Gottesman and Chuang Quantum Digital Signature: Difference between revisions

Line 27: Line 27:
*'''Notations Used:'''
*'''Notations Used:'''
==Relevant Papers==
==Relevant Papers==
*Theoretical Papers
'''Theoretical Papers'''
# [https://arxiv.org/abs/quant-ph/0105032 GC-QDS (2001)] uses [[quantum one way function]] f(); Private keys: classical input x, Public keys: quantum output f(x). '''Requires''' quantum memory, quantum one way function, authenticated quantum and classical channels, [[SWAP Test]] (universal quantum computer). [[Unconditionally Secure]]
# [https://arxiv.org/abs/quant-ph/0105032 GC-QDS (2001)] uses [[quantum one way function]] f(); Private keys: classical input x, Public keys: quantum output f(x).  
#[https://arxiv.org/abs/quant-ph/0601130 ACJ (2006)] discusses coherent states comparison with a QDS scheme outlined in the last section. Protocol uses the same protocol as (2) but replaces qubits with [[coherent states]], thus replacing SWAP-Test with [[Coherent State Comparison]]. Additionally, it also requires quantum memory, authenticated quantum and classical channels, [[multiports]]. [[Unconditionally Secure]]
##'''Requires''' quantum memory, quantum one way function, authenticated quantum and classical channels, [[SWAP Test]] (universal quantum computer).
#[https://www.sciencedirect.com/science/article/pii/S0030402617308069 SWZY (2017)] Discusses an attack and suggests corrections on existing QDS scheme using single qubit rotations. Protocol uses rotation, qubits, [[one-way hash function]]; Private keys: angle of rotation, Public keys: string of rotated quantum states. '''Requires''' [[random number generator]], [[one-way hash function]], quantum memory, key distribution. [[Computationally Secure]]
##Security: [[Information-theoretic]]
[[Category: Quantum Memory Network Stage]]
#[https://arxiv.org/abs/quant-ph/0601130 ACJ (2006)] discusses coherent states comparison with a QDS scheme outlined in the last section.  
*Experimental Papers
##Protocol uses the same protocol as (2) but replaces qubits with [[coherent states]], thus replacing SWAP-Test with [[Coherent State Comparison]]. Additionally, it also requires quantum memory, authenticated quantum and classical channels, [[multiports]].  
##Security: [[Information-theoretic]]
#[https://www.sciencedirect.com/science/article/pii/S0030402617308069 SWZY (2017)] Discusses an attack and suggests corrections on existing QDS scheme using single qubit rotations. Protocol uses rotation, qubits, [[one-way hash function]]; Private keys: angle of rotation, Public keys: string of rotated quantum states.  
##'''Requires''' [[random number generator]], [[one-way hash function]], quantum memory, key distribution.  
##'''Security:''' [[Computational]]
'''Experimental Papers'''
#[https://www.nature.com/articles/ncomms2172 CCDAJB (2012)] uses phase encoded coherent states, [[coherent state comparison]]
#[https://www.nature.com/articles/ncomms2172 CCDAJB (2012)] uses phase encoded coherent states, [[coherent state comparison]]
##Loss from multiport=7.5 dB, Length of the key= <math>10^6</math>
##Loss from multiport=7.5 dB, Length of the key= <math>10^6</math>
Write, autoreview, editor, reviewer
3,129

edits