SU1123512A1 - Noise suppressor - Google Patents

Abstract

A noise suppressor containing an operational amplifier and a frequency dependent voltage divider, one output of which is the input of the squelch, the other connected to the output of the operational amplifier, which is the output of the noise suppressor, and the output of the frequency-dependent voltage divider connected to the inverting input of the operational amplifier, with the first shoulder frequency-dependent voltage divider is made in the form of a resistor, and the second - in the form of a parallel-connected main high-pass filter and low-pass filter, and t Also, the control voltage driver, the output of which is connected to the control input of the second arm of the frequency-dependent voltage divider, characterized in that, in order to reduce the noise level modulation, the main high-pass filter is frequency controlled and its input control is the control input of the second arm of the frequency-dependent voltage divider, the input of the control voltage generator is connected to the output of the input additional (the main frequency-controlled high-pass filter identical to The main high-pass filter, whose control input is connected to the output of the control voltage driver, and the input is connected to the input or output of the noise suppressor. -

Description

11 The invention relates to instrumentation, in particular, to general purpose electronic circuits and gain control devices, in particular, to reduce and expand the dynamic range of loudness in amplifiers, and can be used in magnetic recording, recording and broadcasting equipment. A device for automatic compression or dynamic range expansion is known, which contains signal and control channels, the signal channel includes an inverting amplifier, the input of which is the output of the device, a low-pass filter, the output of which is connected to the input of the inverting amplifier, and the terminals of which are connected to the input of the inverting amplifier, and the control channel includes a control voltage driver. However, the known device has a low noise reduction efficiency due to the effect of the modulation of the noise level, which is a result of a change in the noise level with a change in the level of the useful signal. The closest in technical essence to the present invention is a noise suppressor containing an operational amplifier, a frequency-dependent voltage divider, one output of which is the input of a noise suppressor, the other connected to the output of an operational amplifier, which is the output of the noise suppressor, and the removal of the frequency-dependent divider wiring is connected to the inverting input of the ope. the first amplifier of the frequency-dependent voltage divider is made in the form of a resistor, and the second is in the form of parallel-connected main high-pass filter and low-pass filter, as well as a control voltage driver, the output of which is connected to the control input of the second frequency-dependent voltage divider. However, the known noise suppressor has a low noise reduction efficiency due to the effect of modulating the noise level. The aim of the invention is to reduce the modulation of the noise level. 12 2 The goal is achieved by having a noise suppressor containing an operational amplifier and a frequency-dependent voltage divider, one output of which is the input of the noise suppressor, the other connected to the output of the operational amplifier, the output of the noise suppressor, and the output of the frequency-dependent voltage divider connected to the inverting input of the operational amplifier, with the first shoulder of the frequency-dependent voltage divider made in the form of a resistor, and the second in the form of a parallel filter connected in parallel The high-pass and low-pass filter, as well as the control voltage driver, the output of which is connected to the control input of the second arm of the frequency-dependent voltage divider, the main high-pass filter is frequency controlled, and its control input is the control input of the second of the frequency-dependent voltage divider, the input of the control voltage driver is connected to the output of the introduced additional frequency-controlled high-pass filter and identical to the main high-pass filter one whose control input is connected to vphodom shaper control voltage, and an input connected to the input or output of the squelch. Figure 1 shows a structural electrical noise suppressor circuit in compression mode; Figure 2 is an electrical circuit of a noise suppressor in expansion mode. The noise canceller includes an operational amplifier 1, a frequency-dependent voltage divider 2, the first arm of which is made on resistor 3, and the second on low-pass filter 4 and main high-pass filter 5, additional low-pass filter 6 and control voltage driver 7. The control voltage driver 7 comprises a series-connected amplitude detector, a threshold element and a storage capacitor with charge and discharge circuits (not shown in the drawings). Squelch works as follows. Output impedance of the low pass filter 4 and the main filter

Together with the resistor, the high-frequency circuit 5 forms 3 dividers, which are included in the negative feedback circuit of the operational amplifier 1 and determine the transmission coefficient of the noise suppressor in the passbands of the specified filters. The output impedance of the main high-pass filter 5 is selected N times less than the output impedance of the low-pass filter 4, so that in the compression mode, the transfer ratio of the noise suppressor in the passband of the main filter 5. The high-pass will be N times the transmission coefficient of the device in the passband of the lower 4 filter frequencies, and in the expansion mode, respectively, N times less. The number N determines the maximum amount of compression or expansion of the dynamic range of the signal components located in the passband of the main high-pass filter 5 and does not depend on its cut-off frequency. The change in the amount of compression or expansion of the dynamic range of the signal is carried out only in the attenuation band of the fundamentals of the High pass filter 5 when the cut-off frequency is tuned.

In the absence of a signal at the input of the compressor and, accordingly, at the input of the expander, the amplitude-frequency characteristic of the compressor has a rise, and the amplitude-frequency characteristic of the expander is a reverse fall in the region of medium and high frequencies, resulting in mid-frequency and high-frequency noise of the transmission channel connected between the compressor output and the expander entrance, having passed through the expander, is weakened. The maximum noise attenuation is determined by the value of N, and the frequency range in which the noise reduction is carried out is determined by the initial bandwidth of the main high-pass filter 5.

When a signal with mid-frequency and high-frequency components arrives at the compressor input, the level of which is below the threshold of the threshold element of the control voltage driver 7, the amplitude-frequency characteristic of the compressor has an increase in the medium and high frequencies. Thanks to this rise

The pressure signals, having passed through the compressor, enter the transmission channel and then amplified to the input of the expander. Passing through the expander, these components are attenuated to the former level due to the reverse effect of the expander on them, while simultaneously with the components of the signal the transmission channel noise components located in the same frequency range are attenuated.

The signal input to the Compressor with mid-frequency components exceeding the threshold of the threshold element of the control voltage generator 7 and high-frequency components with a level below the specified threshold leads to an increase in the cut-off frequency of the high-pass filters 5 and 6, as a result of which the compressor transmission coefficient on the middle The frequencies are reduced, remaining unchanged at high frequencies and thus providing the maximum amount of compression at these frequencies.

In the expander, these components are attenuated together with the noise components of the transmission channel. Moreover, in the high frequency range, this attenuation is maximal and corresponds to the maximum value of the expansion.

With a further increase in the level of the mid-frequency and high-frequency components of the upper threshold of the threshold element of the control voltage driver 7, the cut-off frequency of the filters 5 and 6 of the upper frequencies is tuned above the limiting frequency of the operating range. At the same time, the transmission coefficient of the compressor in the region of medium and high frequencies decreases so much that the mid-frequency and high-frequency components of the signal passing through the compressor are weakened, thereby preventing overloading of the transmission channel by these components. lchimi With the passage of these components through the expander, they are amplified to the initial level.

At the same time, the corresponding components of the transmission channel noise are amplified. However, due to the psychoacoustic effect of masking by the loud sounds of quiet sounds, these components of the noise are not bugged.

Control voltage in the compressor at the output of the driver 7 control 511235126

For a good voltage, you can represent „„ R „, in the form of the following expression: R f

- can be written in the following form

UK .ккв (Ри,) - и „, (1)

where and. ,,, is the output voltage of com-from Expression 7, it is seen that the compression of the pressure signal of the compressor; the amic range of the signal to the com- pressure of the threshold of the compression cylinder is carried out with a constant

a threshold el-coefficient of 0.5. Shaper unit 7 up-fO Control voltage in the expansion of the equal voltage; the tree at the output of the former 7 can

Kg (F, U, j) is the transfer coefficient to be presented as the following expression filter 6: for high frequencies, which is a function of frequency, and 15 U,. For KgCF.U,) - uj, (8) control voltage ; .

K, is the transfer ratio for-I “. - the input voltage of the emitter 7 control-pander.

go voltage expressions 8 we define the value

From the expression 1, we determine the value of the 20 additional transmission coefficient

transmission coefficient of an additionalFilter 6 high-pass filter 6 high-pass, U, U fn

, h and „Uv, -v 7 -VE

to (F, U) - - + fi, whence from K, - with we get

you) l.k 7 ebix.K25

whence we get ... ,, ... Un,.,. 4

Kg (F, U) -. (3) Output expander voltage

The output voltage of the compressor can be ° ° ° to be presented in the following form: present in the following form 30Kg- 1 /

. R .. you.e U "X., R; K-DGGi-Uebix .K. .k) () Since the filters 5 and 6 of the upper parts where and, - the input voltage is com- “identical and have the same, the dependence of the cut-off frequency on the control Kj (F, U) is the transfer voltage of the main voltage,

new filter 5 top- / t. ,, h ,, / v, UN, these frequencies-, K5 (F, U,) K (F, U,),

R, - resistance resisto- "expression 11 will take the form

R. 40i and and Bi.HiL.

Ry - output resistance vyh.e -e R ,,) R U

main top5 top- (12)

gnich frequency

Since the filters 5 and 6 of the upper S-vyh.-, (13)

that are identical and have the same s n

dependence of cutoff frequency on control-R,

voltage, if K const, then the voltage

K, (F, UK) "K, (F, u,) iv,". Er., - Y-

and expression 4 takes the following form: ° From expression 14 it is clear that the expansion of RII

T1 p. P. If Stg IT - 11 expander is carried out with a post-RhJVW Atk) in V K f T

. 5. Exit a coefficient equal to 2.

, R, Providing conditions Vj.t 9ЫJ.к

  55, expression 14 can be rewritten

Ue.,. K S. (;). (6) and ,,, UV ,,,. {-(15)

If and .-- K const, then the expression b

5 vii.k (Ki,.,). (7)

b -

  and

6 will take a look at the dynamic range of the signal

the form

or taking into account the expression 7

(sixteen)

and.

and,

output 9 in-x From equality 16, it follows that as a result of compression and subsequent expiration, the proposed yctpoftcTBOM of the dynamic range of the signal does not change.

Thus, in the noise canceller, compression and expansion of the dynamic range and, accordingly, reduction

1235128

the noise of the transmission channel is carried out in the passband of the high-pass filter with a automatically tunable signal depending on the spectrum

 5 by the cut-off frequency, thereby reducing the effect of modulating the noise level.

The use of noise reduction, for example, as part of a tape recorder, allows you to increase the signal-to-noise ratio of the recording channel — playback and 20 dB.

FIG.

Claims (1)

A noise suppressor containing an operational amplifier and a frequency-dependent voltage divider, one output of which is an input of a noise suppressor, the other is connected to an output of an operational amplifier, which is an output of a noise suppressor, and a tap of a frequency-dependent voltage divider is connected to an inverting input of an operational amplifier, with the first pa and the second in the form of a parallel connected main high-pass filter and a low-pass filter, as well as a control voltage driver, the output of which is connected to the input board of the second shoulder of the frequency-dependent voltage divider, characterized in that, in order to reduce the modulation of the noise level, the main high-pass filter is frequency-controlled, and its control input is a control input of the second shoulder of the frequency-dependent voltage divider, the input of the control voltage generator d is connected to the output of an optional additional frequency-controlled / high-pass filter identical to the main high-pass filter, whose control input is connected to the output tors, the control arm 5, frequency-dependent voltage divider is designed as a rezistonapryazheniya and input connected to the input or output of the squelch. FS.1 1 11