DE2321230A1 - PROCEDURE FOR TRANSMISSION OF BROADBAND AUDIO SIGNALS - Google Patents

Description

Method for the transmission of broadband audio signals in addition to P 2309 987.8 The invention relates to a system for transmitting broadband Sound signals, in which the sound signal at the input of the system in a lower and a higher frequency range is subdivided and the partial signal of the lower frequency range is transmitted directly, instead of the partial signal of the higher frequency range the amplitude information obtained by splitting this frequency range by means of Bandpasses generated frequency subranges are transmitted in the case of playback of the overall signal, the amplitude information of the frequency subranges as a modulation signal for substitute signals located approximately in the middle of the individual frequency subranges serve and in which these synthetic audio signals of the frequency subranges of the higher Frequency range with the directly transmitted sound signal of the lower frequency range are added, at the input side a pilot signal, which the amplitude information the individual sub-ranges of the upper frequency range contains, in such a positive way is modulated that the amplitude of the pilot signal on a time average by one such a factor P compared to the amplitude of the signal in the lower frequency range is lowered, which represents the so-called perceptibility limit, and at which the amplitude of the synchronization signal is at most equal to the level of the system noise at the is considered for the compatibility and that the receiver or so selectively evaluated the synchronization signal on the playback side will, that the signal-to-noise ratio of the selected synchronization signal is essentially corresponds to the signal-to-noise ratio of the signal in the lower frequency range.

If in such a system, e.g. as part of the application in broadcasting operations the transmission of the pilot signal with the amplitude information contained therein due to interference is adversely affected, it can have the consequence that the reproduced with the receiver Signal instead of the substitute signals of the heights recorded by the transmitter, such substitute signals are added, which modulates with the always-present transmission interference and are thus falsified.

It is therefore the object of the present invention to provide that which was initially described System on the playback side to be supplemented in such a way that a fault occurs in the event of failure Complete absence or excessive deviations in the synchronization frequency of the No pilot signal.

This is achieved according to the invention in that two multiplicative Mixing the pilot signal containing the synchronization signal and a reference signal is supplied, one of the two signals to the multiplicative mixers with a mutual phase shift of 900 and the other signal the two Mixers is fed directly that a voltage is used as a reference signal, the from the clock generator of the rotating switch by frequency division with the division factor 1 2n is derived, where n is the number of switching positions of the rotating switch is that the output voltages of the two multiplicative mixers each with one Low-pass filter that one of the two filtered voltages is used to tune the frequency and thus serves to synchronize the clock generator that the other sieved Voltage when falling below a specified level to switch off the replacement signals and / or as a control voltage for gain control of the pilot signal.

The amplitude of the control voltage for the shutdown is advantageous also used as a control criterion for the gain control of the pilot signal.

According to one embodiment of the invention it is provided that the rotating Switch consists of n individual switches, which one after the other from the outputs of a are controlled in feedback shift registers and from two outputs this shift register, the output signals of which have a time interval of n / 2 Clock pulses to each other, each controlled a frequency-halving flip-flop and from a flip-flop output a connection to the preparation input of the other flip-flops to ensure that the output voltage of the one flip-flops to the other by 900 and that the output voltages of the two flip-flops as reference voltages offset from one another by 900 both multiplicative mixers are fed to which the das Synchronous signal containing pilot signal is supplied.

This design is characterized by the simplicity of the circuitry and easy implementation in integrated circuit technology.

The invention will then be described in connection with the FIGS and Fig. 2 illustrated embodiments.

The transmitted overall signal is present at input terminal 22, the from the directly transmitted audio signal of the lower frequency range and the pilot signal exists, that with the amplitude information of the subranges of the upper frequency range is modulated and that by the factor P compared to the sound signal of the lower frequency range is lowered and that contains the synchronizing signal, des.son- 'amplitude very much small compared to the possible maximum amplitude of the overall pilot signal. Its frequency corresponds to half the repetition frequency of the sequential transmission of the amplitude information.

The device for playback has a bandpass filter 24, which only the Frequency range of the pilot signal and a controllable amplifier 241 and a demodulator 25 is connected downstream. The demodulated sequence of amplitude information is fed to the rotating switch 27, of whose "contacts" the individual Volume information assigned to time channels is taken and the storage capacitors 28, 29 and 30 and other storage capacitors, not shown, are supplied. The volume information of the individual channels is obtained from the storage capacitors to the modulators 31, 32, 33 and the following, which in turn send the signals the oscillators 34, 35 and 36, which are the replacement frequencies for the respective Generate, modulate partial range. 371 is the summing circuit with which the volume-controlled Substitute signals are added.

The substitute signals added in this way are transmitted via a controllable switch 563 fed to a further addition circuit 564 in which the substitute signals with can be added to the directly transmitted signal of the lower frequency range. That Signal that goes to speaker 42 also includes the pilot signal.

Since, according to the prescription, the pilot signal is due to the lowering is inaudible by the factor P and the use of the masking effect, needs it cannot be eliminated by a filter. The rotating switch 27 is controlled by a Clock generator 55 controlled, which the step frequency of the rotating switch 27 determined.

After n steps, the rotating switch 27 has carried out one cycle. With the frequency divider 54, which has a division factor of 1, the clock frequency divided down and 2n the voltage thus obtained to a multiplicative mixer 53 supplied with which the signal coming from 54 with the demodulated pilot signal is compared in the phase. The output voltage of the multiplicative mixer 53 passes through a very narrow-band low-pass filter 56 with, for example, 0.5 Hz bandwidth. By this performed in the multiplicative mixer 53 phase comparison between the divided signal and the synchronizing signal contained in the pilot signal a phase-dependent control voltage arises at the output of the low-pass filter 56, which is used to tune the frequency of the clock generator 55. The ones in the pilot signal contained main message, which is a considerably larger one relative to the synchronization signal Amplitude falls in this processing due to the multiplicative mixing with a reference signal with half the repetition frequency and because of the narrow bandwidth of the low-pass filter 56 out. The control steepness of the synchronization must be so great be that with all occurring frequency deviations between the output signal of the Frequency divider 54 and the frequency of the synchronization signal, the phase deviation in the synchronized state is so low that the assignment of the individual channels by the rotating switch on the receiver side with the corresponding assignment on the sender side. If, for example, 12 channels are transmitted, then occurs a phase deviation of 3600: 12 = 300 a misallocation of a channel. The phase deviation in the synchronization should therefore no longer be expedient as. +100. In addition, the synchronization range should be symmetrical, i.e. the catch and hold area should be in both directions in the event of frequency deviations be about the same size.

Another frequency divider 541 is controlled by the clock generator 55, which also has the division factor 1, but its 2n output voltage is opposite always leads or lags the output voltage of the first frequency divider by 900. How this is realized in practice becomes. explained in more detail in FIG. The output voltage this second frequency divider 541 becomes. in a second multiplicative mixer 531 is also compared with the demodulated pilot signal. Even this multiplicative one Mixer 531 is followed by a low-pass filter 561.

Under the above synchronization condition, the output voltage of the Low-pass filter 561, depending on whether the output voltage of the frequency divider 541 Leading or lagging by 90, positive or negative, with an amplitude equal to that of the im Pilot signal contained synchronizing voltage amplitude is proportional.

Since the amplitude of this synchronization signal is proportional, as is required is the possible maximum amplitude of the entire pilot signal, according to the invention the voltage output by the low-pass filter as a control voltage for readjusting the Amplitude of the pilot signal present at the output of the band filter 24 with the aid of the controllable amplifier 241 can be used. This measure achieves that with fluctuations in the transmission path, e.g. with selective fading in the area the pilot frequency, these fluctuations are considerable due to the regulation described be reduced. In addition, the voltage output by the low-pass filter 561 can be used for Serve control of the switch 563, with which the substitute tones are switched off. For this purpose, this voltage is switched via a threshold switch, in FIG. 2 by a Zener diode 562 indicated symbolically, led. When the threshold voltage is exceeded, the Switch 563 is closed and the substitute tones are thus played back to the loudspeaker reach. If the voltage falls below the threshold, the switch remains open. on this way it is achieved that when receiving broadcasts without a pilot signal or in the event of its failure, the switch 563 remains open, because in this case it is a low-pass filter 561 no voltage (0 V) is output. But also when receiving a pilot signal and synchronization not occurred, e.g.

as a result of incorrect operation of the synchronization circuit or at If the frequency deviation of the synchronization signal is too great, the switch remains 563 open because there is a frequency deviation between the synchronization signal and the reference signal which is so large that synchronization does not occur the difference frequency of the output voltage of the multiplicative mixer 531 is so high, that it is certainly above the cutoff frequency of the low-pass filter. the The cutoff frequency of the low-pass filter 561 should be equal to or less than that as possible of the low-pass filter 56. At the output of the low-pass filter 561 appears under under the assumed circumstances none (0 V) or one below the mentioned threshold value lying tension.

In Fig. 2 is an embodiment of the rotary switch in electronic construction for 6 channels shown; in it 60 is a five-stage shift register, its outputs 601 to 605 are connected to its input 600 via the NOR gate 61 are. The shift register is incremented by the clock generator 55. As a result of the reaction of the outputs via the NOR gate 61 on the input achieved that only either at the input terminal 600 or at the output terminals 601 to 605 a control pulse appears with which the individual switches 62 to 67 of the rotating switch can be switched one after the other. At the outputs of these switches are the storage capacitors 68 to 73, which in their function the memory 28 to 30 in Fig. 1 correspond to the outputs of the modulators of the individual Ranals, e.g.

31 to 33 in FIG. 1, can be controlled. To generate the reference voltages for the multiplicative mixers 53 and 531, the shift register 60 is connected to two Contacts 602 and 605, whose output voltages have a mutual time offset corresponding to n / 2 steps of a cycle have taken voltages. These output voltages are each a clock input of a so-called JK flip-flop 74 and 75 supplied. In order to ensure that the output voltages of the frequency halving JK flip-flops serving always have the same phase relationship, i.e. that e.g. the output voltage of the flip-flop 75 always corresponds to the output voltage of the flip-flop 74 lags behind by 900, the output of the flip-flop 74 establishes a connection to the relevant Preparation input of the flip-flop 75 is seen. The multiplicative mixers The demodulated pilot signal is additionally supplied to 531 and 53, as in FIG. 1 shown.

The time allocation is of course in the pilot signal contained synchronization signal for the time channels for the individual substitute signals The same on the recording and playback side.

In such applications, where one has to deal with larger frequency deviations of the total signal and thus also of the synchronization signal, it is special expedient instead of the multiplicative circuit operating as a phase comparison circuit Mixer 53 to use a "phase and frequency comparison circuit" known per se, or a circuit known per se, in which until synchronization occurs the bandwidth of the downstream low-pass filter 56 is significantly increased and only after synchronization to the originally small area is switched back.

2 claims 2 sheets of drawings with 2 figures

Claims (2)

Claims 9 system for the transmission of broadband audio signals, at the input of the system the sound signal in a lower and a higher Frequency range is divided and the partial signal of the lower frequency range is transmitted directly, instead of the partial signal of the higher frequency range the amplitude information obtained by splitting this frequency range by means of Bandpasses generated frequency subranges are transmitted in the case of playback of the overall signal, the amplitude information of the frequency subranges as a modulation signal for substitute signals located approximately in the middle of the individual frequency subranges serve and in which these synthetic audio signals of the frequency subranges of the higher Frequency range with the directly transmitted sound signal of the lower frequency range are added, at the input side a pilot signal, which the amplitude information the individual sub-ranges of the upper frequency range contains, in such a positive way is modulated that the amplitude of the pilot signal on a time average by one such a factor P compared to the amplitude of the signal in the lower frequency range is lowered, which represents the so-called perceptibility limit, and where the amplitude of the synchronization signal is at most equal to the level of the system noise at the facilities considered for compatibility and that is on the receiver side or on the playback side, the synchronization signal is so selectively evaluated that the Signal-to-noise ratio of the selected synchronization signal is essentially the signal-to-noise ratio of the signal of the lower frequency range, characterized in that two multiplicative mixers <53, 531) containing the synchronization signal Pilot signal and a reference signal is supplied, one of the two signals the multiplicative mixers (53, 531) with a mutual phase shift from 900 and the other signal fed directly to the two mixers is that a voltage is used as a reference signal from the clock generator (55) of the rotating switch (27) by frequency division (54, 541) with the division factor 1 is derived, where n is the number of 2n switch positions of the rotating switch is that the output voltages of the two multiplicative mixers each with one Low-pass filter (56, 561) are filtered that. one of the two sifted tensions for Frequency adjustment and thus used to synchronize the clock generator (55), that the other screened voltage when falling below a predetermined level for Switching off the substitute signals and / or as a control voltage for gain control (24) of the pilot signal is used. 2. System according to claim 1, characterized in that the rotating Switch consists of n individual switches (62 to 67), one after the other from the outputs (600 to 605) of a feedback shift register can be controlled and from two outputs (602, 605) of this shift register, their output signals have a time interval of n / 2 clock pulses from one another; a frequency-halving one each Flip-flop (74, 75) is controlled and a connection from a flip-flop output (74) to the preparation input of the other flip-flop (75) to ensure that the output voltage of one flip-flop increases or decreases by 900 to the other. leads and that the output voltages of the two flip-flops as around 900 against each other offset reference voltages to the two multiplicative mixers. (53, 531) supplied are fed directly to the pilot signal containing the sync signal will.