NL7908569A - METHOD AND APPARATUS FOR CODING AND DECODING VIDEO AND / OR AUDIO SIGNALS - Google Patents

Description

H.o: 28,487 1 _ t

Method and device for encoding and decoding video and / or audio signals.

The invention relates to a pay-TV system and in particular relates to a method and device for encoding and decoding video and / or audio signals.

In particular, the invention aims to provide a subscriber television system in which the video signals are encoded by suppressing the horizontal and vertical synchronization information.

Another object of the invention is to provide a subscriber television system of the type described, in which the synchronizing pulses are suppressed during the horizontal and vertical blanking intervals and clock and address signals are added therein, which signals are used at the receiver to provide a synchronizing pulse. generator.

The invention also aims to provide a subscriber television system of the type described, in which digital audio signals are inserted into the suppressed horizontal blanking intervals and used at the receiver to provide the audio portion of the television signal.

It is also an object of the invention to provide a subscriber television system in which digital audio signals are inserted into the suppressed horizontal blanking intervals to provide either the primary audio signal or other audio channel.

The invention will be further elucidated with reference to the accompanying drawings, in which: Fig. 1 shows a block diagram of the transmission section JO of the subscriber television system according to the invention; and FIG. 2 is a block diagram of the receiving portion co-operating with the transmitting portion of FIG. 1.

The invention relates to a subscriber television vision system in which wirelessly transmitted television signals are encoded at the transmitter, which signals 790 85 69 Λ ti 2 besides the video signal also comprise signals for use in authorizing and authorizing decoding circuits. with the individual recipients. The synchronization pulses at the horizontal and vertical blanking intervals of the video signal are suppressed to about 25% of the original amplitude. The picture will therefore be distorted both horizontally and vertically, and cannot be used at all unless the required decoding equipment is in operation. Clock signals before? operating the synchronization pulse generator in each receiver are inserted in the vertical blanking intervals. In addition, authorization or address signals for authorizing the decoding equipment are also inserted in the vertical blanking intervals. The audio portion of the television signal can be plain text or unencoded. Also, the audio portion may be in digital form and this digital audio information may be inserted in the horizontal blanking intervals. In the latter case, the audio signal is reformed at each receiver, and the audio program is then recombined at the receiver with the decoded video signal. Also, the audio information may be included in the described horizontal blanking intervals to provide another audio channel.

In Fig. 1, the video program signal is fed to line 10 and the audio signal is fed to line 12. The video signal is applied to both the synchronization processor 14 and port 16. The synchronization processor 14 will output various independent signals for use to be explained. The first output over line 18 for gate 16 is used to operate this gate so that the synchronization pulses are suppressed during the vertical interval 35 of the video signal. The signal at the output of gate 16 is therefore the normal video signal in which the vertical interval is suppressed, preferably up to a value of about 25% of the * * Λ

790 8 5 6 S

3 * original amplitude.

The second output signal of the synchronization processor 14 is supplied via the line 20 to the port 22, to the other input of which the video signal 5 is fed from the port 16. The signal present from the synchronization processor 14 at the gate 22 suppresses the horizontal blanking interval to a value of about 25% of the original amplitude. The output of gate 22 is therefore the original video signal in which both the horizontal and vertical blanking intervals are suppressed to about 25% of their original amplitude.

At 24 a clock generator is indicated which can give a clock signal of 3 »58 mhz. An output signal 15 from the clock generator 24 is supplied to the divider circuit 26 which outputs an output signal with a frequency of 31.5 kHz, representing the sound sampling frequency. In order to be able to sample sound with a maximum frequency of 12 kHz, it is necessary to have a sampling frequency of at least 24 kHz.

For a dynamic range of 48 dB, there must be 8 bits, so that the minimum bit rate will be 192 K bits per second. The synchronization frequency is about 15 kHz, and the sampling frequency is at least 25. 24 kHz is determined to combine two noise samples in each horizontal blanking interval. The delay circuit 28 delays every other of the audio samples as from the sub-circuit 26 supplied at the sampling frequency γ, 5 kHz.

50 Therefore, each horizontal blanking interval will have two sound samples. In order to properly reform the audio signal, it will be necessary to decelerate half of the total number of bits inserted in each horizontal blanking interval in the decoding circuit. In practice, it has been determined that per horizontal blanking interval time slot, 24 bits can be used, two of which are 8-bit audio samples and the remaining 8 bits are used for synchronization and control. The signal from the 790 8 5 69 ✓ 4 delay circuit 28 will have a form as described and will form an input signal for the gate 30. The timing input is applied to the other input of the gate 30 from the synchronization processor 14 along line 32, which will result in the described digital audio information being inserted into the horizontal blanking intervals.

The clock generator 24 is connected to a sub-circuit 38 which outputs clock signals which can be used with the receiver at a frequency of 4/7 of the clock frequency 3> 58 mhz. In this regard, it is noted that the stated frequencies are exemplary only and the invention is not limited thereto.

The output of the dividing circuit 38 is fed via the line modulator 36, to which a further input signal is applied via the line 34 from the synchronization processor 14, which serves to insert the clock signals into the first nine lines of the suppressed vertical blanking interval. The line modulator 36 20 receives from the gate 30 the video signal in which the horizontal and vertical blanking intervals are suppressed and in which the digital audio signal is inserted. The output of modulator 36 will be the described signal with the addition of clock signals 25 during the first nine lines of the blanked vertical blanking interval.

Connected to the synchronization processor 14 is a line or control counter 40, the output of which is connected to a computer 42. The output of the computer 42 is connected to an address port 44. The computer 42 contains the. addresses of all subscribers authorized to receive subscription programs. Not all addresses will be broadcast in every vertical blanking interval, but rather will be sent successively by the computer 35 supplied to the address port to be inserted in the vertical blanking interval after the clock signals in the first nine lines. Assuming, for example, 48 bits per address and an address per line 7908569 5 - a with twelve unused lines, it is possible to insert twelve addresses in each vertical blanking interval. However, in normal operation, prior to the actual broadcast of the subscriber program 5, all receivers will be addressed since it will be possible to utilize the entire video transmission.

The addressing during each vertical blanking interval can be used to continuously authorize the decoder switches in each receiver once they have been authorized once in a beginning by a broadcast prior to the start of the subscriber program. The output of address port 44 will therefore be the above-described video signal into which the digital audio signal in the horizontal blanking interval and into which address or authorization information in the vertical blanking interval is inserted after the above-described clock signals. This signal is delivered to the transmitter 46, which will then wirelessly transmit the described signal for reception by those subscribers who have the required 20 decoding equipment.

3ig. 2 shows the decoder at the receiver.

A tuner 50, which may be either a UHF or a VHE tuner, is connected to an intermediate frequency filter 52 to output an output of approximately 45 MHz frequency 25 which is applied to a video detector.

The output of the detector 5 is the above-described video signal applied to a decoding circuit 56 and a combining circuit 58. The decoder 56 will supply the above-described clock signal along line 60 to the synchronization generator 62 at an output thereof. The output signal of the synchronization generator 62, which consists of the vertical and horizontal synchronization pulses suppressed at the transmitter, is supplied to the combining circuit 58, the output signal of which is thus the reformed video with the correct synchronization signals.

The sync generator 62 will continuously deliver normal sync pulses, but the clock signals 79085 69 v J *, 6 of the decoding circuit 56 are required to properly coordinate the timing of the sync generator and the video signal.

The second output from the decoding circuit 56 is the digital audio information supplied to a digital-analog converter 64. The output of converter 64 will be the reformed audio signal. A 4.5 MHz oscillator 66 is connected to an EM modulator 68, which also receives the audio signal from the converter 64, the output of the modulator 68 being the audio portion of the original television signal at a frequency of 4.5 MHz. This signal is applied to a combining circuit 70, which also receives the combined video signal from the combining circuit 58. The output signal of the combining circuit 70 therefore forms the appropriately decoded video and audio portions of the original television signal.

The third output of the decoding circuit 56, the address or authorization information previously inserted into the vertical blanking interval, is applied to an address authorization decoding circuit 72, which compares the decoded address with the address of the receiver. When found to be in agreement, switch 74 is authorized to operate modulator 76 properly. The modulator 76 changes the frequency of the video and audio signals from the combining circuit 70 into a high frequency signal of the correct frequency for use in a television set. Normally this channel will be 3 or 4, the channels not used in many areas. The output of the modulator 76, a television signal for channel 3 or 4, will be fed through the filter 78 and then to the television receiver 35.

The subscriber television system disclosed in this specification not only provides adequate protection against unauthorized use or breach of the signal, but achieves it in a reliable and relatively straightforward manner. The vertical and horizontal synchronization is removed from the video signal and it is placed on the receiver by an independent synchronization generator, the generator of which time control is controlled by clock signals which form part of the transmitted video. Virtually complete image distortion is obtained by removing both horizontal and vertical synchronization.

As described, the audio can be encoded in the form of digital audio signals. The audio can also be transferred in clear form without coding. In such a case, the horizontal blanking interval may be used to provide another sound channel or the interval may not have coding information superimposed thereon. As yet another possibility, the clock and address information, which has been explained to be entered in the vertical interval, can be inserted in the horizontal blanking interval. It is therefore possible to use the horizontal blanking interval 20 for a different audio channel, for encoded audio information, for no signal or for additional code data that complements the data superimposed in the vertical blanking interval.

790 85 69

Claims (12)

A method of encoding and decoding video signals comprising the steps of suppressing synchronization pulses at the transmitter in the horizontal and vertical video blanking intervals, and inserting clock information into the suppressed intervals, and at the receiver detecting the unsynchronized video and clock information using the detected clock information to control a synchronization pulse generator, and combining the detected video and synchronization pulses to obtain a useful video signal. 2. Method according to claim 1, characterized in that the clock information is only inserted in the suppressed vertical blanking intervals. 15 Method according to claim 1, characterized by the step of inserting address signals into the suppressed blanking intervals at the transmitter, and using the address signals at the receiver for the decoding process. 4. Method according to claim Ί, crazy. features the step of inserting digital audio information at the transmitter into the blanked horizontal blinter intervals, and detecting the digital audio information at the receiver. 25 5 * A method of encoding video signals comprising the steps of suppressing synchronization pulses in the horizontal and vertical video blanking intervals, inserting in the blanked vertical intervals, inserting clock information, and blanking in the blank. Insert 30 vertical intervals of address signals. Method according to claim 5, characterized by the step of inserting digital audio signals into the suppressed horizontal blanking intervals. A method of detecting and reshaping video signals, in which the horizontal and vertical blanking intervals are suppressed and in which clock information and authorization signals are inserted into the blanked blanking intervals, comprising the steps of detecting the staple blanking intervals. -synchronized video, clock and 5 authorization signals, using the clock signals to send a synchronization pulse generator, recombining the unsynchronized video and synchronization pulses, modulating the combined signal to one in a television receiver use signal, 10 and using the authorization signals to control the operation of one of the above-described decoding steps. 8. A method according to claim 7, characterized in that in the. horizontal blanking intervals of the video signal digital audio signals are inserted, and the digital audio signals are detected at the receiver, thereby obtaining an audio signal which is combined with the video signal. 9. A television signal encoding apparatus 20 provided with means for suppressing synchronization pulses in the horizontal and vertical blanking intervals of the video waveform, and means for inserting authorization and clock signals for use in reforming the video. synchronization signals (in suppressed blanking intervals). 10. The apparatus of claim 9 * characterized by means for providing digital audio information representing the audio portion of the television signal and means for inserting the digital audio information 30 into the blanked horizontal blanking intervals. 11. Device for decoding an encoded television signal, in which the synchronizing pulses in the horizontal and vertical video blind intervals are suppressed, and in which clock signals are inserted in the suppressed blind intervals, provided with means for detecting the clock signals, with the detecting means connected synchronizing pulse generating means 790 8 5 69 operated by the clock signals, and means for combining the pulses of the pulse generating means and the video signal having suppressed synchronized pulses to obtain a usable television signal 5, 12. An apparatus according to claim 11, characterized in that the encoded television signal contains digital audio information inserted in the horizontal blinter intervals, the decoding means further comprising means for detecting the digital audio information and for transforming a reformed audio therefrom. signal, and means for combining the reformed audio signal with the video signal. 790 85 69