KR101171530B1 - High complex digital broadcasting receiving system - Google Patents

Abstract

The present invention relates to a high-complex digital broadcasting reception system, and outputs an RF signal input through one RF input terminal through an RF output terminal and a plurality of first to nth MT output terminals, and includes the RF signal in the RF signal through the RF input terminal. A master tuner unit for tuning a preselected channel among the selected channels; A plurality of first to n-th slave tuner units for tuning a pre-selected channel among channels included in an RF signal input through each of the plurality of first to n-th MT output terminals of the master tuner unit; A master demodulator for demodulating the IF signal from the master tuner unit; And a plurality of first to nth slave demodulators that demodulate IF signals from each of the plurality of first to nth slave tuner units.

Description

High-complex digital broadcasting reception system {HIGH COMPLEX DIGITAL BROADCASTING RECEIVING SYSTEM}

The present invention relates to a high-complex digital broadcast reception system that can be applied to a European digital TV set-top box, and more particularly, to a high-complex digital broadcast reception system implemented as a high-complex system including one master tuner unit and a plurality of slave tuner units. It is about.

In general, in the case of a single type PVR set-top box of the PVR set-top box, conventionally, a separate cable is connected to the loopthrough and the second tuner of the first tuner at the back end of the set-top box. shall.

As a solution to this, a One Can and Two Tuner system with two tuners in one can has been developed. According to this One Can tuner system, one RF receiving RF signal is received. The PVR viewing function is now possible with only the input terminal.

In conventional PVR set-top boxes, two or three DVB-C tuners can be used in one set to use the PVR function.

For example, in a DVB-C cable broadcasting system, when a signal output through a MOPLL IC is input to a digital demodulator through a SAW filter, the digital demodulator is software-connected to the amplified IF signal (I2C). ) To send the necessary signal to MPEG Demux.

In this operation, the TS signal is output from the demodulator during final locking, and the set-top box receives the signal from the MPEG decoder to view the screen. Using two or more of these DVB-C reception systems in a set enables PVR viewing of desired functions.

However, in the conventional PVR set-top box, in terms of the consumer or the set, each dual solution requires not only cost but also aesthetics and space because two tuners are connected through separate cables. It takes up a lot, and there is a problem in that unwanted bit interference occurs between two modules, resulting in a characteristically unstable part.

Also, on the consumer side, if you do not want to connect two tuners via separate cables, loop through must be connected through the pins of each module on the internal PCB. In this case, noise or There is also a problem that bit generation can be more severe.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above problems of the prior art, and the present invention provides a high-complex digital broadcast reception system implemented as a high-complex system including one master tuner unit and a plurality of slave tuner units. .

The first technical aspect of the present invention for solving the above problems of the present invention, and outputs an RF signal input through one RF input terminal through the RF output terminal, a plurality of first to n-th MT output terminal, the RF A master tuner unit for tuning a preselected channel among channels included in the RF signal through the input terminal; A plurality of first to n-th slave tuner units for tuning a pre-selected channel among channels included in an RF signal input through each of the plurality of first to n-th MT output terminals of the master tuner unit; A master demodulator for demodulating the IF signal from the master tuner unit; And a plurality of first to nth slave demodulators for demodulating IF signals from each of the plurality of first to nth slave tuner units.

The master tuner unit, AGC circuit unit for amplifying the RF signal through the RF input terminal; A first tuner IC for tuning a first channel selected in advance among channels included in the RF signal from the AGC circuit unit; A second tuner IC for tuning a second preselected channel among channels included in the RF signal from the AGC circuit unit; An LT circuit unit for adjusting the RF signal from the AGC circuit unit to a predetermined level and providing the RF signal to the RF output terminal; And a first-n-th MT circuit part which adjusts the RF signal from the AGC circuit part to a predetermined level and provides it to the plurality of first to n-th MT output terminals.

The master tuner unit provides a reference signal from a directly connected reference oscillator to each of the plurality of first to nth slave tuner units, and each of the plurality of first to nth slave tuner units is provided from the master tuner unit. A reference signal is provided to each of the plurality of first to nth slave demodulators, and the first slave tuner unit provides a reference signal from the master tuner unit to the master demodulator.

The master tuner unit shares a serial communication line with the master demodulator, and each of the plurality of first to nth slave tuner units shares a serial communication line with each of the plurality of first to nth slave demodulators. The master tuner unit may share a serial communication line with each of the plurality of first to nth slave tuner units.

In addition, the high-complex digital broadcast receiving system of the present invention further comprises an RF input unit formed between the RF input terminal and the input terminal of the master tuner unit, amplifying an RF signal from the RF input terminal and outputting the RF signal to the master tuner unit. It is characterized by.

In addition, the high-complex digital broadcast receiving system of the present invention comprises a signal between the RF input unit, the master tuner unit, the plurality of first to nth slave tuners, the master demodulator and the plurality of first to nth slave demodulators. It further comprises a chassis structure for blocking interference.

The high-complex digital broadcasting reception system includes the RF input unit, the master tuner unit, the first and second slave tuner units, the master demodulator unit, and the first and second slave demodulator units, and the chassis structure includes the master unit. A first chassis shielding wall formed between an area where a tuner part and the first and second slave tuner parts are mounted, and an area where the master demodulator and the first and second slave demodulator parts are mounted; A second chassis shielding wall formed between a region where the RF input unit is mounted and a region where the master tuner unit and the first and second slave tuner units are mounted; A third chassis shielding wall formed between the master tuner portion and the first slave tuner portion; And a fourth chassis shielding wall formed between the master tuner portion and the second slave tuner portion.

The master tuner unit is arranged in a zigzag form and mounted on a substrate so as to maintain a predetermined distance between blocks adjacent to each other in order to disperse heat with each of the plurality of first to nth slave tuner units.

According to the present invention, it is implemented as a high-complex system including one master tuner unit and a plurality of slave tuner units, and has an effect of reducing the size and the price, compared to a system consisting of at least two NIMs.

1 is a block diagram of a highly complex digital broadcast reception system according to the present invention.
Figure 2 is an internal block diagram of the master tuner portion of the present invention.
3 is a conceptual diagram of sharing of a reference oscillator of a high-complex digital broadcasting reception system of the present invention.
4 is a serial communication line connection diagram of a high-complex digital broadcasting reception system of the present invention.
5 is a structural diagram of a chassis structure of the high-complex digital broadcasting reception system of the present invention.

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

The present invention is not limited to the embodiments described, and the embodiments of the present invention are used to assist in understanding the technical spirit of the present invention. In the drawings referred to in the present invention, components having substantially the same configuration and function will use the same reference numerals.

1 is a block diagram of a high-complex digital broadcasting reception system according to the present invention.

Referring to FIG. 1, in the high-complex digital broadcasting reception system according to the present invention, an RF signal input through one RF input terminal RFin is inputted to an RF output terminal RFout, and a plurality of first to nth MT output terminals MT01 to. MTOn) and a master tuner unit 110 for tuning a pre-selected channel among channels included in the RF signal through the RF input terminal RFin, and a plurality of first to first terminals of the master tuner unit 110. a plurality of first to nth slave tuner units 120-1 to 120-n for tuning a preselected channel among channels included in an RF signal input through each of the n MT output terminals MT01 to MTOn, and the master tuner; A master demodulator 210 for demodulating the IF signal from the unit 110 and a plurality of demodulators for demodulating the IF signals from each of the plurality of first to nth slave tuner units 120-1 to 120-n. 1 to n-th slave demodulators 220-1 to 220-n.

2 is an internal block diagram of a master tuner unit of the present invention.

Referring to FIG. 2, the master tuner unit 110 includes an AGC circuit unit 111 for amplifying an RF signal through the RF input terminal RFin, and a channel included in an RF signal from the AGC circuit unit 111. A first tuner IC 112 for tuning a first preselected channel, a second tuner IC 113 for tuning a second preselected channel among channels included in the RF signal from the AGC circuit 111, and The LT circuit unit 114 adjusts the RF signal from the AGC circuit unit 111 to a predetermined level and provides the RF output terminal RFout to the RF output terminal RFout, and the RF signal from the AGC circuit unit 111 to a predetermined level. The first to nth MT circuit units 115-1 to 115-n may be provided to the plurality of first to nth MT output terminals MT01 to MTOn.

In this case, each of the plurality of first to nth slave tuner units 120-1 to 120-n may also be configured as a dual tuner including a first tuner IC and a second tuner IC.

3 is a conceptual diagram of sharing of a reference oscillator of a high-complex digital broadcasting reception system according to the present invention.

Referring to FIG. 3, the master tuner unit 110 provides a reference signal from a directly connected reference oscillator XTAL to each of the plurality of first to nth slave tuner units 120-1 to 120-n. Each of the plurality of first to nth slave tuner units 120-1 to 120-n may receive reference signals from the master tuner unit 110 and the plurality of first to nth slave demodulators 220. The first slave tuner 120-1 may be configured to provide a reference signal from the master tuner 110 to the master demodulator 210. .

4 is a serial communication line connection diagram of a high-complex digital broadcasting reception system of the present invention.

Referring to FIG. 4, the master tuner 110 shares the serial communication lines SCL and SDA with the master demodulator 210, and the plurality of first to nth slave tuner units 120-1. Each of the plurality of first to nth slave demodulators 220-1 to 220-n shares a serial communication line SCL and SDA, and the master tuner 110. The serial communication lines SCL and SDA may be shared with each of the plurality of first to nth slave tuner units 120-1 to 120-n.

In addition, referring to FIG. 1, the high-complex digital broadcasting reception system of the present invention is formed between the RF input terminal RFin and an input terminal of the master tuner unit 110, and an RF signal from the RF input terminal RFin. It may further include an RF input unit 10 to amplify the output to the master tuner 110.

5 is a structural diagram of a chassis structure of the high-complex digital broadcasting reception system of the present invention.

Referring to FIG. 5, in the high-complex digital broadcasting reception system of the present invention, the RF input unit 10, the master tuner unit 110, and the plurality of first to nth slave tuner units 120-1 to 120-n ), And may further include a chassis structure (SH) for blocking signal interference between the master demodulator 210 and the plurality of first to nth slave demodulators 220-1 to 220-n.

For example, the high-complex digital broadcasting reception system may include the RF input unit 10, the master tuner unit 110, the first and second slave tuner units 120-1 and 120-2, and the master demodulator unit ( The chassis structure SH will be described in detail with respect to the case in which the first and second slave demodulators 220-1 and 220-2 are included.

The chassis structure SH includes an area in which the master tuner unit 110 and the first and second slave tuner units 120-1 and 120-2 are mounted, and the master demodulator 210 and the first agent The first chassis shielding wall SH1 is formed between the two slave demodulators 220-1 and 220-2, the region on which the RF input unit 10 is mounted, the master tuner 110, and the A second chassis shielding wall (SH2) formed between an area in which the first and second slave tuner parts 120-1 and 120-2 are mounted, and the master tuner part 110 and the first slave tuner part 120-. 1) a third chassis shielding wall SH2 formed between the second chassis shielding wall SH2 and a fourth chassis shielding wall SH3 formed between the master tuner unit 110 and the second slave tuner unit 120-2. Can be.

The master tuner unit 110 is arranged in a zigzag form to maintain a predetermined distance between blocks adjacent to each other in order to dissipate heat with each of the plurality of first to nth slave tuner units 120-1 to 120-n. It may be arranged to be mounted to the substrate.

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

1 to 5, a description will be given of the high-complex digital broadcast reception system according to the present invention. In the high-complex digital broadcast reception system of the present invention shown in FIG. And outputs an RF signal input through one RF input terminal RFin through an RF output terminal RFout and a plurality of first to nth MT output terminals MT01 to MTOn, and an RF signal through the RF input terminal RFin. The IF signal is provided to the master demodulator 210 by tuning a preselected channel included in the channel.

The master demodulator 210 demodulates the IF signal from the master tuner 110 according to a preset demodulation scheme.

In addition, each of the plurality of first to nth slave tuner units 120-1 to 120-n of the present invention may each have a plurality of first to nth MT output terminals MT01 to MTOn of the master tuner unit 110. Tuning a pre-selected channel among the channels included in the RF signal input through the IF signal is provided to the corresponding demodulation unit of the plurality of first to n-th slave demodulator (220-1 ~ 220-n).

Here, the plurality of first to nth slave tuner parts 120-1 to 120-n and the plurality of first to nth slave demodulators 220-1 to 220-n are respectively connected one to one.

Next, each of the plurality of first to nth slave demodulators 220-1 to 220-n is provided from a corresponding tuner unit among the plurality of first to nth slave tuner units 120-1 to 120-n. Demodulates the IF signal according to the preset demodulation scheme.

Referring to FIG. 2, the AGC circuit 111 of the master tuner unit 110 amplifies an RF signal through the RF input terminal RFin by a predetermined gain to thereby obtain a first tuner IC 112 and a second tuner IC. Provided at 113.

The first tuner IC 112 tunes a first channel selected in advance from channels included in the RF signal from the AGC circuit 111. The second tuner IC 113 tunes a second channel selected in advance among channels included in the RF signal from the AGC circuit 111. Here, the first channel and the second channel may be the same channel or may be different channels.

In addition, the LT circuit unit 114 of the master tuner unit 110 adjusts the RF signal from the AGC circuit unit 111 to a predetermined level and provides it to the RF output terminal RFout.

Each of the first to n-th MT circuit units 115-1 to 115-n of the master tuner unit 110 adjusts the RF signal from the AGC circuit unit 111 to a predetermined level so as to control the plurality of first to nth MT circuit units 115-1 to 115-n. The first to nth MT output terminals MT01 to MTOn are provided to corresponding output terminals.

In this case, each of the plurality of first to nth slave tuner units 120-1 to 120-n may also be configured as a dual tuner including a first tuner IC and a second tuner IC.

The high-complex digital broadcast reception system of the present invention can share one reference oscillator, which will be described.

Referring to FIG. 3, the master tuner unit 110 provides a reference signal from a directly connected reference oscillator XTAL to each of the plurality of first to nth slave tuner units 120-1 to 120-n. Each of the plurality of first to nth slave tuner units 120-1 to 120-n may receive reference signals from the master tuner unit 110 and the plurality of first to nth slave demodulators 220. The first slave tuner 120-1 may provide a reference signal from the master tuner 110 to the master demodulator 210. Can be.

The high-complex digital broadcasting reception system of the present invention can share a serial communication line, which will be described.

Referring to FIG. 4, the master tuner 110 shares the serial communication lines SCL and SDA with the master demodulator 210, and the plurality of first to nth slave tuner units 120-1. Each of the plurality of first to nth slave demodulators 220-1 to 220-n shares a serial communication line SCL and SDA, and the master tuner 110. The serial communication lines SCL and SDA may be shared with each of the plurality of first to nth slave tuner units 120-1 to 120-n.

In addition, referring to FIG. 1, the high-complex digital broadcasting reception system of the present invention is formed between the RF input terminal RFin and an input terminal of the master tuner unit 110, and an RF signal from the RF input terminal RFin. It may further include an RF input unit 10 to amplify the output to the master tuner 110, the RF input unit 10 may include a filter or an amplifier.

Referring to FIG. 5, in the high-complex digital broadcasting reception system of the present invention, the RF input unit 10, the master tuner unit 110, and the plurality of first to nth slave tuner units 120-1 to 120-n ), And may further include a chassis structure (SH) for blocking signal interference between the master demodulator 210 and the plurality of first to nth slave demodulators 220-1 to 220-n.

For example, the high-complex digital broadcasting reception system may include the RF input unit 10, the master tuner unit 110, the first and second slave tuner units 120-1 and 120-2, and the master demodulator unit ( The chassis structure SH will be described in detail with respect to the case in which the first and second slave demodulators 220-1 and 220-2 are included.

The chassis structure SH includes an area in which the master tuner unit 110 and the first and second slave tuner units 120-1 and 120-2 are mounted, and the master demodulator 210 and the first agent The first chassis shielding wall SH1 is formed between the two slave demodulators 220-1 and 220-2, the region on which the RF input unit 10 is mounted, the master tuner 110, and the A second chassis shielding wall (SH2) formed between an area in which the first and second slave tuner parts 120-1 and 120-2 are mounted, and the master tuner part 110 and the first slave tuner part 120-. 1) a third chassis shielding wall SH2 formed between the second chassis shielding wall SH2 and a fourth chassis shielding wall SH3 formed between the master tuner unit 110 and the second slave tuner unit 120-2. Can be.

Accordingly, according to the chassis structure (SH) of the present invention, the interference between the circuit portions can be blocked.

The master tuner unit 110, in cooperation with each of the plurality of first to nth slave tuner units 120-1 to 120-n, blocks adjacent to each other to dissipate heat so that heat is not concentrated in one place. Zigzag may be mounted on the substrate to maintain a certain distance therebetween.

In the present invention as described above, in contrast to the method previously designed by using two modules for DVB-C having the same function in the set to watch the PVR, for example, six in one can (CAN) The built-in module allows consumers to use set-top boxes with high complexities as well as aesthetics.

In addition, according to the present invention, not only the concept of a set of complex modules, that is, a set for simply watching TV, but also various functions such as DOCSIS 3.0 and WiFi may be provided together.

In addition, if such a module is installed in the set, it may be difficult to prevent interference of various interferences generated through the use of WiFi or interference from noise generated by the tuner itself, but according to the present invention, each dual tuner ( Three Dual Tuners can provide excellent noise immunity through internal shielding inside PCB and can, and also excludes the part affecting the use of WiFi in the UHF frequency band. can do.

10: RF input unit 110: master tuner unit
111: AGC circuit section 112: first tuner IC
113: second tuner IC 114: LT circuit portion
115-1 to 115-n: 1st-th n-th MT circuit portion
120-1 to 120-n: first to nth slave tuner parts
210: master demodulator
220-1 to 220-n: first to nth slave demodulators
SH: Chassis Structure SH1: First Chassis Shield Wall
SH2: second chassis shield wall SH3: third chassis shield wall

Claims (8)

A master tuner unit for outputting an RF signal input through one RF input terminal through an RF output terminal and a plurality of first to nth MT output terminals, and tuning a preselected channel among channels included in the RF signal through the RF input terminal;
A plurality of first to n-th slave tuner units for tuning a pre-selected channel among channels included in an RF signal input through each of the plurality of first to n-th MT output terminals of the master tuner unit;
A master demodulator for demodulating the IF signal from the master tuner unit; And
A plurality of first to nth slave demodulators that demodulate IF signals from each of the plurality of first to nth slave tuner units
High-complex digital broadcast receiving system comprising a. The method of claim 1, wherein the master tuner unit,
An AGC circuit unit for amplifying the RF signal through the RF input terminal;
A first tuner IC for tuning a first channel selected in advance among channels included in the RF signal from the AGC circuit unit;
A second tuner IC for tuning a second preselected channel among channels included in the RF signal from the AGC circuit unit;
An LT circuit unit for adjusting the RF signal from the AGC circuit unit to a predetermined level and providing the RF signal to the RF output terminal; And
First-n-th MT circuit part for adjusting the RF signal from the AGC circuit part to a predetermined level and providing it to the plurality of first to n-th MT output terminals.
High-complex digital broadcast receiving system comprising a. The method of claim 1, wherein the master tuner unit,
Providing a reference signal from a directly connected reference oscillator to each of the plurality of first to nth slave tuner units,
Each of the plurality of first to nth slave tuner units includes:
Providing a reference signal from the master tuner unit to each of the plurality of first to nth slave demodulators,
The first slave tuner unit,
Providing a reference signal from the master tuner section to the master demodulator section
High-complex digital broadcast receiving system characterized in that. The method of claim 1, wherein the master tuner unit,
Share a serial communication line with the master demodulator,
Each of the plurality of first to nth slave tuner units includes:
Sharing a serial communication line with each of the plurality of first to nth slave demodulators,
The master tuner unit,
Sharing a serial communication line with each of the plurality of first to nth slave tuner units
High-complex digital broadcast receiving system characterized in that. The method of claim 1,
And an RF input unit formed between the RF input terminal and the input terminal of the master tuner unit to amplify the RF signal from the RF input terminal and output the amplified RF signal to the master tuner unit. The method of claim 5,
And a chassis structure for blocking signal interference between the RF input unit, the master tuner unit, the plurality of first to nth slave tuners, the master demodulator, and the plurality of first to nth slave demodulators. Highly complex digital broadcast reception system. The system of claim 6, wherein the high-complex digital broadcasting reception system
The RF input unit, the master tuner unit, the first and second slave tuner units, the master demodulator unit, and the first and second slave demodulator units;
The chassis structure,
A first chassis shielding wall formed between an area in which the master tuner part and the first and second slave tuner parts are mounted, and an area in which the master demodulator and the first and second slave demodulator parts are mounted;
A second chassis shielding wall formed between a region where the RF input unit is mounted and a region where the master tuner unit and the first and second slave tuner units are mounted;
A third chassis shielding wall formed between the master tuner portion and the first slave tuner portion; And
A fourth chassis shielding wall formed between the master tuner portion and the second slave tuner portion
High-complex digital broadcast receiving system comprising a. The method of claim 7, wherein the master tuner unit,
The high-complex digital broadcasting reception system of claim 1, wherein the plurality of first to n-th slave tuner units are arranged in a zigzag form and mounted on a substrate to maintain a predetermined distance between adjacent blocks.

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