Title :
Time domain analysis of low frequency noise in giant magneto-resistive recording heads
Author :
Prabhakar, A. ; Zhang, J.
Author_Institution :
Read-Rite Corp., Milpitas, CA, USA
fDate :
9/1/2000 12:00:00 AM
Abstract :
The low frequency noise observed in giant magneto-resistive recording heads was studied in the time domain. Time series data was collected on bottom spin-valve sensors while varying the bias current (I b) about a nominal operating point. An optimal time delay of 5 ns was chosen based on a 80% reduction in mutual information. Two dimensional embedding of the data revealed a progression from one stable state for low Ib to two metastable states and finally a second stable state at high Ib. The metastable states manifest themselves as random telegraphic noise in the time series. The average time between noise spikes was obtained by calculating the time between consecutive points on a Poincare section and was estimated as 0.37 μs. The Renyi entropy was used to quantify the stability of the system both with and without an isolated pulse pattern
Keywords :
1/f noise; Poincare mapping; entropy; giant magnetoresistance; magnetic heads; magnetic recording noise; spin valves; time series; time-domain analysis; Poincare section; Renyi entropy; Shannon entropy; bias current; bottom spin-valve sensors; giant magnetoresistive recording heads; isolated pulse pattern; low frequency noise; metastable state; nominal operating point; optimal time delay; random telegraphic noise; stable state; time between noise spikes; time domain analysis; time series data; two dimensional data embedding; Delay effects; Entropy; Low-frequency noise; Magnetic domains; Magnetic heads; Magnetic sensors; Metastasis; Mutual information; Stability; Time domain analysis;
Journal_Title :
Magnetics, IEEE Transactions on
