The object of the present invention is a parallel architecture digital filter and a signal receiver with spectrum spreading using such a filter.
The filter of the invention may be used in any technique with a high information rate, but it is particularly suitable for direct sequence spread spectrum digital transmissions where it may be used as an adapted filter. Therefore the invention finds a particular application in wireless local networks (WLAN), in local loops for wireless subscribers (WLL), in mobile telephony, in home automation and remote data collection, communications in transportation, in cable television and in multimedia services on cable networks, etc. . . .
The spectrum spreading technique consists in modulating a digital symbol to be transmitted by a pseudorandom sequence known to the user. Each sequence is composed of N elements called “chips”, the period of which is the Nth fraction of the period of a symbol. This results in a signal with a spectrum spreading over an N-fold larger range as that of the original signal. On reception, demodulation consists in correlating the received signal with the sequence used upon emission in order to rediscover the initial symbol.
This technique has many advantages:
discretion, as the emitted signal power is constant and spread over an N-fold larger band, its power spectral density is reduced by a factor N;
immunity with regards to intentional or parasitic narrow band emissions, the correlation operation carried out at the receiver's level leading to spectral spreading of these emissions;
interception difficulty (for the usual signal-to-noise ratios), as demodulation requires knowledge of the sequence used upon emission;
resistance to multiple paths which, under certain conditions, cause frequency selective fading and therefore only affect the emitted signal partly;
possibility of using code division multiple access (CDMA): several direct sequence spread spectrum links may share the same frequency band by using orthogonal spreading codes.
A description of this technique may be found in two general references:
Andrew J. VITERBI: “CDMA-Principles of Spread Spectrum Communication”, Addison-Wesley Wireless Communications Series, 1975,
John G. PROAKIS: “Digital Communications”, McGraw-Hill International Editions, 3.sup.rd edition, 1995.
Appended
Each adapted filter F(I), F(Q) performs a correlation operation between the received signal and a pseudorandom sequence used upon emission. This operation consists in storing a certain number of successive samples and in performing a weighted sum by means of weighting coefficients which are the coefficients of the digital filter. In the particular case of direct sequence spectrum spreading using binary sequences, these coefficients are equal to +1 and to −1, according to the sign of the chips forming the pseudorandom sequence.
Analog/digital converters CAN(I) and CAN(Q) operate at frequency Ft=neFc where Fc is the chip frequency (Fc=1/Tc), ne is the number of samples taken in a chip period (Tc) and N is the number of chips in each sequence. The number of stored samples is equal to neN. For simplifying the discussion, it will be assumed that only one sample is taken per chip. The number of samples taken into account and coefficients is therefore equal to N.
The correlation operation consists in multiplying the retained samples, noted as Ik−j, where k is a time index and j is a shift with respect to this index, with as many coefficients noted as CN−1−j, and in calculating the sum of these products i.e.:
CN−1Ik+CN−2Ik−1+ . . . +C.sub.0 Ik−(N−1)
which may be written:
This weighted sum is obtained at each sampling period and therefore depends on index k. Signal Sk represents the required correlation signal. Generally, it exhibits a very sharp peak when all the samples taken into account correspond to the chips of the pseudorandom sequence used upon emission.
If ne samples are taken instead of only one per chip period, previous considerations remain valid, except that the total number of samples to be taken into account becomes neN instead of N. The number of coefficients must also be equal to neN but with ne repetitions for samples located in a same chip period (Tc). For example, for a pseudorandom sequence of 31 chips, and for two samples per chip, 2×31=62 samples will have to be taken into account with 62 coefficients formed from 31 pairs of equal coefficients: C61=C60, C59=C58, . . . , C1=C0. However a weighted sum will always be formed, i.e.:
Sk=C61Ik+C60Ik−1+. . . +C1Ik−60+C0Ik−61
The diagram of
In such a technique, the processing rate is directly related to the product D×N×ne where D is the transmitted data rate. This quantity is a frequency, called the operating frequency (or working frequency). The longer the length N of the pseudorandom sequence, the better are the processing gain, resistance to disturbances, discretion of the link and robustness of the latter faced with possible interception. To benefit from these advantages, the direct sequence spread spectrum modulation technique should use length of sequences of at least a few tens of chips.
Furthermore, the performance of a direct sequence spread spectrum system in a multipath environment, depends on its time resolution, which is equal at best to the duration Tc of a chip. The higher the time resolution, the smaller Tc, more it will be possible to separate propagation paths and thus increase the diversity order. It is therefore worth having a high chip frequency.
As the present tendency is further to increase data rate, it is understood that operating frequency for processing means will always increase. But this increase finds its limit in the technology of the components used. In the present state of the art, certain compromises have to be adopted between the desired performances (high processing rate) and circuit possibilities. These compromises vary according to the manufacturers:
at HARRIS, component HFA3824, operates around 44 MHz with sequences from 11 to 16 chips and with two samples per chip. Thus, HARRIS obtains up to 4 Mbits/s with a sequence of 11 chips and QPSK (Quaternary Phase Shift Keying using 2 bits per symbol) modulation. With the new component HFA3860, 11 Mbits/s may be obtained through a more complex modulation (8 bits per symbol) and with sequences of a length of only 8 (its working frequency remains at 44 MHz).
at STANFORD TELECOM, component STEL2000A substantially operates at the same rate (45 MHz). It provides links up to 2 Mbits/s with sequences of 11 chips and two samples per chip.
at SIRIUS COMMUNICATION, component SC2001 operates at 47 MHz and processes up to eight samples per chip and uses sequences of a length from 1 to 1023 chips. The maximum binary rate achieved with a minimum length sequence is 11.75 Mbits/s.
The present applicant has himself developed a processing circuit working at a rate of 75 MHz. It processes up to 16 samples per chip for minimum length sequences and allows the use of sequences of a length from 4 to 64 chips. The maximum binary rate reaches 32.5 Mbits/s for sequences of length 4, with one sample per chip.
This discussion of the state of the art shows that in order to attain binary rates greater than 10 Mbits/s, two solutions are available to one skilled in the art: either use a more complex modulation, which increases the number of bits per symbol, while processing relatively short sequence lengths (HARRIS solution with sequences of length 8), or reduce the length of the sequence in order to have a compatible rate with the maximum working frequency imposed by technology (65 MHz for the present applicant).
With the present invention, it is possible to go beyond these compromises by using a parallel architecture filter. The advantages of spectrum spreading may thus be utilized at best by using long pseudorandom sequences, while allowing for high rates.
Parallel architecture filters are already known. For example, document DE-A-196 27 305 describes a filter with several channels working with a plurality of coefficients, whereby these coefficients are utilized through a circular permutation.
Such a filter is not adapted to spectrum spreading with long sequences. On the contrary, the present invention provides a filter with a structure which provides a specific weighted summation adapted to this technique.
The filter of the invention comprises several channels and, in each channel, several stages and it is structured in order to produce intermediate signals which are special weighted sums of input signals and to produce sum signals of these intermediate signals for obtaining the required filtered signals.
More specifically, the object of the present invention is a parallel digital filter receiving p input signals (I0, . . . , Ii, . . . , Ip−1) and delivering p output signals (S0, . . . , Si, . . . , Sp−1) which are the sums of input signals weighted with M coefficients (C0, C1, . . . , CM−1), wherein this filter comprises p parallel channels (V0, . . . , Vi, . . . , Vp−1) receiving the p input signals (I0, . . . , Ii, . . . , Ip−1), characterized in that it comprises r+1 stages (E0, . . . , Ej, . . . , Er), where r is the integer portion of the ratio (M+p−2)/p, wherein stage of rank j delivers p intermediate signals (R0j, . . . , Rij, . . . , Rp−1j) which are the weighted sums of input signals defined by:
the filter further comprising summing means (Σ) receiving said intermediate signals (Rij) and delivering p sums defined by:
these p sums forming the p output signals (S0, . . . , Si, . . . , Sp−1).
As the filter comprises p channels working at a frequency reduced by a factor p with respect to the frequency of the whole with a given technology, with a given operating frequency and with a fixed sequence length, the rate for the data processed by the whole of the filter of the invention is multiplied by p.
In an embodiment, the number of channels p is equal to 2. The filter then comprises a first channel with first storing means for the samples of even rank and a second channel with second means for storing the samples of odd rank, each channel further respectively comprising first and second means, for respectively calculating even and odd weighted sums, respectively.
The object of the present invention is also a direct sequence spread spectrum signal receiver comprising:
at least an analog/digital converter receiving a spread spectrum signal and delivering digital signals of this signal,
at least a digital filter with coefficients adapted to the spread spectrum sequence, this filter receiving the samples delivered by the digital/analog converter and delivering a filtered signal,
means for processing the filtered signal able to restore the transmitted data,
this receiver being characterized in that the digital filter is the filter defined earlier.
In the description which follows, it will initially be assumed that the number p of channels is equal to 2.
This will then be generalized to the case when p is any value.
In order to illustrate the principle of the filter of the invention, the very simple case of pseudorandom sequences comprising four chips with only one sample per chip will further be considered as in the discussion of the state of the art. Needless to say that practically, the sequence will comprise many more chips and many samples may be taken during a chip period.
When, in the four samples considered, the oldest sample is odd (i.e. Ik−1i), the filter must be able to form the following weighted sum Sik:
Ski=C3Ikp+C2Iki+C1Ik−1p+C0Ik−1i (1)
or:
At the next sampling time, the oldest sample becomes even and the weighted sum to be calculated becomes Skp:
Skp=C3Iki+C2Ik.sup.p+C1Ik−1i+Ck−1p (3)
or:
Therefore the even and odd registers should be combined to two different sets of multipliers and adders so that the weighted sums Ski, and Skp, may be calculated alternately.
The complete filter should therefore be as illustrated in
In order to form the two flows of even and odd samples feeding the even and odd registers, respectively, the means illustrated in
The diagram of
Comparison between
Combining the two signals obtained at the output of adders ADDi and ADDp remains to be done if need be.
The diagram of
Of course, case N=4 and ne=1 is hardly a realistic one and it is only used for describing the invention. Practically, each register will have N×ne/2 flip-flops and there will be 2×N×ne multipliers and Nne weighting coefficients (N groups of ne). The general expression of the sums to be calculated may be obtained by setting M=N×ne. The weighted sums Skp and Ski are slightly different according to whether M is even or odd:
1) Odd M
The filter calculates the following two quantities:
2) Even M:
The filter calculates the following two quantities:
By taking M=4, N=4 and ne=1, the example of
In the embodiment of
The diagram of
In
The filter which has just been described may advantageously be used in spread spectrum signal receivers and, in particular, in two channel receivers, one for processing the signal in phase with the carrier, and the other for processing the signal in phase quadrature with said carrier. This embodiment corresponds to phase difference modulations (with two or more phase states). Thus
in channel I, two analog/digital converters CAN(I)p, CAN(I)i controlled at frequency neFc/2 and shifted by τ1/neFc as described in conjunction with
in channel Q, means are similar, i.e. two analog/digital converters CAN(Q)p, CAN(Q)i, a parallel architecture digital filter F(Q) delivering the even S(Q)ki and odd S(Q)ki filtering signals.
In the illustrative alternative embodiment, even S(I)kp and odd S(Q)ki filtering signals delivered by two odd and even adders of the filter are directly used without recombining these signals into a unique signal. This matter is specified in
in channel I, filter F(I) comprises two adders ADD(I)i, and ADD(I)p delivering weighted sums S(I)ki and S(I)kp;
in channel Q, filter F (Q) comprises two adders ADD(Q)i, and ADD(Q)p delivering weighted sums S(Q)ki and S (Q)kp.
Referring back to
The receiver further comprises a circuit Inf/H which receives the various DOT and CROSS signals and delivers first and second information signals Sinfp and Sinfi, a parity signal Sp/i and a clock signal SH determined from the correlation peaks.
Finally the receiver comprises a decision circuit D which receives first and second information signals Sinfp, Sinfi, the parity signal Sp/i with which they may be distinguished from one another and the clock signal SH which enables information to be restored. The latter circuits are similar to those of standard receivers except that they distinguish the peaks of the first and second DOT and CROSS signals, by means of the parity signal Sp/i.
The p input signals I0, . . . , Ii, . . . , Ip−1 are applied to the p channels. Each of these signals is delayed by 1/Ftwhere Ft is the working frequency. The stages deliver intermediate signals noted as R with a lower index i designating the number of the channel (from 0 to p−1) and an upper index j designating the rank of the stage (from 0 to r). Thus, stage Ej delivers p intermediate signals Rij, i ranging from 0 to p−1, according to the relationship:
The weighting coefficient which may be noted as Cx where x is the index, may be taken as equal to zero if x<0 or if x≧M. In other words, the coefficients range from C0 to CM−1.
The filter further comprises summing means Σ receiving the intermediate signals Rij and delivering p sums defined by:
these p sums forming p output signals S0, . . . , Si, . . . , Sp−1 for the filter (with only two. channels, two output signals are obtained, called in the first part of the description, even and odd signals).
Thus, it is seen that the p signals delivered by the p delay circuits are first multiplied by coefficients CM−1−jp, . . . , CM−1−(p−1)−jp and the p thereby weighted signals are added in an adder A0j in order to obtain a first intermediate signal R0j:
The formation of these intermediate signals is thus repeated with coefficients CM−1−jp, . . . , CM+(p−1)−jp and adder A1j, with coefficients CM−1+i−jp, . . . , CM−1+i−(p−1)−jp and adder A1j, etc. . . . , coefficients CM−1−(p−1)−jp, . . . , CM−1−(p−1+(p−1)−jp and adder Ap1j.
Finally,
all the intermediate signals with the same index i are added by means of r adders Ai0, Ai1, . . . , Aij, . . . , Air−1 connected in series and receiving the intermediate signals Ri0, Ri1, . . . , Rij, . . . , Rir respectively.
In order to illustrate the passing to the general case from certain particular cases, the case may be considered when p is equal to 2. The value of the intermediate signals is then:
On the other hand, by taking M=7, the value of the intermediate signals becomes:
or
Rij=(C6+1−2j)I2j+(C5+1−2j)I1+2j
Number r is equal to the integer portion of (M+p−2)/2 that is 3. So there are 4 stages.
Index i has two values 0 and 1 and the intermediate signals have expressions:
R0j=(C6−2j)I2j+(C5−2j)I1+2j
R1j=(C7−2j)I2j+(C6−2j)I1+2j
The values of the output signals are then:
So respectively:
S0=C6I0+C5I1+C4I2+C3I3+C2I4+C1I5+C.0I6+0.I7
and S1=0.I0+C6I1+C5I2+C4I3+C3I4+C2I5+C1I6+C0I7
Number | Date | Country | Kind |
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98 14071 | Nov 1998 | FR | national |
The present application is a continuation of U.S. application Ser. No. 09/831,166 filed May 7, 2001, now U.S. Pat. No. 7,058,119, which in turn is a national phase application of PCT Application No. PCT/FR99/02724 filed Nov. 22, 1999, which in turn claims priority to FR Application No. 98 14071 filed Nov. 9, 1998.
Number | Date | Country | |
---|---|---|---|
Parent | 09831166 | May 2001 | US |
Child | 11447678 | Jun 2006 | US |