Measurement-Only Universal Blind Quantum Computation: Difference between revisions

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*'''Output:''' Client: Final Outcome
*'''Output:''' Client: Final Outcome
#Server’s preparation
#Server’s preparation
##Server creates a resource state Gmxnxo
##Server creates a resource state <math>G_{\text{mxnxo}}</math>
#Interaction and Computation For i= 1 →m, j= 1 →n, k= 1 →o
#Interaction and Computation
##For i= 1,2,...m, j= 1,2,...n, k= 1,2,...o
##[Protocol 1a]
##[Protocol 1a]
###Server directly sends the qubit <math>|\psi\rangle_{i,j,k}</math> to Client
###Server sends <math>|\psi\rangle_{i,j,k}\rangle</math> to Client
###Client measures his qubit in the measurement basis according to the measurement pattern
###Client measures <math>|\psi\rangle_{i,j,k}\rangle</math> in the required measurement basis according to her measurement pattern
##[Protocol 1b]
##[Protocol 1b]
###Server creates Bell pair  
###Server creates [[Glossary#Bell States|Bell pair]] <math>\phi_{1,2}=\frac{1}{\sqrt{2}}(|00\rangle+|11\rangle)</math>
###Server sends one half (<math>|\phi_2\rangle</math>) of the Bell pair to Client
###Server sends to Client (<math>|\phi_2\rangle</math>) and waits for Client's response
###Client tells her response to Server if she received the sent qubit or not iv. If she didn’t, Server repeats the previous two processes, otherwise
###Client checks if she received and tells the Server as Client.Response()
###Client measures her share of entangled qubit (<math>|\phi_2\rangle</math>) in measurement basis {<math>|0\rangle</math> &plusmn; <math>e^{i\theta}|1\rangle</math>} determined by measurement pattern.  in case of Clifford gates while {<math>\pi/4</math>} in case of non-Clifford gates.
###'''If Client.Response()=No''', Server repeats the previous two steps
###Server uses gate teleportation to apply this unknown gate on the qubit of resource state as follows
###'''Else''' Client measures (<math>|\phi_2\rangle</math>) in measurement basis {<math>|0\rangle \pm e^{i\theta}|1\rangle</math> determined by measurement pattern.
####He entangles his share of Bell pair with the qubit of the resource state <math>|\psi\rangle_{i,j,k}</math> by performing CZ
###'''Server's Computation: [[Glossary#Gate Teleportation]]'''
####He measures the qubit in the register, <math>|\psi\rangle_{i,j,k}</math> in X basis ({<math>|+\rangle,|-\rangle</math>}) and communicates the outcome to the Client. This applies the required measurement on the qubit of the resource state with some correction depending on the outcome
####He entangles <math>|\phi_2\rangle</math> with <math>|\psi\rangle_{i,j,k}</math> by performing [[Gossary#Quantum Gates|C-Z]]
####Client records Server’s outcome and uses it when computing the final result or measurement angles for further qubits
####He measures <math>|\psi\rangle_{i,j,k}</math> in X basis ({<math>|+\rangle,|-\rangle</math>})  
####Server's applies correction on the classical outcome using Gate Teleporation.
###Server communicates the corrected outcome.
####Client records Server’s outcome and uses it when computing the final result or measurement angles for further qubits.
 
*Interaction and Computation steps are repeated until all the qubits of resource state are measured.
*Interaction and Computation steps are repeated until all the qubits of resource state are measured.


<div style='text-align: right;'>''*contributed by Shraddha Singh''</div>
<div style='text-align: right;'>''*contributed by Shraddha Singh''</div>
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