KR101408983B1 - Digital audio mixing system - Google Patents

Abstract

Disclosed is a system for integrally mixing digital sound sources. The system for integrally mixing the digital sound sources comprises a coefficient storage unit, a first digital signal processing device, and a second digital signal processing device. The coefficient storage unit stores coefficient information which is used when sound sources for each mixer are mixed. The first digital signal processing device comprises a first mixer which mixes first sound sources by reflecting coefficient information for a first mixer, stored in the coefficient storage unit and a second mixer which mixes the first sound sources by reflecting coefficient information for a second mixer, stored in the coefficient storage unit. The second digital signal processing device comprises a third mixer which mixes second sound sources by reflecting coefficient information for a third mixer, stored in the coefficient storage unit and a fourth mixer which mixes the second sound sources by reflecting coefficient information for a fourth mixer, stored in the coefficient storage unit. The first digital signal processing device mixes and outputs the output sound sources of the first mixer and the output sound sources of the third mixer. The second digital signal processing device mixes and outputs the output sound sources of the second mixer and the output sound sources of the fourth mixer.

Description

[0001] Digital audio mixing system [0002]

A digital sound source mixing system, particularly a digital sound source mixing system using a digital signal processor with a limited number of pins, is disclosed.

Digital audio technology, which started with the development of compact discs (CD), is a digital signal processor (digital signal processor) for the efficient mixing operation, reliable system configuration, and high- So that it becomes necessary to use it. Compared to the analog audio of the past, the digital audio method using DSP can realize additional performance improvement through software reprogramming, robustness to noise obtained by digital signal processing technique and high performance and sophisticated filter implementation Do.

1 is a reference diagram for explaining a digital sound source mixing method using a conventional DSP.

When a plurality of sound source signals _{(x 1, x 2, ...} , x m) is input to the DSP (10), DSP (10 ) , after combining the input signal with the synthesized signal (y _1, y ₂ , ..., y _n ). This can be expressed by the following equation.

Thus, M × N sound source mixing processing becomes possible.

Korean Patent Laid-Open No. 10-2007-0103579 (October 24, 2007)

An integrated digital sound source mixing system capable of achieving 2M x 2N mixer outputs using two digital signal processors with limited number of pins for sound source input and output is disclosed.

According to an aspect of the present invention, there is provided an integrated digital sound source mixing system comprising: a coefficient storage unit for storing coefficient information used for mixing a sound source by a mixer; a first mixer for mixing first sound sources by reflecting coefficient information for a first mixer stored in the coefficient storage unit; And a second mixer for mixing the first sound sources by reflecting the second mixer coefficient information stored in the coefficient storage unit, and a second digital signal processor for reflecting the third mixer coefficient information stored in the coefficient storage unit, And a second digital signal processor including a third mixer for mixing the sound sources and a fourth mixer for mixing the second sound sources by reflecting the coefficient information for the fourth mixer stored in the coefficient storage unit, The second digital signal processor combines the output sound source of the second mixer and the output sound source of the fourth mixer, and outputs the sum of the output sound source of the first mixer and the output sound source of the third mixer. Output.

In one embodiment, the coefficient storage is a shared memory located outside the first digital signal processor and the second digital signal processor.

According to one aspect, the coefficient storage unit is included in the first digital signal processor, and is included in the first coefficient memory storing the first mixer coefficient information and the second mixer coefficient information, and the second digital signal processor, And a second coefficient memory storing coefficient information for the mixer and coefficient information for the fourth mixer.

The integrated digital sound source mixing system according to another aspect of the present invention includes a coefficient storage unit for storing coefficient information used for mixing sound sources for each mixer, a first mixer for mixing the first sound sources with the coefficient information for the first mixer stored in the coefficient storage unit, And a second mixer for mixing the second sound sources by reflecting the coefficient information for the second mixer stored in the coefficient storage unit, and a second digital signal processor for reflecting the third mixer coefficient information stored in the coefficient storage unit, A third mixer for mixing the first sound sources and a fourth mixer for mixing the second sound sources by reflecting the coefficient information for the fourth mixer stored in the coefficient storage unit, And the second digital signal processor combines the output sound source of the third mixer and the output sound source of the fourth mixer, and outputs the sum of the output sound source of the first mixer and the output sound source of the second mixer. And outputs it.

Integrated digital sound source mixing systems create the effect of achieving 2M x 2N mixer outputs using two digital signal processors with a finite number of pins that can handle only N outputs for, for example, M inputs.

1 is a reference diagram for explaining a digital sound source mixing method using a conventional DSP.
FIG. 2 is a reference diagram for explaining an integrated digital sound source mixing method according to an embodiment of the present invention.
FIG. 3 is a reference diagram for explaining an integrated digital sound source mixing method for achieving Equation (6) according to an embodiment of the present invention.
4 is a view for explaining an integrated digital sound source mixing method for achieving Equation 6 according to another embodiment of the present invention.
5 is a block diagram of an integrated digital sound source mixing system according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The foregoing and further aspects of the present invention will become more apparent from the following detailed description of preferred embodiments with reference to the accompanying drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a reference diagram for explaining an integrated digital sound source mixing method according to an embodiment of the present invention, and FIG. 3 is a diagram illustrating each item of Equation 6 according to an embodiment of the present invention. Digital sound sources are mixed by two digital signal processors. Where the two digital signal processors may have the same number of sound source input / output pins. One can play P (input) × Q (output) mixes of sound sources, and the other can mix M (input) × N (output) sound sources. Where P and M may be the same number, and Q and N may be the same number. P x Q can be expressed by Equation (2), and M x N can be expressed by Equation (3).

Here, a _ji may be a gain and a volume gain. Then, the signals synthesized by the P x Q processor 100 and the signals synthesized by the M x N processor 200 are synthesized as shown in FIG. 2, so that synthesized signals of 1 through Q + N are finally synthesized .

(P + M) x (Q + N) can be expressed by Equation (4), and Equation (4) can be expressed by Equation (5).

Equation (5) can be expressed as Equation (6).

Here, j = {1, ..., Q} in the first and fourth terms, and j = {Q + 1, ..., Q + N} in the second and third terms.

FIG. 3 is a reference diagram for explaining an integrated digital sound source mixing method for achieving Equation (6) according to an embodiment of the present invention. The first mixer 311, the second mixer 312, the third mixer 411, and the fourth mixer 412 both mix the sound source input signals. The first mixer 311 and the second mixer 312 are configured in the first digital signal processor 300 and the third mixer 411 and the fourth mixer 412 are configured in the second digital signal processor 300. [ (Not shown). The first mixer 311 may be configured to correspond to the first term of Equation (6) and may receive P first sound source input signals {x ₁ , ..., x _P } {y ₁ , ..., y _Q }. The second mixer 312 may be configured to correspond to the third term of Equation (6), and may be configured to receive P first sound source input signals {x ₁ , ..., x _P } {y _{Q +1} , ..., y _{Q + N} }. The third mixer 411 may be configured to correspond to the second term of Equation (6), and receives M second sound source input signals {x _{P +1} , ..., x _{P + M} } To generate mixed signals {y _{Q +1} , ..., y _{Q + N} }. The fourth mixer 412 may be configured to correspond to the fourth term of Equation (6), and receives M second sound source input signals {x _{P +1} , ..., x _{P + M} } To produce mixed signals {y ₁ , ..., y _Q }.

The first digital signal processor 300 may mix the mixed signals of the first mixer 311 and the mixed signals of the third mixer 411 and the second digital signal processor 400 may mix the mixed signals of the first mixer 311 and the third mixer 411, The mixed signals of the first mixer 412 and the mixed signals of the second mixer 312 may be mixed and output. Alternatively, the first digital signal processor 300 may mix the mixed signals of the second mixer 312 and the mixed signals of the fourth mixer 412, and the second digital signal processor 400 may mix the mixed signals of the second mixer 312 and the third mixer 412, The mixed signals of the first mixer 411 and the mixed signals of the first mixer 311 may be mixed and output. If only the two DSPs are used to mix sound sources input to each other, only the first mixer 311 and the fourth mixer 412 are configured. This means that the result is output in the first term and the second term in Equation 6, and the third term and the fourth term are not reflected in the result. In order to prevent this, the second mixer 312 and the third mixer 411 are additionally constituted so that the result of the third and fourth expressions of Equation (6) is reflected in the result. Accordingly, the input sound sources are mixed and output so as to satisfy the number of all possible mixes. As a result, when using a DSP having a capacity capable of processing only M × N, 2M × 2N mixer outputs can be implemented with two DSPs.

4 is a view for explaining an integrated digital sound source mixing method for achieving Equation 6 according to another embodiment of the present invention. The first mixer 311, the second mixer 312, the third mixer 411, and the fourth mixer 412 both mix the sound source input signals. The first mixer 311 and the second mixer 312 are configured in the first digital signal processor 300 and the third mixer 411 and the fourth mixer 412 are configured in the second digital signal processor 300. [ (Not shown). The first mixer 311 may be configured to correspond to the first term of Equation (6) and may receive P first sound source input signals {x ₁ , ..., x _P } {y ₁ , ..., y _Q }. The second mixer 312 may be configured to correspond to the second term of Equation (6), and may be configured to receive M second sound source input signals { _{xp +1} , ..., x _{P + M} } To generate mixed signals {y _{Q +1} , ..., y _{Q + N} }. The third mixer 411 may be configured to correspond to the third term of Equation (6), and may be configured to receive P first sound source input signals {x ₁ , ..., x _P } {y _{Q +1} , ..., y _{Q + N} }. The fourth mixer 412 may be configured to correspond to the fourth term of Equation (6), and receives M second sound source input signals {x _{P +1} , ..., x _{P + M} } To produce mixed signals {y ₁ , ..., y _Q }.

The first digital signal processor 300 may mix the mixed signals of the first mixer 311 and the mixed signals of the second mixer 312 and the second digital signal processor 400 may mix the mixed signals of the first mixer 311 and the second mixer 312, The mixed signals of the fourth mixer 411 and the mixed signals of the fourth mixer 412 may be mixed and output. If only the two DSPs are used to mix sound sources input into each of them, only the first mixer 311 and the second mixer 312 are configured. This means that the result is output in the first term and the second term in Equation 6, and the third term and the fourth term are not reflected in the result. In order to prevent this, the third mixer 411 and the fourth mixer 412 are additionally constructed so that the results of the third and fourth expressions of Equation 6 are reflected. Accordingly, the input sound sources are mixed and output so as to satisfy the number of all possible mixes. As a result, when using a DSP having a capacity capable of processing only M × N, 2M × 2N mixer outputs can be implemented with two DSPs.

5 is a block diagram of an integrated digital sound source mixing system according to an embodiment of the present invention. The digital sound source mixing system shown can be implemented in a public address system. As shown, the integrated digital sound source mixing system includes a first digital signal processor 300 and a second digital signal processor 400, and the first digital signal processor 300 and the second digital signal processor 400 0.0 > 310 < / RTI > DSP cores 310 and 410 perform the sound source mixing process described with reference to FIG. 3 or FIG. The integrated digital sound source mixing system includes a coefficient storage unit including a first coefficient memory 320 included in the first digital signal processor 300 and a second coefficient memory 320 included in the second digital signal processor 400. [ (420). The first coefficient memory 320, the first mixer coefficients (a _ij) information and the second mixer coefficients (a _ij), and the information is stored, the second coefficient memory 420, the third mixer coefficients (a _ij) for for Information and a coefficient (a _ij ) information for the fourth mixer are stored. Or the coefficient storage unit may be a memory separately configured from the first digital signal processor 300 and the second digital signal processor 400 and shared by the first digital signal processor 300 and the second digital signal processor 400 . In this shared memory, the first mixer coefficient a _ij information, the second mixer coefficient a _ij information, the third mixer coefficient a _ij information, and the fourth mixer coefficient a _ij information are all stored do.

Further, the integrated digital sound source mixing system may further include a main control unit 500. The main control unit 500 may perform a role of storing and managing coefficient information in the coefficient storage unit. In one embodiment, the main control unit 500 transfers the coefficient information to be stored in the first coefficient memory 320 to the first microprocessor 330 of the first digital signal processor 300 and the second coefficient memory 420 to the second microprocessor 430 of the second digital signal processor 400, the first microprocessor 330 stores the transmitted coefficient information in the first coefficient memory 320 And the second microprocessor 430 stores the transmitted coefficient information in the second coefficient memory 420. Further, the main control unit 500 can update and manage coefficient information according to an administrator command. And for an administrator command, the integrated digital sound source mixing system may further include a device interface 600. [ The device interface 600 is a configuration providing an interface with a device such as a PC, and can provide a wired or wireless interface. Therefore, the administrator can make an instruction to adjust the volume gain or the like by using a PC or the like, and the command data can be transferred to the main control unit 500 through the device interface 600. [ The main control unit 500 can update the coefficient information according to the volume gain control command of the manager.

The present invention has been described with reference to the preferred embodiments. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Therefore, the disclosed embodiments should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is defined by the appended claims rather than by the foregoing description, and all differences within the scope of equivalents thereof should be construed as being included in the present invention.

300: first digital signal processor 310: first DSP core
311: first mixer 312: second mixer
320: first coefficient memory 330: first microprocessor
400: first digital signal processor 410: second DSP core
411: third mixer 412: fourth mixer
420: second coefficient memory 430: first microprocessor
500: main control unit 600: equipment interface

Claims (6)

A coefficient storage unit for storing coefficient information used when a sound source is mixed according to a mixer;
A first mixer for mixing the first sound sources with the first mixer coefficient information stored in the coefficient storage unit and a second mixer for mixing the first sound sources by reflecting the coefficient information for the second mixer stored in the coefficient storage unit A first digital signal processor; And
A third mixer for mixing the second sound sources by reflecting coefficient information for the third mixer stored in the coefficient storage unit and a fourth mixer for mixing the second sound sources by reflecting the coefficient information for the fourth mixer stored in the coefficient storage unit A second digital signal processor,
The first digital signal processor outputs the sum of the output sound source of the first mixer and the output sound source of the third mixer while the second digital signal processor outputs the combined sound source of the second mixer and the output sound source of the fourth mixer, Mixed systems.
The method according to claim 1,
Wherein the coefficient storage unit is a common memory located outside the first digital signal processor and the second digital signal processor.
The apparatus of claim 1, wherein the coefficient storage unit comprises:
A first coefficient memory included in the first digital signal processor and storing first coefficient information for the mixer and coefficient information for the second mixer; And
A second coefficient memory that is included in the second digital signal processor and stores coefficient information for the third mixer and coefficient information for the fourth mixer;
An integrated digital sound source mixing system.
A coefficient storage unit for storing coefficient information used when a sound source is mixed according to a mixer;
A first mixer for mixing the first sound sources with the first mixer coefficient information stored in the coefficient storage unit and a second mixer for mixing the second sound sources by reflecting the coefficient information for the second mixer stored in the coefficient storage unit A first digital signal processor; And
A third mixer for mixing the first sound sources by reflecting coefficient information for the third mixer stored in the coefficient storage unit and a fourth mixer for mixing the second sound sources by reflecting the coefficient information for the fourth mixer stored in the coefficient storage unit A second digital signal processor,
The first digital signal processor outputs the sum of the output sound source of the first mixer and the output sound source of the second mixer, and the second digital signal processor outputs the sum of the output sound source of the third mixer and the output sound source of the fourth mixer, Mixed systems.
5. The method of claim 4,
Wherein the coefficient storage unit is a common memory located outside the first digital signal processor and the second digital signal processor.
5. The apparatus of claim 4, wherein the coefficient storage unit comprises:
A first coefficient memory included in the first digital signal processor and storing first coefficient information for the mixer and coefficient information for the second mixer; And
A second coefficient memory that is included in the second digital signal processor and stores coefficient information for the third mixer and coefficient information for the fourth mixer;
An integrated digital sound source mixing system.

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