KR101331663B1 - Analog and digital satellite wave tuner - Google Patents

Abstract

The present invention relates to an analog and digital satellite wave tuner, wherein the analog and digital satellite wave tuner includes: a common input unit for tracking and outputting analog and digital satellite waves of a corresponding frequency band according to a tuning voltage corresponding to a tuned channel; An analog receiver configured to provide a tuning voltage according to the selected channel to the common input unit, receive analog and digital satellite waves tracked and output from the common input unit, and tune the analog satellite waves to demodulate them into a baseband (BB) signal; And a digital receiver which receives the analog and digital satellite waves tracked and output from the common input unit, tunes the digital satellite waves, and demodulates them into a transport stream (TS) signal, thereby converting the analog and digital satellite waves in a simple configuration using the common input unit. Since it is possible to receive at the same time, the complexity of the configuration is reduced and the cost is reduced. In particular, the digital receiver has an effect of improving the reception performance of the digital satellite wave since the frequency other than the selected frequency can be input by the common input unit. .

Description

ANALOG AND DIGITAL SATELLITE WAVE TUNER}

The present invention relates to an analog and digital satellite wave tuner.

In recent years, with the development of television technology, it has become possible for a broadcasting station to transmit an initial analog transmission television signal as a digital signal with the development of digital technology. Currently, the transmission of television signals using satellites is commercialized and broadcast. Terrestrial television signals can also be transmitted digitally.

The reason why the digital signal is transmitted digitally is that only one program can be transmitted in the analog transmission band in the same transmission band. However, three to four programs can be transmitted digitally. This is because the additional data can be transmitted in addition to the television program.

Unlike conventional analog and digital tuners, such a conventional analog and digital tuner starts with an analog broadcast signal (eg, NTSC, PAL and SECAM) and a digital broadcast signal (eg, DVB-C, DVB-T and As ATSC) exists at the same time, the analog-digital combined tuner converts and outputs a high frequency signal into an intermediate frequency signal, and also converts and outputs a zero intermediate frequency signal during digital conversion.

That is, the analog satellite tuner uses a heterodyne conversion method that converts and detects an inputted high frequency signal by converting an intermediate frequency signal, whereas a digital satellite tuner converts an input high frequency signal into a zero intermediate frequency signal and processes the detected signal. It uses a direct conversion method.

As such, the conventional analog and digital tuners had to have respective input stages due to the difference in the system between the analog receiver processing the analog signal and the digital receiver processing the digital signal.

Accordingly, the conventional analog and digital tuner has a somewhat complicated circuit configuration, and the complicated circuit configuration has a problem of lowering the reliability of the tuner and increasing the production cost.

The present invention has been made to solve the above problems, and an object of the present invention is to provide an analog and digital satellite wave tuner capable of receiving analog and digital satellite waves simultaneously.

It is also an object of the present invention to provide an analog and digital satellite wave tuner capable of improving the tuner performance by eliminating frequencies other than the selected frequency.

In order to achieve the above object, the analog and digital tuner according to an embodiment of the present invention, the common input unit for tracking and outputting the analog and digital satellite waves of the frequency band according to the tuning voltage corresponding to the tuned channel; An analog receiver configured to provide a tuning voltage according to the selected channel to the common input unit, receive analog and digital satellite waves tracked and output from the common input unit, and tune the analog satellite waves to demodulate them into a baseband (BB) signal; And a digital receiver configured to receive the analog and digital satellite waves tracked and output from the common input unit, and to tune the digital satellite waves to demodulate them into a transport stream (TS) signal.

The common input unit may include: a low noise amplifier which removes noise and amplifies a signal of a predetermined magnitude into analog and digital satellite waves input through an antenna; And a tracking filter that receives the analog and digital satellite waves amplified from the low noise amplifier and filters them to pass through the corresponding frequencies according to the tuning voltage V _T according to the tuned channel.

The tracking filter may further include: a first inter-step tuning circuit in which a capacitance of a first varactor diode is changed according to the tuning voltage V _T so that a first tuning band to be filtered is changed; A second end-to-end tuning circuit in which a capacitance of a second varactor diode is varied according to the tuning voltage V _T to vary a second tuning band to be filtered; And a voltage distribution circuit for distributing the tuning voltage V _T to the first and second stage tuning circuits.

The first inter-stage tuning circuit may include: a first LC series circuit comprising a first tuning capacitor connected in series with a first tuning inductor between a tuning voltage input terminal and ground; And a second tuning inductor disposed between a first point between the first tuning inductor and the first tuning capacitor and a signal input terminal, wherein the first varactor diode is parallel to the first LC series circuit. It is characterized in that the connection.

The second inter-stage tuning circuit may include: a second LC series circuit including a second tuning capacitor connected in series with a third tuning inductor between the tuning voltage input terminal and ground; And a fourth tuning inductor installed between a second point between the third tuning inductor and the second tuning capacitor and the signal output terminal, wherein the second varactor diode is connected in parallel to the second LC series circuit. It is characterized in that the connection.

A first voltage divider resistor disposed between a third point between the first varactor diode and the first tuning capacitor and a fourth point between the second varactor diode and the second tuning capacitor; And a second voltage divider resistor disposed between the tuning voltage input terminal and the fourth point.

The analog receiver may provide a tuning voltage V _T according to the tuned channel to the common input unit to amplify analog and digital satellite waves tracked and output from the common input unit, and then mix the first local oscillation frequency. An MLP circuit for converting a frequency into a first intermediate frequency signal and outputting the frequency; An analog saw filter for filtering only an analog satellite wave at the converted first intermediate frequency; A first intermediate frequency amplifier for amplifying the first intermediate frequency of the filtered analog satellite wave by compensating for the gain reduction generated during the filtering; And an analog demodulator for demodulating and outputting the first intermediate frequency signal of the amplified analog satellite wave to a baseband (BB) signal.

In this case, the first intermediate frequency signal is characterized in that 479.5MHz, the analog saw filter is characterized in that the bandpass filter (BPF), the analog demodulator is characterized in that the FM demodulator.

The MOPEL circuit may further include a first amplifier configured to amplify analog and digital satellite waves tracked and output from the common input unit; A first mixer for mixing the analog and digital satellite waves amplified by the first amplifier with a first local oscillation frequency and converting the frequency into a first intermediate frequency signal; A first local oscillator outputting the first local oscillation frequency to the first mixer; And receiving a clock signal Scl and the data signal Sda including the tuned channel information, and controlling the first local oscillation frequency to be compared with the frequency of the clock signal Scl, to the data signal Sda. And a first phase locked loop PLL providing the tuning voltage V _T to the common input unit.

The digital receiver may include: a zero intermediate frequency integrated circuit configured to amplify analog and digital satellite waves tracked and output from the common input unit, and then convert the frequency into a zero intermediate frequency signal by mixing with a second local oscillation frequency and outputting the frequency; And a digital demodulator for outputting the zero intermediate frequency signal of the output digital satellite wave as a transport stream (TS) signal.

In addition, the digital demodulator is characterized in that the FEC integrated circuit (Forward Error Correction IC).

The zero intermediate frequency integrated circuit may further include: a second amplifier amplifying analog and digital satellite waves tracked and output from the common input unit; A second mixer for mixing the analog and digital satellite waves amplified by the second amplifier with a second local oscillation frequency and converting the frequency into a zero intermediate frequency signal; A second local oscillator for outputting the second local oscillation frequency to the second mixer; A second phase locked loop (PLL) configured to receive the clock signal Scl and the data signal Sda including the tuned channel information and compare and control the second local oscillation frequency with the frequency of the clock signal Scl; A second intermediate frequency amplifier amplifying the converted zero intermediate frequency signal; And a digital saw filter for filtering only the digital satellite wave in the amplified zero intermediate frequency signal.

The features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings.

Prior to this, terms and words used in the present specification and claims should not be construed in a conventional, dictionary sense, and should not be construed as defining the concept of a term appropriately in order to describe the inventor in his or her best way. It should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention.

According to the present invention, it is possible to simultaneously receive analog and digital satellite waves in a simple configuration using a common input unit, thereby reducing the complexity of the configuration and reducing the cost.

In addition, in the digital receiver, the satellite wave input through the antenna is not directly input by the common input unit, and frequencies other than the selected frequency may be excluded so that the digital receiver receives the received performance (eg, IM2 and IM3). There is.

1 is a block diagram of an analog and digital satellite wave combination tun according to an embodiment of the present invention.
FIG. 2 is a detailed block diagram of the tracking filter shown in FIG. 1.
3A to 3B are diagrams showing examples of frequencies of analog satellite waves tracked through the tracking filter shown in FIG.
4A to 4B are diagrams showing examples of frequencies of digital satellite waves tracked through the tracking filter shown in FIG.

BRIEF DESCRIPTION OF THE DRAWINGS The objects, particular advantages and novel features of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG. It should be noted that, in the present specification, the reference numerals are added to the constituent elements of the drawings, and the same constituent elements are assigned the same number as much as possible even if they are displayed on different drawings. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

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

1 is a block diagram of an analog and digital satellite wave tuner according to an embodiment of the present invention, and FIG. 2 is a detailed block diagram of the tracking filter shown in FIG. 1.

1 and 2, the analog and digital satellite wave tuner according to an embodiment of the present invention includes a common input unit 100, an analog receiver 200, and a digital receiver 300.

The common input unit 100 tracks and outputs analog and digital satellite waves of a frequency band corresponding to a tuned channel to be input to the analog receiver 200 and the digital receiver 300 to be described later, and the low noise amplifier 110. Tracking filter 120.

The low noise amplifier 110 removes noise from analog and digital satellite waves input through an antenna and amplifies the signal to a tracking filter 120 by amplifying a level signal having an appropriate magnitude.

The tracking filter 120 receives the analog and digital satellite waves amplified from the low noise amplifier 110 and filters them to pass through the analog and digital satellite waves of the corresponding frequency band according to the tuning voltage V _T according to the tuned channel. Output

Then, the analog and digital satellite waves of the frequency band corresponding to the tuned channel are tracked through the tracking filter 120 and input to the analog receiver 200 and the digital receiver 300 to be described later.

In this case, the tuning voltage V _T is provided from the analog receiver 200 (more specifically, the first phase locked loop PLL 212) to be described later. The tuning voltage V _T will be described in more detail in the analog receiver 200 to be performed later.

As shown in FIG. 2, the tracking filter 120 has a first stage in which a capacitance of a _first varactor diode VD ₁ is varied according to the tuning voltage V _T so that a first tuning band to be filtered is varied. A second end-to-end tuning circuit 120-2 in which the capacitance of the _second varactor diode VD ₂ varies according to the tuning circuit 120-1 and the tuning voltage V _T so that the second tuning band to be filtered is changed. And a voltage distribution circuit 120-3 distributing the tuning voltage V _T to the first and second inter-step tuning circuits 120-1 and 120-2.

The first inter-stage tuning circuit 120-1 includes a first LC series circuit including a first tuning capacitor C ₁ connected in series with the first tuning inductor L ₁ between the tuning voltage input terminal 1 and ground. And a second tuning inductor L ₂ provided between the first point a between the _first tuning inductor L ₁ and the first tuning capacitor C ₁ and the signal input terminal ₂ . And the first varactor diode VD ₁ is connected in parallel to the first LC series circuit.

The second inter-phase tuning circuit 120-2 includes a second LC series consisting of a second tuning capacitor C ₂ connected in series with a third tuning inductor L ₃ between the tuning voltage input terminal 1 and ground. circuit, and the third copper casting inductor (L ₃₎ and the second copper casting capacitor (C _2), the fourth copper casting inductor claim provided between the second point (b) and the signal output terminal (3) between the (L ₄₎ And the second varactor diode (VD ₂ ) is connected in parallel to the second LC series circuit.

The voltage distribution circuit 120-3 may include a third point c between the _first varactor diode VD ₁ and the first tuning capacitor C ₁ and the second varactor diode VD ₂ . And a first voltage divider resistor R ₁ provided between a fourth point d between the second tuning capacitor C ₂ and the tuning voltage input terminal 1 and the fourth point d. It is configured to include a second voltage divider resistor (R ₂ ) installed in.

The tracking filter 120 has a capacitance (capacitance) of the first and second varactor diodes VD ₁ and VD ₂ varying according to the tuning voltage V _T so that a tuning band to be filtered is variable (that is, moving). It is possible to do so.

The tracking filter 120 in the present embodiment is composed of a double tuning circuit consisting of the first and second inter-step tuning circuits 120-1 and 120-2, but is not limited thereto. Circuits can be used.

3A to 3B show examples of frequencies of analog satellite waves tracked through the tracking filter shown in FIG. 1, and FIGS. 4A to 4B show examples of frequencies of digital satellite waves tracked through the tracking filter shown in FIG.

Specifically, FIG. 3A illustrates an input frequency (eg, 900 MHz to 2150 MHz) of an analog satellite wave received through an antenna, and FIG. 3B illustrates a frequency tracked through the tracking filter 120 when a low frequency analog satellite wave is tuned. 3C shows a frequency tracked through the tracking filter 120 when a high frequency analog satellite wave is tuned.

Similarly, FIG. 4B shows an input frequency (eg, 950 MHz to 2150 MHz) of a digital satellite wave received through an antenna, and FIG. 4B shows a frequency tracked through the tracking filter 120 when a low frequency digital satellite wave is tuned. 4C shows a frequency tracked through the tracking filter 120 when a high frequency digital satellite wave is tuned.

As shown in FIGS. 3A to 3C and 4A to 4C, analog and satellite wave signals simultaneously tracked at a frequency corresponding to a channel tuned using the common input unit 100 may be simultaneously inputted to the respective analog receivers 200 and digital receivers ( 300).

The analog receiver 200 provides a tuning voltage according to the tuned channel to the common input unit 100, receives analog and digital satellite waves tracked and output from the common input unit 100, and tunes an analog satellite wave to a baseband. Demodulate with a (Baseband; BB) signal.

The analog receiver 200 includes an MPLEL circuit 210, an analog saw filter 220, a first intermediate frequency amplifier 230, and an analog demodulator 240.

The MPL circuit 210 includes a first amplifier 211, a first mixer 214, a first local oscillator 213, and a first phase locked loop (PLL) 212 in one integrated circuit. A module configured to include analog and digital satellite waves that are tracked and output from the common input unit 100 by providing a tuning voltage V _T according to the selected channel to the common input unit (more specifically, the tracking filter 120). After amplifying and mixing with the first local oscillation frequency, the frequency is converted into a first intermediate frequency signal and output.

In this case, the tuning voltage V _T is determined by the first phase locked loop (PLL) 212 of the MOPEL circuit 210 to receive the tuned channel information from a predetermined controller (not shown) in the set. receiving the clock signal (Scl) and data signal (Sda) comprises providing the tuning voltage (V _T) of the corresponding channel to the common input unit 100 (for example, a tracking filter 120).

In addition, the first intermediate frequency signal may be set to a predetermined value. In the present invention, the first intermediate frequency signal may be set to 479.5 MHz.

The first amplifier 211 amplifies the analog and digital satellite waves tracked and output from the common input unit 100 to a predetermined magnitude.

The first mixer 214 mixes the analog and digital satellite waves amplified by the first amplifier 211 with a first local oscillation frequency and converts the frequency into a first intermediate frequency signal.

The first local oscillator 213 outputs the first local oscillation frequency to the first mixer 214.

The first phase locked loop (PLL) 212 receives the clock signal Scl and the data signal Sda including the tuned channel information, and converts the first local oscillation frequency into the frequency of the clock signal Scl. And control and provide the tuning voltage V _T according to the data signal Sda to the common input unit 100.

When the desired first intermediate frequency (for example, 479.5 MHz) is output through the MOPEL circuit 210, the analog saw filter 220 passes the analog satellite wave only, The first intermediate frequency amplifier 230 compensates and amplifies a reduction in the gain value generated during the filtering from the analog saw filter 220.

In this case, the analog saw filter 220 may be a band pass filter (BPF), for example.

The analog demodulator 240 demodulates the analog satellite wave amplified by the first intermediate frequency amplifier 230 and converts the analog satellite wave into a baseband (BB) signal.

The analog demodulator 240 may be, for example, an FM demodulator.

The baseband (BB) signal can then be decoded into audio and video signals via any audio / video codec in the set.

Meanwhile, the digital receiver 300 receives analog and digital satellite waves tracked and output from the common input unit 100, tunes digital satellite waves, and demodulates them into a transport stream (TS) signal.

The digital receiver 300 includes a zero IF IC 310 and a digital demodulator 320.

The zero IF IC 310 may include a second amplifier 311, a second mixer 314, a second local oscillator 313, a second phase locked loop (PLL) 312, and a second amplifier. 2 A module consisting of an intermediate frequency amplifier 315 and a digital saw filter 316 as one integrated circuit. A second local oscillation after amplifying the analog and digital satellite waves tracked and output from the common input unit 100. Mixed with frequency, converted into zero IF signal and output.

Here, the zero intermediate frequency signal means that the intermediate frequency is 0 MHz.

The second amplifier 311 amplifies the analog and digital satellite waves tracked and output from the common input unit 100 to a predetermined magnitude.

The second mixer 314 mixes the analog and digital satellite waves amplified by the second amplifier 311 with a second local oscillation frequency and converts the frequency into a zero intermediate frequency signal.

The second local oscillator 313 outputs the second local oscillation frequency to the second mixer 314.

The second phase locked loop (PLL) 312 receives the clock signal Scl and the data signal Sda including the tuned channel information, and converts the second local oscillation frequency into the frequency of the clock signal Scl. Compare and control.

When a desired zero intermediate frequency signal (0 MHz) is output through the second mixer 314, the digital saw filter is amplified to a level of a predetermined magnitude through the second intermediate frequency amplifier 315. Through 316, only digital satellite waves pass through.

Here, for example, a low pass filter (LPF) may be used as the digital saw filter 316.

The digital demodulator 320 demodulates the digital satellite wave filtered through the digital saw filter 316 of the zero IF IC 310 and converts it into a transport stream (TS) signal.

The digital demodulator 320 may be, for example, an FEC integrated circuit (Forward Error Correction IC).

The transport stream (TS) signal can then be decoded into video and audio signals via any MPEC codec in the set.

As described above, the analog and digital satellite wave tuner according to an embodiment of the present invention can simultaneously receive analog and digital satellite waves in a simple configuration by using the common input unit 100, thereby reducing the complexity of the configuration and the cost. This has the effect of being saved.

In particular, in the digital receiver 300, the satellite waves inputted through the antenna by the common input unit 100 may not be directly input, and frequencies other than the selected frequency may be excluded so that the digital receiver 300 may receive the digital satellite waves. Etc.) may be further strengthened.

Although the above has been described with reference to a preferred embodiment of the present invention, those skilled in the art to which the present invention pertains without departing from the spirit and scope of the present invention as set forth in the claims below It will be appreciated that modifications and variations can be made.

100: common input unit 110: low noise amplifier
120: tracking filter 200: analog receiver
210: MOPEL circuit 220: analog saw filter
230: first intermediate frequency amplifier 240: analog demodulator
300: digital receiving unit 310: zero intermediate frequency integrated circuit
315: second intermediate frequency amplifier 316: digital saw filter
320: digital demodulator

Claims (14)

A common input unit for tracking and outputting analog and digital satellite waves of a corresponding frequency band according to a tuning voltage corresponding to a tuned channel;
An analog receiver configured to provide a tuning voltage according to the selected channel to the common input unit, receive analog and digital satellite waves tracked and output from the common input unit, and tune the analog satellite waves to demodulate them into a baseband (BB) signal; And
A digital receiver configured to receive the analog and digital satellite waves tracked and output from the common input unit, and to tune the digital satellite waves to demodulate them into a transport stream (TS) signal;
The common input unit,
A low noise amplifier which removes noise from the analog and digital satellite waves input through the antenna and amplifies the signal into a level signal having a predetermined magnitude; And
And a tracking filter that receives the analog and digital satellite waves amplified from the low noise amplifier and filters them to pass through the corresponding frequencies according to the tuning voltage V _T according to the tuned channel.
The tracking filter,
A first inter-stage tuning circuit in which a capacitance of a first varactor diode is varied according to the tuning voltage V _T to vary a first tuning band to be filtered;
A second inter-stage tuning circuit in which a capacitance of a second varactor diode is varied according to the tuning voltage V _T so that a second tuning band to be filtered is varied; And
And a voltage distribution circuit for distributing the tuning voltage (V _T ) to the first and second stage tuning circuits.
delete delete The method of claim 1, wherein the first inter-end tuning circuit,
A first LC series circuit comprising a first tuning capacitor connected in series with the first tuning inductor between the tuning voltage input and ground; And
A second tuning inductor installed between a first point between the first tuning inductor and the first tuning capacitor and a signal input terminal,
And the first varactor diode is connected in parallel to the first LC series circuit.
The method according to claim 1, wherein the second inter-step tuning circuit,
A second LC series circuit comprising a second tuning capacitor connected in series with a third tuning inductor between the tuning voltage input terminal and ground; And
A fourth tuning inductor installed between a second point between the third tuning inductor and the second tuning capacitor and a signal output terminal,
And the second varactor diode is connected in parallel to the second LC series circuit.
The method according to any one of claims 4 to 5, wherein a third point between the first varactor diode and the first tuning capacitor and a fourth point between the second varactor diode and the second tuning capacitor are used. An installed first voltage divider resistor; And
And a second voltage divider resistor disposed between the tuning voltage input terminal and the fourth point.
The method according to claim 1, wherein the analog receiver,
Provides a tuning voltage (V _T ) according to the tuned channel to the common input unit, amplifies the analog and digital satellite waves tracked and output from the common input unit, and then mixes the first local oscillation frequency to a first intermediate frequency signal. An MOPEL circuit for converting and outputting;
An analog saw filter for filtering only an analog satellite wave at the converted first intermediate frequency;
A first intermediate frequency amplifier for amplifying the first intermediate frequency of the filtered analog satellite wave by compensating for the gain reduction generated during the filtering; And
And an analog demodulator for demodulating and outputting the first intermediate frequency signal of the amplified analog satellite wave into a baseband (BB) signal.
8. The tuner as claimed in claim 7, wherein the first intermediate frequency signal is 479.5 MHz.
8. The tuner as claimed in claim 7, wherein the analog saw filter is a band pass filter (BPF).
8. The tuner as claimed in claim 7, wherein the analog demodulator is an FM demodulator.
The method according to claim 7, wherein the MOPEL circuit,
A first amplifier amplifying analog and digital satellite waves tracked and output from the common input unit;
A first mixer for mixing the analog and digital satellite waves amplified by the first amplifier with a first local oscillation frequency and converting the frequency into a first intermediate frequency signal;
A first local oscillator outputting the first local oscillation frequency to the first mixer; And
In response to the clock signal Scl and the data signal Sda including the tuned channel information, the first local oscillation frequency is compared with the frequency of the clock signal Scl and controlled according to the data signal Sda. And a first phase locked loop (PLL) for providing the tuning voltage (V _T ) to the common input unit.
The method according to claim 1, wherein the digital receiver,
A zero intermediate frequency integrated circuit for amplifying the analog and digital satellite waves output from the common input unit and amplifying the analog and digital satellite waves and mixing them with a second local oscillation frequency to convert the frequency into zero intermediate frequency signals; And
And a digital demodulator for outputting a zero intermediate frequency signal of the output digital satellite wave as a transport stream (TS) signal.
13. The tuner as claimed in claim 12, wherein the digital demodulator is a forward error correction IC.
The method of claim 12, wherein the zero intermediate frequency integrated circuit,
A second amplifier amplifying analog and digital satellite waves tracked and output from the common input unit;
A second mixer for mixing the analog and digital satellite waves amplified by the second amplifier with a second local oscillation frequency and converting the frequency into a zero intermediate frequency signal;
A second local oscillator for outputting the second local oscillation frequency to the second mixer;
A second phase locked loop (PLL) configured to receive the clock signal Scl and the data signal Sda including the tuned channel information and compare and control the second local oscillation frequency with the frequency of the clock signal Scl;
A second intermediate frequency amplifier amplifying the converted zero intermediate frequency signal; And
And a digital saw filter for filtering only the digital satellite waves in the amplified zero intermediate frequency signal.

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