unbreakable cryptosystem - definizione. Che cos'è unbreakable cryptosystem
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Cosa (chi) è unbreakable cryptosystem - definizione

Damgaard-Jurik cryptosystem; Damgaard–Jurik cryptosystem; Damgård-Jurik cryptosystem; Damgard–Jurik cryptosystem; Damgard-Jurik cryptosystem

unbreakable         
WIKIMEDIA DISAMBIGUATION PAGE
Unbreakable (album); Unbreakable (single); Unbreakable (song) (disambiguation); Unbreakable (song); Unbreakable (Album); Unbreakable (disambiguation)
¦ adjective not liable to break or able to be broken.
unbreakable         
WIKIMEDIA DISAMBIGUATION PAGE
Unbreakable (album); Unbreakable (single); Unbreakable (song) (disambiguation); Unbreakable (song); Unbreakable (Album); Unbreakable (disambiguation)
1.
Unbreakable objects cannot be broken, usually because they are made of a very strong material.
Tableware for outdoor use should ideally be unbreakable.
ADJ
2.
An unbreakable rule or limit must be obeyed.
One unbreakable rule in our school is that no child can be tested without written parental permission.
ADJ
Goldwasser–Micali cryptosystem         
ASYMMETRIC KEY ENCRYPTION ALGORITHM
Goldwasser-Micali; Goldwasser-Micali encryption; Goldwasser-Micali cryptosystem; Goldwasser-Micali encryption scheme
The Goldwasser–Micali (GM) cryptosystem is an asymmetric key encryption algorithm developed by Shafi Goldwasser and Silvio Micali in 1982. GM has the distinction of being the first probabilistic public-key encryption scheme which is provably secure under standard cryptographic assumptions.

Wikipedia

Damgård–Jurik cryptosystem

The Damgård–Jurik cryptosystem is a generalization of the Paillier cryptosystem. It uses computations modulo n s + 1 {\displaystyle n^{s+1}} where n {\displaystyle n} is an RSA modulus and s {\displaystyle s} a (positive) natural number. Paillier's scheme is the special case with s = 1 {\displaystyle s=1} . The order φ ( n s + 1 ) {\displaystyle \varphi (n^{s+1})} (Euler's totient function) of Z n s + 1 {\displaystyle Z_{n^{s+1}}^{*}} can be divided by n s {\displaystyle n^{s}} . Moreover, Z n s + 1 {\displaystyle Z_{n^{s+1}}^{*}} can be written as the direct product of G × H {\displaystyle G\times H} . G {\displaystyle G} is cyclic and of order n s {\displaystyle n^{s}} , while H {\displaystyle H} is isomorphic to Z n {\displaystyle Z_{n}^{*}} . For encryption, the message is transformed into the corresponding coset of the factor group G × H / H {\displaystyle G\times H/H} and the security of the scheme relies on the difficulty of distinguishing random elements in different cosets of H {\displaystyle H} . It is semantically secure if it is hard to decide if two given elements are in the same coset. Like Paillier, the security of Damgård–Jurik can be proven under the decisional composite residuosity assumption.