CZ309327B6 - Audio dynamic range compressor - Google Patents

Abstract

The solution is used to compress the dynamic range of an audio signal in audio technology. An input audio signal with a wide intensity range is compressed to a prescribed intensity range when entering an audio dynamic range compressor. Excessively high audio signal intensity values at the input are reduced, while low audio signal intensity values are passed through the dynamic range compressor of the audio signal without limiting. The compressor of the dynamic range of the audio signal is made up of a temperature-variable resistor, preferably a filament.

Description

Audio dynamic range compressor

Field of technology

The invention relates to a compressor, which is generally used for sound signal processing, especially speech, the task of which is to reduce the dynamic range of the audio signal.

Current state of the art

Compression of the dynamic range of an audio signal is used in sound recording, sound processing in recording studios, during live performance, during radio broadcasting and in various telecommunications equipment (radio stations, some telephone devices, etc.). Compression is used both for the overall audio signal and separately for the audio signals of individual sources (musical instruments, singing, speech and others). The task of dynamic range compressors of an audio signal is to reduce, i.e. weaken high-level sounds, and to amplify low-level sounds, i.e. to dampen noisy and amplify quiet passages of the audio signal.

An audio dynamic range compressor works by adjusting the audio signal of the processed sound by changing the output volume of the processed sound depending on the input volume of the processed sound. If the input volume of the processed sound exceeds the set threshold, the level of the output processed sound in the audio signal is reduced in the set ratio, the so-called "ratio". Most well-known professional compressors of the dynamic range of the audio signal also allow you to set the speed or reaction time for exceeding the so-called "attack" threshold and speed, or the time to release the compression of the audio signal below the so-called "release" threshold after the volume of the processed sound has decreased again.

Compressors of the dynamic range of the audio signal can simultaneously process the entire frequency range of the audio signal, or part of it, or they can process it separately divided into several frequency bands, as is the case with the device according to document EP 2940863 Bl. Such compressors of the dynamic range of the audio signal are called multiband.

Currently, audio dynamic range compressors are commonly addressed, either with electronic analog elements or with digital signal processing (DSP).

They are typically implemented as a combination of two electronic circuits, in which one of the electronic circuits (controller) reacts to the values of the audio signal and the second electronic circuit (controlled) according to the response of the first electronic element affects the audio signal at the output of the compressor of the dynamic range of the audio signal.

The most common representatives of these pairs of electronic circuits are, as a control, a voltage or current converter of an audio signal to RMS ("Root Mean Square" - the effective value of the signal) and as a controlled voltage-controlled amplifier. Or a pair consisting of a sensor with a controlled light source and a photoresistor arranged to it, which, depending on the intensity of the light, changes the level of the audio signal by changing the electrical resistance.

Standard compressors of the dynamic range of an audio signal typically use a so-called VCA (voltage controlled amplifier) as an action element, a voltage-controlled amplifier, see Fig. 1. The control voltage for the amplifier is typically obtained from an RMS converter, which converts the effective value of the audio signal voltage to a direct current voltage. This voltage is then adjusted to achieve the required dynamic properties (threshold, ratio, attack, decay) of the dynamic range compressor of the audio signal.

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The disadvantages are that obtaining the correct (natural) RMS value of an audio signal is problematic due to the relatively high ratio of peak to effective value of the audio signal, the so-called "crest factor". Incorrectly specified control voltage for the VCA causes erroneous, unnatural and audible behavior of the audio compressor. Moreover, RMS converters are relatively expensive and complicated electronic devices.

The task of the invention is to create a compressor of the dynamic range of an audio signal, which would consist of a single electronic element that could simultaneously convert the audio signal to its effective value (RMS) and at the same time adjust the audio signal level by changing the effective value (RMS).

The essence of the invention

The set task is solved by the compressor of the dynamic range of the audio signal created according to the invention described below.

The essence of the invention is that the compressor of the dynamic range of the audio signal consists of at least one temperature-variable resistor.

Experimental tests have shown that a temperature-variable resistor is very well suited for the needs of compression of the dynamic range of an audio signal, in which the instantaneous temperature, and thus the electrical resistance, changes as the electric voltage increases. Following the change in the electrical resistance of the temperature variable resistor caused by the incoming audio signal, the audio signal is compressed.

It is possible to set the compression ratio (ratio) by choosing the appropriate material for the temperature-variable resistor. The mechanical design of the temperature-variable resistor determines the reaction delay (attack) and also the return value (release) of the compressor of the dynamic range of the audio signal.

It is very advantageous that there is no need to use two electronic circuits (controlling and controlled), as was the case until now. Only one component is needed, a thermally variable resistor, which serves as an RMS converter (controlling) and as an element for adjusting the level of the audio signal (controlled).

From the point of view of the design of the compressor of the dynamic range of the audio signal, it is advantageous if the temperature-variable resistor consists of an electrically conductive fiber. From the point of view of construction, the fiber is a very simple technical means. The operational dynamic properties of the compressor are determined by the length, material and cross-section of the fiber.

The most suitable material for an electrically conductive fiber has turned out to be one that is at least partially made of tungsten. Tungsten in the filament is a material resistant to dusting, which is caused by frequent annealing of the filament.

In the course of the development of the invention, it became clear that it is possible to make a compressor of the dynamic range of an audio signal from at least one light bulb designed for mounting in a printed circuit board. This is very convenient as these bulbs are a common commodity and are available at a fraction of the cost of existing audio dynamic range compressors.

Among the advantages of the invention is the revolutionary simplification of the hitherto complex structure of the dynamic range compressor of audio signals. The invention shows excellent properties (low distortion, accurate RMS value, natural sound presentation), while it is formed essentially by an ordinary temperature-variable resistor (in the preferred embodiment of the invention, a filament), which can be purchased at a lower price than current audio compressor components. It is advantageous that the instantaneous temperature (thus the instantaneous electrical resistance) is proportional to the size of the input audio signal and the size of the output audio signal is directly affected by the electrical resistance. Basically temperature

-2CZ 309327 B6 variable resistor functions simultaneously as a detector with accurate RMS conversion and as a control element of the compressor of the dynamic range of the audio signal.

This RMS conversion is very accurate and natural, since the rms value is equal to the value of the direct voltage that would give the same average power when applied to a resistive load. This power directly determines the change in the thermally variable resistor (thermally dependent element). The dynamic properties of the dynamic range compressor of the audio signal (attack and decay) are fixed by the material of the thermally variable resistor (electrically conductive fiber).

Clarification of drawings

Said invention will be further explained in the following drawings, where:

Fig. 1 shows a block diagram of an audio signal dynamic range compressor according to the prior art, Fig. 2 shows a block diagram of an audio signal dynamic range compressor according to the invention, Fig. 3 shows in a general graph the difference between an existing audio signal dynamic range compressor and an audio signal dynamic range compressor according to this invention , Fig. 4 shows a graph of audio signal compression in an audio dynamic range compressor according to the present invention, and Fig. 5 shows the waveform of the actual audio signal at the input and output of the audio dynamic range compressor according to the present invention.

An example of the implementation of the invention

It is understood that the specific embodiments of the invention described and illustrated below are presented for illustration purposes and not as a limitation of the invention to the examples shown. Those skilled in the art will find or be able to ascertain, using routine experimentation, a greater or lesser number of equivalents to the specific embodiments of the invention described herein.

Fig. 2 shows a diagram of an audio signal dynamic range compressor, from which it can be seen that the audio signal dynamic range compressor consists of only a single structural and functional member (temperature-variable resistor), which is a great simplification compared to the design of the existing audio dynamic range compressor from Fig. 1 .

Fig. 3 shows a comparison of the compression of an identical audio signal by the compressor of Fig. 1 and Fig. 2. As Fig. 3 shows, the course of the audio signal in the dynamic range audio signal compressor according to the invention is smooth, while the existing dynamic range compressor of the audio signal shows a point on the curve break.

The THD (Total Harmonic Distortion) of both a typical existing type of audio dynamic range compressor and the audio dynamic range compressor of the present invention was compared. The results were as follows:

Audio compressor using VCA: THD @ 1 V, 1 kHz, 0 dB = 0.1%

Compressor according to this invention: THD @ 1 V, 1 kHz, 0 dB = 0.0005%

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It follows that the qualitative parameters of the temperature variable resistor exceed the qualitative parameters of additional electronic circuits.

Fig. 4 shows the change of the audio signal in the dynamic range compressor of the audio signal according to the invention. If the signal were not limited, its characteristic would be linear and lead to maximum values. This is the waveform of the input signal. While the audio signal coming out of the dynamic range compressor of the audio signal according to the invention shows attenuation, and that is smooth without a break point.

Fig. 5 shows the course of the audio signal over time. Both input and output signals from the audio dynamic range compressor of the present invention are visible. The size of the attack and decay time at 20 dB attenuation can be seen from the output characteristic.

As part of the experiments, filaments from light bulbs were used for mounting in printed circuit boards. In particular, whole lamps were used, with the designation of type CW 23, whose parameters were 5 V, 0.02 A, 03.18 mm, and lamps with the designation of type 6022, whose parameters were 5 V, 0.021 A, TI.

Tests have shown for which operating parameters a temperature-variable resistor is suitable for use in a dynamic range compressor of an audio signal:

signal attenuation range 0 to 60 dB, attack time in the range from 5 ps to 600 s, release time in the range from 5 ps to 600 s.

Audio signal compression falling within the above parameter ranges is typically used in the following example applications.

Compressors with short times are used to limit the dynamic range of an audio signal in sound recording, sound processing in recording studios, in live performance, radio broadcasting, in telecommunication technology (radio stations, telephony) and the like. Typical values of attack and release times for this use are within the preferred ranges for attack time of 5 ps to 100 ms and for release time from 10 ms to 1 s.

Compressors with long times are used to protect audio systems, or to comply with hygienic acoustic limits, acoustic noise levels and the like. Typical values of attack and release times for this use are within the preferred ranges for attack time from 1 s to 10 s and for release time from 10 s to 100 s.

The extent of signal attenuation and the magnitude of attack and release times can vary greatly depending on the specific audio signal processing requirements for a given task/purpose. In addition, it is possible to chain compressors according to the present invention. However, in the opinion of the originator, who is an expert in the given issue with many years of experience, the above operating parameters of the compressor according to this invention should be met in the vast majority of cases of specific use of compressors according to the invention with a temperature variable resistor.

Compressors with selected audio parameters were subsequently tested by selected professional users as part of closed testing to the public, who evaluated it as very functional, high-quality and easy to use and set up.

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Industrial applicability

The compressor of the dynamic range of the audio signal according to the invention finds application in the field of audio engineering.

Claims (4)

1. A compressor of the dynamic range of an audio signal for adjusting electrically transmitted sound, characterized by the fact that it consists of at least one temperature-variable resistor. 5 2. A compressor according to claim 1, characterized in that the temperature-variable resistor is formed by an electrically conductive fiber. 3. A compressor according to claim 2, characterized in that the electrically conductive fiber is at least partially made of tungsten. 4. A compressor according to one of claims 1 to 3, characterized in that the temperature-variable resistor ίο is formed by at least one light bulb intended for mounting in a printed circuit board.