KR0119812Y1 - Tv sound maintenance circuit - Google Patents

Abstract

The present invention relates to a voice holding circuit of the TV, to solve the conventional inconvenience of having to adjust the output level of the voice manually from the outside in order to make the output level of the voice output to the speaker at every channel switching. For this purpose, a pulse generating means for generating a corresponding number of pulses for each broadcast channel tuned by channel switching, and a voice modulation degree for the broadcasting channel is recognized by the number of pulses generated by the pulse generating means, and the tone is adjusted according to the voice modulation degree. It is provided with a voice holding means for controlling the control unit to maintain a constant output level of the voice output to the speaker, so that the output level of the voice does not change even if there is a channel switch.

Description

TV's voice preservation circuit

1 is a block diagram of a voice related portion of a conventional TV.

2 is a block diagram of a voice-related part of a TV to which the voice maintaining circuit of the present invention is applied.

Figure 3 is a diagram showing the output waveform and the like in each part of the present invention.

* Explanation of symbols for main parts of the drawings

201: Tuner 202: Sour filter

203: voice intermediate frequency processing unit 204: tone control unit

206: voice amplifier 108: band pass filter

209: Integrator 210: Comparator

211: pulse conversion section 212: microcomputer

300: pulse generator

The present invention relates to a voice holding circuit of a TV, and more particularly, to a voice holding circuit of the TV which enables to maintain the output level of the voice output to the speaker to the previous output level even if the broadcast channel is switched.

FIG. 1 shows a related art audio output configuration of a TV, a tuner 101 for tuning a broadcast signal of a specific channel, and a saw filter for separating a voice intermediate frequency signal from a broadcast signal tuned through the tuner 101 ( 102, a voice intermediate frequency processor 103 for voice processing the voice intermediate frequency signal separated by the saw filter 102, and outputting a first voice signal and a second voice signal, and the voice intermediate frequency processor 103. The tone control unit 104 performs various voice control operations under the control of the voice control unit 105 with respect to the first voice signal and the second voice signal of the first voice signal, and the first voice signal controlled by the tone control unit 104; An audio amplifier 106 which amplifies the second audio signal and outputs it to the speakers 107a and 107b will be described.

When a broadcast signal of a specific channel is received by the tuner of the tutor 101, the broadcast signal is separated into a video middle frequency signal and a voice middle frequency signal by a SAW filter 102, and the separated voice middle frequency signal. The signal is voice processed by the voice intermediate frequency processing section 103 to obtain a first voice signal and a second voice signal.

The first audio signal and the second audio signal thus obtained are appropriately adjusted by the tone control unit 104 and the voice control unit 105, amplified by the voice amplifier 106, and output to the speakers 107a and 107b.

The problem of the conventional TV's voice processing circuit is that when the broadcasting channel is switched, the audio modulation level of the newly received broadcast signal is different from that of the previous broadcast signal, so that the output level of the voice output to the speaker is changed. In this case, in order to keep the output level of the voice constant, the output level of the voice must be manually adjusted from the outside, so this adjustment operation is very inconvenient.

Accordingly, an object of the present invention is to provide a TV voice maintaining circuit that can maintain the output level of the voice output to the speaker at the previous output level even if the broadcasting channel is switched.

According to the object of the present invention, the voice maintenance circuit of the present invention is a pulse generator for detecting a volume level difference according to different voice modulation degree for each broadcast channel tuned by channel switching and generating a predetermined number of pulses corresponding thereto; According to the number of pulses generated by the pulse generator to recognize the difference between the volume level of the broadcast signal and the control signal corresponding to the volume level difference thus recognized by controlling the tone control unit of the TV output level of the voice output to the speaker It consists of a microcomputer to keep a constant.

The operation and effects of the present invention will be described in detail with reference to FIGS. 2 and 3 showing one specific embodiment of the present invention configured as described above. In this case, detailed description of the same parts as in the prior art will be omitted.

In FIG. 2, when a broadcast signal of a specific channel is received from the tuner 201 and a voice is output from the speakers 207a and 207b, when the broadcast channel is switched, a new first voice according to this switching is performed. The signal and the second voice signal are output from the voice intermediate frequency processor 203, and the second voice signal is input to the band pass filter 208 of the pulse generator 300 according to the present embodiment.

Then, the bandpass filter 208 extracts only the 1KHz frequency component of the second audio signal and sends it to the integrator 209, and the integrator 209 integrates the 1KHz frequency component and compares the integrated DC voltage with the comparator 210. Send to). At this time, the band of 1KHz is set to a frequency band included in 20-2KHz, which is a reproduction frequency range in a general TV, and sounds most sensitive to humans, and is set to achieve effective compensation by compensating for the amount of change in this sensitive frequency band. In addition, the DC voltage output from the integrator 209 is different depending on the magnitude of the volume level according to the voice modulation degree of the received broadcast channel. As the volume level increases, the DC voltage increases.

In this way, the DC voltage output from the integrator 209 is compared with a predetermined ramp signal, which is a sawtooth waveform input to the inverting input terminal (-) of the comparator 210 and to its non-inverting input terminal (+), and thus the DC voltage The higher the level is, the narrower the pulse width modulated signal is output from the comparator 210. That is, when the level of the DC voltage is high, the narrow pulse width modulation signal is output from the comparator 210, and when the level of the DC voltage is low, the wide pulse width modulation signal is output from the comparator 210. Therefore, at this time, the pulse converter 201 receives and outputs a clock signal only for the pulse width corresponding to the pulse width of the pulse width modulation signal output from the comparator 210, and the pulse width modulation signal is high. A predetermined number of pulses are generated during the above pulse width.

Accordingly, the microcomputer 201 calculates the total number by counting the pulses generated by the pulse converting unit 211 and recognizes the volume level according to the voice modulation degree for the current broadcast channel. The tone control unit 204 is controlled by the corresponding preset control signal to correct the output level of the voice output to the speakers 207a and 207b, thereby keeping the output volume constant.

FIG. 3 shows waveforms outputted from each unit so far, and as in the case of (A), the pulse signal having a pulse width of 'T1' is output from the comparator 210 because the volume level according to voice modulation is low. When the pulse conversion unit 211 generates 7-8 pulses, the microcomputer 212 recognizes that the volume is low due to the low voice modulation (50-30%) of the received broadcast channel, and controls it. As shown by the curve, the tone control unit 204 is controlled so that the sound output is compensated for to increase, and the output level of the sound output to the speakers 207a and 207b is kept constant. Here, 'STEP1' corresponds to a position where the volume is adjusted externally before the switching of the broadcasting channel, and the microcomputer 201 controls the tone control unit 204 so that the audio output is constant based on this position.

As in the case of (b), when the pulse signal having the pulse width of 'T2' is output from the comparator 210, the pulse converter 211 generates 4 to 6 pulses, and thus the microcomputer 212 Recognizes that the volume level according to the normal voice modulation degree (80-50%) of the received broadcast channel is the same, and controls the tone control unit 204 to maintain the current state as shown by the control curve speaker ( The output level of the audio output to 207a and 207b is kept constant.

Finally, as in the case of (c), when the pulse signal having the pulse width of 'T3' is output from the comparator 210, the pulse converter 211 generates 1 to 3 pulses, and thus the microcomputer 212 ) Recognizes that the volume due to the high voice modulation (100-80%) of the received broadcasting channel is high, and controls the tone control unit 204 to compensate for the reduced voice output as shown by the control curve. The output level of the audio output to (207a) and (207b) is kept constant.

As described in detail above, the present invention allows the pulse generator to generate a predetermined number of pulses for each broadcast signal tuned by channel switching, and the microcomputer generates the number of pulses generated by the pulse generator. By recognizing the voice modulation degree and controlling the tone control unit according to the voice modulation degree, the output level of the voice output to the speaker can be kept constant.

Claims (3)

Pulse generation means for detecting a difference in volume levels according to different voice modulation degrees for each broadcast channel tuned by channel switching, and generating a predetermined number of pulses corresponding thereto, and the broadcasting according to the number of pulses generated by the pulse generation means. The microphone recognizes the volume level according to the voice modulation degree of the channel, and controls the tone control unit of the TV with the control signal corresponding to the recognized voice level and maintains the output level of the voice output to the speaker even when the channel is switched. A voice maintaining circuit of a television, comprising a computer. 2. The apparatus of claim 1, wherein the pulse generator comprises a band pass filter for extracting only a 1 KHz frequency component of the voice signal output from the voice middle frequency processing unit of the TV, and converting the 1 KHz frequency component extracted by the band pass filter into a DC signal. An integrating unit, a comparing unit comparing the magnitude of the DC signal output from the integrating unit with a predetermined ramp signal to generate a pulse width modulation signal having a predetermined pulse width, and a pulse width modulation signal generated by the comparing unit. And a pulse converter for generating a predetermined number of pulses corresponding to the pulse width. The voice of the TV according to claim 1, wherein the microcomputer compensates the voice output when the volume level according to the perceived voice modulation is high and increases the voice output when the volume level according to the voice modulation is low. Holding circuit.