JPH0317485Y2 - - Google Patents

Description

[Detailed Description of the Invention] (a) Industrial Application Field The present invention relates to an audio signal processing circuit including a noise reduction circuit.

(b) Prior Art Noise reduction (NR) circuits are increasingly being used in recording and reproducing analog signals for the purpose of reducing noise. For example, there is a Dolby NR circuit in an audio cassette tape recorder, or an SNR circuit used in a β system Hi-Fi VTR audio circuit. These NR circuits generally reduce the noise generated during recording and playback by compressing the dynamic range of the high-frequency signal of the input audio signal during recording and expanding it during playback (Sanyo Technical Review). There is an explanation about the SNR circuit in VoL.16, No.1, 1984.PP.88-90).

Since this compression/expansion operation is controlled based on the components of the input audio signal, the input signal of the NR circuit may be a signal other than the information signal, such as a 19KHz pilot signal for stereo demodulation superimposed on the output of an FM tuner or a television receiver. 15.75KHz due to the influence of
There is a risk that the NR circuit may malfunction due to the horizontal synchronization signal. That is, due to the presence of the 19 KHz pilot signal, the rate of compression and expansion during recording and reproduction is reduced, and therefore the noise suppression effect is reduced, making the noise more noticeable.

Therefore, in the past, a 19KHz trap circuit was inserted into the circuit when receiving FM, as disclosed in Utility Model Application No. 55-133655. However, if a 19KHz trap circuit or 15.75KHz trap circuit, or low-pass filter (LPF), is inserted into the audio signal processing circuit, the high-frequency components of the audio signal information will also be cut out, so these trap circuits must always be used. It is not recommended to insert it.

(c) Problems to be solved by the invention As stated above, in the conventional configuration, a 19KHz trap circuit is always inserted when receiving FM. Similarly to this configuration, if a 15.75KHz trap circuit is inserted, the high frequency components of the audio information signal will be cut out. Also, 19KHz pilot signal and 15.75KHz
Even if the horizontal synchronization signal is superimposed on the audio signal,
In general, it is not possible to tell the difference. Therefore, even if each trap circuit can be attached or detached, a trap circuit is always inserted and recording is often performed with poor frequency characteristics.

Therefore, it is desirable to have a configuration in which whether to attach or detach the trap circuit is automatically determined according to the level of a signal other than the audio information signal. The present invention has been devised in view of this point, and provides an audio signal processing circuit that automatically determines whether a trap circuit is attached or detached.

(d) Means for solving the problem In the present invention, means for removing the 15.75 KHz horizontal synchronizing signal and the 19 KHz pilot signal is arranged before the NR circuit. It is controlled according to the level. Therefore, horizontal synchronization signal extraction means, pilot signal extraction means, horizontal synchronization signal level comparison means, and pilot signal level comparison means are provided.

(e) Operation Therefore, the pilot signal removing means and the horizontal synchronizing signal removing means are controlled according to the levels of the pilot signal and the horizontal synchronizing signal. Therefore, each removal circuit is automatically attached and detached, and the audio signal processing circuit can be set in an optimal manner for the state of the input signal.

(f) Examples Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a circuit block diagram of an embodiment. 1st
In the figure, 1 is an audio input changeover switch, 2 is a first low-pass filter (LPF) that removes the horizontal synchronization signal, and 3 is a second low-pass filter (LPF) that removes the pilot signal.
LPF, 4 is an SNR circuit, 5 is an FM modulation circuit,
The FM modulation circuit output is fed to a rotating head and recorded on tape. In other words, this embodiment is Hi-
This applies to FiVTR.

6 is a first band pass filter (BPF) that extracts the horizontal synchronization signal, 7 is a second BPF that extracts the pilot signal, 8 is a first rectifier circuit that converts the level of the horizontal synchronization signal to a DC level, and 9 is the pilot signal. The first and second rectifier circuits 8 and 9 each include resistors R ₁ , R ₂ , R ₃ , R ₄ , capacitors C ₁ and C ₂ , and diodes. It is equipped with D ₁ and D ₂ .

10 is a first level comparison circuit, which includes resistors R ₅ ,
The reference voltage by R ₆ and the output of the first rectifier circuit 8 are compared. Reference numeral 11 denotes a second level comparison circuit, which compares the reference voltage provided by resistors R ₇ and R ₈ with the output of the second rectifier circuit 9.

First and second switch means 12 and 13 are provided between the first LPF 2 and the second LPF 3 and the ground, respectively, and when these switches are in the on state, the corresponding LPFs are activated and a predetermined signal is output. remove. When the switch means 12 and 13 are in the OFF state,
Each LPF 2 and 3 does not affect the audio circuit.

The states of the switch means 12 and 13 are respectively
It is controlled by the outputs of the first and second level comparison circuits 10 and 11. The output of each level comparison circuit 10, 11 is
It also controls the first and second display circuits 14 and 15.

The first display circuit 14 includes a transistor Q ₁ light emitting diode LED ₁ and a current limiting resistor R ₉ , and the on/off of the transistor Q ₁ is controlled by the output of the first level comparison circuit 10 . The second display circuit 15 is
Similarly, transistor Q ₂ and light emitting diode
It is equipped with LED ₂ and current limiting resistor R ₁₀ .

Figure 2 shows the 1st LPF2 (shown by the solid line), the 2nd LPF
3 (indicated by broken lines). FIG. The 1st LPF2 is the frequency of the horizontal synchronization signal
Attenuates the frequency of 15.75KHz by more than 40dB. or,
The 2nd LPF3 receives the 19KHz pilot signal in the same way.
Attenuates by more than 40dB.

FIG. 3 shows the frequency characteristics of the first and second BPFs 6 and 7. The solid line shows the characteristics of the first BPF 6, and the broken line shows the characteristics of the second BPF 7. The first BPF 6 allows the horizontal synchronizing signal component to pass, and is set so that the attenuation is large for other frequency components. The same applies to the second BPF7.
Furthermore, the band of the audio information signal must be kept as free from restrictions as possible.

Next, the operation will be explained. For example, when the input audio signal selected by the changeover switch 1 is an output from an FM tuner, the pilot signal component extracted by the second BPF 7 becomes large, and the second rectifier circuit 9
output level increases. When this level becomes higher than the level determined by the first level comparison circuit, the output of the operational amplifier 17 changes from the L level to the H level, turning on the second switch means 13. As a result, the second LPF3 becomes operational,
The pilot signal component is removed and the NR circuit does not malfunction.

When a horizontal synchronizing signal is superimposed as an interference signal on the input audio signal, for example when there is an influence from a television receiver placed nearby, the output level of the first rectifier circuit 8 increases. When this level is higher than the predetermined level of the first level comparison circuit 10, the output of the operational amplifier 16 becomes H level, and the first switch means 12 is turned on. Therefore 1st LPF
2 operates to remove the horizontal sync signal.

When the outputs of the level comparison circuits 10 and 11 go to H level, the transistors Q ₁ and Q ₂ are turned on, respectively, and the light emitting diodes LED ₁ and LED ₂ are turned on. This lighting display indicates that the level of the corresponding interference signal, ie, the pilot signal and horizontal synchronization signal, exceeds the interference level of the SNR circuit 4. Therefore, a configuration may be considered in which the first and second LPFs 2 and 3 are controlled by operating a manual switch means that supplies the power supply voltage when turned on in accordance with the lighting display.

The reference voltage of each level comparison circuit 10, 11 is
Just set it to the interference level of the SNR circuit. That is, each reference voltage is set to a level beyond which the noise reduction circuit will malfunction.

The switch 20 is a switch that is linked to the changeover switch 1, and the changeover switch 1 is a switch that is linked to the changeover switch 1.
When the TV tuner is selected, the operational amplifier 17 output is forcibly grounded. With such a switch, the output of the second level comparator circuit 11 will not become H level by mistake when the audio output of the TV tuner is being applied.

Furthermore, if a manual switch similar to switch 20 is placed at the output of each operational amplifier 16, 17, the first and second LPFs can be manually and forcibly deactivated.

(g) Effects of the invention As described above, in the present invention, when the level of the interference signal is large, the removal means automatically operates, so it is possible to prevent malfunction of the NR circuit and improve the S/N ratio. . Further, when the level of the interfering signal is low, the removing means does not operate, and the frequency characteristics in that case are improved, which is practical.

[Brief explanation of drawings]

FIG. 1 is a circuit block diagram of an embodiment of the present invention, FIG. 2 is a frequency characteristic diagram of the removing means, and FIG. 3 is a frequency characteristic diagram of the extracting means. 2, 3... Interfering signal removal means (first, first
2LPF), 4... SNR circuit, 6, 7... Interference signal extraction circuit (first, second BPF), 10, 11... Level comparison means, 12, 13... First, second switch means.

Claims (1)

[Scope of utility model registration request] In an audio signal processing circuit having a noise reduction circuit, a removal filter means for removing a continuous interference signal other than an audio information signal provided before the noise reduction circuit, and an extraction filter for extracting the interference signal. and level comparison means which receives the output of the extraction filter means as an input, and the removal filter means is controlled by the level comparison means output means.