Title :
Signal processing for probe storage
Author :
Pozidis, H. ; Bächtold, P. ; Cherubini, G. ; Eleftheriou, E. ; Hagleitner, C. ; Pantazi, A. ; Sebastian, A.
Author_Institution :
IBM Res. Div., IBM Zurich Res. Lab., Ruschlikon, Switzerland
Abstract :
Scanning-probe data storage is emerging as a viable alternative to conventional data storage, offering ultra-high density, low access times, and low power consumption. One probe-storage technique utilizes a thermomechanical means to store and retrieve information in thin polymer films. We describe the readback signal path and characterize the thermomechanical-based probe-storage recording channel. It is shown that this channel exhibits a particular nonlinear behavior at high storage densities or high recording power, that is, the energy per unit time used to write a bit of information. A simple model is proposed that accurately captures the characteristics of this nonlinearity. Experimental results from single-probe recording setups are used to verify the validity of this model and identify its relevant parameters.
Keywords :
data recording; digital storage; polymer films; power consumption; signal processing; thermomechanical treatment; access times; nonlinear behavior; power consumption; probe storage; readback signal path; scanning-probe data storage; signal processing; storage density; thermomechanical recording; thermomechanical-based probe-storage recording channel; thin polymer films; Atom optics; Image storage; Nonlinear optics; Optical films; Perpendicular magnetic recording; Polymer films; Probes; Signal processing; Thermomechanical processes; Writing;
Conference_Titel :
Acoustics, Speech, and Signal Processing, 2005. Proceedings. (ICASSP '05). IEEE International Conference on
Print_ISBN :
0-7803-8874-7
DOI :
10.1109/ICASSP.2005.1416411
