NO173720B - DIGITAL TRANSMISSION TRANSMULTIPLE TRANSMISSION SYSTEM - Google Patents

Description

The invention relates to a digital transmission system according to the introduction to patent claim 1 and patent claim 4 respectively.

Such a transmission system is known, for example, from the papers "On-Board Processing for Communication Satellite Systems: Technologies and Implementation" by Betaharonm.fi., 7th International Conference on Digital Satellite Communications, Munich, Germany, May 1986, pp. 421 to 426, and "Baseband Switches and Transmultiplexers for Use in an On-Board Processing Mobile/Business Satellite System" by Evans et al., 7th International Conference on Digital Satellite Communications, Munich, Germany, May 1986, pp. 587 to 592.

The application area for such a transmission system with digital frequency multiplex - or demultiplexing and digital transmission are advantageous in so-called intelligent satellite systems with transmission and traffic management. With this upcoming generation of signal or communication satellites, it is about connecting the total communication traffic running over the satellites, which can come from one or more ground stations, in the most flexible way possible, i.e. to a large extent arbitrarily changeable, to directional antennas with different lighting zones (Ausleuchtzonen) on earth. The most important application is probably in satellite mobile radio, for example for ships, trucks, planes, etc. Such a mobile subscriber moves for a time in the lobe of one antenna, and later in the area of another antenna. The connection in the satellite must then be transferred to the other antenna. The same applies in the opposite direction. Each mobile subscriber is assigned a separate individual channel frequency and a narrow bandwidth B (for example of the order of magnitude between 8 and 20 kHz), as the traffic from the mobile subscriber to the satellite or vice versa is conducted over frequency multiplex signals. In order to be able to carry out the most flexible traffic management in the satellite, the frequency multiplex signals received by an antenna in the satellite and written from the mobile subscriber must be routed via a frequency demultiplexer, so that they can be individually made available and communicated. The individual signals can then be connected via a connection matrix to the individual multiplexers.

The state of the art is shown in fig. 1 for the one transmission direction and in fig. 2 for the reverse transmission direction.

of received frequency multiplex signal analogue/digitally converted, supplied to a demultiplexer DEMUX in which the L channels bundled together in frequency multiplex are separated, and these thus separated L channels conveyed via a digital L x L switching matrix (L x L Switchmatrix). Groups of these L channels are then bundled together by means of M multiplexers whose output signals, after digital/analog conversion and via a phase control network BFN, which determines the direction and illumination angle of the illumination beam, are given to the transmitting antenna. Maximum flexibility of this mediation (traffic management) is achieved when all M multiplexers MUX for the M antenna lobes (beams) can frequency multiplex all L channels on the demultiplexer output side DEMUX. In this case, by corresponding dimensioning of the L x L connection matrix in accordance with the requirements, each lobe can transmit any arbitrary number of channels, i.e. between 0 and L. To realize this maximum possible flexibility, a demultiplexer for L channels is required , an expensive time/space/time multiple baseband switching device L x L switching matrix, and M multiplexing MUX for respective L channels. One speaks of limited flexibility, and this is in practice the case with the majority of systems, when the M multiplexers MUX can only multiplex L' < L channels, whereby the channel numbers for the individual multiplexers MUX can have different sizes.

Fig. 2 shows a transmission system for the reverse direction, i.e. the opposite direction. The modes of operation for the individual blocks occur in a similar way in the opposite direction and do not need any further description here.

The purpose of the invention is to reduce the costs and thus the volume, mass and power consumption of the above-mentioned transmission system with regard to the baseband coupling device and frequency multiplexing, of course while maintaining the arranged, planned or projected flexibility.

The above-mentioned purpose is achieved by means of the characterizing features stated in claim 1 and claim 4, respectively.

The advantage of the transmission system according to the invention is the reduced cost and thus less power requirement, less mass and less volume. There are further advantages associated with this, such as increased reliability or reduced redundancy, which is a priority goal for satellite applications.

The solution according to the invention is based on a suitable pre-dentation or parallel processing of the functions coupling matrix and frequency multiplexing, which in the following is referred to as distributed or hierarchical traffic management and multiplexing.

The invention will be described in more detail below with reference to the drawings, where fig. 3 shows the structure according to the invention of the alternating switching and frequency multiplexing of channels, the frame of the one in fig. 3 shown structure precisely comprises the functions of the blocks with the digital L x L connection matrix and the M multiplexers MUX of fig. 1, and fig. 4 and 5 show an optimal design for the multiplexer structure.

From fig. 3 shows that it is relayed alternately, and more specifically in the switching matrices SM, and multiplexed in the sub-frequency multiplexers MUX. There are x stages, the first stage with the connection matrix SMI and the MUX1 connected to this up to stage x with SMx and MUXx. The first connection matrix exhibits L = LO inputs and L = LO outputs, and the multiplexer MUX1 in the first stage multiplexes L = LO inputs to LI outputs, as LI < LO. In the following stages, the number of outputs from the multiplexers is continually reduced by means of multiplexing, and in the last stage, M multiplex output signals with Lx multiplexed signals are available to the M lobes.

When using the digital signal processing for the switching matrix in the individual stages, the inputs and outputs are assigned to a fairly specific time slot or time slot on a data bus. The function of the switching matrix then consists in making the allocation of the L^ entry time slots to the L^ exit time slots in the x'th step for x = 0 up to x = x corresponding to the desired traffic management. Each output time slot in the switching matrix SMX is fixedly assigned to an input channel in the subsequent sub-frequency multiplexer MUXX. Each connection matrix can therefore be realized as storage switches (memory switches) that work in a pure time multiple. As such switches, the switching matrices are then substantially more cost-effective than the closed switching matrix according to fig. 1 respectively fig. 2, see also chapter 3 in the above-mentioned thesis "Baseband Switches..." by Evans et al. The bearing switch is in contrast to the closed realized connection matrix according to fig. 1 respectively 2 free of blockage, which is a further advantage of the solution according to the invention. With the solution according to the invention, it is true that approximately ld L or Id L'(ld = logarithmus dualis, x = f ld L'"] ) connection matrices. It can therefore be assumed that the total costs for traffic management with the solution according to the invention are only insignificantly less than the costs according to fig. 1 and fig. 2.

The significant cost advantage of the solution according to the invention is achieved by saving multiplex units, namely a number of separate multiplexers. This will be explained in the following description.

If fig. 1 is considered, it becomes clear that respective, different signal streams must be delivered to the M antennas. In the extreme case that only one channel signal is to be supplied to M-l antennas, and that to one antenna the remaining L-(M-l) or L'-(M-1) channel signals, the grouping on the antenna input side must already be evident in the multiplexer MUX1 in the first stage. In accordance with this, [ H[ L-( M- 1)]"| single multiplexers which combine two respective signals, and M-l single multiplexers which are supplied with only one input signal are needed here. Here [x] means the second largest whole number in relation to x. The first multiplexer MUX1 thus needs LI = f%[L-(M-1)]"| + (M-l) single frequency multiplexers. A hierarchically structured multiplex directly applicable for this purpose can be seen in fig. 4 as overall structure, and of fig. 5 as a single multiplexer. For a detailed description of these, reference is made to the German patent application P 36 10 195.

In general, the last step x applies under the assumption that LO = L:

x times

In accordance with the hierarchical structure of the traffic management and the frequency sub-multiplexing, the scan frequency in the individual multiplexer stages increases by a factor of 2. In a similar way, the scan frequency in the individual demultiplexer stages is reduced in the opposite direction by a factor of 2.

On the basis of an example, the cost advantage of the solution according to the invention in relation to a concentrated solution shall be demonstrated in the following. With M = 12 lobes, the first case is L' = L = 2<8> = 256, and in a second case L' = 2<6> = 64. In the solution according to the known technique, M = 12 complete frequency multiplexers are needed for L ' channels. With a step-shaped structure of this concentrated multiplexer, ld L' steps are then necessary, as each step must exhibit exactly the same calculation performance C, as the number of single multiplexers is halved from step to step, but the scanning frequency is simultaneously doubled. If the computing performance (cost) of a stage in a multiplexer realized in a concentrated manner according to the known technique is determined standardized to 1, in case a) ld L = 8 stages and a total computing performance CK = M • ld L • 1 = 96 apply, and in case

b) ld L' = 6 and a calculation performance of CK = M • ld L' =72.

The corresponding calculation performance Cy for a distributed multiplexer structure in accordance with the solution according to the invention appears in relation to the concentrated multiplexer CK with the following values:

Case a)

or compared to the computational performance of the concentrated multiplexer implementation

CVCk = 29.8125/96 = 0.31.

Case b)

or compared to the concentrated multiplexer design CV/CK = 45.25/96 = 0.628.

Fig. 4 shows a tree structure realization of a stepwise distributed demultiplexer of pure 1:2 single demultiplexers which, during halving of the scanning speed, resolves or divides the input signal into two halves. The connection matrices, which must be connected between the individual steps, are not shown here. Such a tree structure can advantageously be used in transponders

according to fig. 2.

For the device for transmission in the reverse direction according to fig. 1 is the same structure according to fig. 4 is suitable, in that only the direction of the arrow for the direction of transmission must be reversed, so that a corresponding three-structured, distributed multiplex arrangement is created.

In fig. 5 is a particularly cost-effective device for a partial demultiplexer shown in detail (for a description of this, reference is made to the above-mentioned German patent application P 36 10 195).

The switching matrices can advantageously be realized as memory switches. Such stock switches are described, for example, in the thesis "A Baseband Switch for Future Space Applications" by Berner and Grassmann in Space Communication and Broadcasting 5 (1987), pp. 71 to 78 and in the two German patent applications P 36 41 561 and P 37 20 644 .

Claims (7)

1. Digital transmission system in which L channel signals are conveyed by means of a digital switching matrix to the inputs of multiplexers each of which combines up to L' < L channel signals in frequency multiplex and which emits its output signal in one of M < L directions, CHARACTERIZED BY - that the multiplexers are all realized by means of a cascade of several single multiplexers connected in stages one after the other (multiplexer stage MUX1 ... MUXx), - that in front of the individual multiplexer stages (MUX1 ... MUXx) a respective switching matrix (SMI ... SMx) is connected, - that the coupling matrix (SMX) in the x'th stage, for 1 < x < x, has inputs and Lx.x outputs, and - that the outputs of the coupling matrix are connected to the inputs of the multiplexers in the subsequent multiplexer stage (MUXX) which have Lx outputs, and the inputs of the switching matrix are connected to the Lx.x outputs from the upstream multiplexer stage (MUX^). 2. Digital transmission system according to claim 1, CHARACTERIZED IN THAT the multiplexers are all realized by means of a tree structure of stepwise branching, successively arranged 2:1 partial multiplexers, the scanning frequency being doubled at the transition from one to the next stage. 3. Digital transmission system according to claim 2, CHARACTERIZED IN THAT the 2:1 partial multiplexers are realized by means of digital filter banks. 4. Digital transmission system for the transmission of L channel signals, whereby M < L signals, which are formed by frequency multiplexing of at most L' < L channel signals, are received from M directions and with the help of demultiplexers (DEMUX) are resolved into the L single signals, these L single channels are transmitted using a switching matrix, CHARACTERIZED BY - that the demultiplexers are all realized using a cascade of several single demultiplexers connected in stages one after the other, - that a respective switching matrix is connected after the individual demultiplexer stages, - that the switching matrix SMX in the x'th step, for 1 < x < x, shows Lx_x outputs and inputs, and - that the Lx.x inputs of the coupling matrix are connected to the outputs from the upstream partial demultiplexers that show Lx inputs, and the outputs of the coupling matrix are connected to the Lx.x inputs to the downstream partial demultiplexer. 5. Digital transmission system according to claim 4, CHARACTERIZED IN that the demultiplexers are all realized using a tree structure of stepwise branching, successively arranged 1:2 partial demultiplexers, the scanning frequency being halved at the transition from one to the next stage. 6. Digital transmission system according to claim 4 or 5, CHARACTERIZED IN THAT the 1:2 demultiplexers are realized by means of digital filter banks. 7. Digital transmission system according to one of the preceding claims, CHARACTERIZED IN THAT the connection matrices are realized by means of baseband switches.