MAGIC: Making IMR-Based HDD Perform Like CMR-Based HDD
The past decades have witnessed the tremendous success of Conventional Magnetic Recording (CMR)-based Hard Disk Drives (HDDs) in data storage. To eliminate the bottleneck of CMR-based HDDs in providing higher areal density, an emerging Interlaced Magnetic Recording (IMR) is capable of achieving high...
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| Veröffentlicht in: | IEEE transactions on computers 2022-03, Vol.71 (3), p.643-657 |
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| creator | Liang, Yuhong Yang, Ming-Chang Chen, Shuo-Han |
| description | The past decades have witnessed the tremendous success of Conventional Magnetic Recording (CMR)-based Hard Disk Drives (HDDs) in data storage. To eliminate the bottleneck of CMR-based HDDs in providing higher areal density, an emerging Interlaced Magnetic Recording (IMR) is capable of achieving higher areal density with limited changes to disk makeup. Nevertheless, existing approaches for IMR-based HDDs may suffer serious read and write performance degradation as compared with CMR-based HDDs. Thus, this article presents a device-level solution, namely MAGIC translation layer, which aims at MA kin G I MR-based HDDs perform like C MR-based HDDs in terms of comparable access performance. Specifically, not merely trying to improve the performance of raw IMR-based HDDs, this work, for the first time, moves one step forward to minimize the performance gap between IMR and CMR-based HDDs. Technically, by 1) fully utilizing two special CMR-like potentials of IMR and 2) gracefully trading the sequential access performance as space usage increases, MAGIC minimizes track rewriting overheads to achieve CMR-like performance. Our results reveal that MAGIC not only improves the write performance compared with existing designs, but also has potential to approach read and write performance of CMR-based HDD. |
| doi_str_mv | 10.1109/TC.2021.3059770 |
| format | Article |
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To eliminate the bottleneck of CMR-based HDDs in providing higher areal density, an emerging Interlaced Magnetic Recording (IMR) is capable of achieving higher areal density with limited changes to disk makeup. Nevertheless, existing approaches for IMR-based HDDs may suffer serious read and write performance degradation as compared with CMR-based HDDs. Thus, this article presents a device-level solution, namely MAGIC translation layer, which aims at MA kin G I MR-based HDDs perform like C MR-based HDDs in terms of comparable access performance. Specifically, not merely trying to improve the performance of raw IMR-based HDDs, this work, for the first time, moves one step forward to minimize the performance gap between IMR and CMR-based HDDs. Technically, by 1) fully utilizing two special CMR-like potentials of IMR and 2) gracefully trading the sequential access performance as space usage increases, MAGIC minimizes track rewriting overheads to achieve CMR-like performance. 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To eliminate the bottleneck of CMR-based HDDs in providing higher areal density, an emerging Interlaced Magnetic Recording (IMR) is capable of achieving higher areal density with limited changes to disk makeup. Nevertheless, existing approaches for IMR-based HDDs may suffer serious read and write performance degradation as compared with CMR-based HDDs. Thus, this article presents a device-level solution, namely MAGIC translation layer, which aims at MA kin G I MR-based HDDs perform like C MR-based HDDs in terms of comparable access performance. Specifically, not merely trying to improve the performance of raw IMR-based HDDs, this work, for the first time, moves one step forward to minimize the performance gap between IMR and CMR-based HDDs. Technically, by 1) fully utilizing two special CMR-like potentials of IMR and 2) gracefully trading the sequential access performance as space usage increases, MAGIC minimizes track rewriting overheads to achieve CMR-like performance. Our results reveal that MAGIC not only improves the write performance compared with existing designs, but also has potential to approach read and write performance of CMR-based HDD.</description><subject>conventional magnetic recording (CMR)</subject><subject>Data storage</subject><subject>Degradation</subject><subject>Density</subject><subject>Disk drives</subject><subject>hard disk drive (HDD)</subject><subject>Hard disks</subject><subject>Interlaced magnetic recording (IMR)</subject><subject>interlaced translation layer (ITL)</subject><subject>Layout</subject><subject>Magnetic recording</subject><subject>Performance degradation</subject><subject>Performance enhancement</subject><subject>Performance evaluation</subject><subject>Postal services</subject><subject>Space heating</subject><subject>Tracking</subject><issn>0018-9340</issn><issn>1557-9956</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2022</creationdate><recordtype>article</recordtype><sourceid>RIE</sourceid><recordid>eNpNkMFLwzAUxoMoWKdnD14Kntu9JE3SeJudukGLIvUc0jSRbm6dyXbwv7ejQ7y8x-P9vu-DD6FbDCnGIKd1kRIgOKXApBBwhiLMmEikZPwcRQA4TyTN4BJdhbACAE5ARohXs5dl8RBXet1tP-Nl9Z486mDbeDGfx2_Wu95v4rJb27j4_7pGF05_BXtz2hP08fxUF4ukfB3sZmViSC73ScMzl2ciw4bq3NmsFbkZTkOFGGbbNqbFhBjMLM9M44iQDecSS0e1aTUFOkH3o-_O998HG_Zq1R_8dohUhBORU0EpGajpSBnfh-CtUzvfbbT_URjUsRxVF-pYjjqVMyjuRkVnrf2jJWUMQNBfDv1bYw</recordid><startdate>20220301</startdate><enddate>20220301</enddate><creator>Liang, Yuhong</creator><creator>Yang, Ming-Chang</creator><creator>Chen, Shuo-Han</creator><general>IEEE</general><general>The Institute of Electrical and Electronics Engineers, Inc. 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To eliminate the bottleneck of CMR-based HDDs in providing higher areal density, an emerging Interlaced Magnetic Recording (IMR) is capable of achieving higher areal density with limited changes to disk makeup. Nevertheless, existing approaches for IMR-based HDDs may suffer serious read and write performance degradation as compared with CMR-based HDDs. Thus, this article presents a device-level solution, namely MAGIC translation layer, which aims at MA kin G I MR-based HDDs perform like C MR-based HDDs in terms of comparable access performance. Specifically, not merely trying to improve the performance of raw IMR-based HDDs, this work, for the first time, moves one step forward to minimize the performance gap between IMR and CMR-based HDDs. Technically, by 1) fully utilizing two special CMR-like potentials of IMR and 2) gracefully trading the sequential access performance as space usage increases, MAGIC minimizes track rewriting overheads to achieve CMR-like performance. 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| subjects | conventional magnetic recording (CMR) Data storage Degradation Density Disk drives hard disk drive (HDD) Hard disks Interlaced magnetic recording (IMR) interlaced translation layer (ITL) Layout Magnetic recording Performance degradation Performance enhancement Performance evaluation Postal services Space heating Tracking |
| title | MAGIC: Making IMR-Based HDD Perform Like CMR-Based HDD |
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