On-board switching controller for a satellite with on-board switching

US 4,926,422 A
Filed: 11/04/1988
Issued: 05/15/1990
Est. Priority Date: 11/04/1987
Status: Expired due to Fees

First Claim

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1. An on-board switching controllr for a satellite with on-board switching for control of a base band switching matrix with one switching stage and a plurality of multiplexers, said matrix receiving uplink frames and sending downlink frames, said frames being divided into zones (T1 . . . . T6) including a first zone and a last zone comprising service channels and intermediate zones comprising traffic channels, each of said channels encompassing a certain number of states, said controller cooperating with a telecontrol and telemetering station (TLCS) capable of low-frequency bidirectional dialogue with an uplink telecontrol channel (TLC) and a down link telemetering channel (TLM), each of said channels having a preamble and a data message, said controller comprising:

means for directly receiving from said switching matrix (BSM) and processing said service channels (CH, IOTS) of said uplink frames and for directly supplying said switching matrix (BSM) with the service channels (FMC, IOTD) of said downlink frames, and for receiving via said uplink telecontrol channel (TLC) and processing words for control of operation o the controller and sending on said downlink telemetering channel (TLM) reply words;

a preprocessing unit (PREL) selecting, synchronizing and decoding said service channels (CH, IOTS) of the uplink frames and extracting therefrom decoded messages and provided with a first interface means (INC1, INC2) having first and second elements (INC1 and INC2, respectively), said first element receiving said decoded messages, said preprocessing unit (PREL) being provided with counters;

a matrix interface unit (INTM) comprising two memory units (MEMA, MEMB) storing matrix switching stages, and first control means determining an alternation of said memory units as an active memory unit and as a backup memory unit, respectively, the first control means controlling reading in said active memory unit of switching states and sending a reading of the switching states to said matrix (BSM) and updating switching states in both of said memory units; and

a processing unit (ELAB) operatively connected to said preprocessing unit (PREL) and to said matrix interface unit (INTM) and comprising;

said second element (INC2) of said first interface means checking existence and correctness of dialogue with said processing unit and checking veracity of received data messages,second interface means (INTB) for receiving, decoding and checking data messages supplied by said telecontrol channel and for transmitting the telemetering channel, andfirst decoding and executing means (GMS, GTLC) connected to said first and second interface means (INC1, INC2;

INTB) for decoding and executing commands present in data messages receive from said first and second interface means (INC1, INC2;

INTB), said first decoding and executing means (GMS, GTLC) managing, an a basis of said commands, a normal operation mode of the controller in which all functions are activated and a degraded operation mode in which said preprocessing unit (PREL) and said first interface means (INC1, INC2) are disabled, said first decoding and executing means (GMS, GTLC) controlling writing of said switching states selectively only into said backup memory unit or into both said memory units while reproducing frame subdivision into said channels and zones;

said first interface means (INC1, INC2) being constructed and arranged in said normal operation mode to;

write switching states to be transferred to both of said memory units (MEMA or MEMB) into a first buffer (BF10),write switching states to be transferred only to said backup memory unit into a second buffer (BF11),write information on frame zones of switching states written in in said second buffer (BF11) into a third buffer (BF12, BF13, BF14),write control words for operation of said processing unit (ELAB) into a fourth buffer (BF15), andsend to said second interface means (INTB) alarm messages generated upon a negative result of a check on said dialogue or in a case of overflow of said counters of said preprocessing unit (PREL) or reply messages from said preprocessing unit (PREL), said first interface means being disabled in said degraded operation mode.

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Abstract

A controller is provided for a baseband switching matrix with one space switching stage. The matrix supplies the controller with a number of service channels (IOTS, CH) of the uplink frames, which channels comprise encoded commands that are decoded by the controller which generates service channels (IOTD, FMC) for the downlink frames and sends them towards the matrix. The controller is subdivided into three functional units: a preprocessing unit (PREL) which decodes uplink frame service channels; a processing unit (ELAB), which receives the commands decoded by the preprocessing unit and/or by a telecontrol station with which it performs a bidirectional dialogue and generates control signals comprising the matrix switching states; and an interface unit (INTM) comprising two memories (MEMA, MEMB) alternatively operating as active or backup memory, which store the switching states supplied by the processing unit and send them to the matrix.

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5 Claims

1. An on-board switching controllr for a satellite with on-board switching for control of a base band switching matrix with one switching stage and a plurality of multiplexers, said matrix receiving uplink frames and sending downlink frames, said frames being divided into zones (T1 . . . . T6) including a first zone and a last zone comprising service channels and intermediate zones comprising traffic channels, each of said channels encompassing a certain number of states, said controller cooperating with a telecontrol and telemetering station (TLCS) capable of low-frequency bidirectional dialogue with an uplink telecontrol channel (TLC) and a down link telemetering channel (TLM), each of said channels having a preamble and a data message, said controller comprising:
- means for directly receiving from said switching matrix (BSM) and processing said service channels (CH, IOTS) of said uplink frames and for directly supplying said switching matrix (BSM) with the service channels (FMC, IOTD) of said downlink frames, and for receiving via said uplink telecontrol channel (TLC) and processing words for control of operation o the controller and sending on said downlink telemetering channel (TLM) reply words;
  
  a preprocessing unit (PREL) selecting, synchronizing and decoding said service channels (CH, IOTS) of the uplink frames and extracting therefrom decoded messages and provided with a first interface means (INC1, INC2) having first and second elements (INC1 and INC2, respectively), said first element receiving said decoded messages, said preprocessing unit (PREL) being provided with counters;
  
  a matrix interface unit (INTM) comprising two memory units (MEMA, MEMB) storing matrix switching stages, and first control means determining an alternation of said memory units as an active memory unit and as a backup memory unit, respectively, the first control means controlling reading in said active memory unit of switching states and sending a reading of the switching states to said matrix (BSM) and updating switching states in both of said memory units; and
  
  a processing unit (ELAB) operatively connected to said preprocessing unit (PREL) and to said matrix interface unit (INTM) and comprising;
  
  said second element (INC2) of said first interface means checking existence and correctness of dialogue with said processing unit and checking veracity of received data messages,second interface means (INTB) for receiving, decoding and checking data messages supplied by said telecontrol channel and for transmitting the telemetering channel, andfirst decoding and executing means (GMS, GTLC) connected to said first and second interface means (INC1, INC2;
  
  INTB) for decoding and executing commands present in data messages receive from said first and second interface means (INC1, INC2;
  
  INTB), said first decoding and executing means (GMS, GTLC) managing, an a basis of said commands, a normal operation mode of the controller in which all functions are activated and a degraded operation mode in which said preprocessing unit (PREL) and said first interface means (INC1, INC2) are disabled, said first decoding and executing means (GMS, GTLC) controlling writing of said switching states selectively only into said backup memory unit or into both said memory units while reproducing frame subdivision into said channels and zones;
  
  said first interface means (INC1, INC2) being constructed and arranged in said normal operation mode to;
  
  write switching states to be transferred to both of said memory units (MEMA or MEMB) into a first buffer (BF10),write switching states to be transferred only to said backup memory unit into a second buffer (BF11),write information on frame zones of switching states written in in said second buffer (BF11) into a third buffer (BF12, BF13, BF14),write control words for operation of said processing unit (ELAB) into a fourth buffer (BF15), andsend to said second interface means (INTB) alarm messages generated upon a negative result of a check on said dialogue or in a case of overflow of said counters of said preprocessing unit (PREL) or reply messages from said preprocessing unit (PREL), said first interface means being disabled in said degraded operation mode.
- View Dependent Claims (2, 3, 4, 5)
- - 2. The controller defined in claim 1 wherein said preprocessing unit (PREL) is provided with means for selecting upon a command given in normal operation mode by the processing unit (ELAB), a first IOTS) and a second (CH) service channel;
    - synchronizing said channels by looking for a synchronism word (UW) contained in the preamble in successive search steps in which a window twice as wide as said word is analyzed and by comparing the analyzed window with a fixed configuration, non-synchronized channels being neglected and causing advance of counters of lack of synchronization;
      
      comparing the data message of said first service channel (IOTS) with a fixed configuration, incrementing a counter of discrepancies found out; and
      
      decoding the data message of said second service channel (CH) by splitting the message into two interleaved parts and decoding each part first according to a Golay code and then according to a cyclic redundancy code, incrementing a counter of decoding errors, thus obtaining said data messages supplied to the first interface means, said data messages comprising alarms relevant to overflow conditions of said counters.
  - 3. The controlled defined in claim 1 wherein, in said processing unit (ELAB), said second interface means (INTB) is provided with means for, in both operation modes, writing control words for the operation of said processing unit (ELAB) into said fourth buffer (BF15), control words for the operation of the preprocessor unit (PREL) into a fifth buffer (BF15), writing into further registers (RGS1, RGS2) information on the exchange between the active and backup memory and on the identity of the multiplexer to be activated in the matrix, generating alarms in case of negative checks on the messages received from the telecontrol channel, and sending the alarm messages and reply messages received from said first interface means (INC1, INC2), or from the first decoding and execution means (GMS, GTLC) on the telemetering channel;
    - and in said degraded operation mode for writing switching states to be transferred to the only backup memory unit into said second buffer (BF11) and writing information on the frame zones of the switching states written in the second buffer (BF11) into said third buffer (BF12, BF13, BF14).
  - 4. The controller defined in claim 1 wherein, in said processing unit (ELAB), said first decoding and execution means (GMS, GTLC) is provided with means for on the basis of command words read in said fourth buffer (BFG15), determining said normal and degraded operation modes, reading in said first buffer (BF10) and then in said second buffer (BF11) the switching states relevant to the various frame channels, preceded by a corresponding address, also computing a parity bit, and sending them to said interfacing unit (INTM) to which it also sends, at addresses contained in the command words bits identifying of frame positions (F1, F2) where said channel length changes, or wherein a TV channel (TV) ends, sending a command for the exchange between active and backup memory to be executed by said interface unit (INTM) in the subsequent frame or superframe, followed by a command of copying into the new active memory unit, on the basis of the information red in said third buffer (BF12, BF13, BF14), and preparing then messages acknowledging command execution, which are sent by the decoding and execution means onto a third service channel (FMC) of downlink frames.
  - 5. The controller defined in claim 1 wherein said interface unit (INTM) comprises:
    - means for alternately operating said memory units (MEMA, MEMB) as active backup memory, said units being read and/or written by said processing unit (ELAB) or being read with priority by a time base (BT1) which generates a cyclic addressing (ADD1) in order to send the states to said matrix (BSM);
      
      means (PACA, PACB) for checking the parity bit of the words read in said memory unit, and sending a possible parity error signal to said processing unit (ELAB);
      
      a logic circuit ND12, ND13, OR10, FFD10, OR11, OR12) for memory unit exchange, which circuit is controlled by said first decoding and execution means (GMS, GTLC) and allows reading by said time base (BT1) of the active memory unit only, and the possible reading and/or writing either of the backup memory unit only or of both memory units by the processing unit (ELAB) in the remaining frame time, said remaining frame time being determined by said logic circuit for memory unit exchange, which circuit, on the basis of the information on the channel length carried by said identifying bits (F1, F2) coming from the processing unit (ELAB), enables reading by the time base (BT1) of the first switching states only of each channel;
      
      a redundancy circuit (RDEM) activating matrix multiplexers identified both by states read in the active memory unit by said time base (BT1) and by information on the identity of the active multiplexers*, said information being supplied by said processing unit (ELAB) and being present in further registers (RGS1, GS2); and
      
      a circuit (CONTV) for setting up a TV connection and on a basis of a bit identifying the frame position in which a television channel (TV) ends and of the identities of the matrix multiplexers involved in the matrix, supplied by said first decoding and execution means (GMS, GTLC) establishes a fixed connection in said matrix between an input and an output of said multiplexers.

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Current Assignee
Alenia Aeritalia & Selenia SpA (Leonardo S.p.A.)
Original Assignee
Selenia Spazio S.p.A. (Leonardo S.p.A.)
Inventors
Ventimiglia, Giovanni, Alaria, Gian B., Poggio, Cesare
Primary Examiner(s)
Olms, Douglas W.
Assistant Examiner(s)
Jung, Min

Application Number

US07/267,492
Time in Patent Office

557 Days
Field of Search

370/97, 370/104, 370/58, 370/54, 455/12, 342/353, 342/356
US Class Current

370/323
CPC Class Codes

H04B 7/2046 SS-TDMA, TDMA satellite swi...

On-board switching controller for a satellite with on-board switching

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On-board switching controller for a satellite with on-board switching

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