KR100340428B1 - Tuner for digital satellite broadcast - Google Patents

Abstract

The present invention relates to a digital satellite broadcasting broadband tuner that generates a stable oscillation frequency without using a high ratio of diverter diode by dividing the oscillation frequency band into an upper band and a lower band and configuring the oscillation means. Digital satellite broadcasting tuner includes a first tank circuit whose time constant (RC) is variable in the range of the channel corresponding to the first range of satellite broadcasting bands according to the external tuning voltage. A first oscillator for oscillating an oscillation frequency of a selected channel corresponding to a first range of the band, and a second tank circuit portion having a time constant varying in a range of a channel corresponding to a second range of the satellite broadcasting band according to an external tuning voltage. A second oscillator for oscillating an oscillation frequency corresponding to a channel in a second range of the satellite broadcasting reception band; Applying a tuning voltage corresponding to the selected channel to the switching section for selectively turning on / off the operating power of the second oscillation section and the second tank circuit section of the first oscillation section and the second tank circuit section of the second oscillation section according to an external control signal. And a phase locked loop (PLL) unit for controlling a switching operation of the switching unit.

Description

Tuner for digital satellite broadcasting {TUNER FOR DIGITAL SATELLITE BROADCAST}

The present invention relates to a digital satellite broadcasting tuner, and more particularly, to a digital satellite broadcasting wideband tuner, by which the oscillation frequency is divided into an upper band and a lower band and oscillated so that a stable oscillation operation is performed by a tuning voltage.

A general digital satellite tuner is shown in FIG.

As shown in FIG. 1, the digital satellite broadcasting tuner is received by a satellite antenna (not shown), and is converted into a high frequency signal by a low noise frequency converter (not shown) in the satellite antenna. After amplifying to a predetermined level so as to be processed by the following devices through 11, the bandpass filter 12 passes through and filters only frequency signals of a set passband (i.e., satellite broadcast band). Then, the frequency signal passed through the band pass filter 12 is again amplified by a predetermined level or more by the amplifier 13 to compensate for gain, and then the first and second mixers 16 and 17 through the two amplifiers 14 and 15. Enter at the same time. In the first and second mixers 16 and 17, the broadcast signals of the high frequency bands inputted are mixed with the oscillation frequencies (having a phase difference of 90 degrees from each other) inputted to different input terminals, respectively, to convert the high frequency signals into baseband signals. The baseband signals output from the first and second mixers 16 and 17 are again amplified by the respective amplifiers 13 and 14 and then output as I and Q signals. At this time, the oscillation frequency signal input to the first and second mixers 16 and 17 is generated by the oscillator 21, and the PLL 23 outputs a tuning voltage according to the control signals SCL and SDA input thereto. In this case, the RC value of the tank circuit unit 2 is determined by the tuning voltage, and the oscillator 21 oscillates to input a frequency signal according to the RC value to the first and second mixers 16 and 17. The oscillation frequency of the signal input to the second mixer 17 is delayed by 90 degrees by the delay unit 20 and then input to the second mixer 17.

Accordingly, the first and second mixers 16 and 17 frequency convert the received frequency signals into oscillation signals having the same frequency band but having a phase difference of 90 degrees, and output I and Q signals.

However, since the input frequency of the satellite tuner is usually 950 MHz to 2150 MHz, the frequency of the oscillation frequency (f _OSC ) used in frequency conversion is also the same 950 MHz to 2150 MHz. However, in some regions, such as Europe, broadcast frequencies are out of the input frequency band of the satellite broadcast tuner due to the saturation of the broadcast channel, and thus, the range of the oscillation frequency band is required to receive these channels. Should be wider.

By the way, in the conventional tuner, the tank circuit of an oscillation part is provided with the varactor diode which determines a time constant, ie, an oscillation frequency, which has the characteristic curvature of the voltage-band capacitance as shown in FIG. Therefore, when used in the tuner, only the 'A' portion of the tuning voltage can be obtained.

Therefore, in the conventional tuner configured as described above, there is a problem in that an expensive device having a high capacitance ratio is required for the diverter diode that determines the oscillation frequency range to include a wider range.

In order to solve the above-mentioned problems, the present invention divides an oscillation frequency band into an upper band and a lower band, separates the configuration into oscillation means, and generates digital oscillation frequency without using a high ratio of diverter diode. It is to provide a satellite broadcast broadband tuner.

1 is a block diagram showing the configuration of a conventional digital satellite broadcast tuner.

2 is a block diagram showing the configuration of a wideband tuner for digital phase broadcasting according to the present invention.

* Description of the symbols for the main parts of the drawings *

11, 13, 14, 15, 18, 19: amplifier 12: band pass filter

16, 17: mixing unit 20: delay unit

31: first oscillator 32: second oscillator

33: PLL 34: switching unit

311, 321: voltage controlled oscillator 312, 322: tank circuit part

As a construction means for achieving the above object of the present invention, the digital satellite broadcast tuner according to the present invention

In the digital satellite broadcasting tuner which converts the satellite signal of the selected channel among the high frequency satellite broadcasting signals into the I, Q signals of the baseband band,

Including a first tank circuit in which a time constant (RC) is varied in a range of channels corresponding to a first range of satellite broadcasting bands according to an external tuning voltage, and corresponding to a first range of satellite broadcasting reception bands according to an external tuning voltage. A first oscillator for oscillating the oscillation frequency of the selected channel;

A second tank for oscillating an oscillation frequency corresponding to a channel of a second range of the satellite broadcasting reception band, including a second tank circuit having a time constant variable in a range of a channel corresponding to the second range of the satellite broadcasting band according to an external tuning voltage; Oscillation Part,

A switching unit for selectively turning on / off operating power of the first oscillator or the second oscillator;

A phase synchronizing loop (PLL) for applying a tuning voltage corresponding to a selected channel to the first tank circuit part of the first oscillator and the second tank circuit part of the second oscillator according to an external control signal and controlling the switching operation of the switching part; Characterized in that.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation of the present invention.

2 is a block diagram showing the configuration of a digital satellite broadcast tuner according to the present invention. The tuner according to the present invention is a preamplifier 11 for amplifying a satellite broadcast signal received by a satellite antenna and converted into a high frequency signal. A band pass filter 12 configured to pass-through the output signal of the preamplifier 11 to remove out-of-signal noise, and a high-frequency satellite broadcast signal passed through the band pass filter 12. An amplifier 13 for compensating and amplifying the attenuation width, an amplifier 14, 15 for amplifying two separate satellite broadcast signals output from the amplifier 13, and the amplifier 14, ( First and second mixers 16 and 17 for mixing the satellite broadcasting signals of high frequency amplified by 15) with the oscillation frequencies having a phase difference of 90 degrees from each other and outputting I and Q of the basebands as the difference signals; Output from the first and second mixers 16 and 17 Output amplifiers 18 and 19 for amplifying and outputting a baseband satellite broadcast signal, and a 90 degree phase difference between the oscillation signal output from the oscillating means and the oscillation signal input to the first mixer 16 by 90 degrees. Is connected to the delay unit 20 for outputting the oscillation signal to the second mixer 17, the first voltage controlled oscillator 311 and the first voltage controlled oscillator 311, and a time constant related to higher band frequency oscillation. A first oscillator 31 for generating an RC value and oscillating an oscillation frequency corresponding to a selected channel of an upper band of the satellite broadcasting reception band according to an external tuning voltage; and a second voltage. Satellite broadcasting reception comprising a second oscillator circuit 322 for applying a time constant corresponding to a selected channel of a lower band of satellite broadcasting bands to the second voltage controlled oscillator 321 according to a control oscillator 321 and an external tuning voltage. Oscillation frequency corresponding to the lower band of the band A PLL 33 for applying a tuning voltage corresponding to a selected channel to the first oscillator 31 and the second oscillator 32 in accordance with the second oscillator 32 for oscillation and the external control signals SCL and SDA; In response to the control signal of the PLL 33, an operating power is selectively applied to the first voltage controlled oscillator 311 of the first oscillator 31 or the second voltage controlled oscillator 321 of the second oscillator 32. It consists of a switching unit 34.

The operation of the digital satellite tuner configured as above will now be described.

First, the front end of the digital satellite broadcast tuner, that is, the operation of the pre-amplifier 11 to the first and second amplifiers 14 and 15 using the same codes as the conventional constituent means, noise reduction by amplification and filtering of a received signal. Etc. are made in the same manner as in the prior art, and thus detailed description thereof will be omitted.

Therefore, a description will be given focusing on the part related to the present invention, that is, the oscillation part.

The present invention divides the entire satellite broadcasting band into an upper band and a lower band based on its center frequency.

The PLL 33 generates a tuning voltage of the oscillation frequency corresponding to the selected channel in accordance with the external control signals, SCL and SDA, and also controls switching according to whether the selected channel is an upper band or a lower band of the phase broadcasting band. The signal is applied to the switching unit 34, and the switching unit 34 switches the B + power of the main oscillation stage of the first voltage controlled oscillator 311 or the second voltage controlled oscillator 321 on / off.

In more detail, the switching operation 34 controls the first voltage controlled oscillator 311 of the first oscillator 31 when the selected channel is an upper band of the satellite broadcasting band under the control of the PLL 33. If the selected channel is the lower band of the satellite broadcasting band, the operating power is applied to the second voltage controlled oscillator 321 of the second oscillator 32, and if the selected channel is the upper band, The oscillator 31 is operated, and if the lower band, the second oscillator 32 is operated.

Both the first oscillator 31 and the second oscillator 32 receive the tuning voltage applied from the PLL 33 and oscillate and output a corresponding frequency signal. Since the time constant generation ranges of the tank circuit sections 312 and 322 are different, the oscillation frequency ranges are different.

For example, when a total frequency band of satellite broadcasting is 950 MHz to 2150 MHz, the first oscillator 31 oscillates a frequency of 1500 MHz to 2200 MHz so as to cover and receive broadcasts of channels outside the predetermined band. The oscillator 32 oscillates a frequency of 800 MHz to 1500 MHz.

Therefore, compared with the conventional case composed of one oscillator and one tank circuit, the frequency range to be covered in the oscillator is reduced, so that it is possible to use a varactor diode having a smaller ratio than the conventional case.

As described above, the oscillation signal output from the first oscillator 31 or the second oscillator 32 is input to the first mixer 16, and is delayed by 90 degrees through the delay unit 20, and then the second mixer ( 17).

The first and second mixers 16 and 17 respectively mix the oscillation signals inputted with the satellite broadcast signals inputted to another input terminal and convert them into I and Q signals. The I and Q signals are amplified by the amplifiers 18 and 19, and then output to respective output stages and input to a later stage device (e.g., a decoder).

As described above, the present invention is composed of two oscillators for generating the oscillation signal of the upper and lower bands of the tuner, respectively, and can be implemented with a lower ratio varistor diode than the conventional one, and the tuner is more There is an excellent effect that can cover a wide range of bands.

Claims (2)

In the digital satellite broadcasting tuner which converts the satellite signal of the selected channel among the high frequency satellite broadcasting signals into the I, Q signals of the baseband band, According to the external tuning voltage, the satellite broadcasting band is divided into a first range and a second range, and a first tank circuit portion having a time constant (RC) variable in a range of a channel corresponding to the first range includes an external tuning voltage. A first oscillator for oscillating an oscillation frequency of a selected channel corresponding to a first range of the satellite broadcasting reception band; A second tank for oscillating an oscillation frequency corresponding to a channel of a second range of the satellite broadcasting reception band, including a second tank circuit having a time constant variable in a range of a channel corresponding to the second range of the satellite broadcasting band according to an external tuning voltage; Oscillation Part, A switching unit for selectively turning on / off operating power of the first oscillator or the second oscillator; A phase synchronizing loop (PLL) for applying a tuning voltage corresponding to a selected channel to the first tank circuit part of the first oscillator and the second tank circuit part of the second oscillator according to an external control signal and controlling the switching operation of the switching part; Digital satellite tuner, characterized in that. 2. The digital satellite broadcast tuner of claim 1, wherein the first range is an upper band of the satellite broadcasting bands and the second range is a lower band.