JPH10209910A - Bidirectional communication equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide low-price bidirectional communication equipment. SOLUTION: An RF filter 22 for reception is composed of a dielectric resonator directly mounted on a printed circuit board, passes a reception band and attenuates a transmission frequency component, an RF filter 38 for transmission is composed of a dielectric resonator directly mounted on this printed circuit board, passes a transmission band and attenuates a reception frequency component and an inter-step filter 25 for reception is composed of a dielectric resonator directly mounted on this printed circuit board and attenuates a reception image frequency. Thus, by using dielectric resonators for filters, the low-price bidirectional communication equipment can be provided.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a two-way communication device used for portable telephones, cordless telephones and the like.

[0002]

2. Description of the Related Art A conventional two-way communication device will be described below.

A conventional two-way communication apparatus will first describe a receiving system. As shown in FIG. 8, an antenna terminal 1, a receiving SAW filter 2 connected to the antenna terminal 1,
A high-frequency amplifier (hereinafter, referred to as an RF amplifier) 3 connected to the output of the receiving SAW filter 2, an output of the RF amplifier 3 is connected to one input, and the other input is an output of the receiving local oscillator 4. Mixer 5 connected to
A buffer amplifier 6 to which the output of the mixer 5 is connected, an intermediate frequency filter (hereinafter referred to as an IF filter) 7 to which the output of the buffer amplifier 6 is connected, and an intermediate frequency filter to which the output of the IF filter 7 is connected. A frequency amplifier (hereinafter, referred to as an IF amplifier) 8, a demodulator 9 to which the output of the IF amplifier 8 is connected, and a demodulation output terminal 10 to which the output of the demodulator 9 is connected.

Next, the transmission system will be described.
1, a transmission oscillator 12 connected to the modulation input terminal 11, a buffer amplifier 13 connected to the output of the transmission oscillator 12, a drive amplifier 14 connected to the output of the buffer amplifier 13, Drive amplifier 1
4 and a transmission SAW filter 16 connected between the output of the power amplifier 15 and the antenna terminal 1.

[0005]

However, in such a conventional configuration, there is a problem that the reception SAW filter 2 and the transmission SAW filter 16 have very high performance but increase the cost.

The present invention has been made to solve such a problem, and has as its object to provide a low-cost two-way communication device.

[0007]

In order to achieve this object, a two-way communication apparatus according to the present invention comprises an antenna terminal, a receiving filter to which a signal from the antenna terminal is supplied, and an output signal of the receiving filter. , A receiving interstage filter to which an output signal of the high frequency amplifier is supplied, and an output signal of the receiving interstage filter being supplied to one input and receiving to the other input. A mixer to which an output signal of the local oscillator is supplied; a demodulator to which an output signal of the mixer is supplied; a demodulation output terminal to which an output signal of the demodulator is supplied; a modulation input terminal; A transmission oscillator to which a signal of an input terminal is supplied, and a transmission filter connected between the transmission oscillator and the antenna terminal; The transmission filter is configured by a dielectric resonator directly mounted on the printed circuit board by a plurality of transmission filters alone, which attenuates a transmission frequency component while passing a reception band and configured by a directly mounted dielectric resonator. A band is passed and a receiving frequency component is attenuated, and the receiving interstage filter is configured by a plurality of dielectric resonators individually mounted directly on the printed circuit board and configured to attenuate a receiving image frequency. is there.

Thus, a low-cost two-way communication device can be realized.

[0009]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The invention according to claim 1 of the present invention is directed to an antenna terminal, a receiving filter to which a signal of the antenna terminal is supplied, and a high-frequency amplifier to which an output signal of the receiving filter is supplied. A receiving interstage filter to which the output signal of the high-frequency amplifier is supplied, and an output signal of the receiving interstage filter being supplied to one input and an output signal of the receiving local oscillator being supplied to the other input. , A demodulator to which an output signal of the mixer is supplied, a demodulation output terminal to which an output signal of the demodulator is supplied, a modulation input terminal, and a signal to be supplied to the modulation input terminal. And a transmission filter connected between the transmission oscillator and the antenna terminal, wherein a plurality of the reception filters are individually mounted on the printed circuit board directly. And a transmission frequency component is attenuated while passing through a reception band, and the transmission filter is composed of a plurality of dielectric resonators that are individually mounted directly on the printed circuit board. And the interstage filter for reception is
A bidirectional communication device comprising a plurality of dielectric resonators directly mounted on the printed circuit board alone and attenuating a reception image frequency, wherein the reception filter, the transmission filter, and the reception stage Since the filter is composed of a dielectric resonator, a low-cost two-way communication device can be provided. In addition, since the reception filter passes the reception band and attenuates the transmission frequency component, the transmission component does not enter the reception and the reception with less transmission suppression can be performed. Further, since the transmission filter passes the transmission band and attenuates the reception frequency component, the component at the time of reception does not enter the transmission, and no unnecessary component is output from the antenna. Further, the interstage filter for reception attenuates the reception image frequency, so that the interference characteristics are improved.

According to a second aspect of the present invention, there is provided a receiving filter and a transmitting filter, wherein an input terminal, the input terminal and the first
A first capacitor connected between the first connection point and the ground; a first dielectric resonator connected between the first connection point and the ground; a first capacitor connected between the first connection point and the second connection point. A parallel connection of a second capacitor and a first inductance connected to a connection point; a second dielectric resonator connected between the second connection point and ground; 2. The two-way communication device according to claim 1, comprising a third capacitor connected between the connection point of No. 2 and an output terminal, wherein the first inductance is an air-core coil, and its value is adjustable. 3. Since it can be composed only of the dielectric resonator, the air-core coil, and the capacitor, the cost is low, the adjustment is easy with the air-core coil, and the size can be reduced.

According to a third aspect of the present invention, there is provided a receiving interstage filter, comprising: an input terminal, a first capacitor connected between the input terminal and a first connection point, and the first connection point. A series connection of a fourth capacitor and a first dielectric resonator connected between the first connection point and the second connection point;
A third capacitor connected between the second connection point and the ground, a fifth capacitor connected between the second connection point and the ground, and a second dielectric. 2. The bidirectional communication device according to claim 1, comprising a series connection of resonators and a third capacitor connected between said second connection point and an output terminal. Since the cue (hereinafter referred to as Q) is high, the image attenuation can be high. Therefore, the interference characteristics are improved.

The high-frequency amplifier according to the fourth aspect of the present invention comprises:
The bidirectional communication device according to any one of claims 1 to 3, wherein the first high-frequency amplifier and the second high-frequency amplifier are connected in series.
Leakage of the reception local component to the antenna side is reduced by the two-stage high-frequency amplifier.

According to a fifth aspect of the present invention, when the reception frequency is higher than the transmission frequency, the local frequency of reception is set higher than the reception frequency. Since the frequency is far from the transmission frequency, the influence on the transmission frequency is reduced. Conversely, the transmission frequency less affects the local frequency. Therefore, the interference characteristics are good.

According to a sixth aspect of the present invention, when the reception frequency is lower than the transmission frequency, the local frequency of reception is lower than the reception frequency. Since the frequency is far from the transmission frequency, the influence on the transmission frequency is reduced. Conversely, the transmission frequency less affects the local frequency. Therefore, the interference characteristics are good.

According to a seventh aspect of the present invention, there is provided a printed circuit board mounted in a metal frame, a filter mounted on a front surface of the printed circuit board, and a high frequency amplifier mounted on a back surface of the printed circuit board. 2. The two-way communication device according to claim 1, further comprising: a lower surface of the filter, and a surface of the printed circuit board having a ground pattern. The characteristics are stabilized, and the amplification degree is also stabilized because there is a ground pattern between the high-frequency amplifier and the filter on the back surface.

According to the present invention, there is provided an intermediate frequency filter provided between the mixer and the demodulator, a metal partition plate for partitioning the inside of the frame, and a bent portion formed by bending the partition plate. A voltage-controlled oscillator forming a part of the local oscillator for reception is formed on the surface of the printed circuit board facing the bent portion, and a ground pattern is formed on the back surface of the printed circuit board on which the voltage-controlled oscillator is formed. 8. The bidirectional communication device according to claim 7, wherein the intermediate frequency filter is mounted on an upper surface of the bent portion. Since the voltage controlled oscillator is surrounded by the bent portion and the ground pattern, interference occurs. Hateful. Further, since the intermediate frequency filter is mounted on the upper surface of the bent portion, it is resistant to vibration and the mounting space can be reduced.

According to a ninth aspect of the present invention, there is provided the bidirectional communication device according to the eighth aspect, wherein the ground position of the intermediate frequency filter is set near the frame. Because it is stable,
The attenuation characteristics are improved.

According to a tenth aspect of the present invention, there is provided the two-way communication device according to the ninth aspect, wherein the legs of the intermediate frequency filter are clinched. The frequency does not shift and the characteristics of the filter do not vary.

[0019] According to an eleventh aspect of the present invention, there is provided the two-way communication device according to the tenth aspect, wherein the intermediate frequency filter is fixed to the bent portion with an adhesive. Thus, the filter characteristics do not deteriorate.

The demodulator according to the twelfth aspect of the present invention is configured in an integrated circuit, mounted on a printed circuit board, and a filter connected to the demodulator is inclined with respect to the printed circuit board. The two-way communication device according to claim 8, wherein the filter is fixed with an adhesive, while being inserted and bonded to the integrated circuit with an adhesive.
Stable filter characteristics can be obtained.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram of a two-way communication device according to the present invention. In FIG. 1, the receiving system will be described first. An antenna terminal 21 and an antenna terminal 2
1 and a receiving RF bandpass filter (used as an example of a receiving filter) 22
An RF amplifier 23 connected to the output of the band-pass filter 22, an RF amplifier 24 connected to the output of the RF amplifier 23, and a trap filter (an example of a receiving interstage filter) connected to the output of the RF amplifier 24; And a mixer 27 to which the output of the trap filter 25 is connected to one input and the other input is connected to the output of the local oscillator 26 for reception, and the output of the mixer 27 is connected. A buffer amplifier 28, and an IF filter 29 to which the output of the buffer amplifier 28 is connected.
An IF amplifier 30 to which the output of the IF filter 29 is connected, a demodulator 31 to which the output of the IF amplifier 30 is connected, and a demodulation output terminal 32 to which the output of the demodulator 31 is connected. ing. Here, the local oscillator for reception 26 includes a dual PLL-IC 39, a reception local VCO 26a having a PLL loop formed with the dual PLL-IC 39, a buffer amplifier 26b to which an output of the reception local VCO 26a is connected, and a buffer amplifier 26b. Buffer amplifier 26c to which the output of 26b is connected
It is composed of The demodulator 31 is composed of an integrated circuit. The input is connected to the IF amplifier 31a and the output is connected to the FM detector 31b. Also,
An IF filter 31c is connected outside the integrated circuit between the IF amplifier 31a and the FM detector 31b.

Next, the transmission system will be described. As shown in FIG. 1, a modulation input terminal 33, a transmission local oscillator 34 connected to the modulation input terminal 33, and a transmission local oscillator 3
4 and a drive amplifier 36 to which the output of the buffer amplifier 35 is connected.
A power amplifier 37 to which the output of the drive amplifier 36 is connected, and a transmission RF band-pass filter (an example of a transmission filter) connected between the output of the power amplifier 37 and the antenna terminal 21. ) 38. Here, the transmission local oscillator 34
The dual PLL-IC 39 and the dual PLL-I
C39 and a transmission VCO 34a in which a PLL loop is formed.

Next, an RF filter and an RF amplifier forming the high frequency circuit 20 will be described with reference to FIG. That is, this is the portion enclosed by the dotted line in FIG.
Antenna terminal 21 and RF bandpass filter 2 for reception
2, an RF amplifier 23, an RF amplifier 24, a trap filter 25, a drive amplifier 36, a power amplifier 37, and a transmission RF bandpass filter 38. The receiving RF bandpass filter 22 includes an input terminal 22a, a capacitor 221 connected between the input terminal 22a and the connection point A, and a dielectric resonator 222 connected between the connection point A and the ground. A parallel connection of a capacitor 223 and an inductance 224 connected between the connection point A and the connection point B; a dielectric resonator 225 connected between the connection point B and the ground; Third capacitor 226 connected between the output terminal 22b
The first inductance 224 is an air-core coil, and its value is adjustable.

Similarly, the transmission RF band-pass filter 38 has an input terminal 38a and a connection point E connected to the input terminal 38a.
381, a dielectric resonator 382 connected between the connection point E and the ground, and a capacitor 3 connected between the connection point E and the second connection point F.
83 and an inductance 384, and a connection point F
A dielectric resonator 385 connected between the ground and the ground;
The capacitor 386 is connected between the connection point F and the output terminal 38b. The inductance 384 is an air-core coil, and its value can be adjusted.

The trap filter 25 includes an input terminal 25a, a capacitor 251 connected between the input terminal 25a and the connection point C, and a capacitor 252 connected between the connection point C and the ground. A series connection of the body resonator 253, a parallel connection of a capacitor 254 and an inductance 255 connected between the connection point C and the connection point D, and a capacitor 256 connected between the connection point D and the ground. A series connection of the dielectric resonator 257 and a connection point D
258 connected between the output terminal 25b
It is composed of These dielectric resonators 253, 257
Has a high Q, so that a high image attenuation can be obtained. Therefore, the interference characteristics are improved. Further, the RF amplifier 23 and R
Since the F-amplifier 24 is connected in series, the received signal increases and leakage of the received local component to the antenna side decreases.

Referring to FIG. 3, first, FIG.
Indicates the frequency relationship, and the reception frequency f _RX (902.
When 9 MHz is lower than the transmission frequency f _TX (926.9 MHz), the local frequency f _LO (892.2 MHz) is lower than the reception frequency f _RX . Therefore, the influence of the local frequency f _LO on the transmission frequency f _TX is reduced. Also, the transmission frequency f _TX is _equal to the local frequency f
It has less effect on the _LO . Next, FIG. 3A shows the filter characteristics. The transmission filter 38 passes the transmission band and attenuates the reception frequency component G by 30 dB, and the reception filter 39 includes the reception RF bandpass filter 22 and the trap filter. 25,
Pass the receiving band and transmit frequency component H by 30d
B, and the image frequency component J is attenuated by 40 dB. Therefore, the interference characteristics are improved.

Referring to FIG. 4, first, FIG.
Indicates a frequency relationship, and the reception frequency f _RX (926.
When the transmission frequency f _TX (92.9 MHz) is higher than the transmission frequency f _TX (902.9 MHz), the local frequency f _LO (937.6 MHz) may be higher than the reception frequency f _RX . By doing so, the local frequency f _LO has less influence on the transmission frequency f _TX . Further, the transmission frequency f _{TX hardly} affects the local frequency f _LO . Next, FIG. 4A shows the filter characteristics. The transmission filter 38 allows the transmission band to pass and attenuates the reception frequency component K by 30 dB.
An F band-pass filter 22 and a trap filter 25 pass through the reception band and attenuate the transmission frequency component L by 30 dB.
Is attenuated by 40 dB. Therefore, the interference characteristics are improved.

Next, the component arrangement in the present embodiment will be described with reference to FIG. FIG. 5A is a plan view of the two-way communication device as viewed from above, in which a printed board 42 mounted in a metal frame 41, a filter 43 mounted on the surface of the printed board 42, The printed circuit board 4
2 and a high-frequency amplifier 44 mounted on the back surface of the optical amplifier 2. Here, it is assumed that the filter 43 includes the reception RF bandpass filter 22, the trap filter 25, and the transmission RF bandpass filter. Then, the lower surface of the filter 43 and the printed circuit board 42
Is a ground pattern 42a. This is shown in FIG. Since the filter 43 is mounted on the ground pattern 42a, the filter characteristics are stabilized, and the high-frequency amplifier 44 and the filter 4
3, there is a ground pattern 42a, so that the amplifier circuit is also stabilized. Here, the high-frequency amplifier 44 includes the RF amplifier 23, the RF amplifier 24, the drive amplifier 36, and the power amplifier 37.

Referring to FIG. 6, there is provided an intermediate frequency filter 29 and a metal partition plate 53 for partitioning the inside of the frame 41.
Bent portion 5 formed by bending the partition plate 53
4 are formed. The receiving local oscillator 26 is disposed on the printed circuit board 42 facing the bent portion 54. A ground pattern 42c is formed on the back surface of the printed circuit board 42 on which the receiving local oscillator 26 is formed,
The intermediate frequency filter 2 is provided on the upper surface of the bent portion 54.
9 is installed. Thus, the local oscillator for reception 26
Is surrounded by the bent portion 54 and the ground pattern 42c, so that interference hardly occurs. Further, since the intermediate frequency filter 29 is fixed by the adhesive 56 on the upper surface of the bent portion 54, it is resistant to vibration and the space can be reduced. Also,
The ground position of the intermediate frequency filter 29 is
, And the ground of the intermediate frequency filter 29 is stabilized, so that the attenuation characteristic is good. Also, the clinch processing 29b is applied to the leg 29a of the intermediate frequency filter 29, and the adhesion position of the intermediate frequency filter 29 is not fixed in the dipping step, so that the frequency does not move and the characteristics of the filter do not vary. Further, the intermediate frequency filter 29 is fixed to the bent portion 54 with an adhesive 56, and the filter characteristics do not deteriorate due to vibration.

Finally, FIG. 7 will be described. Demodulator 3
Reference numeral 1 denotes a filter which is configured in the integrated circuit 61 and mounted on the printed circuit board 42, and a filter 31c connected to an input of the FM detector 31b in the integrated circuit 61 is inclined with respect to the printed circuit board 42. And the filter is fixed to the integrated circuit 61 with an adhesive 64, and the filter is fixed, so that stable filter characteristics can be obtained. Further, since the filter 31c is mounted obliquely, the thickness can be reduced.

[0031]

As described above, according to the present invention, the receiving filter is composed of a plurality of dielectric resonators which are individually mounted directly on the printed circuit board to pass the receiving band and attenuate the transmitting frequency component. A plurality of the transmission filters are each composed of a dielectric resonator directly mounted on the printed circuit board alone, and pass a transmission band and attenuate a reception frequency component; In the two-way communication device configured by a dielectric resonator directly mounted on the printed circuit board to attenuate a reception image frequency, the reception filter, the transmission filter, and the reception interstage filter, Since it is composed of a dielectric resonator, a low-cost two-way communication device can be provided. In addition, since the reception filter passes the reception band and attenuates the transmission frequency component, the transmission component does not enter the reception and the reception with less transmission suppression can be performed.
Further, since the transmission filter passes the transmission band and attenuates the reception frequency component, the component at the time of reception does not enter the transmission, and no unnecessary component is output from the antenna. Further, the interstage filter for reception attenuates the reception image frequency, so that the interference characteristics are improved.

[Brief description of the drawings]

FIG. 1 is a block diagram of a two-way communication device according to an embodiment of the present invention.

FIG. 2 is a block diagram of a high-frequency circuit unit of the bidirectional communication device.

FIG. 3A is a filter waveform diagram of a two-way communication device, and FIG. 3B is a frequency relationship diagram thereof.

4A is a filter waveform diagram according to another example of the two-way communication device, and FIG. 4B is a frequency relationship diagram thereof.

FIG. 5A is a plan view of the same two-way communication device, and FIG.

FIG. 6A is a plan view showing the vicinity of a first intermediate frequency filter of the two-way communication device, and FIG.

FIG. 7A is a plan view showing the vicinity of a second intermediate frequency filter of the two-way communication device, and FIG.

FIG. 8 is a block diagram of a conventional two-way communication device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 21 Antenna terminal 22 RF band-pass filter for reception 23 RF amplifier 24 RF amplifier 25 Trap filter 26 Local oscillator for reception 27 Mixer 28 Buffer amplifier 29 IF filter 30 IF amplifier 31 Demodulator 32 Demodulation output terminal 33 Modulation input terminal 34 Local transmission Oscillator 35 Buffer amplifier 36 Drive amplifier 37 Power amplifier 38 RF bandpass filter for transmission

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Hironobu Okada 1006 Kadoma Kadoma, Osaka Prefecture Matsushita Electric Industrial Co., Ltd.

Claims (12)

[Claims] An antenna terminal, a receiving filter to which a signal of the antenna terminal is supplied, a high-frequency amplifier to which an output signal of the receiving filter is supplied, and a receiving filter to which an output signal of the high-frequency amplifier is supplied An inter-stage filter, a mixer in which an output signal of the inter-stage filter for reception is supplied to one input and an output signal of a local oscillator for reception is supplied to the other input, and an output signal of the mixer , A demodulation output terminal to which an output signal of the demodulator is supplied, a modulation input terminal, a transmission oscillator to which a signal of the modulation input terminal is supplied, the transmission oscillator and the antenna A transmission filter connected between the terminal and a terminal, wherein the reception filter is composed of a plurality of dielectric resonators individually mounted directly on a printed circuit board, and transmits and transmits a reception band. A transmission frequency component is attenuated, and the transmission filter is composed of a plurality of dielectric resonators individually mounted directly on the printed circuit board, passes a transmission band and attenuates a reception frequency component, and attenuates a reception frequency component. A two-way communication device for attenuating a reception image frequency, wherein the filter is composed of a plurality of dielectric resonators individually mounted directly on the printed circuit board. 2. The filter for reception and the filter for transmission,
An input terminal, a first capacitor connected between the input terminal and a first connection point, a first dielectric resonator connected between the first connection point and ground, The first
And a parallel connection of a second capacitor and a first inductance connected between the second connection point and a second connection point, and a second dielectric connected between the second connection point and the ground. 2. A body resonator, and a third capacitor connected between the second connection point and an output terminal, wherein the first inductance is an air-core coil and its value is adjustable. A two-way communication device according to claim 1. 3. An interstage filter for reception, comprising: an input terminal; a first capacitor connected between the input terminal and a first connection point; and a first capacitor connected between the first connection point and ground. A fourth capacitor connected in series with the first dielectric resonator; a third capacitor connected between the first connection point and the second connection point; A parallel connection, a series connection of a fifth capacitor and a second dielectric resonator connected between the second connection point and the ground, and a connection between the second connection point and an output terminal. 2. The two-way communication device according to claim 1, further comprising a third capacitor connected to the second capacitor. 4. The two-way communication device according to claim 1, wherein the high-frequency amplifier includes a first high-frequency amplifier and a second high-frequency amplifier connected in series. 5. When the reception frequency is higher than the transmission frequency,
The two-way communication device according to claim 1, wherein a local frequency of reception is higher than the reception frequency. 6. When the reception frequency is lower than the transmission frequency,
The two-way communication device according to claim 1, wherein a local frequency of reception is lower than the reception frequency. 7. A printed circuit board mounted in a metal frame, a filter mounted on a surface of the printed circuit board, and a high-frequency amplifier mounted on a back surface of the printed circuit board. 2. The two-way communication device according to claim 1, wherein the printed circuit board has a ground pattern. 8. An intermediate frequency filter provided between the mixer and the demodulator, a metal partition plate for partitioning the inside of the frame, and a bent portion formed by bending the partition plate. A voltage-controlled oscillator forming a part of a local oscillator for reception is formed on the surface of the printed circuit board facing the portion, and a ground pattern is formed on the back surface of the printed circuit board on which the voltage-controlled oscillator is formed, and the upper surface of the bent portion The two-way communication device according to claim 7, wherein the intermediate frequency filter is mounted on the communication device. 9. The two-way communication device according to claim 8, wherein the ground position of the intermediate frequency filter is near the frame. 10. The two-way communication device according to claim 9, wherein the legs of the intermediate frequency filter are clinched. 11. The two-way communication device according to claim 10, wherein the intermediate frequency filter is fixed to the bent portion with an adhesive. 12. A demodulator is formed in an integrated circuit, mounted on a printed circuit board, and a filter connected to the demodulator is inserted obliquely with respect to the printed circuit board and integrated with the integrated circuit. 9. The two-way communication device according to claim 8, wherein the two-way communication device is bonded to the circuit with an adhesive.