RU2001111844A - Method and device for demodulation and correction of broadcast signal of digital audio signal compatible with amplitude-modulated signal - Google Patents

Claims (28)

1. A method for demodulating and correcting a digital broadcast signal compatible with an amplitude-modulated signal, comprising an amplitude-modulated radio frequency signal having a first carrier modulated by an analog program signal in a first frequency spectrum, a plurality of digitally modulated carrier signals arranged in a frequency band, covering the first frequency spectrum, the first group of digitally modulated carrier signals containing complementary carrier signals and located in th frequency spectrum, and the second and third groups of digitally modulated carrier signals contain non-complementary carrier signals and are located outside the first frequency spectrum, namely, they subject to a fast Fourier transform a digital broadcast signal compatible with the amplitude-modulated signal to form the first a converted signal representing non-complementary carriers, characterized in that the first converted signal is processed to form the first corrected a signal by multiplying the first transformed signal by the first correction vector, the first correction vector being formed by the first set of correction factors, update the first set of correction factors used for non-complementary signals, subject to fast Fourier transform of the digital broadcast signal compatible with the amplitude-modulated signal to generate a second a transformed signal representing complementary carriers determines a second correction iruyuschy vector formed by a second plurality of equalizer coefficients, said second plurality of equalizer coefficients are determined by interpolation using coefficients of the first plurality of equalizer coefficients, and processing the second transformed signal to produce the second equalized signal by multiplying the second transformed signal by the second equalization vector. 2. The method according to claim 1, characterized in that the digital broadcast signal compatible with the amplitude-modulated signal is divided into in-phase and quadrature components, and the in-phase component of the digital broadcast signal compatible with the amplitude-modulated signal is filtered before fast Fourier transform performed above a digital broadcast signal compatible with the amplitude modulated signal to form a first converted signal. 3. The method according to claim 2, characterized in that when filtering the in-phase component, the in-phase component is passed through a high-pass filter. 4. The method according to claim 1, characterized in that the digital broadcast signal compatible with the amplitude-modulated signal is weighted with a finite function and the guard interval is removed from the digital broadcast signal compatible with the amplitude-modulated signal before each of the fast Fourier transform operations, produced over a digital broadcast signal compatible with an amplitude modulated signal. 5. The method according to claim 1, characterized in that the second set of correction factors is calculated using the first set of correction factors and a known value for the center frequency of the first frequency spectrum, the calculation being performed by the interpolation method using linear interpolation, cubic spline interpolation, polynomial interpolation, interpolation based on the fast Fourier transform or approximation of a logarithmic curve. 6. The method according to claim 1, characterized in that the interpolation is performed with averaging time. 7. The method according to claim 1, characterized in that the interpolation is carried out over the real and imaginary components used to represent the first and second sets of correction factors. 8. The method of operation of a radio receiver for receiving a digital broadcast signal compatible with an amplitude-modulated signal containing an amplitude-modulated radio frequency signal having a first carrier modulated by an analog program signal in the first frequency spectrum, a set of digitally modulated carrier signals located in a frequency band covering the first frequency spectrum, and the first group of carrier signals subjected to digital modulation contains complementary carrier signals and located in the first frequency spectrum, and the second and third groups of carrier signals subjected to digital modulation, contain non-complementary carrier signals and are located outside the first frequency spectrum, namely, that they receive a digital broadcast signal compatible with the amplitude-modulated signal and are subjected to rapid conversion Fourier digital broadcast signal compatible with the amplitude-modulated signal, for the formation of the first converted signal representing non-complementary carriers, characterized in that the first converted signal is processed to generate the first corrected signal, by multiplying the first converted signal by the first correction vector, the first correction vector being formed by the first set of correction factors, the first set of correction factors used for non-complementary signals is updated, they are subjected to fast Fourier transform digital broadcast signal compatible with amplitude modulated signal for of the second converted signal representing complementary carriers, the second correction vector formed by the second set of correction coefficients is determined, the second set of correction coefficients being determined by interpolation using the coefficients of the first set of correction coefficients, the second converted signal is processed to generate the second corrected signal by multiplying the second converted signal on the second corrective vector and form the output signal in accordance with the first and second corrected signals. 9. The method according to claim 8, characterized in that the digital broadcast signal compatible with the amplitude-modulated signal is divided into in-phase and quadrature components and the in-phase component of the digital broadcast signal compatible with the amplitude-modulated signal is filtered before fast Fourier transform above a digital broadcast signal compatible with the amplitude modulated signal to form a first converted signal. 10. The method according to claim 9, characterized in that when filtering the in-phase component, the in-phase component is passed through a high-pass filter. 11. The method according to claim 8, characterized in that the digital broadcast signal compatible with the amplitude-modulated signal is weighed by a compact function and the guard interval is removed from the digital broadcast signal compatible with the amplitude-modulated signal before each of the fast Fourier transform operations, produced over a digital broadcast signal compatible with an amplitude modulated signal. 12. The method according to claim 8, characterized in that the second set of correction factors is calculated using the first set of correction factors and a known value for the center frequency of the first frequency spectrum, and the calculation is performed by interpolation using linear interpolation, cubic spline interpolation, polynomial interpolation, interpolation based on the fast Fourier transform or approximation of a logarithmic curve. 13. The method according to claim 8, characterized in that the interpolation is performed with averaging over time. 14. The method according to claim 8, characterized in that the interpolation is carried out on the real and imaginary components used to represent the first and second sets of correction factors. 15. Device for demodulating and correcting a digital broadcast signal compatible with an amplitude-modulated signal, comprising an amplitude-modulated radio frequency signal having a first carrier modulated by an analog program signal in the first frequency spectrum, a set of digitally modulated carrier signals located in a frequency band covering the first frequency spectrum, and the first group of carrier signals subjected to digital modulation contains complementary carrier signals and is located in the first frequency spectrum, and the second and third groups of digitally modulated carrier signals contain non-complementary carrier signals and are located outside the first frequency spectrum containing means (170) for fast Fourier transform of a digital broadcast signal compatible with the amplitude-modulated signal to generate the first converted signal representing non-complementary carriers, characterized in that it contains means (178) for processing the first converted signal to form the first the corrected signal by multiplying the first converted signal by the first correction vector, the first correction vector being formed by the first set of correction factors, means (186) for updating the first set of correction factors used for non-complementary signals, means (172) for fast Fourier transform of the digital broadcast signal compatible with amplitude modulated signal to form a second converted signal representing complement carriers, means (190) for determining the second correction vector formed by the second set of correction factors, and to determine the second set of correction factors, the tool interpolates the coefficients of the first set of correction coefficients, and means (188) for processing the second converted signal to generate the second corrected signal by multiplying the second converted signal to the second correction vector. 16. The device according to p. 15, characterized in that it comprises means (118) for separating non-complementary carrier signals into in-phase and quadrature components and means (174) for filtering the in-phase component of the non-complementary carrier signal. 17. The device according to clause 16, wherein the filtering means comprises a high-pass filter. 18. The device according to p. 15, characterized in that it comprises means (171, 173) for weighing with a finite function a digital broadcast signal compatible with the amplitude-modulated signal and for removing the guard interval from the digital broadcast signal compatible with the amplitude-modulated signal. 19. The device according to p. 15, characterized in that for calculating the second set of correction factors, the first set of correction factors and the known value for the center frequency of the first frequency spectrum are used, the calculation being performed by the interpolation method using linear interpolation, cubic spline interpolation, polynomial interpolation, interpolation based on fast Fourier transform or approximation of a logarithmic curve. 20. The device according to clause 15, wherein the interpolation is accompanied by averaging over time. 21. The device according to p. 15, characterized in that the interpolation is performed on the real and imaginary components used to represent the first and second sets of correction factors. 22. A radio receiver for receiving a digital broadcast signal compatible with an amplitude-modulated signal, comprising an amplitude-modulated radio frequency signal having a first carrier modulated by an analog program signal in the first frequency spectrum, a set of digitally modulated carrier signals located in a frequency band spanning the first frequency spectrum, and the first group of carrier signals subjected to digital modulation contains complementary carrier signals and is located in the first part the frequency spectrum, and the second and third groups of digitally modulated carrier signals, contain non-complementary carrier signals and are located outside the first frequency spectrum, comprising means (170) for fast Fourier transform of the digital broadcast signal compatible with the amplitude-modulated signal to generate the first converted signal representing non-complementary carriers, characterized in that it comprises means (110) for receiving a digital broadcast signal compatible with the amplitude-modulated signal ohm, the means (178) for processing the first converted signal to generate the first corrected signal by multiplying the first converted signal by the first correction vector, the first correction vector being formed by the first set of correction factors, the means (186) for updating the first set of correction factors used for non-complementary signals, means (172) for fast Fourier transform of a digital broadcast signal compatible with the amplitude-modulated signal ohm, for generating a second converted signal representing complementary carriers, means (190) for determining a second correction vector formed by a second set of correction factors, and for determining a second set of correction coefficients, the tool interpolates the coefficients of the first set of correction factors, means (188) for processing the second converted signal to generate a second corrected signal by multiplying the second converted second signal to the second correction vector, and means (142) for generating an output signal in accordance with the first and second corrected signals. 23. The radio receiver according to claim 22, characterized in that it comprises means (118) for separating non-complementary carrier signals into in-phase and quadrature components and means (174) for filtering the in-phase component of the non-complementary carrier signal. 24. The radio receiver according to item 23, wherein the filtering means comprises a high-pass filter. 25. The radio receiver according to claim 23, characterized in that it comprises means (171, 173) for weighing with a compact function a digital broadcast signal compatible with the amplitude-modulated signal and for removing the guard interval from the digital broadcast signal compatible with the amplitude-modulated signal. 26. The radio receiver according to claim 23, wherein the first set of correction factors and the known value for the center frequency of the first frequency spectrum are used to calculate the second set of correction factors, moreover, this calculation is performed by the interpolation method using linear interpolation, cubic spline interpolation, polynomial interpolation, interpolation based on fast Fourier transform or approximation of a logarithmic curve. 27. The radio receiver according to item 23, wherein the interpolation is accompanied by averaging over time. 28. The radio receiver according to claim 23, wherein the interpolation is performed over the real and imaginary components used to represent the first and second sets of correction factors.