Teleportation-based quantum homomorphic encryption scheme with quasi-compactness and perfect security

Abstract

This article defines encrypted gate, which is denoted by EG[U]:|α→((a,b),Enca,b(U|α)). We present a gate-teleportation-based two-party computation scheme for EG[U], where one party gives arbitrary quantum state |α as input and obtains the encrypted U-computing result Enca,b(U|α), and the other party obtains the random bits a,b. Based on EG[Px](x∈\0,1\), we propose a method to remove the P-error generated in the homomorphic evaluation of T/T-gate. Using this method, we design two non-interactive and perfectly secure QHE schemes named GT and VGT. Both of them are F-homomorphic and quasi-compact (the decryption complexity depends on the T/T-gate complexity). Assume F-homomorphism, non-interaction and perfect security are necessary property, the quasi-compactness is proved to be bounded by O(M), where M is the total number of T/T-gates in the evaluated circuit. VGT is proved to be optimal and has M-quasi-compactness. According to our QHE schemes, the decryption would be inefficient if the evaluated circuit contains exponential number of T/T-gates. Thus our schemes are suitable for homomorphic evaluation of any quantum circuit with low T/T-gate complexity, such as any polynomial-size quantum circuit or any quantum circuit with polynomial number of T/T-gates.