NO802520L - CLUTCH DEVICE FOR TIME MANAGEMENT OF THE RECEIVER PART IN A EARTH STATION FOR SATELITE CONNECTIONS - Google Patents

Description

The invention relates to a coupling device for time management of the receiver part in an earth station for satellite connection, in particular for time multiplex transmission, where a number of stations, each comprising a central unit, are connected to a number of earth stations.

A transmission system of this kind is known under the term TDMA (Time Division Multiplexed Access).

Each station consists of a central unit which is connected to a number of ground stations, the design of which is in accordance with the signal to be received.

Some of the earth stations that receive digital signals are mainly of the audio frequency interpolation type to facilitate the use of satellite channels.

Sound frequency interpolation is based on the utilization of pauses in telephone conversations in order to transmit conversations from other speakers in the same channel.

The earth stations must be suitable for the current of

data received to satisfy the requirements of the TDMA system and store in memory the data stream for reading at a higher speed in the central unit.

The data at the transmitting station is sent in a group i

a predetermined position in the TDMA frame, which has a duration of 75 0 yseconds.

In the transmitting part of the ground station, data is recorded at high speed and in groups and is continuously read to form a data stream that is sent directly out onto lines.

If, in the same TDMA frame, the earth station in question has to receive data from the same station in two or more time intervals separated by transmission from other stations, certain problems arise when it comes to time management of the data records.

Distribution of the channels within the frame can be such that the receiver part receives x channels from station A,

which can be followed by y channels from station B and then z channels again from station A and so on.

A first technical solution enables accurate recording by monitoring the presence of a number of channel counters, which is equal to the number of stations from

which earth station in question is to receive data.

In that case, the channel counter assigned to station A will, after counting x channels, stop and start again when counting the next z channels, after the counter assigned to station B has counted y channels from the count value at which it had stopped. Any solution of this nature requires the presence of a large number of counting chains when the number of stations to be received is large, which significantly increases the costs and dimensions of the ground stations.

The purpose of the present invention is to provide a particularly simple and economical coupling device, which does not have the above-mentioned disadvantage.

This is achieved according to the invention by a counting device, which is supplied with a series of time pulses from the central unit derived from data received from satellite and which is able to count the number of channels that reach the earth station in question;

a storage device comprising a number of memory rows corresponding to the number of earth stations that receive data for storing the number of channels from the counting device;

a reset device for resetting to zero the counting device and the storage device at the beginning of each frame; and a control device which is supplied with a number w of ready pulses from the central unit together with a code identifying the originating station, and delivers a first series of pulses to cause the storage device to store the count value in the counting device, a second series of pulses upon the occurrence of a pulse which simultaneously with the pulse ^ in the series of 'pulses received by the control device, and a third series of pulses for transferring the contents of the memory row, which is detected by the originating station of the counting device.

In this way, a single counting chain with an associated memory can store the number of channels that have been broadcast

>from each station, and if a given station transmits a further group of channels in the same frame, the counting chain is preset to the number of channels previously stored in memory and the counting starts again from such

count value.

Further features of the invention will be apparent from

requirements 2-6.

The invention will be explained in more detail below

with reference to the drawings.

Figure 1 shows a block diagram of an earth station

of the audio frequency digital interpolation type.

Figure 2 shows a block diagram of the device CR on

figure 1.

Figure 3 shows waveforms that appear on the figure

2.

The ground station in Figure 1 comprises a transmitter part ST, a receiver part SR and a connection unit Ul, which is connected to NPCM systems (e.g. 2 M bits/s).

The transmitting part monitors sound frequency detectors SD,

which detects whether sound frequency activity occurs in a single channel in the PCM systems.

A channel distributor AC is connected to the detectors SD, which connects the earth channel, in which the presence of sound frequency energy is detected at a certain time, with a preceding satellite channel which is assigned to another earth station, in which the detector does not detect the presence of sound frequency activity.

<*>The channel distributor AC is connected to a unit AM which is intended to shape the distribution message, so that the connection between the satellite channel and the earth station channel, which is established also introduces the connection in a transmission connection part.s.eshukpmmefee: CT ,which_stores -all- the connections as-,the unit . AC performs, 'between the ^satellite channels .and' the earth stas ion channels

The audio frequency detectors SD introduce a delay in the detection of audio frequency activity and a delay circuit DL is therefore provided to delay the PCM coded signals transmitted to compensate for the delay introduced by the detectors.

The output of the delay circuit is connected

with a compression memory MC, which contains a first memory A and a second memory B.

After continuous introduction of six frames of pulse-code modulated signal into memory A, the next six frames are introduced into memory B, simultaneously with the reading of the memory

A.

The introduction takes place at high speed by the fact that an output signal consisting of a group of data is used during transmission, the connection between the satellite channel and the earth station channel, which is stored in the unit CT, being taken into account. If it is assumed that the unit AC has connected the earth channel 20 with the satellite channel 15, when satellite channel 15 has to be transmitted, data recorded in row 20 in the memory A or B in the unit MC, which is then in the reading phase, is read.

The output of the compression memory MC is connected to a summing circuit CS, which connects the distribution message, encoded by the unit AM in accordance with an error correction code, with the group of data corresponding to the output signal from the unit MC.

The group of data, which corresponds to the distribution message, is sent to the central unit (in a special ..way_.as the unit is indicated by the designation CTTE), which modulates it and sends it to the satellite that receives data sent by other stations.

The satellite then re-sends a group of data that has been sent by all the stations to the central unit which sends it to the receiving part in the ground stations.

Each receiving station SR monitors a decoder DM, for the distribution message and this decoder is connected to a reception connection memory CR, which transmits the content of the distribution message to inform the receiving part of the connection between the satellite channel and the earth channel made by the transmitting part of the earth station, belonging to the station which has sent out the group of received data.

The memory CR comprises a number of counters equal to the number of stations from which it is possible to receive data (maximum 30) and each unit supplies a number of memory rows equal to the number of satellite channels (120 + 17) that can be processed by a specific earth station .

The data is supplied to an expansion memory ME, which also monitors a memory A and a memory B in the time interval when entries are made in one memory at high speed and readings are made in groups in the other memory continuously at the speed of the PCM system, originating from the earth station.

The purpose of the invention is to monitor the count of the satellite channels and the count value is used to read from the reception connection memory CR.

In particular, the central station provides an indication of the station, below called the originating station, which has sent a specific group of data and this indication addresses the memory assigned to the station. The output signal from the counter then addresses the memory row, in which the number of terrestrial channels connected to each satellite channel is stored.

In the case where the terrestrial channel 20 is assigned to the satellite channel 15, when the counter reaches 15 in the memory assigned to the station to which the channel refers, the counter value 20 will be read. When data relating to the satellite channel 15 is presented at the input .in the memory ME, these are stored in row 20 in the memory A or B, which is in the recording phase.

Since a given receiving station SR can receive data in several broadcasts, which are shuffled, when sending from other stations, the switching device according to the invention monitors a memory that supplies a number of positions equal to the number of stations from which it can receive data, in which positions are recorded a number of channels that have been received during previous broadcasts to start the count again from this count value.

Figure 2 shows a counting chain CN, which contains a first counter CN^, which is supplied with a series of timing pulses CK from the central unit, which derives this series from groups of data received by the satellite. The counter CN^ has a counting capacity of 24, which is equal to the number of bits in each channel of the TDMA frame.

After the counter CN^ has counted 24 pulses of the series CK, it emits a pulse which is supplied to the counting input of a second counter CN2 with a counting capacity of 120, which is equal to the maximum number of satellite channels that can be processed by the earth station.

For every seven normal channels, an overload channel is arranged and the pulses from the counter CN^ are also supplied to a third counter CN^ with a counting capacity of seven and the output signal from this counter is supplied to a fourth counter CN^ with a counting capacity of 17, which is equal to the maximum number of congestion channels arranged.

Output signals from the second, third and fourth counters are applied to a memory device MM, which contains random access memories RAM^, RAM2 and RAM^ each having thirty rows' equal to the maximum number of stations that can be received by the ground station.

The memories are addressed with binary signals, indicating the station of origin, provided by the central unit which receives data from the stations in a predetermined sequence.

The origin signals are supplied to the memories

by means of a corresponding number of multiplexers MT^, MT2

and MT3, which on a second input receives binary signals from a fifth counter CN,. with counting capacity 30 and which forms part of the reset device AZ.

The reset device AZ further comprises three further multiplexers MT^, MT,, and MT^, whose first input group is connected to the output of the associated random access memory and whose second input group is supplied with pulses with a logic level "0".

These multiplexers provide codes that represent the first group of inputs or the second group of inputs depending on the logic level that a control signal represents.

A control device MA is also arranged which contains a sixth counter CNg with a counting capacity of 8 equal to the number of clear pulses delivered from the central unit. The counter CN6_ is connected to a decoder DC with a first output that delivers a pulse (for example, the third) of the first half of the ready interval, a second output that delivers a signal simultaneously with the central pulse (the fourth pulse) in the ready interval and a third output which delivers a pulse (for example the seventh) in the second half of the clear time interval.

Figure 3a shows a curve with two pulses at a time interval of 750 yseconds, and each of these pulses represents a TDMA frame.

Figure 3b shows a pulse at the beginning of the frame and has a duration that enables zeroing using the device AZ. The pulse is supplied to the control input in the multiplexers MT^ - MT^ and determines the sending of codes in the second input group.

At the same time, the counter CN^ is prepared for counting, so that it in turn scans all the addresses in the memories RAM^, RAM2 and RAM^, while the counters CN2, CN3 and CN^ count pulses representing a logic level "0".

In each address scanned by the counter CN,. pulses representing a logic level "0" from the counters CN2, CN^ and CN^ are stored and thus determine zero setting of the counters as well as of the rows in the random access memories.

When the reset phase is performed, the multiplexers MT^-MT^ deliver the coded output signal representing the first group of inputs.

From this point, the central unit receives the indication of the origin signal 0^ from the first station, as shown in figure 3c, together with a group of eight clear pulses as shown in figure 3d. On the first output from the device DC, pulses shown in figure 3e appear, which are used for entering the count value in the counting device in the memories with random access, and on the second output, the pulses shown on figure 3f appear, which are fed to the device TR for recoding , while pulses appear on the third output as shown in figure 3g, which are used for entering the codes in the counters CN2, CN3 and CN4>

The origin signal 0^ is recoded in the unit TR to

> suitable code for the earth station and the recoded code is stored in the memory for a time interval, which is not less than the occurrence of the pulse train f, which represents the clear interval in connection with the next originating signal, as shown in figure

3h.

When the sending of the ready pulses, which apply to a particular station, is completed, the central unit delivers data D, as shown in Figure 3i, which is sent out by the station, and the origin indication for this appears on the output of the unit MT1, MT2 and MT^.

This data is arranged in channels of four bits each and a specific earth station can process 120 standard channels as well as 17 overload channels and from this data the central unit derives the timing pulses CK, which are fed to the counter CN^, which gives an output signal at the end of each channel.

Pulses corresponding to the output signal from the counter CN.j are supplied to the counter CN2, which counts the standard channel and they are also supplied to the counter CN^, which is connected to the counter CN4, which counts the overload channels.

When the counting of the channels assigned to the origin signal 0^ is finished, the pulse train e becomes the origin signal to be observed and determines the transfer of the count value in the counters in the memories RAM^, RAM^ respectively RAM^ and especially in rows identified with the recoded origin signal 0t^.

At the same time as the pulse train f, which follows the aforementioned pulse train e, the unit TR prevents the transmission of the code Ot^ and delivers the code 0t2, which applies to the origin signal 02. The code 0t2 addresses the next row in the random access memories in which, according to the present example, they are stored as bits representing logic level "0", which are simultaneously with the pulse train g, which follows the origin signal 0t2, transferred to the counters CN2, CN3 and CN4.

If the originating station 02 had previously transmitted a number of h standard channels and a number of k, y overload channels in the same frame, in the rows .in the memories RAM^, RAM2 and RAM^, addressed by the code 0t2, the numbers f, y respectively k would be stored.

In this case, the pulse train g would have determined the entry of the numbers h, y and k into the counters CN2, CN^ and CN^ and the counting would therefore have continued from these count values. If it is assumed that the originating station 02transmits n1 r Y 1 and. k^ channels, the numbers h + h and y + <y>^ and k + k1 would be added to the counters CN2, CN3 and CN4 during the second transmission, these would be transferred at the end of the transmission to assigned rows in the memories RAM^, RAM2 and RAM^ simultaneously with the pulse train e, which follows the appearance of the originating signal and so on in the case of further transmissions from the originating station 02. In this way, by means of random access memories RAM^, RAM2 and RAM^, it is possible to use a single counting chain to perform the reading of the terrestrial channel number, which is assigned to each satellite channel and which is entered in the memory CR.

Claims (6)

1. Coupling device for time management of the receiver part in an earth station for satellite connection, where a number of stations each comprising a central unit are connected to a number of earth stations, characterized by a counting device (CN) which is supplied with a series of time pulses (CK) from the central unit derived from data received from satellite and capable of counting the number of channels reaching the relevant earth station; a storage device (MM) comprising a number of memory rows corresponding to the number of earth stations that receive data for storing the number of channels from the counting device; a reset device (AZ) for resetting to zero the counting device and the storage device at the beginning of each frame; and a control device (MA) which is supplied with a number w of ready pulses (d) from the central unit together with a code identifying the originating station, and delivering a first series of pulse(s) to cause the storage device to store the count value in the counting device, a second series of pulses upon the occurrence of a pulse that is simultaneous with the pulse ^ in the series of pulses (f) received by the control device, and a third series of pulses (g) for transferring the contents of the memory row detected by the originating station to the counting device. 2. Switching device according to claim 1, characterized in that the counting device (CN) comprises a first counter (CN^ ) with a counting capacity equal to the number of pulses contained in one channel and whose output signal causes counting in a second (CN2) and a third (CN^ ) counter with counting capacity equal to the maximum number of channels that can be processed by the ground station, resp. equal to the number of standard channels between two consecutive congestion channels, the output signal from the third counter causes counting in a fourth counter (CN^ ) with a counting capacity equal to the maximum number of congestion channels that are arranged. 3. Connection device according to claim 1, characterized in that the storage device (MM) comprises a first (RAM1), a second (RAM,,) and a third (RAM^) memory with arbitrary access and whose data input is connected to the output of the second ( CN2) , the third (CN-^ ) resp. fourth (CN^ ) counter, and whose address input is supplied with the identification for the station served by the central station. 4. Switching device according to claim 3, characterized in that the identification of the station that reaches the memories (RAM^, RAM2, RAM^ ) via a encoder (TR) is supplied to a first group of inputs in a first (MT^ ), a second (MT2 ) and a third (MT^ ) multiplexer whose second group of inputs receives the output signal from a fifth counter (CN,.) which forms part of the reset device (AZ) and has a counting capacity equal to the number of rows in the memories, and that the output signals from the memories (RAM^ ,RAM2 ,RAM^ ) are supplied to a first group of inputs in a fourth (MT^ ), a fifth (MT,-) resp. a sixth (MTg) multiplexer whose second group of inputs is supplied with pulses of logic level "0", and whose output signal is supplied to the second (CN,,), the third (CN3 ) resp. fourth (CN4 ) counter. 5. Switching device according to claim 1, characterized in that the control device (MA) comprises a sixth counter (CNg) with a counting capacity equal to the number of clear pulses supplied, and whose output signal is supplied to a decoder (DC) with a first output which delivers the first series of pulses ( e), a second output which delivers the second series of pulses (f) and a third output which delivers the third series of pulses (g), and that each pulse in the first series (e) or in the third series (g) coincides with a predetermined pulse in the first or second half of each group of clear pulses. 6. Switching device according to claim 5, characterized in that the encoder (TR) transforms the identification (Ch) of the originating station into a code (Ot^V for the associated earth station and emits this code in a time interval that is shorter than the appearance of a pulse in the other series (f) which applies to a series of clear pulses assigned to the run station (0. + 1).