FR2905010A1 - Radio navigation signal receiving method for e.g. global positioning system, involves forming local wave form over time interval of alternating succession comprising two segments of wave form having predetermined total durations - Google Patents

Abstract

The method involves carrying out a correlation between a local wave form (16) and a composite wave form over a time interval of duration, where the composite waveform consists of a linear combination with real coefficients of two components. The local wave form being a binary wave form is formed over the time interval of an alternating succession comprising two segments (18, 20) of wave form having predetermined total durations. An independent claim is also included for a receiver intended to receive a radio navigation signal modulated by a composite waveform.

Description

P-CNES-002B / FR 1 Technical Field The present invention relates to a

  receiving method, respectively a receiver for a radio navigation signal modulated by a CBOC spreading waveform. State of the art Satellite positioning systems such as GPS (Global Positioning System), Galileo, GLONASS, QZSS and others use modulated navigation signals called spread spectrum. These signals essentially convey pseudo-random codes formed of periodically repeating digital sequences, the main function of which is to allow a Code Division Multiple Access (CDMA) and the provision of an accurate measurement of the propagation time of the transmitted signal. by the satellite. Incidentally, satellite positioning signals can also carry useful data. In the case of GPS, the navigation signals are transmitted in the L1 frequency bands, centered on 1575.42 MHz and L2, centered on 1227.6 MHz. During the GPS upgrade, the L5 band, centered on 1176.45 MHz will be added. The satellites of the Galileo constellation will transmit in the E2-L1-E1 band (the median band portion L1 being the same as that of the GPS), E5a (which, according to the Galileo nomenclature, represents the L5 band provided for the GPS) , E5b (centered on 1207.14 MHz) and E6 (centered on 1278.75 MHz). The navigation signals are formed by modulation of the central frequencies (carriers). Various modulation schemes are already implemented for carrying out the navigation signals or at least envisaged. To ensure interoperability and compatibility between the GPS and Galileo systems, the United States of America and the European Union have agreed on certain points concerning signal modulation schemes in the L1 band used by both systems. More details on the proposed modulation schemes can be obtained from the publication MBOC: The New 2905010 P-CNES-002B / EN 2 Optimized Spreading Modulation Recommended for GALILEO L1 OS and GPS L1 C, Hein et al., InsideGNSS, May / June 2006, pp. 57-65. One of the modulation schemes selected as a candidate for modulation of the Galileo OS L1 signal is known as CBOC (Composite Binary Offset Carrier) modulation. The carrier modulating CBOC spreading waveform is a linear combination of a BOC waveform (1,1) and a second BOC waveform (m, 1). BOC is the abbreviation of Binary Offset Carrier. In general, BOC (n, m) is a function of time t defined by: BOC (n, m) (t) = C ,,, (t) • sign [sin (2szfsxt)], where Cm (t) is a 1x1223 Mcps chip rate pseudo-random code taking the values +1 or -1 and fsc the frequency nx 1,023 MHz. A condition on n and m is that the ratio 2n / m is integer. In the case of Galileo's Open Service (OS), the chip rate is 1.023 Mcps (mega-chips per second). A CBOC waveform can be written in this case: CBOC (n1,1) (t) = V BOC (1,1) (t) + W • BOC (n1,1) (t), where V and W are real coefficients defining the relative weighting of the BOC (1,1) and BOC (m, 1) components. In the case of a CBOC waveform, the two BOC components carry the same pseudo-random code. A CBOC waveform may be considered as a particular member of a family of composite waveforms described, for example, in European Patent Application 05 290 083.4. The same document also describes methods of receiving a modulated signal by a composite waveform. According to the first method described, the correlation of the modulated incoming signal is performed by a CBOC waveform and a local replica of this CBOC waveform. This solution involves, at the receiver, the generation of a CBOC replica. It is therefore necessary to implement a four-level quantization at the input of the correlator, which requires at least a 2-bit architecture. According to the second method described, the correlations between the incoming signal and a local replica of the first BOC component, respectively between the incoming signal and a local replica of the second BOC component, are operated. Then, the results of the two correlations are combined. In this solution, local replicas are one bit which may be considered advantageous over the first solution. The price to be paid is a number of correlation operations doubled vis-à-vis the first solution, all other things being equal. Object of the invention An object of the present invention is to propose a new method of receiving data. a radionavigation signal modulated by a composite spreading waveform. General Description of the Invention To receive a radionavigation signal modulated by a composite waveform, the composite waveform comprising a linear combination with real coefficients of a BOC component (ni, m) and a component BOC (n2, m), nor being distinct from n2, it is proposed to make a correlation between a local waveform and the composite waveform over a time interval of duration T. According to an important aspect of the invention, the local waveform is a binary waveform formed over said time interval of an alternating succession comprising at least one BOC waveform segment (n1, m) and at least one segment of BOC waveform (n2, m), the at least one BOC segment (n1, m) having a total duration of aT, a being strictly between 0 and 1, the at least one BOC segment (n2, m ) having a total duration (1-a) T.

  Unlike the reception methods discussed above, the method according to the invention does not involve a waveform at more than two levels and does not require a higher number of correlators. In a preferred embodiment of the invention, the components BOC (ni, m) and BOC (n2, m) carry the same pseudo-random code and the local waveform carries at least a predetermined part of this code 2905010 P-CNES-002B / EN 4 pseudo-random. The pseudo-random codes used in the satellite radionavigation are either entirely predetermined codes (in the case of a pilot channel) or codes comprising a predetermined part and a given part (in the case of a data channel) . The data portion is transmitted at a significantly lower symbol rate than the chip rate of the predetermined portion. In the case where n2 = 1 and m = 1, the linear combination is a CBOC waveform (ni, 1) defined by: CBOC (n1,1) = V BOC (1,1) + W BOC (n1,1) Where V and W are real weighting coefficients. Regarding the CBOC candidate for the future Galileo OS L1 signal, it was further agreed that ni = 6. In some cases, it may be advantageous for the reception of a CBOC signal (ni, 1) that is at least approximately equal to the reference value W / (V + W). In other cases, a less than or greater than this reference value may be more appropriate. The local waveform may comprise an alternating succession comprising a single BOC waveform segment (ni, m) and a single BOC waveform segment (n2, m). In another embodiment of the invention, the alternating succession comprises a plurality of BOC waveform segments (ni, m) of a total duration aT and / or a plurality of BOC waveform segments. (n2, m) of a total duration (1-a) T. To implement the method according to the invention, there is provided a receiver adapted to receive a radionavigation signal modulated by a composite waveform, the composite waveform comprising a linear combination with real coefficients of a component BOC (ni, m) and a BOC component (n2, m), nor being distinct from n2, the receiver comprising a set of local waveform generators and correlators for effecting correlation between the waveform The local waveform generators are, in particular, configured to generate a binary local waveform, formed over said time interval of a succession, and the said composite waveform over a time interval of duration T. alternating circuit comprising at least 2905010 P-CNES-0028 / FR 5 a BOC waveform segment (ni, m) and at least one BOC waveform segment (n2, m), the at least one BOC segment (ni, m) having a total duration of aT, a being strictly between 0 and 1, l at least one BOC segment (n2, m) having a total duration (1-a) T.

According to a preferred embodiment, the receiver comprises a control unit acting on the local waveform generators so as to influence (a) the temporal order of the BOC segment (s) (ni, m) and the one or more BOC segments (n2, m) and / or (b) the duration of the BOC segment (s) (ni, m) and the BOC segment (s) (n2, m). This embodiment is particularly advantageous for a receiver adapted to future Galileo OS L1 and GPS L1 C signals. Indeed, the modulation provided for this latter signal is a time-multiplexed BOC (Time-Multiplexed BOC) modulation. having a BOC component (1,1) and a BOC component (6,1). If the modulation adopted for Galileo OS L1 is a CBOC (6.1) modulation, then it will be possible to receive both signals by the same receiver. By playing on the time order of the BOC (1,1) and BOC (6,1) segments and / or on their duration, the control unit can optimize the local waveform for receiving either the GPS TMBOC or from Galileo CBOC. BRIEF DESCRIPTION OF THE DRAWINGS A preferred embodiment of the invention will be described hereinafter, by way of non-limiting example, with reference to the accompanying drawings, in which FIG. 1: is a temporal representation of a CBOC waveform (6.1); Fig. 2: is a representation of a correlation between a BOC waveform (1,1) and a BOC waveform (6,1); Fig. 3: is a representation of autocorrelations of two CBOC waveforms (6.1) having different weighting factors; Fig. 4: is a temporal representation of a local binary waveform that can be used in a method according to the invention; 2905010 P-CNES-002B / EN 6 Fig. 5: shows a comparison between the autocorrelation function of a CBOC (6,1,1 / 11) and the correlation function between a CBOC (6,1,1 / 11) and a binary local waveform such as illustrated in Figure 4; Fig. Figure 6 shows different correlation functions between a CBOC (6.1.2 / 11) and a binary local waveform; Fig. 7: is a representation of the degradation of the ratio C / No as a function of the parameter a, in the cases of CBOC (6,1,1 / 11) and CBOC (6,1,2 / 11); Fig. Fig. 8 shows a comparison of the error envelope due to multipath in the case where the local waveform is a composite CBOC waveform (6.1) and the error envelope due to the multipath. -trajet in the case where the local waveform is a binary waveform as shown in Figure 4; Fig. 9: is a diagram of a receiver adapted to the reception of a composite signal. DESCRIPTION OF A PREFERRED EMBODIMENT FIG. 1 shows a CBOC (6,1) 10 waveform, defined by: CB'OC (6,1) (t) = V • BOC (1,1) (t) - W BOC (6.1) (t) where V and W are the weighting factors. We will use in the following the following notations: BOC (1,1) (t) = C p (t) • x (t) and BOC (6,1) (t) = Cp (t) • y (t), where Cp (t) represents the pseudo-random code common to both components. For the Galileo OS L1 signal, different V and W values are considered, depending on the multiplexing scheme of this signal. More details can be found in the article by Hein et al. in InsideGNSS, whose full reference is shown in the introduction. In order to introduce certain notations and to better explain the advantages of the invention, we will discuss hereinafter a CBOC signal tracking method 10, the principle of which has been described in the European Patent Application No. CE-0028 / EN 7 05 290 083.4. In this method, there are two correlations to perform in parallel: one with a local BOC (1.1) replica and one with a BOC (6.1) local replica. The local replicas are the following ones (t) = Cp (t) x (t) cos (2Tfu + (b), 5Q1 (t) = Cp (t) x (t) sin (2nfot +, s12 (t) = Cp (t) y (t) cos (27zfot +, sQZ (t) = Cp (t) y (t) sin (2Tfot +, where the indices I and Q mark the in-phase and quadrature phase components of the replicas local, fo is the frequency of the carrier 10 and a phase As the correlation of the signal CBOC with sil, we obtain: T i = fsil (ti) CBOC (ti7, 0 T =! Cp (t ù i) x (t ù i) cos (2TCfot + iCp (t ù 7) {V x (tr) -W y (t ù 7)} cos (27fot + 0) dt, 0 IE _ (VRaoc (1,1) ~ ET) ù WRaoc (1,1)! Aoc (6, I) (5)) cos (so), where is the phase of the pseudo-random code of the local replica signal, estimated from phase i of the pseudo-random code of the received signal , the phase of the carrier of the local replica signal, estimated from the phase 0 of the phase of the carrier of the received signal, T the duration of the integration interval, RBoc (l, 1) the autocorrelation function of a waveform BOC (1,1), RBOC (1,1), BOC (6,1) function correlation between a BOC waveform (1,1) and a BOC waveform (6,1), sT = ùr and so = Where. In the same way, we can write: Qi = (VRBoc (i, l) (AND) ù WRaoc (I, 1) / BOC (6.1) ~ T)) Sin (s0), I2 = (VRBOC (1 , 1) / BOC (6.1) (T) ù WRBOC (6.1) (sT)) cos (go), 2905010 P-CNES-002B / FR 8 Q2 = (VRBOC (i, I) / BOC ( Where RBOC (6, 1) is the autocorrelation of a BOC waveform (6.1). correlations and using the fact that the correlation between a BOC waveform (1,1) and a BOC waveform (6,1) is symmetrical as shown in FIG. 2, we find the autocorrelation function of a CBOC waveform: I = VII ù WIZ = (V ZRaoc (i, l) (e) + W ZRaoc (6, i) ~ sr) û 2VWRaoc (i, inaoc (6, i) () ) cos (s ≠) and Q = VQ1 û WQz = (V 2RBOC (1,1) \ r) + W 2RBOC (6,1) \ r) 2VWRBOC (1,1 /) aoc (6,1) ( AND)) sin (s0). Autocorrelations 12, 14 of two CBOC waveforms are shown in FIG. 3. Assuming that the data and pilot channels each carry 50% of the signal strength, the indices 1/11 and 2/11 indicate the pattern. multiplexing used for the radionavigation signal and refer to a certain weighting of the components BOC (1,1) and BOC (6,1). For CBOC (6.1.1 / 11), V = 0.383998 and W = 0.121431; for CBOC (6.1.2 / 11), V = 0.358235 and W = 0.168874. Reference number 12 marks the autocorrelation function in the case of CBOC (6,1,1 / 11) and reference number 14 marks the autocorrelation function in the case of CBOC (6,1,2 / 11 ). The disadvantage of the method described above is the number of correlators required for its implementation. The present invention proposes, for receiving the CBOC waveform (6.1) defined above, to correlate the incoming signal with a time-multiplexed local signal 16 which comprises a segment or segments of pure BOC (1,1) and a segment or segments of pure BOC (6,1). Figure 4 shows a time representation of a local waveform sLoc (t), which has a BOC (6,1) waveform segment 18 at the beginning of the integration interval and a segment of BOC waveform (1,1) at the end of the integration interval. The local waveform 16 has only two values (binary waveform) and can therefore be bit-coded. The local waveform 16 carries the known part of the pseudo-random code modulating the CBOC signal (6.1). It is possible to recognize transitions of the pseudorandom code value at the abscissae 4,07 and 4,11 of FIG. 4. Note that the local waveform 16 is clearly distinct from the composite waveform modulating the incoming radionavigation signal. Let T be the duration of the integration interval, at T the total duration of the segment (s) 18 of pure BOC (6.1), with 0 <a <1, and [3T the total duration of the segment (s) 20 of pure BOC (1,1), with [3 = 1-a. To analyze the result of a correlation between the radio-wave signal modulated by the CBOC waveform (6.1) and the local binary waveform 16, we can decompose the correlation: T aT T 10 jsLOC (t f) CBOC (t --r) dt = f sLOC (t û i) CBOC (t û r) ch + jsLOC (t û z) CBOC (t û r) dt 0 0 aT Taking again what we have seen in the previous example, and assuming that the sequences of the pseudo-random code corresponding to the intervals [0, aT] and [aT, T] themselves approximate pseudo-random codes, we can make the following approximation: IBOC (6,1) = a (VRBOC (1,1) / BOC (6,1) (Er) WRBOC (E, 1) (Er)) cos (e0), QBOC (6,1) = a (VRBOC ( 1,1) IBOC (6,1) (Er) ù WRB00O31) (Er)) sin (s0), I soc (1,1) =, Q (VR BOC (1,1) (Er) û WR BOC ( 1,1) IBOC (6,1) (Er)) cos (ee) and QBOC (1,1) = fi (VRBOC (1,1) (Er) - WRBOC (1,1) / BOC (6, 1) (Er)) Sin (e0). The correlation thus becomes: I = IBOC (1,1) IBOC (6,1) / ~ (flVRBOC (1,1) (Er) - (/ 3W + aV) RBOC (1,1) / BOC (6, 1) (Er) + aWRBOC (6,1) (Er)) Cos (s) Q ~ = / QjBOC (1, I) -QBOC (6,1) = V Reoc (1,1) (Er) - ( gW + aV) RBOC (1,1) IBOC (6,1) (Er) + aWRBOC (6,1) \ AND)) sin (Eo) We see that to find, to a multiplicative factor, the same relative contribution autocorrelation functions of the BOC (1,1) and BOC (611) waveforms only in the autocorrelation function 12 or 14 of the CBOC, it is necessary that a-WI (V + W) and [3 = V / (V + W).

In the case of the CBOC (6,1,1 / 11) scheme, therefore, a = 0.2403 and 8 = 0.7597 are preferably used. FIG. 5 shows, on the one hand, the autocorrelation function 12 of the CBOC (6,1,1 / 11), already illustrated in FIG. 2, and, on the other hand, the correlation function 22 between the CBOC (6,1 , 1/11) and the local binary waveform 16 with a = 0.2403 and 8 = 0.7597. With regard to the appearance of the local binary waveform 16, this means that out of 4096 bits of the pseudo-random code, approximately 984 form the BOC (6,1) and 3112 waveform segments. the one or more BOC waveform segments (1,1).

In the case of CBOC (6.1.2 / 11), a = W / (V + W) leads to a = 0.3204 and 83 = 0.6796. In this case, out of 4096 snippets of the pseudo-random code, approximately 1312 form the BOC (6,1) waveform segment (s) and 2784 form the BOC (1,1) waveform segment (s). FIG. 6 shows a family of correlation functions 24, 26, 28 and 30 between a CBOC modulated radionavigation signal (6.1.2 / 11) and a time-multiplexed binary local waveform. obtained for different values of the parameter a. It can be seen that the value of a makes it possible to play on the form of the correlation function. For a = 0, we obtain the curve 24, for a = 0.1 the curve 26, for a = 0.2 the curve 28 and for a = 0.3 the curve 30. According to the value of a, the peaks central 32 and secondary 34 are more or less pronounced. Figure 7 shows the degradation of the CINo ratio, i.e. the signal ratio received on the spectral density of the noise. The degradation of the C / No can be calculated by: Peak Corr2 _ ù (113V + aW) 2 degC No = Peak ù Autocorr2 (V 2 + W 2 because RBOC (l, l) / BOC (6.1) is symmetrical and is 0 to 0. Alternatively, one can write: 25 degc / No (V + a (WûV)) 2 2905010 P-CNES-0028 / EN 11 The degradation of C / No is represented in figure 7 for the cases of CBOC (6,1,1 / 11) (curve 36) and CBOC (6,1,2 / 11) (curve 38) We see that for the case a = C, which corresponds to the case where the waveform local is a pure BOC (1,1), we have the degradation associated with part of the signal power 5 allocated to the BOC (6,1) (1/11 and 2/11 respectively). 6.1.1 / 11), with a = 0.2403, there is a degradation of the C / N0 ratio of 1.97 dBs.In the case of CBOC (6.1.2 / 11), with a = 0.3204 the degradation of the C / No ratio of 2.56 dBs is shown For the example of CBOC (6,1,1 / 11), Figure 8 shows, on the left, the multi-path error envelope 40 in the case where the local waveform is a composite CBOC waveform (6 , 1) and, on the right, the multipath error envelope 42 in the case where the local waveform is a time-multiplexed binary waveform with a = 0.2403. Note that the multipath error envelopes 40, 42 are essentially identical. It should be noted that obtaining a correlation function similar to a proportionality factor to the autocorrelation function of the CBOC is not the only criterion for optimizing the value of a. Indeed, it is also possible to choose the local binary waveform depending in particular on the criteria: (a) minimizing the degradation of the C / No ratio, (b) minimizing the tracking error due to Gaussian white noise (c) optimizing the shape of the correlation function between the incoming signal and the local waveform and (d) reducing multipath errors. There is therefore a certain freedom to choose the value of a.

FIG. 9 shows the simplified diagram of the reception channel of a receiver 44 adapted to receive a composite signal, for example a CBOC signal. Supposed baseband signals are assumed, without considering local carriers for this illustration. Receiver 44 comprises a set 46 of correlators, exemplified in number of three. These correlators 46.1, 46.2, 46.3 can also be two in number, see one per channel, but also more numerous, to reduce the acquisition time and / or the error due to the multi-channel. for example. Each correlator comprises a mixer 48.1, 48.2, resp., 48.3, mixing the incoming signal CBOC with a copy of the local binary waveform soc, and an integrator 50.1, 50.2, resp. 50.3 effecting the integration of the mixed signals and producing an output signal. It should be noted that to receive several signals transmitted by the satellites, a receiver needs a plurality of reception channels (channels). For each receive channel of the receiver, there is such a set of correlators whose output signals are combined to form, in signal acquisition mode, the energy estimate of the received signal and, in continuation mode, signal, the discriminator of the pseudo-random code. The first correlator 46.1, said in advance, provides the correlation value of the incoming signal CBOC (t-i) and an advance copy of the local binary waveform sLoc (t-1 -0 / n). It is recalled that i is the phase of the pseudo-random code of the received signal and z an estimate of ti.O is the duration of a chip and n determines the fraction of chip duration that the copy of the waveform local binary is ahead of the estimate. The second in-phase correlator 46.2 provides the value of the correlation of the incoming signal CBOC (t-'r) and a phase copy of the local binary waveform sLoc (t-1). The late third correlator 46.3 provides the correlation value of the incoming signal CBOC (t-z) and a late copy of the local binary waveform sLoc (t-1 + A / n). To produce the signals sLoc (t-1-Ain), sLoc (t-1) and sLoc (ti + Ain), the receiver 44 comprises a set of generators. For the sake of clarity, only the generator 52 providing the copy sLoc (t-1 + A / n) of the local waveform is shown. The generator 52 is controlled by a control unit 54. The generator 52 may comprise, for example, a digitally controlled oscillator (OCN). In this case, the OCN receives as input a target oscillation frequency corresponding to the corrected chip rate for the Doppler effect as well as a binary value which determines whether the OCN outputs a BOC waveform (n2 , m) or BOC (n, m). The binary value is given by the control unit as a function of the operating mode of the receiver, i.e. depending on whether the receiver is in acquisition mode, in tracking mode, or whether it receives a CBOC signal or a TMBOC signal. The control unit determines in particular the temporal order of the BOC segment (s) (ni, m) and the BOC segment (s) (n2, m) and the duration of the BOC segment (s) (ni, m) and the BOC segments (n2, m).

Claims (10)

claims   A method of receiving a radionavigation signal modulated by a composite waveform, the composite waveform comprising a linear combination with real coefficients of a BOC component (ni, m) and a BOC component ( n2, m), nor being distinct from n2; wherein a correlation between a local waveform and said composite waveform is performed over a time interval of duration T, characterized in that the local waveform is a binary waveform, formed on said time interval of an alternating succession comprising at least one BOC waveform segment (ni, m) and at least one BOC waveform segment (n2, m), the at least one BOC segment (and , m) having a total duration of a T, a being strictly between 0 and 1, the at least one segment BOC (n2, m) having a total duration (1-a) T.   2. Method according to claim 1, in which the BOC components (ni, m) and BOC (n2, m) bear the same pseudo-random code and in which the local waveform carries at least a predetermined part of this code. pseudorandom.   3. Method according to claim 1 or 2, wherein n2 = 1 and m = 1, the linear combination being a CBOC waveform (ni, 1) defined by: CBOC (nl, 1) = V • BOC ( 1,1) + W BOC (n1,1), where V and W are real weighting coefficients.   The method of any one of claims 1 to 3, wherein n1 = 6.   The method of claim 3 or 4, wherein a is at least approximately equal to W / (V + W).   The method of any one of claims 1 to 5, wherein said local waveform is formed over said time interval of an alternating succession comprising a plurality of BOC waveform segments (ni, m). of a total duration aT and / or a plurality of BOC waveform segments (n2, m) of a total duration (1-a) T.   Receiver adapted to receive a radionavigation signal modulated by a composite waveform, the composite waveform comprising a linear combination with real coefficients of a BOC component (ni, m ) and a BOC component (n2, m), nor being distinct from n2, the receiver comprising a set of local waveform generators and correlators for effecting correlation between the local waveform and said form composite waveform over a time interval of duration T, the receiver being characterized in that the local waveform generators are configured to generate a binary local waveform formed over said time interval of a succession alternator comprising at least one BOC waveform segment (ni, m) and at least one BOC waveform segment (n2, m), the at least one BOC segment (ni, m) having a duration total of aT, a being strictly between 0 and 1, the at least one segment BOC (n2, m) ayan t a total duration (1-a) T.   8. Receiver according to claim 7, characterized in that it comprises a control unit acting on the local waveform generators so as to influence a temporal order of the BOC (ni, m) segment (s) and the BOC segments (n2, m), and / or the duration of BOC segment (s) (ni, m) and BOC segment (s) (n2, m).   9. Receiver according to claim 7 or 8, wherein n1 = 6, n2 = 1 and m = 1.   10. Use of a receiver according to any one of claims 7 to 9 for receiving a radionavigation signal modulated by a composite waveform, the composite waveform comprising a linear combination with real coefficients of a component BOC (ni, m) and a BOC component (n2, m), nor being distinct from n2.