Esteban L. Valles scite author profile

Abstract-This paper addresses the carrier-phase estimation problem under the low SNR conditions often encountered in turbo and LDPC-coded applications. In [1] a decision-directed carrier synchronization (DDCS) circuit that uses soft information from an iterative LDPC decoder was presented for BPSK and QPSK constellations with constant phase offsets. In this work, we present a method that is able to handle arbitrary constellations with a random-walk phase noise process. Loop SNR equations are derived and the performance for different constellations is shown. An extension of the DDCS algorithm is described that uses a search and tracking method based on measuring the number of satisfied LDPC constraint-node equations equations at the decoder and is able to track arbitrary carrier phase.

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Carrier and Timing Synchronization of BPSK via LDPC Code Feedback

Valles

Wesel

Villasenor

et al. 2006

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Abstract-In traditional receiver architectures, symbol acquisition and tracking are performed using phase lock techniques that are independent of the channel-code decoding process. In [1] feedback from the constraint-node side of a bi-partite graph is used to estimate symbol frequency and timing offset in a baseband pilotless transmission. In [2] soft information feedback from an LDPC decoder is used to recover carrier phase information under the assumption of perfect symbol timing. In this paper we address the problem of joint carrier-phase and symbol timing recovery. The proposed system is able to perform within 0.3 [dB] of the code performance with perfect knowledge of carrier phase and symbol timing.

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Joint LDPC decoding and timing recovery using code constraint feedback

Lee¹,

Valles²,

Villasenor³

et al. 2006

IEEE Commun. Lett.

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Abstract-Timing recovery and channel decoding are traditionally performed independently. However, we show here that the information generated during the iterative decoding of LowDensity Parity-Check (LDPC) coded data can be fed back to the timing recovery circuit to enable accurate estimation of frequency and phase errors without the need for any pilot symbols. We describe a method capable of handling large offsets with complexity that grows linearly with offset size. Combining the LDPC constraint node observations with a properly calibrated phase locked loop allows successful tracking of a constant time delay, a frequency offset and a random phase walk.

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An EMWIN and LRIT software receiver using GNU radio

Valles

Tarasov

Roberson

et al. 2009

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Esteban L. Valles

Approximate-min* constraint node updating for ldpc code decoding

Pilotless carrier phase-synchronization via LDPC code feedback

Carrier and Timing Synchronization of BPSK via LDPC Code Feedback

Joint LDPC decoding and timing recovery using code constraint feedback

An EMWIN and LRIT software receiver using GNU radio

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