03590nam a22005295i 4500001001800000003000900018005001700027007001500044008004100059020003700100024003500137041000800172050001300180072001700193072002300210082001700233100002700250245012000277260004600397264004600443300003400489336002600523337002600549338003600575347002400611505034100635520157100976650001702547650001902564650003302583650002102616650002502637650001702662650002602679650003502705650005402740650004202794700002502836700002502861710003402886773002002920776003602940856004802976912001403024942000703038999001503045978-1-4020-8391-4DE-He21320141014113440.0cr nn 008mamaa100301s2008 ne | s |||| 0|eng d a97814020839149978-1-4020-8391-47 a10.1007/978-1-4020-8391-42doi aeng 4aTK7888.4 7aTJFC2bicssc 7aTEC0080102bisacsh04a621.38152231 aMicheloni, R.eauthor.10aError Correction Codes for Non-Volatile Memoriesh[electronic resource] /cby R. Micheloni, A. Marelli, R. Ravasio. 1aDordrecht :bSpringer Netherlands,c2008. 1aDordrecht :bSpringer Netherlands,c2008. aXII, 338 p.bonline resource. atextbtxt2rdacontent acomputerbc2rdamedia aonline resourcebcr2rdacarrier atext filebPDF2rda0 aBasic coding theory -- Error Correction Codes -- NOR Flash memories -- NAND Flash memories -- Reliability of floating gate memories -- Hardware implementation of Galois field operators -- Hamming code for Flash memories -- Cyclic codes for non volatile storage -- BCH hardware implementation in NAND Flash memories -- Erasure technique. aAfter "A Mathematical theory of communication" by C. E. Shannon, the 'Coding Theory' has begun its tremendous development as interface between Engineering, Computer Science and Mathematics. Contributions by mathematicians have focused on the design of new codes and the study of their properties, while contributions by engineers have focused on efficient implementations of encoding/decoding schemes. The research activities in Coding Theory have produced a vast range of different codes (with usually several alternative encoding/decoding algorithms), and their availability has pushed for new applications. Nowadays it is hard to find an electronic device which does not use codes: for example, we listen to music via heavily encoded audio CD's and we watch movies via encoded DVD's. There is at least one area where the use of encoding/decoding is not so developed, yet: Flash non-volatile memories. Flash memory high-density, low power, cost effectiveness, and scalable design make it an ideal choice to fuel the explosion of multimedia products, like USB keys, MP3 players, digital cameras and solid-state disk. In ECC for Non-Volatile Memories the authors expose the basics of coding theory needed to understand the application to memories, as well as the relevant design topics, with reference to both NOR and NAND Flash architectures. A collection of software routines is also included for better understanding. The authors form a research group (now at Qimonda) which is the typical example of a fruitful collaboration between mathematicians and engineers. 0aEngineering. 0aCoding theory. 0aParticles (Nuclear physics). 0aPhysical optics. 0aSystems engineering.14aEngineering.24aCircuits and Systems.24aCoding and Information Theory.24aApplied Optics, Optoelectronics, Optical Devices.24aSolid State Physics and Spectroscopy.1 aMarelli, A.eauthor.1 aRavasio, R.eauthor.2 aSpringerLink (Online service)0 tSpringer eBooks08iPrinted edition:z978140208390740uhttp://dx.doi.org/10.1007/978-1-4020-8391-4 aZDB-2-ENG cEB c1288d1288