DE10118989A1 - Digital communications system allocates variable length code words gives bandwidth flexibility - Google Patents

Abstract

The digital communication system allocates variable length code words (Bn1-3) to data streams in asynchronous transfer mode.

Description

Technical field

The present invention is concerned with digital transmission of information. To make better use of the transmission paths are there also changed the bandwidths and the bit rates, whereby the transm package based.

State of the art

In this regard, the asynchronous transfer mode (ATM) is known, based on is based on a connection-oriented packet switching procedure. there all useful and control information from a source becomes more fixed in packets Length, the cells, divided. This sequence of cells form a di gital news flow. The number of cells that are assigned to a source are ordered, then determine the bandwidth. This range is included to be requested from the network before the connection is established. A cell head includes the tax information. Cell overhauls can also occur in the coupling network whose elimination requires resequencing mechanisms. A disadvantage This technology is a major hardware effort. Buffer memory are then required when the physical current path no longer has bandwidth provides.

Summary of the invention

The object of the invention is the disadvantages of ATM, such as the effort the hardware, the transmission paths optimally not only through bandwidth and bit switching but also a targeted channel orientation benefit. This is he through the teaching disclosed in claim 1 enough.

Brief description of the drawings:

Fig. 1, 2, 3 principle of phase and continuous pulse coding.

Fig. 4, 5, 7 principle of the envelopes and soft amplitude change.

Fig. 9 is a 16 PSK diagram

Fig. 8, 11 and conventionally radio relay system according to the invention.

Fig. 6 Principle of switching to different types of transmission.

Fig. 10 application of the invention in EB.

Fig. 12 Switching channels over several switching nodes.

Fig. 13, 13a A flexible packet and channel-oriented transmission.

Fig. 14 Principle of a television receiver with single-carrier signal transmission.

Fig. 15 Principle of ATM technology.

First, the methods on which this invention is based are explained in more detail. The more stages the code has, the more information can be transmitted, as the following table shows.

Is used for coding 2 alternating currents phase-shifted by 90 ° same frequency, which are added for the transmission (QAM) one 4 × 4 = 16 steps.

With carrier frequency transmission you can use the EB method because of the 1/6 power. Because according to the carrier formula

the modulation amplitude is not included in the frequency, you get a narrowband transmission.

The phase principle

With this principle, the phase positions of pulses z. B. to a reference pulse or the positive or negative difference to the previous pulse are provided as stages. In Fig. 1, the reference phase of the pulse B1, B2, B3,. , , As shown in FIG. 1a, the pulses Bn1, Bn2, Bn3,. , , out of phase by the amount. In Fig. 1b, the pulses BN1, BN2, BN3 are the same phase. This phase code would therefore have two levels Bn and BN. These pulses are represented by integer half-periods or periods of the same frequency. In FIG. 2, such a coding is positioned drawing net. 4 periods are assigned to the reference pulse. The 1st pulse BNp therefore has 4 periods. If the following pulse is to be lagging, it must have 5 periods. The 2nd pulse Bnn is therefore lagging by the amount n. If the 3rd pulse is to remain lagging, it must have 4 periods. The 4th pulse should be in phase with the reference pulse again, this is achieved in that it receives one period less, i.e. 3 periods. It can also be seen that each subsequent pulse has an amplitude change. A doubling of the number of stages can be achieved by letting the impulses begin with a positive and a negative half period. Hatched in the drawing. So you get 2, 4 levels. (Euro patent EP 0 953 246 B1).

The pulse duration principle

With this principle, different pulse durations or pulse duration differences are used as stages. In FIG. 3, 3 pulse durations represented D1, D2 and D3 which are 3 stages. It also represents a 3-digit code word. The position 1 can assume the levels D1, D2, D3 - the position 2 the levels D2, D1, D3 and the position 3 D3, D1, D2. You get 3 to 3 combinations of 3 levels and 3 digits, i.e. 3 × 3 × 3 = 27 combinations. If you also use the positive and negative start of the levels or code elements, you get 6 levels. With 3 digits you get 216 combinations. The QAM can also be used. The coding alternating current can also be provided as a transmission alternating current.

How will the "flexibility of bandwidth" feature, which is particularly emphasized in the ATM method, be achieved in the present methods? This can be done in a very, very simple way. The envelope changes also result from the amplitude changes. In FIG. 4, such is shown by 2 and 3 periods as steps. fH is the envelope here. In FIG. 5, however, the stages 11, 12 and 11, 12, 13 periods. In both stages, 10 periods are provided as filling elements. You can see here that the frequency of the envelope is much smaller, which means that the bandwidth is also smaller. So you can determine the bandwidth using the filler elements. It is not necessary to change the coding frequency.

You can also control the bit rates very flexibly. It can be seen from FIGS. 1 to 3 that a large number of stages can be provided without having to change the coding frequency. Depending on the type of transmission, language, data, images, you can precisely match the code words to the required number of bits, which of course also applies to ATM. The principle is shown in FIG. 6. The coding frequency is generated in the oscillator OSC and fed to the modulator MO. Depending on whether music, voice or image or television is to be transmitted, marked by the feed M, S, B on the encoder, the appropriate stages and code words - it is only a period count and amplitude switching is necessary - given to the modulator . This avoids redundancy. The number of bits in the code words is therefore precisely adapted to the respective transmission type. The code words are then decrypted in the decoder D Cod and converted into the respective analog values of M or S or B. In Fig. 7 a soft amplitude switching is provided. Between the amplitudes A and AI there is another period with the transition amplitude AÜ.

In order to document how large the information density is in this method, a comparison is made with a directional radio system, the principle circuit of which is shown in FIG. 8. This is designed for 34.368 Mbit / s. The bandwidth is 1700-2100 MHz with 4 PSK coding. As you can see, the hardware is very complex. In the case of a code according to FIGS. 1-3 or 4, the predetermined bandwidth would not be sufficient. Filling elements must therefore be provided. With 4 levels with 10, 11, 12 and 13 periods, an average of 11.5 periods is required for one code element. 4 × 11.5 = 46 periods are then required for a 4-digit code word. 1900 MHz is the coding frequency, then you get 1900: 46 = 41.3M code words / s. With a code word you get 4 to the power = 256 combinations, that is 8bit. With 41.3M code words, this is 41.3 × 8 = 330Mbit / s. So it holds 9.6 times more bits than with the conventional directional radio system. If the stages are doubled, as shown in FIG. 2, 8 stages are then obtained. With 4 digits you get 8 to the power 4 = 4096 combinations = 12 bit. With 41.3 code words, this is 495.6 Mbit / s. That is 14.4 times as much as with the directional radio system of conventional coding. If 2 alternating currents of 1900 MHz are used for coding, which are 90 ° out of phase with respect to one another and which are added during transmission (OAM), 8 × 8 = 64 steps are obtained. With a code word with 2 digits you get 12bit. An average of 23 periods are then required for each code word, so that 82.6 M code words are obtained at 1900 MHz. That is 991Mbit / s, 28.8 times more than the directional radio system. Counting elements are mainly required for coding and decoding. To compare how simple this code is, a diagram of a 16-stage phase coding is shown in FIG. 9. In FIG. 11, the principle of a directional radio system is shown according to the invention. The signal arriving with the HDB3 code is converted into the code according to the invention in the code converter and switched directly to the transmission amplifier Vr and further to the antenna.

In Fig. 10, a carrier transmission on single sideband basis EB is Darge. The information Jf is coded in the encoder Cod with the alternating coding current fM and in the ring modulator RM with the alternating current fTr. At the output of the ring modulator, the carrier is +/- modulation frequency. In the example, the lower sideband is filtered out with the high pass HP, so that only the upper sideband, which also contains the entire information, is transmitted. As can be seen from the carrier formula, the modulation amplitude is not included in the frequency.

In Fig. 12 are network nodes K1, K2, K3 with included Koppelanordnun conditions. Each node has a control unit St. Over 0, the long-distance connections of the local connections to the respective control unit are switched on. Statistically recorded is how much traffic goes directly from node 1 to node 3. Correspondingly, channels in node K2 are then switched through immediately.

An encoding of the color television signals is shown in FIG . The luminance taps L are assigned 8 bits. 4 luminance taps are assigned 1 color tap I / Q or red / blue with 6 bits each. These 12 bits are then appended to the 4 × 8 bits of the luminance values. Each bit of tapping is assigned 1 bit for control signals and voice. So 12 taps must be coded for each tap. A carrier is therefore sufficient for the transmission. Therefore, the television receiver according to FIG. 14 can be designed like a superhet radio receiver up to the decoder, ie the input stage, mixer stage, demodulator. The signals are then separated in the decoder according to their tasks. The color difference signals are then generated via the matrix M. AS, Y, tone T and other signals SO are connected to the corresponding modules.

Another method for bandwidth and bit rate flexibility is shown below, which is explained in more detail with reference to FIG. 13. As can be seen from this figure, all color television signals are coded and transmitted with 12 bits. Since the tapping of the color signals is slower than that of the luminance signals, these are temporarily divided into 4 luminance values. If another type of information is to be transmitted after the end of the color television transmission, redundancy losses are to be expected with the previous codings. Fig. 13 shows a method in which these disadvantages do not occur. The code words I, II, III,. , , , trained as virtual code words. These are also transmitted at a predetermined frequency. Each parallel code element 1p to 12p is assigned a channel, ie channels 1 to 12 for the 12 code elements 1p to 12p. In other words, code words are formed in series, e.g. B. I1p, II1p, III1p, IV1p, I1P,. , , For speech, 8 code elements would be required serially. These code words can have any size. It only depends on the type of information to be transmitted. With the help of parallel / serial converter you get the serially arranged code words. With memories and multiplexers you can then e.g. B. occupy all 12 channels, each channel can transmit code words of different sizes. Of course, when changing the type of information and the channel assignment, this must be communicated to the next evaluation point, e.g. B. similar to ATM cell header. A block but not a cell transmission is expedient. The transfer of information e.g. B. the 12 channels can be done with any code, with 4PSK, QAM. Most convenient is the code of the present invention. With memory and the transfer speed, you always have options for adaptation.

This method achieves bandwidth flexibility and bit rate flexibility without hardware intervention. The transmission routes are optimally used. Together with the wavelength division multiplexer driving is likely to remedy the lack of bandwidth for the foreseeable future his.

The coding of the information of the respective channel can be done with a Co alternating current. Two alternating currents can also be used for this provide frequency that are 90 ° out of phase with each other and be added for transmission. You can of course make 2 changes Provide currents in phase if they are 90 ° pha for transmission 2 shifted beams are modulated. Then these will also be added.

Real-time requirements are not met at ATM. With various services, e.g. B. when watching TV, the signal value should be transmitted simultaneously with the tap. According to the invention, this is achieved by providing virtual code words as real code words in a predetermined time sequence. In Fig. 13a, f is a real code word. If real-time transmission is necessary, this code word is inserted at the tap frequency of the television picture. This must be taken into account when tapping channels 1-12 for the virtual code words. The destination of these television signals can be coded in the header. As in ATM technology, you can of course also provide empty code elements or empty code words.

If it is determined that a switching node can be bypassed because there is so much information about the next but one node, a separate virtual code word channel can be switched to the next but one node. Such a channel V2 is provided in FIG . With egg ner coding with an alternating current of a frequency and phase position according to FIGS . 1, 2 and 3, z. B. change the number of bits and the bandwidth by the coding frequency or by the code itself by reducing or enlarging the envelope, as shown in FIGS. 4 and 5.

The principle of ATM technology is shown in FIG . In this data of different transmission rates, such as high speed, data, speech, are packed in cells of the same length, each with a cell head and ver arranged in series and asynchronously via a multiplex device. The address information required for the respective cell is encoded in the cell header.

Claims (3)

1. Digital transmission method for bandwidth and / or bit rate and / or channel orientation flexibility, characterized in that virtual and real code words are provided for the transmission ( FIGS. 14, I, 1p-12p-f) which are transmitted with any code (e.g. 4 PSK, QAM or with an alternating current of a frequency and phase position), one or more parallel code elements of the virtual code words serially form a channel (FIGS . 14, 1-12) whose code elements are combined to form a code word is assigned to each type of information to be transmitted (e.g. language 8bit, 1p I + II + III + IV + I + II + III + IV), whereby the code words of the channels can have a different number of bits, whereby between the virtual code words ( I, II,...) Real code words are provided (FIGS . 14, f) for a channel-oriented transmission, if necessary real-time transmission (for example television). 2. The method according to claim 1, characterized in that for the coding of the virtual code word an alternating current of a frequency and phase position, sent in an uninterrupted sequence, is provided, in which the stages by a different number or different size duration and / or by different Phase positions of pulses through the half-periods or periods of a periodic sequence, e.g. B. an alternating current, are also shown, with a bandwidth change in the manner by the number of active destination code elements ( Fig. 5 - 1.2 (11, 12 - 1, 2, 3 (11, 12, 13)) predetermined number of filling elements are assigned ( Fig. 5 - 1 to 10 filling elements). 3. The method according to claim 1, characterized in that switching the virtual code word to a different number of bits when encoding with an alternating current of a frequency and phase ge, sent in uninterrupted succession and the stages by a different sizes of half periods or periods or by ver differed long durations and / or different phase positions of impulses Darge by the half periods or periods of a periodic sequence provides, e.g. B. an alternating current, in the manner by a Stel Len or step reduction or digit and / or step enlargement by the half periods or periods of the periodic sequence follows with one or more coding alternating currents or different frequencies, the location of the code elements except a parallel arrangement is also serial or / parallel / serial can be arranged.