Coherent AM demodulator using a weighted LSB/USB sum for interference mitigation

US 7,127,008 B2
Filed: 02/24/2003
Issued: 10/24/2006
Est. Priority Date: 02/24/2003
Status: Expired due to Term

First Claim

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1. A method of processing an AM radio signal comprising the steps of:

receiving an AM radio signal including an upper sideband portion and a lower sideband portion;

passing the upper sideband portion and the lower sideband portion through a plurality of bandpass filters to produce a plurality of filtered signals;

demodulating the plurality of filtered signals to produce a demodulated upper sideband signal and a demodulated lower sideband signal;

weighting the demodulated upper sideband signal and the demodulated lower sideband signal using a weighting factor that varies in response to signal to noise ratio in the demodulated upper sideband signal and the demodulated lower sideband signal to produce a weighted demodulated upper sideband signal and a weighted demodulated lower sideband signal; and

combining the weighted demodulated upper sideband signal and the weighted demodulated lower sideband signal to produce an output signal.

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Abstract

A method of processing an AM radio signal comprises the step of receiving an AM radio signal including an upper sideband portion and a lower sideband portion, demodulating the upper sideband portion and the lower sideband portion to produce a demodulated upper sideband signal and a demodulated lower sideband signal, weighting the demodulated upper sideband signal and the demodulated lower sideband signal in response to noise power to produce a weighted demodulated upper sideband signal and a weighted demodulated lower sideband signal, and combining the weighted demodulated upper sideband signal and the weighted demodulated lower sideband signal to produce an output signal. Demodulators which process AM radio signals in accordance with the method, and receivers incorporating the demodulators, are also included.

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38 Claims

1. A method of processing an AM radio signal comprising the steps of:
- receiving an AM radio signal including an upper sideband portion and a lower sideband portion;
  
  passing the upper sideband portion and the lower sideband portion through a plurality of bandpass filters to produce a plurality of filtered signals;
  
  demodulating the plurality of filtered signals to produce a demodulated upper sideband signal and a demodulated lower sideband signal;
  
  weighting the demodulated upper sideband signal and the demodulated lower sideband signal using a weighting factor that varies in response to signal to noise ratio in the demodulated upper sideband signal and the demodulated lower sideband signal to produce a weighted demodulated upper sideband signal and a weighted demodulated lower sideband signal; and
  
  combining the weighted demodulated upper sideband signal and the weighted demodulated lower sideband signal to produce an output signal.
- View Dependent Claims (2, 3, 4, 5, 6, 7)
- - 2. The method of claim 1, further comprising the step of:
    - determining a noise power of the demodulated upper sideband signal and the demodulated lower sideband signal prior to the step of weighting the demodulated upper sideband signal and the demodulated lower sideband signal.
  - 3. The method of claim 2, wherein the step of determining the noise power of the demodulated upper sideband signal and the demodulated lower sideband signal comprises the steps of:
    - cross-correlating a quadrature component of the demodulated upper sideband signal with the demodulated upper sideband signal; and
      
      cross-correlating a quadrature component of the demodulated lower sideband signal with the demodulated lower sideband signal.
  - 4. The method of claim 3, wherein:
    - the step of cross-correlating a quadrature component of the demodulated upper sideband signal with the demodulated upper sideband signal comprises the steps of shifting the quadrature component of the demodulated upper sideband signal by 90° and
      
      multiplying the shifted quadrature component of the demodulated upper sideband signal by the demodulated upper sideband signal; and
      
      the step of cross-correlating a quadrature component of the demodulated lower sideband signal with the demodulated lower sideband signal comprises the steps of shifting the quadrature component of the demodulated lower sideband signal by 90° and
      
      multiplying the shifted quadrature component of the demodulated lower sideband signal by the demodulated lower sideband signal.
  - 5. The method of claim 1, wherein the weighting factor is a function of the variance of interference plus noise.
  - 6. The method of claim 1, wherein the step of combining the weighted demodulated upper sideband signal and the weighted demodulated lower sideband signal further comprises the step of:
    - frequency selective combining of the weighted demodulated upper sideband signal and the weighted demodulated lower sideband signal.
  - 7. The method of claim 1, wherein the step of demodulating the plurality of filtered signals to produce a demodulated upper sideband signal and a demodulated lower sideband signal comprises the steps of:
    - multiplying a Hilbert Transform of an imaginary component of the radio signal by a weighted correction signal to obtain a weighted signal; and
      
      subtracting the weighted signal from a coherent double sideband signal.

8. A method of processing an AM radio signal comprising the steps of:
- receiving an AM radio signal including an upper sideband portion and a lower sideband portion;
  
  demodulating the upper sideband portion and the lower sideband portion to produce a demodulated upper sideband signal and a demodulated lower sideband signal;
  
  weighting the demodulated upper sideband signal and the demodulated lower sideband signal using a weighting factor that varies in response to signal to noise ratio in the demodulated upper sideband signal and the demodulated lower sideband signal to produce a weighted demodulated upper sideband signal and a weighted demodulated lower sideband signal; and
  
  combining the weighted demodulated upper sideband signal and the weighted demodulated lower sideband signal to produce an output signal;
  
  wherein the step of weighting the demodulated upper sideband signal and the demodulated lower sideband comprises the steps of multiplying the demodulated upper sideband signal by the weighting factor; and
  
  multiplying the demodulated lower sideband signal by one minus the weighting factor.
- View Dependent Claims (9)
- - 9. The method of claim 8, further comprising the step of:
    - single sideband filtering the AM radio signal prior to the step of demodulating the upper sideband portion and the lower sideband portion.

10. A demodulator for processing an AM radio signal comprising:
- means for demodulating the upper sideband portion and the lower sideband portion of an AM radio signal to produce a demodulated upper sideband signal and a demodulated lower sideband signal;
  
  means for weighting the demodulated upper sideband signal and the demodulated lower sideband signal using a weighting factor that varies in response to signal to noise ratio in the demodulated upper sideband signal and the demodulated lower sideband signal to produce a weighted demodulated upper sideband signal and a weighted demodulated lower sideband signal; and
  
  means for combining the weighted demodulated upper sideband signal and the weighted demodulated lower sideband signal;
  
  wherein the means for weighting the demodulated upper sideband signal and the demodulated lower sideband signal comprises means for multiplying the demodulated upper sideband signal by the weighting factor, and means for multiplying the demodulated lower sideband signal by one minus the weighting factor.
- View Dependent Claims (11, 12, 13, 14, 15)
- - 11. The demodulator of claim 10, further comprising:
    - means for determining a noise power of the demodulated upper sideband signal and the demodulated lower sideband signal prior to weighting the demodulated upper sideband signal and the demodulated lower sideband signal.
  - 12. The demodulator of claim 11, wherein the means for determining the noise power of the demodulated upper sideband signal and the demodulated lower sideband signal comprises:
    - means for cross-correlating a quadrature component of the demodulated upper sideband signal with the demodulated upper sideband signal; and
      
      means for cross-correlating a quadrature component of the demodulated lower sideband signal with the demodulated lower sideband signal.
  - 13. The demodulator of claim 12, wherein:
    - the means for cross-correlating the quadrature component of the demodulated upper sideband signal with the demodulated upper sideband signal comprises means for shifting the quadrature component of the demodulated upper sideband signal by 90° and
      
      for multiplying the shifted quadrature component of the demodulated upper sideband signal by the demodulated upper sideband signal; and
      
      the means for cross-correlating the quadrature component of the demodulated lower sideband signal with the demodulated lower sideband signal comprises means for shifting the quadrature component of the demodulated lower sideband signal by 90° and
      
      for multiplying the shifted quadrature component of the demodulated lower sideband signal by the demodulated lower sideband signal.
  - 14. The demodulator of claim 10, further comprising:
    - means for filtering the upper sideband portion and the lower sideband portion.
  - 15. The demodulator of claim 10, wherein the means for demodulating the upper sideband portion and the lower sideband portion of an AM radio signal to produce a demodulated upper sideband signal and a demodulated lower sideband signal comprises:
    - means for multiplying a Hilbert Transform of an imaginary component of the radio signal by a weighted correction signal to obtain a weighted signal; and
      
      means for subtracting the weighted signal from a coherent double sideband signal.

16. A receiver for processing an AM radio signal comprising:
- means for receiving an AM radio signal including an upper sideband portion and a lower sideband portion;
  
  means for demodulating the upper sideband portion and the lower sideband portion to produce a demodulated upper sideband signal and a demodulated lower sideband signal;
  
  means for weighting the demodulated upper sideband signal and the demodulated lower sideband signal using a weighting factor that varies in response to signal to noise ratio in the demodulated upper sideband signal and the demodulated lower sideband signal to produce a weighted demodulated upper sideband signal and a weighted demodulated lower sideband signal; and
  
  means for combining the weighted demodulated upper sideband signal and the weighted demodulated lower sideband signal to produce an output signal;
  
  wherein the means for weighting the demodulated upper sideband signal and the demodulated lower sideband sianal comprises means for multiplying the demodulated upper sideband signal by the weighting factor, and means for multiplying the demodulated lower sideband signal by one minus the weighting factor.
- View Dependent Claims (17, 18, 19, 20, 21, 22)
- - 17. The receiver of claim 16, further comprising:
    - means for single sideband filtering the AM radio signal prior to demodulating the upper sideband portion and the lower sideband portion.
  - 18. The receiver of claim 16, further comprising:
    - means for determining a noise power of the demodulated upper sideband signal and the demodulated lower sideband signal prior to weighting the demodulated upper sideband signal and the demodulated lower sideband signal.
  - 19. The receiver of claim 18, wherein the means for determining the noise power of the demodulated upper sideband signal and the demodulated lower sideband signal comprises:
    - means for cross-correlating a quadrature component of the demodulated upper sideband signal with the demodulated upper sideband signal; and
      
      means for cross-correlating a quadrature component of the demodulated lower sideband signal with the demodulated lower sideband signal.
  - 20. The receiver of claim 19, wherein:
    - the means for cross-correlating the quadrature component of the demodulated upper sideband signal with the demodulated upper sideband signal comprises means for shifting the quadrature component of the demodulated upper sideband signal by 90° and
      
      for multiplying the shifted quadrature component of the demodulated upper sideband signal by the demodulated upper sideband signal; and
      
      the means for cross-correlating the quadrature component of the demodulated lower sideband signal with the demodulated lower sideband signal comprises means for shifting the quadrature component of the demodulated lower sideband signal by 90° and
      
      for multiplying the shifted quadrature component of the demodulated lower sideband signal by the demodulated lower sideband signal.
  - 21. The receiver of claim 16, further comprising:
    - means for filtering the upper sideband portion and a lower sideband portion.
  - 22. The receiver of claim 16 wherein the means for demodulating the upper sideband portion and the lower sideband portion to produce a demodulated upper sideband signal and a demodulated lower sideband signal comprises:
    - means for multiplying a Hilbert Transform of an imaginary component of the radio signal by a weighted correction signal to obtain a weighted signal, and means for subtracting the weighted signal from a coherent double sideband signal.

23. A demodulator for processing an AM radio signal comprising:
- a circuit for demodulating the upper sideband portion and the lower sideband portion of an AM radio signal to produce a demodulated upper sideband signal and a demodulated lower sideband signal;
  
  a circuit for weighting the demodulated upper sideband signal and the demodulated lower sideband signal using a weighting factor that varies in response to signal to noise ratio in the demodulated upper sideband signal and the demodulated lower sideband signal to produce a weighted demodulated upper sideband signal and a weighted demodulated lower sideband signal; and
  
  a combiner for combining the weighted demodulated upper sideband signal and the weighted demodulated lower sideband signal;
  
  p1 wherein the circuit for weighting the demodulated upper sideband signal and the demodulated lower sideband signal multiplies the demodulated upper sideband signal by the weighting factor, and multiplies the demodulated lower sideband signal by one minus the weighting factor.
- View Dependent Claims (24, 25)
- - 24. The demodulator of claim 23, further comprising:
    - a circuit for cross-correlating a quadrature component of the demodulated upper sideband signal with the demodulated upper sideband signal; and
      
      a circuit for cross-correlating a quadrature component of the demodulated lower sideband signal with the demodulated lower sideband signal.
  - 25. The demodulator of claim 24, wherein:
    - the circuit for cross-correlating the quadrature component of the demodulated upper sideband signal with the demodulated upper sideband signal comprises a first phase shifter for shifting the quadrature component of the demodulated upper sideband signal by 90° and
      
      for multiplying the shifted quadrature component of the demodulated upper sideband signal by the demodulated upper sideband signal; and
      
      the circuit for cross-correlating the quadrature component of the demodulated lower sideband signal with the demodulated lower sideband signal comprises a second phase shifter for shifting the quadrature component of the demodulated lower sideband signal by 90° and
      
      for multiplying the shifted quadrature component of the demodulated lower sideband signal by the demodulated lower sideband signal.

26. A receiver for processing an AM radio signal comprising:
- an input for receiving an AM radio signal including an upper sideband portion and a lower sideband portion;
  
  a demodulator for demodulating the upper sideband portion and the lower sideband portion to produce a demodulated upper sideband signal and a demodulated lower sideband signal;
  
  a circuit for weighting the demodulated upper sideband signal and the demodulated lower sideband signal using a weighting factor that varies in response to signal to noise ratio in the demodulated upper sideband signal and the demodulated lower sideband signal to produce a weighted demodulated upper sideband signal and a weighted demodulated lower sideband signal; and
  
  a combiner for combining the weighted demodulated upper sideband signal and the weighted demodulated lower sideband signal to produce an output signal;
  
  wherein the circuit for weighting the demodulated upper sideband signal and the demodulated lower sideband signal multiplies the demodulated upper sideband signal by the weighting factor, and multiplies the demodulated lower sideband signal by one minus the weighting factor.
- View Dependent Claims (27, 28)
- - 27. The receiver of claim 26, further comprising:
    - a circuit for cross-correlating a quadrature component of the demodulated upper sideband signal with the demodulated upper sideband signal; and
      
      a circuit for cross-correlating a quadrature component of the demodulated lower sideband signal with the demodulated lower sideband signal.
  - 28. The receiver of claim 27, wherein:
    - the circuit for cross-correlating the quadrature component of the demodulated upper sideband signal with the demodulated upper sideband signal comprises a first phase shifter for shifting the quadrature component of the demodulated upper sideband signal by 90° and
      
      for multiplying the shifted quadrature component of the demodulated upper sideband signal by the demodulated upper sideband signal; and
      
      the circuit for cross-correlating the quadrature component of the demodulated lower sideband signal with the demodulated lower sideband signal comprises a second phase shifter for shifting the quadrature component of the demodulated lower sideband signal by 90° and
      
      for multiplying the shifted quadrature component of the demodulated lower sideband signal by the demodulated lower sideband signal.

29. A method of processing an AM radio signal comprising the steps of:
- splitting the AM radio signal into real and imaginary components;
  
  taking a Hilbert Transform of the imaginary component to produce a transformed signal;
  
  using the real component and the transformed signal to calculate a weighting factor;
  
  mixing the transformed signal with the weighting factor to produce a weighted transformed signal; and
  
  combining the weighted transformed signal and the real component to produce an output signal.
- View Dependent Claims (30, 31, 32, 33, 34)
- - 30. The method of claim 29, further comprising the steps of:
    - delaying the transformed signal prior to mixing the transformed signal with the weighting factor; and
      
      delaying the real component prior to combining the weighted transformed signal and the real component.
  - 31. The method of claim 29, wherein:
    - the real and imaginary components are separated at baseband.
  - 32. The method of claim 29, wherein:
    - the weighting factor includes a term for forcing the weight to zero for double sideband modulation.
  - 33. The method of claim 29, further comprising the step of:
    - frequency-selective combining upper sideband and lower sideband portions of the AM radio signal.
  - 34. The method of claim 29, further comprising the step of:
    - reducing post-detection bandwidth of the signal as noise increases.

35. A receiver for processing an AM radio signal comprising:
- a splitter for splitting the AM radio signal into real and imaginary components;
  
  a processor for taking a Hilbert Transform of the imaginary component to produce a transformed signal and using the real component and the transformed signal to calculate a weighting factor;
  
  a mixer for mixing the transformed signal with the weighting factor to produce a weighted transformed signal; and
  
  a combiner for combining the weighted transformed signal and the real component to produce an output signal.
- View Dependent Claims (36, 37, 38)
- - 36. The receiver of claim 35, further comprising:
    - a first delay circuit for delaying the transformed signal prior to mixing the transformed signal with the weighting factor; and
      
      a second delay circuit for delaying the real component prior to combining the weighted transformed signal and the real component.
  - 37. The receiver of claim 35, wherein:
    - the real and imaginary components are separated at baseband.
  - 38. The receiver of claim 35, wherein:
    - the weighting factor includes a term for forcing the weighting factor to zero for double sideband demodulation.

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Current Assignee
iBiquity Digital Corporation (Xperi Inc.)
Original Assignee
iBiquity Digital Corporation (Xperi Inc.)
Inventors
Kroeger, Brian William
Primary Examiner(s)
Fan, Chieh M.
Assistant Examiner(s)
PUENTE, EVA YI ZHENG

Application Number

US10/373,484
Publication Number

US 20040165680A1
Time in Patent Office

1,338 Days
Field of Search

375/321, 375/270, 375/285, 375/230, 375/348, 375/347, 375/322, 375/357, 375/222, 375/235, 375/316, 455/126, 455/296, 381/15, 370/529
US Class Current

375/321
CPC Class Codes

H03D 1/04 Modifications of demodulato...

H03D 1/2245 using two quadrature channe...

Coherent AM demodulator using a weighted LSB/USB sum for interference mitigation

First Claim

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38 Claims

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Coherent AM demodulator using a weighted LSB/USB sum for interference mitigation

First Claim

14 Assignments

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Accused Products

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Abstract

Citations

38 Claims

Specification

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