FR2601210A1 - Method and installation for digital communications for mobiles - Google Patents

Abstract

The method, intended essentially for the link between mobiles in a disturbed medium, comprises: the coding 10 of the bits with the aid of a redundant code leading to parallel modulation symbols Afn tj; the transmission of the said symbols by distributing them within the frequency spread f through distribution between n frequencies or broadcasting channels 12 (n being an integer greater than 1), two successive elements A never being transmitted at successive instants and at the same frequency, and possibly the association of this distribution in frequency with an interlacing in time.

Description

Method and installation of digital communications
For mobiles
The invention relates to the dissemination of data in digital form in an environment disturbed by parasites and / or by the existence of multiple paths.

It finds a particularly important, although not exclusive, application in digital sound broadcasting to mobiles.

 The main difficulties encountered in broadcasting to mobiles - or the communication of mobiles between them - come from disturbing phenomena, the characteristics of which (frequency, amplitude, duration, etc.) vary greatly depending on their origin, the frequency band used and the location of the receiving mobile in the reception area.

We already know many processes intended to limit the disturbances brought to the reception
- Repetition of broadcast information, with detection and possible correction of errors on arrival, which limits the effect of impulsive noise, even at broadband
- Data coding using a convolutional code, ensuring redundancy which allows an increase in the distance between transmitted signals, therefore a reduction in the number of errors at reception
- Increase in the duration of each of the symbols transmitted, which has a favorable effect vis-à-vis all disturbances but which limits the maximum bit rate.

- Broadcast called hopping frequency hopping ", consisting of transmitting successive symbols alternately on several frequencies, only one of which is used at the same time, which reduces the incidence of echoes and recurring jammers, because they do not play only on a limited frequency domain, if they can be permanent
- Interleaving of information, which reduces the incidence of disturbances of limited duration.

 None of these solutions gives a fully satisfactory result in a reception site affected by disturbances of various natures, corresponding to different portions of the time-frequency space.

This is particularly the case for broadcasting in urban areas, where there are many echoes and radioelectric disturbances of domestic or industrial origin.

 The invention aims to provide a method and a device for broadcasting data to mobiles which meet the requirements of the practice better than those known in the past, in particular in that they considerably improve the reliability of reception in the presence of multiple paths and reduce the incidence of parasites.

 To do this, the invention uses the general knowledge set out above, but, on the one hand, it combines them in a new way and, on the other hand, it supplements them in order to arrive at a reliability which has been shown to be common. measure with those obtained if we omit an element from the combination.

 A method according to the invention of broadcasting data from a source comprises putting the data in the form of digital samples, coding the bits using a redundant code leading to modulation symbols A (fi, tj), the transmission of said symbols by distributing them in parallel in the time frequency space t with temporal interleaving and simultaneous transmission on n frequencies or broadcasting channels (n being greater than 1). By implementing this method, two successive elements A are never transmitted at successive instants at the same frequency.

 The distribution according to the invention is completely different from a diversity or frequency hopping type diffusion because at a given instant there is diffusion of n elements and not of a single one. Thanks to this distribution method, the duration of each element transmitted can be multiplied by n for a given bit rate, which improves the reliability of reception by reducing selective phenomena.

 The independence from the channel between successive symbols presented to the decoder which makes a decision according to the maximum likelihood a posteriori is an essential aspect of the good performance of the system. This independence is obtained thanks to the double interleaving (in frequency and in time) associated with this coding.

 The reconstitution of the message on arrival is done by memorizing the elements for a duration t = Ts x, Ts being the duration assigned to an element A and ffi being an integer corresponding to the total duration concerned by the interleaving algorithm .

 Frequency interleaving provides an additional degree of freedom (reduction of intersymbol interference) and does not require any particular synchronization device, which is an element of simplicity. Deinterlacing consists in returning the symbols to their order of output from the encoder. The redundancy introduced is used in the receiver by implementing a decision algorithm which advantageously makes the choice by searching for the maximum likelihood a posteriori by determining which is, among all the possible mosaics (that is to say authorized by the coding), the one closest to the mosaic actually received.

The invention also proposes a diffusion installation making it possible to implement the above method. The installation includes
a transmitter having a convolutional encoder providing digital samples, means for interleaving the time-coded symbols by assigning to each a longer transmission time by using several channels of a transmission channel, generally at different frequencies, and
a receiver comprising deinterleaving means intended to restore the coded symbols and to store them over a period of time making it possible to evaluate the original binary sequence by determining the paths of maximum probability in the trellis produced by the convolution.

The invention will be better understood on reading the following description of a particular embodiment of the invention, given by way of non-limiting example. The description refers to the accompanying drawings in which
FIG. 1 is a block diagram showing the distribution of the successive coded symbols to be transmitted in time-frequency space,
FIG. 2 shows a possible mosaic of the symbols to be transmitted produced by time interleaving and frequency distribution,
FIG. 3 is a diagram of the emission principle in the implementation of the method according to the invention,
- Figure 4, similar to Figure 3, is a reception diagram,
- Figures 5 and 6 are diagrams corresponding to a particular case of Figures 3 and 4.

In principle, the method according to the invention successively implements, on transmission, coding and then a distribution of the information elements in frequency (frequency interleaving) and in time (time interleaving). This distribution can be of the kind shown in FIG. 1. The discrete elements (symbols) A obtained by digitization of successive samples of a signal, then coding, are memorized, then distributed in the space frequency time t. On the
Figure 1, n discrete elements A (fi, tj) are simultaneously transmitted at the same instant tj, each for a duration T51 at n different frequencies fol, ...

fi, .... fn.

 As shown in Figure 3, the binary elements (bits) ak to be transmitted are first subjected to convolutional coding intended to bring about redundancy. This coding implies that the yield (ratio between the number of useful bits p and the corresponding number q of bits at output) is less than 1. One can for example use a code having a yield R = p / q = 1/2 and it is this particular case which will be detailed later.

 The coder 10 provides, with a delay related to the coding algorithm, q bits on q different outputs for p input bits.

 The next step is to perform time and frequency interleaving. Provided that there are a sufficient number of channels, frequency interleaving makes it possible to assign to each bit S a duration T5 greater than that of an input bit ak, in spite of the efficiency lower than 1 of the encoder 10 FIG. 2 shows, by way of example, a possible time and frequency distribution of bits S1, S2,... Supplied in succession by the encoder 10, on four channels at different frequencies.

 To reduce the spectral congestion on transmission, the bits transmitted on each channel can be grouped into blocks of k bits by coders 14. In this case, the successive blocks are applied to modulators 16 to 2k states associated with oscillators with respective frequencies zut fn The modulator outputs drive a baseband multiplexer 18 whose output is connected to the transmitting antenna.

 The reception diagram (Figure 4) has n input channels each having a demodulator 22 provided with a filter of width Fs centered on one of the frequencies fl to fn and an analog / digital converter 24. The outputs of the converter are linked to a set performing the deinterlacing and supplying the estimated values âk of the bits k of the message applied to the transmitter, using the redundancy introduced by the convolutional code.

 In general, it is advantageous to use a receiver comprising, downstream of the A / D converters 24, a decision logic using not "hard" detection by comparison of the samples received at a predetermined threshold, but a search logic a posteriori of the mosaic of A (fi, tj) having the maximum likelihood. In practice, this amounts to choosing that of the diagrams in the mosal of A (fi, tj) which corresponds to the maximum value of the metric r, defined as the probability density of the sequence received conditionally upon the emission of a given sequence. For this, each decision is taken after observation of a number M of symbols A (fi, tj) received.

 This number depends on the code used; for convolutional coding, it depends on the constraint length of the code.

Several types of algorithms can be used at the reception, and in particular the algorithm of
Viterbi, described in * Convolutional Codes and Their
Performances in Communication Systems ", IEEE TRANS.,
Common. Technol. Flight. COM., October 19, 1971.

 The reception diagram is then of the kind shown in FIG. 4 which successively comprises the deinterlacing at 26 following an algorithm stored in the receiver, the calculation of the metrics at 28 and the search for the path corresponding to the maximum metric at 30.

As an example, we will now describe the basic principle of a transmitter (Figure 5) and a receiver (Figure 6) corresponding to a process where
- the convolutional code has a yield p / q = 1/2
- the lattice for determining the maximum metric path comprises four nodes and each branch of the lattice is coded on two bits
- the transmission channel has n = four channels which will be assumed to be frequencies f1, f2, f3 and f sufficiently separate to be independent from the disturbances which affect the transmission channel
- the modulation on each channel is binary (0 and 1).

 The transmitter (FIG. 5) comprises the convolutional coder 10 of the type supplying two bits online simultaneously, on the outputs 32 and 34, for each bit ak of information, by involving three successive bits in the coding algorithm.

 The convolutional code used, as well as the interleaving algorithm, can be chosen according to the type of disturbances to be feared: in fact, the disturbances have very different shapes in the time-frequency representation. For example, a Rayleigh loss is selective in frequency and in time; impulsive noise corresponds to a broad frequency spectrum, but is localized in time. Interleaving in time and frequency makes it possible to reduce the probability of false decisions by ensuring independence between successive samples with respect to channel disturbances.

The frequency interleaving of the online bits is carried out by a device 36 for distribution on four channels, represented schematically by the transformation 2 bits-4 bits parallel. Interleaving in time is obtained using shift registers 38 placed on the outputs of the device 36, delaying the online bits of respective durations T1, T2 and T3 multiple of Ts and which maintain the symbols in output for a double the duration of the input data period
The transmitter illustrated does not have block coding circuits and the modulation is binary. The outputs of the device 36 are applied, directly for one of the channels, via a register 38 for the other channels, to the modulators 16 which each receive a carrier of frequency f1, f2, f3 or f4.

The modulation mode adopted is advantageously such that the receiver demodulators can be simple, for example of the envelope detection or differential type. However, in general, any amplitude, phase or frequency modulation can be adopted.

 The receiver (Figure 6) comprises, downstream of conventional input, amplification and filtering stages, not shown, organs symmetrical to those of the transmitter.

Each channel includes a demodulator 22 providing a sample, at successive instants separated from
T 1 xn
D x P / q with
D useful linear flow
P / q code output n number of channels (or carriers).

 In general, the part of the receiver located downstream of the demodulator is digital and each channel then comprises an A / D converter 24, providing for example the sample coded on three bits to the time deinterlacing circuit. This circuit consists of three shift registers 42 providing delays complementary to those applied on the channels corresponding to the transmission. In this particular case of interleaving, the registers 42 operate automatically in synchronism due to the parallel transmission.

 The frequency deinterlacing circuit 40 is constituted by a wired matrix making it possible to have simultaneously, on four parallel outputs, samples representative of the message coded by the convolutional coder, but affected by noise.

 The samples, coded on three bits, are applied to the metric calculation unit 28, provided here for calculating twice four correlation metrics emitting the decision on two successive branches of the trellis.

 At all times kT, the Viterbi decoder retains only one path leading to a trellis node on the criterion of the largest metric (correlation).

 The decision circuit 30 applying the Viterbi algorithm provides the evaluated binary elements. For bit rates of the order of a few hundred k bits / s, it is possible to use, to implement functions 28 and 30, a microcomputer whose software applies in real-time Viterbi algorithm.

 The invention is susceptible of numerous modes of implementation. It will be noted that the decorrelation between carriers imposes a minimum distance between carriers.

This solution is particularly easy to implement when several separate transmission channels are provided: it is therefore natural to intercalate the frequencies corresponding to the different emissions.

It is also possible to carry out a multiplexing by the mode described in the article "Advanced Groupband
Data Modem Using Orthogonally Multiplexed QAM Technique "by Hirosaki et al. (IEEE Transactions on Communications, Vol. COM-34, No. 6, June 1986, pp. 557-592) to which reference may be made.

Claims (5)

 1. A method of digital broadcasting, characterized in that it comprises: the coding (10) of the bits using a redundant code leading to symbols for modulation in parallel A (fi, tj); the emission of said symbols by distributing them in the frequency space f by distribution between n frequencies or diffusion channels (12) (n being an integer greater than 1), two successive elements A never being emitted at successive instants and at the same frequency, and possibly the association of this frequency distribution with an interleaving in time.  2. Method according to claim 1, which ensures, by distributing the bit rate between several transmission channels and increasing the duration of the symbols transmitted in each of the channels, the independence of the attenuations and distortions which affect the successive symbols while reducing intersymbol interference.  3. Method according to claim 1 or 2, characterized in that the signal upon arrival is decoded by reconstructing the ordered sequence of the coded symbols and in that the sequence of information bits is estimated from received data by a posteriori maximum likelihood search algorithm.  4. Method according to claim 1, 2 or 3, characterized in that the coding is carried out by a convolutional code and the interleaving in frequency by modulation on n channels with two modulation levels.  5. Data dissemination installation, characterized in that it comprises:  - a transmitter having a convolutional encoder providing digital samples, time interleaving means and ensuring for each of the modulation symbols a longer duration associated with mutual independence from the channel thanks to the distribution between multiple transmission routes  a receiver comprising deinterleaving means intended to restore the ordered sequence of symbols and to decode them by determining the paths of maximum probability in the lattice produced by the convolution.