DE2328317C2 - System for the transmission of broadband music and / or voice signals - Google Patents

Description

The invention relates to a system for transmitting Breltbandigen music and / or speech signals according to the preamble of claim 1. In the DE-OS 08 805 Is a system for the transmission of Breltbandigen Sound signals have been proposed in which at the input of the system the sound signal in a lower and a higher frequency range is subdivided and the partial signal of the lower frequency range is transmitted directly in which instead of the partial signal of the higher frequency range the amplitude information of the but averaged frequency subranges created by splitting this frequency range by means of bandpass filters in which the amplitude information of the frequency subranges is used to reproduce the overall signal as a modulation signal for substitute signals located approximately in the middle of the individual frequency control areas serve and in which these synthetic sound signals of the frequency control area of the higher frequency range with the directly transmitted partial signal of the lower frequency range can be added.

The main patent 23 28 316 is a further development the display page of such a system. The synthetic sound signals of the frequency distribution area of the higher frequency range are modulated with narrowband noise. This will make the Sound quality Usually improved significantly. In some cases, however, the noise modulation affects it disadvantageous.

The invention is based on the object To be able to make noise modulation dependent on the respective sound event.

This task is solved by a system with the Features according to claim 1.

With a system implemented in this way, it is special favorable if the amplitude value of a harmonic is used as a signal for controlling the degree of modulation The basic frequency of a synchronization signal is used, which is used as a trapezoidal voltage simultaneously with the amplitude information the signals of the sub-bands is transmitted or stored and which has a frequency that corresponds to half the repetition frequency of the sequential transmission of the amplitude information format, well the additional message merely by changing an otherwise subordinate property of the synchronization signal and does not have to be transmitted in a separate time or frequency channel.

Further details and advantages of the invention can be found in the following description of the context can be taken from the embodiment shown with the figures.

Flg. 1 shows the block diagram in a schematic representation for the input of the system using the sequential transmission of the amplitude information and simultaneous transmission of the synchronization signal,

Flg. 2 shows the implementation of a controllable frequency lock,

Flg. 3 shows the block diagram of the playback page in a likewise schematic representation,

Flg. 4 shows an embodiment for the rotating Switch and

Flg. 5 shows the course of voltages over time.

The input terminal 1 in Flg. 1 is the to be transmitted, breltbandlge sound signal supplied. At this terminal 1 is once a low-pass filter 3 is connected, its Bandwidth or cut-off frequency, depending on the qualitative requirements with regard to the audio signal, Im Range from about 4 to 7 kHz. Bandpass filters 4, 5 and 6 and possibly others are not parallel to the low-pass filter 3 shown, switched on, which split the higher frequency range, which does not pass through the low-pass filter 3, into sub-ranges.

This can be done, for example, in the form that

an octave can be divided into 12 subranges corresponding to the semitones of this octave. The filters 4, 5 and 6 are followed by rectifiers 7, 8 and 9, at the outputs of which amplitude information of the individual frequency range, which is dependent on the volume, appears. In the present example, the amplitude information is tapped cyclically one after the other by an electronic, so-called rotating switch 11. The rotation frequency of the switch 11 has the value / 1. With a number η switch terminals 110, the frequency of the sampled values of the amplitude information is accordingly./T = n / 1. The clock generator 51 determines the step frequency JT of the switch 11. The successive amplitude information reaches a modulator 13, in which this amplitude information modulates the pilot frequency emitted by a pilot generator 14. The modulated pilot signal and d * s appearing at the output of the low-pass filter 3 are combined in an addition circuit 17 to form a common output signal 19.

To generate the synchronizing signal transmitted simultaneously, a frequency divider 52 is connected to the clock generator 51, which divides the clock or step frequency JT in the ratio 1: In , this division being carried out so that the divided voltage has a fixed phase relationship to the position of the rotating switch Has. This divided square-wave or trapezoidal voltage is added to the pilot signal as a synchronization signal in the addition circuit 50 via a controllable frequency blocker 521, which will be explained in more detail.

According to the invention with the controllable frequency lock 521 a harmonic, preferably the third harmonic of this synchronization signal is lowered. The measure of Lowering this harmonic is used as a message to control the playback-specific modulation level of the Noise modulation of the substitute signals used there.

According to the invention with the controllable frequency lock 521 single harmonic, preferably the third harmonic of this synchronization signal lowered. The measure of Lowering this harmonic serves as a message to control the actual playback modulation of the Noise modulation of the substitute signals used there.

In Flg. 2 wildly an embodiment of such controllable frequency lock for lowering a harmonic of the synchronization signal reproduced. In it is 52 the frequency divider for generating the synchronization signal and 50 the additon circuit with which the Synchronizing signal is added to the pilot signal. The actual filter consists of a bridge circuit an RC-Tlefpasses and an RC-Hochpasses, which together are dimensioned in catfish known per se are that the harmonic to be lowered is completely suppressed. Parallel to this filter network is the Series connection of a changeover switch and various resistors, through which the action of the filter is gradual Is rendered ineffective in different stages. Of course it is possible instead of the switch and the fixed resistors also use a continuously adjustable potentiometer.

At the input terminal 22 in Fig. 3 is the transmitted Total signal that is made up of the directly transmitted sound signal of the lower frequency range and the Pllotslenal consists of the AmDlltudenlnformatlo-

The sub-ranges of the upper frequency range are modulated and lowered by a factor of P compared to the audio signal of the lower frequency range and contain the synchronization signal, the amplitude of which is very 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 reproduction has a bandpass filter ι 24, which only lets through the frequency range of the pilot signal and which is followed by a demodulator 25. The demodulated sequence of the amplitude infinite signals is fed to the rotating switch 27, from whose "contacts" the volume information assigned to the individual channels is taken and fed to the storage capacitors 28, 29 and 30 and other storage capacitors (not shown). The volume information of the individual channels is sent from the storage capacitors to the modulators 31, 32, 33 and following, which in turn modulate the signals of the oscillators 34, 35 and 36, which generate the substitute frequencies for the respective subrange. The synchronization signal is evaluated in such a way that the entire output signal of the demodulator 25 is fed to a symmetrical, multiple-catalytic mixer 53, at the second input of which the output signal of a frequency plate 54 is available. This frequency divider 54 divides the frequency of the clock generator 55 like the frequency plate 52 in the ratio 1: In. In the synchronized state, the direct voltage component of the output voltage of the multiple-cat mixer 53 thus only depends on the phase difference between the synchronization symbol and the downgraded signal. So it is B. positive with positive phase deviation. With the following low-pass filter 56, which has a bandwidth of approximately 0.5 Hz, this direct voltage component is separated from the essential higher-frequency alternating components. In the non-synchronized state, instead of the direct voltage, an alternating voltage is generated in accordance with the frequency deviation, which in the present case should not, however, notably exceed 0.5 Hz. The clock generator 55 is synchronized with the screened voltage.

To evaluate the amplitude information of the amplitude on the recording side with the controllable Frequency lock 521 lowered harmonic of the synchronization signal is in a second frequency divider 552 the clock frequency of the clock generator 55 down to a frequency that of the beireffenden harmonic of the synchronization signal. This reference voltage obtained in this way is used in a multiplicative mixer supplied, which is additionally supplied with the pilot signal containing the synchronization signal. The output voltage This multi-functional mixer is screened with a very narrow-band, low-pass filter 553. the The bandwidth of this filter 553 is advantageously less than the bandwidth of the low-pass filter 56. The The amplitude of the voltage emitted by the filter 553 is proportional to the amplitude of the harmonic generated by the Frequency lock 521 on the transmitter side is still allowed through. This voltage, which is used as a control signal, is is fed to an attenuator 554 which lowers the noise voltage of the noise generalor 372 as much as it does for quality reasons on the receiving body by setting the frequency lock 521 z. B. from a sound engineer was selected. The noise voltage weakened on this catfish is in its bandwidth in a low-pass filter 555 and a noise

10

15th

20th

30th

modulator 373 supplied, in which the total signal of all Substitute signals, which were generated in the addition circuit 371, additionally modulated with this noise will. 564 Finally, is an addition circuit, In the total signal of the substitute signals processed in this way with the transmitted Tellslgnal of the lower frequency range is added.

Because the phase relationship between the 3rd harmonic of the synchronization signal and that of the frequency table 552 output reference voltage must be such that in the synchronized state behind the Filter circuit 553 the full amplitude of the 3rd harmonic appears are in Flg. 4 the details the frequency plate 552 and 54, as well as the clock generator 55 and the rotating switch 27 are shown.

In Flg. 4 is an embodiment of the rotating Switch in electronic. 6 channel construction shown; 60 therein is a five-stage shift register whose outputs 601 to 605 via the NOR gate 61 with his Input 600 are connected. The shift register is incremented by the clock generator 55. As a result the reaction of the outputs via the NOR gate 61 on the input 600 is achieved that in each case only either a control pulse appears at input terminal 600 or output terminals 601 to 605, with which the individual switches 62 to 67 of the rotating Switches can be switched one after the other. The storage capacitors are located at the outputs of these switches 68 to 73, which in their function the memories 28 to 30 in Flg. 3 correspond to the outputs of the modulators of the individual channels, e.g. 31 to 33 in Flg. 3, can be controlled.

To generate the reference signal for the multiplicative mixer 53, which is to be compared with the synchronizing signal, the clock, which is divided down relative to the clock frequency ^ ⁵ JT in a ratio of 1: 6, is again 1: 2 at the output of the NOR gate 61 with a flip-flop 74 divided. The voltage with the frequency divided in this way is the reference voltage for the synchronization. The synchronization signal is contained in the pilot signal which is fed from the demodulator 25 to the multiplicative mixer 53. The function of the frequency divider, denoted by 54 in FIG. 3, is fulfilled by the frequency division by means of the shift register 60 and by the frequency division of the flip-flop 74 in a ratio of 1: 2.

The frequency plate 552 of Flg. 3 is in Fig. 4 through the flip-flops 741 and 742 realized. MH these flip-flops the clock frequency / Γ in a ratio of 1: 4 divided.

The phase of the reference signal thus obtained for the multiplicative mixer 551 must be identical to that Phase of the 3rd harmonic of the synchronization signal. To achieve this phase relationship, the output voltage is of the flip-flop 74 via a monostable multivibrator 743 to the set inputs of the fllp-flops 741 and 742 supplied.

In Fig. 5 is denoted by α the profile of the voltage of the clock generator 55 with the frequency / T, with b the profile of the reference voltage which is fed from the flip-flop 74 to the muscular mixer 53 is designated. The curve c is the synchronization voltage with the frequency / syn contained in the pilot signal, which in the synchronized state is phase shifted by 90 ° with respect to the reference voltage with the frequency / sy «and at this phase position offers a control voltage of 0 V via the Slebglled 56 to the clock generator 55 . With d is the course of the 3rd harmonic contained in the rectangular synchronization signal and the curve e is finally the one in Flg. 4 reference voltage output by the flip-flop 742 to the multiplicative mixer 551 with the frequency 3 fsyn. The special choice of resetting the two flip-flops 741 and 742 with the monlable multivibrator 743 ensures that the phase relationship between the voltages according to curves e and d is 0 or 180 ° and not a phase shift of 90 ° between the two signals occurs. It is thereby achieved that the output voltage of the sieving element 553, with which the output voltage of the multiplicative mixer 551 is sieved, is proportional to the amplitude of the 3rd harmonic according to the course / In Flg. 5.

Reference symbols used

60

1 Input terminal 3 Low pass filter 4,5,6 Band pass filter 7.8.9 Rectifier U rotating switch Ul Distributor UO Clamp 112 exit 13th modulator 14th Pilot generator 17th Addition circuit 19th Overall signal 22nd Input terminal 24 Bandpass 25th Demodulator 27 rotating switch 271 Distributor 28, 29, 30 Capacitor (storage) 31,32,33 modulator 34, 35, 36 oscillator 371.564 Addition circuit 372 Noise generator 373 modulator 42 speaker 50 Addition circuit 51 Clock generator 52 Frequency divider 521 Controllable frequency lock 53, 551 multiplier mixer 54, 552 Frequency divider 55 Clock generator 56, 553 Low pass 554 Attenuator (modulator) 555 Low pass 60 Shift register 600 Input terminal 601-605 Output terminal 61 NOR gate 62-67 counter 68-73 Storage 74, 741, 742 Flip flop 743 monostable multivibrator

For this purpose 4 sheets of drawings

Claims (2)

Patent claims: 1. System for the transmission of music and / or speech signals with a reduced amount of breltband Transmission bandwidth at which the signals to be transmitted senderseltlg In a lower and an upper The frequency band is split up and the upper frequency band is still divided into a number of sub-bands is, of which the amplitude information is obtained by rectification and this by means of a Sampling switch are scanned cyclically, then a subcarrier with the output signal of the Sampling switch modulates and this modulated signal with the lower frequency band to one Total signal is transmitted united to the receiving side, in which there is then a low-pass filter and a Bacd pass filter is fed, the output signals of the Bandpass filter are demodulated by means of a demodulator and that of the transmitter-side cyclic Amplification information sequence corresponding demodulation product supplied to the rotor of a distributor whose stator contacts the amplitude information corresponding to the individual sub-bands on the transmitter side taken and stored in memories, whereupon the amplitudes of the signals The output signals are set by the stored values using modulators from overtone generators these modulators and the output signal of the low-pass filter to the inputs of an additon circuit applied and the output of the same the restored Breltband music and speech signals are taken, with a playback side in which a first noise modulator of the addition circuit to improve the sound quality is connected upstream, one input of which is a narrowbandlges Noise signal is fed from a noise generator and at its other input the output signals from further modulators of the overtone generators apply, according to PS 23 28 316, characterized in that on the playback side at the Modulation of the signals of the sub-bands with the output signal of the noise generator (372) the degree of modulation is controlled that as a criterion for the control a transmitted from the receiving side Signal is evaluated and that on the recording side together with the amplitude information the signals of the partial bands a signal for the control the degree of modulation is sent. 2. System according to claim 1, characterized in that the amplitude value of a harmonic is used as a signal for controlling the degree of modulation Basic frequency of a synchronization signal is used, which is a trapezoidal voltage simultaneously with the Amplltudenlnformatlonen the signals of the partial bands is transmitted or stored and that a frequency which is half the repetition frequency of the sequential transmission of the amplitude information is equivalent to. 60