KR101743773B1 - Rf signal processing circuit - Google Patents

Abstract

The present invention provides a hybrid RF signal processing circuit in which an analog demodulator and a digital demodulator do not affect each other in operation. The present invention relates to an RF signal receiver, A digital demodulator for demodulating an intermediate frequency signal output from the signal selection unit and outputting the demodulated digital signal; An analog demodulator for demodulating the intermediate frequency signal output from the signal selection unit and outputting the demodulated intermediate frequency signal as an analog signal; A trap circuit provided between the analog demodulator and the signal selection unit; And a RF signal processing circuit including a switch unit for selectively connecting the trap circuit and the signal selection unit.

RF signal, automatic gain, demodulator, switch.

Description

[0001] RF SIGNAL PROCESSING CIRCUIT [0002]

The present invention relates to an RF signal processing circuit, and more particularly, to an RF signal processing circuit operating in an analog mode and a digital mode.

With the development of wireless communication technology, it is possible to transmit and receive voice signals and video signals remotely. When a voice signal and a video signal are transmitted, a signal having a communication frequency of several hundred Mhz to several Ghz is used as an RF signal. The transmitting equipment combines the voice signal and the video signal with the RF signal, and the receiving equipment separates the RF signal, the voice signal and the video signal. At this time, coupling is called modulation and demodulation is called separation.

Generally, an RF signal processing apparatus amplifies an inputted RF signal, filters it by a signal of a desired frequency band, and then performs demodulation. In this process, noise is input and amplified as much as possible, and the RF signal needs to be amplified as needed to improve the characteristics of the RF signal processing device. There is an automatic gain control function in the internal operation of the RF signal processing circuit. If the size of the input RF signal is too small, it is detected and amplified, and if it is inputted too large, it is sensed to reduce the amplification.

In recent years, there are cases where an analog demodulator that processes an RF signal in an analog manner and a digital demodulator that processes a digital RF signal are provided together in one RF signal processing circuit. In this case, the RF signal processing circuit operates in the analog mode and the digital mode. However, since the analog demodulator and the digital demodulator interfere with each other, stable operation can not be achieved.

The present invention provides a hybrid RF signal processing circuit in which an analog demodulator and a digital demodulator do not affect each other in operation.

The present invention relates to an RF signal receiver, A digital demodulator for demodulating an intermediate frequency signal output from the signal selection unit and outputting the demodulated digital signal; An analog demodulator for demodulating the intermediate frequency signal output from the signal selection unit and outputting the demodulated intermediate frequency signal as an analog signal; A trap circuit provided between the analog demodulator and the signal selection unit; And a RF signal processing circuit including a switch unit for selectively connecting the trap circuit and the signal selection unit.

Further, the RF signal processing circuit of the present invention includes a digital SAW filter between the digital demodulator and the signal selection unit.

In addition, the RF signal processing circuit of the present invention includes an analog SAW filter between the analog demodulator and the signal selection unit.

The switch unit is controlled by the digital demodulator.

The digital demodulator receives a signal in the range of 32.125 to 40.125 MHz and demodulates the signal.

In addition, the analog demodulator receives a signal in the range of 33.4 to 38.9 MHz and demodulates the signal.

Also, the RF signal processing circuit of the present invention includes: a filter unit for receiving and filtering an input RF signal; A first RF amplifier for amplifying the filtered RF signal; A first peer inquiry for transmitting only a desired band of the RF signal amplified by the RF amplifier; A second RF amplifier for amplifying and transmitting an RF signal transmitted from the first tuning circuit in response to an automatic gain control signal provided from the signal selector; And a second tuning circuit for transmitting only a signal of a desired band out of the signals output from the second RF amplifier to the signal selector.

The reliability of operation of the hybrid RF signal processing circuit is improved because the analog demodulator and the digital demodulator do not work reliably with respect to each other according to the present invention. In particular, the analog demodulator can prevent malfunctions in the operation of the RF signal processing circuit.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, in order to facilitate a person skilled in the art to easily carry out the technical idea of the present invention. do.

1 is a block diagram showing an RF signal processing circuit for explaining the present invention.

1, the RF signal processing circuit includes an input filter unit 10, an RF amplifier 20, a filter unit 41, an RF amplifier 42, a filter unit 43, a signal selection unit 44, A trap circuit 50, a digital SAW filter 51, an analog SAW filter 52, a digital demodulator 53, and an analog demodulator 54.

The input filter unit 10 transmits a signal of a desired band among the RF signals inputted through the antenna. The RF amplifier 20 amplifies a signal transmitted from the input filter unit 10. The RF amplifier 42 adjusts the amplification degree of the input signal in response to the automatic gain control signal AGC provided by the signal selector 44. [

The signal selection unit 44 selects and delivers an RF signal of a predetermined frequency band among the input signals. The signal selecting section 44 selects and transmits RF signals of a predetermined frequency band including a phase locked loop circuit 44A, a mixing circuit 44B and an amplifier 44C. In recent years, And the like. In addition, the signal selector 44 receives a clock signal of 4 MHz provided by the oscillator circuit for the operation of the blocks provided therein.

The digital SAW filter 51 filters and outputs the intermediate frequency signal IF output from the signal selection unit 44. [ The analog SAW filter 52 filters and outputs the intermediate frequency signal IF output from the signal selector 44. [ The digital demodulator 53 receives and demodulates the signal A outputted from the digital SAW filter 51 and the analog demodulator 54 outputs the signal B outputted from the analog SAW filter 52 Demodulate.

The SAW filter is a filter that uses a structure in which two comb-like metal plates are arranged on the piezoelectric substrate so as to be shifted on both sides and SAW (surface acoustic wave) is generated on the piezoelectric substrate when electrical signals are inputted in one direction. The SAW filter has a very narrow bandwidth to pass through compared to a filter using an artificial LC resonance principle, so that it almost completely filters out signals of unnecessary frequencies. So, if you want to select the frequency of the desired signal with a narrow bandwidth, the SAW filter is the best feature. And is widely used in an RF signal processing circuit using an intermediate frequency.

1, when the RF signal processing circuit is operated in combination with the analog mode and the digital mode, the digital SAW filter 51 and the analog SAW filter 52 receive the intermediate frequency signal IF . Due to such a structure, there is a problem of interference due to signals in the peripheral frequency band of the frequency band processed in the analog operation and other noise. To solve this problem, the trap circuit 50 is arranged in front of the analog SAW filter 52. However, there may arise a problem that the trap circuit 50 has an adverse effect on the operation in the digital mode.

The signal A output from the digital SAW filter 51 has a center frequency of 36.125 MHz and a band ranging from 32.125 MHz to 40.125 MHz. The signal B output from the analog SAW filter 52 is 33.4 MHz in the case of audio and 38.9 MHz in the case of video. The trap circuit has a frequency of 40.2 MHz to 40.7 MHz for N-1 and 30.5 MHz to 31 MHz for N + 1.

Since the signal A output from the digital SAW filter 51 and the signal B output from the analog SAW filter 52 are connected to the same signal path, the trap circuit 50 ) May cause data loss around 40.125 MHz.

Digital processing is less susceptible to Error Correction Code up to 64 QAM, but in the case of 256 QAM where processing data is rapidly increased, senstivity degradation occurs, In this case, deterioration in the performance of the adjacent interference occurs.

The quadrature amplitude modulation (QAM) scheme is a quadrature amplitude modulation scheme. One of the multi-level modulation schemes, which is a type of digital modulation scheme, is a scheme in which both the amplitude and the phase of the modulated carrier Modulation scheme. And is widely used as a high-speed modulator for digital transmission using an analog telephone line.

For example, if the amplitude of four values per one wave of the sweep wave and the phase of four values can be discriminated, 16 information can be transmitted. Therefore, if the carrier wave is 2400 Hz, transmission of 9600 bps is possible. To accurately determine the 16 value on the receiving side, it is necessary to restore the degraded characteristics of the telephone line. This is called automatic equalization. In recent years, automatic equalization techniques have been developed and high-speed modulators such as 32-bit QAM, 64-bit QAM, and 256-QAM have been introduced.

The present invention provides an RF signal processing circuit having a switch and capable of reducing adverse effects caused by a trap circuit and an analog demodulator when operating in a digital mode.

2 is a block diagram showing an RF signal processing circuit according to a preferred embodiment of the present invention.

2, the RF signal processing circuit according to the present embodiment includes an input filter unit 100, an RF amplifier 200, a filter unit 410, an RF amplifier 420, a filter unit 430, A selection circuit 440, a trap circuit 500, a digital SAW filter 510, an analog SAW filter 520, a digital demodulator 530, an analog demodulator 540 and a switch part 600.

The input filter unit 100 transmits a signal of a desired band among the RF signals input through the antenna.

The RF amplifier 200 amplifies and transmits a signal transmitted from the input filter unit 100. The filter units 410 and 430 filter and transmit the signal of the predetermined band. The RF amplifier 420 adjusts the amplification degree of the input signal in response to the automatic gain control signal AGC provided from the signal selector 44.

The signal selection unit 440 selects and delivers an RF signal of a predetermined frequency band among the input signals. The signal selector 440 selects and transmits an RF signal of a predetermined frequency band including a phase locked loop circuit 441, a mixing circuit 442 and an amplifier 443. Recently, And the like. The signal selector 440 receives a clock signal of 4 MHz provided by the oscillator circuit for the operation of the blocks provided therein.

The digital SAW filter 510 filters and outputs the intermediate frequency signal IF output from the signal selection unit 44. The analog SAW filter 520 filters and outputs the intermediate frequency signal IF output from the signal selector 440. The digital demodulator 530 receives and demodulates the signal A output from the digital SAW filter 510 and the analog demodulator 540 demodulates the signal B output from the analog SAW filter 520, do.

The digital SAW filter 510 and the analog SAW filter 520 receive the intermediate frequency signal IF as shown in FIG. 2 when the RF signal processing circuit is operated in both the analog mode and the digital mode, . Because of such a structure, a problem of interference due to signals in the peripheral frequency band of the frequency band processed in the analog operation and other noise occurs. To solve this problem, the trap circuit 500 is arranged in front of the analog SAW filter 520. However, there may arise a problem that the trap circuit 500 has an adverse effect on the operation in the digital mode.

The signal A output from the digital SAW filter 510 has a center frequency of 36.125 MHz and a band of 32.125 MHz to 40.125 MHz. The signal B output from the analog SAW filter 520 is 33.4 MHz in the case of audio and 38.9 MHz in the case of video. The trap circuit has a frequency of 40.2 MHz to 40.7 MHz for N-1 and 30.5 MHz to 31 MHz for N + 1.

As described above, since the signal A output from the digital SAW filter 510 and the signal B output from the analog SAW filter 520 are connected to the same signal path, when the digital signal is processed in the digital mode A data loss may occur in the vicinity of 40.125 MHz by the trap circuit 500.

To solve this problem, the RF signal processing circuit according to the present embodiment includes a switch unit 600. [ The switch unit 600 is turned off when operating in the digital mode, and turned on when operating in the analog mode. Although the control of the switch unit 600 can be variously controlled, the digital demodulator 530 controls the switch unit 600.

If the digital demodulator 530 is performing the demodulating operation, the digital demodulator 530 turns off the switch unit 600 and turns off the switch unit 600 if the demodulating operation is not performed.

Thus, since the switch unit 600 is provided, the influence of the analog demodulator 540 and the trap circuit 500 is eliminated while the RF signal processing circuit capable of operating in the digital mode and the analog mode processes the digital signal can do.

Therefore, the RF signal processing circuit according to the present embodiment can be provided with the original trap circuit 500 by adding the switch unit 600, thereby achieving a desired characteristic improvement, and at the same time, .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, I will understand. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the scope of the appended claims, as well as the appended claims.

1 is a block diagram showing an RF signal processing circuit for explaining the present invention.

2 is a block diagram showing an RF signal processing circuit according to a preferred embodiment of the present invention.

Description of the Related Art [0002]

100, 410, 430: Inquiry 100: Input filter unit

200,443: RF amplifier 600: switch

440: Signal selector 530: Digital demodulator

540: Digital Demodulator

Claims (7)

A signal selection unit including a phase locked loop circuit, a mixing circuit, and an amplifier, and outputting an RF signal as an intermediate frequency signal of a predetermined frequency band; A digital demodulator for demodulating an intermediate frequency signal output from the signal selection unit and outputting the demodulated digital signal; An analog demodulator for demodulating the intermediate frequency signal output from the signal selection unit and outputting the demodulated intermediate frequency signal as an analog signal; A trap circuit provided between the analog demodulator and the signal selection unit; And And a switch unit for selectively connecting the trap circuit and the signal selection unit, Wherein the switch unit is turned off when operating in a digital mode and turned on when operating in an analog mode. The method according to claim 1, And a digital SAW filter between the digital demodulator and the signal selection unit. The method according to claim 1, And an analog SAW filter between the analog demodulator and the signal selection unit. The method according to claim 1, And the switch unit is controlled by the digital demodulator. The method according to claim 1, Wherein the digital demodulator receives and demodulates signals in the range of 32.125 to 40.125 MHz. 6. The method of claim 5, The analog demodulator receives and demodulates signals in the range of 33.4 to 38.9 MHz. The method according to claim 1, A filter unit for receiving and filtering an input RF signal; A first RF amplifier for amplifying the filtered RF signal; A first peer inquiry for transmitting only a desired band of the RF signal amplified by the RF amplifier; A second RF amplifier for amplifying and transmitting an RF signal transmitted from the first tuning circuit in response to an automatic gain control signal provided from the signal selector; And And a second tuning circuit for transmitting only a signal of a desired band among the signals output from the second RF amplifier to the signal selector.

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