KR101698688B1 - Bluetooth Earset Antenna Using Receiver Lines - Google Patents

Abstract

Disclosed is a Bluetooth earset antenna using a receiver line, which separates an audio signal and an antenna signal. The Bluetooth earset antenna comprises: a feeding circuit implemented on a substrate; at least one or more passive devices disposed in the feeding circuit for feeding to the antenna; an inductive device installed between the feeding circuit and an audio signal to shield an antenna signal so as not to flow to an audio signal end under a high frequency environment; and a capacitance device disposed between an anode and a cathode of a receiver line to make the anode and the cathode of the receiver line operate by being separated from each other in a low frequency environment, and to make the anode and the cathode of the receiver line operate as one emission body in the high frequency environment. The antenna signal and the audio signal are independently operable.

Description

[0001] The present invention relates to an antenna for a wireless Bluetooth < RTI ID = 0.0 > earset,

The following embodiments relate to an antenna for a wireless Bluetooth earset that utilizes a receiver line. More particularly, the present invention relates to an antenna for a wireless Bluetooth earset that utilizes a receiver line that feeds an earphone line of a Bluetooth earset to an antenna.

2. Description of the Related Art [0002] Portable terminals have been widely used in various electronic and communication industries. To meet the needs of users, functions of the terminals have been diversified and gradually become smaller and thinner. Accordingly, a peripheral device attached to or added to the terminal is also developing. For example, a peripheral device such as a camera device that is attachable or built-in, a smart card that is an auxiliary memory, And a Bluetooth headset for wirelessly communicating with a Bluetooth module installed in the terminal.

The terminal having the Bluetooth function has a separate Bluetooth antenna module for operating in the 2.4 GHz band separately from the main antenna device for communication, and a predetermined Bluetooth module is mounted on the main board of the terminal and is connected to a Bluetooth headset .

Since the Bluetooth headset is used as a hands-free part in using a portable terminal, since a separate cable from the terminal is not needed, the convenience of operation of the terminal is increased, and in addition to the portable hands-free microphone device, It has a simple advantage.

The Bluetooth headset includes an antenna radiator for performing short-range wireless communication with the terminal. Conventionally, at least one chip antenna is mounted in the SMD type on the headset substrate. Generally, the chip antenna is configured such that a coil is wound on a ceramic body a predetermined number of times to resonate in a predetermined band.

However, in the Bluetooth headset configured as described above, since the antenna radiator must be installed on the board inside the headset, the volume of the antenna due to the antenna mounting space is increased, which causes the headset to slim down.

In addition, the Bluetooth hair set utilizes not only a chip antenna but also an antenna using a flexible printed circuit board (FPCB) and a ground radiation antenna. However, conventional Bluetooth hair sets have problems in terms of price and performance. In case of FPCB antenna, the size of antenna is very large, so the radiation performance is good, but the price is very expensive. In case of chip antenna and ground radiated antenna, it is implemented on a printed circuit board (PCB) The price is low, but it is difficult to secure performance when the ground of the terminal is small.

Korean Patent No. 10-0781228 relates to a Bluetooth headset having such a built-in antenna module, which includes a body having a microphone device and an earphone device, a predetermined shape including a Bluetooth module therein, Describes an art relating to an apparatus including an ear hook of a curved shape to be used and an antenna module provided on the ear hook.

Embodiments describe an antenna for a wireless Bluetooth earset that utilizes a receiver line, and more specifically, provide a technique for feeding a receiver line of a Bluetooth earset to an antenna.

Embodiments provide an antenna for a wireless Bluetooth earset utilizing a receiver line that isolates an audio signal from an antenna signal, as well as a technique of feeding a receiver line of a Bluetooth earset to an antenna.

An antenna for a wireless Bluetooth earset utilizing a receiver line according to an embodiment, comprising: a feed circuit implemented on a substrate; At least one passive element arranged to feed the antenna to the power feeding circuit; An inductive element disposed between the power feeding circuit and the audio signal to shield the antenna signal from flowing to the audio signal terminal in a high frequency environment; And a capacitive element disposed between the cathode and the anode of the receiver line, the cathode and the anode of the receiver line being operated in a low frequency environment to operate the receiver line as a single radiator in a high frequency environment, The antenna signal and the audio signal are independently operated.

Here, the power feeding circuit may include a power feeding part including a feeding point for supplying an electric signal; And a radiator that maintains electromagnetic coupling with the feeding part and radiates a signal of a certain frequency band, one end of which is electrically connected to the ground, and the radiator is connected to the receiver line so that the receiver line is operated as a radiator .

Wherein the power supply circuit includes: a first capacitive element connected in series to the feed point to the feed part; A second capacitive element connected in series between the ground and the radiator; And a first inductive element connected in series between the radiator and the receiver line.

The first capacitive element and the second capacitive element may comprise at least one or more capacitors to control the input impedance.

The first inductive element comprises at least one or more inductors to control the operating frequency.

The inductive element may comprise a plurality of inductors connecting the cathode and anode of the receiver line from the audio signal, and the capacitive element may be a capacitor.

Wherein the power supply circuit comprises: a second inductive element connected in series between the feed point and the first capacitive element; And a third inductive element connected in series between the second capacitive element and the radiator.

The power supply circuit may further include a third capacitive element connected in series between the radiator and the first inductive element connected to the receiver line.

A wireless Bluetooth earset utilizing a receiver line according to another embodiment, comprising: a body including an antenna module therein; And a receiver connected to the antenna module through the receiver line, wherein the antenna module comprises: an antenna signal unit configured to include a power supply circuit and operate the receiver line as a radiator in a high frequency environment; And an audio signal unit for transmitting an audio signal to the receiver line in a low frequency environment, wherein the antenna signal and the audio signal are independently operated.

Here, the antenna module may include at least one passive element arranged to feed the antenna to the power feeding circuit; An inductive element disposed between the power feeding circuit and the audio signal to shield the antenna signal from flowing to the audio signal terminal in a high frequency environment; And a capacitive element disposed between the cathode and the anode of the receiver line to operate the cathode and anode of the receiver line in a low frequency environment and to operate the receiver line as a single emitter in a high frequency environment .

Wherein the power supply circuit comprises: a power supply portion including a power supply point for supplying an electrical signal; And a radiator that maintains electromagnetic coupling with the feeding part and radiates a signal of a certain frequency band, one end of which is electrically connected to the ground, and the radiator is connected to the receiver line so that the receiver line is operated as a radiator .

Wherein the power supply circuit includes: a first capacitive element connected in series to the feed point to the feed part; A second capacitive element connected in series between the ground and the radiator; And a first inductive element connected in series between the radiator and the receiver line.

An antenna for a wireless Bluetooth earset utilizing a receiver line according to another embodiment, comprising: a power supply circuit implemented on a substrate; At least one passive element arranged to feed the antenna to the power feeding circuit; An inductive element disposed between the power feeding circuit and the audio signal to shield the antenna signal from flowing to the audio signal terminal in a high frequency environment; And a capacitive element disposed between the cathode and the anode of the receiver line, the cathode and the anode of the receiver line being operated in a low frequency environment to operate the receiver line as a single radiator in a high frequency environment, Wherein the power supply circuit comprises: a power supply portion including a power supply point for supplying an electrical signal; A radiator that maintains electromagnetic coupling with the feeding part and is electrically connected to the receiver line to radiate a signal of a certain frequency band; An inductor and a capacitor connected to the feeding part in series with the feed point; And a capacitor and an inductor connected in series between the radiator and the receiver line, wherein the radiator is connected to the receiver line so that the receiver line is operated as a radiator.

Embodiments can provide an antenna for a wireless Bluetooth earset utilizing a receiver line that isolates an audio signal from an antenna signal, as well as a technique of feeding a receiver line of a Bluetooth earset to an antenna.

According to the embodiments, since the emitter structure of the earpiece is implemented as a circuit on the PCB, it is possible to implement the receiver line at a very low cost without additional cost. have.

1 is a view for explaining an antenna for a wireless Bluetooth earset utilizing a receiver line according to an embodiment.
FIG. 2 is a view schematically showing an antenna for a wireless Bluetooth earset by enlarging part A of FIG. 1;
3 is a diagram for explaining the operation of audio according to an embodiment.
4 is a view for explaining the operation of the antenna according to one embodiment.
5 is a view for explaining an antenna for a wireless Bluetooth earset utilizing a receiver line according to another embodiment.
6 is a view for explaining an antenna for a wireless Bluetooth earset utilizing a receiver line according to another embodiment.
7 is a view showing an actual production example of an antenna for a wireless Bluetooth earset utilizing a receiver line according to an embodiment.
8 is a diagram showing measurement data of antenna radiation according to one embodiment.
9 is a diagram showing simulation results of antenna radiation according to one embodiment.
10 is a diagram showing input impedance control according to a change of C _s (second capacitive element) of an antenna according to an embodiment.
11 is a diagram showing input impedance control according to a change of C _f (first capacitive element) of an antenna according to an embodiment.
12 is a diagram showing resonance frequency control according to a change in L _r (first inductive element) of an antenna according to an embodiment.

Hereinafter, embodiments will be described with reference to the accompanying drawings. However, the embodiments described may be modified in various other forms, and the scope of the present invention is not limited by the embodiments described below. In addition, various embodiments are provided to more fully describe the present invention to those skilled in the art. The shape and size of elements in the drawings may be exaggerated for clarity.

The following embodiments describe an antenna for a wireless Bluetooth earset that utilizes a receiver line, and more specifically, provide a technique for feeding a receiver line of a Bluetooth earset to an antenna. Embodiments can provide not only a technique of feeding a receiver line of a Bluetooth earset to an antenna but also an antenna for a wireless Bluetooth earset that utilizes a receiver line that isolates an audio signal from an antenna signal.

An antenna for a wireless Bluetooth earset that utilizes a receiver line according to an exemplary embodiment may be implemented to operate independently of an antenna signal and an audio signal capable of wireless communication.

The antenna signal is used for wireless communication, and can be operated as a wireless communication antenna using Bluetooth, which is a near field wireless communication technology, for example. Such an antenna signal operates in a high frequency environment, and in the case of Bluetooth, it can operate at an antenna frequency of 2.4 GHz to 2.5 GHz.

On the other hand, an audio signal transmits an audio signal to a receiver and can be operated in a low frequency environment.

When the antenna signal and the audio signal are implemented together, interference may occur between them, which may cause a problem. Accordingly, the antenna signal and the audio signal can be shielded from each other to prevent interference between signals.

1 is a view for explaining an antenna for a wireless Bluetooth earset utilizing a receiver line according to an embodiment.

FIG. 2 is a view schematically showing an antenna for a wireless Bluetooth earset by enlarging part A of FIG. 1;

Referring to FIGS. 1 and 2, an antenna for a wireless Bluetooth earset using a receiver line according to an exemplary embodiment may be implemented to independently operate an audio signal and an antenna signal. That is, it is possible to provide an antenna for a wireless Bluetooth earset that utilizes a receiver line capable of isolating an audio signal and an antenna signal from each other. Also, it is possible to implement a power feeding circuit that feeds the receiver line of the Bluetooth earset to the antenna. Here, the earset may include a microphone and an earphone, and may be used to include a headphone, a headset, and the like.

2, an antenna for a wireless Bluetooth earset that utilizes a receiver line according to one embodiment includes a power supply circuit, passive elements 112, 114, 116, inductive elements 122, and capacitive elements 124 ).

A feed circuit may be implemented on a substrate such as a PCB.

In addition, efficient feeding is possible by using the passive elements 112, 114, and 116 in the power feeding circuit. The passive elements 112, 114, and 116 may be composed of at least one passive element 112, 114, and 116 disposed to feed power to the power feeding circuit.

The power feeding circuit may include a feeding part including a feeding point 110 for feeding an electric signal and a radiator for maintaining electromagnetic coupling with the feeding part and radiating a signal of a certain frequency band at one end in electrical connection with the ground have.

The feeding part is electromagnetically coupled to the feeding point 110 and receives a feeding signal. For example, the feeder may be coupled to the inner conductor of the coaxial line to receive a feed signal.

The ground may provide a ground voltage to the electrical / electronic components of the communication device in which the antenna is embedded. The ground is coupled to the terminus of the radiator and forms a loop together with the radiator and the feeder. The radiator may be formed of the same conductive metal material as the ground, and the radiator may be formed with a predetermined width.

Also, the radiator may extend while maintaining electromagnetic connection with the power feeder, and the termination may be connected to the ground. The radiator can transmit / receive a signal in a frequency band, and the power feeding structure formed including the feeding part, the ground, and the radiator can radiate the antenna signal. In this case, the antenna signal may be a high frequency band signal for wireless communication, for example, a Bluetooth antenna signal having an antenna frequency of 2.4 GHz to 2.5 GHz.

The feed portion, the ground, and the radiator form a loop, the first capacitive element 114 is coupled to the feed portion, and the second capacitive element 112 is coupled to the radiator. The first inductive element 116 may be coupled to the radiator connected to the receiver line 210.

And the radiator may be connected to the receiver line 210 so that the receiver line 210 can be operated as a radiator. By feeding the receiver line 210 of the earset as a radiator, the radiating performance is very good since the size of the radiator is large like the FPCB antenna, and the power supply structure is implemented as a circuit on the PCB, so that no additional cost is incurred.

Here, the receiver 200 is an apparatus for receiving the audio signal 120, and may be used to include a receiver line 210, an earphone line, and the like. The receiver 200 may also be a device for receiving a low-frequency signal, and it is also possible to feed a cable used as a low-frequency signal other than an audio signal.

The power feeding circuit may include a first capacitive element 114 connected in series to the feeding point 110 at the feeding portion and a second capacitive element 112 connected in series between the ground and the radiating element . A first inductive element 116 may also be formed that is connected in series between the radiator and the receiver line 210.

Here, the first capacitive element 114 and the second capacitive element 112 may include at least one capacitor to control the input impedance.

In this case, the capacitors C _s 112 and C _f 114 and the inductor L _r 116 are elements for adjusting the antenna signal and can be used for effective feeding of the antenna. The capacitors C _s 112 and C _f 114 may be matched by adjusting the input impedance of the antenna. For example, the size of the capacitors C _s 112 and C _f 114 may be about 0.1 to 2 pF.

The first inductive element 116 comprises at least one or more inductors to control the operating frequency.

In this case, the inductor L _r (116) uses the receiver line 210 as a radiator, and can adjust the operating frequency of the antenna.

The inductive element 122 may be disposed between the feeder circuit and the audio signal 120 to shield the antenna signal from flowing to the audio signal end in a high frequency environment. Here, the audio signal represents one example of a signal in a low-frequency environment and may mean another low-frequency signal.

The inductive element 122 may be comprised of a plurality of inductors connecting the cathode and anode of the receiver line 210 from the audio signal 120, respectively.

In this case, the inductor L _a 122 is an element for preventing the antenna signal from flowing to the audio signal terminal at the antenna frequency (2.4 GHz to 2.5 GHz). That is, the inductor L _a 122 shields the antenna signal and the audio signal 120 to prevent interference with each other.

For example, the inductor L _a 122 can be made to have a relatively large impedance at high frequencies by using a device of about 100 nF size.

The capacitive element 124 is disposed between the cathode and the anode of the receiver line 210 so that the cathode and the anode of the receiver line 210 are operated separately in a low frequency environment and in a high frequency environment, It can be operated as a radiator.

The capacitive element 124 may comprise a capacitor.

In this case, the capacitor C _a 124 allows the cathode and the anode of the receiver line 210 to operate separately in a low-frequency environment, and the receiver line 210 can operate as a single emitter in a high-frequency environment.

The capacitor C _a 124 may be an open circuit or a short circuit depending on the operating frequency. For example, the capacitor C _a 124 may have an impedance of about 2 pF or more.

Accordingly, the antenna signal and the audio signal can be independently operated without interfering with each other.

3 is a diagram for explaining the operation of audio according to an embodiment.

Referring to FIG. 3, an antenna for a wireless Bluetooth earset utilizing a receiver line according to an exemplary embodiment may be used as an audio antenna by cutting off an antenna signal in a low frequency environment.

Since the operating frequency of the audio is very low compared to the antenna signal, the impedance of C _s , C _f , and C _a is very large and is regarded as an open circuit and no current flows. Accordingly, the audio signal 120 is directly input to the receiver signal, so that the audio can be operated without interference.

4 is a view for explaining the operation of the antenna according to one embodiment.

Referring to FIG. 4, an antenna for a wireless Bluetooth earset using a receiver line according to an exemplary embodiment may block the audio signal 120 in a high frequency environment and operate as an antenna for wireless communication.

At the operating frequency (high frequency) of the antenna, C _a is considered a short circuit so that the two lines 210 of the receiver 200 can operate as a single radiator.

Also, since the impedance of L _a is large, it is regarded as an open circuit, and the antenna current can be prevented from flowing to the audio end. C _s (112) and C _f (114) are elements for controlling the coupling between the antenna and the power feeding circuit, and L _r (116) are elements for controlling the operating frequency of the antenna.

Accordingly, the antenna can operate as a monopole antenna.

Hereinafter, a wireless Bluetooth earset using a receiver line using an antenna for a wireless Bluetooth earset utilizing a receiver line according to an embodiment will be described in detail.

A wireless Bluetooth earset utilizing a receiver line may include a body including an antenna module therein and a receiver connected to the antenna module through a receiver line.

The antenna module includes an antenna signal unit configured to operate a receiver line as a radiator in a high frequency environment and a low frequency signal unit to transmit a low frequency signal to a receiver line in a low frequency environment, .

Here, the low-frequency signal portion can be added with an audio signal. That is, the low-frequency signal unit is an audio signal unit for transmitting an audio signal to the receiver line in a low-frequency environment, and the antenna signal and the audio signal can be independently operated.

As described above, the antenna module is disposed between the at least one passive element, the feeder circuit, and the audio signal, which are disposed for feeding the antenna to the feeder circuit, so that the antenna signal is shielded from the antenna signal in the high- Device and a capacitive element disposed between the cathode and the anode of the receiver line so that the cathode and anode of the receiver line are operated separately in a low frequency environment and the receiver line is operated as a single emitter in a high frequency environment have.

The feed circuit may include a feeder including a feed point for feeding an electrical signal and a radiator for maintaining electromagnetic coupling with the feeder and radiating a signal of a certain frequency band at one end electrically connected to the ground, May be connected to the receiver line so that the receiver line can be operated as a radiator.

Further, the power supply circuit includes a first capacitive element connected in series with the feed point to the feed portion, a second capacitive element connected in series between the ground and the radiator, and a second induction coupled in series between the radiator and the receiver line. And may further comprise a sag element. Since this has been described in detail with reference to FIGS. 1 and 2, detailed description is omitted.

5 is a view for explaining an antenna for a wireless Bluetooth earset utilizing a receiver line according to another embodiment.

Referring to FIG. 5, an antenna for a wireless Bluetooth earset using the receiver line illustrated in FIG. 2 may further include an inductive element and a capacitive element in a power supply circuit. A second inductive element connected in series between the feed point and the first capacitive element in the feed circuit and a third inductive element connected in series between the second capacitive element and the radiator, . The power supply circuit may further include a third capacitive element connected in series between the radiator and the first inductive element connected to the receiver line.

An antenna for a wireless Bluetooth earset that utilizes a receiver line according to another embodiment may comprise a feed circuit, passive elements, inductive elements 521, 522, and a capacitive element 524.

A feeder circuit may be implemented on the PCB.

It is possible to efficiently supply electric power by using the passive elements 511 to 516 in the power supply circuit. The passive element may comprise at least one passive element arranged for feeding the antenna to the feed circuit.

The power feeding circuit may include a feeding part including a feeding point 510 for supplying an electric signal and a radiator for maintaining electromagnetic coupling with the feeding part and radiating a signal of a certain frequency band at one end in electrical connection with the ground have. The radiator may be connected to the receiver line 210 so that the receiver line 210 may be operated as a radiator.

The power feeding circuit may include a first capacitive element 513 connected in series to the feeding point 510 at the feeding part and a second capacitive element 511 connected in series between the ground and the radiating element . A first inductive element 516 may also be formed which is connected in series between the radiator and the receiver line 210.

Here, the first capacitive element 513 and the second capacitive element 511 may include at least one capacitor to control the input impedance.

The first inductive element 516 may comprise at least one inductor to control the operating frequency.

The inductive elements 521 and 522 are disposed between the power supply circuit and the audio signal 520 so as to shield the antenna signal from flowing to the audio signal end in a high frequency environment.

The inductive elements 521 and 522 may be composed of a plurality of inductors connecting the cathode and the anode of the receiver line 210 from the audio signal 520, respectively.

The capacitive element 524 is disposed between the cathode and the anode of the receiver line 210 so that the cathode and the anode of the receiver line 210 are operated separately in a low frequency environment and in a high frequency environment, It can be operated as a radiator.

The capacitive element 524 may be a capacitor.

And a second inductive element 514 connected in series between the feed point 510 and the first capacitive element 513 in the feed circuit and a second inductive element 514 connected in series between the second capacitive element 511 and the radiator A third inductive element 512 may be constructed.

A third capacitive element 515 connected in series between the radiator and the first inductive element 516 coupled to the receiver line 210 may also be further configured.

In this way, a structure may be realized in which an inductor is added to a feed circuit and a shorting in order to improve the efficiency and usability of antenna impedance matching.

6 is a view for explaining an antenna for a wireless Bluetooth earset utilizing a receiver line according to another embodiment.

Referring to FIG. 6, it is similar to the antenna for a wireless Bluetooth earset using the receiver line described in FIG. 2, but it is also possible to implement a power supply structure that does not include a short-circuit end according to a terminal structure.

In an antenna for a wireless Bluetooth earset utilizing a receiver line according to another embodiment, a power supply circuit may be implemented on a substrate, and at least one passive element may be disposed to feed power to the power supply circuit.

Here, the power feeding circuit includes a feeding part including a feeding point 610 for feeding an electrical signal, a radiator that is electromagnetically coupled to the feeding part and is electrically connected to the receiving line 210 to radiate a signal of a certain frequency band .

An inductor 614 and a capacitor 613, which are connected in series with the feeding point 610, are disposed in the feeding part, so that the input impedance of the antenna can be adjusted. A capacitor 615 and an inductor 616, which are connected in series between the radiator and the receiver line 210, are disposed to control the resonance frequency of the antenna. At this time, the radiator may be connected to the receiver line 210 so that the receiver line 210 may also be operated as a radiator.

The inductive elements 621 and 622 are disposed between the power supply circuit and the audio signal 620 so as to prevent the antenna signal from flowing to the audio signal terminal in a high frequency environment so that interference between the antenna signal and the audio signal can be prevented.

The capacitive element 624 is disposed between the cathode and the anode of the receiver line 210 so that the cathode and the anode of the receiver line 210 are operated separately in a low frequency environment and the receiver line 210 is connected to one It can be operated as a radiator.

As described above, according to the embodiment, by using the receiver line 210 of the earset as a radiator, it is possible to provide an antenna having a high radiating performance because the size of the radiator is large.

7 is a view showing an actual production example of an antenna for a wireless Bluetooth earset utilizing a receiver line according to an embodiment.

Referring to FIG. 7, there is shown an actual production example of an antenna for a wireless Bluetooth earset that utilizes a receiver line according to an embodiment, and shows an antenna for a wireless Bluetooth earset utilizing the receiver line described with reference to FIG. Referring to FIG. 1, for example, an antenna for a wireless Bluetooth earset using a receiver line may have a ground width of 15 mm and a length of 10 mm, and a clearance portion of 5 mm wide and 3 mm wide.

An antenna for a wireless Bluetooth earset utilizing such a receiver line can be implemented to operate an audio signal and an antenna signal independently of each other, and a power feeding circuit for feeding a receiver line of the Bluetooth earset to an antenna can be implemented.

8 to 12 can confirm the control of the resonance frequency and / or the input frequency according to changes of the antenna radiation and the passive elements (capacitors and inductors), using the above-mentioned example of the condition.

8 is a diagram showing measurement data of antenna radiation according to one embodiment.

9 is a diagram showing simulation results of antenna radiation according to one embodiment. FIG. 9A shows the return loss of the antenna, and FIG. 9B shows the impedance of the antenna.

10 is a diagram showing input impedance control according to a change of C _s (second capacitive element) of an antenna according to an embodiment. 11 is a diagram showing input impedance control according to a change of C _f (first capacitive element) of an antenna according to an embodiment. 12 is a view showing a resonance frequency control according to a change of L _r (first inductive element) of the antenna according to an embodiment.

As described above, according to the embodiments, it is possible to provide an antenna for a wireless Bluetooth earset utilizing a receiver line that isolates an audio signal from an antenna signal, as well as a technique of feeding a receiver line of a Bluetooth earset to an antenna. In addition, as a technique of feeding a receiver line of an earset to a radiator, the radiating performance is very good because the size of the radiator is large like the FPCB antenna, and the power supply structure is realized by a circuit on the PCB.

Furthermore, according to embodiments, various structures such as an earphone line using an audio signal as well as a receiver that receives an audio signal can be utilized, and it is also possible to feed a cable used as a low-frequency signal other than an audio signal.

As described above, the embodiments of the present invention are technologies for feeding a receiver line of an earset into a radiator. Since the radiator is large in size as in a flexible printed circuit board (FPCB) antenna, the radiation structure is excellent, Print Circuit Board (PCB), so that it can be implemented at a very low cost without additional cost.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. For example, it is to be understood that the techniques described may be performed in a different order than the described methods, and / or that components of the described systems, structures, devices, circuits, Lt; / RTI > or equivalents, even if it is replaced or replaced.

Therefore, other implementations, other embodiments, and equivalents to the claims are also within the scope of the following claims.

Claims (14)

1. An antenna for a wireless Bluetooth ear-set utilizing a receiver line,
A feed circuit implemented on a substrate;
At least one passive element arranged to feed the antenna to the power feeding circuit;
An inductive element disposed between the power feeding circuit and the audio signal to shield the antenna signal from flowing to the audio signal terminal in a high frequency environment; And
A capacitive element which is disposed between the cathode and the anode of the receiver line so that the cathode and the anode of the receiver line are operated in a low frequency environment to operate the receiver line as a single radiator in a high-
Lt; / RTI >
Wherein the antenna signal and the audio signal are independently operated
An antenna for a wireless Bluetooth earset that utilizes a receiver line. The method according to claim 1,
The power supply circuit includes:
A feeding part including a feeding point for feeding an electric signal; And
A radiator for radiating a signal of a certain frequency band, one end of which is electrically connected to the ground,
Lt; / RTI >
The radiator being connected to the receiver line such that the receiver line is operated as a radiator
An antenna for a wireless Bluetooth earset that utilizes a receiver line. 3. The method of claim 2,
The power supply circuit includes:
A first capacitive element connected in series with the feeding point to the feeding part;
A second capacitive element connected in series between the ground and the radiator; And
A first inductive element connected in series between the radiator and the receiver line,
The antenna for a wireless Bluetooth earset utilizing a receiver line further comprising: The method of claim 3,
Wherein the first capacitive element and the second capacitive element are connected in series,
Controlling the input impedance by at least one or more capacitors
An antenna for a wireless Bluetooth earset that utilizes a receiver line. The method of claim 3,
Wherein the first inductive element comprises:
It consists of at least one inductor to adjust the operating frequency
An antenna for a wireless Bluetooth earset that utilizes a receiver line. The method according to claim 1,
Wherein the inductive element comprises a plurality of inductors connecting the cathode and the anode of the receiver line from the audio signal, the capacitive element being a capacitor
An antenna for a wireless Bluetooth earset that utilizes a receiver line. The method of claim 3,
The power supply circuit includes:
A second inductive element connected in series between the feed point and the first capacitive element; And
A third inductive element connected in series between the second capacitive element and the radiator,
The antenna for a wireless Bluetooth earset utilizing a receiver line further comprising: 8. The method of claim 7,
The power supply circuit includes:
A third capacitive element coupled in series between the radiator and the first inductive element coupled to the receiver line,
The antenna for a wireless Bluetooth earset utilizing a receiver line further comprising: delete delete In a wireless Bluetooth earset utilizing a receiver line,
A main body including an antenna module therein; And
A receiver connected to the antenna module via the receiver line,
Lt; / RTI >
The antenna module includes:
An antenna signal unit constituting a power supply circuit and operating the receiver line as a radiator in a high frequency environment;
A low frequency signal portion for transmitting a low frequency signal to the receiver line in a low frequency environment;
At least one passive element arranged to feed the antenna to the power feeding circuit;
An inductive element disposed between the power feeding circuit and the audio signal to shield the antenna signal from flowing to the end of the audio signal in a high frequency environment; And
A capacitive element disposed between the cathode and the anode of the receiver line for operating the cathode and anode of the receiver line in the low frequency environment and operating the receiver line as a single radiator in the high frequency environment;
Lt; / RTI >
The low frequency signal portion is an audio signal portion for transmitting an audio signal to the receiver line in the low frequency environment and the antenna signal and the audio signal are independently operated
Wireless Bluetooth earset that utilizes a receiver line. 12. The method of claim 11,
The power supply circuit includes:
A feeding part including a feeding point for feeding an electric signal; And
A radiator for radiating a signal of a certain frequency band, one end of which is electrically connected to the ground,
Lt; / RTI >
The radiator being connected to the receiver line such that the receiver line is operated as a radiator
Wireless Bluetooth earset that utilizes a receiver line. 13. The method of claim 12,
The power supply circuit includes:
A first capacitive element connected in series with the feeding point to the feeding part;
A second capacitive element connected in series between the ground and the radiator; And
A first inductive element connected in series between the radiator and the receiver line,
Wireless Bluetooth < RTI ID = 0.0 > earset. ≪ / RTI > 1. An antenna for a wireless Bluetooth ear-set utilizing a receiver line,
A feed circuit implemented on a substrate;
At least one passive element arranged to feed the antenna to the power feeding circuit;
An inductive element disposed between the power feeding circuit and the audio signal to shield the antenna signal from flowing to the audio signal terminal in a high frequency environment; And
A capacitive element which is disposed between the cathode and the anode of the receiver line so that the cathode and the anode of the receiver line are operated in a low frequency environment to operate the receiver line as a single radiator in a high-
Lt; / RTI >
The power supply circuit includes:
A feeding part including a feeding point for feeding an electric signal;
A radiator that maintains electromagnetic coupling with the feeding part and is electrically connected to the receiver line to radiate a signal of a certain frequency band;
An inductor and a capacitor connected to the feeding part in series with the feed point; And
A capacitor and an inductor connected in series between the radiator and the receiver line,
Lt; / RTI >
The radiator being connected to the receiver line such that the receiver line is operated as a radiator
An antenna for a wireless Bluetooth earset that utilizes a receiver line.

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