DE102016218541A1 - antenna means - Google Patents

Abstract

An antenna device of a portable device such as a remote keyless entry system uses a small-loop antenna (15), but a radiated electric wave is weak, which should be improved. Therefore, a holding portion of a device in which an antenna device (10) is accommodated and a power supply circuit (14) of the antenna device are arranged close to each other, and when a user holds the device, a human body causes high frequency coupling, so that a current in the dipole mode is efficient flows, whereby the radiated electric wave of the antenna is improved.

Description

BACKGROUND OF THE INVENTION

FIELD OF THE INVENTION

The present invention relates to an antenna device suitable as a transmission antenna mounted on a portable / portable device transmitting a lock / unlock signal, such as a remote keyless entry system for a vehicle such as a vehicle remote control.

STATE OF THE ART

A remote keyless entry system performs wireless communication between a portable device carried by a user and a vehicle-mounted device disposed in a vehicle via electric waves. In a system that performs typical unidirectional communication, an antenna device that radiates an electric wave for instructing locking or unlocking of a door of the vehicle is provided on the portable device. When the user operates the portable device, the antenna device transmits an electric wave to instruct locking or unlocking of a door of the vehicle. Subsequently, the antenna device of the vehicle-mounted device receives the electric wave transmitted from the portable device and locks or unlocks the door.

When an antenna device is provided on the portable device, the antenna efficiency is often insufficient due to the restriction of the size of the housing of the portable device. In particular, a small-loop antenna in which a conductor has been formed in a loop shape (ring shape) is used in the antenna device of the portable device, but in the portable device operated by the user when the power of the antenna is included is supplied to the small loop when an electric wave is sent out, a problem indicated that the radiated electric wave is weakened because it is influenced by a human body.

In other words, since the human body is a medium that causes a large loss at a high frequency, and the electric wave radiation from the human body is small, when a circuit board emitting the electric waves covers the user's hand is, the emission of electric waves is weakened.

Therefore, in order to reduce the influence of a human body, for example, it has been proposed that an antenna device disclosed in Patent Literature 1 has a structure in which a part of the outer box of the housing is formed of a conductor and the conductor is connected to a grounded circuit of a power supply circuit so that the ground potential side of the power supply unit and the terminal circuit side of the antenna device are grounded via the human body in use to provide sufficient antenna amplification performance or the like during communication.

CITATION

patent literature

• Patent Literature 1 JP-A-9-199920

The antenna device in Patent Literature 1 is formed such that a part of the housing, which is generally formed of a dielectric, serves as a conductor, and the conductor is connected to the grounded circuit of the power supply unit. Consequently, when the user grips the portable device, the portion of the conductor of the housing and the substrate ground (the substrate ground) are connected across the human body so as not to reduce the antenna performance. However, the structure in which a portion of the housing serves as a conductor to connect the substrate ground and the package causes problems in that the cost is high and the manufacturing steps increase.

SUMMARY OF THE INVENTION

It is an object of the present invention to provide a device which has a sufficient function as an antenna without substantially changing the manufacturing steps, as providing an antenna device used in a portable device.

An antenna device according to the present invention comprises: a circuit board or board accommodated in a housing of a portable device; a small loop antenna disposed on the circuit board; a power supply unit attached to the circuit board in the vicinity of a holding portion of the housing portable device, which is connected to the small-loop antenna and supplies the power of the small-loop antenna, a connection circuit which adjusts the small-loop antenna according to a desired frequency band; a ground potential (also referred to as a ground) provided in a region different from an antenna region in which the small-loop antenna of the circuit board is provided; a first switch provided in the antenna area of the circuit board; and a second switch provided in a different area from the antenna area of the circuit board, and is characterized in that a transmission via the small loop antenna is performed by the operation of the first switch and / or the second switch.

According to an antenna device of the present invention, since a first switch is provided in an antenna region, a second switch is provided outside the antenna region, and a power supply circuit is provided in the vicinity of a holding portion held by a user of a housing of a portable device holding the Antenna device accommodates, when the user holds the housing to perform a switching operation, the power supply circuit and a portion of the human body of the user holding the housing approach each other. As a result, high frequency coupling is obtained, whereby the antenna performance is improved only by arranging the power supply circuit.

BRIEF DESCRIPTION OF THE DRAWINGS

1A to 1C 13 are structural diagrams schematically showing a portable device and an antenna device according to a first embodiment of the present invention;

2A to 2C Fig. 15 are diagrams showing an operating state according to the first embodiment of the present invention;

3A to 3D Fig. 15 are diagrams showing an operation state according to a second embodiment of the present invention;

4A and 4B 12 are schematic diagrams showing an operation of an antenna device according to the second embodiment of the present invention;

5A and 5B Fig. 15 are diagrams showing an operation state according to a third embodiment of the present invention; and

6A and 6B FIG. 15 are diagrams showing an operation state according to a third embodiment of the present invention. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

First embodiment

As in 1A 3, which shows a view of a portable device that is the subject of the present invention, such as a common portable device, is a first button 2 and a second button 3 on a housing 1 of a dielectric and an area where the first button 2 and the second button 3 is provided (button area), and an area in which a user grips the portable device (holding portion) are formed. An antenna device 10 is in the case 1 provided the portable device and when the user first button 2 or the second button 3 presses, a predetermined signal is transmitted.

As in 1B as a top view and in 1C as a sectional view, both showing the structure of the antenna device 10 show are a CPU (central processing unit) 12 , a transmission circuit 13 , a power supply circuit 14 , an antenna with a small loop 15 , a connection circuit 16 , a first switch 17 and a second switch 18 on a circuit board 11 intended. The CPU 12 , the transmission circuit 13 , the power supply circuit 14 , the antenna with small loop 15 , the connection circuit 16 and the second switch 18 are at a substrate mass 19 (English: substrate ground) arranged. There is also a battery 20 for providing voltage necessary for driving the antenna device 10 is used on the back surface of the circuit board 14 arranged.

As in 1B shown is the first switch 17 in an area (antenna area) arranged by the small loop antenna 15 is surrounded and the second switch 18 is at the substrate mass 19 arranged.

Depending on whether the left hand or the right hand is used, as in 2 is shown when this portable device is operated, the housing 1 the portable device supported from the bottom and the first button 2 or the second button 3 is pressed from the top. 2A to 2C show examples of the use of the portable device and reproduce a state in which the portable device is operated by the right hand. 2A Gives a state in which the first button 2 is pressed and 2 B returns a state in which the second button 3 is pressed. In This operation, when the user holds the portable device in such a manner as to enclose it and presses a button corresponding to a desired remote keyless function, becomes the first switch 17 or the second switch 18 the antenna device 10 pressed. For example, in the case where the second switch 18 is pressed, pushing the second switch 18 to that the CPU 12 Data corresponding to the depressed second switch to the transmission circuit 13 sends.

The transmission circuit 13 modulates the data and outputs a high-frequency signal, such as a UHF (ultra-high frequency) signal band with binary FSK (frequency shift key). This high frequency signal becomes the power supply circuit 14 fed and into space through the element of the small loop antenna 15 sent out. The small loop antenna 15 is formed by a pattern, for example, on the circuit board 11 is trained. The power supply circuit 14 and the connection circuit 16 are adjustment circuits around the element of the small loop antenna 15 in the desired frequency band. In the UHF band, for example, the power supply circuit 14 with the substrate mass 19 connected via a ground coil. In addition, the connection circuit 16 with the substrate mass 19 connected by a capacitor connected in series. The substrate mass 19 is on the circuit board 11 is formed and formed at one end opposite to the end to which the element of the small loop antenna 15 is provided to send out the antenna with a small loop 15 not to prevent or hinder.

The power supply circuit 14 is on the circuit board 11 arranged and is in particular on the circuit board 11 at or near the position where the portable device is supported when the user performs a button operation on the portable device. For example, the length of 1/10 or less of the wavelength or preferably 1/40 or less of the wavelength may be considered to be electrically close because the very small loop is formed in the length of 1/4 or less of the wavelength. For example in 2A That is, since the button is pressed with the thumb while the portable device is held with the index finger, a feeding point is provided at a position between the second joint and the third joint of the index finger. When the index finger and the power supply circuit 14 approach each other, a high frequency coupling (electric field coupling) is obtained between them and when the power supply circuit 14 the element of the small loop antenna 15 Power is generated, an electric field is generated in the index finger of the user, that is, the body of the user and thus flows a current.

As described in the first embodiment, when power from the power supply unit 14 on the circuit board 11 to the small loop antenna 15 is supplied as in 2C a minute current in the loop flows to the element of the small loop antenna 15 (Route a) and a current in dipole mode also flows to the substrate ground 19 (Route b). Therefore, a signal emitted by the portable device is equal to the sum of the radiation through the current in the small loop mode and the radiation of the current through the dipole mode.

Therefore, by providing the substrate mass, it flows 19 at the side of the human body, the current in dipole mode passing through the substrate mass 19 flows to the human body via the index finger by means of high-frequency coupling (route c). Since the human body has the length of the wavelength order, the radiation from the current in the dipole mode becomes stronger. For this reason, by arranging the power supply unit 14 at the position of the index finger (that is, the position where the portable is supported), the current of the small-loop antenna and the current in the dipole mode obtained from the human body as the ground (ground potential) are obtained. Consequently, when the portable device is held by the human body, the antenna performance of the portable device is improved.

As described above, by providing the power supply circuit 14 at the position where the portable device is supported, the antenna performance is improved.

It should be noted that 1 an example shows in which two switches, that is, the first switch 17 and the second switch 18 be used. Here is at least one switch in the antenna 15 arranged with a small loop and the other switch is at the substrate ground 19 arranged. Although the circuit board 11 is shown in a flat, plate-like, rectangular shape, the shape of the circuit board 11 not limited to a rectangle and may represent an ellipse or a square or the like. However, from the viewpoint of easy handling, when the user operates the portable device, it is preferable that the circuit board 11 an elliptical shape having a diameter that is longer and another diameter that is shorter. In addition, although in the first embodiment, an example in which the portable device is held by the right hand is presented In addition, even in the case where the portable device is held with the left hand, the back of the portable device is supported, whereby a feeding point is disposed on the supported portion.

Second embodiment

In general, if a conductor in the element of the antenna 15 is provided with a small loop, the antenna performance is reduced. This is so because an electric field is present in the small loop antenna 15 is generated, is interrupted. If the human body is used as an antenna ground, as in the first embodiment, the user's hand also acts as a part of the antenna ground. Consequently, as in the case where the first button 2 is pressed, as in 3A shown, and in the case where the second button 3 is pressed, as in 3C shown approaches in the element of the small loop antenna 15 the mass of this or moves away, depending on which button is pressed. Therefore, the intensity of the electric wave that varies from the element of the small-loop antenna varies 15 is sent out, from low, as in 3B shown too high, like in 3D depending on which button is pressed. Thus, in the remote keyless entry system, the intensity of the electrical wave from the antenna varies extremely depending on which button is pressed. The way to deal with it will now be described.

The second embodiment is an improvement for preventing a large difference in the intensity of the electric wave. The second embodiment will be described with reference to 4A and 4B described. 4A shows the antenna device and shows the arrangement of the substrate ground 19 , The power supply circuit 14 , the connection circuit 16 and the like are not shown since they are the same as those of the first embodiment.

In the second embodiment, a second substrate mass is 192 , which serves as a conductor, between the first switch 17 and the second switch 18 provided and connected to the ground. Here, though the second substrate mass 192 on the circuit board 11 is provided when the circuit board 11 is a multilayer substrate, becomes the second substrate mass 192 not necessarily provided on the surface and may be provided on any layer of the laminated body.

Here, when a high-frequency signal flows the power supply circuit 14 is supplied, a current through the element of the antenna 15 with a small loop, creating an electric field. An electric field is also in the antenna 15 with a small loop 15 generated. The wave intensity is in 4B shown with the thickness of the arrow and the intensity of the electric wave in the area of the antenna 15 with small loop is high, but the electric wave from the second substrate mass 192 shielded, between the first switch 17 and the second switch 18 is provided. Therefore, the intensity of the electric wave is around the second substrate mass 192 reduced.

In the second embodiment, the switch operation is shown with the thumb. In the element of the antenna 15 with a small loop, to eliminate the influence of the thumb on the user, the second substrate mass 192 which is to be connected, the width of about 3 mm, which is narrower than the size of the typical finger, for example, not to deteriorate the antenna performance.

It should be noted that the second substrate mass 192 in a circular arc shape in addition to a rectangular arc shape, as in 4A shown, can be trained.

By providing a structure having the function of the second substrate mass 192 serving as the face plate to reduce the electric wave intensity when the switch is depressed, even when a finger gets near or away from the device, large fluctuation does not occur in the electric wave intensity. That is, it is possible to reduce the difference in antenna performance caused depending on which button is pressed.

As described above, by providing an element for shielding an electric wave, such as the second substrate mass, between switches connected to the electric circuit board 11 are arranged, the electrical wave intensity coming from the element of the antenna 15 with small loop, are reduced in advance, hence the antenna performance does not vary significantly depending on which button is pressed.

Third embodiment

In the second embodiment, by providing the second substrate mass 192 between the first switch 17 and the second switch 18 the difference in antenna performance caused depending on which button is being pushed is reduced.

However, it is necessary the location of the connection circuit 16 and the power supply circuit 14 to be observed. That is, as in 5A and 5B shown in the state in which the connection circuit 16 closer to the side of the antenna 15 with a small loop than to the power supply circuit 14 in the longitudinal direction of the circuit board 11 , such as in 5A shown when the user first button 2 presses with the thumb, a high-frequency coupling between the connection circuit 16 and the thumb of the user. Therefore, the current in the dipole mode flows from the terminal circuit 16 to the user's thumb due to high frequency coupling (Route 1). In addition, a current in dipole mode from the human body to the connection circuit 16 generated over the thumb of the user (Route 2). Therefore, the route 2 is increased, the current in the dipole mode is equal to the sum of the current in the dipole mode of the substrate, the current in the dipole mode of the human body via the route 1 and the current in the dipole mode via the human body via the route 2. Accordingly, it differs the antenna performance between the case where the first button 2 is pressed and the case in which the second button 3 is pressed, as in 5B will be shown. The third embodiment provides an improvement to prevent the condition in which the antenna performance greatly differs depending on which button is pressed.

The third embodiment will be described with reference to FIG 6A and 6B described. It should be noted that the same parts as in the second embodiment, such as the portable device and the antenna device are not shown, and a description thereof will be omitted.

In the third embodiment, the connection circuit 16 and the power supply circuit 14 arranged at the same position when from the small loop antenna 15 considered. That is, as in 6A and 6B As shown, they are arranged at symmetrical positions at the same distance from the small loop antenna in the longitudinal direction of the circuit board. In other words, in the longitudinal direction of the circuit board 11 if from the position of the antenna 15 looked at with small loop, the connection circuit 16 at the same position as the power supply circuit 14 arranged. It should be noted that the substrate mass 19 on the opposite side to the element of the antenna 15 with a small loop in relation to the power supply circuit 14 and the connection circuit 16 is arranged.

With this arrangement, for example, as in 6A shown when the user first button 2 presses with the thumb, the combined amount of current in dipole mode, that of the connection circuit 16 through the thumb to the human body between the thumb and the connection circuit 16 flows, reduced, since the thumb of the connection circuit 16 away. In a similar way as in 6B shown when the user presses the second button with the thumb, as in the case where the first button 2 is pressed, the current flows in the dipole mode via the route 3 and the route 4, which are coupled with the thumb. In this state are the combined amount between the first button 2 and the connection circuit 16 and the combined amount between the second button 3 and the connection circuit 16 almost even, even if any button is pressed, since the shortest distances between the connection circuit 16 and the thumb are the same.

Therefore, it is possible to reduce the difference in antenna performance between the case where the first button 2 is pressed, and the case where the second button 3 is pressed. As described above, it is by arranging the connection circuit 16 and the power supply circuit 14 at the same position in the longitudinal direction of the circuit board 11 it is possible to reduce the fluctuation in antenna performance caused depending on which button is pressed.

It should be noted that in the present invention, each component in each embodiment can be changed or omitted, if it is within the scope of the invention.

Claims (3)

Antenna device comprising: a circuit board ( 11 ) housed in a housing ( 1 ) is housed a portable device; an antenna ( 15 ) with a small loop attached to the circuit board ( 11 ) is arranged; a power supply circuit ( 14 ) connected to the circuit board ( 11 ) in the vicinity of a holding portion of the housing ( 1 ) of the portable device is arranged and that with the antenna ( 15 ) is connected to a small loop and that of the antenna ( 15 ) supplies power with a small loop; a connection circuit ( 16 ), the antenna ( 15 ) with a small loop according to a desired frequency band; a mass ( 19 ) arranged in a different area with respect to an antenna area in which the antenna ( 15 ) with a small loop of the circuit board ( 11 ) is provided; a first switch ( 17 ) located in the antenna area of the circuit board ( 11 ) is provided; and a second switch ( 18 ) provided in a different area to the antenna area of the circuit board, thereby characterized in that a transmission via the antenna ( 15 ) is performed with a small loop by the operation of the first switch and / or the second switch. Antenna device according to claim 1, characterized in that a conductor ( 192 ) between the first switch ( 17 ) and the second switch ( 18 ) attached to the circuit board ( 11 ) are arranged, is provided and the conductor with a mass ( 19 ) on the circuit board ( 11 ) connected is. Antenna device according to claim 1 or 2, characterized in that the connection circuit ( 16 ) and the power supply circuit ( 14 ) at symmetrical positions equidistant from the antenna ( 15 ) with a small loop in the longitudinal direction of the circuit board ( 11 ) are arranged.

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