DE1248094B - Television transmission device with reserve audio channel - Google Patents

Description

Television transmission equipment with reserve audio channel The present The invention relates to a television transmission device with an image signal source and an arrangement for transmitting additional signals in the gaps in the frequency spectrum of the image signals. The device according to the invention is particularly suitable for transmission of television picture and sound signals via a transmission path of limited bandwidth, z. B. in the transmission of image and sound signals from a studio to a remote television station.

The invention is intended to provide a television transmission device which contains a substitute sound channel that is used in the event of interference with the ordinary sound channel can be put into operation and ensures uninterrupted sound transmission. It is already known that one can line-by-line into the gaps in the frequency spectrum transmitted television image signal can nest additional signals. The additional In the known case, signals consist of telegraphic characters. The present invention makes use of this additional transmission facility to provide a television transmission facility to create that is practically insensitive to disturbances of the normal separated Is the sound transmission channel.

A television broadcasting device having an image signal source and with a device for the transmission of additional signals in the gaps in the frequency spectrum the image signals is characterized according to the invention by a converter device for the carrier-frequency insertion of the audio signal into a gap in the frequency spectrum of the image signal on the transmission side and a selective demodulation device for Recovery of the low-frequency audio signal on the receiving side and through a control device which has the effect that in the event of faults in a separate audio channel alternatively, the transmission of the into the gap in the frequency spectrum of the image signal falling carrier-frequency tone signal occurs while at full power level the output power of the Reduced converter device and the gain of the demodulation device accordingly increased so that while largely avoiding image interference operational monitoring of the reserve clay channel is enabled.

The invention will now be explained in more detail with reference to the drawing; where F i means g. 1 shows a block diagram of an embodiment of the device according to the invention, FIG . 2 shows an excerpt from the frequency spectrum of a composite television signal with audio and video signals, as it is in the device according to FIG. 1 occurs, FIG. 3 shows two video signal curves which serve to illustrate the mode of operation of the invention, FIG. 4 is a circuit diagram of a purely exemplary embodiment of a for use in the block diagram according to FIG. 1 suitable box tone generator and FIG. 5 is a circuit diagram of a merely exemplary Ausführungsforin a suitable for use in the block diagram of FIG. 1 Elton shaft receiver.

For the purposes of the present description it is assumed that the invention applies to the connection between a program source, for example a television studio, and a radio station or other device for transmitting the television signal generated in the studio to a desired remote location. This application form of the invention is shown in the block diagram according to FIG. 1 illustrates.

The program source 10 is equipped with any suitable means for generating the audio and video components of a television signal. The image component is transmitted to the transmission system 12 via a connection illustrated by the line 11. The line 11 can be any device suitable for transmitting an image or video signal, for example a coaxial cable of conventional design and mode of operation. As indicated by the dotted line section, the connection represented by the line 11 can also include a wireless transmission device, for example a microwave relay system.

According to the invention, the sound component is sent from the program source 10 via a connection indicated by the line 14 to a converter or box tone generator 13 . In one embodiment of the invention, the generator 13 is set up in such a way that it converts the audio signal fed to it into a single sideband signal of a predetermined carrier frequency. The single sideband signal is sent from the generator 13 via a connection indicated by the line 15 into the line or connection 11 and there combined with the video signal. The carrier frequency of the single sideband signal generated in the generator 13 and sent into the line 11 is set so that a composite signal or a composite oscillation appears in the line 11 , in which the single sideband sound signal is nested in the space between two predetermined adjacent energy bundles of the image signal.

The composite signal is fed to the transmitter system 12 via the line 11. There is an image transmitter which picks up the image signal received via the line 11 and transmits it to a remote location via the antenna 16. A portion of the composite signal sent via the line 11 is fed to a demodulation device or a box tone receiver 17 via connections indicated by the line 18. The box tone receiver 17 converts the single sideband tone signal present in the received composite vibration back into the original Toasigual originating from the source 10. The audio signal is fed to the audio transmitter of the transmitter system 12 via connections indicated by the line 19 and the switch 20. The sound transmitter transmits the sound signal via antenna 16 or other suitable device to the remote Oe. Instead of the transmitter 12 shown also any other suitable Vorricbtungen can be used for transmission or recovery of the sound and Bildsignate.

The usable energy of the television signals is generally in the frequency range of 30 Hz to about 4.2 MHz. DAS in the image scanning generated video signal has a power spectrum having spectral lines in a harmonic relation to the horizontal and vertical scanning frequency are .. Assuming that the hvrizo-Ntale sampling frequency amounts to 15 750 Hz, the video signal appears in, the form of energy beams, the centers of which each are at multiples of 15,750 Ilz, with sidebands at different multiples of the vertical scanning frequency. Between the individual bundles of energy there are Lückeri, which are largely free of video energy.

In Fig. 2 shows part of the frequency spectrum of a characteristic Md or video signal. While only the 112th, 111, 114th and 115th harmonics are shown here, one can easily get an idea of the remaining part of the with the aid of the excerpt shown. specified frequency range of the video signal. 266 harmonics of the time frequency encompassing Make the frequency spectrum of the image signal. How one sees, are located between the around the corresponding corresponding harmonic frequencies packed video bundle energy gaps in which the video energy is minimal. There are hundreds of such inter- valle between the video energy bundles, and one or more of these loopholes may be known for Message transmission purposes are used. Tests have shown, however, that certain Places in the video spectrum are particularly favorable. The bundles of energy at lower harmonics of 15 750 Hz, for example on the order of a few hundred kilohertz, as it turns out, generally has larger amplitudes than those for harmonics in the MHz range. This means- that in itself near the top of the Vidte- frequency range the most favorable point for the intermediate nesting of Tonsignakn would be. Important However, there are reasons against setting the tone To place too high a frequency range. Durcb & e Interleaved audio when the frequency is too high can the with the stable half of the device exacerbate the problems associated with this. Fem " would be the consequence of fluctuations in the tax shifting fluctuations occurring due to the mains frequency in the synchronization generator to bdxä £ htlk # h «So- then poor transmission properties For example, coaxial cables make the tour components get lost. At frequencies Ym about 515 kHz, 142U kHz and 1860 kHz duration Conducted comparative tests have shown that the best overall results in the field of HöeJ "bm of the three frequencies mentioned above. After the for Tonzwischenschachte- ment im, image signal best approximate Freq.uewl * W has determined, it is still necessary to find the cheapest NiodK- lation type for the in-between km tone au # to make resourceful. Frequency modulation would be, in itself possible, but in this case the ratio & - moderately narrow width of the gaps between the individual bundles of video energy, and in the case of frequency modulation, the voUe is always transmission level required, regardless of whether the There are peaks or pauses in the sound program. GewöhnEche amplitude modulation would be from um- unsuitable for any reason. Amplitude modulation with a suppressed carrier would be cheaper in this respect, than during any breaks. in the Tofflogaram kdo Intervention in the video message takes place and the signal-to-noise ratio in the produced sound is better. On the other hand, the Required bandwidth twice as large as with one Single sideband system. From this it results] &, dall da Single sideband system with suppressed carrier sichm decisive advantages. A dexartigu System requires the comparatively righteous FV (-. frequency bandwidth and therefore allows the largest & det possible tolerance for any Verhageruagen TV sync generator frequency and dax from consequent founding publishing houses of the B "nergiever.Un- lung. Furthermore, one can use stabilized transmission and developing reception facilities that are easier and work more reliably than, cleverly those institutions that ei w # Uiiter & üzk-ung, you Synchronization generator pulses. the Reintroduction of the carrier # is not phase »- dependent, as it is with one; Double sideband system with suppressed carrier is the case, and ultimately the best overall signal-to-noise ratio for the sound can be achieved without impairing the picture.

For the purposes of the present description, it will be assumed that, taking into account the factors set forth above, it has been found that the best results in a given application are to be obtained by interleaving the audio signal at a frequency of approximately 1785 kl-1z, i. H. in the region of the 113th to 114th harmonics of the horizontal scanning frequency. Gaps in the video energy band are found with the center at all odd multiples of half the horizontal scanning frequency or at 15750/2 times any odd whole number. If you know the desired working frequency of around 1785 kHz, you get 227 as a suitable odd integer. The given multiplication by this number shows that the desired gap center is 1787 625 Hz (assuming that the synchronization generator is controlled at 60 Hz will). Mains frequency measurements have shown a maximum fluctuation of 0.1%. Furthermore, the calculation of the frequency deviation of the color synchronization generators from the generator controlled at precisely 60 Hz shows that their frequency deviates by Or, 1 II / o to lower values. In one embodiment of the invention that has been tested, it has been decided to place the middle of the audio frequency band in the middle between the frequency values of the corresponding harmonic, of the color synchronization generator and that of the 60 Hz-controlled synchronization generator, although occasionally the black and white values up to about 0 .05 1 / o, above the normal value. Correspondingly, one divides 0.10/0 from 1787 625 Hz by 2 and subtracts the result 894 Hz from 1787 625 Hz. This gives 1786 731 Hz as the desired band center frequency for the audio signal interleaved in the video signal.

The current standard tone spectrum ranges from 120 to 4200 Hz, and its maximum energy is grouped on average around 500 Hz. However, this energy center is not the only factor to consider when determining the most favorable interleaving frequency, as the high tone frequencies are emphasized and occasionally cause the highest peak levels. One therefore takes 1000 Hz as the center of the audio frequency band. Assuming that single sideband tone modulation, specifically the upper sideband, is used, the result for the single sideband carrier before it is suppressed is a frequency that is around 1000 Hz below 1786 73 1. Hz, i.e. H. a frequency of 1785 731 Hz.

In the case of the in FIG. 1 and 2, the box generator 13 generates a single sideband signal from the audio signal supplied by the program source 10 , the center of which is 178673-1 Hertz. This single sideband signal is combined with the image signal supplied by the program source 10 via the line 11, see above that a composite signal as shown in FIG. 2 shows. The sound components are interleaved in the gap between the video bursts of the 113th and 114th harmonics. The box tone receiver picks up the single sideband tone signal from the composite signal and delivers the tone signal in the original form generated by the program source 10 to the tone transmitter 12.

As in Fig. 2, the amplitude of the sound components is noticeably larger than the amplitude of the neighboring video bundles in order to achieve a favorable signal-to-noise ratio, although the Diagranim does not claim to represent these relationships on exactly the right scale. However, if you combine all the video bundles, as z. B. with a voltage measurement of. When peak-to-peak is the case, the audio components are only a small fraction. The complete video signal curve as seen on a CRT is shown in FIG. 3 shown. F i g. 3 a part of a single scan line, under normal conditions, while F i g. 3 b shows the same line excerpt additionally with tone interlaced according to the invention. It can be seen that the audio signal amplitude is approximately 5 % of the total amplitude. After transmission over a long line or, for example, over a radio relay link, the audio carrier oscillations on the synchronization pulses have generally disappeared.

In describing the invention it has been assumed that the audio signal should be interleaved in the form of a single sideband signal. A circuit diagram of a single sideband signal generator which is suitable for use as generator 13 in the block diagram according to FIG. 1 is suitable in FIG. 4 shown. Assuming that the upper sideband of a single sideband signal is to be used with an uncrushed carrier, the circuit has a local oscillator, for example a crystal oscillator 25 with an operating frequency of 1785 731 Hz. The output oscillation of the oscillator 25 is fed to the control grid of a weakly amplifying or isolating amplifier tube 26 via an RC network consisting of a capacitor 27 and the resistors 28, 29 connected in series to ground. In the context of the present description, the term "ground" is intended to mean a point of fixed or unchangeable reference potential. The cathode of the tube 26 is connected to the junction of the resistors 28 and 29 via a resistor 30 . The braking grid of the tube 26 is connected to ground. The anode of the tube 26 is connected to the positive terminal 31 of a direct voltage source of 150 V, for example, via a working circuit consisting of the primary winding 32 of an input transformer 33 and a resistor 34. The screen grid of the tube 26 is connected to the terminal 31 via the resistor 34 and a network consisting of the resistor 35 and the bridging capacitors 36, 37 connected to ground.

The tube 26 is biased in the manner described so that it is normally conductive. The vibrations generated in the oscillator 25 are amplified in the tube and then fed to the winding 32 of the transformer 33-. The transformer 33 has two secondary windings 38, 39. One end of the first winding 38 is connected to ground via the capacitor 41, while the other end is connected to the grid of a triode 43. One end of the second winding 39 is connected to ground via the capacitor 44, while the other end of the winding 39 is connected to the grid of a second triode 45. A resistive load element, consisting of the series connection of two resistors 46, 47, bridges the windings 38, 39 between the grids of the tubes 43, 45. A grid bleeder resistor 48 is connected between ground and the connection point of the resistors 46, 47. A variable capacitor 49 with a bridging fixed capacitor 50 is connected between the grids of the tubes 43, 45; it is used to tune the input voltage of the tubes 43, 45.

An example from a program source 10 according to FIG. 1 sound signal is routed to input terminals 51, 52 via the connections indicated by line 14. One side of the input is connected from terminal 51 via a contact arm of a two-pole input switch 53 with three switch positions and contact 2 of switch 53 and a capacitor 54 to the connection point between winding 38 and capacitor 41. The other side of the input is connected from the terminal 52 via the second contact arm and the contact 2 of the switch 53 as well as via a capacitor 55 to the connection point between the second winding 39 and the capacitor 44. The cathodes of the tubes 43, 45 are connected to one another via a compensation resistor 56, the adjustable tap of which is connected to ground via a resistor 57. The anodes of the tubes 43, 45 are directly connected to one another and connected together via a resistor 59, a FIF bypass capacitor 60 and a resistor 61 to the positive terminal 58 of a direct voltage source of 150 V, for example.

From the foregoing it will be seen that the tubes 43 and 45 form a symmetrical modulator of conventional design and operation. The audio signal supplied via the terminals 51, 52 and the HF signal supplied by the oscillator 25 are both coupled to the grids of the tubes 43, 45 either in phase or out of phase (push-pull). The resistor 56 is set so that the carrier frequency energy at the output is minimally small and consequently only the sum and difference frequencies resulting from the activity of the modulator appear at the modulator output. The resulting output frequencies are fed from the anodes of the tubes 43, 45 via an RC element, consisting of a coupling capacitor 63 and a grid resistor 64 connected to ground, to the control grid of an amplifier tube 62 .

The cathode of tube 62 is connected to ground through a bias resistor 65. The anode of the tube 62 is connected via two resistors 71, 72 to the positive terminal 70 of a - connected DC voltage source. The screen grid of the tube 62 is connected to the terminal 70 via an RC network consisting of a grounded capacitor 73, a resistor 74, a grounded capacitor 75 and the resistor 72 . The tube 62 is biased in the manner described so that it normally conducts. The resulting amplified signal is passed from the anode of tube 62 through a capacitor 76 to a single sideband crystal filter 77 which is connected to ground.

The filter 77 only lets through one of the sidebands fed to its input. It was assumed that the upper sideband should be used in the present case. Accordingly, the filter 77 is sized so that it blocks the carrier and the lower sideband frequencies and only allows the upper sideband to pass. Such crystal filters with such a characteristic are commercially available, so that a detailed description of their design and mode of operation is unnecessary. If one wanted to utilize the lower sideband, one would have to use a filter 77 which only allows the lower sideband to pass through.

The upper sideband is fed from the filter 77 to the control grid of an amplifier tube 79. The control grid of the tube 79 is connected to ground via a resistor 80 and the contact arm 81 and the contact 82 of a relay 83. For the moment it will be assumed that the winding 84 of the relay 83 is energized by a power source such as a battery 86 through a closed on-off switch 85 , thereby bringing the contact arm 81 into contact with the contact 82 , as in FIG is shown in the drawing. The cathode of the tube 79 is connected to ground via a resistor 87 and the contact arm 81 and the contact 82 of the relay 83. The braking grid of the tube 79 is also grounded. The anode of the tube 79 is composed, connected via a working circuit of a resistor 89, one lying on 'grounding capacitor 92 and a parallel tuned circuit including a variable inductor 90 and a capacitor 91 to the positive terminal 88 of a DC voltage source, for example, 150 V. The screen grid of the tube 79 is connected to the terminal 88 via an RC network consisting of a grounded capacitor 93, a resistor 94, the capacitor 92 and the resistor 89 . The anode of the tube 79 is tuned by the coil 90 to approximately the center of the upper sideband signal. The anode of the tube 79, at which the amplified upper sideband signal appears, is connected to a working circuit consisting of a capacitor 95, a resistor 96 and a resistor 97 connected to ground.

The resistor 96 has a variable tap connected to the control grid of a power amplifier tube 98. The cathode of the tube 98 is connected to ground via a resistor 99. The braking grid of tube 98 is also grounded. The anode of the tube 98 is connected via resistors 101, 102 to the positive terminal 100 of a direct voltage source of 150 V, for example. The screen grid of the tube 98 is connected to the terminal 100 via an RC network consisting of a capacitor 103 connected to ground, a resistor 104, a capacitor 105 connected to ground and a resistor 102.

The output of amplifier tube 98 (the amplified upper sideband tone signal) is fed from the anode of tube 98 via the circuit shown in FIG. 1 through the line 15 indicated connection with a capacitor 106 and a resistor 107 coupled into the image line 11 shown as a coaxial cable. The high impedance in the form of the resistor 107 serves to bridge the single sideband signal generator on the video coaxial cable 11.

If the circuit arrangement according to FIG. 4 is in operation, a composite signal in accordance with F i g in the cable or in the cable. 11 2 formed. The single sideband sound signal is interposed in the gap between the video signal bursts corresponding to the 113th and 114th harmonics. The output signal level of the generator is adjusted with the aid of the resistor 96 to the level desired for the sound transmission in the video line. As in connection with F ! G. 3 , satisfactory results have been obtained by setting the audio signal level to approximately 5% of the measured peak-to-peak composite video level. Under these conditions, video monitors and receivers show a pattern during the modulation peaks that is slightly less visible than the cross-hatched pattern that occurs as a result of color transfer on a black and white monitor. If the sound level is low, the video signal is not affected.

A circuit diagram of a box tone receiver which is suitable for use as a receiver 17 in a device according to FIG. 1 including the box tone generator according to FIG. 4 is shown in FIG. 5 shown. The recipient is through the in F i g. 1 as line 18 indicated connections with the series connection between ground and the cable 11 of a capacitor 108 and a resistor 109 coupled to the cable or the line 11. The resistor 109 has a variable tap which is connected to the control grid of an amplifier tube 115 via a resistor 110 . The retarding grid of tube 115 is connected to the cathode of this tube. The cathode in turn is connected to ground via an RC element consisting of the capacitor 119 and the resistors 116, 118. The anode of the tube 115 is connected to the positive terminal 120 of a direct voltage source of 150 V, for example, via an RC element consisting of a resistor 121, a capacitor 122 connected to ground and a resistor 123. The screen grid of the tube 115 is connected to a capacitor 124 connected to ground and via resistors 125, 123 to the terminal 120.

The tap on resistor 109 is used to regulate the input level; it is set so that the correct operating level for the amplifier tube 115 results. The amplified image and single-sideband audio signals are conducted from the anode of tube 115 through a capacitor 127 to a crystal filter 126 connected to ground. The design and characterization of the filter 126 are the same as for the filter 77 in the generator according to FIG. 4; the filter is sized to allow the upper sideband to pass through. The interposed audio signal coupled into the image line 11 therefore passes through the filter 126 and via a capacitor 128 to the control grid of an amplifier tube 129.

The control grid of the tube 129 is connected to ground via an RC network consisting of a resistor 130, a grounded capacitor 131 and resistors 132, 133 . The cathode of the tube 129 is connected to ground via a resistor 134. The braking grid of the tube 129 is connected to ground. The anode of the tube 129 is connected to the positive terminal 135 of a DC voltage source via a working circuit consisting of a resistor 136, a grounded capacitor 137 and a tuned parallel circuit with a variable inductance 138 and a capacitor 139. The screen grid of the tube 129 is connected to the cathode via a resistor 140 and to the terminal 135 via an RC network consisting of a grounded capacitor 141, a resistor 142 and the resistor 136 . The anode of the amplifier tube 129 is tuned to the center of the upper sideband with the aid of the coil 138.

The adjusted output signal of the amplifier 129 is fed to a demodulator stage with a multigrid tube 143. For reasons of convenience, the individual grids of the tube 143 are designated below with the numbers 1 to 5, specifically in the direction from the cathode to the anode. The cathode of tube 143 is grounded. The first grid is coupled to the output of a local oscillator 144 via an RC network consisting of a grounded resistor 145 and a capacitor 146. The oscillator 144, for which a crystal oscillator of the same design and mode of operation as the local oscillator 25 in the generator according to FIG. 4 is set to provide vibrations of the same carrier or RF frequency, namely 1785 731 Hz. The third grid of the tube 143 is coupled to the tuned anode of the tube 129 via a capacitor 147 and a series circuit, connected to ground, having an inductance 148 and a resistor 149. The fifth grid of the tube 143 is grounded. The anode of the tube 143 is connected to the positive terminal 150 of a direct voltage source of 150 V, for example, via a working circuit consisting of a grounded capacitor 151 and resistors 152, 153. The second and fourth grids of the tube 143 are common to the terminal via an RC network consisting of the grounded parallel connection of a capacitor 154 and a resistor 155, a resistor 156, a grounded capacitor 157 and the resistor 153 150 connected.

The capacitor 151 removes the high frequency or local oscillator frequency; it is large enough to take away some of the higher audio frequencies. The function of the capacitor 151 is to limit the upper end of the audio frequency band in such a way that interference with the sound from the edge regions of the video bundles adjacent to the interleaved sound components in the composite signal passing through the line 11 is avoided.

The audio frequency signal resulting from the beating of the local oscillator frequency with the received single sideband tone signal is transmitted from the anode of the demodulator tube 143 via a working circuit consisting of a capacitor 159, a resistor 161 connected to ground and a series circuit connected to ground with a resistor 160, a capacitor 165 and an inductor 166, coupled to the grid of an amplifier tube 158. The tuned serial circuit just described serves to cut the response characteristic in the areas where excessively high amounts of energy would occur as a result of imperfections in the transmission characteristic of one of the filters 77, 126 or both filters.

The cathode of the audio amplifier tube 158 is connected to ground via a resistor 167. The anode of tube 158 is coupled to the control grid of a second or audio amplifier tube 168 through a capacitor 169 and a resistor 170 connected to ground. The anode of the tube 158 is also connected via a resistor 172 to the positive terminal 171 of a direct voltage source of 150 V, for example. The amplified audio signal is passed from the first audio amplifier 158 to the second amplifier 168 for further amplification. The cathode of the second audio amplifier tube 168 is connected to ground via a resistor 173. The retarding grid of tube 168 is connected to the cathode. The anode of the tube 168 is connected to the terminal 171 via the primary winding 174 of an output transformer 175 . The screen grid of the tube 168 is connected directly to the terminal 171 . The amplified audio frequency or tone signal appears in the form as it was originally provided by the programmer source 10 in FIG. 1 was delivered to the secondary winding 176 of the transformer 175 and can there via output terminals 177, 178 and through the line 19 in FIG. 1 indicated connections are fed to the sound transmitter 12 or other suitable devices.

In order to reduce the distortion factor and the output impedance, between the sound amplifier tubes 158, 168 in FIG. 5 two negative feedback branches before seen. The first negative feedback branch is formed by a resistor 179 connecting the anode of the tube 168 to the output of the tube 158 and serves to reduce the gain of the second amplifier tube 168. The second negative feedback branch leads from the anode of the tube 168 via a capacitor 180 and a resistor 181 to the cathode of the tube 158; it serves to reduce the gain of the entire sound amplifier.

In order to obtain the best possible signal-to-noise ratio, the audio signal from the program source 10 is coupled into the box tone generator with the aid of an automatic tone gain control (compressor). In order to partially reverse the effect of the compression circuit at the generator input and at the same time to increase the signal-to-noise ratio, an expansion circuit is provided on the receiver side. Part of the amplified sound signal appearing at the anode of the tube 168 is conducted to ground via an RC element consisting of a capacitor 182, a resistor 183 and a resistor 184. The resistor 184 has a variable tap which is connected to the connection point of the resistors 132, 133 via a diode or some other device 185 which conducts the current in only one direction. The diode 185 is polarized so that it conducts in the direction of the arrow. The resistors 132 and 133 are, as previously described, in the bias circuit of the amplifier tube 129. During program sections with a high tone level, the fed-back positive voltage increases the gain of the tube 129 . During periods of rest, the apparent signal-to-noise ratio is improved as a result of the reduced gain of the tube 129. Satisfactory results were obtained when setting the tap on resistor 184 to a value such that the expansion or spreading circuit dz, with an increase of 8, or about operates from this value obtained.

In the description of the invention it has been assumed that the image and sound signals originating from a program source are transmitted regularly with the means according to the invention via a single video arrangement. However, the invention can also be applied to facilities where the box tone system according to the invention is intended to be used in an emergency. In operating television broadcasting equipment between a program source and equipment such as broadcasting equipment 12, it is common practice to send the audio signals via one conduit, such as a coaxial cable, and the image signals via a second separate path with, for example, a microwave relay system. Such a device is shown in FIG. 1 illustrates. The image signals are sent via the line 11, which, as indicated by the dotted portion may include a Mikrowellenrelais- or otherwise wireless system, while the audio signals via a second 'by the dotted line 186 indicated way are passed. The line 186 can include a coaxial cable or, as indicated by the dotted section, also a microwave relay or other radio system. The switch 20 is normally set so that the path 186 for the audio signals between the source 1.0 and the audio transmitter 12 is free.

If the audio signals are lost as a result of a mechanical or other failure in the line 186 , there is considerable cost and inconvenience for those involved in the maintenance and operation of the entire facility. The invention now provides an inexpensive and extremely expedient method of saving the standard two-channel transmission of the pro-cram transmission in the event of a failure in audio transmission equipment. According to the invention, a box tone generator 13 of, for example, the one shown in FIG. 4 connected between the line 11 and the output of the source 10 . The generator 13 treats the sound signals originating from the source 10 in the manner described in such a way that a composite signal of the type described is provided in the line 11. The example in the in F i g. Way formed Elton shaft receiver 17 shown 5 is connected between the line 11 and the switch 20th

In the description of the circuit according to FIG. 4 the relay 83 in the box tone generator was mentioned. As long as the tone is properly transmitted over line 186 , the generator only operates "on demand" or in standby mode. The switch 85 is open and consequently the winding 84 of the relay 83 is not energized. The contact arm 81 lies on an empty contact 187 of the relay 83. As a result, the cathode and the control grid of the amplifier tube 79 are connected to ground via a second resistor 188. The added value of resistor 188 lowers the gain of tube 79 and thereby lowers the level of the audio signal interleaved in line 11 to such an extent that the audio no longer appears in the image signals running via line 11. A similar relay arrangement is in the receiver of FIG . 5 provided. As long as the receiver is working “on demand”, switch 189 is open and consequently winding 190 of relay 191 is not energized. In this state of the relay 191 , the cathode of the amplifier tube 115 is connected to ground via the resistor 116 and the contact arm 192 and the contact 193 of the relay 191. The resistor 118 in the cathode circuit is short-circuited, so that the gain of the tube 115 and of the entire receiver increases accordingly.

If an error occurs in the audio line or connection 186 , the switch 20 is set to the position shown in FIG. 1 brought the position shown and thereby the sound input of the transmitter 12 is coupled to the output of the box tone receiver. The switch 85 in the generator ( FIG. 4) is closed. The relay 83 occurs in activities and submit the contact 81 to the contact 82. As a result, the resistance is 188 short-circuited in the cathode and control grid circuit of the tube 79 and increases the gain of the tube 79 accordingly. The audio output signal interleaved in line 11 is increased by, for example, 15 dz to the full transmission level. On the receiver side ( FIG. 5) the switch 189 is closed and the relay 191 is thereby activated. The contact arm 192 is connected to an empty contact 194 of the relay 191 . This causes the cathode of the tube 115 to be grounded through the resistors 116, 118 , and the gain of the tube 115 is lowered. Although the switches 85 and 189 are shown as manually operated switches in the drawing, a suitable alarm and automatic switching system with devices for transmitting a control tone or other signal via an auxiliary connection line can also be arranged between the switches, so that the two switches when an error occurs in the line 186 are switched almost simultaneously automatically and thereby the time lost for the sound transmission is kept to a minimum. If tube 79 operates at high gain and tube 115 at low gain with full sound transmission, the result is a signal-to-noise ratio 15 dz better than when operating "on demand".

While the device according to Fig. 1 presupposes two separate inputs, picture and sound, and two separate transmitters for the transmitting device 12, the invention can also be used in connection with an arrangement in which a single transmitter is used for transmitting or otherwise handling the Composite audio and video signals are provided. In such an arrangement, the composite signal is received at a desired remote location with a suitable receiver and passed to a box tone receiver of the type described. The audio signal is recovered in its original form by the box tone receiver and fed to a loudspeaker or other sound reproduction device, while the image signal is fed from the receiver to the cathode ray tube or other image display device.

When operating the box tone system according to the invention, frequent monitoring of the oscillator frequencies is desirable in order to avoid audible distortion. For this purpose, the contact arms of the input switch 53 in the generator ( FIG. 4) can be connected to corresponding contacts 3 of the switch 53 and thus the output of a 120 Hz sound source 195 can be connected to the input of the push-pull modulator 43, 45. The output frequency of the generator can be measured with the help of an accurate frequency meter. If necessary, the frequency meter can be arranged on the receiver side (FIG . 5) . Or you can observe the sound output signal of the receiver with the aid of an oscilloscope and check the accuracy of the 120 Hz tone using Lissajous figures, provided that the oscillation frequency of the oscilloscope is kept constant at exactly 60 Hz. If the generator is not to provide an output signal, the contact arms of switch 53 are connected to empty contacts 1 so that the generator does not receive an input signal.

The invention thus makes a simple and inexpensive one Device for the simultaneous transmission of the audio and video components of a television signal created via a single arrangement.

Claims (2)

Claims: 1. Television transmission device with an image signal source and an arrangement for the transmission of additional signals in the gaps in the frequency spectrum of the image signals, characterized by a converter device (13) for carrier-frequency insertion of an audio signal into a gap in the frequency spectrum of the image signal on the transmission side and a selective demodulation device ( 17) for the recovery of the low-frequency audio signal on the receiving side and by a control device which causes, in the event of interference in a separate audio channel (186), the transmission of the carrier-frequency audio signal, which falls into the gap in the frequency spectrum of the video signal, takes place at full power level, while it takes place at full power level operation of the separate sound channel (186) reduces the output power of the converter means (13) and increases the gain of the demodulation means (17) corresponding such that while largely Vermeidun '- of Bildstörun The operational monitoring of the reserve clay channel is enabled. 2. Device according to claim 1, characterized in that the frequency range of the image signal is between about 30 Hz and about 4.2 MHz and that the carrier-frequency audio signal supplied by the converter device (13) is in a frequency range between 1 and 2 MHz. 3. Device according to claim 1 or 2, characterized in that the converter device (13) supplies a single sideband signal with a suppressed carrier. 4. Device according to one of the preceding claims, characterized in that the converter device (13) is capable of delivering a carrier-frequency audio signal, the amplitude of which is considerably greater than the amplitude of adjacent bundles of energy of the image signal. 5. Device according to claim 4, characterized in that the amplitude level of the carrier-frequency audio signal in the image channel is approximately 50le of the level of the overall signal. Documents considered: German Patent No. 600 042; Austrian Patent No. 178,659; French patent specification No. 843 528.