FR2671248A1 - METHOD FOR SYNCHRONIZING FREQUENCY AND TIME SLOTS USING ADAPTIVE FILTERING, AND RADIOTELEPHONE USING THE SAME. - Google Patents

Abstract

The synchronization method according to the invention filters the received signal using an adaptive bandpass filter (101) and buffers the received signal (108). Estimates are made for the energies of the input signal and the filtered signal (103 and 104), and an adaptation of the gain of the filter is made (105) based on the difference between these energies. The pole of the filter is matched (102) such that the frequency of the input signal is centered within the passband of the filter. If a sound (106) is detected, its duration (107) is determined to verify that it is a frequency correction burst (FCB). In this case, the buffered signal is then filtered in the bandpass filter (101) and the difference between its frequency and 67.5 kHz is calculated (109). This difference represents the frequency offset between the base station and the mobile radiotelephone and enables the necessary compensations to be made.

Description

 The present invention relates generally to the field of telecommunications and, more particularly, the synchronization of frequencies and time slots in a mobile telecommunications environment.

 Since a mobile radio does not have an internal frequency reference that is sufficiently precise, it must make fine frequency adjustments to achieve the desired frequency synchronization with the frequency of a base station. In a time multiple access system (TDMA), multiple logical channels are transmitted on the same frequency, but with time separation, as shown in Figure 2.

 To communicate with a base station, the mobile radio must also find the boundaries of these time slots, which is called synchronization of the time slots.

 The different base stations of a cellular radiotelephone system maintain very precise frequency references, but use different transmission frequencies and, possibly, different time slot alignments. When a mobile radiotelephone passes from one cell to another in a cellular radiotelephone system, the mobile radiotelephone may request some minor frequency adjustment, as well as complete synchronization of the time slots, in order to be able to communicate with the new radio station. based.

To achieve this in a digital cellular radiotelephone system, the radiotelephone first finds a frequency correction channel (FCCH), which is part of the broadcast control channel (BCCH). Figure 2 illustrates the slices of the
FCCH and other data control channels which realize the BCMA multi-frame TDMA structure. This presentation format is described in more detail in the GSM of standard specifications.
Bands for digital cellular systems, Recommendation 5.02,
Version 3.3.1, October 13, 1989.

 The FCCH baseband signal is a frequency correction burst (FCB), i.e. a pure sound (sine wave) at 67.5 kHz, comprising 148 samples, which is sent periodically and always occupies the time slot zero of the data train The offset between the carrier frequency of the base station and that of the mobile radiotelephone is reflected, for the baseband, in the form of a deviation from 67.5 kHz. The boundaries of the FCB delimit the time slices of the TDMA structure. From the detection of the FCCH, the mobile radio synchronizes the limits of the time slots and its local oscillator frequency with those of the base station by using the burst of frequency correction in the time slot of the FCCH.

 Since the burst is relatively short, the mobile radio must find it in the data train and synchronize with it in this very short time. There is therefore a need for a method making it possible to very quickly detect the presence and the boundaries of the FCB, as well as to estimate very precisely the frequency offset, even when the signals are received in the presence of noise.

 The synchronization method according to the invention comprises the operations consisting in filtering a received signal using an adaptive filtering means, in buffering this signal in a storage means, and in determining whether the correction sound of frequency is present (the detection process). This also establishes the boundaries of TDMA time slots. When this frequency correction sound is present, operations are carried out consisting of filtering the buffered signal and determining the difference between the frequency of this filtered signal and 67.5 kHz (The method for estimating the frequency offset carrier).

The following description, intended as an illustration of
The invention aims to give a better understanding of its characteristics and advantages; it is based on the appended drawings, among which
Figure 1 is a block diagram of the method according to the invention;
Figure 2 shows the format of the multiframe broadcast control channel (TDMA); and
FIG. 3 represents a typical radiotelephone, which uses the method according to the invention, in a system of the TDMA type.

 The method according to the invention realizes the rapid synchronization of frequencies and time slots between a mobile radiotelephone and the base station with which it communicates.

This is accomplished by detecting the presence and boundaries of the frequency correction burst and by determining the frequency of this baseband sound.

The preferred embodiment of the method according to the invention is illustrated in FIG. 1. The input signal applied to the method is one of the two baseband quadrature signals, the data current I or Q, sampled at due to one sample per binary time unit, coming from the radiotelephone receiver. This signal, called xn in FIG. 1, is initially filtered in a second order infinite impulse response (IIR) bandpass filter (101). The gain and the pole of this filter are both adaptive. We adjust the gain in order to substantially maintain a unity gain in the filter, i.e. the energy present at the output is equal to the energy present at l 'Entrance. The pole of the filter is moved so that the bandwidth of the filter contains the received signal. The filter output signal is called yn. Filtering is carried out as follows

The energy of the input signal and the energy of the filtered signal are then estimated in the energy estimation blocks (103 and 104). The estimation of the input energy is carried out as follows

0ce est le coefficient d'adaptation d'énergie et est fixé à une valeur égale à 0,091 pour les opérations d'estimation.The estimated filtered energy is as follows:

0ce is the energy adaptation coefficient and is fixed at a value equal to 0.091 for the estimation operations.

ou bn+1 est le gain du filtre adaptatif et ab est le coefficient d'adaptation du gain, qui est fixé à 0,077 pour l'opération d'adaptation de gain.The input and output energies, E (x) n + 1 and E (y) n + 1, are compared in the gain adaptation block (105), the gain of the filter being adapted so as to match the energies of the input signal and the filtered signal. This adapted gain is then returned to the filter. Comparison and Adaptation are carried out as follows

where bn + 1 is the gain of the adaptive filter and ab is the gain adaptation coefficient, which is fixed at 0.077 for the gain adaptation operation.

The pole matching block (102) is used to estimate the instantaneous frequency of the filtered signal. The blade of the adaptive filter is adapted in the direction of this frequency and the new position of the pole is returned to the filter (101). This operation is as defined below

End If
End If where e is an instantaneous estimate of the pole and Oc is the
np pole adaptation coefficient, which is set at 0.083 for the pole adaptation operation. When the adaptive filter follows a pure sound, for example the frequency correction burst, any
The energy in the input signal is contained in the band of the bandpass filter. We can therefore obtain a unity gain in the filter (101) with the lowest value of the gain of the filter. We check this condition to determine the instantaneous presence of a sound in the sound detection block (106). If gn + 1 is less than a threshold value of 1.2 and if good + 1 is less than a threshold value of f (an), then Sound is present.

 The timer block (107) measures the duration during which the state of presence of the sound persists. If this sound is present for at least 100 samples in the preferred embodiment, it is considered that the presence of the frequency correction burst has been checked. This integration prevents the algorithm from erroneously detecting a signal which, for short periods, may appear as a narrowband signal.

The signal xn, which is applied as an input to the filter (101), is also stored in a buffer of the shift register type (108). As soon as it has been determined that this stored signal is the frequency correction burst, the signal from the buffer (108) is applied to the input of the bandpass filter (101), again using the coefficients optimal values, a and b, which were determined during the detection process. Since the bandwidth of the filter (101) is now tuned to the frequency of the frequency correction burst, then, after the above-mentioned adaptation process, it transmits this signal without attenuation and filters out the background noise , which improves the effective signal-to-noise ratio.

 The filtered signal, ie yn, is then processed according to a method of estimating the least squares error, so that an estimate of the frequency, ie q, of the sound of the baseband is produced.

*
The difference between q and p / 2 (67.5 kHz) constitutes the frequency offset between the carrier frequency of the base station and that of the mobile radiotelephone. This data is applied to the local oscillator circuit of the radiotelephone to compensate for the offset of the carrier frequency. The process described above is carried out periodically to keep the mobile radio locked on the carrier frequency of the base station.

An example of the receiving part of a typical mobile radiotelephone to be used in a TDMA system is illustrated in FIG. 3. The block of the decoder of I and Q contains the synchronization method according to the invention. This type of radiotelephone is discussed in more detail in the United States patent application filed under number 590 415, "Interference Reduction Using an Adaptive Receiver Filter Signal
Strength, and Ber Sensing "September 28, 1990 in the name of Cahill and ceded to the plaintiff.

 In summary, a new method has been presented which makes it possible to synchronize the frequency of local oscillator and the positions of the time slots of a mobile radiotelephone with those of the signal received from a base station. This synchronization takes place in real time and with significantly improved precision.

 Of course, those skilled in the art will be able to imagine, from the method and the device, the description of which has just been given by way of illustration only and in no way limitative, various variants and modifications which do not depart from the scope of the invention.

Claims (6)

 1. Frequency synchronization method between a cellular telecommunication base station which transmits a plurality of signals, at least one of these signals having a frequency correction sound, and a mobile telecommunication device which receives the different signals, the mobile telecommunication device having a local variable frequency oscillator means, the method being characterized by the following operations  a) filtering a first signal from the plurality of signals to produce a first filtered signal (101);  b) buffering the first signal to produce a buffered signal (108) ;;  c) determining whether the frequency correction sound is present in the first signal by determining the energy of the first signal and the energy of the filtered signal as well as the duration for which a relationship exists between these energies (102-107);  d) when the frequency correction sound is present, filtering the buffered signal to produce a second filtered signal which contains carrier frequency offset information (110); the method being further characterized by the following operation  e) when the frequency correction sound is present, determine, from the second filtered signal, the frequency difference between the carrier frequency of the signal coming from the base station and the frequency of the local oscillator means of the mobile telecommunication device (109).  2. Method according to claim 1, characterized by the operation which consists in adjusting the local oscillator means of the mobile telecommunication device as a function of the frequency difference.  3. Method according to claim 1, characterized in that the relation between the input and output energies is a relation of equality.  4. Frequency synchronization method, in a time-division multiple access cellular telecommunications system (TDMA), between a telecommunications base station, which transmits several TDMA signals at several frequencies, and a mobile telecommunications device which receives the various signals , each signal consisting of a plurality of samples and at least one of the signals having a frequency correction sound, the mobile telecommunication device having a variable frequency local oscillator means which varies as a function of the frequency correction sound, the process being characterized by the following operations:  a) filtering a first signal among the different signals using an adaptive filter in order to produce a filtered signal, the adaptive filter having a variable gain and a variable pale (101);  b) buffering the first signal to produce a buffered signal (108);  c) determining a first energy level for the first signal (103);  d) determining a second energy level for the filtered signal (104);  e) varying the gain of the adaptive filter as a function of the difference between the first and second energy levels (105);  f) varying the pole of the adaptive filter as a function of the frequency of the second signal (102) ;;  g) when the first energy level is equal to the second energy level, determining the quantity of samples of the first signal for which the relationship between the first and second energies exists (106-107);  h) when the amount of samples is substantially equal to the predetermined number, filtering the buffered signal to produce a second filtered signal having carrier frequency offset information (110); the method being further characterized by the following operation  i) if the quantity of samples is substantially equal to a predetermined number, determine from the second filtered signal, the frequency difference between the carrier frequency of the signal coming from the base station and the frequency of the local oscillator means of the device mobile telecommunications (109).  5. The method of claim 4, further characterized by the operation of adjusting the local oscillator means of the mobile telecommunication device as a function of the frequency difference.  6. Radiotelephone intended for use in a cellular telecommunications system of the TDMA type, the radiotelephone having a demodulation means serving to produce the signals I and Q, the radiotelephone being characterized by  a) means for transmitting a first signal;  b) means for receiving a second signal, coupled to the TDMA demodulation means, the TDMA demodulation means processing the second signal to produce the I and Q signals; the radiotelephone being further characterized by  c) a processing means for processing the I or Q signals, the processing means performing the following operations:  filtering a first signal from among the different signals using an adaptive filter to produce a first filtered signal (101);  buffering the first signal to produce a buffered signal (108);  determining whether the frequency correction sound is present in the first signal by determining the energy of the first signal and the energy of the filtered signal as well as the length of time a relationship exists between these energies (102-107);  when the frequency correction sound is present, filtering the buffered signal to produce a second filtered signal containing carrier frequency offset information (110); the processing means further performing the following operation  when the frequency correction sound is present, determine, from the second filtered signal, the frequency difference between the carrier frequency of the signal coming from the base station and the frequency of the local oscillator means of the mobile telecommunication device (109 ).