RU2006121497A - Coherent Tracking for the FM Receiver of the VLF Standard Using the Antenna System with Switching Diversity - Google Patents

Claims (32)

1. A method of coherent tracking of a radio signal including a plurality of reference subcarriers subjected to digital modulation, including the steps of receive symbols transmitted on the reference subcarriers using a plurality of antenna elements, while switching between the antenna elements causes an abrupt transition, combine the symbols of the reference subcarriers with the conjugate value of the known reference sequence to obtain multiple samples, performing median filtering of the samples to obtain filtered samples, and smoothing samples for each of the reference subcarriers on the set of reference subcarriers to obtain a coherent estimate of the reference signal for each of the subcarriers. 2. The method according to claim 1, further comprising the steps of using said plurality of samples and a coherent estimate of the reference signal for each of the subcarriers to obtain a noise dispersion signal, filtering the noise dispersion signal to obtain a filtered noise dispersion signal, choosing between a noise dispersion signal and a filtered noise dispersion signal to determine a selected noise dispersion signal, and smoothing the selected noise dispersion signal for each of the reference subcarriers on the plurality of reference subcarriers to obtain an estimate of the signal noise dispersion for each of the subcarriers. 3. The method of claim 2, wherein the step of using a plurality of samples and coherently estimating a reference signal for each of the subcarriers to obtain a noise dispersion signal includes the steps of: subtracting the coherent estimate of the reference signal from said plurality of samples to obtain a noise sample, and squaring the noise sampling unit to obtain a noise dispersion signal. 4. The method according to claim 2, wherein said step of filtering the noise dispersion signal to obtain a filtered noise dispersion signal includes a step of sequentially pass the noise dispersion signal through the median filter and an additional filter to smooth the noise dispersion signal in frequency. 5. The method according to claim 4, in the implementation of which an additional filter contains a filter with an infinite impulse response or a filter with a finite impulse response. 6. The method according to claim 2, further comprising the step of scaling the noise dispersion signal before the selection step between the noise dispersion signal and the filtered noise dispersion signal to determine a selected noise dispersion signal. 7. A receiver for coherent tracking of a radio signal including a plurality of reference subcarriers subjected to digital modulation, comprising a plurality of antenna elements for receiving a radio signal, while switching between the antenna elements causes an abrupt transition, an input for receiving a radio signal and a processor for coherently monitoring a radio signal by receiving symbols transmitted on the reference subcarriers, combining the symbols of the reference subcarriers with the conjugate value of the known reference sequence to obtain a plurality of samples, performing median filtering of samples to obtain filtered samples, and smoothing samples for each of the reference subcarriers on a plurality of reference subcarriers to obtain a coherent estimate of the reference signal for each of the subcarriers. 8. The receiver according to claim 7, in which the processor additionally uses the aforementioned set of samples and a coherent estimate of the reference signal for each of the subcarriers to obtain a noise dispersion signal, filters the noise dispersion signal to obtain a filtered noise dispersion signal, selects between the noise dispersion signal and the filtered signal noise dispersion for determining a selected noise dispersion signal and smooths the selected noise dispersion signal for each of the reference subcarriers on the set of reference subcarriers to obtain about signal noise dispersion quotes for each of the subcarriers. 9. The receiver of claim 8, wherein the processor further subtracts the coherent estimate of the reference signal from said plurality of samples to obtain a noise sample, and squares the noise sample module to obtain a noise dispersion signal. 10. The receiver of claim 8, wherein the processor sequentially passes the noise dispersion signal through a median filter and an additional filter. 11. The receiver of claim 10, in which the additional filter contains a filter with an infinite impulse response or a filter with a finite impulse response. 12. The receiver of claim 8, wherein the processor scales the noise dispersion signal before the selection step between the noise dispersion signal and the filtered noise dispersion signal to determine a selected noise dispersion signal. 13. A method of coherent tracking of a radio signal, including at least one reference carrier, subjected to digital modulation, including the steps of using a plurality of antenna elements for receiving a radio signal, while switching between the antenna elements causes an abrupt transition process, demodulating the reference carrier to obtain complex coherent reference gain, detect a transient process that affects the complex coherent reference gain, filtering complex coherent reference gain to obtain smoothed complex coherent reference gain and process the smoothed complex coherent reference gain factors, discarding the values of the complex coherent reference gain factors closest to the transient and replacing the values of the complex coherent reference gain factors closest to the transition process with the closest value of the complex coherent reference gain factors not affected by the filter. 14. The method according to item 13, in which the radio signal contains many reference subcarriers and which regulate the complex coherent reference gain in the vicinity of the transient for each of the reference subcarriers. 15. The method of claim 13, wherein the step of detecting a transient that affects the complex coherent reference gain factors includes the steps of: process complex coherent reference gain for multiple reference subcarriers and group complex coherent reference gain factors for all reference subcarriers to obtain one composite reference coherent channel signal for each OFDM (multiplexed with orthogonal frequency division) symbol (OFDM symbol). 16. The method of claim 13, wherein the step of detecting a transient that affects the complex coherent reference gain factors includes the steps of: calculate the modulus of the difference of the set of composite reference signals of the coherent channel, determine if the module is a local peak, and if the module is a local peak, then the module is scaled back by the sum of the module of the difference. 17. The method of claim 13, wherein the step of detecting a transient that affects the complex coherent reference gain factors includes the steps of: calculating a sequence of samples x _n based on the complex coherent reference gain factors, calculating square difference diffsg _n (razn.kvadr. _n) between the samples x _{n + 1} and x _n-1, set detpeak _n (obnaruzh_pik _n) of the peak detection variable equal to unity if diffsg _n ≥ diffsg _n-1 (razn.kvadr. _n ≥ razn.kvadr. _n-1) or diffsg _n ≥ diffsg _{n + 1} (razn.kvadr. _n ≥ different squared _{n + 1} ), otherwise set the peak detection variable to 0, and indicate a transient if

(different squared _n / (| x _{n + 1} | ² + | x _n-1 | ² )) is greater than the predetermined threshold value. 18. The method according to item 13, in which the processing step of the complex coherent reference gain factors includes the steps of discarding values (α) of complex coherent reference gain factors close to the transient, which include the symbol where the transient is detected, and replace the discarded values (α) with the nearest value α, which is not affected by the filter used to estimate α. 19. The method according to item 13, in which the processing step of the complex coherent reference gain factors includes the steps of if the distorted value (α) of the complex coherent reference gain is detected within 3 characters before the current character, then instead of using the current value of α, use the value (α _n-4 ), which is 4 characters before the transient, if the distorted value (α) of the complex coherent reference gain is detected within 3 characters after the current symbol, then instead of using the current value of α, use the value (α _{n + 4} ), which is 4 characters after the transient, if the distorted value (α) of the complex coherent reference gain is at the location of the current detected symbol, then use the average value (α _n-4 + α _{n + 4} ) / 2 of the values of α samples that are in position ± 4 characters from any sides of the transition process, and if the distorted value (α) of the complex coherent reference gain is not detected, then use the current input values of α. 20. A receiver for coherent tracking of a radio signal including at least one reference carrier, subjected to digital modulation, containing a plurality of antenna elements connected to the input, while switching between the antenna elements causes an abrupt transition, an input for receiving a radio signal and a processor for demodulating a reference carrier to obtain complex coherent reference gain factors, for detecting a stepwise transient that affects complex coherent reference gain factors, and for adjusting complex coherent reference gain factors in the vicinity of the transition process to obtain adjusted coherent reference gain factors. 21. The receiver according to claim 20, in which the processor substitutes the previous or future value of the complex coherent reference gain in place of the complex coherent reference gain in the vicinity of the transient. 22. The receiver of claim 20, wherein the processor filters the complex coherent reference gain factors and processes the smooth complex coherent reference gain factors, discarding the complex coherent reference gain factors closest to the transient, and replacing the values complex coherent reference gain factors closest to the transient, the closest value of complex coherent supports gain factors not affected by the filter. 23. The receiver according to claim 20, in which the radio signal contains many reference subcarriers and which regulate the complex coherent reference gain in the vicinity of the transient for each of the reference subcarriers. 24. The receiver of claim 20, wherein the processor processes the complex coherent reference gains for the plurality of reference subcarriers and groups the complex coherent reference gains across all the reference subcarriers to obtain one composite coherent channel reference for each OFDM symbol. 25. The receiver according to claim 20, in which the processor calculates the module of the difference of the set of composite reference signals of the coherent channel, determines whether the module is a local peak, and if the module is a local peak, then the module is scaled back by the sum of the module of the mentioned difference. 26. The receiver of claim 20, wherein the processor receives a sequence of samples x _n, calculates a difference square diffsg _n (razn.kvadr. _N) between the samples x _{n + 1} and x _n-1, sets the variable peak detection ditpeak _{n (n} obnaruzh_pik ) equal to one if diffsg _n ≥ diffsg _n-1 (different squared _n ≥ different squared _n-1 ) or diffsg _n ≥ diffsg _{n + 1} (different squared _n ≥ different squared _{n + 1} ) otherwise, set the peak detection variable to 0, and indicate a transient if

(different squared _n / (| x _{n + 1} | ² + | x _n-1 | ² )) is greater than the predetermined threshold value. 27. The receiver according to claim 20, in which the processor discards the values (α) of the complex coherent reference gain factors close to the transient, which include the symbol where the transient is detected, and replaces the discarded values (α) with the closest value α, by which is not affected by the filter used to estimate α. 28. The receiver according to claim 20, in which if the distorted value (α) of the complex coherent reference gain is detected within 3 characters before the current character, then instead of using the current value of α, the value (α _n-4 ) is used, which is in 4 characters before the transient, if the distorted value (α) of the complex coherent reference gain is detected within 3 characters after the current symbol, then instead of using the current value of α, the value (α _{n + 4} ) is used, which is 4 characters after the transient, if the distorted value (α) of the complex coherent reference gain is at the location of the current detected symbol, then the average value (α _n-4 + α _{n + 4} ) / 2 of the values of α samples that are in position ± 4 characters from any sides of the transition process, and if the distorted value (α) of the complex coherent reference gain is not detected, then the current input values are used. 29. A receiver for coherent tracking of a radio signal including at least one reference carrier, subjected to digital modulation, containing a plurality of antenna elements connected to the input, while switching between the antenna elements causes an abrupt transition, an input for receiving a radio signal and means for demodulating the reference carrier to obtain complex coherent reference gain, for detecting a transient that affects the complex coherent reference gain, and for adjusting the complex coherent reference gain in the vicinity of the transition to obtain adjusted complex coherent reference gain. 30. A method for estimating the noise variance of symbols in a radio signal, when the noise may include pulsed noise samples among Gaussian noise samples, the method including the steps of summarize input samples and coherent reference samples to obtain error samples, calculate the squares of the error samples, separate squared samples of Gaussian noise and squared samples of impulse noise, and non-linear filtering of the squares of the error samples is performed to obtain an estimate of the noise variance, which is the sum of the long-term average dispersion of the Gaussian noise and the short-term dispersion of pulsed noise. 31. The method according to item 30, including the stage at which determining whether each squared noise sample is pulse-like by comparing the sample with a multiple of the current average noise variance estimate, and if the squared noise sample is not defined as impulse-shaped, then the squared noise sample is introduced into the filter used to estimate the long-term dispersion of the Gaussian noise, and if the noise sample is defined as pulse-shaped, then squared the noise sample in the filter is reduced to prevent over-estimation of the long-term Gaussian noise dispersion. 32. The method according to item 30, including the stage at which creating an excess noise value including a portion of the reduced squared noise sample, and the excess noise value is added to the Gaussian noise variance estimate to produce a composite noise variance representing the sum of the long-term averaged Gaussian noise variance and the short-term impulse noise variance.