IT202100013946A1 - DERIVATOR FOR TELEVISION SYSTEMS - Google Patents

Description

DERIVATOR FOR TELEVISION SYSTEMS

DESCRIPTION

TECHNICAL FIELD

The present invention refers to a shunt for television systems.

STATE OF ART

In a television system, the signal received by the antenna is distributed to a multiplicity? of sockets positioned in different apartments of the building and/or in different rooms of a single apartment.

For the distribution of the signal dividers and shunts are used, i.e. passive components that allow the television signal received by the antenna and suitably amplified by one or more sockets to be distributed equally on all sockets. amplifiers.

The dividers divide the input signal symmetrically on the outputs, have no separation between the various outputs and allow the passage of current between the outputs and the input. These devices are therefore mainly used to divide the risers or, in satellite systems, to carry an SCR or dCSS signal on multiple? took. Given the poor separation between the outputs, no ? the connection of terminating sockets to a splitter is permitted.

The shunts are, on the other hand, products designed to take the signal from a main line (riser) and distribute it attenuated towards one or more? terminal sockets, guaranteeing a high separation between the outlets of the distribution block and the riser. The attenuation of the signal between the input and output of the riser ? typically very small and determined by the particular model of the derivator.

The use of dividers and shunts within a TV system is carried out by carefully studying the signal distribution scheme and evaluating the losses of the system (passive components, coaxial cables, dividers, shunts, junctions, etc.). In particular, the shunts must be chosen in such a way as to accurately balance the whole system, on pain of malfunctioning (caused by too low or too high a signal level at the terminal socket) or instability? of the signal to the terminal socket.

A company involved in the construction of TV systems must therefore keep a large number of shunts in stock, so as to be able to use each time those suitable for the number of outputs and for the attenuation value introduced. Alternatively, such a company will have to? reorder the derivatives project by project.

In the first case there? involves large warehouse management costs, while in the second case these costs are reduced, but in the event of an unforeseen event (e.g. system design error or malfunction of some shunts) the installer can? be in trouble?.

OBJECTS AND SUMMARY OF THE INVENTION

? object of the present invention is to overcome the drawbacks of the prior art.

In particular, ? The object of the present invention is to present a shunt device which is flexible in use and allows its use in different plant conditions.

These and other objects of the present invention are achieved by a lighting system incorporating the characteristics of the attached claims, which form an integral part of the present description.

According to a first aspect, the invention? direct to a shunt apparatus which includes a directional coupler. The directional coupler? equipped with an input port to receive a radio frequency input signal, a coupled port on which it reports a coupled signal equal to the input one but with lower power, and an output port on which it reports a d? output with power substantially equal to the difference between the power of the input signal minus that of the coupled signal. The apparatus further includes at least one branch connector connected to the coupled port so as to receive a signal from the coupled port. The shunt apparatus further includes a user adjustable variable attenuator. The variable attenuator? operably connected between the coupled port and the at least one drop connector for attenuating the coupled signal or a signal obtained by dividing the coupled signal.

A shunt device with these characteristics offers many advantages, particularly in terms of flexibility? of use, as an installer can? to bring with you? the shunt and then choose the attenuation by acting on the attenuator of the device, instead of? having to bring with you? many derivatives with different attenuation to then choose the device pi? suitable for the system.

Advantageously, the variable attenuator (10) ? a variable pitch attenuator, in which the attenuation values that can be chosen by the user are in discrete number. This solution allows a more? simple installation why? the installer, choosing between precise discrete values, can? have the output attenuation under control.

Advantageously the? attenuator ? operated through a knob and/or through a graphical user interface.

In one embodiment, the shunt apparatus comprises a primary splitter electrically connected to the attenuator so as to receive the attenuated coupled signal output from the variable attenuator and split it over two secondary lines, wherein the at least one shunt connector ? connected to one of said two secondary lines to allow the picking up of a signal coming from one of said two lines.

Advantageously, the shunt apparatus also comprises a pair of secondary splitters, each secondary splitter of the pair being coupled to a respective secondary line. There? allows you to have four branch connectors or more? if additional splitters were added in cascade to the others.

In one embodiment, the tapping apparatus comprising a primary splitter electrically connected to the coupled port to receive the coupled signal and split it onto two secondary lines. At least one variable attenuator is therefore provided on one or both secondary lines, so? to allow different attenuation adjustment on the branch ports connected to the secondary lines.

Further characteristics and purposes of the present invention will become clearer from the following description.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will come described hereinafter with reference to some examples, provided for explanatory and non-limiting purposes, and illustrated in the accompanying drawings. These drawings illustrate different aspects and embodiments of the present invention and, where appropriate, reference numerals illustrating similar structures, components, materials and/or elements in different figures are indicated by like reference numerals.

Figure 1 shows a shunt apparatus according to an embodiment of the present invention.

Figure 2 shows a circuit diagram of the apparatus of Figure 1.

Figure 3 shows a variant of the circuit diagram of Figure 2.

DETAILED DESCRIPTION OF THE INVENTION

While the invention? susceptible to various modifications and alternative constructions, some embodiments provided for purposes of explanation are described below in detail.

It must be understood, however, that there is no no intention of limiting the invention to the specific embodiment illustrated, but, on the contrary, the invention is intended to cover all modifications, alternative constructions, and equivalents which fall within the scope of the invention as defined in the claims.

In the following description, therefore, the use of ?for example?, ?etc.?, ?or? indicates non-exclusive alternatives without limitation, unless otherwise indicated; the use of ?also? means ?including, but not limited to? unless otherwise indicated; the use of ?includes / includes? means ?includes / includes, but not limited to? unless otherwise indicated.

With reference to Figure 1 , a shunt 1 according to an embodiment of the present invention is illustrated.

The shunt 1 has a box-shaped body 2 from which six coaxial connectors protrude: the input connector 3 ? intended to receive a cable carrying the input signal, the output connector 4 ? intended to receive a cable carrying the output signal, while the four branch connectors 50, 51, 52 and 53 are intended to receive the branch cables. In other embodiments, the branch connectors can have a different number from the four of the example described here, for example they can be one, two, six, eight, etc.

The shunt then comprises a knob 6 by means of which the installer can? adjust the attenuation between the input signal on connector 3 and the output branch signal on branch connectors 50-53. Clearly other solutions are possible and, instead of knob 6, ? Is it possible to provide other means for adjusting the attenuation, such as a touch display, or a plurality? of buttons to which a different attenuation value is associated.

As can be seen in figure 2, the shunt 1 comprises a directional coupler 7, for example a DBTC-10-13 or TCD-13-4 coupler from Mini-Circuits?, which has an input port P1, a transmitted port P2, a coupled port P3, and an isolated port P4 (ie through which the direct current does not pass) which is terminated by means of a network RC.

The input connector 3 ? connected to input port P1 via a capacitor C5 which filters any DC components of the input signal present at input connector 3.

The directional coupler 7 extracts part of the power present at the input port and makes it available to the coupled port P3, while an output signal is emitted to the transmitted port P2 with power equal to the input power minus that present at the coupled port P3 .

The output signal is made available to the output connector 4 which ? connected to the transmitted port P2 via a capacitor C4 which cuts any DC components present at the transmitted port P2.

Since the capacitors C4 and C5 prevent the passage of direct current towards the coupler 7, in a preferred embodiment, a circuit 30 is inserted between the input connector 3 and the output connector 4, capable of passing the direct current between the two connectors. For example, such a circuit pu? be achieved by two coils that cut the radio frequency and a grounded capacitor connected to the two coils.

The isolated port P4 is instead connected to a balancing circuit 8 which comprises a resistor R1 and two capacitors, C3 and C2, each connected to a different end? of resistor R1 and to ground. The purpose of the balancing circuit? that of correctly terminating the main line 9 which connects the coupled port P3 and the terminated port P4. The balancing circuit 8 pu? therefore be implemented through other types of passive RC networks.

To paired port P3 ? therefore there is a coupled signal S3 which is attenuated by means of a variable attenuator 10 (for example the SJ-4B actuator or the SJ-3B actuator of the SQ-CableDevice?) connected to the knob 6. The attenuator 10 ? connected, via a capacitor C10 to the coupled port P3, and via a capacitor C1 to a primary splitter 11, for example a Mini-Circuits? SBTC-2-10+ splitter. Preferably, the attenuator 10 ? a variable-pitch attenuator configured to introduce uniform loss across the cable TV frequency band, e.g. between 5 MHz and 2350 MHz.

By acting on knob 6, the installer selects the preferred attenuation value (e.g. 0 dB, 2.5 dB, etc.) allowed by attenuator 10.

The primary splitter 11 divides the signal S3 attenuated by the variable attenuator 10 and filtered by the capacitor C1, on two secondary lines 12 and 13. Between the secondary lines 12 and 13 ? a resistor R2 is arranged which helps to maintain the correct impedance matching optimizing the performance of the primary splitter 11. Generally the resistor R2 is foreseen by the manufacturer of the splitter.

The signal present on each secondary line 12 and 13 is in turn divided by a respective secondary splitter (14, 15) on termination lines 16-19 terminated with the branch connectors 50-53.

In the example of figure 2, the primary splitter 11 ? connected to the secondary splitters 14 and 15 by means of two respective capacitors C11 and C12, while each branch connector 50-53 ? connected to the respective termination line by means of a respective capacitor C9, C8, C6, C7. As for the primary splitter 11, also for the secondary splitters 14 and 15, respective resistors R3 and R4 are provided which are connected between the outputs of the splitter.

Examples of values for the components of Figure 2 are given in Table 1 below. Clearly, according to the specific application? It is possible to change the values indicated below by choosing components or equivalent circuits suitable for the case.

Table 1

Figure 3 illustrates a variant of the circuit diagram of figure 2, in which the splitter 11 is connected, preferably by means of a microstrip, to the coupled port P3 of the linear coupler. In this embodiment, two attenuators 10A and 10B are therefore inserted on the secondary lines 12 and 13, so as to be able to adjust the attenuation of the signal directed to the branch connectors. This solution therefore allows for different attenuations between connectors 50-51 on one side and connectors 52-53 on the other.

In a further embodiment, ? It is possible to provide an attenuator before each branch connector so that the attenuation can be adjusted independently on each individual output.

In general, then, ? It is possible to insert an attenuator along any line placed between a branch connector and the coupled port of the linear coupler, so? to get different possibilities? of regulation. For example, can you provide a first output attenuator to the coupled port P3 of the linear attenuator, and then one or more? attenuators after several splitters that carry the signal to the branch connectors.

From the description above ? evident as the? invention allows a great flexibility? during installation, as the addition of the variable attenuator allows you to configure the shunt in an optimal way for the system, without requiring the installer to keep a considerable number of different shunts with different attenuations in stock.

? therefore evident, to a technician of the branch, that ? It is possible to make modifications and variations to the solution described with reference to the figures without thereby departing from the scope of protection of the present invention as defined by the attached claims.

For example, ? evident that the technician of the branch can? make shunts with a different number of shunt ports than those of the example described above. By envisaging a different number of splitters, it is, in fact, possible to obtain a different number of branch lines.

Again, in the example of figure 2 yes ? used a symmetrical 7 directional coupler which required a balancing circuit 8. Are there directional couplers on the market in which the isolated port P4 is not ? accessible and the balancing circuit (at the limit a simple resistance) ? inside the coupler and not accessible to the user. In case you decide to use such a device, the balancing circuit 8 can? be omitted.

Likewise, the components of the example of figure 2 can have different values or be replaced by equivalent circuits, therefore they must not be understood in a limiting sense of the invention, but only as an example of an embodiment. For example, instead of individual capacitors ? It is possible to provide a different passive matching circuit or to use microstrips of the appropriate length to obtain the filter function of the capacitor and adjust the overall impedance of the line to the desired one.

Claims (8)

1. Shunt apparatus (1) comprising: a directional coupler (7) provided with an input port (P1) to receive a radio frequency input signal, with a coupled port (P3) on which it reports a coupled signal equal to the input one but with lower power, and an output port (P2) on which it reports an output signal with power substantially equal to the difference between the power of the input signal minus that of the coupled signal (S3), at least one branch connector (50) connected to the coupled port (P3) in such a way as to receive a signal from the coupled port (P3), characterized by the fact of further comprising a user adjustable variable attenuator (10), the variable attenuator being operably connected between the coupled port (P3) and the at least one branch connector for attenuating the coupled signal or a signal obtained by dividing the coupled signal. The shunt apparatus (1) according to claim 1, wherein the variable attenuator (10) is? a variable pitch attenuator. 3. Shunt apparatus (1) according to claim 1 or 2, wherein the attenuator ? operated by a knob. 4. Shunt apparatus (1) according to claim 1 or 2, wherein the attenuator ? operated through a graphical user interface. The shunt apparatus (1) according to any one of claims 1 to 4, further comprising a primary splitter (11) electrically connected to the attenuator (10) so as to receive the attenuated coupled signal output from the variable attenuator (10 ) and divide it on two secondary lines (12,13), in which the? At least one branch connector (50) ? connected to one of said two secondary lines to allow the picking up of a signal coming from one of said two lines. The shunt apparatus (1) according to claim 5, further comprising a pair of secondary splitters (14,15), each secondary splitter of the pair being coupled to a respective secondary line. The shunt apparatus (1) according to any one of the preceding claims, further comprising a primary splitter (11) electrically connected to the coupled port (P3) so as to receive the coupled signal and split it onto two secondary lines (12,13), in which l?at least one variable attenuator (10A,10B) ? adapted to attenuate a signal present on one of said two secondary lines (12,13), and in which the at least one branch connector (50) ? connected to one of said two secondary lines to allow the picking up of a signal coming from one of said two lines. The shunt apparatus (1) according to claim 7, wherein ? there is a variable attenuator (10A,10B) on each secondary line (12,13).