A Bpsk/qpsk Timing-error Detection For Sampled Receivers

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Request full-text A BPSK/QPSK timing-error detector for sampled receiversArticle in IEEE Transactions on Communications 34(5):423 - 429 · June 1986 with 303 ReadsDOI: 10.1109/TCOM.1986.1096561 · Source: IEEE Xplore1st Floyd M. GardnerAbstractA simple algorithm for detection of timing error of a synchronous, band-limited, BPSK or QPSK data stream is proposed. The algorithm requires only two samples per symbol for its operation. One of the two samples is also used for the symbol decision. Derivation of the s curve reveals a sinusoidal shape.Do you want to read the rest of http://ieeexplore.ieee.org/iel5/8159/24007/01096561.pdf this article?Request full-text CitationsCitations449ReferencesReferences14Performance Study of a Near Maximum Likelihood Code-Aided Timing Recovery Technique"Timing recovery is required to ensure that the sampling instants coincide with the maximum opening of the signal eye-diagram thus maximizing the robustness to noise and interference. Some DA and non-data-aided (NDA) time delay estimation techniques have been employed in real systems for decades such https://www.researchgate.net/publication/224733847_A_BPSKQPSK_timing-error_detector_for_sampled_receivers as those reported in [1] and [2]. However, in a DA mode, we need to insert some pilot signals which leads to the loss of throughput and the decrease of spectrum efficiency. "[Show abstract] [Hide abstract] ABSTRACT: In this paper, we propose a new code-aided (CA) timing recovery algorithm for various linear constant modulus constellations based on the Maximum Likelihood (ML) estimator. The first contribution is the derivation of a soft estimator expression of the transmitted symbol instead of its true or hard estimated value which is fed into the timing error detector (TED) equation. The proposed expression includes the Log-Likelihood Ratios (LLRs) obtained from a turbo decoder. Our results show that the proposed CA approach achieves almost as good results as the data-aided (DA) approach over a large interval of SNR values while achieving a higher spectral efficiency. We also derive the corresponding CA Cramer Rao Bounds (CRB) for various modulation orders. Contrarily to former work, we develop here the CRB analytical expression for different M-PSK modulation orders and validate them thr

Search All Support Resources Support Documentation MathWorks Search MathWorks.com MathWorks Documentation Support Documentation Toggle http://www.mathworks.com/help/comm/ref/gardnertimingrecovery.html navigation Trial Software Product Updates Documentation Home Communications System Toolbox Examples Functions and Other Reference Release Notes PDF Documentation Gardner Timing Recovery On this page Library Description Inputs Outputs Delays Parameters Algorithm Supported Data Types References See Also This is machine translation Translated by Mouse over text to timing recovery see original. Click the button below to return to the English verison of the page. Back to English × Translate This Page Select Language Bulgarian Catalan Chinese Simplified Chinese Traditional Czech Danish Dutch English Estonian Finnish French German Greek Haitian Creole Hindi Hmong Daw Hungarian Indonesian Italian Japanese a bpsk/qpsk timing-error Korean Latvian Lithuanian Malay Maltese Norwegian Polish Portuguese Romanian Russian Slovak Slovenian Spanish Swedish Thai Turkish Ukrainian Vietnamese Welsh MathWorks Machine Translation The automated translation of this page is provided by a general purpose third party translator tool. MathWorks does not warrant, and disclaims all liability for, the accuracy, suitability, or fitness for purpose of the translation. Translate Gardner Timing RecoveryRecover symbol timing phase using Gardner's methodNote: Gardner Timing Recovery will be removed in a future release. Use the Symbol Synchronizer block instead. LibraryTiming Phase Recovery sublibrary of SynchronizationDescriptionThe Gardner Timing Recovery block recovers the symbol timing phase of the input signal using Gardner's method. This block implements a non-data-aided feedback method that is independent of carrier phase recovery. The timing error detector that forms part of this block's algorithm requires at least two samples per symbol, one of which is the

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