KR100244215B1 - Apparatus for receiving broadcasting signal - Google Patents

Abstract

The present invention relates to a device for controlling FPLL operation required for frequency lock in a frequency-phase locked loop (FPLL) system using a tuner with a built-in phase locked loop (PLL) device. A tuner for converting a post-IF signal, a demodulator for asynchronously detecting a carrier after amplifying only a frequency band of a desired signal among the IF signals output from the tuner, a VCO providing a carrier to the demodulator, and the VCO A PLL which controls the carrier of the synchronously synchronized with the intermediate frequency signal, and a switching unit which controls the operation of the FPLL on / off by PLL lock data of the tuner, and is built into the tuner instead of the conventional crystal oscillator. Negative lock data is used to turn on / off the operation of the FPLL to stabilize the operation of the FPLL, simplifying circuit configuration and reducing component costs. .

Description

Broadcast signal receiver

The present invention relates to a broadcast signal receiving apparatus using a frequency phase locked loop (FPLL), and more particularly, to a frequency lock (FPLL) system in a FPLL system using a tuner having a phase locked loop (PLL). The present invention relates to a device for generating an oscillation signal necessary for a frequency lock.

1 is a block diagram illustrating a conventional broadcast signal receiving apparatus. The tuner 11 tunes an RF input signal and converts the RF input signal into an intermediate frequency (IF) signal, and a desired signal from the IF signal output from the tuner 11. A SAW filter 12 that removes the remaining sections, leaving only a band of the signal, an IF amplifier 13 that amplifies the output of the SAW filter 12, a demodulator 14 that demodulates the amplified IF signal, and Voltage controlled oscillator (VCO) 16 for inputting carrier to demodulator 14, FPLL section 17, tuner 11 for changing the frequency and phase of IF signal carrier to remove bit frequency And a crystal oscillator 18 for generating a local oscillator frequency for generating an IF signal and providing it to an output stage of the IF amplifier 13.

In FIG. 1 configured as described above, when the RF signal is received through the antenna, the tuner 11 tunes using a channel selection signal output from the microcomputer 15 to select a desired broadcasting frequency, and then converts it into an IF signal by mixing with a local oscillator frequency. . The SAW filter 12 passes only the desired frequency band from the output of the tuner 11 to the IF amplifier 13 and removes all remaining bands. The IF amplifier 13 amplifies the IF signal passing through the SAW filter 12 under the control of the microcomputer 15 and outputs the demodulator 14. The demodulator 14 synchronously detects the amplified IF signal with a carrier provided from the VCO16 and outputs the composite image signal.

At this time, almost all devices use the FPLL unit 17 or the PLL device to synchronize the IF signal transmitted with the carrier. The crystal oscillator 18 generates a local oscillator frequency approximately equal to that of the IF signal under the control of the microcomputer 15, mixes it with the output of the IF amplifier 13, and outputs the demodulator 14 to the FPLL unit 17. ) Should not malfunction.

On the other hand, when there is no signal at the RF input or when switching channels, noise is generated at the output of the demodulator 14. This noise is input to the FPLL section 17, and shifts the frequency of the VCO 16. The VCO 16 will generally move to a lower frequency because of the influence of the SAW filter 12.

In this case, when the signal is input to the RF input terminal due to noise, the FPLL unit 17 fails to synchronize with the IF signal. In other words, there are bits corresponding to the frequency corresponding to the difference. In particular, the case where the size of the carrier relative to the signal is relatively small occurs more severely. Therefore, when the channel switching occurs, the crystal oscillator 18 is operated to force the oscillation frequency of the VCO 16 to oscillate at a position substantially similar to the IF signal (carrier) and then apply the tuned signal again. You can stop it.

However, the crystal oscillator 18 used to prevent the malfunction of the FPLL 17 is an unnecessary circuit that does not operate while receiving the actual signal. Therefore, the circuit configuration of the broadcast signal receiving apparatus becomes complicated and large, which causes a problem of increasing component cost.

The present invention is to solve the above problems, by using the lock data of the PLL unit built into the tuner instead of the crystal oscillator used to stabilize the operation of the FPLL by turning on / off the operation of the FPLL By stabilizing, there is provided a broadcast signal receiving apparatus which simplifies the circuit configuration.

A feature of the apparatus for receiving broadcast signals according to the present invention for achieving the above object is that a tuner having a built-in PLL unit and amplified by passing only a frequency band of a desired signal among IF signals output from the tuner are synchronized with a carrier A demodulation unit to detect, a VCO providing a carrier to the demodulation unit, an FPLL unit controlling the carrier of the VCO to be synchronized with an IF signal, and controlling the operation of the FPLL by PLL lock data of the tuner It is configured to include a switching unit.

1 is a block diagram of a conventional broadcast signal receiving apparatus

2 is a block diagram of a broadcast signal receiving apparatus according to the present invention

3 is a detailed block diagram of a double convergence tuner used as the tuner of FIG.

Explanation of symbols for main parts of the drawings

21: Tuner 22: Soo filter

23: IF amplifier 24: demodulator

25: Micom 26: VCO

27: FPLL section 29: switching section

32,28 Mixer 35,40 VCO built into tuner

34,39: Tuner's built-in PLL 33: Tuner's built-in crystal oscillator

31: amplifiers and filters 36,41: filters

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram illustrating a broadcast signal receiving apparatus for FPLL operation control according to the present invention.

Referring to FIG. 2, a PLL is built in, and a tuner 21 for tuning an RF input signal to an IF signal and a SAW filter for removing a remaining section leaving only a band of a desired signal from the IF signal output from the tuner 21. (22), an IF amplifier (23) for amplifying the output of the SAW filter (22), a demodulator (24) for synchronous detection of the amplified IF signal to a carrier, and a VCO (26) for inputting a carrier to the demodulator (24). ), The FPLL unit 27 for changing the frequency and phase of the IF signal and the carrier to remove the bit frequency, the microcomputer 25 for controlling the tuning of the tuner 21, and the PLL lock control of the tuner 21. As a result, the switching unit 29 is configured to control the operation of the FPLL unit 27 on / off.

The tuner 21 may be configured as a double conversion tuner, or may be configured as a single conversion tuner.

As shown in FIG. 3, the double conversion tuner amplifies and filters the RF signal received through the antenna from the amplifier 31 and the filter 31 to the first mixer 32, and outputs the first mixer 32. 32 selects only the frequency of the channel selected by the user by multiplying the signal output from the amplifier and filter 31 with the first local oscillator frequency.

At this time, the first VCO 35 provides the mixer 32 with a first local oscillator frequency proportional to the voltage output from the first PLL unit 34, and the first PLL unit 34 provides a crystal oscillator 33. After detecting the phase difference between the reference frequency generated in the reference frequency and the frequency fed back from the first VCO 35 and outputs a voltage proportional to the difference to the first VCO 35, the crystal oscillator 33 oscillates By providing a reference frequency to the first PLL section 34 by.

Then, the filter 36 passes only the desired broadcast signal components from the output signal of the first mixer 32 to the amplifier 37, amplifies them, and outputs them to the second mixer 38. The second mixer 38 multiplies the output of the amplifier 37 by the second local oscillator frequency, converts it into an IF signal which is a frequency band that is easy to handle in a general circuit, and then outputs it through the filter 41. 40 provides a second local oscillator frequency proportional to the voltage output from the second PLL section 39 to the mixer 38, and the second PLL section 39 is generated from the crystal oscillator 33. After detecting a phase difference between a reference frequency and a frequency fed back from the second VCO 40, a voltage proportional to the difference is provided to the second VCO 40. At this time, when a specific channel is selected by the user, the microcomputer 25 outputs the channel selection signal according to the first and second PLLs 34 and 39 to control the frequency of the corresponding channel to be selected.

Meanwhile, the SAW filter 22 passes only the desired frequency band from the output of the filter 41 of the tuner 21 to the IF amplifier 23 and removes all remaining bands. The IF amplifier 23 amplifies the IF signal passing through the SAW filter 22 by the control of the microcomputer 25 and outputs the demodulator 24. The demodulator 24 synchronously detects the amplified IF signal on a carrier and outputs the composite image signal.

At this time, the FPLL unit 27 is used to synchronize the IF signal transmitted with the carrier. That is, the FPLL unit 27 controls the VCO 26 to oscillate near the IF signal (carrier).

The switching unit 29 is switched by the difference frequencies of the first and second VCOs 35 and 40 of the tuner 21 to generate the same signal as the conventional crystal oscillator and provide the same to the FPLL unit 27. .

That is, assuming that the first local oscillator frequency provided by the first VCO 35 is f1 and the second local oscillator frequency provided by the second VCO 40 is f2, normally f2 is variable for automatic fine tuning (AFT). The range is often narrow and fixed.

In this case, when the IF output frequency is f _IF , it may be expressed as Equation 1 below.

f _IF = f1-f2

According to Equation 1, an IF signal may be generated.

For example, if f _IF signal is 46.69MHz and f2 is 876MHz, then oscillate f1 to 922.69MHz.

At this time, when the channel switching signal is input, this operation is performed before tuning the channel so that the VCO 26 is oscillated around the intermediate frequency and tuning is performed.

The switch unit 29 turns off the loop of the FPLL unit 27 while tuning is performed in order to prevent instantaneous noise from flowing into the VCO 26 during tuning. Thus, the VCO 26 is not duplexed and oscillation is maintained near the IF signal. Then, when the next tuning is completed, the switching unit 29 is turned on so that the loop of the FPLL unit 27 operates normally.

The control signal for turning on / off the switching unit 29 may use the lock output of the first PLL 34. That is, this control signal is output as a signal opposite to that of the stable state of the PLL loop during tuning, which means that a pulse is generated during tuning.

The control signal may be generated by the microcomputer 25 according to the characteristics of the peripheral circuit. When the tuning speed of the tuner 21 is much faster than the loop time constant of the FPLL unit 27, the switching unit 29 is always turned on. It is possible to warm up.

Therefore, the VCO 26 generates a frequency approximately equal to that of the IF signal even when channel tuning is performed under the control of the FPLL unit 27, thereby enabling stable channel tuning even without a crystal oscillator.

As described above, according to the broadcast signal receiving apparatus for controlling the operation of the FPLL according to the present invention, instead of the crystal oscillator, the operation of the FPLL is turned on / off using the lock data of the PLL unit inside the tuner, so that there is no signal at the RF input or the channel. Even in the case of switching, by stabilizing the operation of the FPLL, the circuit configuration is simplified, the component cost is reduced, and the quality is improved.

Claims (3)

A tuner incorporating a phase-locked loop (PLL) portion, which performs channel tuning from an input high frequency (RF) signal and converts it into an intermediate frequency (IF) signal A control unit controlling channel tuning of the tuner by a user input; A demodulator for synchronously detecting a carrier after amplifying only a frequency band of a desired signal among IF signals output from the tuner; A voltage controlled oscillator for providing a carrier to the demodulator; A frequency phase locked loop (FPLL) section for controlling a carrier of the voltage controlled oscillator to be synchronized with an intermediate frequency signal; And a switching unit which controls on / off operation of the FPLL by PLL lock data of the tuner. The method of claim 1, wherein the FPLL unit And a FPLL loop is turned off while tuning is performed by the control of the switching unit, and when the next tuning is completed, the FPLL loop operates normally. The method of claim 1, wherein the switching unit And controlling the operation of the FPLL on / off under the control of the controller.

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