EP1693980A2 - Low Noise Block down converter (LNB) for reception of Direct Broadcast Satellite (DBS) signals - Google Patents

Abstract

The receiver has a ZF matrix with frequency converter applying a selected output to a preset ZF frequency band. A coupler block concatenates ZF signals from a ZF converter block and outputs switching signal to an output terminal of cascaded satellite receivers. A power supply device and a micro controller device (26) receive the switching signal and output a control signal to the frequency converter for controlling the matrix. Independent claims are also included for the following: (1) a method of designing a direct broadcast satellite system (2) a method of pairing or coupling of satellite receivers and low noise blocks.

Description

The invention relates to an LNB receiving device according to the preamble of claim 1, a method for forming a DBS system or for connecting a satellite receiver to a DBS system and a method for pairing between an LNB and a satellite receiver.

Satellite receivers generally have a satellite antenna, e.g. As a symmetrical parabolic antenna or offset parabolic antenna, for receiving and bundling of DBS signals of a satellite, the bundled signals are bundled on a receiving system serving as LNB (low noise block converter, low-noise converter). In this case, the LNB generally has a horn or feed horn, a SHF filter (SHF = Super High Frequency, in particular in the range 3 to 30 GHz), a polarization diverter for separating the satellite signals of different polarization directions and a vertical RF signal respectively mixed with the lower oscillator frequency and the upper oscillator frequency, whereby in a conventional manner a superposition is achieved whose output frequencies are the difference and sum of the incoming signals, of which subsequently only the lower frequencies are transmitted through band pass filter. This results in the output of the intermediate frequency converter block thus four output signals, namely a lower horizontal and lower vertical band of 950 to 1,950 MHz and an upper horizontal and upper vertical band of 1100 to 2150 MHz, which are output to an IF matrix, the in turn, at multiple outputs allows the optional access to each of the four incoming frequency bands. Conventionally, a plurality of satellite receivers are connected to these multiple lines via a plurality of lines routed in parallel or satellite tuner connected to the selection of the respective frequency band z. B. a DC switching voltage between 14V and 18V to select the polarization plane and a 22 kHz switching signal to select the respective lower and upper intermediate frequency band output. This results in a star-shaped distribution of z. B. a multi-switch to each connected satellite receiver or receiver.

Furthermore, the receivers may output standard control commands according to the DiSEqC (Digital Satellite Equipment Control) standard, in which the 22 kHz switching signal is used as a carrier for digital messages, to the LNB for selecting the respective frequency band.

US 6,205,185 B1 describes a receiver for a DBS system and a method for implementing various receive modes.

US 6,334,045 B1 describes a satellite system which can transmit signals of two different frequencies and polarities simultaneously via the same cable. Here, two different polarity commands from two or more different sources are accepted simultaneously.

From the provided outside the unit satellite antenna and LNB thus generally several lines to the individual satellite receivers must be performed, but this is complex and costly, especially for longer distances. However, the number of receivers used in the home area is increasing as multiple tuners are operated, in particular video recorders, e.g. B. DVR (Digital Video Recorder), parallel to the TV sets.

The invention is based on the object to provide an LNB receiving device and a method for their use, which allow a small additional retrofit effort when using multiple satellite receiver.

This object is achieved by an LNB receiving device according to claim 1. The dependent claims describe preferred developments. In particular, methods for using these LNBs are provided, e.g. A plug & play method of connecting another satellite receiver to a satellite receiving system having such an LNB, and a method of pairing an LNB with a satellite receiver, i. for pairing or verifying, authenticating or verifying that a subsequent satellite receiver is allowed. The invention also relates to the LNB with the LNB receiving device.

According to the invention, the IF frequencies provided by the IF matrix (intermediate frequencies, IF) are thus received by a second IF converter block, frequency converters, preferably adjustable oscillators, in particular voltage-controlled ones, being provided at the outputs of the IF matrix Oscillators (VCOs) are provided which, depending on a control signal, request a respective frequency band from the IF matrix (ie control the matrix to output the frequency band) and each time to a predetermined, fixed frequency band. Subsequently, these fixed frequency bands are superimposed or combined (superposed) in a coupler block (combiner, combiner block) and output to a single output cable. The predetermined frequency bands are separated within the IF frequency range of 950 to 2150 MHz and advantageously have a bandwidth set by bandpass filters. The Bandwidth advantageously corresponds to the bandwidth of the transponder, the z. B. is less than or equal to 40 MHz.

The output signals of the VCOs can optionally be output via baluns or baluns.

According to the invention advantageously only a single output cable is provided, which is a clear advantage over conventional star distributions of a multi-switch to each receiver. The multiple satellite receiver can be connected to the one output cable z. B. be connected by a cascade circuit or shared bus circuit or series connection; each of the satellite receiver is assigned a frequency band, so that in several frequency bands corresponding to more than four, z. B. eight satellite receiver can be connected. The satellite receivers can be connected in series with a cable, for example in multi-storey houses from one floor to the other, up to eight floors, with only one cable.

The setting or selection of the respective frequency band by the satellite receiver is again - according to conventional satellite receivers or DBS systems - via a DC switching signal and 22 kHz signal, which is returned via the one output line and in the LNB receiving device of the invention a control device recorded and used to control the VCOs.

The LNB reception device according to the invention can in particular be realized on a printed circuit board which is subsequently inserted into the housing of the LNB. All modules can be accommodated in the LNB, a subsequent connection of modules is basically not required.

• Fig. 1 ein erfindungsgemäßes DBS-System mit einer Satelliten-Antenne, einem LNB, und vier Satellitenempfängern;
• Fig. 2 ein DBS-System mit einer Satelliten-Antenne, einem LNB gemäß einer weiteren Ausführungsform mit einem zusätzlichen, herkömmlichem Universal- LNB-Ausgang, drei in Kaskade angeschlossenen Satellitenempfängern und einem an den Universal- LNB-Ausgang angeschlossenen herkömmlichen Satellitenempfänger,
• Fig. 3 ein DBS-System mit einer Satelliten-Antenne, einer terrestrischen Antenne, einem LNB gemäß einer weiteren Ausführungsform, einem Splitter, kaskadierten Satellitenempfängern und einem terrestrischen Empfänger;
• Fig. 4 ein Blockdiagramm einer erfindungsgemäßen LNB- Empfangseinrichtung zur Aufnahme von DBS-Signalen über eine nicht gezeigte Hornantenne und Polarisationsweiche und zur Ausgabe eines Zwischenfrequenz-Ausgabesignals auf einer Ausgangsleitung an mehrere Satellitenempfänger, zum Einsatz in Figur 1;
• Fig. 5 ein Plug& Play-Verfahren zur Verwendung in dem erfindungsgemäßen DBS-System, mit a) einer Tabelle der Zwischenfrequenz-Träger-Statuswerte, b) einem Flussdiagramm der Abfrageroutine eines kaskadiert angeschlossenen Satellitenempfängers; c) einem Flussdiagramm der Abfrage der Status-Tabelle;
• Fig. 6 ein Flussdiagramm eines Pairing-Verfahrens zum Einsatz in dem erfindungsgemäßen DBS-System bei a) Booten bzw. in das System Eintreten des Satellitenempfängers und b) das Verfahren des LNB;
• Fig. 7 den Aufbau eines Unterfunktions-Bytes gleich 3;
• Fig. 8 den Aufgabe eines Unterfunktions-Bytes gleich 4,
• Fig. 9 ein Blockdiagramm einer erfindungsgemäßen LNB- Empfangseinrichtung gemäß einer zu Fig. 4 alternativen bzw. erweiterten Ausführungsform zum Einsatz in Fig. 2;
• Fig. 10 ein Blockdiagramm einer erfindungsgemäßen LNB- Empfangseinrichtung gemäß einer zu Fig. 4 alternativen bzw. erweiterten Ausführungsform entsprechend Fig. 3, aber ohne legacy-Anschluss

The invention will be explained in more detail below with reference to the accompanying drawings to an embodiment. Show it:

• 1 shows a DBS system according to the invention with a satellite antenna, an LNB, and four satellite receivers;
• 2 shows a DBS system with a satellite antenna, an LNB according to another embodiment with an additional, conventional universal LNB output, three cascade-connected satellite receivers and a conventional satellite receiver connected to the universal LNB output,
• 3 shows a DBS system with a satellite antenna, a terrestrial antenna, an LNB according to another embodiment, a splitter, cascaded satellite receivers and a terrestrial receiver;
• 4 shows a block diagram of an inventive LNB receiver for receiving DBS signals via a horn antenna and polarization diverter, not shown, and for outputting an intermediate frequency output signal on an output line to a plurality of satellite receivers for use in FIG. 1;
• 5 shows a plug & play method for use in the DBS system according to the invention, with a) a table of intermediate frequency carrier status values, b) a flow chart of the interrogation routine of a cascaded satellite receiver; c) a flow chart of the query of the status table;
• 6 shows a flow chart of a pairing method for use in the DBS system according to the invention in a) boats or in the system entry of the satellite receiver and b) the method of the LNB;
• Fig. 7 shows the structure of a subfunction byte equal to 3;
• 8 shows the task of a subfunction byte equal to 4,
• 9 is a block diagram of an inventive LNB receiver according to an alternative embodiment of FIG. 4 for use in FIG. 2;
• 10 shows a block diagram of an inventive LNB receiving device according to an alternative to FIG. 4 embodiment according to FIG. 3, but without legacy connection

According to FIG. 1, a DBS system 7 according to the invention has a satellite antenna 1 in concave form - generally a symmetrical parabolic antenna or offset parabolic antenna - an LNB (Low Noise Block) connected to the satellite antenna 1 via a holder 2 Converter, low-noise coaster assembly) 3, an output cable 4 connected to the LNB 3, generally a coaxial cable, and four satellite receivers 5.1, 5.2, 5.3 and 5.4. The satellite antenna 1 is directed in a known manner to a communication satellites or broadcasting satellites and concentrates incident electromagnetic DBS signals in the SHF frequency range of 3 to 30 12 GHz to the LNB 3 rigidly attached to it. The LNB 3 is known per se a horn antenna (Feed Horn), a SHF (Super High Frequency) filter, a polarizer and the LNB receiver 6 explained in more detail in Figure 4, which receives the polarization separated electromagnetic DBS signals, converted into electrical signals, a IF conversion performs and on the output cable 4, an intermediate frequency signal in the intermediate frequency (IF, intermediate frequency) range from 950 to 2150 MHz outputs to the satellite receiver 5.1 to 5.4.

According to the invention, in this case only a single output cable 4 is connected to the LNB 3, with several satellite receivers 5.1 to 5.4 cascaded to the one output cable 4 are connected. For this purpose, the satellite receiver 5.1 to 5.4 z. B. be connected in cascade in a shared bus circuit. Each of the satellite receivers 5.1, 5.2 and 5.3 thus each leaves a connecting cable 8 to the next satellite receiver 5.2, 5.3 or 5.4, so that a cascade is formed. The IF signal output from the LNB 3 to the output cable 4 has four frequency bands in the frequency range of 950 to 2150 MHz with a bandwidth of z. B. 40 MHz. According to the invention more than four satellite receiver, z. For example, eight satellite receivers can be connected and, correspondingly, the IF signal output from the LNB 3 can be divided into eight bands, the set 40 MHz bandwidth being selected such that the bands do not overlap or do not overlap to any relevant extent.

The operation of the data transmission between LNB 3 and the satellite receivers 5.1 to 5.4 will be explained in more detail below with reference to FIG. 4.

Thus, a DBS system 7 is formed, in which the satellite antenna 1 with holder 2 and the LNB 3 is mounted outside the house in a known manner, and in the house a single output cable 4 or RF cable to the satellite receivers 5.1 bis 5.4 is performed.

Figure 2 shows another embodiment of a DBS system 7, in which outside the house in turn the satellite antenna 1 with the holder 2 and the LNB 3, the LNB 3 having in addition to the first output 8 for the output cable 4 in this embodiment a conventional output terminal 9 (legacy output port) to which a conventional second output cable 11 is connected Satellite receiver 12 is connected, which has no extended DiSEqC instruction set. In this case, a frequency spectrum according to the diagram 14 is output to the second output cable 11 with a lower band between 950 and 1,950 MHz and a partially overlapping upper band between 1,100 and 2,150 MHz.

FIG. 3 shows a further embodiment of a DBS system 7, in which the LNB 3 has an additional input terminal 14 for a terrestrial antenna 15. In the output cable 4, a splitter 16 is provided to connect a terrestrial receiver 18.

FIG. 4 shows the circuit diagram of the LNB receiver 6 accommodated in a single LNB housing, which in the LNB 3 contains the electromagnetic DBS signals in the SHF range from 3 to 30 GHz, via the horn antenna, the SHF filter and the polarization diverter arrive, absorbs, amplifies and implements. For this purpose, the LNB receiver 6 has an antenna block 1, a first intermediate frequency (IF) converter block 22, an IF matrix 23, a second IF converter block 24, a combiner block (coupler) 25 and a microcontroller (MCU) 26 , Incoming electromagnetic mutually orthogonal DBS signals DBS1 and DBS2 are received by a first receiving sample 30 and a second receiving sample 31. Here, the mutually orthogonal DBS signals DBS1, DBS2 z. B. a vertically polarized DBS signal DBS1 and a horizontally polarized DBS signal DBS2; Alternatively, they may, for. B. also be left-polarized and right-polarized or divided by the polarization diverter accordingly. The vertical reception sample 30 outputs the received RF signal via two low noise amplifiers LNA1, LNA2 to two bandpass filters BPF1A, BPF1B connected in parallel; Accordingly, the second reception sample 31 outputs the RF electric signal to two parallel band pass filters BPF1 C, BPF1 D in the IF converter block 22 via two low-noise amplifiers LNA3, LNA4.

The vertical RF signal output from the low-noise amplifiers LNA1, LNA2 is filtered through two parallel band-pass filters BPF1A and BPF1B and input to a first mixer MIX1 and a second mixer MIX2, respectively; Accordingly, the horizontal RF signal outputted from the low-noise amplifiers LNA3 and LNA4 is supplied to a third and fourth mixer MIX3 and MIX4 via two parallel band-pass filters BPF1C and BPF1D in a conventional manner. In the first and fourth mixers MIX1, MiX4, the input RF signals are mixed with a frequency from an oscillator O1 of 9.75 GHz, so that a sum and difference of the combined frequencies are formed in a manner known per se, of which subsequently in the low frequency Bandpass filter LBF1 the lower intermediate frequency in the band 950 to 1,950 MHz is passed and, accordingly, the superimposed or mixed signal output from the mixer MiX4 via the low-frequency band-pass filter LBF4 filtered and output via an amplifier. In the mixers MiX2 and MIX3, the input signals are mixed with a second frequency of a second oscillator 02 at 10.6 GHz, so that an intermediate frequency in the band of 1100 to 2150 MHz is output and output via the low-frequency band pass filters LBF2, LBF3. Thus, both the horizontal and the vertical signal in the IF converter block are divided into two frequency bands, an upper frequency band of 1,100 to 2,150 MHz and a lower frequency band of 950 to 1,950 MHz, so that a total of four groups of signals are output, namely one vertical bottom band, vertical top band, horizontal lower band and horizontal upper band following the mxn IF matrix 23, e.g. As a 4 X 4 IF matrix 23, are output.

The IF matrix 23 allows each of the four input signals or signal groups at each of its four outputs to be output as a selected satellite transponder frequency.

In the subsequent second IF converter block 24, four VCOs (Voltage Controlled Oscillators) 40, 41, 42, 43 are provided, each receiving an output signal of the IF matrix 23, to a fixed IF frequency within the IF frequency range of 950 to 2150 MHz and in each case by means of a bandpass filter, z. B. Filter SAW filters with a bandwidth of 40 MHz. The VCOs 40, 41, 42, 43 are - in a basically known manner - by a DC switching voltage 14V / 18V between the signals of the vertical plane of polarization and the horizontal polarization plane and with a 22 kHz switching signal between the lower IF band and the upper IF Band switched. These control signals are input through the micro-controller MCU 26 and the power supply LDO 27. According to the embodiment shown, in each case one balun or balun 44, 45, 46, 47 is connected to the VCOs 40, 41, 42, 43 so that asymmetrical or unbalanced second IF signals IF2 are output.

The second ZF signals IF2, each having a fixed IF frequency, output by the second IF converter block 24 are subsequently filtered in the combiner block 25 via bandpass filters BPF4A, BPF4B, BPF4C, BPF4D, superimposed in a combination device (combiner, coupler) 50 and over an amplifier 52 as an IF output signal IF3 output via the output cable 4. The satellite receiver 5.1, 5.2, 5.3, 5.4 in turn give - in a conventional manner - via the DC switching voltage and the 22 kHz signal to the MCU 26 and a DC-DC converter 55 control signals, which are used according to the invention for adjusting the VCOs 40, 41, 42, 43. The DC-DC converter 55 thus serves as a voltage supply and provides the voltage levels for the various ICs in the LNB, ie the MCU 26 and the VCOs 40, 41, 42, 43, the supply voltage also being applied to the circuit via the LDO 27 28 is outputted to the control or bias adjustment of the blocks 21, 22, which provides the power supply and setting signals or control signals for the antenna block 21 and the first IF converter block 22 in a manner known per se.

The output from the combiner block 25 on the output cable 4 third IF signal IF3 thus has in the frequency range between 950 and 2150 MHz four frequency bands with a bandwidth of z. Each at 40 MHz; It can be suitably z. B. eight frequency bands are output in this frequency range. Their frequencies or middle frequencies are in each case fixed, since according to the invention, the satellite receiver 5.1 to 5.4 via the DC switching signal and the 22 kHz signal, the VCOs 40 to 43 such that they each have a desired output to the respective IF Tape.

FIGS. 9 and 10 show corresponding LNB receiving devices for FIG. 2 or FIG. 3, wherein in FIG. 10 a DC block and filter device 90 is additionally provided.

A plug-and-play method or method for connecting an additional satellite receiver to the DBS system or single-cable network according to the invention is described below:

According to the invention, the digital switching method DiSEqC known per se can be used, in which the 22 kHz switching signal is used as a carrier or carrier for digital messages. Here owns the satellite receiver or the satellite tuner, a master IC, which sends a command telegram to the slave IC in the switching matrix and the slave IC in the LNB, whereupon the slave ICs for confirmation send a response telegram. The command telegrams generally consist of header, address part, command part and data parts; the response message has a header and data parts. The transmission sequence is controlled by the micro-controller or the micro-processor in the satellite tuner or the satellite receiver. The command telegram generally selects the LNB, the plane of polarization and the frequency band. The parts of the telegrams are generally composed of 8 bits and a parity bit, wherein a bit having the value "0" consists of 22 oscillations of the 22 kHz switching signal and a pause corresponding to the time of 11 oscillations, and a bit with the value "1" consists of 11 oscillations of the 22 kHz switching signal and a pause, which corresponds to a time expenditure of 22 oscillations.

According to the invention, the protocol used in conventional satellite receivers is extended by further control commands or commands. This extended DiSEqC instruction set is recorded in EN 61319-1 and part of the software of the satellite receiver according to the invention. Here, one-way communication from the satellite receiver (IRD) to the LNB, or bidirectional communication between them may be made. This method relies on dynamic and automatic IF channel assignment. The IF channels are dynamically assigned by the microcontroller in an automatic configuration, with the microcontroller managing and updating a display table with the status of the IF channels. The status value of each IF channel may be "free" or "busy" or "locked". The status values are updated based on the communication information sent from the satellite receivers 5.1, 5.2, 5.3, 5.4 to the LNB 3. This is an occupancy signal (or life signal) from the satellite receivers to the LNB a fixed period of time, e.g. B. all z. For example, 30 sec is sent to refresh or update the respective status value in the display table. The satellite receiver transmits a specific control command or a specific command to enable an IF channel, with the status value being switched from busy to free when the satellite receiver is switched off. As soon as the microcontroller does not receive three consecutive live signals from a satellite receiver, the respective status value in the respective entry of the display table is set to "free". The satellite receivers may ask for an idle IF channel by an allocation request signal when they are connected.

According to the invention, a Plug & Play, in particular a "hot plug & play" during operation is thus possible.

According to the invention, a semi-automatic method may further be performed in which a manual setting of an IF channel is performed by a connected IRD, wherein a specific user interface option supported by the IRDs is performed, the end user having an IF Manually assign each IRD to the LNB and support a request command from the IRD to display all the available IF channels together so that the end user receives a list of all available IF channels to obtain an IF channel for his IRD wants to join, choose.

Furthermore, a pairing method is provided according to the invention, in which a connection between the LNB and the IRD is secured, the method being based on a PIN code, the IRD in the LNB either by direct access to an internal memory of the LNB or through enters a given control command. This method is used by IRDs that allow for return capability or bi-directional communication, where the IRD is the PIN code from the LNB can either read or read back by direct access to its internal memory, or can request the LNB via a predetermined control command to use the IF carrier so that the PIN code is specified, in which case the present carrier as binary "1", and a non-existent carrier is considered "0". Under such a method, where the PIN code is given to the LNB, working IRDs may then use different algorithms to verify the PIN code before allowing normal use of the IRD. As a result, z. B. an authorized expansion of an IRDs - z. B. with a special decoder - and subsequent installation in another DBS system can be prevented, so that z. For example, decoders used in pay-TV are relevant in which use in an existing DBS system is allowed at a tariff but not a new use in another DBS system.

FIG. 5a shows a display panel in which the status - d. FIG. 5 shows the various IF carriers ZF1, ZF2, ZF3 and ZF4 listed in the first column in the following column. H. a 0 or a 1 - is displayed. Furthermore, in the right column the number of received live signals are displayed, which were received in the last three periods; Accordingly, here the value between 0 (no input, so that the absence of the relevant IRD can be concluded) and 3 vary.

• Schritt S1: Anfrage an LNB, alle freien Träger mit Leistung zu belegen;
• Schritt S2: Scannen nach freien ZF-Trägern;
• Entscheidungsschritt S3: Sind Träger gefunden worden?;
  • in der Ja-Verzweigung Y folgt daraufhin Schritt S4: Anfrage an LNB, einen der Träger zu verriegeln bzw. zuzuweisen;
  • Schritt S5: Scannen nach ZF-Frequenz + einem festen Wert, z. B. 24 MHz, zur Verifikation;
  • Entscheidungsschritt S6: Ist der Träger zugewiesen?
  • Falls S6 nicht erfüllt ist, wird gemäß Ausgang N auf Schritt S1 zurückgeführt; falls S6 erfüllt ist, wird gemäß Zweig Y ein Belegungs-Signal jeweils in dem Zeitintervall, z. B. alle 30 Sekunden ausgesendet;
  • falls in Entscheidungsschritt S3 die Bedingung nicht erfüllt ist, wird gemäß Verzweigung N der Benutzer in Schritt S8 informiert und das Verfahren in Schritt S9 beendet.

According to FIG. 5b, the following algorithm is provided for requesting the STB:

• Step S1: Request to LNB to power all free bearers;
• Step S2: scanning for free IF carriers;
• Decision step S3: Have vehicles been found ?;
  • in the YES branch Y, step S4 follows: request to LNB to lock one of the bearers;
  • Step S5: Scan to IF frequency + a fixed value, e.g. 24 MHz, for verification;
  • Decision step S6: Is the wearer assigned?
  • If S6 is not satisfied, the output N is returned to step S1; if S6 is satisfied, according to branch Y, an occupancy signal is generated in the time interval, e.g. B. every 30 seconds sent out;
  • if the condition is not met in decision step S3, the user is informed according to branch N in step S8, and the process is ended in step S9.

Fig. 5c shows the following procedure performed by the controller MCU 26 in the LNB:

In step T1, a satellite receiver (STB) command is waited by a satellite receiver (eg, an IRD); in a request of a satellite receiver for a free IF carrier is searched according to step T2 for free IF carriers in the display table of FIG. 5a. In decision step T3, depending on whether free IF carriers are present, branch N is again returned to step T1 and branch Y, d. H. in the presence of a free IF carrier, this is power and again returned to step T1. Furthermore, according to step T5, the respective entry in the display table according to FIG. 5a is updated and in step T6 the respective IF carrier + 40 MHz is occupied with power, whereupon in turn is returned to step T1. According to T7, the counter is continuously updated by the signal of the satellite receiver (IRD).

The pairing method according to FIG. 6a shows the routine at the receiving device, ie the respective connected satellite receiver (STB or IRD), which is being started up: First, a request for a PIN is output in step P1; in subsequent step P2, IF carriers are scanned to detect the PIN code; below will be in the decision step P3 checks whether a PIN has been successfully detected. If this is not the case, branch N returns again to step P1; in case a PIN is found, branch Y is checked to see if the PIN code is correct; if this is not the case, according to branch N in step P5, the boot process is stopped and the user informed. If the condition is satisfied in step P4, according to branch Y, the boot process in step P6 is completed.

Other units in the network may or may not be in stand-by mode.

The routine in the LNB, according to FIG. 6b, is such that in step U1, STB requests are waited, in PIN requests according to step U2, the PIN code in the internal memory is updated and, according to step U3, upon receipt of one PIN request of the ZF-carriers is assigned in each case with achievement.

Below are some software commands:

Known commands to DiSEqC are ODU_ChannelChange E0 10 5A channel_byte1 channel_byte2 ODU_PowerOFF E0 10 5A poweroff_byte 00 ODU_SCRxSignal_ON E0 10 5B subfunction_byte XX ODU_Config E0 10 5B subfunction_byte config_byte ODU_LOFREQ E0 10 5B subfunction_byte lofreq_byte

According to the invention, the following additional software instructions are used: ODU_PowerFreelF E0 10 5B subfunction_byte = 7 ODU_AllocatelF E0 10 5B subfunction_byte = 3 ODU_LiveSignal E0 10 5B subfunction_byte = 4

Such as: ODU_SetPIN (E0 10 5B subfunction_byte = 5 PIN_byte) ODU GetPIN (E0 10 5B subfunction_byte = 6)

For DiSEC 2.0 satellite receivers, commands 0E and 0D are used for direct access to the EEPROM. All commands exist in DiSEqC 2.0 format and start with "E2" instead of "Eo". The controller MCU 26 responds with an "E4" frame to each command starting with "E2".

A: Dynamic IF channel assignment:

By an automatic IF channel assignment, the invention allows the connection of more than four satellite receivers to the one output line 4, wherein a dynamic IF channel assignment for each new STB or IRB, which is connected to the cascade of satellite receivers 5.1,. .. is connected.

The procedure is carried out as follows:

• IF-Channel #0 locked / free
• IF-Channel #1 locked / free
• IF-Channel #2 locked / free
• IF-Channel #3 locked / free
• .......
• IF-Channel #n locked / free

The MCU 26 maintains a small table as follows:

• IF channel # 0 locked / free
• IF channel # 1 locked / free
• IF channel # 2 locked / free
• IF channel # 3 locked / free
• .......
• IF channel #n locked / free

1. For DiSEqC 1.0 STB:

The procedure starts with a request to put all free IF frequencies under power.

If a satellite receiver (STB) is configured to boot using the inventive plug and play method, it will request the LNB to put all free IF frequencies into service.
ODU_PowerFreeIF (E0 10 5B subfunction_byte)

The LNB will then power the free channel bearers at mid-frequency + 24 MHz (to avoid an occupied channel interrupt).

The satellite receiver will then perform an IF scan. Once she has found a vehicle, she will ask the LNB to "lock" that vehicle for her, using the following command:
ODU_ALLOCATE IF (E0 10 5B SUBFUNCTION_BYTE)

The LNB will then update the scoreboard and put the requested carrier under power in the center frequency. The satellite receiver will then perform a second scan and, if it identifies the carrier at the center frequency, may conclude that the channel has been assigned to it; see Fig. 7, which is to be set here as SatCR "VCO module".

From now on, the satellite receiving device occupancy signals, z. For example, to send N occupancy signals per minute to secure this IF channel for use, otherwise the MCU 26 will "release" that channel.

When the STB enters standby mode or is completely powered off, the command becomes
ODU_POWER OFF (E0 10 5A POWER OFF_BYTE 00)
In addition to its traditional operation, the controller MCU 26 indicates that the channel in question can be noted as "free" in the table.

In addition, each in-service satellite receiver will issue an occupancy signal every z. B. Send 60 seconds to the controller MCU 26, by a new command
ODU_LIFESIGNAL (E0 10 5B SUBFUNCTION_BYTE).

When MCU 26 sets the occupancy signal for a particular IF channel above N, e.g. For example, if N = five does not receive consistent durations, it interprets this as having received an ODU_POWER OFF command for that VCO module and will note the respective table entry as "free" and the respective VCO module chip into one set low power mode (operating mode); see Fig. 8.

2. For DiSEqC2.0 - Satellite Receiver:

The EEPROM byte will store the IF channel status values (0 = free, 1 = busy). The default value for this byte is "00".

When a satellite receiver is configured to boot up using the Plug & Play method of the invention, the byte is read from the EEPROM using the 0D instruction, the byte at the dedicated index of the EEPROM.

If the satellite receiver detects a free IF channel, it will mark it as locked by updating the EEPROM using the 0E command.

If the satellite receiver goes into stand-by mode or is completely switched off, it will update or update the EEPROM and mark the vacant IF channel as free (0).

The command ODU-POWER OFF (E0 10 5A POWER OFF_BYTE 00) will indicate, in addition to its other operation to the MCU 26, that the respective channel may be marked as "free" in the EEPROM.

In addition, each on-going satellite receiver will send an assignment signal to the controller MCU 26, for example every 30 seconds, by a new command
ODU assignment signal (E0 10 5B SUBFUNKTION_BYTE).

If the controller MCU 26 does not receive an occupancy signal for a particular IF channel over N (e.g., N = five) consecutive periods, it will behave as if it has received an ODU_POWER OFF signal for that VCO module and Update or update the EEPROM data accordingly and set the corresponding VCO module chip to a low operating state.

All DiSEqC1.0 commands have DiSEqC2.0 equivalents; Thus, if a DiSEqC2.0 command is sent from a satellite receiver to the LNB, the LNB will respond with an acknowledgment byte, usually OxE4 byte

B: PIN code (PARY, ODU and IDU):

The idea is to have a specific system work with set satellite boxes (STBs); This can z. B. an unauthorized use can be avoided.

• (1) Für DiSEqC1.0 Satellitenempfänger:
  ODU_SETPIN (E0 10 5B SUBFUNKTION-BYTE = 5 PIN_BYTE)
  Wenn dieser Befehl empfangen wird, wird die Steuereinrichtung MCU 26 in dem dedizierter Index des EEPROM den PIN-Code (Daten [0..7]) des PIN-Byte speichern.
  ODU_GET PIN (E0 10 5B SUBFUNKTION_BYTE = 6)
  Bei Empfang dieses Befehls wird das MCU auf dem VCO-Modul die jeweiligen Träger (carrier) unter Leistung setzen (d.h. aus (bzw. kein Träger) oder Mitte).
• (2) Für DiSEqC2.0 Satellitenempfänger:

A dedicated index (ie, generally zz, fixed value) in the EEPROM can be used as follows (the default value in the index is "0"):

• (1) For DiSEqC1.0 satellite receiver:
  ODU_SETPIN (E0 10 5B SUBFUNCTION BYTE = 5 PIN_BYTE)
  When this command is received, the controller MCU 26 will store in the dedicated index of the EEPROM the PIN code (data [0..7]) of the PIN byte.
  ODU_GET PIN (E0 10 5B SUBFUNKTION_BYTE = 6)
  Upon receipt of this command, the MCU on the VCO module will power the respective carriers (ie, off (or no carrier) or center).
• (2) For DiSEqC2.0 satellite receiver:

Using the Write command (Write command, OE command), the satellite receiver will write the PIN code into the EEPROM.

Using the read command (read command, 0D command), the satellite receiver will read out the PIN code from the EEPROM.

Claims (19)

LNB receiving device for receiving and converting DBS signals (DBS1, DBS2) of a satellite, the LNB receiving device (6) comprising: an antenna block (21) having two receiving samples (30, 31) for receiving mutually orthogonal DBS signals and amplifiers (LNA1, LNA2) for amplifying the DBS signals; a first IF converter block (22) for receiving the RF signals of the antenna block (21), the first IF converter block (22) having four mixers (MIX1, MIX2, MIX3, MIX4) connected to local oscillators (01, 02 ) perform a first frequency conversion of the RF signals (RF1, RF2) and division into ZF signals of a horizontal lower band, horizontal upper band, vertical lower band and vertical upper band, and an IF matrix (23) for receiving the first IF signals output from the first IF converter block (22) and selectively outputting to a plurality of outputs;
characterized in that to the IF matrix (23) a second IF converter block (24) is connected, which has a plurality of adjustable frequency converters (40, 41, 42, 43), each frequency converter (40, 41, 42, 43) sets the selected output of the IF matrix (23) in each case to a predetermined, fixed IF frequency band, the IF bands of the plurality of frequency converters (40, 41, 42, 43) are different from each other, a coupler block (25) is provided for receiving the second IF signals output from the second IF converter block (24), linkage or superposition to a third IF signal and output to an output terminal (54) for cascaded satellite receivers (5.1, 5.2, 5.3, 5.4), via the output terminal (54) switching signals are receivable, and a voltage supply (27, 55) and a control device (26) are provided which receive the switching signals picked up by the output terminal (54) and supply control signals to the frequency converters (40, 41, 42, 43) for controlling the IF matrix ( 23) or output selection of the IF matrix (23). LNB receiving device according to claim 1, characterized in that the controllable frequency converter variable oscillator modules (40, 41, 42, 43). LNB receiving device according to claim 2, characterized in that the oscillator modules have voltage-controlled oscillators (40, 41, 42, 43) which receive the output signals of the IF matrix (23) in response to a control voltage and to the respectively fixed IF Lay band. LNB receiving device according to one of the preceding claims, characterized in that in the second IF converter block (24) balancing members (44, 45, 46, 47) are provided, each receiving an output signal of a frequency converter and unbalances. LNB receiver according to one of the preceding claims, characterized in that in the first IF converter block (22) an oscillator (01) having a lower frequency of 9,750 MHz and an oscillator (02) provided with an upper frequency of 10,600 MHz are each two mixers provide their oscillator frequency. LNB receiving device according to one of the preceding claims, characterized in that in the coupler block (25) a plurality of bandpass filters (BPF4A, BPF4B, BPF4C, BPF4D) are provided which receive the second IF signal (24) received by the second IF converter block (24). IF2). LNB receiving device according to one of the preceding claims, characterized in that the control device (26) has a non-volatile memory, for. B. EEPROM or flash ROM, for receiving via the output terminal (54) recorded control signals connected satellite receiver (5.1, 5.2, 5.3, 5.4). LNB receiver according to one of the preceding claims, characterized in that it additionally comprises a conventional output terminal (9) for connecting conventional satellite receivers (12). LNB receiver according to one of the preceding claims, characterized in that it additionally comprises an input terminal (14) for a terrestrial antenna (15). LNB receiving device according to one of the preceding claims, characterized in that their configuration parameters, for. As reception frequencies, polarization, band, are pre-stored in internal registers, preferably in tabular form, and can be read by predetermined control commands or direct access to the LNB registers. Method for forming a DBS system with a DiSEqC operating LNB (3) according to one of the preceding claims, a plurality of IF channels and a plurality of satellite receivers (5.1, 5.2, 5.3, 5.4) connected via a single output cable (4), wherein : a controller (26) of the LNB (3) stores data on the individual IF channels, whether they are busy or idle, and continuously updates the data, the satellite receivers connected to the DBS system continuously send occupancy signals to the control device (26), in the absence of occupancy signals of a satellite receiver the controller recognizes that this satellite receiver is no longer connected and stores the IF channel assigned to this satellite receiver as free, a satellite receiver to be connected to the DBS system makes an inquiry as to whether a channel is free, the controller, in response to the request of the new satellite receiver, checks from the stored data whether a channel is free and, if the channel is free, assigns it to the satellite receiver. A method according to claim 11, characterized in that the control means (26) stores a table with data on the IF channels, the table for each IF channel a number of the IF channel, a status, whether the respective channel is occupied and Contains data on the received occupancy signals of the satellite receiver assigned to the respective IF channel. Method according to claim 11 or 12, characterized in that the satellite receivers connected in the DBS system periodically emit occupancy signals to the control device (26) and, in the absence of a predetermined number, e.g. B. five, of occupancy signals of a satellite receiver, the controller detects that its IF channel is free. Method according to one of claims 11 to 13, characterized in that the connected satellite receiver (5.1, 5.2, 5.3, 5.4) before they are turned off or before their transition to a stand-by mode log off by sending a deregistration signal to the controller. Method according to one of Claims 11 to 14, characterized in that at least one further satellite receiver (12) is addressed via a further output cable in parallel with the satellite receivers (5.1, 5.2, 5.3) connected via the output cable (4). A method of pairing a satellite receiver (5.1, 5.2, 5.3, 5.4) and an LNB according to any one of claims 1 to 10, wherein a satellite receiver registering in the DBS system performs the steps of: Request for an identification, eg. A PIN, Verification of the IF carrier after identification, in the case that no identification is detected, resetting the method to the request for identification, - in case an identification is discovered, Checking whether the identification matches a prestored identification, - if the identification matches, continuation of the registration process, - if the identification does not match, stopping the logon process. A method according to claim 16, characterized in that in the case that the identification does not match, an indication signal is output to the user. A method according to claim 16 or 17, characterized in that the prestored identification is entered in a first programming operation or first logon process in a DBS system and stored non-volatile in the satellite receiver. Method according to one of claims 16 to 18, characterized in that the LNB on receipt of a request for an identification sets the IF carrier under power.

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