Title :
Bi-Directional Pattern-Dependent Noise Prediction for Heat-Assisted Magnetic Recording With High Jitter Noise
Author :
Ng, Yibin ; Kumar, B. V K Vijaya ; Cai, Kui ; Radhakrishnan, Rathnakumar ; Chong, Tow Chong
Author_Institution :
Data Storage Syst. Center (DSSC), Carnegie Mellon Univ., Pittsburgh, PA, USA
fDate :
5/1/2012 12:00:00 AM
Abstract :
In this paper, we first report the results of an investigation of perpendicular heat-assisted magnetic recording (HAMR) channels containing high jitter noise that is likely to be the case at very high areal densities (e.g., 4 Tb/in2). To model the HAMR channel, we use the thermal Williams-Comstock model and the microtrack model to derive the transition response, without large thermal spot approximation. Further, we propose a novel bi-directional pattern-dependent noise prediction (biPDNP) detector to improve the performance of the HAMR channel under high jitter noise conditions. The biPDNP detector utilizes backward linear prediction in the noise prediction process, as well as the conventional forward linear prediction. At bit error rate of 10-3, biPDNP detector offers 0.6-1.4 dB performance gain over the conventional PDNP detector.
Keywords :
heat treatment; jitter; magnetic recording noise; perpendicular magnetic recording; thermomagnetic recording; HAMR channel; bidirectional pattern-dependent noise prediction; conventional forward linear prediction; jitter noise; microtrack model; perpendicular heat assisted magnetic recording; thermal Williams-Comstock model; Approximation methods; Bidirectional control; Detectors; Equalizers; Heat-assisted magnetic recording; Jitter; Noise; Bi-directional PDNP; PDNP; Williams-Comstock recording model; heat-assisted magnetic recording; jitter noise; maximum likelihood sequence detection; noise prediction; signal-dependent noise;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2011.2170827
