DE3600795A1 - Digital communications system - Google Patents

Abstract

The invention relates to a digital communications system for broadband data such as video, videotelephony etc., comprising networks which are in each case synchronised by means of a local reference clock, the data received in one network from other networks being stored temporarily in a buffer memory and being read out again in time with the reference clock, and is characterised in that the serially received bit stream is divided into N bit streams at the same bit rate which are temporarily stored in a buffer memory, are then read out and re-combined to form a serial bit stream. Parallelisation and re-combination are carried out by serial/parallel or parallel/serial converters. The write clock is derived by means of an N/1 divider from the receive clock and the read clock is derived, similarly by means of an N/1 divider, from the transmit clock (Figure 1). <IMAGE>

Description

The invention relates to a digital message transmission system according to the preamble of claim 1.

Channels with the PCM bit rate of 139.264 MBit / s on the long-distance routes between the local exchanges ( OVSt ) will be used in the planned ISDN B network and in the BB upstream network for the transmission of broadband data, video telephony and video conference services etc. used. It is planned to control these networks isochronously, whereby the individual OVSt islands are to be connected to a clock standard of 2.048 MHz. Because of the frequency drift of the clock standards, because of the temperature-related phase fluctuations of the transmission links and because of other influences, a phase deviation of up to ± 9 µs between the individual clock islands must be expected (according to Hartmann's article, among others, "Synchronization of integrated networks by microprocessor-controlled digital phase locked loops", NTG - Report No. 88, March 1985, pp. 218-225).

These phase deviations must be stored in the buffer memory the received data are temporarily stored will. The required buffer storage depth must be at least 2 · 9 µs · 139.264 Mbit / s = 2507 bits if you want to fully compensate for the long-term drift of ± 9 µs. At high bit rates of e.g. B. 139.264 Mbit / s, the buffer memory executed in ECL technology and required thus a great supply performance.

The present invention was therefore based on the object a digital message transmission system of the aforementioned Specify type that allows using a buffer memory get along with a smaller utility needed.  

This task was carried out with the characteristic features of the Claim 1 solved.

The advantage of the system according to the invention is that by parallelizing the incoming receive bit stream into several slower bit streams and for the subsequent one A buffer memory is required for the intermediate storage of these bit streams will be at a much slower speed works and can therefore be implemented in a technology that requires much less utility power. This will generates much less heat loss, and the buffer storage can therefore be realized with a high packing density, d. H. the buffer memory can with integrated circuit technology be carried out.

Optimal configurations of the invention result from the subclaims.

There now follows the description of the invention with reference to the figures.

Fig. 1 shows a circuit arrangement embodying the invention, again, by which the latched received data ED and cyclically in synchronism with a jitter-free, abgleiteten by a clock normal TN transmit clock ST as sending data SD to be read out again. The input data are parallelized in N bit streams by means of a series / parallel converter S / P , and written into the intermediate buffer Sp . The series / parallel converter is clocked by means of the reception clock ET derived from the reception data ED by means of a clock derivation TA . The write clock S is obtained from the receive clock ET by a first divider N / 1. The N bit streams are read out in a parallel / series converter P / S , which in turn produces a serial bit stream, the transmit data SD . The transmit clock ST is obtained from a clock standard TN via a phase locked loop PLL . The transmit clock ST is divided by means of a further N / 1 divider and serves as a read clock L for reading out the buffer. The phase difference between the write and read clock is determined by means of a phase comparison stage Δϕ and, if necessary, briefly stopped or switched over by the second divider, controlled by a phase shifter + ϕ , brought to values around π, so that write and read accesses to the buffer memory Sp Safety apart in time. Advantageously, the clock division is carried out by means of N = 16, since commercially available memories, e.g. B. RAM, 8-bit or 16-bit are organized.

The write and read clock then amount to one PCM channel of 139.264 Mbit / s 8.704 MHz. In this case there is a memory depth from 2 · 9 µs · 8.704 MHz = approximately 157 16-bit Words required. The number of memory flip-flops is then 16 x 157 = 2512 bits, which includes the Control of the write and read cycle in a simple manner find space in a CMOS gate array.

The series / parallel or parallel / series converter can be implemented in ECL or E ² CL technology, including the divider N / 1 in an ECL gate.

The selection from N to 17 is particularly advantageous, in this case an N / 1 divider can be saved because this 17: 1 divider is part of the phase lock loop PLL according to FIG. 2. There, the transmit clock ST of 139.264 MHz in this example is generated by a voltage-controlled oscillator VCO and divided to a frequency of 8.192 MHz by means of the 17: 1 divider mentioned, which can be used directly as the read clock L. A subsequent 4: 1 divider is used to divide down to 2.048 MHz, that is to say the frequency of the clock standard TN , and to compare the clock frequency thus generated by means of a multiplier X or a phase difference element to the clock standard TN . The comparison result is given to the control input of the voltage-controlled oscillator VCO via a low-pass element. With this solution, the components of the phase locked loop such as phase detector X, 17: 1 and 4: 1 divider also find space in the ECL module.

Advantageously, those in ECL structures and those in Circuit functions to be defined in CMOS structures a single integrated circuit with mixed Technologies of bipolar and CMOS processes combined, a technique known, for example, as Hi-BICMOS (Hitachi) or as BICMOS from Telefunken electronic (Jürgen Arndt. "BICMOS - A key to high performance VLSI circuits ", NTG technical report No. 87, large integration, Baden-Baden, March 18 to 20, 1985, pp. 5-6).

Claims (13)

1. Digital message transmission system for broadband data such as video, telephony, etc., consisting of networks, each of which is synchronized by means of a local clock standard, the data received across a network being temporarily stored in a buffer memory and read out again in synchronism with the clock standard, characterized that a series / parallel converter ( S / P ) is provided, by which the cross-network received bit stream ( ED ) is divided into N bit streams of the same bit rate,
that the N bit streams are written into the buffer memory ( Sp ) by means of a clock ( S ) which is derived from the receive clock ( ET ) by division by N ,
that the N bit streams are read out of the buffer memory ( Sp ) by means of a clock ( L ), which is derived from the transmission clock ( ST ) obtained from the clock standard ( TN ) by division by N , and
that a parallel-serial converter ( P / S ) is provided, through which the N bit streams are combined synchronously with the transmit clock ( ST ) to form a bit stream ( SD ) ( FIG. 1). 2. A digital communication system according to claim 1, characterized in that a phase comparator (Δφ) is provided through which the phase between the divided-by-N receive timing (S) and the N-divided transmission clock (L) is determined. 3. Digital message transmission system according to claim 2, characterized in that a phase shifter (+ ϕ ) is provided which is controlled by the phase comparator ( Δϕ ) and which shifts the transmission clock divided by N ( L ) so that write and read access to the buffer memory ( Sp ) are separated in time. 4. Digital message transmission system according to one of the preceding claims, characterized in that it for PCM channels with a bit rate of 139.264 Mbit / s becomes. 5. Digital message transmission system according to claim 4, characterized in that the buffer memory ( Sp ) has a capacity of at least 2507 bits. 6. Digital message transmission system according to one of the preceding claims, characterized by N = 16. 7. Digital message transmission system according to claim 6, characterized in that the buffer memory ( Sp ) has a depth of 157 words. 8. Digital message transmission system according to one of the preceding claims, characterized in that the buffer memory ( Sp ) is implemented in CMOS technology. 9. Digital communication system, characterized in that the parallel / series converter ( P / S ), the series / parallel converter ( S / P ) or the divider N / 1 are implemented in ECL or E ² CL technology. 10. Digital message transmission system according to one of the preceding claims and claim 4 with the exception of claim 6 or 7, characterized by N = 17. 11. Digital message transmission system according to claim 10, wherein the local clock standard ( TN ) has a jitter-free value of 2.048 MHz, characterized in that a PLL loop is provided for generating the local transmit clock ( ST ) of 139.264 MHz, in which the transmit clock ( ST ) at the output of a voltage controlled oscillator (VCO) is divided by a 17: 1 divider to the reading clock ( L ) and then by a 4: 1 divider to the value of the clock standard ( TN ). 12. Digital message transmission system according to claim 9 and 11, characterized in that the phase comparator ( Δϕ ), the 17: 1 and 4: 1 divider are implemented in ECL or E ² CL technology. 13. Digital message transmission system according to claim 12, characterized in that the modules realized in ECL or E ² CL and CMOS technology are integrated on a single integrated circuit.