FR2801465A1 - Dual GSM/enhanced GSM mode radio telephone station having selection mechanism recognizing received signal radio type and selecting mode. - Google Patents

Abstract

The radio telephone station communicates with two mobile radio modes. There is a mode selection mechanism (6) which recognizes the type of radio signal received and selects that mode (66).

Description

With the current development of mobile telephony, the GSM standard is evolving towards derived standards, especially EDGE, on enhanced data rate for Enhanced Data Rate for GSM Evolution, GSM and EDGE standards being distinguished from each other by their respective modulations GMSK and 8PSK.

It is envisaged to manufacture cellular telephones and cell phone network base stations capable of operating in both GSM and EDGE radio transmission modes. In this case, to allow a cellular phone to communicate through a cellular network, the telephone and the base station to which it is connected will have to agree on the mode of radio transmission, GSM or EDGE. If the phone does not know in what mode the base station wishes to establish communication, it will be unable to decode the radio signals that the station transmits to it. Or conversely, if the base station does not know in what mode the phone wants to establish communication, it will be unable to decode the radio signals that the phone sends him. The present invention proposes to solve this difficulty.

The invention thus originates from a problem related to the use of both GSM and EDGE modes. However, the applicant intends not to limit the scope of its application to this particular case, but to extend it to the use of at least two radio transmission modes of any kind.

For this purpose, the invention relates to a radio telephony station, with transmission-reception means, arranged to communicate according to at least two radio transmission modes, characterized in that it comprises mode selection means, arranged to recognize, automatically, the mode of transmission of a radio signal received by the station, and to select said mode.

From the outset, it should be noted that the term "station" refers to any radio telephone station. It can be not only a "base station" of a cellular network, but also a "mobile station" of a cellular network, that is to say a cell phone.

When the station receives a radio signal transmitted in one of the two transmission modes, it recognizes and selects the transmission mode used, automatically, that is to say without the intervention of an operator. Advantageously, the mode selection means comprise means for determining a frequency spectrum, relative to the received radio signal, and means for discriminating the spectra respectively corresponding to the two modes of transmission.

Thus, the station discriminates the radio signals transmitted in one of the two modes and those transmitted in the other mode, by passage in the frequency domain.

In a particular embodiment, the means for determining a frequency spectrum comprise means for estimating the Fourier transform of a function of the signal.

Advantageously, means for sampling the received radio signal are provided, the frequency spectrum being determined from the samples. In a particular embodiment, there are provided means for raising the samples to a power of discriminatory order, preferably at power four.

More preferably, there are provided means for calculating the modulus of the estimate of the Fourier transform.

Advantageously, the discrimination means are arranged to detect at least one spectral line projecting out of the spectrum and to discriminate the spectra, depending on the existence or absence of at least one protruding line.

The station searches for predominant spectral lines, that is, projects out of the spectrum, and selects one or the other of the two modes, depending on whether or not the spectrum contains protruding lines.

The invention will be better understood with the aid of the following description of a particular embodiment of the radio telephony station of the invention, with reference to the appended drawing in which: FIG. 1 represents a functional block diagram of FIG. the telephony station of the invention, according to the particular embodiment; FIG. 2 represents a frequency spectrum S, and FIG. 3 represents a frequency spectrum S2. In the particular example of the description, the radio telephony station is a mobile station, in other words a mobile telephone, or cell phone, of a cellular telephone network 100.

The cellular telephone 10 is "dual mode", which means that it can use two modes of radio transmission, in this case the respective modes of GSM and EDGE standards. These two modes are distinguished from each other by their respective modulations: GSM mode uses GMSK modulation and EDGE mode uses 8PSK modulation.

The mobile network <B> 100 </ B> comprises a plurality of cellular base stations 101, which can use both GSM and EDGE radio transmission modes. Only one of the base stations 101 is shown in FIG.

In operation, the cellular telephone 10 communicates, by radio, with a base station 101, covering the topographic cell in which it is located, using one of the two GSM and EDGE radio transmission modes. The radio transmission mode is here chosen automatically by the base station <B> 101, </ B> according to pre-established criteria, and the cellular telephone 10 automatically selects this mode, using the received radio signal, transmitted by the base station, as will be explained later. For example, it may be envisaged that some of the base stations 101 use the GSM mode and another part of the base stations 101 use the EDGE mode.

Since the cellular telephone 10 comprises the conventional elements of a cellular telephone, only the elements of the cellular telephone necessary for understanding the invention will now be explained.

The telephone comprises a radio antenna 1, a radio transmission block 2, a radio reception block 3, a communication module in GSM mode 4, an EDGE mode communication module 5, a mode selection automaton 6 human-machine interface 7 and a central control unit 8, in this case a microprocessor.

The radio transmission block 2 and the radio reception block 3, connected to the radio antenna 1, are respectively intended to transmit and receive radio signals at high frequencies. It is recalled here that the radio signals, received and transmitted by the telephone 10, are analog signals x (t), which are a function of time t. The human-machine interface 7 comprises a keyboard, a display, a microphone and an earphone.

The communication module 4 allows the telephone 10 to communicate using the communication protocol of the GSM standard. It comprises in particular a modulation / demodulation block intended to modulate the data to be transmitted and to demodulate the radio signals received according to the GMSK modulation.

The communication module 5 allows the telephone 10 to communicate using the communication protocol of the EDGE standard. It comprises in particular a modulation / demodulation block for modulating the data to be transmitted and demodulating the received radio signals according to the 8PSK modulation.

The selection automaton 6 is designed to recognize, automatically, the transmission mode of a radio signal received by the telephone 10 and to select this mode. It comprises a baseband converter 61, a sampler 62, a memory 63 for storing samples, a block 64 for determining a frequency spectrum, a spectrum discrimination block 65 corresponding respectively to the two GSM and EDGE modes and a switching block 66, for activating one of the two modes GSM and EDGE.

The baseband converter 61 is connected, at the input, to the radio reception block 3 and, at the output, to the sampler 62. The converter 61 is intended to lower the frequency of the received radio signal, supplied by the reception block 3, to bring the signal back to low frequencies, almost zero. In other words, the converter 61 is intended to transform the received high frequency radio signal into a low frequency signal.

The sampler 62 is intended to sample the radio signal, supplied by the converter 61. A sampling operation consists in taking a determined number N of samples of the analog signal, at a succession of times t ,, ..., tp, ..., tN, with the sampling frequency Fe, and to assign to each of these samples a discrete, numerical value. Then called "xp", the sample of numerical value, index p (with p between 1 and N), taken at time tp. In the particular example of the description, the number N of samples, taken during each sampling operation, is equal to 512. The memory 63, connected to the sampler 62, is intended to store the number N of digital samples {x ,, x2, ..., xP, ..., xN}, obtained during a sampling operation.

The block 64 is intended to determine a frequency spectrum S relative to the received radio signal, containing useful information on the frequency content of the signal. This spectrum S is determined from the N samples x P, using a calculation algorithm. In this case, the calculation algorithm makes it possible to estimate TF [x (t)] 4, that is to say the Fourier transform of the high radio signal at the power of four. The module 64 comprises three computing operators, or digital processing operators, 641, 642, 643, intended to execute a digital signal processing process, implementing the algorithm for calculating an estimate of TF [x (t) ] 4. For further information on the Fourier transformation, the reader may refer in particular to the works "Techniques de l'ingénieur", volume E3 I f E <B> 160 </ b> ≈1,5 1, and "Fourier analysis and applications ", edition MASSON 1990.

The first operator 641 is intended to raise each of the N samples xp to the power four.

D'emblée, on rappelle que "i" est un nombre complexe, tel que 1z (c'est-à-dire i élevé à la puissance deux) est égal à la valeur négative "-1 ". The second operator 642 is intended to calculate, for each frequency of index k, the magnitude X, using the following formula:

From the outset, it is recalled that "i" is a complex number, such that 1z (i.e., raised to the power of two) is equal to the negative value "-1".

The frequency index k is a natural integer varying from 1 to N. At each frequency index k corresponds to a frequency fk. The relationship between frequency index and frequency is as follows:

<I> Index <SEP> frequency </ I>
<tb> 1 <SEP>-><SEP> 0
<tb> 2 <SEP> Fe / N
<tb> 3 <SEP> 2Fe / N
<tb> k <SEP> (k-1) Fe / N
<tb> N / 2 <SEP> + <SEP> 1 <SEP> Fe / 2
<tb> N / 2 <SEP> + <SEP> 2 <SEP> - <SEP> Fe / 2 <SEP> + <SEP> Fe / N

N / 2 <SEP> + <SEP> k '<SEP> - @ <SEP> - <SEP> Fe / 2 <SEP> + <SEP>(k'-1) Fe / N
<tb> N <SEP> - @ <SEP> - <SEP> Fe / N Thus, for frequency indices k between 1 and (N / 2 + 1), the corresponding frequency fk is equal to (k-1 ) Fe / N, and for frequency indices k between (N / 2 + 2) and N, the corresponding frequency fk is equal to (-Fe / 2 + (k-1) Fe / N).

The magnitude X (k), which is a complex value, represents an estimate of the Fourier transform, for the frequency index k, of the signal x (t) raised to the power four.

The third operator 643 is intended to calculate the module Y (k) of each of the variables X (k). We thus have the following relation between X (k) and Y (k): Y (k) = IIX (k) II <I> (II) </ I> The frequency spectrum S can be represented in a two-dimensional reference , comprising, on the abscissa, the indices of frequency k and, on the ordinate, the values Y (k). A spectrum of lines is thus obtained.

The discrimination block 65 is intended to detect at least one spectral line projecting out of the spectrum S, by a local maximum detection algorithm, and to discriminate the spectra respectively corresponding to GSM and EDGE modes, depending on the existence or the absence of at least one protruding line, as will be explained later.

Finally, the central control unit 8, connected to all the elements of the telephone 10, is intended to control the operation of the telephone 10. After the functional and structural description of the cellular telephone 10, its operation will now be described.

When the telephone 10 is turned on and connects to a base station 101 of the cellular network 100, it automatically triggers an automatic selection operation of a radio transmission mode. The telephone 10 receives a radio signal x (t), at high frequencies, transmitted by the base station 101, without knowing a priori the radio transmission mode used by the base station <B> 101. </ B>

The received radio signal is converted into low frequencies by the converter 61 before being supplied to the sampler 62.

The sampler 62 takes a number N samples of the analog signal, N being here equal to 512, with a sampling frequency Fe, and digitizes these samples, by assigning them numerical values. N samples of numerical value xp are thus obtained, with p being between 1 and N.

The N samples xp are then temporarily stored in the memory 63, for digital processing by the module 64.

To determine the frequency spectrum S, relative to the received radio signal x (t), the module 64 executes the digital signal processing process comprising the three steps, explained below, performed successively by the three operators 641, 642, 643.

 STEP <U> 1 </ U> Operator 641 raises each of the samples xp to the fourth power. Step <U> 2 </ U> The operator 642 calculates, for each frequency index k, with k varying from 1 to N, the magnitude X (k), using the formula 1.

 Step <U> 3 </ U> The operator 643 calculates the module Y (k) of X (k), for each frequency index k.

The N values {Y (1), ..., Y (k), ..., Y (N)} represent the amplitudes of the N lines of the spectrum S. This spectrum S contains useful information relating to the frequency content of the received radio signal, for determining the type of modulation, GMSK or 8PSK, used by the transmitter (i.e., the base station 101) to modulate this signal.

The detection block 65 searches for the presence of spectral lines projecting out of the spectrum S. In the case where the spectrum S contains at least one protruding line, the modulation of the radio signal x (t) received is a GMSK modulation. In the opposite case, the modulation of the received radio signal x (t) is an 8PSK modulation.

FIG. 2 shows graphically a spectrum S relative to a radio signal x, (t) and, in FIG. 3, a spectrum S2 relating to a radio signal x2 (t). In the graphs of FIGS. 2 and 3, the frequency indices k and the values Y (k), which represent the amplitude of the spectral lines, are respectively represented on the abscissa and on the ordinate, with k varying from 1 to N (N being equal to 512).

As can be seen in FIG. 2, the spectrum S has three predominant lines 20-22 protruding out of the spectrum S 1, forming peaks in the Si spectrum. The presence of these protruding lines 20-22 indicates that the radio signal xi (t) has been modulated with a GMSK modulation. In contrast, the spectrum S2, shown in Figure 3, has no protruding line. The absence of protruding lines indicates that the signal x2 (t) has been modulated with 8PSK modulation.

If the spectrum contains one or more protruding lines, the discrimination block 65 detects them and provides the switch block 66 with a GSM mode enable control signal. After activation of the GSM mode, the telephone 10 and the base station 101 communicate using the GSM radio transmission mode, and therefore the GMSK modulation.

If the spectrum does not contain any protruding line, discrimination block 65 provides switch block 66 with an EDGE mode enable control signal. After activation of the EDGE mode, the telephone 10 and the base station 101 communicate using the radio transmission EDGE mode, and hence the 8PSK modulation.

The automatic radio transmission mode selection operation, described above, is performed by the telephone 10 when it is turned on. This automatic mode selection operation is also performed when the phone changes cell and therefore connects to a new base station and when it reconnects itself to a base station.

One could also consider performing the automatic mode selection operation, at regular time intervals, the base station can change the radio transmission mode during the same connection of the phone. In the above description, the samples xp of the radio signal are raised to the power of four. They could be raised to a power of another discriminatory order, that is to say to discriminate the frequency spectra respectively corresponding to the two modes of GSM and EDGE transmission. To perform this discrimination, it is preferable that the power be of even order and strictly greater than two.

dans laquelle xp" est la grandeur conjuguée de xp et q est l'ordre de puissance d'élévation des échantillons, par exemple égal à 4. Samples of complex value could be taken and Fourier transform of the signal x (t) could be estimated using the following formula:

where xp "is the conjugate magnitude of xp and q is the elevation power order of the samples, for example equal to 4.

Of course, we could take a number of samples different from 512, this number must however be large enough to obtain reliable results.

Furthermore, in the above description, the base station automatically chooses the radio transmission mode and the cellular phone automatically selects this mode. In other words, the base station and the telephone respectively play the role of master and the role of slave, for the determination of the radio transmission mode used. In a variant, the base station and the telephone are, respectively, respectively slave and master. In this case, the mode selection module is implemented not in the cellular phone but in the base station. The telephone automatically chooses one of two radio transmission modes, for example under the control of a user, and the base station automatically selects the transmission mode chosen by the telephone, by executing the automatic selection process of the telephone. mode that has just been described.

The invention could also apply to the selection of modes other than the GSM and EDGE modes.

Claims (12)

 CLAIMS 1- A radio telephone station, with transmission-reception means, arranged to communicate according to at least two radio transmission modes, characterized in that it comprises mode selection means (6), arranged to recognize , automatically, the transmission mode of a radio signal, received by the station, and to select said mode. 2- station according to claim 1, wherein the means (6) of mode selection comprises means (64) for determining a frequency spectrum, relative to the received radio signal, and means (66) for discriminating corresponding spectra respectively to both modes of transmission. The station of claim 2, wherein the frequency spectrum determining means (64) comprises means (642) for estimating the Fourier transform of a signal function. 4- station according to one of claims 1 to 3, wherein there is provided means for sampling the received radio signal, the frequency spectrum being determined from the samples. The station of claim 4, wherein means (641) are provided for raising the samples to a power of discriminatory order. Station according to Claim 5, in which means (641) are provided for raising the samples to a power of even order and strictly greater than two. 7- Station according to one of claims 5 and 6, wherein there is provided means (641) for raising the samples to the power four. 8- Station according to one of claims 3 to 6, wherein there is provided means for calculating the module of the estimate of the Fourier transform. 9- Station according to one of claims 2 to 7, wherein the discrimination means are arranged to detect at least one spectral line projecting out of the spectrum and to discriminate the spectra, depending on the existence or absence at least one protruding line.       10- Station according to claim 9, wherein the means for determining the frequency spectrum are intended to calculate, for the index frequency k, a magnitude X (k) representing an estimate of the Fourier transform of the signal raised to the power. four, using the following formula:

 xp representing a sample of index p of the signal and N representing the total number of samples. 11- Station according to one of claims 1 to 10, wherein there is provided baseband conversion means for lowering the frequency of the received radio signal. 12- Station according to one of claims 1 to 11, wherein the two modes of radio transmission are respectively the GSM mode and the EDGE mode.