초록 ▼

The invention relates to methods of processing signals subjected to interference. It consists, when this signal is formed of a first wideband channel and of a second narrowband channel modulating one and the same carrier in which these signals are cut off for the duration of the interference, in usi

The invention relates to methods of processing signals subjected to interference. It consists, when this signal is formed of a first wideband channel and of a second narrowband channel modulating one and the same carrier in which these signals are cut off for the duration of the interference, in using a single phase loop and a single code loop to process these two channels simultaneously. It makes it easier to process signals in satellite based navigation systems of the GPS type when they are scrambled by the DME-type distance measuring system signals, as well as more generally making it possible to increase the robustness of the processing by joint processing of the bands broadcast to the users.

대표청구항 ▼

The invention claimed is: 1. A method for processing a first and a second signal, the first signal being spread over a wide band channel and the second signal being spread over a narrowband channel, and modulating one and the same carrier in a single carrier phase tracking loop controlled by a carr

The invention claimed is: 1. A method for processing a first and a second signal, the first signal being spread over a wide band channel and the second signal being spread over a narrowband channel, and modulating one and the same carrier in a single carrier phase tracking loop controlled by a carrier phase discriminator, comprising the steps of: generating two components sine and cosine phase shifted of a local carrier at the frequency of the carrier, demodulating the first and second signals with the sine and cosine phase shifted components of the local carrier so as to obtain a first couple of quadrature demodulated components IWB, QWB for the first wide spread signal and a second couple of quadrature demodulated components INB, QNB for the second narrow spread signal, in a single code tracking loop controlled by a code discriminator, generating a code clock signal, on the base of the code clock signal, generating, a first punctual code and a first Δ code, and a second punctual code and a second Δ code compatible with the pseudorandom code, correlating the first couple of quadrature demodulated components IWB, QWB with the first local punctual and Δ codes in order to obtain four demoduladed and dc-spread signal components IPWB, IΔWB, QPWB and QΔWB issued from the wide channel, correlating the second couple of quadrature demodulated components INB, QNB with the second local punctual and Δ codes in order to obtain four demodulated and de-spread signal components IPNB, IΔNB, QPNB and QΔNB issued from the narrow channel, generating an input signal for the phase discriminator mixing the demodulated and de-spread signal components IPWB, QPWB, IPNB, QPNB issued from the correlations of the wide (WB) and narrow (NB) channel signals with the punctual codes, and generating an input signal for the code discriminator, mixing the demodulated and de-spread signal components IPWB, IΔWB, QPWB, QΔWB, IPNB, QΔNB issued from the correlations of the wide (WB) and narrow channel (NB) signals with the Δ codes; and wherein, the input signal for the phase discriminator has its quadrature components Ip opt Qp opt defined by mixing the signal components IPWB, QPWB, IPNBQPNBissued from the correlations of the wide and narrow channel signals with the punctual codes according the formula: description="In-line Formulae" end="lead"Ip opt=αIpWB+βIp NBdescription="In-line Formulae" end="tail" description="In-line Formulae" end="lead"Qp opt=αQpWB+βQp NBdescription="In-line Formulae" end="tail" α, β being weighting parameter. 2. The method as claimed in claim 1, wherein the parameters α and β are determined by the formula: in which the parameters σNB and σWB are estimated on the basis of the number of samples deleted C and of the total number of samples N0 by the formula: description="In-line Formulae" end="lead"σwb2=1/(C/N0 WB)description="In-line Formulae" end="tail" description="In-line Formulae" end="lead"σNb2=1/(C/N0 NB).description="In-line Formulae" end="tail" 3. A method for processing a first and a second signal, the first signal being spread over a wide band channel and the second signal being spread over a narrowband channel, and modulating one and the same carrier in a single carrier phase tracking loop controlled by a carrier phase discriminator, comprising the steps of: generating two components sine and cosine phase shifted of a local carrier at the frequency of the carrier. demodulating the first and second signals with the sine and cosine phase shifted components of the local carrier so as to obtain a first couple of quadrature demodulated components IWB, QWB for the first wide spread signal and a second couple of quadrature demodulated components INB, QNB for the second narrow spread signal, in a signal code tracking loon controlled by a code discriminator, generating a code clock signal, on the base of the code clock signal, generating, a first punctual code and a first Δ code, and a second punctual code and a second Δ code compatible with the pseudorandom code, correlating the first couple of quadrature demodulated components INB, QNB with the first local punctual and Δ codes in order to obtain four demoduladed and de-spread signal components IPNB, IΔPNB issued from the wide channel, correlating the second couple of quadrature demodulated components INB, QNB with the second local punctual and Δ codes in order to obtain four demodulated and de-spread signal components IPNB, IΔNB, QPNB and QΔNB issued from the narrow channel, generating an input signal for the phase discriminator mixing the demodulated and de-spread signal components IPWB, QPWB, IPNB, QPNB issued from the correlations of the wide (WB) and narrow (NB) channel signals with the punctual codes, and generating an input signal for the code discriminator, mixing the demodulated and de-spread signal components IPWB, IΔWB, QPWB, QΔWB, IΔNB, QPNB, QΔNB issued from the correlations of the wide (WB) and narrow channel (NB) signals with the Δ codes; wherein, the input signal for the phase discriminator has its quadrature components Ip opt, Qp opt defined by mixing the signal components IPWB, QPWB, IPNB, QPNB, issued from the correlations of the wide and narrow channel signals with the punctual codes according the formula: description="In-line Formulae" end="lead"Qp opt=αIpWB+βIp NBdescription="In-line Formulae" end="tail" description="In-line Formulae" end="lead"Qp opt=αQp WB+βQp NBdescription="In-line Formulae" end="tail" α, β being weighting parameter; and wherein the input signal for the code discriminator has its quadrature components IΔopt, QΔopt defined by mixing the signal components IΔWB, QΔWB, IΔNB, QΔNB issued from the correlations of the wide and narrow channel signals with the Δ codes according the formula: description="In-line Formulae" end="lead"IΔopt=(αlΔWB +bIΔNB)description="In-line Formulae" end="tail" description="In-line Formulae" end="lead"QΔopt=(αQΔWB +bQΔNB)description="In-line Formulae" end="tail" a, b being weighting parameters. 4. The method as claimed in claim 3, wherein the parameters a and b are determined by the formula: in which the terms SWB and SMB correspond to the slopes of the response curves of the discriminators as measured at the central level of these curves, and the terms ρWB and ρMB are the normalized slopes of the discriminators as obtained by dividing the slope S by a factor σΔ determined by the formula: description="In-line Formulae" end="lead"σΔ=[1-A(2d)] description="In-line Formulae" end="tail" in which A is the normalized authorization function of the filtered spreading code such that A(0)=1, and 2d is the value of the deviation between the early code and the late code used to generate the Δ code.