Measurement Device Independent Quantum Digital Signature (MDI-QDS): Difference between revisions

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<u>'''Stage 1'''</u> Distribution
<u>'''Stage 1'''</u> Distribution
*'''Input''' Key Length, Threshold values (s_a, s_v)
*'''Input''' Key Length (L), Threshold values (s_a, s_v)
*'''Output''' Seller: <math>S^B_0,S^B_1,S^V_0,S^V_1</math> Buyer: <math>B^0,B^1</math>; Verifier: <math>V^0,V^1</math>
*'''Output''' Seller: <math>S_B^0,S_B^1,S_V^0,S_V^1</math> Buyer: <math>B^0,B^1</math>; Verifier: <math>V^0,V^1</math>
**'''Key Distribution:'''
**'''Key Distribution:'''
#For k = 0,1
#For k = 0,1
##<math>S_B^k=B^k=</math>MDI-KGP(Seller, Buyer, Arbitrator)
##<math>S_B^k=B^k=</math>MDI-KGP(Seller, Buyer, Arbitrator,k)
##<math>S_V^k=V^k=</math>MDI-KGP(Seller, Verifier, Arbitrator)
##<math>S_V^k=V^k=</math>MDI-KGP(Seller, Verifier, Arbitrator,k)


**'''Symmetrisation'''
**'''Symmetrisation'''
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###Verifier counts the number of mismatches (<math>B^m_l!=S^m_l</math>), b=b+1
###Verifier counts the number of mismatches (<math>B^m_l!=S^m_l</math>), b=b+1
# If <math>(b < s_vL/2)\&\&(v < s_vL/2)</math>, Verifier accepts m else he aborts
# If <math>(b < s_vL/2)\&\&(v < s_vL/2)</math>, Verifier accepts m else he aborts
*'''MDI-KGP'''(Seller, Receiver, Arbitrator)
*'''MDI-KGP'''(Seller, Receiver R, Arbitrator,i)
**For k=0,L
#Seller chooses <math>s_{\text{basis}}\epsilon \{X,Z\}</math> and generates <math>|a\rangle</math>
#Seller chooses <math>s_{\text{basis}}\epsilon \{X,Z\}</math> and generates <math>|a\rangle</math>
#Receiver chooses <math>r_{\text{basis}}\epsilon \{X,Z\}</math> and generates <math>|b\rangle</math>
#Receiver chooses <math>r_{\text{basis}}\epsilon \{X,Z\}</math> and generates <math>|b\rangle</math>
#Seller.send(Arbitrator,<math>|a\rangle</math>)
#Seller.send(Arbitrator,<math>|a\rangle</math>)
#Receiver.send(Arbitrator,<math>|b\rangle</math>)
#Receiver.send(Arbitrator,<math>|b\rangle</math>)
#Arbitrator.'''BSM'''(<math>|a\rangle</math>,<math>|b\rangle</math>)
#|\Psi\rangle=Arbitrator.'''BSM'''(<math>|a\rangle</math>,<math>|b\rangle</math>)
#If (<math>|Psi\!={}</math>)\&\&(<math>s_{\text{basis}}=r_{\text{basis}}</math>)
###A^i_R(k)=a
###If (<math>s_{\text{basis}}=r_{\text{basis}}=Z</math>)
####If (|Psi\rangle=\frac{1}{\sqrt{2}}(|00\rangle+|11\rangle))||(|Psi\rangle=\frac{1}{\sqrt{2}}(|00\rangle-|11\rangle)) '''then''' R^i(k)=b
####If (|Psi\rangle=\frac{1}{\sqrt{2}}(|01\rangle+|10\rangle))||(|Psi\rangle=\frac{1}{\sqrt{2}}(|01\rangle-|10\rangle)) '''then''' <math>R^i(k)=\tilde b</math>
###If (<math>s_{\text{basis}}=r_{\text{basis}}=X</math>)
####If (|Psi\rangle=\frac{1}{\sqrt{2}}(|++\rangle+|--\rangle))||(|Psi\rangle=\frac{1}{\sqrt{2}}(|+-\rangle+|-+\rangle)) '''then''' R^i(k)=b
####If (|Psi\rangle=\frac{1}{\sqrt{2}}(|++\rangle-|--\rangle))||(|Psi\rangle=\frac{1}{\sqrt{2}}(|01\rangle-|+-\rangle)) '''then''' <math>R^i(k)=\tilde b</math>
**


==Further Information==
==Further Information==
Write, autoreview, editor, reviewer
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