KR20110085539A - Display device and method of receiving a braodcast signal thereof - Google Patents

Abstract

PURPOSE: A display device and method for receiving a broadcasting of the same are provided to selectively compensate an IF frequency according to a channel bandwidth between a neighboring channel. CONSTITUTION: A viewing channel is selected. A channel bandwidth between adjacent channels and the viewing channel are confirmed based on a frequency of the selected viewing channel(S110). A parametric value for compensating an IF frequency is set based on the confirmed channel bandwidth(S130). A broadcast signal corresponding to viewing channel based on the fixed parametric value is received(S140).

Description

Display device and method for receiving broadcast signal thereof

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display apparatus, and more particularly, to a display apparatus and a method for receiving broadcast signals thereof, capable of receiving broadcast signals according to channel bandwidths between adjacent channels.

Broadcasting systems used in many countries include NTSC (National Television System (s) Committee), PAL (Phase-Alternating Line) broadcasting systems and SECAM (Sequential Color with Memory) broadcasting systems, depending on the color scheme of the video signal. It can be classified as a broadcasting system.

Each country in the world adopts any of the above broadcasting systems and performs television broadcasting. For reference, our country adopts NTSC broadcasting system.

Accordingly, the television apparatus is produced for a broadcasting system corresponding to the country in which it is used to receive / reproduce a broadcast signal.

In other words, the broadcasting system is NTSC method adopted by the US, Japan, Canada, etc., PAL method adopted by Germany, UK, Australia, etc., and SECAM method adopted by various countries such as France, Russia, Middle East, etc. Can be classified as

According to each broadcasting scheme corresponding to the reception area, the NTSC scheme is 6MHz, the PAL scheme is 8MHz (except, the PAL_M and PAL_N schemes are 6MHz, the PAL_B scheme is 7MHz), and the SECAM scheme is 8MHz, respectively. (Exceptionally, the SECAM_B scheme is 7 MHz).

A configuration of a display apparatus according to the prior art will be described with reference to FIG. 1.

The conventional display apparatus includes a display unit 6, an antenna 1 for receiving an RF broadcast signal, a tuner 2 for tuning an RF broadcast signal received through the antenna 1 to an IF broadcast signal; And a demodulator 3 for demodulating and outputting an IF broadcast signal from the tuner 2 to a predetermined composite CVBS video signal, and a video decoder for decoding and outputting the video signal output from the demodulator 3 into a digital video signal. (4), a scaler (5) for converting and outputting a digital video signal output from the video decoder (4) into a format for display on the display section (6), a key input section (8) for user key input, and And a tuner 2 and a demodulator to tune the RF broadcast signal corresponding to the channel switched through the key input unit 8 and to convert / demodulate / decode the RF broadcast signal so as to be displayed on the display unit 6. (3) and video decoder (4) and scaler (5) It includes a microcomputer 7 for controlling.

Here, a SAW filter (not shown) is interposed between the tuner 2 and the demodulator 3.

In addition, assuming that the conventional display apparatus is used in a country employing a PAL broadcasting system and the output IF frequency is 38.9 MHZ, a SAW filter of 38.9 MHZ / 8 MHZ (not shown) is provided between the tuner 2 and the demodulator 3. Is interposed. Accordingly, the tuner 2 tunes an RF broadcast signal by a control signal according to a frequency in which an RF frequency and an output IF frequency (38.9 MHZ) to be actually received are mixed.

The tuner 2 converts the tuned RF broadcast signal into an IF broadcast signal, and the demodulator 3 converts the IF broadcast signal filtered through a SAW filter (not shown) according to a demodulation algorithm according to a fixed PAL broadcast system. Demodulate a predetermined composite CVBS video signal.

As such, the conventional display apparatus can process only a predetermined broadcasting system (for example, PAL) that is fixed to be processed in production.

However, because each country adopts a different broadcasting system, such a television apparatus must replace the IC of the SAW filter (not shown) and the demodulator 3 in order to receive another broadcasting system (for example, NTSC). do.

In addition, in the PAL broadcast system as described above, it may have a channel bandwidth of 6Mhz, or a channel bandwidth of 8Mhz depending on the detailed method. Accordingly, when a broadcast signal having a channel bandwidth of 6 MHz is received in a PAL broadcast system, a picture carrier of adjacent channels N-2 to N + 2, which is a strong electric field, remains in the reception channel region. Noise is generated in the display image by the picture carrier of the adjacent channel remaining in the reception channel region.

According to an embodiment of the present invention, it is possible to provide a display device capable of selectively compensating IF frequencies according to channel bandwidths between adjacent channels and a method of receiving broadcast signals thereof.

Technical problems to be achieved in the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned above are clearly understood by those skilled in the art to which the embodiments proposed from the following description belong. Could be.

In accordance with another aspect of the present invention, there is provided a method of receiving a broadcast signal of a display apparatus, the method including selecting a viewing channel; Checking a channel bandwidth between the viewing channel and an adjacent channel based on the frequency of the selected viewing channel; Setting a parameter value for compensating the IF frequency based on the checked channel bandwidth; And receiving a broadcast signal corresponding to the viewing channel based on the set parameter value.

In addition, the display device according to an embodiment of the present invention includes a tuner for receiving a broadcast signal corresponding to a viewing channel; An SAW filter for passing only a band component corresponding to a preset parameter value from the received broadcast signal; A storage unit for storing channel information; And a controller for checking a channel bandwidth between the viewing channel and an adjacent channel based on the stored channel information and adjusting a parameter value of the SAW filter based on the identified channel bandwidth.

According to an embodiment of the present invention, by adjusting / compensating the IF frequency according to the channel bandwidth of the input broadcast signal in various conditions, it is possible not only to prevent the noise phenomenon that may occur in an abnormal environment, but also to the signal-to-noise ratio There is an effect that can improve (S / N).

1 is a block diagram of a display device according to the prior art.
2 is a block diagram of a display device according to an embodiment of the present invention.
3 is a detailed configuration diagram of the tuner and digital demodulator of FIG. 2;
4 is a detailed configuration diagram of a symbol recovery unit shown in FIG. 3.
FIG. 5 is a detailed configuration diagram of the image processor shown in FIG. 2.
6 is a flowchart illustrating a method for receiving broadcast signals in a display apparatus according to an embodiment of the present invention step by step.

The proposed embodiment will be described.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. However, the spirit of the present invention is not limited to the embodiments presented, and other inventions which are further deteriorated by addition, change, deletion, etc. of other components, or other embodiments included within the scope of the present invention can be easily made. I can suggest.

The term used in the present invention was selected as a general term widely used as possible, but in some cases, the term is arbitrarily selected by the applicant, in which case the meaning is described in detail in the description of the invention, the name of a simple term It should be clear that the present invention is to be understood as a meaning of terms.

In other words, in the following description, the word 'comprising' does not exclude the presence of other elements or steps than those listed.

2 is a block diagram of a display apparatus according to an exemplary embodiment of the present invention.

Referring to FIG. 2, the display apparatus includes a tuner 210, a demodulator 220, a demultiplexer 130, a signal processor 140, a display 150, a storage 160, and a controller 170. It is configured to include.

The tuner 210 receives a signal desired by a user, that is, a broadcast signal of a specific channel selected by the user, from among broadcast signals transmitted through a wired / wireless medium. The broadcast signal may be a terrestrial broadcast, satellite broadcast, or cable broadcast signal. The tuner unit 210 includes an RF antenna 212 for detecting a broadcast signal from the air and a tuner 214 for tuning a signal of a desired channel among various broadcast signals and converting the tuned signal to an intermediate frequency. Can be. If the cable broadcast is received, the RF antenna 212 may be replaced by a signal input unit (not shown) of the cable modem.

The tuner 214 provides the demodulator 220 with the signal converted into the intermediate frequency. Then, the demodulator 220 restores the transport stream from the signal converted from the intermediate frequency, and provides the recovered transport stream to the demultiplexer 230.

3 to describe the operations occurring in the tuner unit 210 and the demodulator 220 in more detail. FIG. 3 is a diagram illustrating a detailed configuration of the tuner unit and the digital demodulation unit of FIG. 2.

First, the tuner unit 210 may include an RF antenna 212, a tuner 214, a SAW filter 216, and a PLL circuit 218. In addition, various commands of the user may be input to the controller 170 through a remote controller (not shown).

The tuner 214 converts the RF signal (e.g., 50-860 MHz) into an IF (middle frequency) signal (e.g., 44 MHz) and passes it to the SAW filter 216.

The SAW filter 216 performs the removal of the adjacent channel signal and the noise signal from the intermediate frequency signal transmitted from the tuner 214, and outputs the result to the phase locked loop (PLL) circuit 218.

The PLL circuit 218 calculates a difference between the signal output from the SAW filter 216 and the signal output from the first VCO (Voltage Controlled Oscillator (not shown)) and repeatedly reduces the voltage of the VCO in the direction of reducing the difference. Adjust it. The state in which the phase difference between the two signals disappeared by the loop repetition process is called locked.

When the control unit 270 receives a selection command of a specific channel and a change command to a specific channel (button input, remote control input, etc.) from the user, the controller 270 transmits a signal notifying that the user command is present to the tuner unit 210. Then, the demodulator 220 controls to demodulate in a demodulation manner for the channel to be switched accordingly.

The demodulator 220 may include an AGC amplifier 222, an A / D converter 224, and a symbol recovery unit 226.

The AGC amplifying unit 222 compensates the gain of the signal output from the tuner unit 210 and outputs it as a signal capable of A / D conversion. That is, since the signal passing through the SAW filter 216 is weak, the output of the tuner 210 is compensated for by the signal gain that the A / D converter 224 of the rear stage can normally perform A / D conversion.

The A / D converter 224 converts the signal amplified by the AGC amplifier 222 into a digital signal according to the sampling frequency generated by the second VCO (not shown) and outputs the digital signal to the symbol recovery unit 226.

The symbol recovery unit 226 is configured by the A / D converter 224 according to the demodulation scheme (VBS-8, VSB-16, QAM64, QAM256, QAM1024, DPSK, QPSK, etc.) selected by the controller 270. Recover the transmitted symbols from the digitally converted signal. The symbol recovery unit 226 recovers the transmission symbol and outputs the result to the outside of the demodulator 220. As shown in FIG. 4, the symbol recovery unit 226 may be subdivided into an error interpolation unit 226a, a carrier recovery unit 226b, a channel equalizer 226c, and a channel decoder 226d. .

The error interpolator 226a receives feedback of timing errors of symbols coming from the baseband signal processing, for example, transmission symbols decoded by the channel decoder 226d. Then, using a resampler (not shown), the interpolation is performed in a direction of reducing an error between the digital signal output from the A / D converter 224 and the received signal and the result is returned to the carrier recovery unit ( 226b).

The carrier recovery unit 226b removes the frequency offset and phase noise of the carrier from the bandpass digital signal, and base-bands the bandpass digital signal from which the frequency offset and phase noise have been removed. -band) Digital demodulation into a digital signal and output to the channel equalizer 226c.

The channel equalizer 226c removes the inter-symbol interference caused by the multipath included in the signal recovered by the carrier recovery unit 226b and then outputs it to the channel decoder 226d. That is, in a digital transmission system such as HDTV, a bit detection error occurs at a receiving side due to distortion generated by a multi-path channel, interference by an NTSC signal, and distortion by a transmission / reception system. Since signal propagation through a path causes intersymbol interference and is a major cause of bit detection error, the channel equalizer 226c is employed to eliminate the symbol interference.

The channel decoder 226d uses the Reed-Solomon coding scheme and the lattice modulation code scheme to collect congestion noise present on a channel included in a signal from which interference is removed between symbols in the channel equalizer 226c. Excessive scattering noise is removed, and the synchronization signals that were inserted at the time of transmission from the baseband signal are recovered, and the received data, that is, the transmission symbols are recovered using the synchronization signals.

2, data demodulated by the demodulator 220 and output, for example, a transport stream (TS), are input to the demultiplexer 230. Under the control of the controller 270, the demultiplexer 230 parses the provided transport stream into video signals, audio signals, and additional information signals, and provides the separated signals to respective processing blocks.

The signal processor 40 processes the video signal and the audio signal output through the demultiplexer 30, respectively. In this case, the signal processor 240 includes an image processor 242 for processing a video signal and a voice processor 244 for processing an audio signal.

That is, the video signal separated by the demultiplexer 30 is signal-processed through the image processor 242 and output through the display 250, and the separated audio signal is connected to the voice processor 44. The signal is processed through the display unit 250 is output. Accordingly, the display unit 250 includes a display unit for displaying an image and a speaker for outputting audio.

In this case, the image processor 242 may be a video decoder that decodes the video signal to restore a video image. Such a video decoder may be implemented according to, for example, a video decompression scheme (MPEG-1, MPEG-2, MPEG-4, etc.) of the Moving Picture Experts Group (MPEG) series.

5 is a diagram illustrating a detailed configuration of the image processor 242. The image processor 242 includes a variable length decoder 242a, a frame reader 242b, an inverse quantizer 242c, an inverse spatial transform unit 242d, an adder 242e, and a frame memory 242f. ), And a motion compensation unit 242g.

The variable length decoder 242a receives the compressed video signal output from the demultiplexer 220 and performs variable length decoding. Such variable length decoding is a decoding method for lossless coding performed by displaying an array of bits more efficiently.

The frame reading unit 242b reads texture information and motion information of the video frame from the bit string that is losslessly restored by variable length decoding, and the read texture information is dequantized by the dequantization unit 242c, and the read motion information is read. The motion compensation unit 242g is provided. The motion information may include a motion vector indicating a motion size from a reference frame of blocks constituting the current frame, a frame number of the reference frame, and the like.

Such frames may be classified into intra frames that can be decoded without reference to other frames (reference frames) and inter frames that can be decoded with reference to other frames. In the MPEG codec, an I frame corresponds to an intra frame, and a P frame and a B frame correspond to an inter frame.

On the other hand, the frame reading unit 242b transmits the 'intra frame notification signal' to the controller 270 when the first intra frame appears after the channel switching. The intra frame notification signal may simply be represented by 1 bit, where 1 may correspond to the intra frame notification signal, and 0 may indicate that it is not.

The inverse quantizer 242c inversely quantizes the texture information transmitted from the variable length decoder 242a and outputs a transform coefficient. The inverse quantization process is a process of finding a quantized coefficient matched with a value represented by a predetermined index in the video encoder stage. A table indicating a matching relationship between the index and the quantization coefficients may be passed from the video encoder stage or may be previously promised between the encoder and the decoder.

The inverse spatial transform unit 242d performs the inverse of the spatial transform method performed by the encoder stage, and inversely transforms the transform coefficients into transform coefficients in the spatial domain. The spatial transform method includes a DCT (Discrete Cosine Transform) transform method and a wavelet transform method.

If the current frame is an intra frame, the original video image is directly restored through the inverse spatial transform unit 242d. Therefore, the original frame is directly output to the display unit 250. However, in the case of an inter frame, the original frame is configured by the motion compensator 242g. By adding the motion compensation frame, the original video image is reconstructed and output to the display unit 250.

The motion compensator 242g generates a motion compensated frame by reconstructing a reference frame that is already reconstructed and stored in the frame memory 242f using the provided motion information.

In this case, the display unit 250 displaying the image may be implemented by various display modules such as a liquid crystal display (LCD), a plasma display panel (PDP), an electro luminescent display (ELD), and a vacuum fluorescent display (VFD).

The controller 270 controls the overall operation of the display apparatus.

Hereinafter, the operation of the controller 270 will be described in more detail.

First, the SAW filter 216 is set to a specific output IF frequency, and selectively passes only signals of specific band components from the broadcast signal received through the tuner 214 based on the set output IF frequency. For example, if the display device is used in a country employing a PAL broadcast system, an IF frequency of 38.9 MHz / 8 MHz is set in the SAW filter. In addition, if the display device is used in a country employing an NTSC broadcast system, the SAW filter 216 is set with an IF frequency of 45.75 MHz / 6 MHz.

Accordingly, the tuner 214 serves to receive an RF broadcast signal received through the RF antenna 212. More specifically, the frequency tuned by the tuner 214 is represented by the sum of the actual RF frequency (ie, the frequency of the selected channel (viewing channel)) and the output IF frequency (eg, frequency of the SAW filter). Here, the actual tuning frequency when the SAW filter 216 has a parameter of 38.9 MHz / 8 MHz by the PAL broadcasting system and wants to receive a channel corresponding to a frequency of 55.25 MHz

F _OSC = F _RF + F _IF → F _OSC = 55.25MHZ + 38.9MHZ

And if 1 step of the tuner 214 uses 62.5KHZ, the tune data tuned in the actual tuner 214 is

to be.

The SAW filter 216 receives the tuned broadcast signal from the tuner 214, passes a frequency of a specific band component, and outputs an IF broadcast signal to the PLL circuit 218. Here, when the display apparatus assumes that a parameter of 38.9 MHz / 8 MHz is initially set by a PAL broadcast system, the SAW filter 216 passes only a band component corresponding to 8 MHz from the received broadcast signal. Let's do it. In this case, the SAW filter 216 is shown between the tuner and the digital demodulator, SAW filter 216 is included in the rear end of the tuner 214 or is included in the front end of the digital demodulator 220 It is also possible.

However, in this case, when the display apparatus is used in a country employing a PAL broadcasting system, broadcasting signals are generally received with a bandwidth of 8 MHz, but broadcasting has a bandwidth of 6 MHz for the PAL_M and PAL_N methods and 7 MHz for the PAL_B method. The signal is received. Accordingly, even in the same PAL scheme, a wrong parameter may be set in the SAW filter 216 based on the detailed scheme, and thus a case in which an image of an adjacent channel is included in the received broadcast signal is generated.

Accordingly, the controller 270 checks the channel bandwidth between the channel to be received through the tuner 214 and the adjacent channel using the channel information of each channel stored in the storage 160, and checks the checked channel bandwidth. Based on the adjustment, the parameter value set in the SAW filter 216 is adjusted.

For example, if the parameter of the SAW filter 216 is initially set to 38.9 MHz / 8 MHz and the checked channel bandwidth is 8 MHz, the controller 270 does not perform a separate setting process. The broadcast signal for the viewing channel is received based on the set parameter value.

However, when the parameter of the SAW filter 216 is initially set to 38.9 MHz / 8 MHz and the checked channel bandwidth is 6 MHz, the controller 270 sets the parameter value of the SAW filter 216 to 38.9 MHz. / 6MHz, and the broadcast signal for the viewing channel is received based on the changed parameter value.

The SAW filter 216 passes a frequency component of an 8 MHz band or a frequency component of a 6 MHz band based on a parameter value set by the controller 270.

Accordingly, even in the same broadcast system, it is possible to prevent noise phenomena caused by having different channel bandwidths in accordance with the detailed broadcast scheme.

6 is a flowchart illustrating a method of receiving a broadcast signal in a display apparatus according to an exemplary embodiment of the present invention.

Referring to FIG. 6, first, the controller 270 checks a frequency of a viewing channel (step 100). That is, the user inputs a channel number that he / she wants to watch using a remote controller (not shown). The controller 270 receives the channel number input through the remote controller and checks an RF frequency corresponding to the input channel number using the channel information stored in the storage unit 260.

In addition, the controller 270 checks the frequency of the input channel number and neighboring channels, compares the frequency of the neighboring channel with the frequency corresponding to the input channel number, and compares the frequency between the viewing channel and the adjacent channel. Check the band (step 120). In general, a PAL broadcasting system has a frequency band of 8 MHz, and an NTSC broadcasting system has a frequency band of 6 MHz.

The controller 270 compares the checked frequency band with the frequency band identified at a previous time, and determines whether the two frequency bands are the same or have different bands (step 120).

If the checked frequency band and the checked frequency band are the same as each other, the controller 270 omits a separate setting step and broadcasts the broadcast channel corresponding to the viewing channel based on a parameter of a previously set SAW filter. Allow a signal to be received.

However, if the checked frequency band and the checked frequency band are different from each other, the controller 270 changes the parameter value of the SAW filter 216 based on the checked frequency band (step 130). For example, the 38.9 MHz / 6 MHz set in the SAW filter 216 is changed to 38.9 MHz / 8 MHz.

The tuner 214 receives a broadcast signal based on the sum of the RF frequency corresponding to the viewing channel and the IF frequency (38.9 MHz) set in the SAW filter 216 (step 140).

The SAW filter 214 passes only the components of the frequency band corresponding to the set parameter value from the received broadcast signal (step 150).

As described above, according to the embodiment of the present invention, by adjusting / compensating the IF frequency according to the channel bandwidth of the input broadcast signal in various conditions, it is possible to prevent noise phenomenon that may occur in an abnormal environment in advance. The signal-to-noise ratio (S / N) can be improved.

In addition, the above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains various modifications and variations without departing from the essential characteristics of the present invention. . Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

210: tuner portion 220: demodulation portion
230: demultiplexer 240: signal processor
250: display unit 260: storage unit
270: control unit

Claims (8)

Selecting a viewing channel;
Checking a channel bandwidth between the viewing channel and an adjacent channel based on the frequency of the selected viewing channel;
Setting a parameter value for compensating the IF frequency based on the checked channel bandwidth; And,
And receiving a broadcast signal corresponding to the watched channel based on the set parameter value. The method of claim 1,
And the parameter value is set only when the previously confirmed channel bandwidth is different from the identified channel bandwidth. The method of claim 1,
And the parameter value is a parameter value of a SAW filter. The method of claim 3, wherein
The set parameter value of the SAW filter is a broadcast signal reception method of a display device, characterized in that the frequency bandwidth passed through the SAW filter. The method of claim 3, wherein
Receiving the broadcast signal
Receiving a broadcast signal for the viewing channel based on the sum of the RF frequency and the IF frequency of the selected channel;
And passing only components corresponding to the set frequency band from the received broadcast signal. A tuner for receiving a broadcast signal corresponding to a viewing channel;
An SAW filter for passing only a band component corresponding to a preset parameter value from the received broadcast signal;
A storage unit for storing channel information; And,
And a controller for checking a channel bandwidth between the viewing channel and the adjacent channel based on the stored channel information and adjusting a parameter value of the SAW filter based on the identified channel bandwidth. The method of claim 6,
And the controller adjusts a parameter value set in the SAW filter only when a channel bandwidth checked at a previous time and a channel bandwidth checked at a current time are different. The method of claim 6,
And said parameter value is a frequency band passed through said SAW filter.

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