Near-optimal PLL design for decision-feedback carrier and timing recovery

@article{citeulike:2782050, abstract = {A new design method is presented for the design of PLL loop filters for carrier recovery, bit timing, or other synchronization loops given the phase noise spectrum and noise level. Unlike the conventional designs, our design incorporates a possible large decision delay and S-curve slope uncertainty. Large decision delays frequently exist in modern receivers due to, for example, a convolutional decoder or an equalizer. The new design also applies to coherent optical communications where delay in the loop limits the laser linewidth. We provide an easy-to-use complete design procedure for second-order loops. We also introduce a design procedure for higher order loops for near-optimal performance. We show that using the traditional second-order loop is suboptimal when there is a delay in the loop, and also shows large improvements, either in the amount of allowed delay, or the phase error variance in the presence of delay}, author = {Yaniv, O. and Raphaeli, D. }, booktitle = {Communications, IEEE Transactions on}, citeulike-article-id = {2782050}, doi = {10.1109/26.950353}, journal = {Communications, IEEE Transactions on}, keywords = {design, frequency, pll, time}, number = {9}, pages = {1669--1678}, posted-at = {2008-05-10 00:59:55}, priority = {2}, title = {Near-optimal PLL design for decision-feedback carrier and timing recovery}, url = {http://dx.doi.org/10.1109/26.950353}, volume = {49}, year = {2001} }

TY - JOUR ID - citeulike:2782050 TI - Near-optimal PLL design for decision-feedback carrier and timing recovery T2 - Communications, IEEE Transactions on JF - Communications, IEEE Transactions on VL - 49 IS - 9 SP - 1669 EP - 1678 N2 - A new design method is presented for the design of PLL loop filters for carrier recovery, bit timing, or other synchronization loops given the phase noise spectrum and noise level. Unlike the conventional designs, our design incorporates a possible large decision delay and S-curve slope uncertainty. Large decision delays frequently exist in modern receivers due to, for example, a convolutional decoder or an equalizer. The new design also applies to coherent optical communications where delay in the loop limits the laser linewidth. We provide an easy-to-use complete design procedure for second-order loops. We also introduce a design procedure for higher order loops for near-optimal performance. We show that using the traditional second-order loop is suboptimal when there is a delay in the loop, and also shows large improvements, either in the amount of allowed delay, or the phase error variance in the presence of delay KW - design KW - frequency KW - pll KW - time AU - Yaniv, O AU - Raphaeli, D PY - 2001/// UR - http://dx.doi.org/10.1109/26.950353 ER -