RU2000111467A - SYSTEM AND METHOD FOR SMOOTHING PERIODIC INTERRUPTIONS IN THE AUDIO SIGNAL BROADCASTING SYSTEM - Google Patents

Claims (48)

A system for smoothing periodic interruptions in an audio signal broadcasting system, comprising: an audio signal source, transmission means, the first input of which is connected to an audio signal source for modulating at least one first carrier signal with an audio signal for broadcasting the main radio signal, the first delay means, input which is connected to an audio signal source for introducing into the audio signal the first predetermined time delay in order to form a delayed backup audio signal at its output, the output d is connected to the second input of the transmission means for modulating at least one second carrier signal with a delayed backup audio signal to simultaneously broadcast the delayed backup radio signal together with the main radio signal, reception means for receiving the main radio signal and the delayed backup radio signal, wherein the receiving means demodulates the main radio signal by outputting an audio signal at its first output, and demodulating a delayed backup radio signal, producing a delayed backup audio signal at its second output, the reception means includes means for detecting a deterioration in the reception quality of the main radio signal, wherein the deterioration detection means provides a quality measurement signal to a third output of the reception means, a second delay means, the input of which is connected to the first output of the reception means for an audio signal of a second predetermined time delay in order to form at its output a delayed main audio signal, the second predetermined time delay being practically equal to the first a specified time delay, a mixing means, the first input of which is connected to the output of the second delay means, and the second and third inputs are connected, respectively, to the second and third outputs of the reception means for combining the first weight coefficient with the delayed main audio signal and the second weight coefficient with the delayed backup an audio signal and combining the weighted delayed primary audio signal with the weighted delayed backup audio signal to form a composite audio signal, the first the second weight coefficient smoothly changes from the first value to the second value, provided that the quality measurement signal is less than a predetermined threshold value, and the second weight coefficient smoothly changes from the second value to the first value, provided that the quality measurement signal is less than a predetermined threshold value, and the output means an audio signal connected to the mixing means for converting the composite audio signal into an acoustic signal.  2. The system according to claim 1, characterized in that the first time delay is greater than or equal to 2.0 s.  3. The system according to claim 1, characterized in that it further includes a digital encoding means, the input of which is connected to an audio signal source, and the output is connected to the first input of the transmission medium.  4. The system according to p. 3, characterized in that it further includes a digital decoding means, the input of which is connected to the output of the second delay means, and the output is connected to the first input of the mixing means.  5. The system according to p. 4, characterized in that the means of detecting deterioration in the reception quality of the main radio signal includes means for determining one or more parameters selected from the group consisting of signal-to-noise ratio, bit error rate, signal power level and cyclic control redundancy.  6. The system according to claim 4, characterized in that the second carrier is at least one compacted subcarrier of the FM stereo signal in the spectrum of the FM broadcast signal.  7. The system of claim 6, wherein the first carrier is at least one subcarrier spaced at least 53 kHz from the average frequency of the spectrum of the FM broadcast signal.  8. The system of claim 6, wherein the first carrier is at least one subcarrier of the RFKS (Regulation of the Federal Communications Commission) of the FM broadcast signal spectrum.  9. The system according to claim 1, characterized in that the second carrier is at least one high-frequency signal in the spectrum of the FM broadcast signal.  10. The system according to p. 9, characterized in that the first carrier is at least one subcarrier of the RFKS spectrum of the FM broadcast signal.  11. The system according to claim 1, characterized in that the first weight coefficient is a function that varies smoothly from 1.0 to 0.0, provided that the quality measurement signal is less than a predetermined threshold value, and the second weight coefficient is a function that smoothly changes from 0.0 to 1.0 provided that the quality measurement signal is less than a predetermined threshold value.  12. A method for smoothing periodic interruptions in broadcasting an audio signal, comprising the steps of (a) providing an audio signal, (b) modulating at least one first high frequency signal with an audio signal to transmit an audio signal as a first radio signal; (c) introducing into the audio signal a first predetermined time delay to generate a delayed backup audio signal, (d) modulating at least one second high frequency signal with a delayed backup audio signal to transmit the delayed backup audio signal as a second radio signal, (e) receiving the first and second radio signals and extracting the audio signal and the delayed backup audio signal, (f) measuring the reception quality of at least the first radio signal, (g) introducing the second task into the extracted audio signal time delay for generating the delayed main audio signal, the second time delay being almost equal to the first time delay, (h) setting the first weight coefficient, the first weight coefficient being 1.0, when the quality measurement result is not less than a given threshold value, and changes smoothly to 0.0 during a given period of time when the result of the quality measurement is less than a predetermined threshold value, (i) setting a second weight coefficient, and the second weight coefficient is 0.0 when the quality measurement result is not less than a predetermined threshold value, and smoothly changes to 1.0 within a predetermined period of time, when the quality measurement result is less than a predetermined threshold value, (j) combining the first weight coefficient with the delayed main audio signal and combining the second weight coefficient with the delayed backup an audio signal, (k) combining the weighted delayed primary audio signal with the weighted delayed backup audio signal to form a composite audio signal And (1) providing an audio output circuit and feeding it a composite audio signal.  13. The method according to p. 12, characterized in that the step of modulating at least one first high-frequency signal includes a step of digitally encoding an audio signal.  14. The method according to p. 13, wherein the receiving step includes the step of decoding the extracted audio signal.  15. The method according to p. 12, characterized in that the step of introducing a first predetermined time delay includes the step of selecting a delay time in the range of about 2.0 to 5.0 s.  16. The method according to p. 14, characterized in that the step of modulating at least one first high-frequency signal includes the step of modulating at least one carrier, spaced approximately 130-199 kHz from the average frequency of the signal spectrum FM broadcasts, digitally encoded audio.  17. The method according to p. 16, characterized in that the step of modulating at least one second high-frequency signal includes the step of modulating at least one high-frequency signal in the spectrum of the FM broadcast signal with a delayed backup audio signal.  18. The method according to p. 16, characterized in that the step of modulating at least one second high-frequency signal includes the step of modulating at least one RFCX subcarrier of the spectrum of the FM broadcast signal with a delayed backup audio signal.  19. The method according to p. 12, characterized in that the quality measurement step includes the step of determining one or more parameters selected from the group consisting of signal-to-noise ratio, bit error rate, signal power level, and cyclic redundancy control.  20. A method for smoothing periodic interruptions in a digital audio broadcasting system in a main channel band in which each channel includes at least one carrier signal modulated by an analog audio signal and a plurality of subcarriers modulated by a digital representation of the analog audio signal, comprising the steps (a) introducing a predetermined first time delay into the analog audio signal before modulating at least one carrier signal, wherein the analog audio signal has a delay relative to the digital smooth representation of the analog audio signal, (b) providing a receiver for receiving at least one modulated carrier signal and modulated subcarriers to restore the delayed analog audio signal and digital representation of the analog audio signal, (c) detecting a predetermined level of degradation in the quality of the digital representation of the analog audio signal , (d) introducing a predetermined second time delay into the digital representation of the analog audio signal and converting the delayed digital suppressing the analog audio signal to generate the main audio signal, and (e) substituting the delayed analog audio signal instead of the main audio signal when a predetermined level of quality deterioration is detected.  21. The method of broadcasting in the band of the main channel, which includes the steps of providing a first signal for broadcasting, providing a second signal for broadcasting, introducing a delay in one of the two signals, the first or second, relative to the other of the first and second signals, modulating the first carrier with the first of the first and second signals, modulating with orthogonal frequency division of the set of subcarriers by the second of the first and second signals, the set of subcarriers being located in the upper and lower side bands in relation ju to the first carrier, combining the first carrier and a plurality of subcarriers to form a composite signal, and transmit the composite signal.  22. The broadcasting method in the band of the main channel according to p. 21, characterized in that the first signal is an analog signal, and the second signal is a digital signal.  23. The broadcasting method in the band of the main channel according to claim 21, characterized in that the first signal is a digital signal, and the second signal is an analog signal.  24. The method of broadcasting in the band of the main channel according to p. 21, characterized in that the first signal and the second signal represent the same audio information.  25. The broadcasting method in the band of the main channel according to claim 21, characterized in that the first carrier is modulated in frequency, the upper side band occupies a region of about 130 kHz to 199 kHz with respect to the first carrier, and the lower side band occupies a region of approximately -130 kHz to -199 kHz relative to the first carrier.  26. The method of broadcasting in the band of the main channel according to p. 25, characterized in that each of the side bands, upper and lower, contains 95 subcarriers.  27. The broadcast transmitter in the band of the main channel, including means for providing a first signal for broadcasting, means for providing a second signal for broadcasting, means for introducing a delay into one of two signals, the first or second, relative to the other of the first or second signals, means for modulating the first carrier first of the first and second signals, modulation means with orthogonal frequency division of the set of subcarriers to the second of the first and second signals, the set of subcarriers being extending in the upper and lower sidebands with respect to the first carrier, means for combining the first carrier and the totality of subcarriers to form a composite signal, and means for transmitting the composite signal.  28. The broadcast transmitter in the band of the main channel according to p. 21, characterized in that the first signal is an analog signal, and the second signal is a digital signal.  29. The broadcast transmitter in the band of the main channel according to p. 21, characterized in that the first signal is a digital signal, and the second signal is an analog signal.  30. The broadcast transmitter in the band of the main channel according to p. 27, characterized in that the first signal and the second signal are the same audio information.  31. The broadcast transmitter in the main channel band according to claim 27, wherein the first carrier is modulated in frequency, the upper side band occupies an area of about 130 kHz to 199 kHz with respect to the first carrier, and the lower side band occupies an area of approximately -130 kHz to -199 kHz relative to the first carrier.  32. The broadcast transmitter in the band of the main channel according to p. 31, characterized in that each of the side bands, upper and lower, contains 95 subcarriers.  33. A method of receiving a broadcast signal in a band of a main channel including a first carrier modulated by a first signal, a set of subcarriers located in the upper and lower side bands with respect to the first carrier, to be broadcast and modulated with orthogonal frequency division by a second signal, according to which one of the signals, the first or second, receives a delay relative to the other of the first and second signals, the method includes the steps of demodulating the first carrier to form the first demodule signal, demodulating the totality of subcarriers to generate a second demodulated signal, introducing a delay into one of the demodulated signals, the first or second, relative to the other from the first and second demodulated signals, selecting one of the demodulated signals, the first or second, for use in generating the output signal, and generating an output signal depending on the selection of one of the first or second demodulated signals.  34. The method of receiving a broadcast signal in the band of the main channel according to claim 33, wherein the first signal is an analog signal, and the second signal is a digital signal.  35. The method of receiving a broadcast signal in the band of the main channel according to claim 33, wherein the first signal is a digital signal, and the second signal is an analog signal.  36. The method of receiving a broadcast signal in the band of the main channel according to p. 33, characterized in that the first signal and the second signal are the same audio information.  37. The method of receiving a broadcast signal in the band of the main channel according to claim 33, wherein the first carrier is modulated in frequency, the upper side band occupies an area of about 130 kHz to 199 kHz with respect to the first carrier, and the lower side band occupies an area from about -130 kHz to -199 kHz relative to the first carrier.  38. The method of receiving a broadcast signal in the band of the main channel according to claim 37, characterized in that each of the side bands, upper and lower, contains 95 subcarriers.  39. The method of receiving a broadcast signal in the band of the main channel according to claim 33, wherein the step of selecting one of the first or second demodulated signals for use in generating the output signal includes the step of detecting a deterioration in the quality of one of the first or second demodulated signals by determining one or more parameters selected from the group consisting of signal-to-noise ratio, bit error rate, signal power level, and cyclic redundancy control.  40. The method of receiving a broadcast signal in the band of the main channel according to claim 33, characterized in that the step of selecting one of the first or second demodulated signals for use in generating the output signal includes the steps of issuing a quality measurement signal representing the first signal, setting the first weight coefficient when the quality measurement result is less than a predetermined threshold value, setting a second weight coefficient when the quality measurement result is less than a predetermined threshold value, combining a new weighting factor with the first signal and combining the second weighting factor with the second signal, and combining the weighted first signal with the weighted second signal to form a composite audio signal, and supplying the composite audio signal to the output.  41. The receiver of the broadcast signal in the band of the main channel, including the first carrier, modulated by the first signal, a set of subcarriers located in the upper and lower side bands relative to the first carrier, to be broadcast and modulated with orthogonal frequency division by a second signal, in which one of the signals, the first or second, receives a delay relative to the other of the first and second signals, the receiver includes means for demodulating the first carrier to form the first demodulated of the second signal, means for demodulating the totality of subcarriers for generating a second demodulated signal, means for introducing a delay into one of the two demodulated signals, the first or second, relative to the other of the first and second demodulated signals, means for selecting one of two demodulated signals, the first or second, for use when creating the output signal, and means for generating the output signal depending on the choice of one of the first or second demodulated signals.  42. The receiver of the broadcast signal in the band of the main channel according to p. 41, characterized in that the first signal is an analog signal, and the second signal is a digital signal.  43. The receiver of the broadcast signal in the band of the main channel according to p. 41, characterized in that the first signal is a digital signal, and the second signal is an analog signal.  44. The receiver of the broadcast signal in the band of the main channel according to p. 41, characterized in that the first signal and the second signal represents the same audio information.  45. The broadcast signal receiver in the main channel band according to claim 31, wherein the first carrier is modulated in frequency, the upper side band occupies an area of about 130 kHz to 199 kHz with respect to the first carrier, and the lower side band occupies an area of about , from -130 kHz to -199 kHz relative to the first carrier.  46. The receiver of the broadcast signal in the band of the main channel according to p. 45, characterized in that each of the side bands, upper and lower, contains 95 subcarriers.  47. The broadcast signal receiver in the main channel band according to claim 41, characterized in that the means for selecting one of the first or second demodulated signals for use in generating the output signal includes means for detecting a deterioration in the quality of one of the first or second demodulated signals by determining one or several parameters selected from the group consisting of signal-to-noise ratio, bit error rate, signal power level and cyclic redundancy control.  48. The receiver of the broadcast signal in the band of the main channel according to p. 41, characterized in that the means for selecting one of the first or second demodulated signals for use in generating the output signal includes means for issuing a quality measurement signal representing the first signal, means for setting the first weight coefficient when the quality measurement result is less than a predetermined threshold value, a means for setting a second weight coefficient when the quality measurement result is less than a predetermined threshold value and means for combining the first weighting coefficient with the first signal and combining the second weighting factor with the second signal, and means for combining the weighted first signal with the weighted second signal to form a composite audio signal, and means for supplying the composite audio signal to the output.