Number Theory for ComputingSpringer Science & Business Media, 24 apr 2002 - 435 pagine Modern cryptography depends heavily on number theory, with primality test ing, factoring, discrete logarithms (indices), and elliptic curves being perhaps the most prominent subject areas. Since my own graduate study had empha sized probability theory, statistics, and real analysis, when I started work ing in cryptography around 1970, I found myself swimming in an unknown, murky sea. I thus know from personal experience how inaccessible number theory can be to the uninitiated. Thank you for your efforts to case the transition for a new generation of cryptographers. Thank you also for helping Ralph Merkle receive the credit he deserves. Diffie, Rivest, Shamir, Adleman and I had the good luck to get expedited review of our papers, so that they appeared before Merkle's seminal contribu tion. Your noting his early submission date and referring to what has come to be called "Diffie-Hellman key exchange" as it should, "Diffie-Hellman-Merkle key exchange", is greatly appreciated. It has been gratifying to see how cryptography and number theory have helped each other over the last twenty-five years. :'-Jumber theory has been the source of numerous clever ideas for implementing cryptographic systems and protocols while cryptography has been helpful in getting funding for this area which has sometimes been called "the queen of mathematics" because of its seeming lack of real world applications. Little did they know! Stanford, 30 July 2001 Martin E. Hellman Preface to the Second Edition Number theory is an experimental science. |
Sommario
I | 1 |
IV | 13 |
V | 14 |
VI | 21 |
VIII | 27 |
IX | 33 |
X | 40 |
XI | 44 |
LIX | 228 |
LXI | 232 |
LXII | 234 |
LXIII | 237 |
LXIV | 240 |
LXV | 244 |
LXVI | 251 |
LXVII | 254 |
XII | 52 |
XIV | 54 |
XV | 57 |
XVI | 63 |
XVIII | 66 |
XIX | 71 |
XX | 79 |
XXI | 85 |
XXIII | 87 |
XXIV | 94 |
XXV | 95 |
XXVI | 104 |
XXVII | 106 |
XXVIII | 110 |
XXIX | 111 |
XXXI | 118 |
XXXII | 123 |
XXXIII | 130 |
XXXIV | 133 |
XXXV | 139 |
XXXVI | 150 |
XXXVII | 155 |
XXXVIII | 160 |
XXXIX | 163 |
XL | 164 |
XLI | 168 |
XLII | 169 |
XLIII | 171 |
XLIV | 173 |
XLVI | 174 |
XLVII | 177 |
XLVIII | 181 |
XLIX | 188 |
L | 194 |
LI | 198 |
LII | 202 |
LIV | 206 |
LV | 208 |
LVI | 215 |
LVII | 222 |
LVIII | 225 |
LXVIII | 255 |
LXIX | 258 |
LXX | 262 |
LXXI | 266 |
LXXII | 270 |
LXXIII | 273 |
LXXV | 278 |
LXXVI | 279 |
LXXVII | 285 |
LXXVIII | 287 |
LXXX | 292 |
LXXXI | 295 |
LXXXII | 299 |
LXXXIII | 300 |
LXXXIV | 303 |
LXXXVI | 305 |
LXXXVIII | 308 |
LXXXIX | 312 |
XC | 315 |
XCI | 317 |
XCII | 321 |
XCIII | 326 |
XCIV | 332 |
XCVI | 344 |
XCVII | 348 |
XCVIII | 354 |
XCIX | 358 |
C | 373 |
CI | 379 |
CII | 385 |
CIII | 392 |
CIV | 395 |
CV | 399 |
CVI | 403 |
CVII | 409 |
CVIII | 410 |
CIX | 411 |
CX | 415 |
| 429 | |
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algebraic Alice amicable pairs arithmetic binary bit operations called Chinese Remainder Theorem ciphertext complexity composite Computer Science congruence conjecture decryption defined Definition denoted Digital Signature discrete logarithm problem divisor elements elliptic curve encryption Euclid's algorithm Euler's example exponential Fermat numbers Field Sieve gcd(a hence integer factorization Jacobi symbol known Legendre symbol linear log log Lucas m₁ mathematician Mathematics Mersenne primes method mod q multiplicative n₁ nontrivial Note Number Field Sieve O(log odd perfect number odd prime P₁ plaintext points polynomial Pomerance positive integer primality testing prime factors Prime Number Theorem primitive root probable prime Proof pseudoprimality test public-key cryptography public-key cryptosystems quadratic nonresidues quadratic residues quantum computer random number Re(s relatively prime residue classes residues modulo Riemann Hypothesis secure sequence simple continued fraction solution solve Springer-Verlag subsection Suppose Turing machine University Z/nZ zeros