Drive-based recording analyses at 800 Gfc/in super(2 using shingled recording)

Since the introduction of perpendicular recording, conventional perpendicular scaling has enabled the hard disk drive industry to deliver products ranging from [approx]130 to well over 500 Gb/in super(2 in a little over 4 years. The incredible areal density growth spurt enabled by perpendicular reco...

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Bibliographic Details
Published in:Journal of magnetism and magnetic materials 2012-02, Vol.324 (3), p.330-335
Main Authors: Cross, RWilliam, Montemorra, Michael
Format: Article
Language:English
Subjects:
Corners
Density
Disk drives
Gain
Magnetic recording
Mathematical analysis
Media
Recording
Online Access:Get full text
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Summary:Since the introduction of perpendicular recording, conventional perpendicular scaling has enabled the hard disk drive industry to deliver products ranging from [approx]130 to well over 500 Gb/in super(2 in a little over 4 years. The incredible areal density growth spurt enabled by perpendicular recording is now endangered by an inability to effectively balance writeability with erasure effects at the system level. Shingled magnetic recording (SMR) offers an effective means to continue perpendicular areal density growth using conventional heads and tuned media designs. The use of specially designed edge-write head structures (also known as 'corner writers') should further increase the AD gain potential for shingled recording. In this paper, we will demonstrate the drive-based recording performance characteristics of a shingled recording system at areal densities in excess of 800 Gb/in) super(2) using a conventional head. Using a production drive base, developmental heads/media and a number of sophisticated analytical routines, we have studied the recording performance of a shingled magnetic recording subsystem. Our observations confirm excellent writeability in excess of 400 ktpi and a perpendicular system with acceptable noise balance, especially at extreme ID and OD skews where the benefits of SMR are quite pronounced. We believe that this demonstration illustrates that SMR is not only capable of productization, but is likely the path of least resistance toward production drive areal density closer to 1 Tb/in super(2 and beyond.)
ISSN:0304-8853
DOI:10.1016/j.jmmm.2010.12.015