Phase detectors in carrier recovery for offset QAM and VSB
First Claim
1. In an offset QAM receiver that recovers in-phase signals sampled at in-phase sampling times and quadrature-phase signals sampled at quadrature-phase sampling times, a method for detecting the phase of the recovered signals comprising:
- separating the in-phase signals into a first data stream at the in-phase sampling times and a second data stream at the quadrature-phase sampling times;
separating the quadrature-phase signals into a third data stream at the quadrature-phase sampling times and a fourth data stream at the in-phase sampling times;
generating a fifth data stream representing tentative decisions from the first data stream;
generating a sixth data steam representing tentative decisions from the third data stream;
comparing the first and fifth data streams to generate a first error signal;
comparing the third and sixth data streams to generate a second error signal;
combining the first error signal and the fourth data stream to form a first phase error signal; and
combining the second error signal and the second data stream to form a second phase error signal.
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Abstract
Improved carrier recovery, symbol timing, and carrier phase tracking systems and methods suitable for use in connection with a dual-mode QAM/VSB receiver system are disclosed. Carrier and phase recovery systems operate on complex signals representing symbols having the same time stamp for each phase error term. in-phase signals are sampled twice a symbol at the in-phase symbol sampling time and at the quadrature-phase symbol sampling time. The signals are de-multiplexed to generate I and XI data streams, where I represents the in-phase sampling time signals and XI represents mid-symbol point sample times. A similar procedure is carrier out on quadrature-phase signals. When the in-phase signal is de-multiplexed to generate a symbol I, the quadrature-phase signal is de-multiplexed to generate its mid-symbol point XQ. Both I and Q are decoded in a decision device to define a symbol error term, which is combined with the opposite mid-symbol signal to define a phase error term PI and PQ for each rail. In both cases, the symbol (I) decision (Î), and mid-symbol (XQ) in each phase error term (PI) computation will have the same prime index.
61 Citations
8 Claims
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1. In an offset QAM receiver that recovers in-phase signals sampled at in-phase sampling times and quadrature-phase signals sampled at quadrature-phase sampling times, a method for detecting the phase of the recovered signals comprising:
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separating the in-phase signals into a first data stream at the in-phase sampling times and a second data stream at the quadrature-phase sampling times;
separating the quadrature-phase signals into a third data stream at the quadrature-phase sampling times and a fourth data stream at the in-phase sampling times;
generating a fifth data stream representing tentative decisions from the first data stream;
generating a sixth data steam representing tentative decisions from the third data stream;
comparing the first and fifth data streams to generate a first error signal;
comparing the third and sixth data streams to generate a second error signal;
combining the first error signal and the fourth data stream to form a first phase error signal; and
combining the second error signal and the second data stream to form a second phase error signal. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8)
separating the VSB signal into in-phase and quadrature phase data streams;
generating a data stream representing tentative decisions from the in-phase data stream;
comparing the in-phase data stream and the data stream representing tentative decisions to generate an error signal; and
combining the error signal and the quadrature phase data stream.
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7. The method of claim 6, in which the step of generating the data stream representing tentative decisions from the in-phase data stream comprises decision devices.
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8. The method of claim 7, additional comprising the step of coupling the combined phase error signals and the quadrature phase data stream to a VCO to reduce any difference therebetween.
Specification
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- Resources
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Current AssigneeAvago Technologies International Sales Pte Limited (Broadcom, Inc.)
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Original AssigneeBroadcom Corporation (Broadcom, Inc.)
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InventorsKrafft, Stephen E., Lin, Thuji S., Liu, Tian-Min
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Primary Examiner(s)TSE, YOUNG TOI
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Application NumberUS10/288,833Publication NumberTime in Patent Office419 DaysField of Search375/269, 375/279, 375/281, 375/326, 375/327, 375/329, 375/332, 375/344, 375/345, 375/375, 375/376, 329/304, 329/307, 329/308, 348/725, 348/726US Class Current375/375CPC Class CodesH04B 1/68 for wholly or partially sup...H04L 2025/03382 Single of vestigal sidebandH04L 2025/0342 QAMH04L 2025/0349 as a feedback filterH04L 2025/03503 as a combination of feedbac...H04L 2027/0032 at baseband and passbandH04L 2027/0042 the equaliser providing the...H04L 2027/0057 quadrature phaseH04L 2027/0067 Phase error detectorsH04L 2027/0087 Out-of-band signals, (e.g. ...H04L 25/03057 with a recursive structure ...H04L 27/02 Amplitude-modulated carrier...H04L 27/066 Carrier recovery circuits H...H04L 27/2273 associated with quadrature ...H04L 27/3427 in which the constellation ...H04L 27/3827 in which the carrier is rec...H04N 11/24 High-definition television ...H04N 21/426 Internal components of the ...H04N 5/21 Circuitry for suppressing o...H04N 5/211 Ghost signal cancellation H...View All
