KR0166252B1 - Television with discrimination of sound modes - Google Patents

Abstract

The present invention discriminates whether the voice intermediate frequency signal is a French Instantaneous Companded Audio Multiplex (NICAM) mode using a 5.85 MHz S2 carrier in addition to a 6.5 MHz S1 carrier or a D / K mode using an S2 carrier of 6.26 MHz. A video processor 10 for outputting a discriminating signal; The trap unit for attenuating the energy of the S1 carrier of the voice intermediate frequency signal in the French NICAM mode according to the mode discrimination signal of the video processor 10, and passing the voice intermediate frequency signal as it is in the D / K mode. 20; A sound processor 30; The present invention relates to a television having a sound mode discrimination function including an amplifier 40. If the broadcast voice signal being received is a French NICAM mode, the audio is automatically attenuated by the energy of the S1 carrier (AM carrier) of the voice intermediate frequency signal. Because it processes and outputs through the speaker, it is effective to allow the viewer to listen to the multi-speech voice of the uniform sound quality.

Description

TV with sound mode discrimination

(A) of FIG. 1 is a diagram showing a frequency spectrum of a two carrier system.

(b) is a diagram showing the frequency spectrum of the Japanese multiplex voice system (FM-FM system).

(c) is a diagram showing the frequency spectrum of the US voice multiplex method (AM-FM method: Zenith method).

2 is a diagram illustrating a frequency spectrum of a NICAM (Near Instantaneous Companded Audio Mmltiplex) scheme.

(a) is a diagram showing a frequency spectrum of the I scheme.

(b) is a diagram showing a frequency spectrum of a B scheme.

(c) is a diagram showing a frequency spectrum of a G scheme.

Figure 3 (a) is a diagram showing a stereo audio signal structure of one frame in the NICAM scheme.

(b) is a diagram showing a mono audio signal structure of one frame in the NICAM scheme.

Figure 4 (a) is a diagram showing the frequency spectrum of the French Near Instantaneous Companded Audio Multiplex (NICAM) scheme.

(b) shows a D / K frequency spectrum, and FIG. 5 is a partial block diagram of a television receiving system according to the present invention.

* Explanation of symbols for main parts of the drawings

10: video processor 20: trap unit

30: sound processor 40; amplifier

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a television having a sound mode discriminating function. In particular, when a broadcasting voice signal being received is a French Near Instantaneous Companded Audio Multiplex (NICAM) mode, the energy of the S1 carrier, which is an AM carrier, is automatically attenuated so that the NICAM signal is an S1 carrier. It is about TV which is not affected by.

The terrestrial broadcasting television transmission system is classified into M, B / G, D / K, I, L, etc. according to the characteristics of the synchronization signal, and also NTSC (NATIONAL TELEVISION SYSTEM COMMITTEE) and PALQKDTLR (PHASE ALTERNATION BY) according to the color scheme. LINE) and SECAMQKDTLR (SEQUENTIAL COULEUR A MEMOIRE).

Therefore, countries around the world are doing television broadcasting using a combination of a television transmission system and a television color system. For example, NTSC-M is adopted in the United States, Japan, and Korea, and PAL-B / G is adopted in Western Europe, such as Germany, Spain, Italy, and Sweden, and PAL-D / in China and Romania. It adopts K method, PAL-I is adopted in UK, Ireland, South Africa, etc., SECAM-L method is adopted in France, Luxembourg, etc., and SECAM-D / K method is adopted in Eastern Europe such as the Union of Independent States. Doing.

On the other hand, in television, voice multicasting is a system in which another voice signal is superimposed simultaneously on the sound wave of a television broadcast, and a stereo broadcast or bilingual broadcast is possible at the same time.

In the voice multiplexing system, a dual carrier system, which is a method of providing a second voice carrier in addition to the existing voice carrier, and a subcarrier system, which is a method of multimodulating a subcarrier modulated with a negative voice to an existing voice carrier The system is divided into two types: analog two carrier type (Korean, German), FM-FM (Japanese), AM-FM (US), and digital phase shift keying (DPSK). There is a way.

(A) of FIG. 1 is a diagram showing a frequency spectrum of two carriers. The two carriers are used in Korea, Germany, China, and the like. In addition to the existing voice carrier (channel 1), a second voice carrier (channel 2) From Channel 1, Korea is added 14.25fh (fh = 15.7342KHz), while Germany and China are 15.5fh (fh = 15.625KHz). The pilot signal used to determine the speech content at the receiver is a control signal obtained by modulating the 3.5fh subcarrier at 50% AM. The modulation frequency is 149.85Hz in Korea, 117.5Hz in Germany and China when the modulation frequency is stereo. 276.04Hz, 274.1Hz for Germany and China, and unmodulated for mono. The two-carrier method has better left and right separation in stereo than the FM-FM method, and crosstalk, signal-to-noise ratio, etc. are excellent in two languages.

FIG. 1 (b) shows the frequency spectrum of the Japanese multiplex system (FM-FM). The multiplex system in Japan is an FM-FM system in which 2fh is a subcarrier. L + R, subchannel signal consists of stereo LR, bilingual and pilot signal. For better separation of the two languages, the frequency shift of the sub-signals is set to 15KHz and 20KHz for stereo, and the pilot signal with 60% AM modulation of the 3.5fh subcarrier is 982.5Hz, two when the modulation frequency is stereo. 922.5Hz is used in Korean. Analyzing the frequency spectrum of the Japanese multiple voice signal, the 4.5 MHz carrier of the FM FM wave is FM-modulated at 25 KHz by combining the main signal of the unmodulated baseband, the FM modulated sub-signal, and the AM modulated pilot signal. Send. In this case, the sub-signal is an FM-FM wave that modulates FM twice, and the control signal is an AM-FM wave. In this way, the Japanese multiplexing method is called the FM-FM method based on the modulation method of the sub-signals. In the case of stereo broadcasting, the receiver detects the LR signal through a band pass filter, which limits the bandwidth required to transmit the signal to prevent interference with the main channel or control channel and to prevent noise. Since the 0.00002s delay occurs and the stereo separation becomes worse due to the time difference with the L + R signal, the transmitter compensates the time difference with the LR signal by delaying the L + R signal by 0.00002 s and removes the high frequency noise. During transmission, the high frequency component is emphasized to pre-emphasis, and de-emphasis is performed to demodulate the original signal in the receiver.

Figure 1 (c) is a diagram showing the frequency spectrum of the US voice multiplex method (AM-FM method: Zenith method), the US voice multiplex system is adopted Zenith dbx system by the Federal Communications Commission (FCC) Zenith The stereo system of this method is an AM-FM method that uses 2fh as a subcarrier and fh as a pilot signal, and is easier to be affected by the buzz generated in the receiver compared to the FM-FM method, so that dbx is included in the first subchannel (LR). Noise reduction circuitry is employed to improve the signal-to-noise ratio. The bilingual broadcast is a second subchannel in which FM modulation of a second carrier (5fh) called a second audio program (SAP) is performed, and this channel also employs a dbx noise reduction circuit to improve the signal-to-noise ratio. The main channel (L + R) contains a filter to compensate for the delay caused by the noise reduction circuit of the subchannel, which improves the signal-to-noise ratio and prevents deterioration of the separation of the stereo signal. The FM maximum frequency shift set by the FCC modulates the transmitter with a composite signal of 1st sub-signal (LR) + pilot signal + 2nd sub-signal + Telemetry = 50K + 5K + 15K + 3K = 73KHz when L = -R. When it is the maximum side. The noise reduction system adopted by the FCC's television-to-voice multiplexing scheme is a circuit inserted to obtain a high noise reduction effect in a channel having a bad signal-to-noise ratio.

2 is a diagram showing a frequency spectrum of the NICAM scheme, in which (a) shows I scheme, (b) shows B scheme, and (c) shows G scheme. Digital methods are divided into English (I) voice multiplexing and Swedish (or Scandinavian, B / G) voice multiplexing. English multiplexing (I) or Swedish multiplexing (or Scandinavian, B / G) adds a second carrier to the I, B / G television modulation schemes. Data signal is digitized with this signal, and the British carrier (I method) transmits a 6.55 MHz second carrier by four-phase DPSK modulation, and in the Swedish method (or Scandinavian method, B / G method), a second carrier of 5.85 MHz Is a method of transmitting 4-phase DPSK modulation and is also called a NICAM method.

The Swedish method (or Scandinavian method, B / G method) modulates a second carrier of 5.85 MHz into a four-phase DPSK using a 728 KHz clock and 728 Kbit / sec data as an input signal, and has a transmission bit rate of 728 Kbit / sec.

On the other hand, Japanese satellite voice multiplexing digitally transmits two channels of voice (A mode: mono, stereo and dual broadcast, B mode: stereo broadcast) and two independent voices (A mode), and carries a signal of 5.727272 MHz with a carrier. Is a method of adding four-phase DPSK modulation as a subcarrier.

The NICAM-728 Digital Voice Carrier System processes digital signals such as Near Instantaneous Companding, Bit Interleaving, and Energy Dispersal Scrambling for two voice and data signals. QDPSK (Quadrature DPSK) modulation and 16 second frame carrier (16 Frame Sequence: 16ms). The C-MAC-based speech coding is initially performed at 32 samples / ms block by 32KHz sampling frequency. 14 bits / sample are condensed at 10 bits / sample, and compressed sample encoding is performed with two's complement.

Figure 3 (a) is a diagram showing a stereo audio signal structure of one frame in the NICAM scheme, (b) is a diagram showing a mono audio signal structure of one frame in the NICAM scheme, the baseband frame structure is an 8-bit frame It consists of a synchronous signal, 5-bit control information, 11-bit additional data, and 728 bits of a 704-bit audio data block.

There was no French NICAM system, so there was no need to distinguish between sound modes. However, in order to implement a NICAM broadcasting system in France, there is a need to distinguish between the French NICAM mode and the D / K mode.

Referring to Figure 4, the reason why the need to distinguish between French NICAM mode and D / K mode is raised.

(A) of FIG. 4 shows a frequency spectrum of the French NICAM scheme, and (b) shows a frequency spectrum of the D / K scheme. The French NICAM signal becomes uneven when the NIC1 signal is affected by the S1 carrier. Sensitivity deteriorates. Therefore, in the French NICAM scheme, the energy of the S1 carrier must be attenuated in order not to be influenced by the S1 carrier, and in D / K mode, the energy of the S1 carrier must be passed without being attenuated.

Accordingly, the present invention distinguishes whether the broadcast voice signal currently being received is a French NICAM mode or a D / K mode, and automatically attenuates the energy of the S1 carrier (AM carrier) in the voice intermediate frequency signal when the French NICAM mode is used. It is an object of the present invention to provide a television that allows the viewer to listen to the voice multiplexing with a uniform sound quality by providing a portion that passes the voice intermediate frequency signal as it is.

In order to achieve the above object, the television of the present invention can determine whether the voice intermediate frequency signal is a French NICAM mode using a 5.85 MHz S2 carrier in addition to a 6.5 MHz S1 carrier or a D / K mode using an S2 carrier of 6.26 MHz. A video processor for discriminatingly outputting mode discrimination signals; A trap unit for attenuating and outputting energy of the S1 carrier of the voice intermediate frequency signal in the French NICAM mode according to the mode discrimination signal of the video processor, and passing the voice intermediate frequency signal as it is in the D / K mode; A sound processor for amplifying a voice intermediate frequency signal output from the trap unit and obtaining a low frequency signal; It characterized in that it comprises an amplifier for increasing the volume by power amplifying the weak low-frequency signal from the sound processor.

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

5 is a partial block diagram of a television reception system according to the present invention, wherein the television is a French NICAM mode in which the voice intermediate frequency signal (SIF) uses a 5.85 MHz S2 carrier in addition to the S1 carrier of 6.5 MHz. A video processor (10) for distinguishing between D / K modes and outputting a mode discrimination signal through a SECAM-L port (not shown); According to the mode discrimination signal output from the SECAM-L port of the video processor 10, in the French NICAM mode, the energy of the S1 carrier of the voice intermediate frequency signal SIF is attenuated and output, and in the D / K mode, A trap unit 20 for passing the voice intermediate frequency signal SIF as it is, a sound processor 30 for amplifying the voice intermediate frequency signal output from the trap unit 20 and obtaining a low frequency signal; And an amplifier 40 for power amplifying the weak low frequency signal from the sound processor 30 to increase the volume.

The trap unit 20 absorbs and attenuates only 6.5 MHz frequency signals when connected to ground and passes other frequency signals as it is, and 6.5 traps 21 pass all signals as they are regardless of frequency when not connected to ground; A reverse current preventing diode (D) connected to the 6.5 trap to prevent a reverse current from flowing to the 6.5 trap; The collector terminal is connected to the cathode terminal of the reverse current prevention diode (D), the emitter terminal is connected to the ground, and the base terminal is connected to the SECAM-L port of the video processor 10 so as to provide a logic high signal at the SECAM-L port. Is turned on to connect the 6.5 trap 21 to ground through the reverse current prevention diode D, and when the logic low signal is output, the NPN transistor does not connect the 6.5 trap 21 to ground. It consists of (Q).

Looking at the operation of the present invention in detail with reference to Figure 5 as follows.

First, the video processor 10 discriminates whether the voice intermediate frequency signal SIF is a French NICAM mode or a D / K mode, so that the video processor 10 is in the French NICAM mode, that is, when the television is currently receiving the broadcast voice signal in the French NICAM mode. Outputs a high signal and outputs a logic low signal in the D / K mode, i.e., when the television is currently receiving a broadcast audio signal in the D / K mode.

The NPN transistor Q of the trap unit 20 is turned on when a logic high signal is output from the SECAM-L port of the video processor 10 to connect the 6.5 trap 21 to ground, and the 6.5 trap 21 When connected to ground, only the energy of the S1 carrier 6.5 MHz of the voice intermediate frequency signal SIF is attenuated and output to the sound processor 30. On the other hand, the NPN transistor Q is turned off when the logic low signal is output from the SECAM-L port of the video processor 10, so that the 6.5 trap 21 is not connected to the ground. The frequency signal SIF is passed through as it is and output to the sound processor 30.

The sound processor 30 amplifies the voice intermediate frequency signal input through the 6.5 trap 21, obtains a low frequency signal, and outputs the low frequency signal to the amplifier 40.

The amplifier 40 amplifies the weak low frequency signal from the sound processor 30 to increase the volume and output the speaker to the speaker.

As described above, the television of the present invention automatically attenuates the energy of the S1 carrier (AM carrier) of the voice intermediate frequency signal and outputs it through the speaker when the broadcasting voice signal being received is the French NICAM mode. It is effective to listen to the voice of the multicast.

Claims (1)

The video processor 10 outputting a mode discrimination signal by discriminating whether the voice intermediate frequency signal is a French NICAM mode using a 5.85 MHz S2 carrier or a D / K mode using a 6.26 MHz S2 carrier in addition to a 6.5 MHz S1 carrier. Wow; The trap unit for attenuating the energy of the S1 carrier of the voice intermediate frequency signal in the French NICAM mode according to the mode discrimination signal of the video processor 10, and passing the voice intermediate frequency signal as it is in the D / K mode. 20; A sound processor (30) for amplifying a voice intermediate frequency signal output from the trap unit (20) and obtaining a low frequency signal; And an amplifier (40) for power amplifying the weak low frequency signal from the sound processor to increase the volume.