DE2235238A1 - MULTISIGNAL TRANSMISSION DEVICE - Google Patents

Description

It 2199 SQHY CORPORASIOiT, Tokyo / Japan

SZ SZ SS SS 55 3 »iS 'SS SS SS S! S? SS S

Multi-signal transmission device

The invention relates to a multi-signal transmission device and in particular improved decoding and reproduction on a variety of speakers to achieve a Listener a. highly realistic multi-channel prο grarom one To convey sound reproduction.

A so-called matrix four-channel stereo system has already been proposed in which four original Sehallsignals (which for the sake of simplicity are called Ii _f , Ii ^, R ^ and R _fe for "left front", "left rear", "right front" or "right." behind "are identified) into signals of only two channels by matrix networks, so-called coders, converted and then decoded into four signals by matrix networks, so-called decoders,

The corresponding, original sound is preferably only reproduced by a loudspeaker. With such a matrix four-channel stereo system becomes in addition to the corresponding original Sehallsignal another Sehallsignal, the must be reproduced by another speaker at the same time, as crosstalk reproduces what is obvious is undesirable.

In order to avoid such an unwanted signal, in particular crosstalk, it was suggested to use a control amplifier to use a special logic circuit, for example in U.S. Patent 3 * 632,886. In this

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In this case, the gain of the channels in which the crosstalk effect occurs is obviously reduced with the control signal. Thus, if only the crosstalk signal is taken into account, there is no crosstalk, with the result that the separation between the channels is improved so that error-free production cannot be carried out. Further, depending on the increase or decrease in the gain of the control amplifier, the noise components of the sound components existing in the channel are also decreased or increased. Therefore, noise components are simultaneously reproduced from the speaker, giving an unrealistic sensation to a listener. "

The invention is therefore based on the object of creating a multi-signal transmission device in which the Separation between the channels can be improved and, in particular, a crosstalk signal can be deleted without loss of the main signal can,

In a multi-signal transmission device according to the invention a variable mixing circuit is provided between a pair of channels, the mixing circuit having a control signal controlled as a function of a crosstalk signal will.

With the device according to the invention it is possible to eliminate a crosstalk signal between two channels with a variable Mlech circuit that is simple in construction and can be realized with little cost.

In the case of the MultisigiaÄl ^ transmission unit with the new Overspreading devices are coded, grouped

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Set signals of different types to a matrix circuit applied to the appropriate, composite signals to decode so that the separation between channels is improved will. In the case of the multi-signal transmission device eventually deleted a crosstalk between channels without that the gain of a channel transmitting a signal is varied so that a noise signal inherent in the sound elements is kept substantially constant.

A specific embodiment of the invention can be summarized as follows. In a multi-signal transmission device that can receive first and second composite signals Lm and B ~, respectively, which contain predominant signal components L 'and R- and each have at least two subordinate signal components 1, and R with a predetermined phase relationship with one another the apparatus includes decoding circuit means for converting the two composite signals L ″, and R ™ into four output signals containing the predominant signal components Ii ″, R ″, i, and R, respectively, each of the output signals also having minor signal components as crosstalk contains, and to generate a Überspreeh detector circuit, van least one control signal. Mixing circuitry is connected between a pair of output channels to transmit the output signals, the mixing circuitry being controlled to mix two output signals in accordance with the control signal so as to eliminate the cross-talk signals contained therein.

Embodiments of the invention will now be based on the attached drawings. Show it:

Pig. 1 shows a schematic representation of an encoder for a better understanding of the invention;

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- 4 - // :? ■■■ / ^ο ' ^:

Pig. Figure 2 is a schematic diagram of a device according to the invention;

Pig. 3 is a schematic diagram of a crosstalk signal detector circuit used in the method disclosed in Pig. 2 shown Facility is used;

Pig. 4 is a circuit diagram of a mixer circuit shown in "at the one in Pig. 2 is used;

Pig. Fig. 5 is a schematic diagram of another encoder for explaining the invention;

Pig. 6 and 7 phase diagrams to explain the mode of operation and the advantages of the in Pig. 5 of the encoder shown;

Pig. Figure 8 is a schematic diagram of another decoder used in connection with the invention;

Pig. 9 is a schematic diagram of another crosstalk detector circuit; the one in Pig. 8 is to be used;

Pig.10 is a schematic diagram of another decoder, used in connection with the invention; and

Pig. 11 is a schematic diagram of another crosstalk detector circuit, the one in Pig. 10 shown decoder can be used.

For a better understanding of the invention, first an encoder is described which encodes four original sound signals into two composite signals

2 0 ü UH h / U 9 h 7

ORIGINAL INSPECTED j

- 5 -. 223f ^ 3B

causes. An encoder (Fig. 1) has four input connections 10, 12, 14 and 16, to the four original sound signals! Ι. ,, Iu, R, and R ~, which are shown as in-phase signals of the same amplitude in the figure, respectively created. All of the I. The output of summing junction circuit 18 is applied to a ^ network (all-pass phase shifting network) 20 which provides a phase shift of * f + 90 (where 'f is a function of frequency. The full Rf signal appearing at the input terminal 16 is pending, is summed up in a summing network 22 with 0.707 of the I. signal, which is present at the input terminal 12 and runs through a phase inverter 12a. The output of the summing network 22 is given by a V network 24, which also has a phase shift of . ψ effected + 90 ° the phase-inverted Iu signal and the R signal are also applied to the corresponding ψ network 26 and 28 which cause respectively a phase shift of ψ the full signal on the output side of ψ. - Network 20 occurs is summed in a summing circuit 30 to 0.707 of the signal appearing on the output side of network 26 to produce a composite signal Im at its output terminal 32a en. Similarly, the full signal from network 24 is added in a summing circuit 34 to 0.707 of the signal from network 28 to produce a composite signal Rm su at its output terminal 36. It should be noted that the phasor group 38 of the composite signal L ₃ consists of the L _f signal, 0.707 of the R ^ signal in phase with the L _f signal and 0.707 of the L ^ signal which is opposite to the L _f -Signal lagging by 90 °. A phaeor group 40 of the composite signal R- consists of the R - signal, 0.707 of the R. signal, which leads the R _f signal by 90 °, and 0.707 of the L

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gnales, which is 90 ° from the 0.707 R ^ signal. It should also be noted that the composite signals L ^ and R ₃ can be transmitted by a frequency-modulated multiplex radio. They can also be recorded on any two-channel medium such as two-track tape or a stereophonic disk for later reproduction.

The two composite signals Lm and IL ,, which pass through The encoder shown in Fig. 1 are coded into four output signals by the decoder shown in Fig. 2 decoded that contain the respective predominant signals corresponding to the respective original signals. The compound Signals L ^, and R ^ passing through the phasor groups 38 and 40 are applied to input terminals 50 and 52, respectively, of the decoder shown in FIG they are applied to corresponding f-networks 54 and 56. In this way tritfc. the composite signal Lm without relative phase shift through the network 54 and is applied from there to an amplifier 58. The other composite signal R ™ occurs with a relative phase shift of 90 ° through the network 56 and is connected to an amplifier 60 from there. The .707 fraction of the Signal appearing on the output side of the network 54 becomes in a summing connection 60 to -0.707 times of the signal appearing on the output side of the network 56, from where the summed signal is sent to an amplifier 62 is applied. 0.707 times that which occurs on the output side of the network 54, the signal is in a Summing junction 64 is added to 0.707 times the output of network 56 from where the summed Signal is applied to an amplifier 66. The phasor groups 68, 70, 72 and 74 «own the output of the amplifier 58, 62, 66 or 60. At this moment the phasor group 68 exists

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ORIGINAL INSPECTED

-7- ■

from an L _f signal, a 0.707 R ^ signal in phase with the Ii _f signal and a 0.707! ^ signal that _{lags by 90 ° with respect to the R f} and 0.707 R ^ signals. The phasor group 70 consists of the 1 ^ signal, a 0.707 l _f signal which leads the L ^ signal by 90 ° and a 0.707 R _f signal which leads the 0.707 l _f signal by 90 °. The phasor group 72 consists of the R, signal, a 0.707 L _f signal in phase with the R, signal and a 0.707 R _f signal that lags behind the R ^ and 0.707 L _f signals by 90 °. The phasor group 74 consists of the R signal, a 0.707 R ^ signal, which leads _{by 90 ° with respect to the R fT} signal, and a 0.707 L ^ signal, which leads by 90 ° with respect to the 0.707 R ^ signal. Note that the 0.707 L _b signal of the phasor group 69 and the 0.707 1, signal of the phasor group 74 are out of phase with each other, and further that the 0.707 R _f signal of the phasor group 70 and the 0.707 R _f signal of the Phasor group 72 are out of phase with each other.

The output signals from amplifiers 60 and 66 are fed to phase inverters 80 and 82, respectively, so that the polarities of the output signals from phase inverters 80 and 82 are reversed as shown by phasor groups 84 and 86. It should be noted that the 0.707 R -.- signal of the phasor group 68 and the 0.707 R, signal of the phasor group 84 are out of phase with each other, and that the 0.707 L "signal of the phasor group 70 and the 0.707 L" signal are also out of phase of the phasor group 86 are out of phase with one another. The output signals of amplifiers 58 and 62 and the output signals of phase inverters 82 and 80 are applied to Ψ networks 88, 90, 92 and 94, respectively. In this pail, the ψ networks 88 and provide a phase shift of V +90 °. The output signals which occur at the output sides of the ψ networks 88 and 90 are passed on through phase inverters 96 and 98 to the output connections 112 and 114, respectively. The output signals,

ÖRHälNÄL INSPECTS *

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the th occurring at the output sides of the ψ networks 92 and 94 'are connected directly to the Ausgangsanschlüsee 116 and 118

transfer. The phasor groups of the output signals that are sent to the. <

corresponding output connections 112-118 can be derived

den are shown at 104, 106, 108 and 110, respectively. It is to be j

ensure that corresponding prevailing signals, in particular;

I <£ -, L, - and R "signals, in the corresponding phasor groups f,

are in phase with each other. ^f

With the setup described above, the original! borrowed sound signals L ^, L,, R _f and R, which are contained in the composite) signals L ^ and Rn, in the output | output connections 112-118 derived signals or as predominant signals. In this case, however, contains, \ as shown in the Phasorgruppe 104 appearing at the output terminal 112 output signal undesired tributary signals L and R, are the cause of crosstalk. The output signal appearing at the output terminal 114 also contains undesired subordinate signals L ~ > and R _f , which are also the cause of crosstalk.

In the invention, therefore, means are, for example

variable mixer circuits for eliminating crosstalk, j provided between the channels in which crosstalk components occur in reverse phase relationship. The Mischschal- 'obligations are controlled in operation with the adjacent thereto crosstalk components, see the crosstalk components to be solved), or reduce.

Since the 0.707 L, signal of the phasor group 68 and the 0.707 \

L, signal of the phasor group 74, as described above, to j

are inverted or out of phase with each other, a first over-,

speech-lb'echechaltung or a first variable mixing circuit »->

device 120 in the Pig embodiment. 2 between '

the output 3 sides of amplifiers 58 and 60 are provided. On '

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INSPECTED

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Similarly, a second, - third and fourth variable Kisöhöelaaltuiigseinriclitting 122, 124 or '126 between the output sides of the amplifiers 62 and 66, wherein the subordinate eü S / ignale R ^ are in AEEN outputs the same atißer phase between the output of the amplifier 58 and the phase inverter -80, with the subordinate signal R, and da © subordinate signal R ^ in their outputs out of phase, and inserted between the outputs of the amplifier 62 and the phase inverter 82, with the subordinate signals If * in the outputs except Phase are. The mixing circuits 120-126 are respectively controlled in their operation by control signals which are generated by the crosstalk signal detector, which will be described below.

Pig. FIG. 3 shows an embodiment of the audio signal detector which is used in the device shown in FIG. The input terminals 132, 154, 136 and 137 '* it tiber speech signal detector 130 are respectively old the output * terminals 132a, 134a _R 136a and 137a of the amplifiers 58, 62, 66 and 60 (Pig. 2), so that from the outputs shown to the phasor groups 68, 70, 72 and 74 are fed to all-wave rectifier circuits 138, 140, 142 and 144 respectively with unchanged phases and then all-wave rectified. The output of the rectifier circuit 138, shown in the figure as phasor group 146, has the 0.707 L. signal which is reversed in phase from the previously applied signal. The output of the rectifier circuit 144, which is shown in the Pigur as phasor group 148, has the R _f signal, the phase of which is reversed with respect to the previously applied signal. Similarly, the outputs of the G-leichrichterßAhaltuiigen 140 and respectively shown in the figure as Phasorgruppen 150 and 152 142, wherein the Phasorgruppe 150, the L _b - i signal in phase with the 0.707 R _f -Slgnal and Phasor-, ru- _t > yii 152 the 0.707 H _f -üsignal by 90 ° compared to the R ^ -

has leading. The outputs of the equator circuits 138 and 144 are fed to a subtraction circuit 154 in order to generate a subtraction signal of the _f and R _f signals, in particular / IiJ - /R ^./, because the 0.707 L, - and 0.707 R ^ signals of the two phasor types 146 and 148 are in phase with each other and are consequently canceled by the substruction. Similarly, the outputs of rectifier circuits 140 and 142 are fed to a subtraction circuit 156 to produce a subtraction signal of the L. and R i signals, particularly / L ^ / - / R ^ /, because the 0.707 R _f - and 0.707 L _f signals of the two phasor types 150 and 152 are in phase and are consequently canceled by stopping. The outputs of the subtraction circuits 154 and 156 can therefore be viewed as absolute comparison outputs between the prevailing signals in the front and rear channels. Assuming that the output signals of the subtraction circuits 154 and 156 are designated as α and β, respectively, the output signal α is applied to an output terminal 160a through a rectifier 160 and further to an output terminal 164a through a phase inverter 162 and a rectifier 164, while the Output signal β is output to an output terminal 166a through a rectifier 166 and further to an output terminal 170a through a phase inverter 168 and a rectifier 170. The output connections 160a, 164a, 166a and 170a of the crosstalk signal detector 130 are connected to the input connection 126a, 122a, 120 * and 124 of the Mieehechaitunken 126, 122, 120 and 124 respectively (FIG. 2).

An example of the Mieekaltungen is based on FIG. 4 which shows the mic circuit 120 as an example. The mixed law 120 consists mainly of "us a" tran-, sistor Tr, whose collector connects to the output of the amplifier 58 is connected through a resistor K. while being Emitter to the output of amplifier 60 through a resistor

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stood R _{2 is} connected. The base of the transistor Tr serves as an input terminal 120a of the mixing circuit 120 to which the control signal is applied. The other mixer circuits can similarly be thawed. It will be apparent, however, that circuits other than mixer circuits can be used in the invention.

In the following, the operation of the one shown in FIG. 2 will be described Decoder described. If only the! ^ Signal in the compound Signal I ^ is present, the L ^ signal appears to output terminal 112 as the dominant signal L-, but simultaneously to output terminals 114 and 116 as subordinate signals or crosstalk signals. The DC component of the Iy signal or the S expensive signals However, α is derived from the output terminal 160a of the crosstalk signal detector 130 by the subtraction circuit 154 and from the output terminal 160a =. to the output port 126a of the mixer circuit 126 is supplied as a control signal. Thereby, the transistor Tr of the mixer circuit 126 is between its collector and emitter conductive, and the corresponding signals of the phasor groups 70 and 86 are in the mixer circuit mixed together to produce the 0.707 Ru signals of the same that are out of phase. ! Consequently, are no L "signals from the output terminals 114 and 116 derived.

If the composite signal R 1 contains only the R 1 signal, then the R 1 signal appears at the output terminal 116 as the predominant signal R 1 and at the output terminals 112 and 118 as subordinate signals or crosstalk signals. By the subtraction circuit 156, however, the DC voltage component of the R ^ signal or the -ß signal is generated as a control signal. The control signal -β is sent by the phae "! Inverter 168 and the rectifier 170 to the output terminal 170a as a control

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signal β output and then to the input terminal 124a of the Mixing circuit 124 is supplied. The corresponding signals of the phasor groups 68 and 84 are combined with one another in the mixer circuit 124 mixed, with the 0.707 R-u signals contained therein, that are out of phase are canceled, thus becoming the 0.707 R. signals that cause crosstalk would be prevented from being output to output ports 112 and 118. The control signal or the -ß signal, which is derived from the subtraction circuit 156, is also fed to the rectifier 166 at the same time, however, it is not transmitted to the output terminal 166a of the detector 130 because it is a negative signal component and is prevented from passing through rectifier 166. Similarly, the 0.707 R ^ signals that would cause crosstalk and contained in the phasor groups 170 and 172 are deleted in the switch 122. The 0.707 L ^ signals that a Would cause crosstalk and are contained in the phasor groups 68 and 74, are in the mixer 120 cleared, this prevents crosstalk signals from being sent to the output terminals. With the invention Selialtung, the holdings as crosstalk deletion devices is used, the separation of the respective channels is easily and efficiently performed.

FIG. 5 shows a modified embodiment of an encoder which has animal input connections 210, 212, 214 and applied to the Tier original® sound signals L, L, R, and R, also as phase signals of the same amplitude .® are barked. The entire L _f signal is added in a SramirLsrverbiMusg 218 with -0.707 of the R ^ signal, the output of the Suiamier connection 218 being applied to a phase shifter 220 which introduces a reference phase shift f which is a function of the frequency. The full R ^ signal on terminal 216 becomes

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is summed in a summing network 222 with 0 ^ 707 of the L ^ signal appearing at the input terminal 212, and the output is passed through a ψ network 224 which also provides a reference phase shift ψ . The Ji, - and R ^ signals are also applied to respective ψ networks 226 and 228, each of which produces a phase shift of ψ + 90 °. The full signal appearing at the output of network 220 is added in a summing circuit 230 with -0.707 of the signal appearing at the output of network 226 to produce _{a composite signal L 3 at its output terminal 232.} Similarly, the full signal from network 224 is added in a summing junction 234 to 0.707 of the signal from network 228, the latter occurring in this pail in the positive Si.r> n. The signal appearing at an output port 236 of network 234 is the composite signal

The meaning of the Pig's coder modifications. for the realization of Pig's encoder. 5 (in particular the reversal of the phase of the 0.707 connections of the two summing lines in the upper half of the diagram) results from an analysis of the phase relationship of the combined "Lg and R ^ signals, which are shown as phasor groups 238 and 240, respectively. Es Note that the phasor group 238 consists of the signal L _f (which, although shown in the same phase relationship as the input signal L _f , has an angular difference ψ as a puncture of the frequency therebetween), a signal 0.707 R ^ in a negative sense with respect to the corresponding input phase value and a 0.707 Ii ^ signal, which lags the phasor 0.707 R by 90 ° due to the action of the network 226. The phasor group 240 consists of the original signal R ~ in the same relative phase position as the corresponding input signal, a signal 0.707 I ^ in phase with the R _f signal and a 0.707 R ^ j signal which, due to the effect of the ψ network 228, lags the 0.707 I ^ signal by 90 °.

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The effect of the swivel split (Pig. 6) is to split the signal (for example by two coupled dampers) between two channel inputs. In the center of the pivot dividing the signal _f is exactly between the front channels L and R _f or divided between AEEN rear channels I ^ or R ^. This state will now be described. The phasor groups 238 and 240 (Pig. 5) are repeated here as phasor groups 250 and 252, respectively, with the center signals obtained by pivoting being added. The front center signal C- is brought into proportion 0.707 G _f and in phase in phasor groups 250 and 252, appearing as phasors 254 and 256.

It should also be noted that the rear center channel C, in the proportion 0.707, is divided into the left Mnterem and right rear channels. Since these two phasors occur as 0.707 values, the corresponding part of the G ^ signal is 0.5 in phase with the 0.70? L ^ phasors and 0.5 in phase with the Ο ,, 707 R ^ phasors in both phasor groups. With this convention observed, it can be seen that the two phasors in each group add up to make larger phasors 0.707 C ^ in each of the phasor groups 250 and 252. Note, however, that the Phaser O _? 7O7 C ^ in phasor group 250 with the corresponding phasor in group 252 is out of phase.

Another important feature of the encoder is provided by the phasorgmpexi 256 and 258 in fig. 7, where the former represents the situation SiOH results when the Phasorg-irupiiea 250 and 252 of 3? _E are added 6 ig, and the latter represents the situation ,, wean the combined signal R ₃ (Phasorgrappe 252) is subtracted from the signal I ^ (phasor group 250). If the! ", - mid R ^ signals are added, the phasors L _f , I ^, R ^ and E _f all have an intensity equal to 1, while the front center signal C ^ is increased by a factor of 1.414, which is exactly the Situation corresponds if

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a stereo record is played on a mono playback system. However, the center rear signal O ^ is canceled because of the above out-of-phase relationship. If the phasor groups are subtracted, the phasors Ii £, L ^, R ^ and R _f all appear again with an amplitude equal to 1, but this time the rear center signal C is increased by a factor of 1.414, while the front center signal C is deleted . The relationship represented by phasor groups 256 and 258 is extremely important as it indicates that when there is only a front center signal. (ie no rear center signal), the phasor group 256 is larger than the group 258 and that conversely, if there is only a rear center signal but no front center signal, the phasor group 258 is larger. This property is used to facilitate the operation of the Pig. to improve the decoder used, which will now be described.

The decoder shown in FIG. 8 is similar in many respects to the decoder shown in FIG. The combined signals Lm and Rm, represented in Fig. 5 by the phasor groups 238 and 238, respectively, are applied to the respective input terminals 300 and 302, from where they are applied in parallel to respective pairs of Ψ networks 304, 306, 308 and 310 will. In this way, each of the signals Lm and Rm passes through networks 304 and 308, respectively, with no relative phase shift and through networks 306 and 310 with a relative phase shift of 90 °. In the phasor groups 212, 214, 216 and 218, which represent the output signals from the networks 304, 306, 310 and 308, respectively, the individual phasors, which are essentially identical to the corresponding phasors in the groups 238 and 240, are represented by a Apostrophes are distinguished to indicate that they have been subjected to the action of a ψ network and therefore differ from the input phasors by an angle that is a ψ function of frequency, and additionally by “a differential angle introduced by the networks will. 203885/0957

The outputs of networks 304 and 308 are applied directly to the input terminals of the respective amplifiers 313 and 315. the outputs of which are applied to respective speakers 316 and 318 located in the front left and front right corners in an audience room M. The signals applied to loudspeakers 316 and 318 contain the predominant original signals L _f and R- and the two subordinate interference signals 0.707 L and 0.707 RJ _3, respectively. Equal parts, in particular 0.707 of the outputs, of networks 306 and 308 are summed up at a summing connection 320 to form a combined signal consisting of a predominant signal. L ^, which is applied to an amplifier 322 and from there to a loudspeaker 324, which is arranged in the left rear corner of the room M. The same negative cables, in particular -0.707 of the output signals of the networks 304 and 310 are summed at a second summing network 326 in order to apply a combined signal to an amplifier 328 consisting of a predominant signal R ^ together with 0.707 R ^ -and 0.707 L ~ - Signals after: to generate an amplification. This combined signal is applied to a loudspeaker 330 located at the right rear corner of the room M. From the phasor groups 332, 334, 336 and 338, which respectively represent the combined signals on the loudspeakers 316, 324, 330 and 318, it can be seen that the predominant phasors on all loudspeakers are in phase.

If the secondary signals L ~, and Rm contain the front center signal & al G _f , 0.707 times the front center signal C _f occurs in phase in the L _f and R _f signals of the decoded phasor groups 332 and 338, respectively. The entire front center signal 1.4 C _{f of} both phasor groups 332 and 338 can be represented by a phasor 340 in Pig.8. 0.5 times the front center signal components G "also occurs in both the L _f and R" signals

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* of the phasor groups 334 and 336 in phase. Thus, the front center signal component C _{f of} the phasor group 334 can be shown as a whole by a phasor 342 and the front center signal component of the phasor group 336 can be shown as a whole by a phasor 344. As mentioned earlier, when a front center sound exists in an original sound field, the front center sound signal is reproduced from speakers 324 and 330 for the rear channels with opposite phase relationship, respectively. Similarly, when a sound exists in the center back in an original sound field, the rear center signal C appears in a reproduced sound field in both phasor groups 334 and 336 and also in phasor groups 332 and 332. In a similar manner, these rear center signals are represented in the phasor groups and by the phasors 346 and 350 in the figure, respectively. Accordingly, when a sound in the center back exists in an original sound field, a sound in the center back is reproduced in a reproduced sound field, respectively, from the speakers 316 and 318 for the front channels in opposite phase relation. For this reason, a listener can in the reproduced sound field does not sufficiently separate the sound from the front center and rear center and therefore has an unpleasant impression.

It should be noted, however, that the rear center signals passing through to the front channels and the front center signals, which pass through to the rear canals, reversed in phase, but the same in size. Consequently can with the invention the überpreehsignale with the reverse Phase can be deleted in the same way as described in connection with the first embodiment became. To this end, in the embodiment of FIG. 8, a mixing circuit 360 is used between the input sides the amplifier 313 and 315 as a first crosstalk cancellation network and a second mixing circuit 262 between the inputs

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the amplifiers 322 and 328 as the second overspread cancellation ' network or connected. Mixer circuits 360 and 362 are a type of variable mixer, whose mixed operation is changed or controlled according to the crosstalk signals. Circuits similar to those in Pig. 4th can be used as variable mixing devices for this example.

Fig. 9 shows a circuit which generates the front center signal or the rear center signal (crosstalk signal) recorded. Generally shown in this figure is the front or rear center signal detector circuit 370. the Input terminals 372 and 374 of circuit 370 are connected to terminals 300a and 302a (FIG. 8), respectively, so that the input signals L ", and R ™, which are applied to the input connections 300 and 302 are pending, also to input terminals 372 and 374 and then to a summing junction 376 and a subtracting junction 378 respectively. The sum signal appearing at the output of summing junction 376 and the sum of Lm and Rm is as a phasor group 256 in Fig. 7 shown. The output of subtraction junction 378 is a combined signal whose properties are shown in FIG Phasor group 258 is shown in FIG. From Fig. 7 it can be seen that when the front center signal is dominant the output of summing circuit 376 exceeds the output of subtracting circuit 378, and vice versa if the rear center signal dominates, the output of the subtraction link exceeds the output of the summing junction. In order to obtain the relative relationship between these two quantities, the outputs of connections 376 and 378 become in respective quasi-logarithmic amplifiers 380 and 382 amplified and then by corresponding grueling lights 384 and 386, which are preferably full wave rectifiers, and with imperfect integrators 388 and 390, respectively integrated. The outputs of the integrators 388 and

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390 are applied to a subtraction circuit 392, the output of which is passed through a rectifier 394 to an output terminal 394a and through a phase inverter 396 and a rectifier 398 is applied to an output terminal 398a. Output terminals 394a and 398a of circuit 370 become connected to the control terminals 362a and 36Oa of the mixing circuits 362 and 360, respectively.

If the two composite signals L ™ and Rm contained a front center signal, the front center signal is detected by summing junction 376 and then on the subtraction circuit 392 is applied through the rectifier 384. In the meantime, there occurs the output of the subtraction connection 378 did not contain a front center signal, a positive output at the output terminal of the subtraction circuit 392 as a control signal, which is then applied to the mixer circuit 362 by the rectifier 394. as As a result, the outputs of summing junctions 320 and 326 are mixed in mixer circuit 362 to form the front center signal components C ~ except phase to be deleted. The output of the subtraction circuit 392 is sent to the phase inverter 396 is applied and made a negative control signal so that no control signal is output to the output terminal 398a will. As a result, mixer circuit 360 does not operate, so the front center signal is from the front speakers 316 and 318, respectively.

In contrast, when the two composite signals Lm and Rm contain a rear center signal, respectively, a negative control signal is derived from the output terminal of the subtracting circuit 392 as the output of subtraction link 378 becomes larger than that of subtraction link 376. The negative control signal becomes a positive control signal from the phase inverter 396 in

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verted and then to the control connection 36Oa of the mixer circuit 360 is applied by rectifier 398. Thus, the outputs of networks 304 and 308 become in mixer circuit 360 mixed and the center back signal components C i, which are out of phase, are canceled from each other. The negative control signal from the subtracting circuit 392 is not applied to the output terminal due to the function of the rectifier 394 394a submitted.

As can be seen from the preceding description, it is possible by the invention that by front and to delete rear center signals caused crosstalk with the help of the mixer circuits.

It can be seen that the circuit 370 described above is applied to the decoder of FIG. 2 with the same effect can be. Furthermore, it may also be possible to connect the input connections 372 and 374 to the output connections of networks 304 and 308 for the same purpose. It is obvious that if the subordinate signals of the same type in circuit 130 are reversed in phase, the subtracted output is substantially zero as they pass through full wave rectifiers and subtracted from each other.

Fig. 10 shows another decoder according to the invention. The decoder of Fig. 10 has two input terminals 402 and 404 to which the composite signals L ^ and R ^ are applied. The composite signals L _m and R ^ are generated by an encoder (not shown) called a regular matrix encoder. The composite signal Lm consists of a! «Signal, a 0.4 R ^ signal in phase with the L _f signal, an L ^ signal that leads the! Signal by 90 ° and a 0, 4 R ^ signal in phase with the L, signal. The composite signal Rm consists of an R _f signal, a 0.4! Signal in phase

209885/0957

ORIGINAL INSPECTED

with the R "signal., an R, signal that _{lags behind the R f} signal by 90 °, and a 0.4! -, - signal, in phase with the R ^ signal. A basic matrix circuit 406 is connected to input terminals 402 and 403 and has four output terminals 408, 410, 412 and 414 for providing four output signals. The four output signals are shown in the figure as phasor groups 420, 422, 424 and 426, respectively, and are fed from the output terminals 408 to 414 through networks 440, a phase inverter 442, a ψ network 444, a phase inverter 446, a y network 448 and transmit a ψ network 450 to output ports 460, 462, 464 and 466. The phasor group 420 consists of the! "- signal, a 0.707 R _f signal in phase with the! - signal and a 0.707 ¹ Lu signal that leads the!" Signal by 90 °. The phasor group 422 consists of an L, signal, a 0.707 R, signal in phase with the!, - signal and a 0.707! ^ - signal which lags behind the L, signal by 90.degree .. The phasor group 424 consists of an R. , Signal, a "0.707!, Signal in phase with the R, signal and a 0.707 R _f signal that leads the R, signal by 90 °. The phasor group 426 finally consists of an R n signal, a 0.707 L, signal in phase with the R ^ signal and a 0.707 R. signal, which _{lags behind the R f} signal by 90 °. In this pail the R _f -,! * .- »& u ~ 'and. R ~ signals in the corresponding phasor groups 420 to 426 predominate (dominant) signals and the other signals are subordinate (subdominant) signals which are presented as noise signals. It should be noted, however, that the R- signal components in phasor groups 420 and 424 have the same amplitude but are out of phase with each other, and similarly these R- signal components in phasor groups 422 and 426 have the same amplitude but out of phase with each other are. The output signals from output terminals 410 and 412 are phase-determined by phase

209885/0957

ORIGINAL INSPECTED

- ²² - 2235236

inverters 442 and 446 are inverted and are shown in the figure as phasor groups 454 and 456. As can be seen from phasor groups 454 and 456, the signal components of L ^ in phasor groups 420 and 456 have the same amplitude but are out of phase. Similarly, the signal components of L _f in phasor groups 14 and 454 have the same amplitude but are out of phase. the

-Networks 440, 444, 448 and 450 are used to receive the prevailing signals, ^ & ie from the output ports 460, 462, 464 and 466 included output signals to make them in phase. The ones at the output ports 460 to 466 derived outputs are shown in the figure as phasor groups 470-476.

About the opposite phase crosstalk signals in this pail becomes a variable Mixer circuit 480-486 used as a cancellation circuit for crosstalk. Mixer circuit 480 is between the output terminals 408 and 412 of the basic matrix circuit 406, the mixer circuit 482 between the output terminals 410 and 414, the mixer circuit 484 between the output terminal 408 and the output of the phase inverter 446 and 446 the mixer circuit 486 is connected between the output of the phase inverter 442 and the output terminal 414, respectively. Circuits similar to the circuits shown in Fig. 4 can be used as mixer circuits in this embodiment.

Fig. 11 shows a circuit diagram of a crosstalk signal detector 488. The detector 488 has four input ports 490, 492, 494 and 496 that correspond to the output ports 408, 412, 410 and 414, respectively, of the basic matrix circuit 406 are connected. The input terminals 490 and 492 are connected to full wave rectifiers 498 and 500 respectively, and lead from there to a first subtraction

209885/095?

connection 502, while the input connections 494 and 496 are connected to full-wave rectifiers 504 and 506, respectively, and lead from there to a second subtraction connection 508. It should be noted that the first subtraction signal from the L 1 and R 1 _{signals are generated in connection 502 and the second subtraction signal from the 1 and R f} signals are generated in connection 508 as first and second control signals, respectively . The first control signal is then connected through a rectifier 512 to a first output terminal 510 which is connected to a control terminal 486a of the mixer circuit 586, and furthermore through a phase inverter 516 and a rectifier 518 to a second output terminal 514 which is connected to a control terminal 482a of the Mixing circuit 482 is connected. The second control signal is connected through a rectifier 522 to a third output terminal 520 which is connected to a control terminal 480a of the mixer circuit 480, and furthermore through a phase inverter 526 and a rectifier 528 to a fourth output terminal 524 which is connected to a control terminal 484a of the mixer circuit 464 is connected.

The in the 5 ¹ Ig. Circuits shown in FIGS. 10 and 11 serve to cancel the crosstalk signals in a manner similar to that of the first and second embodiments, as already described. However, an operation of the circuits shown in Figs. 10 and 11 will now be described as an example. The R signal contained in the L ™ and R ™ composite signals appears at output terminals 408 and 412 of the basic mixer circuit 406 as a crosstalk signal. However, since the output signals of the output terminals 408 and 412 are mixed by the _{mixer circuit 480, the R f} signal components contained therein have the same amplitude but are out of phase with each other. In this case, the mixing circuit 480 is in its mixed state with the control signal.

2 09885 / 09B7

- 24 - 2 2 3 5 / ° 8

which is derived from the output terminal 520 of the detector circuit 4-88.

In the present invention, since crosstalk signals are present in the mixer circuits used between the channels, the separation much improved between the channels. In the foregoing description, the detector circuits 130 and 488 fed to the outputs of the output connections of the decoders as input signals. However, it may be possible for them as input signals the signals are supplied, which from derived from the combined signals that have passed through the matrix circuit separate from the Decoder is provided.

209885/0957

INSPECTED

Claims (1)

PATENT CLAIMS J Multi-signal transmission device with: a) a device for converting two composite signals into four output signals, each of the Output signals has a predominant signal and at least two subordinate signals, which in other output signals or prevailing signals, b) transmission channels for transmitting the respective output signals, c) means to track the phases of the two output signals in such a position that they are out of phase with respect to the same, subordinate contained therein Signals are, and with d) a device for generating at least one control signal by comparison with two signals which are derived from the implementation facility, characterized in that a variable device is connected between two channels in which the same subordinate signals are transmitted, and that the variable device is controlled with the control signal is used to substantially cancel the out-of-phase minor signals. 2. Device according to claim 1, characterized in that the conversion device all-pass phase shifter networks, to give the two composite signals a relative phase difference of 90 °, and a summing switch 2098öb / 0957 J "picnic tion, around the two composite ones, shifted in their phase Summing up signals received from the all-pass phase-shifting networks are derived. 3. Device according to claim 1, characterized in that the variable device is a variable impedance device to which the control signal is applied and whose impedance is varied with the control signal. 4. Device according to claim 1, characterized in that the control signal generating means includes a circuit for receiving a first pair of signals that one Pair of output signals and which contain the same subordinate signals, respectively, which are essentially have the same amplitude and a coincidence or antiparallelism in their phase, and around a to receive a second pair of signals corresponding to the other pair of output signals that are subordinate to them Signals respectively contain which are essentially the same size and a coincidence or in their phase position Have antiparallel and have a comparator circuit to match the first pair of signals and the second Pair the signals respectively to compare in order to distinguish whether the signals have signal components with substantially equally large amplitudes, which in their phase either have a coincidence or an antiparallel position demonstrate. 5. Device according to claim 4, characterized in that the circuit device has four input terminals for receiving of four output signals and full wave rectifier circuits and in that the comparison circuit comprises a subtraction circuit to obtain the outputs of to subtract the full wave rectifier circuits. 209Ö8 5/0957 6. Multi-signal transmission device with: a) a first channel for transmitting a first composite Signal, which is a first predominant (dominant) signal and at least one subordinate contains (subdominant) signal, b) a second channel for the transmission of a second composite Signal comprising a second predominant signal and at least one subordinate signal, that of the same kind and opposite in its phase to the subordinate signal in the first composite signal, c) a third channel for transmitting a third composite Signal that has a third predominant signal and at least one subordinate signal contains, and with d) a fourth channel for transmitting a fourth composite Signal comprising a fourth predominant signal and at least one subordinate signal, that of the same type as the subordinate signal in the third composite signal and in its phase is opposite to this, characterized by: e) a first variable mixing device between the first and the second channel for mixing the first and the second composite signal is switched on with each other to the subordinate ones contained therein Delete signals depending on an existing control signal, f) a second variable mixing device between the third and fourth channels for mixing the third and fourth composite signals nL connected to one another is to control the subordinate signals contained therein as a function of a second control signal to delete, and through 209885/0957 - 28 - 2/2 ^ ' ^Ί ?. ^Q. g) a Schalteinrichtimg for generating the first and second control signal by comparison with at least two of the first to fourth composite signals. Multi-signal transmission device with: a) two input connections for receiving two respective composite input signals, the respectively contain at least three different signals, b) a device connected to the two input connections for converting the two composite input signals into first, second, third and fourth composite output signals, the Output signals or a predominant signal component a and two subordinate signal components c and d, a predominant signal component b and two subordinate signal components c and d, a predominant signal component c and two subordinate ones Signal components a and b and a predominant signal component d and two subordinate signal components have a and b, c) means for the phase of the first and second composite output signals so in position bring that it is in antiparallel with respect to the subordinate signal components of the same kind, d) means for the phase of the third and fourth composite output signals so in position bring that it is in antiparallel with respect to the subordinate signal components of the same kind, e) a first, a second, a third and a fourth channel for the transmission of the first, the second, of the third and fourth, 'composite output signal, respectively, and with f) means to phase the respective composite output signals so in position bring that the phases are more appropriate in the ■ 203888/05 57 INSPECTED -29- ^ 2235? 38 prevailing signals contained in set output signals are in phase with each other by: g) a first variable mixing network connected between the first and the second channel, h) a second variable mixing network connected between the third and fourth channels, and by i) a control circuit for generating at least one control signal of a first and a second control signal, which is to be fed to the corresponding variable mixing networks, whereby the variable MischnetzwBrke two composite output signals mix to the subordinate signal components of the same kind depending on the predetermined control signals to delete. 8. Multi-signal transmission device which is suitable for receiving a first and a second composite signal Lm and Rm, each of which contains predominant signals Ii "and _Rf in phase with one another and at least two subordinate signal components L, and R, consisting of: a) a circuit device consisting of all-pass phase shift networks and combination networks to derive four output signals containing predominant signal components L ^, R _f , I ^ and R, respectively, marked by: b) a first, a second, a third and a fourth channel for the transmission of the respective output signals, ■ ORIGINAL c) a first and a second variable mixing device, connected between the first and second channels and the third and fourth channels, respectively are to mix the output signals, d) control circuit means for comparing fifth and sixth composite signals; corresponding to the two composite signals and at least one of the first and the second Control signal depending on whether the fifth composite signal is the sixth composite signal exceeds or not, to generate, and through e) a device for supplying the control signal to the variable mixing device for its mixing operation to be controlled in dependence on the control signal. 9. Multi-signal transmission device with: a) a first, a second, a third and a fourth channel for the transmission of a first, a second, a third and a fourth composite signal, the respective predominant signal component a and two subordinate signal components c and d, a predominant signal component b and two minor signal components c and d, one predominant signal component c and two minor ones Signal components a and b and a predominant signal component d and two subordinate signal components a and b contain, b) means for arranging the phases of the first and second composite signals so that they are in phase-antiparallel position with respect to the subordinate signal components of the same type, and with c) means for arranging the phases of the third and fourth composite signals so that 20988b / ü967 they are in phase-antiparallel position with respect to the subordinate signal components of the same type, marked by: d) a first and a second variable mixing network, which are connected between the first and the second channel, respectively, e) a third and a fourth variable mixing network connected between the third and fourth channels are, and through f) a control circuit device for generating first, second, third and fourth control signals and for outputting the corresponding control signals to the associated variable mixing networks that combine a pair of the composite signals depending on the mix corresponding control signals so that the subordinate signal components of the same type are deleted will. Multi-signal transmission device, which is suitable for receiving a first and a second composite signal L ^ and Rm, the respective predominant signals L ~ and R ~ in phase with one another and each contain two subordinate signal components L, and R. in one of the composite signals, which are essentially in a quadratic relationship with the signal components L _{1 and R 1 in the other composite signal, one of the L f} and Rv signals being in phase antiparallel with respect to the respective associated R ^ - or L ^ -components and that / other is in phase with the associated components, consisting of: a) a switching device with all-pass phase shift networks and linking networks to provide a first, BWQQbI a second, a third and a fourth output signal to generate the predominant signal components L _f , R _f , Lj ₃ and R ^ respectively and subordinate signal components 1. and R-, L "and R, L" and R ^ as well as R ~ and L ^ respectively, where the subordinate Signal components in the corresponding output signals are in phase quadrature with one another, b) a first, a second, a third and a fourth channel for transmitting the corresponding output signals and c) a control circuit device, the sum and the Difference in the first and second composite signals compares to at least one of the first and second Generate control signals depending on whether the sum exceeds the difference or vice versa, characterized in that a first and a second variable Mixing device between the first and the second channel and the third and fourth channel respectively connected are dependent on the first with the second output signal and the third with the fourth output signal to mix from the control signal to cancel predetermined subordinate signals. 11. Device according to claim 10, characterized in that the control circuit device means for adding up the two composite signals with each other, means for subtracting the two composite signals, means for rectifying the outputs of the summing and subtracting devices and means for subtracting the rectified ones Have outputs. 209885/0957 ee rse