KR101581748B1 - Smart-dynamic control apparatus using digital signal processor - Google Patents

Abstract

The present invention is a smart dynamic control apparatus using a digital signal processor (DSP), which comprises a division unit for dividing an inputted audio signal by frequency; a determination unit for determining whether the size of the audio signal exceeds a threshold value set by divided frequency; a measurement unit for measuring a parameter value necessary for compression, based on the size of the audio signal exceeding the set threshold value and the frequency; and a compression unit for compressing only on the audio signal exceeding the set threshold value based on the measured parameter value.

Description

TECHNICAL FIELD [0001] The present invention relates to a smart dynamical control device using a DSP,

The present invention relates to a technique for separating an audio signal by frequency, determining whether the size of an audio signal exceeds a threshold value for each frequency, and compressing only an audio signal exceeding a threshold value.

There is a variety of methods and apparatuses for high-efficiency encoding of audio or voice signals. For example, time-domain audio signals or the like may be blocked for each unit time, and time-axis signals for each block may be converted into signals on the frequency axis Spectrum conversion), and a block-frequency-band dividing method for coding a signal (spectrum component) in the obtained frequency domain. In addition, there is a band division coding (SBC) scheme, which is a non-blocking frequency band division scheme in which an audio signal in the time domain is divided into a plurality of frequency bands without blocking each unit time as described above have. Also, a method and apparatus for high-efficiency encoding that combines the above-described band division encoding and transcoding are considered. In this case, for example, after a time-domain signal is frequency-band-divided by the band-division coding method, a signal for each frequency band is spectrally transformed into a frequency-domain signal (spectrum component) by the transcoding system, To code the spectral components.

The prior art relating to the present invention is disclosed in Korean Patent No. 10-0402189 (Mar. 19, 2004).

The present invention separates an audio signal by frequency, determines whether the size of an audio signal exceeds a threshold value for each frequency, calculates a parameter to be used for compression based on the size and frequency of an audio signal exceeding a threshold value, (DSP) that enables an optimized audio signal compression by changing the state of an audio signal by using the audio signal.

In addition, the present invention is to provide a smart dynamic control device using a DSP (DSP) capable of minimizing distortion of an original sound by compressing only audio signals exceeding a threshold value, rather than compressing all audio signals .

In addition, the present invention does not compress all audio signals but only compresses audio signals exceeding a threshold value, so that the original sound does not artificially decrease due to compression, so that the SN rate is not significantly lowered even after compression. And to provide a smart dynamic control device using a digital signal processor (DSP).

Other objects and advantages of the present invention can be understood by the following description, and will be more clearly understood by the embodiments of the present invention. It will also be readily apparent that the objects and advantages of the invention may be realized and attained by means of the instrumentalities and combinations particularly pointed out in the appended claims.

According to an aspect of the present invention, there is provided a smart dynamical control apparatus using a DSP, comprising: a demultiplexer for demultiplexing an input audio signal on a frequency basis; A determination unit for determining whether a threshold value is exceeded; an operation unit for calculating a parameter value necessary for compression based on the size and frequency of the audio signal exceeding the set threshold value; Of the compressed audio signal.

The operation unit may calculate the difference between the size of the audio signal exceeding the set threshold value and the threshold value, and may calculate the size and the compression ratio of the bandwidth to be used when compressing the audio signal based on the calculated difference value.

The operation unit can calculate the size of the bandwidth corresponding to the difference value based on the graph value set so that the size of the bandwidth becomes smaller as the difference value increases.

The operation unit can calculate the magnitude of the compression ratio corresponding to the difference value based on the graph value set so that the compression ratio increases as the difference value increases.

The operation unit can calculate the attack time and the release time based on the frequency of the audio signal exceeding the set threshold value.

The arithmetic unit can calculate the attack time and the release time corresponding to the frequency of the audio signal exceeding the set threshold value, based on the graph value set so that the attack time and the release time become smaller as the frequency of the audio signal exceeding the set threshold value increases. have.

According to an embodiment of the present invention having the above-described structure, it is possible to separate audio signals by frequency, determine whether the size of the audio signal exceeds a threshold value for each frequency, The parameter to be used for compression is calculated and used for compression based on the state of the audio signal, so that the optimized audio signal compression can be performed by changing the parameter.

In addition, it is possible to minimize the distortion of the original sound by compressing only the audio signal exceeding the threshold value, instead of compressing all the audio signals.

In addition, not compressing all the audio signals but compressing only the audio signals exceeding the threshold value, the original sound is not artificially reduced due to compression, so that the SN rate may not be remarkably lowered even after compression.

FIG. 1 is a block diagram illustrating a smart dynamic control apparatus using a DSP, which is an embodiment of the present invention.
2 is a block diagram illustrating an operation unit according to an embodiment of the present invention.
FIGS. 3 to 7 are diagrams for explaining a method of driving a smart dynamic control apparatus using a DSP, which is an embodiment of the present invention.
FIG. 8 is a diagram showing a compression result according to a smart dynamic control apparatus using a DSP, which is an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments of the present invention can be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described below. The embodiments are provided to explain the present invention to a person having ordinary skill in the art to which the present invention belongs.

FIG. 1 is a block diagram illustrating a smart dynamic control apparatus using a DSP, which is an embodiment of the present invention. FIG. 2 is a block diagram illustrating an operation unit according to an embodiment of the present invention.

1 and 2, a smart dynamic control apparatus 100 using a DSP includes a separator 110, a determination unit 120, an operation unit 130, and a compression unit 140.

The separator 110 may separate the input audio signal by frequency. For example, the separator 110 may frequency-convert an audio signal and then separate the audio signal by frequency.

The determination unit 120 may determine whether the size of the audio signal exceeds a preset threshold value for each of the separated frequencies.

The operation unit 130 can calculate a parameter value required for compression based on the size and the frequency of the audio signal exceeding the set threshold value. For example, the parameter value may include a size of a bandwidth, a compression ratio, an attack time, a release time, and the like. The size of the bandwidth means the bandwidth to be used for the portion to be compressed. The compression ratio means the degree of compression. For example, if the compression ratio is 2: 1, the signal that has been increased to 1, 4, 8, and 16 is compressed to 1, 2, 4, and 8, and the width of the change is reduced by half. The attack time means a time at which the input audio signal is compressed. The release time is the time it takes for the compressed signal to return to its previous normal state. If the release time is too short, the dynamic range of the music will change drastically and distract, while the average level of the audio signal will increase. On the other hand, if the release time is too long, the rhythm of the music decreases and the tone becomes very dark. Therefore, it is very important to set the optimal release time.

The calculating unit 130 may calculate the difference between the magnitude of the audio signal exceeding the set threshold value and the threshold value, and may calculate the size and compression ratio of the bandwidth to be used when compressing the audio signal based on the calculated difference value.

For example, the operation unit 130 may calculate the size of the bandwidth corresponding to the difference value based on the graph value set so that the size of the bandwidth becomes smaller as the difference value increases.

For example, the operation unit 130 can calculate the magnitude of the compression ratio corresponding to the difference value based on the graph value set so that the compression ratio increases as the difference value increases.

The operation unit 130 may calculate the attack time and the release time when compressing the audio signal based on the frequency value of the audio signal exceeding the set threshold value.

For example, the operation unit 130 may calculate an attack time corresponding to the frequency of the audio signal exceeding the set threshold value, based on the graph value set so that the attack time and the release time become smaller as the frequency of the audio signal exceeding the set threshold value increases. And the release time.

In this way, the operation unit 130 can calculate the parameter value differently according to the difference value or the frequency of the audio signal. A detailed description thereof will be made with reference to FIG. 2 to FIG.

The compression unit 140 can compress only the audio signal exceeding the set threshold value based on the calculated parameter value.

A smart dynamical control apparatus using a DSP (DSP) according to the present invention separates audio signals according to frequencies, determines whether the size of an audio signal exceeds a threshold value for each frequency, and determines the size and frequency of an audio signal exceeding a threshold value The parameter to be used for compression is calculated and used for compression, so that it is possible to change the parameter according to the state of the audio signal without fixing the parameter, thereby enabling optimized compression.

In addition, the smart dynamic control apparatus using the DSP according to the present invention can compress not only all audio signals but also audio signals exceeding a threshold value, thereby minimizing the distortion of the original sound.

Further, the smart dynamic control apparatus using DSP according to the present invention does not compress all audio signals, but performs compression only on audio signals exceeding a threshold value, so that a phenomenon that the original sound is artificially reduced by compression So that the SN rate can not be significantly lowered even after compression.

FIGS. 3 to 7 are diagrams for explaining a method of driving a smart dynamic control apparatus using a DSP, which is an embodiment of the present invention.

Referring to FIGS. 1 and 3, a smart dynamic control apparatus 100 using a DSP can separate an input audio signal by frequency.

The smart dynamic control apparatus 100 using the DSP can determine whether the size of the audio signal exceeds a preset threshold value for each of the separated frequencies.

As shown in FIG. 3, the smart dynamic control apparatus 100 using a DSP can determine a portion of the audio signal whose size exceeds a predetermined threshold (a portion shown in red).

The smart dynamic control apparatus 100 using the DSP can calculate the difference value between the magnitude and the threshold of the audio signal exceeding the set threshold value. For example, the smart dynamic control apparatus 100 using the DSP can calculate the difference (3dB) between the magnitude and the threshold value of the audio signal exceeding the threshold value set in the 750 Hz band of the audio signal. In addition, the smart dynamic control apparatus 100 using the DSP can calculate the difference (2.7 dB) between the magnitude and the threshold of the audio signal exceeding the threshold value set in the 1 kHz band of the audio signal. In addition, the smart dynamic control apparatus 100 using the DSP can calculate the difference value (4 dB) between the magnitude and the threshold value of the audio signal exceeding the threshold value set in the 5 kHz band of the audio signal. In addition, the smart dynamic control apparatus 100 using the DSP can calculate the difference (2dB) between the magnitude and the threshold of the audio signal exceeding the threshold value set in the 10 kHz band of the audio signal.

Referring to FIGS. 1 and 4, a smart dynamic control apparatus 100 using a DSP can calculate a size of a bandwidth to be used when an audio signal is compressed based on a calculated difference value.
The user, producer, and the like can preset a value that matches the difference between the size and the threshold of the audio signal exceeding the preset threshold value and the bandwidth. The value set by matching the difference between the size of the audio signal exceeding the set threshold value and the bandwidth is set so that the size of the bandwidth becomes smaller as the difference between the size of the audio signal exceeding the set threshold value and the threshold value becomes larger .
The graph of FIG. 4 shows two-dimensionally connected values of the values set by matching the difference between the size and the threshold of the audio signal exceeding the set threshold and the bandwidth. The horizontal axis of the graph means the bandwidth, and the vertical axis of the graph means the difference value. Here, the difference value means the difference between the size of the audio signal exceeding the set threshold value and the threshold value. For example, when the difference value and the bandwidth are matched, the horizontal axis bandwidth is 0.6 Octave, 0.5 Octave, 0.4 Octave, and 0.33 (1) as the vertical axis difference increases to 1 dB, 2 dB, / 3) Octave and so on.
For example, the smart dynamical control apparatus 100 using the DSS (DSP) calculates a value ('a value obtained by matching a difference between a magnitude and a threshold of an audio signal exceeding a set threshold value and a bandwidth , The size of the bandwidth corresponding to the difference value can be calculated. Specifically, when the difference value is 4 dB, the smart dynamic control apparatus 100 using the DSP computes a difference value corresponding to 4 dB, which is a difference value, by using a value ('set graph') set by matching the difference value and the bandwidth You can calculate the 1/3 Octave value as the bandwidth size.
Referring to FIGS. 1 and 5, a smart dynamic control apparatus 100 using a DSP can calculate a magnitude of a compression ratio to be used when an audio signal is compressed based on a calculated difference value.
The user, the producer, and the like can preset a value obtained by matching the compression ratio with the difference value between the size and the threshold value of the audio signal exceeding the set threshold value. The value set by matching the compression ratio with the difference value between the size and the threshold value of the audio signal exceeding the set threshold value is set so that the compression ratio becomes larger as the difference value between the size and the threshold value of the audio signal exceeding the set threshold value becomes larger Can be set.
The graph of FIG. 5 shows two-dimensionally connected values of the values set by matching the compression ratio and the difference value between the magnitude and the threshold of the audio signal exceeding the set threshold value. The horizontal axis of the graph means the compression ratio, and the vertical axis of the graph means the difference value. Here, the difference value means the difference between the size of the audio signal exceeding the set threshold value and the threshold value. For example, the values set by matching the difference values and the compression ratios are set so that the compression ratio in the horizontal axis is 2: 1, 3: 1, 4: 1, 2, 1, 5: 1, and so on.
For example, the smart dynamic control apparatus 100 using a DSP (DSP) calculates a value ('a value obtained by matching a compression ratio with a difference value between a magnitude and a threshold of an audio signal exceeding a set threshold value The ratio is set to be large '), the size of the compression ratio corresponding to the difference value can be calculated. Specifically, when the difference value is 4 dB, the smart dynamic control apparatus 100 using a DSP (DSP) corresponds to a difference value of 4 dB using a value ('set graph') set by matching a difference value and a compression ratio 5: 1 can be calculated as the magnitude of the compression ratio.

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Referring to FIGS. 1 and 6, a smart dynamic control apparatus 100 using a DSP (DSP) calculates an attack time when compressing an audio signal based on a frequency value of an audio signal exceeding a set threshold value .
The user, the producer, and the like can preset a value that matches the attack frequency with the frequency of the audio signal exceeding the set threshold value. The value set by matching the frequency of the audio signal exceeding the set threshold value with the attack time can be set so that the attack time becomes smaller as the frequency of the audio signal exceeding the set threshold value becomes larger.
In the graph of FIG. 6, values set by matching the frequency of the audio signal exceeding the set threshold value with the attack time are two-dimensionally connected and displayed. The abscissa of the graph means the frequency of the audio signal exceeding the set threshold value, and the vertical axis of the graph means the attack time. For example, the values set by matching the frequency of the audio signal exceeding the set threshold value with the attack time, as the horizontal axis frequencies increase to 5Khz, 6Khz, 7Khz, 8Khz, etc., the attack times in the vertical axis are 0.1ms and 0.08ms 0.06 ms, 0.04 ms, or the like.
For example, the smart dynamical control apparatus 100 using a DSP (DSP) may set the values set by matching the frequency of the audio signal exceeding the set threshold value with the attack time ('set to decrease the attack time as the parking number increases' , It is possible to calculate the attack time corresponding to the frequency. Specifically, when the frequency of the audio signal exceeding the set threshold value is 5 kHz, the smart dynamic control apparatus 100 using the DSP (DSP) sets a value ('set graph'), which is set by matching the frequency of the audio signal with the attack time, A value of 0.1 ms corresponding to the frequency of the audio signal of 5 kHz can be calculated as the attack time.

Referring to FIGS. 1 and 7, a smart dynamic control apparatus 100 using a DSP (DSP) calculates a release time when compressing an audio signal based on a frequency value of an audio signal exceeding a set threshold value .
The user, the producer, and the like can preset a value matching the release time with the frequency of the audio signal exceeding the set threshold value. The value set by matching the frequency of the audio signal exceeding the set threshold value with the release time can be set so that the size of the release time decreases as the frequency of the audio signal exceeding the set threshold value becomes larger.
The graph of FIG. 7 shows the values set by matching the frequency of the audio signal exceeding the set threshold value with the release time in a two-dimensionally connected manner. The abscissa of the graph means the frequency of the audio signal exceeding the set threshold value, and the vertical axis of the graph means the release time. For example, the values set by matching the frequency of the audio signal exceeding the set threshold value with the release time, as the horizontal axis frequency increases to 5Khz, 6Khz, 7Khz, 8Khz, etc., the attack times in the vertical axis are 0.5ms and 0.58ms , 0.56 ms, 0.54 ms, or the like.
For example, the smart dynamical control apparatus 100 using a DSP (DSP) may set values that match the frequency of an audio signal exceeding a set threshold value with a release time ('set to decrease the attack time as the parking number increases' , It is possible to calculate the release time corresponding to the frequency. Specifically, when the frequency of the audio signal exceeding the set threshold value is 5 kHz, the smart dynamic control apparatus 100 using the DSP (DSP) sets a value ('set graph') matching the frequency of the audio signal with the release time, A 0.5 ms value corresponding to the frequency of 5 kHz, which is the frequency of the audio signal, can be calculated as the release time.

As described above, the smart dynamic control apparatus 100 using the DSP according to the present invention variably calculates a parameter to be used in compression based on the magnitude and frequency of an audio signal exceeding a threshold value, So that the optimized audio signal compression can be performed.

FIG. 8 is a diagram showing a compression result according to a smart dynamic control apparatus using a DSP, which is an embodiment of the present invention.

Referring to FIG. 8, a smart dynamic control apparatus using a DSP (DSP) according to the present invention compresses only a portion of an audio signal exceeding a threshold value. On the other hand, a smart dynamical control device using a general DSP (DSP) compresses all audio signals as well as a part of the audio signal exceeding a threshold value.

Therefore, when an audio signal is compressed by a smart dynamic control device using a general DSP, not only the size of the audio signal is artificially reduced, but also the SN rate is significantly lowered.

On the other hand, since the smart dynamic control device using the DSP according to the present invention compresses only the audio signal portion exceeding the threshold value, since the audio signal portion not exceeding the threshold value is not compressed, distortion of the original sound can be minimized There is no artificial reduction in the size of the original sound due to compression, and the SN rate is not significantly lowered even after compression.

The embodiments described may be constructed by selectively combining all or a part of each embodiment so that various modifications can be made.

It should also be noted that the embodiments are for explanation purposes only, and not for the purpose of limitation. In addition, it will be understood by those of ordinary skill in the art that various embodiments are possible within the scope of the technical idea of the present invention.

100: Smart dynamics control device using DSP
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Claims (6)

A separator for separating input audio signals by frequency;
A determination unit for determining whether the size of the audio signal exceeds a threshold set for each of the separated frequencies;
A parameter value required for compression is calculated on the basis of the magnitude and frequency of the audio signal exceeding the set threshold value and the attack time and the release time are reduced as the frequency of the audio signal exceeding the set threshold value is increased, Calculating an attack time and a release time corresponding to a frequency of an audio signal exceeding the set threshold value based on a value set by matching an attack time and a release time with a frequency of an audio signal exceeding a predetermined value; And
And a compression unit that performs compression only on the audio signal exceeding the set threshold value based on the calculated parameter value.
The method according to claim 1,
The operation unit,
(DSP) for calculating a size and a compression ratio of a bandwidth to be used in compressing an audio signal based on the calculated difference value, and calculating a difference between the magnitude of the audio signal exceeding the set threshold value and the threshold value, Smart dynamic control device.
3. The method of claim 2,
The operation unit,
A value obtained by matching the difference between the size and the threshold of the audio signal exceeding the set threshold value and the bandwidth so that the size of the bandwidth becomes smaller as the difference between the size of the audio signal exceeding the set threshold value and the threshold value becomes larger, And calculates a size of the bandwidth corresponding to the difference value based on the difference value.
3. The method of claim 2,
The operation unit,
A value obtained by matching a compression ratio with a difference value between the size and the threshold of the audio signal exceeding the set threshold value so that the compression ratio becomes larger as the difference between the size of the audio signal exceeding the set threshold value and the threshold value becomes larger, And calculates a magnitude of the compression ratio corresponding to the difference value based on the difference value. delete delete

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