FI67006B - SIGNALFOERDELNINGSANORDNING FOER EN KABELTELEVISION - Google Patents

Description

U ^ 4 ^ T1 ΓΒΐ rt1 ^ ANNOUNCEMENT / πλλ / jrofifc lBJ UTLÄGCNINGSSKRIFT 6 / UU6 (51) h 04 N 7/16 FINLAND — FINLAND (21) p * ·· *** · * »" »· —ρκμνμβμαι 7536A0 ( 22) HakMntaplM — AiMeknhic ^ g 23.12.75 (FI) (23) AMnpUvi — GHtlglt «until 23.12.75 (41) TuHm fuUtlMfcsl - UlvftefftncRg 25.06.76

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Patent and ocean registration 7 AmMur utkgd od * utijkrKteo puMicw-ad (32) (33) (31) Pyydity «cuoikMt — Begird prlorket 24.12.74 Hol1 anti-Hoi land (NL) 7416880 (71) Oak Communications, Inc., Crystal This invention relates to a signal distribution device for cable television. The present invention relates to a signal distribution device for use in a cable network. in connection with a supply line through which a plurality of television and radio frequency bands can be transmitted according to the frequency multiplex principle together with suitable coding to a plurality of subscriber lines, the device comprising a data receiver connected to the supply line and a logic control unit connected to the data receiver to control a high frequency switch with each subscriber line to connect it to the network and so on to disconnect from it.

In this known cable television circuit, subscribers are generally connected, with the aid of signal distribution devices, to a supply or ring line which distributes a frequency-multiplexed set of television programs and radio programs to the subscribers in question. In such a system, a certain number of subscribers are connected to each distribution device.

2 67006

One disadvantage associated with such systems is that, during the installation of the cable television circuit in question, only those subscribers who have previously indicated that they wish to join the system can be connected. Later, when ordering, the technician must connect the subscriber's apartment to the dispenser in question, which is expensive and time-consuming. In the event of both termination and non-payment, the technician must also disconnect the subscriber from the dispenser.

As a result, it is not always possible for the system mentioned in the introduction to prevent subscribers already connected from receiving certain programs.

The object of the present invention is to provide a signal distribution device by means of which, during the installation phase, each dwelling in the television network is connected to the distribution device so that each subscriber can be connected to or disconnected from the central television network at any desired time.

It is also an object of the present invention to allow remote control to be implemented using appropriate code so that certain programs on certain subscriber lines can be interfered with so that viewing and listening to the programs belonging to them is made impossible.

The signal distribution device according to the present invention is characterized in that in addition to said high-frequency switch, each subscriber line also includes a second semiconductor-type high-frequency switch adapted to switch on and off the transmission of one or more frequency bands on this subscriber line, respectively.

A particular advantage of this system is that each subscriber connected to the distribution device can be connected or disconnected from a centrally located location, and also that each subscriber can be allowed or prevented from receiving certain programs without disturbing other subscribers.

An additional advantage is also that the subscriber is not able to switch these on himself.

The present invention will now be explained with reference to an embodiment thereof with reference to the accompanying drawings, in which: Fig. 1 is a block diagram of a signal distribution apparatus including four subscriber transmission lines, each line having a high frequency switch 3 67006 in series and remote transmission and disconnection Fig. 2 is a block diagram of a signal distribution device including only one subscriber sub-line equipped with four high-power switches in co-operation and in parallel with this line for interfering with certain television and radio programs as needed; Fig. 3a is a drawing of a high-frequency switch embodiment using a semiconductor in the device according to Fig. 2, Fig. 3b is a drawing of a part of the high frequency operation in the high frequency switch according to Fig. 3a, Fig. 4 is a front view of the housing in which the distribution device is placed, Fig. 5 is a block diagram of the signal distribution Figure 6 is a drawing of an embodiment of a high frequency switch of the second type, comprising only one subscriber line with four large hair switches of another type and installed in series with the cable to interfere with certain television and radio programs as required, used in the device of Figure 5, and Figure 7 is a drawing of another embodiment of a high frequency switch of this second type and which may be used individually for a plurality of channels.

Referring now to Figure 1, there is shown a supply line or ring type line 1, a plurality of subscriber transmission lines 2, a data receiver 3, a logic control unit 4, high frequency switches 5 and a branch section 6. The data receiver 3 in said distribution device is connected to a branch or connection distribution point. It can be used with a directional switch or side output for this branching task. The logic control unit 4 following the data receiver 3 interprets the appropriate codes to be input in the high frequency signals. Depending on the information of these codes, the control unit 4 switches one or a number of high-frequency switches 5 so that the high-frequency signals belonging to the television and radio programs are transmitted to the subscriber line 2 or are prevented * 67006 from entering there.

Referring to Figure 2 below, a signal distribution device is shown in block diagram, by means of which it is possible to connect interfering signals to the subscriber's transmission lines and by means of which the subscribers concerned can be allowed or prevented from receiving television and radio programs. Referring again to Figure 2, there is shown a supply line 1, a single subscriber transmission line 2, a data receiver 3 connected to a branch distribution point 6, a logic control unit 4, a single high frequency switch 5 installed in series with the subscriber line 2. Also shown are a number of high frequency switches 14 arranged in parallel with the subscriber line 2, a number of pre-connected oscillators 9 and a number of attenuators 7 connected between them.

The oscillators 9 have substantially the same frequency as the associated programs, so that when the switch 14 is closed, a strong interference signal is applied to the subscriber's line, thus preventing the program from being viewed and listened to. When this signal is connected to the subscriber's line, low levels of interference signals can be used, e.g. about 0 dBraV. These interference levels can be maintained using, for example, a pin diode attenuator, which is controlled by automatic volume control in the data receiver 3. In order to prevent leakage into the system, oscillator signals are fed into the subscriber line via the directional switch S.

With respect to Figure 3a, there is shown a high frequency switch of the semiconductor or solid state type. The attenuation of this switch in the range of 50 ... 300 MHz is more than 88 dB. The input power is 2 mA when using 5 V DC. This operation is as follows:

If point A is positive compared to point B, a direct current is provided to the circuit, R2, R1, D2 and R1, by means of which the series diodes D3 are then connected, and the diodes connected in parallel and D2 are connected in the wiring direction. With respect to Fig. 3b, it shows in terms of high frequency operation how this structure forms an attenuator, which includes large series impedances (D1, and D1.) And small parallel field impedances (D1 together with part and D2 together with C2) such that high frequency the signal is not transferred from input to output (nor vice versa).

If point A is negative compared to point B, a DC current flow to the circuit Rg, Dg, Dg and Rg is included, whereby the Bitten serial diodes Dg, D1 and Dg are connected in the conducting direction and the parallel diodes D1 and D2 are connected in the blocking direction. The high frequency signal is now transmitted virtually without attenuation. Capacitors C2 and Dg operate to prevent the DC voltage supplied to points A and B from entering the high frequency cables.

Capacitor Cg is used to prevent the occurrence of high frequency leakage through resistors R1 and R3 connected in parallel to part D1 (in the blocking direction). All resistors have the function of matching the DC forward voltage and have no high-power function.

At the branch point of four subscribers, the following is required in the example case: - one data receiver, - one logic unit containing for the branch address: bits for the subscriber address: 2 bits for switching and disconnecting: 1 bit for four programs: 4 bits - four oscillators and corresponding attenuators, - four subscriber units , each of which includes five High-frequency switches.

Basically, any number of subscribers and a set of programs per unit can be combined together.

Referring to Figure 4, there is shown how such a combination can be placed in the formed housing.

Referring to Figure 5, there is shown a block diagram of a signal distribution device which, as with the device of Figure 2, allows and prevents the subscriber from receiving four or more or fewer corresponding programs, respectively. The same parts in Fig. 5 as in the part according to Fig. 2 are indicated by the same reference numerals. However, instead of four high-frequency switches 14 connected in parallel to the subscriber's line, four high-frequency switches 10 are used, which are of another type placed in series with the line.

Referring to Figure 6, there is shown a drawing of a high frequency switch 10 of another type. Prior to this second type of switch, a high frequency switch 5 (S 2) may be installed in the series to transmit or block all signals of the high frequency program from each subscriber, respectively. In the switch 10, a T-filter is placed in series with the subscriber line and a parallel circuit of the inductance 11 and the accompanying varactor 12 is placed in the transverse branch of this T-filter. When this variator 12 is periodically adjusted using e.g. a low frequency signal at a frequency of 50 or 1000 Hz, the tuning of this circuit can be swept over the whole channel or a part so that periodically (not synchronously) another relatively narrow part of the side strips of this signal is filtered out so that the resulting character is disturbed. The tuning of this High-frequency switch or trap circuit is obtained in position "na" (not authorized) by switch S2 by adjusting the inductance in the interfering channel 11. Care should be taken during this procedure that and the interference of the relevant program channel is removed to position "a" (allowed) Switch S2 transmits only low frequencies and may therefore be of both mechanical type and semiconductor type.

When the varactor diode is connected in the line direction "a", current flows from the DC supply source 15 through the part S2, the resistor R, the varactor 12 and the inductance 11 back to the supply source 15. This inductance is short-circuited and two capacitors C with relatively small values occur in parallel. 2 and thus have virtually no effect on the transmission of this mark.

It is also possible to simultaneously interfere with a number of channels located side by side by selecting the low frequency sweep of the source 16 to be large enough. In this case, only one switch is enough for 10 sets of channels.

Referring to Fig. 7, it is shown how, in the exemplary case, switch 10 can be tuned to four different channels periodically by switching this switch via a solid state switch (S2 as well as -Sg) to various negative voltages, which are then later blocked. Switch S2 can be switched on periodically (e.g. three ^ us). Switching - S g for the four programming channels, each of these, under the control of the control unit 4, can only be set to a positive DC voltage (with no interference) or a low frequency voltage matched to the negative DC voltage.

The tuning is then determined by the DC voltage of the varactor and the trap circuit is swept at 50 or 1000 Hz over the corresponding channel. By switching on or off these low-frequency voltages with the aid of the data receiver and the control unit, the program can be allowed or prevented from running one after the other, respectively. Each channel that is blocked is sufficiently disturbed by selecting the correct playback frequency in this way.

In order to interfere with a number of channels, it is also possible to use parallel connection in addition to the first-mentioned series connection and the above-mentioned several connections, namely by placing a number of trap circuits in parallel on each other in the longitudinal branch of the T-filter.

Claims (6)

8 67006 A signal distribution device for use in connection with a cable network with a supply line (1) through which a plurality of television and radio frequency bands can be transmitted according to the frequency multiplex principle together with suitable coding to a plurality of subscriber lines (2), the device comprising a data receiver (3), connected to the supply line, and a logic control unit (4) connected to the data receiver for interpreting the codes and controlling the high frequency switch (5) in series with each subscriber line to connect it to the network and disconnect it, characterized in that in addition to said high frequency switch (5) in connection with each subscriber line (2), there is also a second half of a conductor-type high-frequency switch (14; 10) adapted to switch on and off the transmission of one or more frequency bands on this subscriber line, respectively. Device according to claim 1, characterized in that said second high-frequency switch (14) is arranged in parallel with the subscriber line (2) for connecting blocking signals from the blocking oscillator (9) to the subscriber line, optionally connected to a damping unit (7) (3) controlled by automatic gain control members. Device according to Claim 1 or 2, characterized in that each high-frequency switch (5, 14) consists of a diode-resistor-capacitor network comprising three diodes (D1, D5) connected in parallel in series, and that the connection point of the center diode ( D 1) on each side is connected to ground via a corresponding series circuit of a diode and a capacitor (D 1, and D 2, C 2), so that the cathode of the second diode (D 1) is connected to the cathode of the center diode (D 2) and the anode of the second diode (D 2) is connected the anode of the middle diode (D 2). Device according to Claim 3, characterized in that the high-frequency input and output of the high-frequency switch (5, 14) are connected to the cathode of the first diode (D1) and to the anode of the third diode (Dc), respectively, between the capacitor (C1, Cc). that the central diode (D4) is bypassed by two series resistors, the connection point of which is connected to ground by means of a capacitor (C ^), and that the first diode and said second diode (D ^ resp. D ^) and the third diode and said second diode the series circuit of the diode (Dg vs. D2) is bypassed by two series-connected resistors (Rg, R, j and Rg, R1), the connection points of each pair (A, B) being connected to a direct voltage. Device according to claim 1, characterized in that said second high-frequency switch (10) is connected in series with the subscriber line (2) to filter out certain frequency bands, each switch being formed as a T-filter with a parallel circuit including an inductance (11). ) and a variable capacitor (varactor) (12), which is periodically controlled via a switch (S2) by a low - frequency signal applied to a negative DC voltage or to a positive DC voltage. Device according to claim 5, characterized in that the variable capacitor (12) in the cross-section of the high-frequency switch (10) is connected via said switch (S2) to a number of additional switches (S1 ~ Sg) having the same number of positions and switched on periodically, and that the selected positions of the high-hair switches are connected to a positive DC voltage and a low-frequency signal, respectively, which is arranged each time on top of another negative voltage, so that the same number or part of the program channels are closed. 10 67006