in which the mobile telephone is attached to the same as above.

FIG. 3 is an explanatory diagram showing a micro magnet dipole equivalent to a micro magnet loop.

[Explanation of symbols]

1 Compact magnetic loop antennas for mobile phones 2a, 2b Antenna parts 5a, 5b Tuning capacitors 6a, 6b Feed lines 7a, 7b Coupling circuit

Claims (4)

[Scope of utility model registration request] 1. An antenna section having two symmetrically shaped tuning capacitors formed at both ends thereof, and a coupling circuit formed at both ends thereof.
A compact magnetic loop antenna device for a mobile phone, comprising: two antenna parts; and a power supply line connected with the same impedance, wherein the antenna part and the power supply line are formed of a metal foil in a planar shape. 2. The compact magnetic loop antenna device for a mobile phone according to claim 1, wherein the film is formed by hot stamping a metal foil. 3. The compact magnetic loop antenna device for a mobile phone according to claim 1, wherein the film is formed by vapor-depositing a metal foil. 4. The compact magnetic loop antenna device for a mobile phone according to claim 1, wherein the plastic is formed by metal plating.