EP2106049A2 - Device for signalling flaws in a signal distribution system for satellite signals - Google Patents

Abstract

The device has a cable distribution network, where the device evaluates a voltage distribution at satellite signal output of programmable signal converter for signaling of operational conditions. The device signalizes an alteration between voltage levels of operational direct voltage, to display, whether satellite receivers (SE1,SE2,SE3) support the communication operation of the programmable signal converter by system-intern defined requirement duration.

Description

The invention relates to a device for signaling operating states, in particular faulty configured devices in a Signalverkeil system with a cable distribution network that simultaneously supplies a plurality of radio receiver via a common coaxial cable with a requested satellite signal. The common coaxial cable of the cable distribution network for which the subject matter of the invention is usable transmits the broadcast programs to the radio receivers on different output frequency bands.

Technical background

Known conventional satellite systems transmit a multiplicity of programs, radio, data services in different frequency blocks and with different antenna polarization to the satellite receiver. It is known to use various radio frequency bands, such as the lower band between 10.7-11.7 GHz and the upper band 11.7-12.75 GHz and a use of at least the vertical and the horizontal wave polarity for transmitting satellite signals to the satellite -Antenna. Since it is not possible at the same time neither both bands nor both Wellenpolaritäten to be transmitted from the satellite antenna system via a single coaxial cable to the satellite receiver, a programmable signal converter is required, which at the request of a satellite receiver each with only a subband of available in the bands satellite signals only a wave polarity in an intermediate frequency range, for example, 950MHz-2150 MHz converts and transmits to the satellite receiver.

A signal distribution system for satellite signals with a common cable uses narrowband output signals for each satellite receiver. When installing a cable distribution network each receiver is assigned a fixed output frequency band and the receiver sends via the common terminal a control signal with control commands to a programmable signal converter, which contains both information on the desired frequency block and the frequency within this block and an identification of the requesting STB (so-called User band number).

The signal converter selects the desired frequency block and makes a frequency translation from the selected frequency within that block to the output frequency associated with the requesting receiver. The control is closely based on DiSEqC, in principle only defined additional custom commands.

However, sharing a port in the sense of a multi-recipient control bus required some significant changes to the system specification and protocol of control commands over DiSEqC. The transmission duration of the control signals takes place exclusively in a short command sequence of 5 bytes with a length of about 68 ms. Is in FIG. 1 shown.

In receive mode, the receivers permanently give a DC voltage of 13V on the common coaxial cable, just for sending a control command, the voltage from the transmitting satellite receiver is raised to 18V a few milliseconds before the start of the command and lowered again a few ms after the end of the command,

The connection of the receiver to the common coaxial cable of the cable distribution network will each include a switching diode reverse biased when the receiver provides a voltage level of 13V to the programmable signal converter. However, during a communication operation within a system-internally defined control period of 68 ms, the receiver raises the voltage level of the operating voltage to a second level value of 18V and adds thereto a modulated control signal on a carrier frequency of 22 kHz. The switching diodes, via which the receivers are connected to the cable distribution network, effect during decoupling of the control command, a decoupling of all receivers are in the receive mode to avoid distortion of the control signal, which is modulated on the 22 kHz carrier.

State of the art

The journal Astra Aktuell, No. 58, March 2007 discloses in a "Satellite Direct Reception for Single Cable Distribution Systems" article a single cable reception system.

According to the CENELEC EN50494 standard further mentioned herein, such a single-cable receiving system can provide a plurality of satellite receivers with a desired satellite broadcasting signal over a single cable. The system uses a multi-switch or a programmable signal converter (LNB = Low Noise Block). The multiswitch receives several broadcast signals via several tuners and transforms them into different frequency bands. A common cable is used to transmit to the satellite receivers with multiple satellite receivers connected to the common cable.

The satellite receivers may sequentially transmit their request for a satellite signal having a desired broadcast program to the programmable signal converter via the common cable, for example, at the request of users, each during a communication operation with a system-defined control duration via the common coaxial cable. For each radio receiver for a frequency band is assigned, in which the multi-switch transforms the respective requested broadcast signals to transmit them to the respective radio receiver.

From the DE102005036810B4 A solution is known to solve a blocking problem by permanently fed 18V by means of an RF junction box, which is integrated in a monitoring device. The junction box disconnects a connected, improperly configured receiver from the cable distribution network when a voltage above a selectable threshold is applied for longer than a specified time. Alternatively separation, if due to the permanently high voltage the current through the can exceeds certain limits regarding height and duration.

The international document WO2006120203A2 discloses the connection of the satellite receiver to a cable via a so-called "smart splitter". This includes additional active monitoring and switching equipment where two or more paths are merged. When a control command is detected at one connection, the other or the others are forcibly disconnected from the bus. At the same time should be informed with a "busy tone", which can be detected by a DiSEqC return channel satellite receiver, the forcibly separated branch that control commands are currently not forwarded to the distribution device. The solution is primarily for locally identifying the state of a branch of the bus ie green - control command of the relevant branch is forwarded, red - control command of the relevant branch is not forwarded.

From the patent DE19749120C2 For example, a single-cable system is known which contains a device for generating and evaluating a collision protection signal. This ensures that at any given time, communication with a controller is feasible only on the part of a single radio receiver.

The device for generating and evaluating a collision protection signal is constructed so that before the dispatch of a designated therein as "control signal" channel change command first an actual control signal upstream collision protection phase is performed, in which first checks the data bus for activities of another radio receiver is, so that only if no activity on the data bus is detected, be sent by the broadcast receiver actual control signals to the control unit. For this purpose, the collision protection phase is at least three-parted, namely a first bus activity observation phase for a period of time (t0) in which it is checked whether other radio receivers or the control unit active on the bus, a subsequent bus request phase having a duration (t2) in which a signal signaling an activity is delivered by the radio receiver to the bus, and a subsequent further bus observation phase for a second time duration (t2) in which no signal is present delivered the bus.

Furthermore, it is known from the aforementioned standard EN50494 that a satellite receiver during the transmission of a control signal applies a DC voltage of about 18V to the common cable. If no such message is transmitted via this cable, a maximum voltage of 14 V is usually applied to this cable during operation. A diode matrix, which can be implemented in the outputs of the connected satellite receivers, prevents this from overloading each other when transmitting control signals.

The publication DE102005036810B4 points in this context on the problem that satellite receivers also exist, which can take on a voltage applied to its output DC voltage, which can assume a first voltage state of about 14V or a second voltage state of about 18V, a desired polarization plane via a multi-switch or a Select LNB converter. Such a satellite receiver may block the control signal transmission of other satellite receivers connected to this cable due to misadjustment by the continuous application of a voltage of 18V to the common cable of a single-cable receiving system.

DE102005036810B4 proposes to solve this problem, an HF-can, in which a detector device is provided, which checks the DC voltage supplied. This detector device then switches off the connected receiver or disconnects it from the common cable if the DC voltage fed in by this receiver remains at the excessively high DC voltage level for a corresponding predefinable period of time. The time to switch off a faulty receiver is set so that a certain number of DiSEqC commands can pass through the bus unhindered.

The following disadvantages exist in this prior art:

For already existing systems, new, comparatively expensive and expensive antenna sockets must be installed. The known means are part of a mostly existing cable network or must be integrated in a user device and the respective participant itself has no advantage of a new acquisition of such means, such as a new antenna socket. The installation of such a new antenna socket in a particular participant is only for the other. Subscribers connected to the same transmission line are an advantage. Also, such antenna doses are fed in practice by the DC voltages connected thereto receiver. Thus, a not insignificant voltage drop of these DC voltages at these antenna doses of sometimes more than 1 V to record. Such a voltage drop can affect the function of a multi-switch or other standard-compliant components such a house distribution.

Although previously described display devices allow with the mentioned restrictions a signaling of the command transmission, but not a distinction of the normal receiving operation of the de-energized idle state.

Description of the invention

The object of the present invention is to provide a device for signaling operating conditions in a cable distribution network, which avoids the aforementioned problems, and manages without reinstalling existing network components

It is a further object of the invention to provide a recognizable for the user signaling the problem cases or the operating condition, such as troubleshooting, installation assistance or to control the ongoing operation.

This object is achieved by a device for signaling operating states in a signal distribution system for satellite signals with a cable distribution network.

The cable distribution network includes a programmable signal conversion device which converts the broadcast signals of different satellite transponders into different output frequency bands. Such a programmable signal conversion device is defined for example in the standard DIN EN 50494 as a single cable interface (SCIF) and may include a block converter (LNB) or multi-switch. The programmable signal transceiver (SCIF) has at least one satellite signal output providing satellite signals requested simultaneously for a plurality of satellite receivers via a coaxial cable, wherein the requested satellite signals are converted to different output frequency bands and each satellite receiver is assigned a single frequency band. For a fault-free detection of the control commands, it is necessary that only a single occupies the communication mode to the Signalumetzeinrichtung. That is, multiple satellite receivers must send their control signals in sequence.

The satellite receivers connect the transmission of control signals to the programmable signal conversion device with the coupling of different voltage levels of the DC operating voltage via switching diodes in the coaxial cable. A first voltage level indicates a receiving operation of the radio receiver, while a second voltage level defines the communication operation of a satellite receiver.

In order to indicate whether a satellite receiver occupies the communication mode of the programmable signal converter beyond the system-internally defined request duration, according to the invention the device for signaling operating states evaluates a voltage profile at the satellite signal output of the programmable signal Signal converter and signals at least one change between a first voltage level of the DC operating voltage and a second voltage level, wherein the second voltage level corresponds to the communication operation of a satellite receiver.

Since each receiver indicates its communication mode on the common coaxial cable through the second voltage level, it is necessary to indicate with the device for signaling operating states according to the invention, when a partial receiver occupies the communication mode of the programmable signal conversion device beyond the system internally defined request duration and the Communication mode so that it is not available for other connected satellite receiver.

The device for signaling operating states is advantageously designed such that it signals when a satellite receiver occupies the communication mode of the programmable signal conversion device beyond the system-internally defined request duration and furthermore signals that at least one satellite receiver connected to the programmable signal conversion device is in the receive mode.

In a further preferred embodiment of the invention, the device includes a voltage level detection, which only outputs a signal when the DC operating voltage on the common coaxial cable beyond the system-defined internal control defect duration takes the second voltage level.

In addition, it is advantageous that the signaling device has additional means for signaling the control signal transmitted in the communication mode on the common coaxial cable. This will allow correct docking of all satellite receivers to the coaxial cable.

In a further embodiment, the invention uses for displaying light-emitting diodes, which are connected via at least one voltage-dependent threshold value switch on the common coaxial cable.

A particularly convenient signaling occurs when processor means for evaluating data, transmitted control commands and operating states on the common coaxial cable are cached in a command buffer. Thus, a faulty satellite receiver can be determined on the part of the programmable signal converter. The detection of causes of disturbances in the receiving mode, such as access to the same output frequency by multiple receivers is possible, such as the transmission of configuration commands while receiving other receivers

Such a device advantageously contains an alphanumeric display for displaying control command elements transmitted in the control signal or outputting the identification of Satellite receivers that are in receive mode. For this purpose, the device additionally has means which recover and display its identification from the operating state of the programmable signal conversion device or from the control signal of the requesting satellite receiver. In order to identify which satellite receivers have successfully programmed the signal conversion equipment prior to a blockage failure by a failed satellite receiver, the signaling apparatus may additionally comprise satellite signal detection means for which satellite receivers the signal conversion equipment provides a converted output frequency band.

The invention can be used at any point in the distribution system and is not bound to the branches.

Preferred Embodiment: Evaluation and Signaling of the Increased 18V Level of DC Voltage with Very Simple Means, e.g. using a zener diode, thereby signaling the failure of the permanent supply of 18V as well as the short-term supply of 18V in regular operation in terms of a bus activity indicator. Signaling e.g. (but not limited to) optically by LED.

Further preferred embodiments limit the signaling to the supply of 18V longer than a selectable period of time, and thus to the fault case.

Further preferred embodiments provide that the error signaling is reset manually by the user, so that the cause of the error remains identifiable even beyond the duration of the actual occurrence of the error.

Signaling the voltage level for the receive mode allows an indication of the usage of the system as opposed to the de-energized idle state or fault short circuit / undervoltage.

A further preferred embodiment provides for the evaluation and signaling also of a modulated AC voltage or a modulated AC current, e.g. 22 kHz, thereby e.g. Signaling one for conventional systems.

Further preferred embodiment: use of a more complex evaluation circuit, e.g. using a microprocessor, for the evaluation, buffering and signaling of the transmitted control commands or elements thereof, e.g. Display by means of LCD display.

Another preferred embodiment provides for use of a more complex evaluation circuit, for example using RF filters, RF detectors and PLL synthesizers, for evaluating and signaling the occupancy of the RF output frequencies of the distribution device with regard to level and modulation type. Enables, for example, the fast detection of used and unused output frequencies in receive mode as well as the detection of erroneous assignments of these frequencies to user-band numbers due to incorrect configuration,

Further preferred embodiment: integration of the invention for evaluation and signaling of the bus state in the distribution device,

Further preferred embodiment: Integration of the invention for evaluation and signaling of the bus state in the STB.

Further preferred embodiment: Integration of the invention for evaluation and signaling of the bus state in a separate, only when needed connected to the bus device in the sense of an installation aid or antenna measuring device.

The abovementioned incorrect operation is thereby recognized, for example, by a service technician and can be assigned to the corresponding output of the device according to the invention, for example a multiswitch.

In the event of a fault, this allows a simple, uncomplicated analysis, which can deliberately be remedied in the event of a faulty operation.

The solution according to the invention can be integrated in existing systems, for example by installing a corresponding multi-switch without further installation effort and in particular when supplying several households via a line without entering the individual apartments.

In an advantageous embodiment, the signaling always takes place precisely when the said DC voltage continuously assumes a correspondingly high voltage level for longer than a predetermined period of time.

In a further advantageous embodiment, the signaling is maintained until it is manually canceled by the manual operation of the means provided for it.

In a further embodiment, in addition, the operating state in which at least one radio receiver connected to the common cable is in operation is also signaled, for example, via a further light-emitting diode or via a second state of the first light-emitting diode. In this case, the said DC voltage may preferably be less than 14V. This state can be represented, for example, in that the first light-emitting diode is a so-called "multi-color light-emitting diode", which is characterized in that it lights up in different colors in different voltage states, and this multicolor light-emitting diode lights up in a first color, if the DC voltage assumes a first voltage state of greater than 17V, and that this multicolor LED lights in a second color when the DC voltage assumes a second voltage state of less than 14V.

In the following, a preferred embodiment will explain the invention.

FIG. 2 shows an exemplary embodiment of the invention

FIG. 3 schematically shows a conversion of frequency ranges of several available fixed to fixed output frequency bands

FIG. 4 shows an apparatus according to the invention for signaling operating conditions in a signal distribution system. Via a low-pass inductance L and a series resistor, a light-emitting diode LED 1 is connected to a common coaxial cable K1 in order to signal the receiving state. In series with a light emitting diode LED 2 is a threshold value D, so that the light emitting diode LED 2, only lit when the operating voltage reaches the voltage level for the communication mode.

In a residential complex several satellite receiver SE1 to SE3 are connected to a single-cable receiving system of the type mentioned. This single-cable receiving system has a multi-switch SCIF with at least one output EP. At the output EP several satellite receiver SE1 to SE3 are connected via a common cable.

In a household, a satellite receiver SE2 is set incorrectly in such a way that it applies a continuous 18V DC operating voltage to its input during operation. This blocks the transmission of control signals from other satellite receivers SE1 and SE2 via the common cable to the multi-switch SCIF.

In the multi-switch SCFI is a device for signaling operating states according to the invention, which indicates via a light emitting diode, by constantly lighting the voltage level, which is provided for the communication operation. Thus, a service technician or an interested layman can immediately detect the cause of the fault and inform the households connected to this common cable accordingly.

In the simplest case, the signal means may be a "multi-color LED" which lights up at different voltage states in different colors, and that this first LED lights in a first color when the DC voltage corresponds to the first voltage state and that the first LED lights in a second color when the DC voltage corresponds to the second voltage state.

Advantageously, the one "multi-color LED" can be used as an operating status display, which signals different voltage levels by different colors

The signaling device according to the invention may be both a multi-switch in a satellite multiswitch system and a cable headend in a cable television system as well as a frequency converter, a so-called Low Noise Block (LNB) in a satellite receiving system.

Claims (12)

Device for signaling operating states in a signal distribution system for satellite signals with a cable distribution network, In which the signal distribution system includes at least one programmable signal converter with at least one satellite signal output, which simultaneously supplies several satellite receivers with a requested satellite signal via a common coaxial cable of the cable distribution network on different Ausgangsfrequenzbändem In which a plurality of satellite receivers for the signal converters provide, via the common coaxial cable, a DC operating voltage indicating a reception operation of the satellite receiver by a first voltage level • And in which also send different satellite receiver each during a communication operation with a system-internally defined Steuerbefehldauer on the common coaxial cable their request for a satellite signal with a desired broadcast program to the programmable signal converter by the requesting satellite receiver during the defined Steuerbefehldauer the DC operating voltage with a provides a second voltage level and adds a programmable signal converter control signal to the second voltage level, characterized in that the device for signaling operating conditions evaluates a voltage profile at the satellite signal output of the programmable signal converter and signals at least one change between the voltage levels of the DC operating voltage to indicate whether a satellite receiver occupies the communication mode of the programmable signal converter beyond the system-internally defined request duration addition. A signaling device according to claim 1, comprising a voltage level detection which outputs a signal only when the DC operating voltage on the common coaxial cable exceeds the second internal voltage level beyond the control deficit time defined internally by the system. Signaling apparatus according to claim 1, comprising additional means for signaling the control signal transmitted in communication mode on the common coaxial cable. Device for signaling according to claim 1, with light-emitting diodes which are connected via at least one voltage-dependent threshold value switch on the common coaxial cable. Apparatus for signaling according to claim 1, comprising processor means for evaluating, latching in a command buffer and signaling the transmitted control commands. A signaling device according to claim 1, including an alphanumeric display for representing control command elements transmitted in the control signal. A signaling device according to claim 1, which retrieves and displays its identification from the control signal of the requesting satellite receiver. A signaling device according to claim 1, including satellite signal detection means for utilizing the output frequency bands. A signaling device according to claim 2, wherein the signaling is maintained until manually reset. A signaling device according to claim 1, comprising additional signaling means indicating that at least one satellite receiver connected to the programmable signal conversion means is in receive mode. A signaling device according to claim 7 connected to a satellite receiver for indicating that the satellite receiver is correctly configured for both receive mode and communication mode in a cable distribution network having a common coaxial cable. A signaling device according to claim 1, which is included in a service tester for installing and servicing cable distribution networks.

Images