NL8600172A - Signal security system for cable TV network - transmits signal mixed with HF interference to prevent unauthorised reception - Google Patents

Abstract

At the central cable TV station, the composite video signal, for the programme which is to be protected, is fed to one input (2) of a fork circuit (3). The other input (4) is fed by an interference signal generator (5). The interference signal has an amplitude equal to the max. of the video signal, and an accurately controlled frequency which is 100 to 150 times higher than the video line frequency. The fork circuit output (6) is fed via a conventional C.A.I. cable network (7) to the aerial input connector (8) of a subscriber. The aerial input is connected to the input (9) of another fork circuit, one output (10) of which is connected to a correction circuit (11). The other outputs (12,13) of the fork circuit are connected directly and via a crystal (14) to the inputs (15,16) of a third fork circuit. The third fork circuit output (18) is fed to the aerial input of the subscribers TV set. The fork circuits and crystal form a filter which removes the interference.

Description

-1-? .- VO 8030

Tape barrier filter circuit and system for rendering a video signal to be transmitted unrecognizable and selectively recognizing the received video signal using the tape barrier filter.

The invention relates to a tape pre-filter circuit and to the ESI system for rendering a video signal to be unrecognizable and making the received video signal selectively recognizable again using the tape pre-filter circuit.

With central antenna installations (hereinafter C.A.I.) that transmit a large number of radio and television programs to the C.A.I. cable network connected receiving equipment, it is also possible to transmit so-called subscriber television. Hereby, via the C.A.I. cable network transferred one or more programs which have been processed in such a way that an unrecognizable image is obtained when the signal received via the cable is directly connected to a television receiver and that only those who have subscribed to such programs are disturbed because they have an electronic circuit capable of converting the unrecognized video signal into a recognizable video signal.

With such subscriber television systems it is desirable to keep the cost price of the circuit to be installed at a subscriber to make the unrecognizable video signal recognizable as low as possible, while this circuit may also not be so simple that it can be easily passed through a everyone can be recreated.

The object of the invention is to provide a system with which it is possible to render a video signal unrecognizable in a simple manner and wherein the electronic circuit for making the video signal recognizable again cheaply. and is simple in construction, wherein the video signal obtained by means of the circuit is of good quality and wherein the reconstruction of circuit 5 is still relatively difficult.

To this end, the invention provides a system in which a false signal source is provided, which can output a false signal with a predetermined frequency, and means for combining the video signal to be transmitted with the false signal of which the frequency is within the frequency band of the video signal is placed at a position where the information content of the video signal is small, and in a band-separator circuit for filtering the interference signal from the received signal after receiving the video signal.

It has been found that by including in the video signal an interference signal in the form of an unmodulated carrier wave with a frequency approximately 100-150 times the line frequency higher than the image carrier frequency of the video signal, this interference signal has a sufficiently large amplitude, e.g. an amplitude equal to that of the picture carrier, the video signal can be distorted such that upon direct reception thereof the synchronization of the picture on the television receiver 25 is completely eliminated, so that the signal is useless, while suppressing it correctly in the received signal the image quality of the interference signal is excellent. If the video signal is not modulated on an image carrier, the interference frequency is about 100-150 times the line frequency.

The interference frequency must be very stable and depending on the frequency difference between the interference frequency and the frequency of the image carrier divided by the line frequency, this interference signal must be suppressed at the subscriber's 35 40-60 dB in order to allow undisturbed reception of the original video signal. Λ Ά% jC * v C 'ΰ} / * * -3-.

To this end, the subscriber must be equipped with a very sharp band-block filter in order to minimize the loss of image information, while the attenuation 5 for the interference frequency is nevertheless sufficiently high. Such a filter cannot be realized in a simple manner with conventional filtering techniques, because the quality factor Q of the band-blocking filter will have to be at least a value 104.

The object of the invention is therefore also to provide a band barrier filter circuit which is particularly suitable for use in the system described above.

To this end, the invention provides a band-pass filter circuit having an input terminal and an output terminal, comprising means for splitting a signal applied to the input terminal into a first and a second substantially equal signal part, in means adapted to filter the second signal part and pass a narrow frequency band signal, in means to effect a 180 ° phase shift between the first signal portion and the narrowband signal obtained after filtering, and in means to subsequently combine and output these signals at the output terminal.

The band barrier filter circuit according to the invention differs from a conventional filter in that with a conventional band barrier filter the suppression of a certain frequency band takes place because the impedances of the components of the filter change as a function of the frequency, while in the filter according to the invention the phase shift between the first and the second signal part determines the shape of the filter characteristic.

Although the tape barrier circuit according to the invention is particularly suitable for use in the above described system for rendering a video signal unrecognizable and recognizable, the filter is also normal. 1 7 £ -4 band filter with narrow bandwidth and high attenuation. There are e.g. already propose to use a C.A.I. in a particular channel, only transmit teletext information which is also transmitted on a subscriber basis to the C.A.I.-5 terminals, whereby a subscriber can request teletext information by means of a dialing signal. By including the band-filtering circuit according to the invention in the cable network, it is possible to suppress the frequency band with teletext information in the video signal received via a predetermined television channel such that the teletext decoder present in a connected television receiver is not able to provide the teletext information. decoding, while the received video signal is not disturbed by the filter in such a way that the synchronization is canceled, so that eg

the screen remains completely dark. This has the advantage that when a subscriber does transmit a dialing signal, the transient video signal with teletext information broadcast to that subscriber is correctly received.

The filter must of course be switched off after the transmission of the dialing signal. Likewise, for certain applications it may be desirable to filter out the teletext information from a video signal containing both image information and teletext information, the maximum attenuation of the band barrier filter being e.g. selected at a frequency equal to the clock frequency of the teletext information in the video signal.

The invention will be described in more detail below with reference to an exemplary embodiment with reference to the drawing, in which: Fig. 1 shows a block diagram of the system according to the invention; and Fig. 2 shows a diagram of a possible construction of the band-block filter according to the invention.

FIG. 1 shows a video signal source which outputs a video signal modulated on an image carrier or not Λ 17 $ r. / '-J 4 / .intt * -5- at a first input terminal 2 of a fork circuit 3, at the second input terminal 4 of which a signal source 5 is connected, which can give a false signal with an accurately determined frequency, which frequency, for example

100-150 times the line frequency is higher than the image carrier frequency of the video signal output from source 1 and which signal has a sufficiently large amplitude, e.g. an amplitude equal to that of the image carrier.

Since the line frequency is 15,625 kHz at a 10 video signal according to the CCIR standard with a line number of 625 and a frame frequency of 50 Hz, the frequency of the interference signal is about 1.5 MHz-2.35 MHz higher than the picture carrier frequency. It appears that in that region of the frequency spectrum of the video signal little to no image information is present, so that suppressing the frequency of the interfering signal does not or hardly noticeably affect the image quality.

The fork circuit 3 combines the signals on the input terminals 2 and 4 and outputs the combined signal 20 to the output terminal 6. From output terminal 6, the disturbed video signal is sent via the usual C.A.I. cable network, schematically represented by line 7, transferred to a user's antenna terminal. The input terminal 8 of a fork circuit 9 is connected to this antenna connection, of which fork circuit one output terminal 10 is coupled to a correction circuit 11, the purpose of which will be explained below.

The outputs 12 and 13 are resp. via a crystal 14 and directly with resp. a first input 15 and a second input 16 of a fork circuit 7 connected, the output terminal 18 of which is connected to the television set 19 of the user.

The actual filter circuitry is located in the circuit of FIG. 1 between the terminals 8 and 18 and its operation will be explained below. For the sake of clarity, it will be assumed that the operation of the components shown in the circuit is ideal, while a practical embodiment of the circuit will now be discussed with reference to Fig. 2.

The fork circuit 9 divides the video signal applied to terminal 8 into two equal parts, without a phase shift occurring between these parts. In a fork circuit 9 with ideal operation, the circuit 11 consists of a terminating resistor.

The first signal part at terminal 13 is directly coupled to the input 16 of fork circuit 17. However, the second signal part at terminal 12 is led to the input 15 of fork circuit 17 via a quartz crystal 14, which ideally has the property that at 15 the resonant frequency of the crystal the impedance is zero and at other frequencies than the resonant frequency the impedance is infinite. If now the resonance frequency of the crystal is chosen to be equal to the interference frequency given by source 5, then at terminal 15 of the fork circuit 17 there will be only a signal consisting of a single frequency, i.e. the interference frequency. The fork circuit 17 has the property of adjusting the on or off. the signals presented at terminals 15 and 16 can be combined with each other under a phase shift of 180 ° with each other, so that the complete video signal, as present in the second signal part, is available at terminal 18, but the interference frequency is suppressed in this video signal because the Components of the interference signal rotated in phase by 180 ° in resp. the first and the second signal parts, which components have the same amplitude, cancel each other out completely.

The operation of the filter is therefore based on the insight that a very strong suppression of a signal with a certain frequency within the frequency band of a video signal is possible by splitting this video signal into two halves, by dividing all signals in one half - - - - I 7 v

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-7- with the exception of the signal with the determined frequency and by subsequently combining both signal parts with a relative phase shift of 180 ° relative to each other, so that in the signal part that all the video information still contains the signal with the determined frequency, that tw the interference signal is suppressed.

For signals within the video tape that have a frequency that is not equal to the interference frequency, the attenuation of the tape blocking filter is theoretically 6 dB, viz.

10 twice the fork damping.

With reference to Fig. 2, a practical embodiment of the band barrier filter shown schematically in Fig. 1 between terminals 8 and 18 will now be described.

The video signal is sent from the cable of the C.A.I. supplied with an impedance of 75 ohms asymmetrical and this signal is connected to one end terminal of a 1: 2 transformer 21, a center tap of which is connected to a center tap of a 1: 1 transformer 22, and the other end terminal of which is grounded . One end-of-20 connection of transformer 22 is coupled to one connection terminal of a crystal 26 and the other end-connection to one connection terminal of a capacitor 27. A compensation network is arranged between the two end connections, consisting of a series connection of a resistor 24 and a coil. 23, the junction of the coil and the resistor being grounded through an adjustable capacitor 25.

The other terminal of the crystal 26 is connected via one low-pass filter consisting of coils 31, 33 and capacitor 32, the function of which will be explained below, to one end connection of a 1: 1 transformer 28, the other end connection of which is connected with the other terminal of capacitor 27. The center tap of transformer 28 is grounded through a resistor 29. The two end terminals of transformer 28 are further connected to respective input terminals of a transformer 30, which has the function of the "-"? 7 9 * * Zm -8- convert synunetric output impedance between the end terminals of transformer 28 to an asymmetrical output impedance 75 ohm, which can be connected directly to the antenna input of a television.

The transformers 22 and 28 are designed as a so-called "ohnesorge" fork circuit, whereby the balancing of fork circuit 22 is formed by the combination of resistor 24, coil 23 and capacitor 25 and the balancing of fork 28 by resistor 29. - and output impedance 10 of 75 ohms is the impedance of resistor 29 and the combination of resistor 24, capacitor 25 and coil 23, respectively.

75 and 75/4 ohms.

With the aid of the adjustable capacitor 25 it is possible to adjust the circuit shown in Fig. 2 in such a way that in the output signal supplied by transformer 30 the frequency of the interference signal is suppressed by approximately 60 dB, the bandwidth circuit's 3 dB bandwidth being suppressed. 9 kHz, so that the content of the spectrum of the video signal is not appreciably affected for the rest. Due to the non-ideality of the components, it has been found desirable to include capacitor 27 in the circuit so as to achieve the desired phase shift.

At a crystal frequency of 50 MHz, a band barrier filter having the following properties was obtained with the circuit shown in Fig. 2; attenuation in passband: 9 dB attenuation at 50 MHz 70 dB • bandwidth at attenuation of 12 dB; 9 kHz 30 bandwidth at 39 dB attenuation; 50 Hz.

The low-pass filter consisting of coils 31, 33 and resistor 32 aims to block signals with a frequency that form the higher harmonics of the crystal frequency, because otherwise these signals could adversely affect the video signal. At a crystal frequency of 50 MHz, the cut-off frequency of this low-frequency

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As shown in dotted line in Fig. 2 by a coil 34 and a capacitor 35, it is possible to replace the crystal 26 and the low-pass filter with an LC series circuit which in theory also has an impedance equal to zero at only one frequency and beyond that frequency an impedance that rapidly increases to a very high value, so that also here a narrow band around one frequency component in the second signal part can be filtered and added in counterphase to the first signal part in order to suppress that one frequency component to the maximum. . However, since the properties of an LC circuit are not ideal and are also inferior to that of a crystal, in the circuit of FIG. 2, when the dotted chain was used instead of the crystal and the low-pass filter, at a frequency of 50 MHz the following values were measured: attenuation in passband: 10 dB attenuation at 50 MHz: 75 dB 20 bandwidth at a damping of 13 dB: 2 MHz bandwidth at a damping of 40 dB: 80 kHz.

This characteristic is clearly less sharp than the characteristic which can be obtained with the aid of a crystal, so that for suppression of a faulty sewing e.g. the implementation of the filter with a crystal will be chosen. For use at e.g. suppressing teletext information, as explained above, such a filter with an LC circuit is useful.

The filter can herein be switched off in a very simple manner in order to receive teletext information in addition to the synchronization signals, after the subscriber has sent a dialing signal, by interrupting the branch in the filter in which the crystal or the LC circuit is incorporated. so that the signal path only passes through capacitor 27 and thus the full video signal is output by transformer 30. Furthermore, the filter according to the invention Λ 1 7 9 ✓ V * J & * * V '-10- can be used anywhere where a crystal or an LC circuit is used anywhere where a filter with a band barrier characteristic, and in the a filter with an exceptionally high quality factor is particularly desirable when using a crystal.

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Claims (13)

System for rendering a video signal to be transmitted unrecognizable and making the received video signal selectively recognizable again, characterized in that a disturbing signal source is provided, which can output a disturbing signal 5 with a predetermined frequency, and in means in order to combine the video signal to be transmitted with the interference signal, the frequency of which lies within the frequency band of the video signal at a position where the information content of the video signal is small, and in a band pre-filtering circuit to receive the interference signal after reception of the video signal filter from the received signal. System according to claim 1, characterized in that the frequency of the interference signal is approximately 100-150 times the line frequency. System according to claim 1, wherein the video signal is modulated at an image carrier frequency, characterized in that the frequency of the interference signal is about 100-150 times the line frequency higher than the image carrier frequency. System according to at least one of claims 1 and 3, characterized in that the amplitude of the interference signal is substantially equal to the amplitude of the image carrier. 5. Band-filtering circuit comprising an input terminal and an output terminal, characterized in that means are provided for splitting a signal applied to the input terminal into a first and a second substantially equal signal part, in means arranged around the second signal part. filtering and transmitting a narrow frequency band signal, in means to effect a 180 ° phase shift between the first signal portion and the narrowband signal obtained after filtering, and in means to subsequently transmit these signals V Sj V v Λ. / Jèê 4 v- '-12- combine and deliver to the output terminal. Band barrier filter according to claim 5, characterized in that the means for filtering the second signal part and passing a narrow frequency band signal comprises a quartz crystal. Filter according to claim 5, characterized in that the means adapted to filter the second signal part and pass a narrow frequency band signal comprises an LC circuit. Filter according to claims 5 and 6, characterized in that a low-pass filter is included in series with the quartz crystal. Filter according to at least one of claims 5 to 8, characterized in that the means for splitting the signal applied to the input terminal comprise a fork circuit and the means for effecting a phase shift of 180 ° between the first signal part and the narrow-band signal obtained after filtering, and to subsequently combine these signals comprise a second fork circuit. Filter according to claim 9, characterized in that the fork circuit are ohnesorge fork circuits. 11. Filter according to claim 10, characterized in that the first fork circuit is closed with a compensation network. Filter according to claim 11, characterized in that the compensation network comprises a series connection of a resistor and an inductance, which is connected to the output terminals of the fork circuit, the connection point of the resistor and the inductance via an adjustable capacitance. is connected to a reference potential. System according to at least one of claims 1 to 4, provided with a band-stop filter circuit according to at least one of claims 5 to 12, wherein the means 35 for filtering the second interference signal part are adapted to the interference frequency. % ·: Λ λ 4 -? / -¾ v J J i /