RU184643U1 - Squelch model - Google Patents

Abstract

The utility model relates to the field of metrology, in particular to devices for simulating a static type noise reduction system with frequency predistortions. The first processing and broadcasting channel comprises a series-connected predistortion circuit, a broadcast path, and a recovery circuit. The predistortion circuit includes a series-connected first amplifier, a high-pass filter, the outputs of which are connected to different inputs of the first adder, the output of which forms the output of the predistortion circuit. The broadcast path consists of two adders: a second adder and a third adder. The recovery circuit consists of a tunable low-pass filter, an adjustable amplifier, an adder. The multiplexer has four signal inputs, four multipliers, adders, two outputs, a control input that is connected to a source of control signals, an inverter, a signal source of a single level. The technical result consists in increasing the efficiency of the simulation of noise reduction systems. 1 ill.

Description

Technical field

The utility model relates to the field of measurement technology and is intended to simulate a static type noise reduction system with frequency predistortions for scientific and educational purposes.

The purpose of the utility model is to increase the efficiency of simulating a noise reduction system.

This goal is achieved by combining the ability to simulate a noise reduction system with frequency predistortions with the ability to alternate the sequence of unprocessed and frequency-processed audio signals at the outputs of a noise reduction system simulation device, which will allow using the model for conducting auditory examinations using pairwise comparisons, for which four signal signals are introduced into the multiplexer input, two for each channel, through which the outputs of the channels are connected to the first inputs of four controllers, from the first to the fourth, respectively, control signals are supplied to the second inputs of these multipliers, moreover, if the control signals from the control input of the multiplexer are fed directly to the second inputs of the first and third multipliers, then the control signal is supplied to the second inputs of the second and fourth multipliers, polarity which has been changed, for which the control signal from the control input of the multiplexer is fed to the inverter, from the output of which - to the first input of the fifth adder, to the second input of which a signal is supplied from the signal source of the unit level, the output of the fifth adder is connected to the second inputs of the second and fourth multipliers, the signals from the outputs of the first and second multipliers are fed to different inputs of the sixth adder, and from the outputs of the third and fourth multipliers to different inputs of the seventh adder, the sixth adder forms the first output of the multiplexer and the entire device, and the output of the seventh adder forms the second output of the multiplexer and the entire device.

Description of analogues

A device for simulating a static-type noise reduction system with frequency predistortions [1]. This type of system introduces a rise in the level of high-frequency components of an audio signal during transmission or recording using a predistortion circuit, followed by correction during reception or playback using a restoration circuit. As a result of the combined action of these circuits, frequency distortion does not occur, but the influence of the noise spectral component on the output signal of the device is reduced.

The reasons that impede the achievement of the required technical result when using the known device include the fact that the device does not have the ability to ensure alternation of the sequence of unprocessed and frequency-processed signals at the outputs of the device, which is a prerequisite for conducting auditory examinations using pairwise comparisons.

Prototype description

The closest solution for the same purpose in terms of features is a multiplexing device that allows you to obtain an alternation of signals supplied to its inputs at each of its two outputs, while the signals are switched in pairs with each other using a control signal supplied to the control input of the device [ 2 - prototype].

Prototype criticism

The reasons that impede the achievement of the required technical result when using the known device include the fact that it does not provide unprocessed and frequency-processed signals imitating a noise reduction system, i.e. its application is of a subordinate nature: the signals to the main and control inputs of the device must come from sources external to it and have the parameters required for implementing the method of pairwise comparisons.

Utility Model Essence

The problem the utility model aims to solve is to increase the efficiency of simulating a noise reduction system.

This problem is solved due to the achievement in the implementation of a useful model of a technical result, which consists in combining the ability to simulate a noise reduction system with frequency predistortions with the ability to alternate the sequence of unprocessed and frequency-processed audio signals at the outputs of the device simulating a noise reduction system.

The specified technical result in the implementation of the utility model is achieved by the fact that four signal inputs are introduced into the multiplexer, two for each channel, through which the channel outputs are connected to the first inputs of four multipliers, from the first to the fourth, respectively, signals are fed to the second inputs of these multipliers control, moreover, if the second signal of the first and third multipliers is supplied directly with a control signal from the control input of the multiplexer, then the second inputs of the second and four of the second multipliers, a control signal is supplied whose polarity is reversed, for which a control signal from the control input of the multiplexer is fed to an inverter, from the output of which - to the first input of the fifth adder, to the second input of which a signal is supplied from a signal source of a single level, the output of the fifth adder is connected to the second the inputs of the second and fourth multipliers, the signals from the outputs of the first and second multipliers are fed to different inputs of the sixth adder, and from the outputs of the third and fourth multipliers to different moves the seventh adder, wherein the output of the sixth adder forms an output of the first multiplexer and the entire device, and the output of the seventh adder - a second multiplexer output and the entire device.

List of drawings

The figure shows a structural diagram of a device that implements the proposed utility model, where 1 is the first channel of processing and broadcasting; 2 - predistortion circuit, 3 - first amplifier; 4 - high-pass filter; 5 - the first adder; 6 - broadcast path; 7 - second adder; 8 - the third adder; 9 - a source of interference common to both channels; 10 - recovery circuit; 11 - low-pass filter; 12 - second amplifier; 13 - the fourth adder; 14 - the second channel of processing and broadcasting; 15 - multiplexer; 16 - source of control signal; 17 - the first signal input of the multiplexer; 18 - the second signal input of the multiplexer; 19 - the third signal input of the multiplexer; 20 - the fourth signal input of the multiplexer; 21 - control input of the multiplexer; 22 - the first multiplier; 23 - the second multiplier; 24 - the third multiplier; 25 - the fourth multiplier; 26 - inverter; 27 - source signal unit level; 28 - fifth adder; 29 - sixth adder; 30 - seventh adder; 31 - the first output of the multiplexer; 32 - the second output of the multiplexer. Blocks 3, 4, 11, and 12 are tunable.

Information confirming the feasibility of implementing a utility model

Information confirming the possibility of implementing a utility model to obtain the specified technical result is as follows.

It is known the use of noise reduction systems in the channels of sound broadcasting or in devices for recording and reproducing audio signals, introducing a rise in the level of high-frequency components of the signal during transmission with subsequent correction when receiving. The feasibility of introducing frequency predistortions of the signal is based on the premises set forth in [1].

The proposed device is a simulator of a two-channel noise reduction system with adjustable values of the parameters of the pre-emphasis and correction circuits. The device is intended for conducting auditory examinations aimed at determining the optimal frequency dependencies of these circuits of the system when transmitting audio signals of various genre nature and origin, including synthesized signals, in the presence of noise uniformly distributed over the spectrum in the path.

The device contains two channels of processing and broadcasting identical to each other (1 and 14), a common source of interference 9 for the channels, and a multiplexer 15 controlled by the source 16 of the control signal, each channel including a series-connected predistortion circuit 2, a broadcast path 6 recovery circuit 10, the composition of the predistortion circuit 2 includes series-connected adjustable first amplifier 3 and high-pass filter 4, connected by the output of high-pass filter 4 to one of the inputs of the first adder 5, to another the input of which is connected to the input of the first amplifier 3, which is simultaneously the input of the predistortion circuit 2 and the input of channel 1, the output of the predistortion circuit 2 is the output of the first adder 5, the broadcast path 6 includes the second 7 and third 8 adders, one of the inputs of the second adder 7 is connected to the output of the first adder 5, an interference source 9 is connected to another input of the second adder 7, the output of the second adder 7 is connected to the input of the recovery circuit 10, the input of the predistortion circuit is connected to different inputs of the third adder 8 and 2 and the interference source 9, the output of the third adder 8 is the first channel output connected to one of the four signal inputs of the multiplexer 15, the recovery circuit 10 includes adjustable second amplifier 12 and a low-pass filter 11, the inputs of which are connected to the output of the second adder 7, and the outputs are with different inputs of the fourth adder 13, the output of which forms the output of the recovery circuit 10, which is also the second output of the channel connected to another signal input of the multiplexer 15, .e. each of the two outputs of both channels is connected to a separate signal input of the multiplexer 15, the switching of which is controlled by the control signal source 16 connected to the control input of the multiplexer 15, the two outputs (31 and 32) of the multiplexer 15 form two outputs of the entire device, and the channel inputs (1 and 14) processing and broadcasting form two inputs of the entire device. The first 3 and second 12 amplifiers, as well as a high-pass filter 4 and a low-pass filter 11 are made adjustable.

The outputs of channels 1 and 14 formed by the outputs of the third adders of the channels provide signals that do not undergo frequency processing, but contain only added interference. The outputs of the fourth channel adders provide a signal that has undergone frequency processing, which affects the addition of noise.

The multiplexer provides an alternation of the sequence of unprocessed and frequency-processed channel signals at the device outputs, which is required for auditory examinations carried out by the method of pair comparisons and aimed at determining the influence of the values of the noise reduction system correction circuit parameters on the sound quality in the presence of evenly distributed noise spectrum in the path broadcasting or recording-playback path of audio signals. At the control input of the multiplexer 15 from the source 16 of the control signal, a control signal of the operation of the multiplexer is supplied, switching the output signals of the channels in pairs with each other. This signal is a meander frequency of 0.1 Hz. Two outputs of the multiplexer 15 form two outputs of the entire device. When simulating a noise reduction system for single-channel broadcasting, one of the processing channels is used, at the input of which a monophonic signal source is connected. When simulating a noise reduction system of two-channel (stereo) broadcasting, both processing and broadcasting channels are used, the inputs of which are connected to the left and right channels of the signal source.

The device operates as follows. The signal from the output of the sound signal source is fed to the input of the predistortion circuit 2. The unchanged source signal also goes to one of the inputs of the first adder 5, to the other input of which the high-frequency part of the signal extracted by the high-pass filter 4 from the input signal previously amplified by the first amplifier 3 is fed. Amplifier 3 and filter 4 are adjustable, which allows during the experiments to change the beginning, steepness (parameters of the high-pass filter 4) and the amount of rise (transmission coefficient of the first amplifier 3) of the frequency response of the predistortion circuit. Next, the predistorted signal from the output of the first adder 5, together with the interference signal from the source 9, is fed to the second adder 7, the output of which is connected to the input of the recovery circuit 10, where, with the help of the low-pass filter 11, the frequency response is reduced in the high-frequency region. The low-pass filter 11 and the second amplifier 12 are adjustable. This ensures the regulation of the beginning, steepness and decrease in frequency response of the recovery circuit. Simultaneously with the supply of the signal to the input of the predistortion circuit 2, the input signal together with the interference signal from the interference source 9 is supplied to the third adder 8, the output of which is a noisy signal that has not passed processing. Processed by the noise reduction system and unprocessed sound signals from the outputs of the third 8 and fourth 13 adders are fed to different signal inputs of the multiplexer 15, where, alternately, using the control signal from the source 16, they are switched to the output signal of the first output 31 of the multiplexer 15, which means the whole device. When using a two-channel source of an audio signal and both processing and broadcasting channels, the output signals of the second processing and broadcasting channel 14 are supplied to the other two inputs of the multiplexer 15, which are switched to a different output signal at the second output 32 of the multiplexer 15 and the entire device, which ensures two-channel broadcasting.

The disclosed internal structure of the multiplexer 15 has four signal inputs from 17 to 20, to which the outputs of both channels are connected. So, to the signal input 17 is connected the first output of the first channel 1, through which the unchanged but noisy input signal of this channel is transmitted, to the signal input 18 - the second output of the first channel 1, through which the noisy and processed signal of this channel is transmitted, to the signal input 19 - the first output of the second channel 14, through which the unchanged but noisy input signal of this channel is transmitted, to the signal input 20 - the second output of the second channel 14, through which the noisy and processed signal of channel 14 is transmitted.

The control input 21 of the multiplexer 15 receives a signal whose value determines the connection to the outputs 31 and 32 of one of the two signal inputs (17 or 18 for the first channel and 19 or 20 for the second channel of the device). When the level of the control signal corresponds to unity (1 V), the sound signals from the input 17 for the first channel and from the input 19 for the second channel are supplied to the first 22 and second 24 multipliers, respectively, where they are multiplied with a unit level of the control signal, as a result, through the sixth adder 29 and the seventh adder 30 signals arrive at the outputs of the multiplexer 31 and 32, respectively.

At the same time, using the inverter 26, the source signal source 27 and the fifth adder 28, the control signal changes its polarity and then multiplies with sound signals applied to the input 18 for the first channel and to the input 20 for the second channel, through the second multiplier 23 and the fourth multiplier 25, respectively.

Due to the fact that in the fifth adder 28, the control signal, the polarity of which is changed, is added to the unit level generated by the source 27, at the inputs of the multipliers 23 and 25 the value of the control signal turns out to be zero, and as a result, the sound signal does not pass at this moment in time through these multipliers. When the signal level at the input 21 of the control takes a zero value, the multipliers 22 and 24 stop passing the signal, at the same time, a single level is formed at the output of the fifth adder 28, which allows the signal to pass through the multipliers 23 and 25, thereby switching the data streams from the inputs 18 and 20 to the corresponding outputs of the multiplexer 15.

The device can be implemented in hardware and software, for example, using the System View simulation package (currently the package has been renamed “SystemVue”), developed by Elanix. The package implements simulation systems at the level of functional blocks. The internal structure of the multiplexer 15 can be implemented as a metasystem. Metasystems in SystemView serve to introduce a project hierarchy and are components that contain subsystems that can include other metasystems, representing a multi-level hierarchical structure.

It is important that the SystemView system has the ability to record a temporary implementation to a file, which allows you to process data using other software tools, including using a PC sound card, and this provides the ability to listen to the audio file. Sources and receivers of audio signals can be audio two-channel WAV-files. As the most characteristic source of interference 9, you can use the white noise generator. As the source 16 of the control signal, you can use a square wave generator (meander) with a frequency of 0.1 Hz. This allows you to get the sound file at the output of multiplexer 15, in which the sound of the system-processed noise reduction and the unprocessed signals will alternate with a predetermined time interval, which increases the convenience of performing an auditory assessment of the results of the system depending on the set values of the parameters of the adjustable blocks.

The above indicates that the structural diagrams of the processing and broadcasting channels of the noise suppressor model provide unprocessed and frequency-processed signals at their outputs, while the structural diagram of the multiplexer, to the main inputs of which the outputs of the processing and broadcasting channels are connected, provides an alternation of these signals on the outputs of the entire device. This will make it possible to use the model of the noise reduction system for conducting auditory examinations using the paired comparisons method, which requires alternating reference and evaluated audio signals, in which the experts are presented with listening to unprocessed and frequency-processed signals, respectively.

Thus, the above information indicates the fulfillment of the following conditions when using the claimed utility model:

- a device that embodies the claimed utility model in its implementation, will more effectively simulate a noise reduction system.

- for the claimed utility model in the form described in the utility model formula, the possibility of its implementation using the means described above or known prior to the priority date is confirmed;

- a device embodying the claimed utility model in its implementation, is able to achieve the specified technical result.

Therefore, the claimed utility model meets the requirement of "industrial applicability" under applicable law.

Literature

1. RF patent for the invention No. 2559821 (RU 2559821 C1). IPC G11B 20/24 (2006.01). A device for simulating a noise reduction system with frequency pre-emphasis [Text] / Tikhonova LS, Rastriga SK; Applicant and patent holder St. Petersburg State University of Cinema and Television. - No. 2014141188 dated October 13, 2014. Publ. 08/10/2015, bull. Number 22.

2. Veselova N.I., Tikhonova L.S. The use of metasystems in modeling REU // Science, Education, Society: Problems and Development Prospects: Sat. scientific tr according to the materials of the Intern. scientific-practical conf. February 28, 2014 Part 8. Tambov: Publishing House of TROO "Business Science Society", 2014 - 163 p., Pp. 23-25.

Claims (1)

A noise suppressor model containing two processing and broadcasting channels that are identical to each other, a common source of interference for the channels, and a multiplexer controlled by the control signal source, each channel including a pre-distorting circuit connected in series, a broadcasting path and a recovery circuit, the predistorting circuit includes series-connected adjustable first amplifier and high-pass filter, connected by the output of the high-pass filter to one of the inputs of the first adder, to another input in which the input of the first amplifier is connected, which is both the input of the predistortion circuit and the input of the channel, the output of the predistortion circuit is the output of the first adder, the broadcast path includes the second and third adders, one of the inputs of the second adder is connected to the output of the first adder, to the other input of the second adder the noise source is connected, the output of the second adder is connected to the input of the recovery circuit, the input of the predistortion circuit and the noise source are connected to different inputs of the third adder, in the output of the third adder is the first channel output connected to one of the four signal inputs of the multiplexer, the recovery circuit includes an adjustable second amplifier and a low-pass filter, the inputs of which are connected to the output of the second adder, and the outputs are with different inputs of the fourth adder, the output of which forms the output of the recovery circuit, which is simultaneously the second output of the channel connected to another signal input of the multiplexer, i.e. each of the two outputs of both channels is connected to a separate signal input of the multiplexer, the switching of which is controlled by a control signal source connected to the control input of the multiplexer, two outputs of the multiplexer form two outputs of the entire device, and the inputs of the processing and broadcasting channels form two inputs of the whole device, characterized in that four signal inputs are introduced into the multiplexer, two for each channel, through which the channel outputs are connected to the first inputs of the four multipliers, from the first about up to the fourth, respectively, control signals are supplied to the second inputs of these multipliers, moreover, if the control signal from the control input of the multiplexer is fed directly to the second inputs of the first and third multipliers, then the control signal whose polarity is changed is applied to the second inputs of the second and fourth multipliers, why the control signal from the control input of the multiplexer is fed to the inverter, from the output of which - to the first input of the fifth adder, to the second input of which the signal from a signal of a single level, the output of the fifth adder is connected to the second inputs of the second and fourth multipliers, the signals from the outputs of the first and second multipliers are fed to different inputs of the sixth adder, and from the outputs of the third and fourth multipliers to different inputs of the seventh adder, the output of the sixth adder forms the first output of the multiplexer and the entire device, and the output of the seventh adder - the second output of the multiplexer and the entire device.

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