Communication system with end-to-end quadrature balance control
First Claim
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1. In a digital communication system, a method for ameliorating a bit error rate for a data stream transmitted from a first site to a second site, said method comprising:
- a) receiving a communication signal at said second site, said communication signal conveying said data stream;
b) generating a signal quality statistic at said second site, said signal quality statistic being determined from said communication signal;
c) formulating a command at said second site in response to said signal quality statistic;
d) transmitting said command at said second site;
e) receiving said command at said first site;
f) adjusting, at said first site, a quadrature balance signal in response to said command, said quadrature balance signal altering one of first and second quadrature-phase signals relative to the other, said first and second quadrature-phase signals collectively conveying said data stream;
g) combining said quadrature-phase signals at said first site to form said communication signal; and
h) transmitting said communication signal at said first site.
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Abstract
A communication system (10) includes a transmitter (20) having programmable signals (46, 58, 60, 80) which can be used to adjust transmitter-caused quadrature-phase signal imbalances. A receiver (18) of the system (10) is remotely located from the transmitter (20) and generates a signal quality statistic (102, 112) that is monitored in a slow-tracking feedback loop to formulate commands which indicate how to program the programmable signals (46, 58, 60, 80). This receiver (18) performs its signal quality statistic monitoring while a data stream (36) is being extracted from a received communication signal.
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Citations
20 Claims
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1. In a digital communication system, a method for ameliorating a bit error rate for a data stream transmitted from a first site to a second site, said method comprising:
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a) receiving a communication signal at said second site, said communication signal conveying said data stream;
b) generating a signal quality statistic at said second site, said signal quality statistic being determined from said communication signal;
c) formulating a command at said second site in response to said signal quality statistic;
d) transmitting said command at said second site;
e) receiving said command at said first site;
f) adjusting, at said first site, a quadrature balance signal in response to said command, said quadrature balance signal altering one of first and second quadrature-phase signals relative to the other, said first and second quadrature-phase signals collectively conveying said data stream;
g) combining said quadrature-phase signals at said first site to form said communication signal; and
h) transmitting said communication signal at said first site. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14)
in a first quadrature balance signal alteration process, said formulating activity c), said transmitting activity d), said receiving activity e) and said adjusting activity f) are performed a plurality of times to alter relative phase between said first and second quadrature-phase signals;
in a second quadrature balance signal alteration process, said formulating activity c), said transmitting activity d), said receiving activity e) and said adjusting activity f) are performed a plurality of times to alter relative amplitude between said first and second quadrature-phase signals;
in a third quadrature balance signal alteration process, said formulating activity c), said transmitting activity d), said receiving activity e) and said adjusting activity f) are performed a plurality of times to alter a DC offset of said first quadrature-phase signal;
in a fourth quadrature balance signal alteration process, said formulating activity c), said transmitting activity d), said receiving activity e) and said adjusting activity f) are performed a plurality of times to alter a DC offset of said second quadrature-phase signal; and
said first, second, third, and fourth quadrature balance signal alteration processes continuously repeat while performing said extracting activity.
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8. A method for ameliorating the bit error rate as claimed in claim 1 wherein said quadrature balance signal alters relative phase between said first and second quadrature-phase signals.
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9. A method for ameliorating the bit error rate as claimed in claim 1 wherein said quadrature balance signal alters relative amplitude between said first and second quadrature-phase signals.
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10. A method for ameliorating the bit error rate as claimed in claim 1 wherein said quadrature balance signal alters DC offsets of said first and second quadrature-phase signals.
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11. A method for ameliorating the bit error rate as claimed in claim 1 wherein:
said formulating activity c), said transmitting activity d), said receiving activity e) and said adjusting activity f) are repeatedly performed to adjust said quadrature balance signal until said signal quality statistic indicates a local optimum condition.
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12. A method for ameliorating the bit error rate as claimed in claim 11 wherein:
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said method additionally comprises adaptively equalizing said communication signal at said second site, said adaptively equalizing activity exhibiting a first response time; and
said adjusting activity f) adjusts said quadrature balance signal in an end-to-end feedback loop that exhibits a second response time, said second response time being slower than said first response time.
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13. A method for ameliorating the bit error rate as claimed in claim 12 wherein said end-to-end feedback loop is configured to optimize said signal quality statistic.
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14. A method for ameliorating the bit error rate as claimed in claim 1 wherein said signal quality statistic is one of an error vector magnitude parameter and a bit error rate parameter.
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15. A digital communication system which ameliorates a bit error rate of a data stream while communicating said data stream, said system comprising:
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a first receiver located at a first site;
a first transmitter located at said first site, said first transmitter being configured to generate a quadrature balance signal which alters one of first and second quadrature-phase signals relative to the other, said first and second quadrature-phase signals collectively conveying said data stream, and said first transmitter being configured to combine said quadrature-phase signals to form a communication signal and to transmit said communication signal;
a second receiver located at a second site, said second receiver being configured to receive said communication signal which conveys said data stream, to generate a signal quality statistic determined from said communication signal and to formulate a command in response to said signal quality statistic; and
a second transmitter located at said second site and configured to transmit said command so that said command can be received by said first receiver;
wherein said first transmitter is further configured to adjust said quadrature balance signal in response to said command. - View Dependent Claims (16, 17, 18)
said quadrature balance signal is a first quadrature balance signal which alters relative phase between said first and second quadrature-phase signals;
said transmitter is additionally configured to generate a second quadrature balance signal which alters relative amplitude between said first and second quadrature-phase signals;
said transmitter is additionally configured to generate a third quadrature balance signal which alters a DC offset of said first quadrature-phase signal; and
said transmitter is additionally configured to generate a fourth quadrature balance signal which alters a DC offset of said second quadrature-phase signal.
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18. A system as claimed in claim 15 wherein said signal quality statistic is one of an error vector magnitude parameter and a bit error rate parameter.
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19. In a digital communication system, a method for ameliorating a bit error rate for a data stream transmitted from a first site to a second site, said method comprising:
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a) establishing a bi-directional communication link between said first and second sites;
b) receiving a communication signal at said second site, said communication signal conveying said data stream;
c) generating a signal quality statistic at said second site, said signal quality statistic being determined from said communication signal;
d) formulating a command at said second site in response to said signal quality statistic;
e) transmitting said command at said second site;
f) receiving said command at said first site;
g) adjusting, at said first site, a quadrature balance signal in response to said command, said quadrature balance signal altering one of first and second quadrature-phase signals relative to the other, said first and second quadrature-phase signals collectively conveying said data stream;
h) combining said quadrature-phase signals at said first site to form said communication signal;
i) transmitting said communication signal at said first site; and
j) repeating said formulating step d), said transmitting step e), said receiving step f) and said adjusting step g) to adjust said quadrature balance signal until said signal quality statistic indicates a local optimum condition. - View Dependent Claims (20)
said quadrature balance signal is a first quadrature balance signal which alters relative phase between said first and second quadrature-phase signals;
said adjusting step additionally adjusts a second quadrature balance signal which alters relative amplitude between said first and second quadrature-phase signals;
said adjusting step additionally adjusts a third quadrature balance signal which alters a DC offset of said first quadrature-phase signal; and
said adjusting step additionally adjusts a fourth quadrature balance signal which alters a DC offset of said second quadrature-phase signal.
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Specification
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Current AssigneeIntersil Americas LLC (Renesas Electronics Corporation)
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Original AssigneeSiCOM, Inc. (Renesas Electronics Corporation)
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InventorsMcCallister, Ronald D., Cochran, Bruce A.
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Primary Examiner(s)TSE, YOUNG TOI
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Application NumberUS09/407,132Time in Patent Office575 DaysField of Search375/219, 375/221, 375/223, 375/225, 375/227, 375/259, 375/269, 375/279, 375/280, 375/281, 375/284, 375/308, 375/329, 375/332, 455/42, 455/63, 455/67.1, 455/67.3, 455/69, 455/70, 455/500, 455/501, 329/304, 332/103US Class Current375/225CPC Class CodesH04L 2027/0016 Stabilisation of local osci...H04L 2027/002 using feedback from a remot...H04L 27/0014 Carrier regulation of chaot...
