DE20211276U1 - Switching device for a satellite reception system - Google Patents

Description

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Switching device for a satellite reception system

The present invention relates to a switching device for a satellite reception system according to the preamble of the main claim. Such devices are well known as so-called "multiswitches" and are used in single or multi-user satellite systems as connection nodes between the input-side converters (so-called LNB = Low Noise Block Converters) that convert the actual satellite high-frequency signal into a satellite intermediate frequency signal, which provide the input signals for the input connections of a generic switching device, and one or more receivers (reception systems specially configured for satellite reception), which then convert the satellite IF signal into a suitable television signal for the user on the output side.

To optimize channel usage, satellite reception signals are available in two polarization planes (horizontal/vertical) and in two separately controlled frequency bands, so that, with every possible combination of these two parameters, each satellite can typically be received with four of these so-called IF planes. Accordingly, the multiswitches known from the state of the art have a number of input connections that is a multiple of four; a typical configuration of known multiswitches offers around eight input connections for connecting two satellite systems (e.g. Astra I and Hotbird in Germany) with four IF planes each.

The connection means known in the state of the art then recognize from the receiver signal present at the output connection which of the input connections is to be connected according to the IF level assignment. Typically, this connection scheme is standardized and is selected by so-called switching criteria (namely control information of the receiver). So far, so-called analog switching criteria

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usual, whereby the selection of the required IF level was selected by a 14/18 volt level; additionally or alternatively a low frequency tone signal is used, typically 22 kHz. So-called digital switching criteria according to the DISEqC standard use a modulated 22 kHz signal.

In practice, however, it often happens that some satellites (satellite systems) only transmit in one frequency band and/or with only one receivable polarization plane, so that it is not necessary to provide the four IF planes for these satellites. However, since conventional multiswitches according to the state of the art generally reserve four inputs per satellite system due to the described, rigid and clear assignment, numerous inputs remain unused, which means that the switching device is fundamentally over-dimensioned: More (rigidly configured) inputs must be provided than are actually required for reception. Until now, it was not possible to use these input connections for other satellites without interfering with the generation of the selection control signals on the receiver side.

However, since multi-switch technology is becoming an established mass product and there is an increasing need for optimization in terms of production costs, the aim of the present invention is to optimize conventional, generic switching devices for a satellite reception system with a view to more flexible, universal assignment and configurability of the input connections to one or more output connections. In particular, the rigid assignment of all four IF levels to each connectable satellite system, which has been necessary due to the previous standardization, is to be broken, so that in the ideal case each input connection can be connected to an IF satellite signal that is actually required.

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Furthermore, it is an object of the present invention to make such an improved switching device for a satellite reception system accessible to a flexible plurality of users in a multi-user system, wherein it is particularly an object to design the device to be expandable into any number of parts.

The object is achieved by the device having the features of the main claim; advantageous developments of the invention are described in the subclaims.

In an advantageous manner according to the invention, the means for selectively connecting one of the plurality of input connections to the output connection at high frequency are preceded by configuration and storage means within the scope of the invention, said means being configurable and programmable by means of an interface. The configuration and storage means ensure, by means of a non-volatile memory unit, that any of the input connections (which receives one of four possible IF levels of an associated satellite system) can be permanently assigned to the output connection in response to the associated selection control signal. In other words, the present invention breaks through the known, rigid configuration and allocation scheme "four IF levels per satellite system with four associated input connections, which are selected according to the selection control signals and the associated switching criteria", and it is now possible to carry out any allocation of any of the input connections for any IF levels of satellite systems in an efficient manner that optimizes the hardware outlay. In an extreme case, a multi-switch according to the invention with eight input connections could therefore address eight different satellite systems, provided that only one frequency band and one receivable polarization plane are required per satellite. Such a configuration is flexible and can be implemented in one-

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Can be set or configured in various ways via the interface.

According to a further development, this programming is carried out using a commercially available PC or another, preferably portable programming unit, which is then connected to the device according to the invention or its configuration and storage means via common data buses, e.g. USB. Such a programming interface will particularly preferably have visual or graphical aids and control surfaces that enable the operator (the configurator) to set the desired configuration for the relevant system in a simple and clear manner and then -- more preferably -- to store it permanently in a non-volatile memory unit of the system.

In a preferred embodiment of the present invention as a multi-subscriber system, a plurality of output connections are provided, wherein the configuration and storage means according to the invention preferably provide individual configurability for each of the output connections (although implementations with a uniform configuration are also conceivable and favorable). Particularly suitable for this purpose are configuration units provided for each output connection, which, ideally implemented in the form of assignment tables, can specifically address the required input for each of the selection control signals generated by an output-side user and connect it at high frequency. It is also particularly preferred in this implementation form as a multi-subscriber system if the user-specific assignment units can be provided with configuration data, for example by means of a central data bus from a common, central storage unit.

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The prerequisite for the proper implementation of this inventive principle is that the selection control signal, which is typically introduced via the output connection and generated by the connected receiver, for example according to the DISEqC protocol, is separated from the high-frequency signal (flowing into the receiver) and then reliably interpreted in terms of data, so that the aforementioned allocation unit provided in accordance with the further development can be reliably provided with control data.

A particularly preferred form of implementation of the present invention with regard to flexible and scalable multi-user systems lies in the modularization provided in accordance with the further development: Here, it is firstly provided that a so-called basic module is provided as the core of each switching device according to the invention, which is independently operational and receives all input connections (and loops them through to the expansion modules provided in accordance with the further development), while only a limited number of output connections, typically 4, 6, 8 or none, are present in the basic module. The basic module itself then contains the central storage unit, which is connected in terms of data to the assignment units assigned to each user-side output connection, as well as the (only) central programming interface, so that the joint setting and configuration can take place here, for example at a suitable central location within a larger house (or residential complex or spatially extensive distribution network). The respectively connectable extension modules then enable the flexible assignment of further output connections, which can each, as described above, be selectively connected to the plurality of input connections in the manner according to the invention by individual configuration, detached from the rigid limits of the conventional four-IF level assignment scheme.

As a result, the present invention achieves that, without receiver-side or other manipulative

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Interventions, an assignment of different satellite IF levels to input connections of a multiswitch can be carried out in an extremely flexible and hardware-technically efficient manner; in particular, the invention ensures that the previous limit of "four input connections per satellite system" can be effectively broken.

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Further advantages, features and details of the invention emerge from the following description of preferred embodiments and from the figures; these show in

Fig. 1: a block diagram of a basic unit with eight input connections and two output connections and an extension module with an additional output connection and

Fig. 2: an exemplary representation of a graphical user interface for programming the unit according to Fig.

1.

As shown in Fig. 1, a multiswitch 10 as a switching device according to a preferred embodiment of the invention has a plurality in the form of eight input connections _10a to 10h, to each of which a converter unit (LNB) of a satellite module can be connected at any high frequency. Accordingly, SAT IF signals are present in the ranges 950 - 1,950 MHz or 1,100 to 2,150 MHz.

The connections 10 are each followed by a high frequency amplifier 12, which is primarily intended to compensate for the attenuation caused by a downstream directional coupler field 14. The directional couplers 14 provide the RF signal present on the input connections 10 _a to 10 _h to an RF switch (selection switch) 16, via which the signal from one of the eight lines is then selectively selected and provided to an output connection 18 for connection to an otherwise known, external satellite receiver. The multi-switch unit 10 duplicates, as can be seen in Fig. 1, the chain of directional couplers 14, selection switch 16 and output connection 18 for a second output.

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output connection 20 with corresponding parallel circuitry consisting of directional couplers 22 and changeover switches 24.

In addition, the device according to the invention has the possibility of flexibly assigning the assignment of input connections (and corresponding RF signals) to selection control signals fed in on the output side: A selection control signal generated by a connected receiver (not shown), usually a DISEqC control signal, is present via the output connections 18 and 20. Such a low-frequency signal is coupled out of the high-frequency line running to the selection unit 16 or 24 by means of a low-pass filter 30 shown schematically and is detected and interpreted by means of a decoding unit 32 provided separately for each output-side channel, namely with regard to the necessary switching criteria. This signal is fed to a downstream assignment unit 34 ("mapping table") with the aim of generating a switch configuration of the selection switches 16 or 24 associated with the decoded switching criterion from this table, thus contacting the associated input connection at high frequency.

As can also be seen from Fig. 1, all allocation units 34 are connected together in terms of data to a central permanent storage unit 38 (as a central mapping table) by means of a data bus 36, which is provided in particular for the non-volatile storage of the configuration data.

External programming is then carried out in this permanent storage unit 38 by means of a programming interface 40 or an associated external data bus or input 42, typically a USB port for an externally connectable PC or similar programming unit.

Fig. 1 also illustrates the interaction of the unit 10 designed as a basic unit or basic module

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with an extension module 50, which receives the eight input connections 10 _a ... 10 h looped through in parallel (and in turn loops them through to possible subsequent further extension modules). In addition, the extension module creates space for one or more output-side channels for an output connection 52; parallel to the output-side channels described above, an arrangement of directional couplers 54, switch 56, low-pass filter 30 for the selection control signal, decoding unit 32 and allocation unit 34 is provided here. In terms of high frequency, the high-frequency signal of the respectively selected input line then flows to the output connection 52, depending on the switch position of the unit 56. The data bus 36 for the allocation unit (mapping table) 34 is further looped through.

In practical use, the person responsible for configuration now has the option of connecting several satellite units, in particular more than two, to the eight input connections 10 _a to 10 h; in particular, fewer than four IF levels can be connected and freely configured per satellite unit. This is done using a visual and graphically operable user interface, shown as an example in Fig. 2, of a PC connected to connection 42; the associated configuration data is stored in unit 38 and then made available individually to the mapping tables 34 via data bus 36. In practical operation, this makes it possible for each of the receivers connected to output connections 18, 20, 52 to access the input connections selectively at the same time and freely configured according to the respective mapping table, or a common central configuration takes place. Ideally, the eight input connections are fully occupied by active satellite IF levels.

Claims (10)

1. Switching device for a satellite reception system with
a plurality of input terminals ( 10 _a . . . 10 _h ) designed for connection to satellite intermediate frequency converters and
at least one output terminal ( 18 , 20 , 52 ) designed for connection to a user-side receiving device,
wherein means ( 16 , 24 , 56 ) are provided for selectively connecting one of the plurality of input terminals to the output terminal at high frequency in response to a selection control signal applied in particular via the output terminal,
characterized in that
the connecting means are preceded by configuration and control means ( 32 , 34 , 36 , 38 , 40 ) which can be configured and programmed by means of an interface ( 42 ) preferably implemented in data form such that a selection control signal can be permanently assigned to any of the input connections receiving the satellite intermediate frequencies of a predetermined polarization plane and a predetermined satellite frequency band. 2. Device according to claim 1, characterized by a plurality of output terminals which are designed independently of one another for connection to one of the input terminals by means of the connection means, wherein the configuration and control means for each of the plurality of output terminals has individually configurable allocation units ( 32 , 34 ) for assigning user-specific selection control signals to input terminals. 3. Device according to claim 1 or 2, characterized in that the configuration and control means are designed to cooperate with a common, central and non-volatile memory unit ( 38 ). 4. Device according to one of claims 1 to 3, characterized in that the configuration and control means can be configured and programmed by means of an externally connectable data processing device, in particular a PC via a USB interface, wherein further preferably the assignment of selection control signals to input connections can be programmed by means of a graphically supported operator unit on the data processing device. 5. Device according to claim 4, characterized in that the data processing device is designed to be portable. 6. Device according to one of claims 1 to 5, characterized in that the selection control signal is an analog voltage or low frequency signal or a control signal according to the DISEqC standard. 7. Device according to one of claims 1 to 6, characterized in that the device is implemented modularly with a basic module ( 10 ) having the plurality of input connections, preferably at least one output connection and a programming and/or data bus and which is independently operable, which can be expanded by at least one non-independently operable extension module ( 50 ) for at least one additional output connection ( 52 ), wherein the extension module for configuration information can be connected to the basic module in terms of data. 8. Device according to claim 7, characterized in that the plurality of input connections are looped through the basic module and at least one extension module. 9. Device according to one of claims 1 to 8, characterized in that a complete deactivation of an output connection can be set by means of the configuration and control means. 10. Device according to one of claims 1 to 9, characterized in that at least one additional input connection is provided for a terrestrial and/or cable-based high-frequency signal.