JPH0423961B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a digital signal mixing device suitable for application to mixing audio signals.

A conventional digital signal mixing device that mixes digitized multi-channel audio signals at a desired mixing ratio to obtain a new digitized multi-channel audio signal is as shown in Figure 1. It is composed of Below, first, a conventional mixing device will be explained with reference to FIG. 1.

That is, a plurality of channels of input digital signals are supplied from each input terminal 1 to each DA converter 2 to obtain a plurality of channels of input analog signals. A plurality of other analog signals, such as microphone signals, are supplied from each input terminal 3 to each amplifier 4. Each output of each D-A converter 2 and each amplifier 4 is switched to each selector switch 5.
The signal is selected by switching and supplied to each analog tone control circuit 6. The output of each analog tone control circuit 6 is supplied to an analog signal mixing circuit 7. A part of the mixed output of the analog signal mixing circuit 7 is supplied to the analog reverberation adding device 11, the output thereof is supplied to the tone control circuit 6 via the on/off switch 5', and each output is supplied to the analog signal mixing circuit 7 again. supply A portion of the output analog signal of the mixing circuit 7 is supplied to each A-D converter 8 to obtain a plurality of output digital signals from each output terminal 9. Note that the output analog signal can be obtained as is at the output terminal 10.

However, such conventional digital signal mixing devices have the following drawbacks. That is, D-
Since it uses an A converter and an A-D converter,
Quantization noise is mixed into the output of the A-D converter. Since mixing is performed in the analog signal state, distortion occurs due to the non-linearity of the input/output characteristics of the analog signal mixing circuit.Also, since the analog signal mixing circuit is easily affected by external noise, the noise caused by this will also affect its output. be mixed into the

In view of this, the present invention proposes a digital signal mixing device that eliminates the above-mentioned drawbacks by performing mixing on digital signals as they are.

Embodiments of the present invention will be described in detail below with reference to FIG. 2 and FIGS. 4 and 8, which partially illustrate the invention in detail. In FIGS. 2 and 4, parts corresponding to those in FIG. 1 are designated by the same reference numerals and will be explained. First, FIG. 2 will be explained.

3a and 3b are input terminals for a plurality of input analog signals, the former being a microphone signal input terminal and the latter being an auxiliary input terminal. 4 is an amplifier for amplifying the microphone signal. Each input terminal 3a, 3b
Therefore, each input analog signal is switched by each changeover switch 15 and sent to each sample hold circuit and A.
- is supplied to the D converter 16. Each input digital signal from each input terminal 1 and the digital signal from each sample hold circuit and A-D converter 16 are switched by each changeover switch 17 and supplied to each digital tone control circuit 18, and the output thereof is Each input digital signal is supplied to a digital signal mixing operation circuit 19. Then, each output digital signal is outputted to each output terminal 9. In addition, as shown by a broken line in a part of the output terminal 9, the D-A converter 2
1 can be connected to obtain an output analog signal at the output terminal 10.

Further, a part of the output digital signal of the digital signal mixing operation circuit 19 is supplied to the digital reverberation adding device 22, and each output is sent to each on/off switch 17'.
The output signal is supplied to each tone control circuit 18 through the digital signal mixing circuit 19 .

This digital signal mixing calculation circuit 19 mixes the input digital signals of the S channel to obtain the output digital signal of the T channel.
As will be described in detail with reference to FIG. 4, a digital storage device 27 is provided for storing matrix elements of SXT as digital signals. Reference numeral 20 denotes a matrix element determination circuit that determines matrix elements of SXT according to a desired mixing ratio of input digital signals of the S channel and stores the determined matrix elements in the storage device 27. Furthermore, the digital signal mixing operation circuit 19 includes a matrix operation circuit 67 that performs matrix operation on the input digital signal of the S channel and the matrix elements sequentially read out from the digital storage device 27.

Note that the digital tone control circuit 18 is
By specifying values such as low cut, high cut, bass, treble, and presence (realism), it is possible to obtain various frequency-output level characteristics as shown in FIG. 3, for example.

Next, details of the digital signal mixing operation circuit 19 and the matrix element determination circuit 20 will be explained with reference to FIG. 49 is an analog signal mixing circuit provided in the matrix element determination circuit 20, and input terminal 49-I1
The input analog signal of the S channel is supplied to ~49-IS, and the output analog signal of the T channel with the desired mixing ratio is obtained at the output terminals 49-O1 to 49-OT.An example of a specific circuit will be described later. This is illustrated in FIG. In the present invention, this analog signal mixing circuit 49 is considered as a black box, and the relationship between the input analog signals VI ₁ to VI _S and the output analog signals VO ₁ to _VOT is expressed as a determinant as shown in the following equation, and the mixing circuit 49 is Characteristics of circuit 49 as matrix [A]
It is expressed as

VO ₁ VO ₂ 〓 VO _T = [A] VI ₁ VI ₂ 〓 VI _S ……(1) [A] = A _1,1 A _2,1 〓 A _T,1 A _1,2 A _2,2 〓 A _T,2 … … … A _1,S A _2,S 〓 A _T,S …(2) If there is an input offset or temperature drift, all of the input analog signals VI ₁ to VI _S should be ), the output analog voltage is VO ₁ ′~
As VO _T ′, equation (1) can be set as shown in the following equation.

VO ₁ −VO ₁ ′ VO ₂ −VO ₂ ′ 〓 VO _T −VO _T ′＝[A] VI ₁ VI ₂ 〓 VI _S ……(3) However, since it is simple here, formula (1) is adopted. I'll keep it.

Here, to know the elements of SXT of matrix [A],
It turns out that it is sufficient to sequentially set one of the input analog signals VI ₁ to VI _S to 1 (volt), set the others to O (volt), and measure the output analog voltages VO ₁ to _VOT . Then, the voltages (analog voltages) of each element of this matrix [A] are converted into digital signals, which are supplied to the digital storage device 27 and stored therein.

Now, the matrix element determining circuit 20 will be explained in detail. 48 is a drive circuit for the analog signal mixing circuit 49. This drive circuit 48 has its respective input terminals 48-I1 to 48-IS and output terminal 48.
Driving circuits as shown in the figure are provided between -O1 to -O48 and -OS, respectively. This drive circuit is, for example, a MOS
Type field effect transistors Q ₁ , Q ₂ , inverter 6
6, and the output terminal 4 is
The voltage of 1 volt from the power supply +B is outputted to 8-O1 to 48OS, or the ground potential, that is, O volt is obtained. That is, if the input signal is "1", transistor Q ₁ is on and transistor Q ₂ is off, and a voltage of 1 volt is output. If the input signal is "O", transistor Q ₁ is off and transistor Q ₂ is on. As a result, a voltage of O volts is output.

Reference numeral 47 denotes a scanning pulse generation circuit (decoder), which is driven by the clock signal supplied thereto and outputs "1" sequentially and cyclically to its output terminals 47-O1 to 47-OS. ing.
Note that the output terminal 47- of the scanning pulse generation circuit 47
The output obtained at any output terminal 47-OC other than OS and these is supplied to an input terminal 48-I1 and an output terminal 48-I (C+1) of a drive circuit 48, respectively.

50 is a 12-bit A-D converter, for example, to which the output of the analog signal mixing circuit 49 is supplied;
It consists of T A-D converters 50-1 to 50-T connected to respective output terminals of 9. A latch circuit 51 is supplied with the output of the AD converter 50, and is made up of T latch circuits 51-1 to 51-T corresponding to the AD converters 50-1 to 50-T. 52-1 to 52-T are latch circuits 51-1
Each output terminal of 51-T becomes an output terminal of the matrix element determining circuit 20 at the same time.

Next, the clock circuit 68 will be explained. The clock signal from this is partially utilized not only by the matrix element determination circuit 20 but also by the digital signal mixing operation circuit 19. 40 is a clock generation circuit, for example
2MHz square wave clock pulse (first clock pulse) with a duty of 50% as shown in Figure 5A.
occurs. This first clock pulse is supplied to a counter 41 of S-base (for example, S=40).
In the counter 41, as shown in FIG. 5B, 1, 2,
..., S, and every time S is counted, a second clock pulse (with a frequency of 50k) as shown in FIG.
Hz) is output. FIG. 5D shows this second clock pulse again with a reduced time axis. This second clock pulse is supplied to a counter 42 in U base (for example, U=50). At the counter 42,
As shown in FIG. 5, 1, 2, ..., U are counted, and every time U is counted, the third clock pulse (frequency is 1 kHz) as shown in FIG. is supplied to the counter 43. In the counter 43, as shown in FIG. 5H...C-1, C, C
+1, . . . are counted, and a fourth clock pulse (frequency: 25 Hz) is outputted, which is supplied to the scanning pulse generation circuit 47.

FIG. 5 I and J are respectively analog signal mixing circuits 4
9 input terminals 49-(C+1), 49-(C+2)
The waveform of the input voltage is shown. K in FIG. 5 is the output terminal 49-0 (C+1) of the analog signal mixing circuit 49.
shows the waveform of the output voltage of input terminal 49-I.
After a predetermined settling time after the input voltage supplied to (C+1) rises, it reaches a constant voltage. Figure 5 L
shows the output waveform of the AD converter 50-(C+1). In this case, the output of the counter 42 is
V is supplied to the counter 42 during counting from 1 to U.
(1<V<U), the decoder 44 obtains a start pulse as shown in FIG. . Further, the third clock pulse (FIG. 5G) from the counter 42 is supplied to the latch circuit 51, so that the contents of the A-D converter 50 (for example, 50-(C+1)) are changed at the timing of the third clock pulse. is the latch circuit 51
{Therefore, 51-(C+1)} is latched (as shown in FIG. 5M).

Thus, by sequentially supplying a voltage of 1 volt to the input terminals 49-I1 to 49IS of the analog signal mixing circuit 49, the A-D converted elements of the matrix [A] are output to the latch circuits 51-1 to 51-. It will be latched to T. The processing time for this one cycle is calculated after manual adjustment of the analog signal mixing circuit 49.
It is a short time of about 50 msec.

The contents of the latch circuit 51 are then supplied to the digital storage device 27 of the digital signal mixing operation circuit 19 and stored therein. Next, the digital signal mixing calculation circuit 19 will be explained. Digital storage device 27
are T shift registers 27-1 to 27-2 each having S stages.
7-T, each with input terminals 27-I1 to 27
-IT and output terminals 27-O1 to 27-OT. For example, a one-stage shift register has 12 bits. This digital storage device 27 is controlled by a first clock pulse from a clock generation circuit 40.

Then, the outputs of the latch circuits 51-1 to 51-T of the matrix element determination circuit 20 are sent to the digital storage device 2 through write logic circuits 53-1 to 53-T, respectively.
7 input terminals 27-I1 to 27-IT. Since the write logic circuits 53-1 to 53-T have the same configuration, the write logic circuit 53-1 will be explained as a representative.

In the subtracter 54, the output of the latch circuit 51-1 is converted to the shift register 27- of the digital storage device 27.
1 is subtracted, and the subtracted output is supplied to decoders 55 and 56. Decoder 55,5
6 is a circuit that outputs an output when the output of the subtracter 54 is +1 and -1, respectively. Decoders 55, 56
Each output is supplied to an AND circuit 59 via an OR circuit 57 and an inverter 58. Further, in the matrix element determining circuit 20, each clock pulse from the counters 41 and 43 is sent to an exclusive OR circuit 45.
and its output is supplied to the AND circuit 59 through the inverter 46. Then, the output of the latch circuit 51-1 and the output of the AND circuit 59 are supplied to an AND circuit 60. Further, the output of the output terminal 27-O1 of the digital storage device 27 and the output of the AND circuit 59 passed through the inverter 61 are supplied to the AND circuit 62. The outputs of the AND circuits 60 and 62 are then supplied to the input terminal 27-I1 of the shift register 27-1 of the digital storage device 27 through the OR circuit 63.

The write logic circuits 53-1, . . . , 53-T operate as follows. When the contents of the counters 41 and 43 match, "1" is obtained at the output side of the inverter 46, and the latch circuit 51-
1 to 51-T or the outputs of output terminals 27-O1 to 27-OT of the digital storage device 27 are supplied. Then, each output of the latch circuits 51-1 to 51-T and the output terminal 27- of the digital storage device 27 are connected to each other.
O1 ~ 27 - Output difference with OT is +1 or - of LSB
If it is 1 times, the latch circuit 51-
Considering that the outputs of 1 to 51-T include noise, the output terminals 27-O1 to 51-T of the digital storage device 27 are
27-OT output as is input terminal 27-I1
~27-IT, and if the output difference is neither +1 nor -1 times the LSB, the latch circuit 51-
The outputs of the latch circuits 51-1 to 51-T are assumed to contain no noise, and the outputs of the latch circuits 51-1 to 51-T are input to the input terminals 27-I1 to 27-I of the digital storage device 27.
7- Make sure to feed IT.

Such write logic circuits 53-1 to 53-T
By providing A of the matrix element determining circuit 20,
- In the D converter 50, when the analog input voltage is near the quantization boundary voltage value as shown in FIG. 6, the digital output fluctuates between codes m and m+1 due to slight input noise. This prevents noise from entering the digital output.

Note that even if the output of the latch circuit 51 does not contain noise, the output may be obtained from the decoder 55 or 56, and even in this case, the outputs of the output terminals 27-O1 to 27-OT of the digital storage device 27 are It is supplied to the input terminals 27-I1 to 27-IT, but the difference between the outputs of the latch circuits 51-1 to 51-T and the outputs of the output terminals 27-O1 to 27-OT is at most ±1 times the LSB. Therefore, this difference can be ignored and, moreover, it is possible to avoid deterioration in sound quality due to modulation noise caused by changing the digital input to the digital storage device 27, which is preferable.

26 is a 16-bit load circuit that supplies input digital signals CH ₁ to _{CH S} (signals synchronized with the second clock pulse) of the S channel to be mixed to input terminals 25-1 to 25-S and performs parallel-to-serial conversion. In the shift register, S stage register 26-1~
Consisting of 26-S. This register 26 is supplied with the following signals. First, clock generation circuit 4
A first clock pulse from zero (FIG. 7A) is applied to register 26. The code content of the counter 41 (FIG. 7B) is supplied to the decoder 36, and when the code S is obtained by the counter 41, the decoder 3
A detection signal (FIG. 7D) is obtained from the register 26 and supplied as a load pulse (FIG. 7F) to the register 26, and the phase of this detection signal is inverted by the inverter 37, and the signal is sent to the register 26 as a shift register (FIG. 7F). Supplied as Figure 7G). Incidentally, FIG. 7C shows the second clock pulse from the counter 41.

28 is T 16-bit multipliers 28-1 to 28;
-T, to which the outputs from the output terminals 27-O1 to 27-OT of the digital storage device 27 (FIG. 7I) are sequentially supplied, and the outputs CH ₁ to CH of the register 26, respectively. Multiplied by _S (Figure 7H). The outputs of multipliers 28-1 to 28-T are 16
It is supplied to bit adders 29 {29-1 to 29-T}. The outputs of the adders 29-1 to 29-T are each connected to a 16-bit accumulator 33{33-
1 to 33-T}. Accumulator 3
3-1 to 33-T are controlled by the first clock pulse. Also, the accumulators 33-1 to 33
-T outputs are respectively connected to AND circuits 32 {32-1 to 3
2-T}. The code content of the counter 41 is supplied to the decoder 30, and when the code 1 is obtained by the counter 41, a detection signal (FIG. 7E) is obtained from the decoder 30, which is transmitted via the inverter 31 to the AND circuit 32{32- 1 to 32-T}. And this AND circuit 32-
The outputs of 1 to 32-T are sent to adders 29-1 to 29, respectively.
-2.

The outputs of the accumulators 33-1 to 33-T (Fig. 7J) are each connected to a 16-bit latch circuit 34{34
-1 to 34-T}, and the output terminal 35-1
An output digital signal (K in FIG. 7) is obtained at ~35-T. Latch circuits 34-1 through 34-T are controlled by the first clock pulse and the output of decoder 30.

Additionally, a multiplier 28, an adder 29, an AND circuit 32
A matrix calculation circuit 67 is constituted by the accumulator 33 and the accumulator 33 .

Next, with reference to FIG. 8, a specific example of the analog signal mixing circuit 49 in FIG. 4 will be described. still,
Since the analog signal mixing circuit shown in FIG. 8 is a well-known circuit, it will be briefly explained in relation to the embodiment shown in FIG.

70, 71 are faders and level adjusters, 72
is the pan pot (panoramic potentiometer,
73 is an inverter, and 74 is a combiner, each of which has a circuit configuration as shown in the legend. 75,
76 is an input terminal for an input analog signal;
K (=32) line signal input terminals 75, respectively;
It consists of L (=8) echo return signal (output signals from an analog reverberation adding device (not shown) provided corresponding to the digital reverberation adding device 22 in FIG. 2) input terminals 76. . 77-8
1 is an output terminal for the output analog signal, and M
(=24) multi-channel signal output terminals, N
(=4) 4-channel signal output terminals, Q(=
4) echo send signal (which becomes the input signal to the above-mentioned analog reverberation adding device) output terminal, R (=
4) Queue send signal output terminals and P (=2)
It consists of solo signal output terminals. Note that "queue send" means sending a signal to a headphone, and "solo" means a signal of an announcer's voice, for example. 8
Reference numeral 2 indicates K input circuits respectively connected to the K input terminals 75, 83 indicates L input circuits respectively connected to the L input terminals 76, and 84 indicates M output circuits. SW ₁ to SW ₁₃ are changeover switches. SW ₁
is a phase inversion switch, SW ₂ and SW ₃ are front/back switching, SW ₄ is a channel odd-even and channel muting switch, SW ₅ is a bus selection switch, SW ₆ is a solo selection switch, SW ₇ is a 4-channel selection switch, SW ₈ is solo selection switch, SW ₉
SW ₁₀ is a phase inversion switch, SW ₁₁ is a channel mutating switch, SW ₁₂ is a channel selection switch, and SW ₁₃ is a 1/D selection switch.

According to the present invention described above, the coefficient data is changed in accordance with the operation of the operating means and the matrix elements of the storage device are rewritten, so that the operation can be performed in the same way as a conventional analog mixing device, and the mixing ratio can be changed freely. can be selected. Further, since the digital signals are directly mixed as they are, it is possible to obtain a digital signal mixing apparatus free from the various noises mentioned at the beginning.
Further, although the digital signals are directly mixed, the mixing is performed by performing matrix calculations on the input digital signals, so the configuration is simple and the mixing state can be easily varied.

[Brief explanation of drawings]

Fig. 1 is a block diagram showing a conventional digital signal mixing device, Fig. 2 is a block diagram showing an embodiment of the present invention, Fig. 3 is a characteristic curve diagram, and Fig. 4 is a part of Fig. 2. A block diagram showing the specific configuration of
5 is a waveform diagram, FIG. 6 is a characteristic curve diagram, FIG. 7 is a waveform diagram, and FIG. 8 is a block diagram showing a specific configuration of a part of FIG. 2. 19 is a digital signal mixing operation circuit, 20 is a matrix element determining circuit, 27 is a digital storage device, and 67 is a matrix operation circuit.

Claims (1)

[Claims] 1. A digital signal mixing device configured to mix S channel (S is a positive integer) digital input signals with each other to obtain a T channel (T is a positive integer) digital output signal, comprising: The ratio setting operating means and the analog input signal of the S channel corresponding to the digital input signal of the S channel are mixed with each other at a desired mixing ratio according to the position or change of the mixing ratio setting operating means to produce an analog output of the T channel. The analog signal mixing circuit from which the signal is obtained and the input/output relationship of this analog signal mixing circuit are measured to determine a mixing coefficient according to the position or change of the mixing ratio setting operation means.
a matrix element determining circuit that outputs a digital signal of the matrix element of ×T; a digital storage device that stores the digital signal of the matrix element of S×T;
A matrix calculation circuit for performing a matrix calculation on the digital input signal of the channel and the digital signal of the S×T matrix elements sequentially read out from the digital storage device to obtain the output digital signal of the T channel. A digital signal mixing device.