DE19636098A1 - Tamper protection system - Google Patents

Abstract

The invention concerns a system for protecting programme signal distributor systems or the like against manipulation, the protection system consisting of a security infeed device (1) for the infeed of a security voltage on a signal line (2), and at least one device (3) for protection against manipulation which automatically interrupts the signal line (2) when a variation in direct current is detected on a by-pass (8) present in the device (3) for protecting against manipulation.

Description

The invention relates to a manipulation protection system for Pro Gram signal distribution systems, and in particular for antenna sensors signal distribution systems.

The ever increasing number of program providers, in particular those of television program providers with different Programs, entice participants to look through Mani population of electronic devices and program distribution networks To give access to additional program groups to de they have no authorization.  

DE 37 04 405 C1 uses a release box for supply authorized receiver with selected television programs wrote. A release box is attached to a standard connector Tennendose socket of an antenna system attached by a Central unit forth with signals to enable reception calculation selected television channels according to the reception authorization of a specific recipient. The release box releases certain program blocks via filters if the part is entitled to subscribe. The authorization is in the Central unit stored, which release via a Si gnal controls such that the release box of a certain Participant, known by location and location of the central unit is addressed and then by removing the filter groups releases different transmission areas. The addresses Each release box is constantly called up by the control center and their switching status checked, the release box Release by means of a signal generator via return signals from the central unit requests. The release box on this zen central control system can only be in cooperation with the Central work. It also receives its Be from there drive voltage.

If a defect occurs on a certain release box or a technical manipulation is carried out an interruption of the feedback signal, and this interrupt is saved and registered in the central unit. An operator working on the central unit recognizes that a defect or tampering has occurred. Provided really manipulation is done, the end gets participant who has carried out the technical manipulation, initially the program group to which he actually belongs does not have access authorization. Only after the program offers access to the end connection of the part in question procured and thus found the manipulation the reception of the program group for the participant blocked.  

Such central systems with central control for protection before manipulations lead to very high levels in network operation Cost and administrative expense so that it is economical cannot be operated sensibly. It also receives the manipulating end user continues to run programs, to which he has no authorization and there is none immediate signal shutdown for these programs.

It is therefore the job of a tamper protection system create, which the Pro Gram reception for a manipulating end user immediately locks.

This object is achieved by manipulation protection system with the features of claim 1 or a Manipulation protection device with the features of the patent Proverb 20 solved.

Other advantageous embodiments of the invention are derived from the subclaims.

The following is the structure and operation of the he Tamper protection system according to the invention with reference explained on the accompanying drawings.

Fig. 1 is a schematic diagram showing the tamper protection system of the invention. The tamper protection system has a safety feed device 1 for feeding a safety voltage, a signal line 2 and at least one tamper protection device 3 for automatic interruption of the signal line 2 when a manipulation carried out on the output side is detected, for example in an antenna socket 4 .

Fig. 2 shows the tamper protection device 3 shown in Fig. 1 in detail. The tamper protection device is connected at its input connection 5 via the signal line 2 to the safety feed device 1 . Off input terminal 6 of the tamper protection means 3 is closed for example to an antenna socket 4 or further manipulation protection device 3 is on the signal line. 2 The input terminal 5 is connected directly to a Auskop pelschalt 7 for decoupling a Sicherheitsppan voltage from the signal line 2 in a bypass line 8th In the bypass line 8 , an electronic detection device 9 for detecting a change in current on the bypass line 8 is connected. The electronic detection device 9 is connected to a switching device 11 via a control line 10 . The switching device 11 can be an electronic switch or a relay. In a preferred embodiment, the switching device 11 has two switches 12 , 13 . The switch 12 is connected to the signal line 2 and the switch 13 in the bypass line 8 . The switch 12 switches the switch contact 12 a on the output side between the switch contacts 12 b and 12 c. The switch 13 switches the switch contact 13 a on the output side between the switch contacts 13 b and 13 c. The switch contact 12 c is connected via a terminating line 14 and a terminating resistor 15 to ground. The switch contact 13 c is just over a terminating line 16 and a terminating resistor 17 if grounded. The switch contact 13 b is connected via the bypass line 8 to the node 18 in the signal line 2 , as a result of which the safety voltage is further fed into the signal line 2 via output 6 .

Fig. 3 shows the anti-manipulation device shown in principle in Fig. 2 in detail. The same reference numerals denote the same components.

The decoupling circuit 7 contains a connection point 7 a, at which the bypass line 8 to the signal line 2 is ruled out. At the connection point 7 a, a DC voltage separating capacitor 7 b, which is connected in the signal line 2 , and a coupling coil 7 c, which is connected in the bypass line 8 , is connected. In series with the decoupling coil 7 c of the decoupling circuit 7 , a resistor 19 is connected in the bypass line 8 . The resistor 19 forms part of the electronic detection device 9 and is used to detect a DC change on the bypass line 8 . An amplifier device 20 , preferably an operational amplifier, picks up the voltage drop via the measuring resistor 19 via the nodes 21 and 22 . A line 23 ver connects the tapping node 21 to a first input 24 of the operational amplifier 20th Via a line 25 , the line 23 is connected to a power supply connection 26 of the operational amplifier 20 . In a ground connection 27 , the operational amplifier 20 is connected to ground via a ground line 28 . The second input terminal 29 of the operational amplifier 20 is connected to the node 22 via a tapping line 30 . The amplifier 20 and the measuring resistor 19 together form the electronic detection device 9 . At an output connection 31 of the amplifier 20 , the electronic detection device 9 is connected via the control line 10 to an input connection 11 a of the switching device 11 . At the input terminal 11 a of the switching device 11 , a control circuit, not shown, for controlling the switches 12 , 13 contained in the switching device 11 is ruled out. At the node 21 , which lies between the coupling coil 7 c and the coupling circuit 7 and the measuring resistor 19 of the electronic detection device 9 , an electrolytic capacitor 33 is preferably connected via a further line 32 , which is connected to ground via a ground line 34 . Between the tapping point 22 and the input Schaltkon clock 13 a of the switch 13 of the switching device 11 , an additional series resistor 35 is preferably switched into the reverse line 8 before. A diode 36 and a choke 37 a are preferably provided between the output switch contact 13 b of the switch 13 and the node 18 . The second switching contact 12 c and the second switching contact 13 c are, as already described in connection with FIG. 2, resistors 15 and 17 connected to ground via termination. The terminating resistor 15 for the signal line 2 preferably has a resistance of 75 ohms. The resistor 17 is to be dimensioned such that the previous current flow of the safety voltage loop in the bypass line 8 is retained.

Fig. 4 shows a further embodiment of the tamper protection means 3. The manipulation protection device 3 shown in FIG. 4 differs from the manipulation protection device shown in FIG. 3 only in that it is integrated in a conventional antenna through-socket, which is designated by 39 in FIG. 4. Such a conventional antenna through-socket has a tap 40 which is connected to the signal line 2 . Via a distributor 41 , the branched signal is then divided, for example, to a radio output 42 and a television output 43 . The structure of the tamper protection device is otherwise identical to the structure shown in Fig. 3, only Lich the resistors 35 and 17 in their values may have to be slightly modified due to the continuity circuit of the individual Antennendo sen to get the ideal measuring current in the safety voltage bypass loops . Furthermore, the capacitor 37 b is connected in the signal line 2 for DC separation.

Fig. 5 shows a schematic diagram of the Sicherheitseinspei seeinrichtung 1st The safety feed device 1 has an input connection 44 and an output connection 45 . Via the input connection 44 , the Sicherheitseinspeisein device 1 is connected to the incoming signal line 2 . A coupling circuit 46 is connected into the signal line 2 and is connected to a DC power supply 49 via a coupling line 47 and a switch 48 or a reset button 48 . The coupling circuit 46 contains a capacitor 50 and a coupling coil 51 . Through the power supply 49 of the safety feed device 1 , a DC voltage of, for example, 24 volts can be generated. The power supply 49 can be plugged into a conventional power socket via a power cable 52 , which has a plug 53 at its end. In an embodiment not shown, each of the amplifiers connected to the distribution network can be supplied with its own DC supply voltage from its power supply unit via the circuit shown in FIG. 5 as a safety voltage that can be switched off into its output.

Fig. 6 tamper protection system of the invention shows an example of a loop-through system. The safety supply device 1 receives a highly frequented program signal via the signal line 2 , which is distributed to a distributor 54 with direct current passage on a plurality of signal lines 55 , 56 . The distributor 54 downstream signal lines 55 , 56 are branch 57 also connected with direct current passage with manipulation protection. From the Abzwei 57 likes the program signal on signal lines 58 ver branches, in which antenna sockets 59 are connected in loop-through circuit, the antenna sockets 59 are formed as shown in Fig. 4. In principle, any number of antenna sockets 59 with tamper protection device 3 can be connected in series in a loop-through system. The antenna sockets 58 a can be carried out in a conventional manner with a direct current and RF termination resistance of 75 ohms, preferably without tamper protection.

Fig. 7 tamper protection system of the invention is exemplified as a Sternverteilsystem. In this case, a safety device 1 is connected to the signal line 2 , the signal line 2 being distributed to signal lines 55 and 56 on a distributor 54 with direct current passage. At branches 57 and / or 57 a, the signal and the safety voltage at distribution devices 60 or antenna sockets 59 are branched off with or without a tamper protection device. Several common antenna sockets 61 without tamper protection can be connected in parallel to the distribution devices 60 , into which a plurality of tamper protection devices are integrated.

The loop-through system shown in FIG. 6 can be combined as desired with the star distribution system shown in FIG. 7.

FIG. 8 shows the distributor device shown in FIG. 7 here in detail as a 6-way branch tap 60 . The signal line 2 branched off at a tap 57 is fed to the distribution device 60 . In a Auskoppelschal device 62 , which corresponds to the Auskoppelschal device 7 shown in FIGS. 3 and 4, a safety voltage is coupled out of the signal line 2 . In the part of the signal line 2 connected downstream of the decoupling circuit 62 , a plurality of taps 63 are connected, through which the signal is branched in parallel to a number of output signal lines 64 . The distributor device 60 has a separate manipulation protection device 65 for each of the parallel output signal lines 64 . The structure of the tamper protection device 65 corresponds essentially to the structure of the tamper protection device 3 'as shown in Fig. 3 or 4. The only difference is that not for each tamper protection device 65 has its own decoupling circuit, comparable to the decoupling circuit 7 in Fig. 3, but only one decoupling circuit 62 for all parallel tamper protection devices 65 within the distribution device 60th The trunk line 2 can be switched together with its safety voltage via the trunk output of the last branch 63 to a further branch tap, which is not shown in detail here.

The mode of operation of the electronic manipulation protection system according to the invention is described below:
Through the safety feed device 1 , a DC voltage generated in the power supply 49 is coupled via the coupling circuit 46 to the signal line 2 when the reset button 48 is closed, and this DC voltage together with the high-frequency program signal via the signal line 2 through the entire distribution network to the input terminal 5 fed to each tamper protection device 3 . There, the voltage at node 7 a is coupled out to the bypass line 8 through the decoupling circuit 7 of the tamper protection device 3 . The decoupled direct voltage leads to a direct current through the measuring resistor 19 and the series resistor 35 which is preferably to be provided, since in normal operation the signal line 2 and the bypass line 8 are switched to continuity, that is to say the switches 12 , 13 of the switching device 11 are switched such that the switch contact 12 a with the switch contact 12 b and the switch contact 13 a with the Schaltkon clock 13 b are connected. The direct current passed through the bypass line 8 thus reaches the node 18 via the diode 36 and the Dros sel 37 a. From there it arrives via the output signal line 2, for example, to another antenna socket with a tamper protection device. In principle, this makes it possible to implement a series connection of any number of antenna sockets with a tamper protection device. As long as no manipulation is carried out on an antenna socket, a uniform direct current flows through the signal line 2 to the node 7 a, through the Auskop pelspule 7 , the measuring resistor 19 , the series resistor 35 and from there via the contacts 13 a, 13 b and the diode 36 to the coupling choke 37 a and finally to the node 18 on the signal line 2 . If an end user tries to carry out mechanical or electrical manipulation on his antenna socket, the moment at which he disconnects, reconnects or removes a component, there is a temporal change in the flowing direct current. This DC change is detected by the measuring resistor 19 in the manipulation device 3 desje Nigen component, which is located directly in front of the manipulated antenna socket. The induced DC change tion by the Manipula in the Umgehungslei tung 8 of the upstream manipulation device 3 causes at the measuring resistance 19 between the nodes 21, 22, a voltage drop change caused by the difference amplifier inputs 20 in the direction between the input terminals 24 and detected 29 and then amplified by the amplifier device 20 becomes. The amplifier 20 outputs a control signal to the control signal terminal 11 a of the control circuit 11 from the control signal line 10 . The amplifier device 20 holds the pulse, ie the control signal is present at the switching device 11 after a detected change in current until it is only reset when the safety voltage is switched off. The applied control signal leads to the fact that a control circuit held in the switching device 11 switches the switches 12 and 13 of the switching device 11 from a forward switching position to a blocking switching position. In the forward switching position, the switching contacts 12 a and 12 b of the switch 12 and the switching contacts 13 a and 13 b of the switch 13 are connected. The forward switching position corresponds to an operation in which no manipulation was detected or in which there is no safety voltage in the distribution network and thus on the signal line 2 . After detection of the direct current change caused by the technical manipulation, the control signal applied to the control signal line causes the Sc holder 12 to switch to the blocking switching position, in which the switching contact 12 a is connected to the switching contact 12 c, whereby the signal line 2 to the terminating resistor 15 is switched. At the same time, the switch contact 13 a is separated from the switch contact 13 b and switched to the switch contact 13 c of the switch 13 . This switch-over isolates the tamper protection device from the reception of the high-frequency program signal. To switch the signal line 2 by means of the switch 12 to the terminating resistor 15 ensures that the previous radio tion of this component, for example as an antenna socket with tamper protection, as shown in Fig. 4, is retained. The switch of the switch 13 causes the current flow through the diode 36 and the choke 37 a to the next en subscriber to be interrupted. The flowing through the Umgehungslei device 8 direct current is abge after switching the switch 13 via the load dissipation resistor 17 to ground. As a result, a recognizable current flows through the respective measuring resistor 19 for all upstream anti-tamper devices in the safety voltage circuit, and there is no chain reaction due to further circuits. This can also be prevented by the optionally provided electrolytic capacitor 32 , which slows down the abrupt change in current, thereby preventing the detection of manipulation protection elements that are switched on.

An electronic holding device in the amplifier device 20 holds the pulse, which is supplied via the control line 10 to the switching device 11 , until the supply voltage, which is coupled out via the decoupling circuit 7 and supplies the amplifier circuit with voltage via lines 23 , 25 , is interrupted once at the reset button 48 of the safety feed device 1 , where the entire system is briefly de-energized or de-energized. In this one-time interruption of the safety voltage at the safety feed device 1, for example by an operator or by remote control, there is no voltage at the amplifier 20 and therefore no control signal on the control signal line 10 , and the switching device 11 switches back to the open position. As a result, the downstream antenna sockets are again supplied with the program signal.

In the de-energized delivery state, the switching device 11 is in the through switching position, ie the contact 12 a is connected to the contact 12 b, and the contact 13 a with the contact 13 b. This switch position is maintained throughout the normal operating state. If manipulation is carried out on a downstream antenna socket by a current change in the security circuit, the manipulation device upstream of the manipulated device 3 switches over to the blocking switch position. Now tries the manipulator, for example, by feeding a DC voltage in the opposite direction to transfer the program signal to compensate for the current change at the measuring resistor 19 , this prevents the diode 36 connected in the bypass line 8th The manipulator is therefore forced to report to the program provider and to eliminate or have the technical manipulation eliminated. The program provider can then in a simple manner by opening and re-closing the switch 48 in the safety feed device 1, if necessary, also remotely controls the subscriber again.

The purely passive commercially available end sockets in the stub line system connected to multi-distributors or multi-taps, as shown, for example, in FIG. 7, have an ohmic resistance of 0-75 ohms. Since these spur line sockets with directional coupler distributors have an ohmic resistance of 0 ohms, it is advisable to provide the additional series resistor 35 in the tamper protection device 3 , since it detects the current within the bypass line 8 and thus the voltage jump detection between the lines 23 and 30 in necessary limits.

Both electronic and switching devices are suitable Switches as well as electromechanical switches, such as wise relay.

Since the short-circuit-proof safety feed device 1, which is not accessible to everyone, has a simple structure and only the manipulating end user is switched off from program reception by the electronic manipulation protection device 3, the manipulation protection system according to the invention provides an excellent instrument for the network operator to manage his system and his system Protect participants from third-party intervention. Anyone who unauthorized disconnects, reclamped, removed, damaged or changed, due to the tamper protection system according to the invention must be expected that this intervention on the component upstream in the signal flow interrupts the outgoing program signal from the component connected before, so that it lasts receives no signal until the network operator causes the shutdown and then the restart of a safety voltage, which then switches all construction parts back on with electronic signal shutdown. The invention is suitable not only for preventing the number of unauthorized interventions, for example in operators' antenna distribution networks, but also for effectively preventing program theft and thus, for example, forgery of documents or enrichment of third parties at the expense of the general public.

Claims (23)

1. Manipulation protection system for program signal distribution systems or the like with
a safety feed device ( 1 ) for feeding a safety voltage onto a signal line ( 2 ) and with
at least one tamper protection device ( 3 ) for the automatic interruption of the signal line ( 2 ) upon detection of a direct current change on a bypass line ( 8 ) contained in the tamper protection device ( 3 ). 2. Manipulation protection system according to claim 1, characterized in that the tamper protection device ( 3 )
a decoupling circuit ( 7 ) for decoupling a safety voltage from a signal line ( 2 ) into a bypass line ( 8 ),
an electronic detection device ( 9 ) for detecting a current change on the bypass line ( 8 ) and a switching device ( 11 ) connected to the signal line ( 2 ) and the bypass line ( 8 ), which via a control line ( 2 ) with the electronic detection device ( 9 ) is connected. 3. Manipulation protection system according to claim 1 or 2, characterized in that the decoupling circuit ( 7 ) has a capacitor ( 7 b) and a coil ( 7 c). 4. Manipulation protection system according to one of the preceding claims, characterized in that the electronic detection device ( 9 ) has a device ( 19 ) for detecting a direct current change on the bypass line ( 8 ) and an amplifier device ( 20 ). 5. Manipulation protection system according to one of the preceding claims, characterized in that the device ( 19 ) for detecting a DC amendment is a resistor. 6. Manipulation protection system according to one of the preceding claims, characterized in that the amplifier device ( 20 ) is an operational amplifier. 7. Manipulation protection system according to one of the preceding claims, characterized in that the switching device ( 11 ) is an electronic switch. 8. Manipulation protection system according to one of the preceding claims, characterized in that the switching device ( 11 ) is a switching relay. 9. Manipulation protection system according to one of the preceding claims, characterized in that the signal line ( 2 ) and / or the bypass line ( 8 ) can be switched to continuity or to ground by the switching device ( 11 ). 10. Manipulation protection system according to one of the preceding claims, characterized in that the signals can each be switched to ground via a terminating resistor ( 15 ). 11. Manipulation protection system according to one of the preceding claims, characterized in that a diode ( 36 ) in the bypass line ( 8 ) is connected. 12. Manipulation protection system according to one of the preceding claims, characterized in that in the bypass line ( 8 ) a choke for Einkop peln the safety voltage in the signal line ( 2 ) is switched GE. 13. Manipulation protection system according to one of the preceding claims, characterized in that the safety feed device ( 1 ) has a power supply unit ( 49 ) for generating the safety voltage and a coupling circuit ( 46 ) for coupling the safety voltage to the signal line ( 2 ). 14. Manipulation protection system according to one of the preceding claims, characterized in that the safety feed device ( 1 ) has a switch ( 48 ) connected between the power supply unit ( 49 ) and the coupling circuit ( 46 ), which switch can also be controlled remotely. 15. Manipulation protection system according to one of the preceding claims, characterized in that the coupling circuit ( 46 ) for the Sicherheitsppan voltage has a coil ( 51 ) and a capacitor ( 50 ). 16. Tamper protection system according to one of the preceding Expectations characterized, that the safety voltage is a DC voltage of about up to approx. 24 volts. 17. Manipulation protection system according to one of the preceding claims, characterized in that the tamper protection device ( 3 ) is built into an antenna socket ( 39 ). 18. Manipulation protection system according to one of the preceding claims, characterized in that a distribution network is connected between the security feed device ( 1 ) and the manipulation protection devices ( 3 ). 19. Tamper protection system according to one of the preceding claims, characterized in that several anti-tamper devices ( 3 ) are connected in series. 20. Tamper protection device with
a decoupling circuit ( 7 ) for decoupling a safety voltage from a signal line ( 2 ) into a bypass line ( 8 ),
an electronic detection device ( 9 ) for detecting a current change on the bypass line ( 8 ) 'a in the signal line ( 2 ) and the bypass line ( 8 ) switched switching device ( 11 ) via a control line ( 10 ) with the electronic detection device ( 9 ) is connected. 21. Manipulation protection device according to claim 20, characterized in that the electronic detection device ( 9 ) has a device ( 19 ) for detecting a direct current change on the bypass line ( 8 ) and an amplifier device. 22. Manipulation protection device according to claim 20 or 21, characterized in that the decoupling circuit ( 7 ) has a capacitor ( 7 b) and a coil ( 7 c). 23. Manipulation protection device ( 3 ) according to one of claims 20 to 22, characterized in that the signal line ( 2 ) and / or the bypass line ( 8 ) can be switched to continuity or to ground by the switching device ( 11 ).