Trap Code for Quantum Authentication

Notation

• ${\displaystyle \rho }$: 1-qubit input state

Protocol Description

• Encoding:

1. Input: ${\displaystyle \rho }$, pair of keys ${\displaystyle k=(k_{1},k_{2})}$
2. Apply an ${\displaystyle [[n,1,d]]}$ error correction code (corrects up to ${\displaystyle t}$ errors, ${\displaystyle d=2t+1}$)
3. Append an additional trap register of ${\displaystyle n}$ qubits in state ${\displaystyle |0\rangle \langle 0|^{\otimes n}}$
4. Append a second additional trap register of ${\displaystyle n}$ qubits in state ${\displaystyle |+\rangle \langle +|^{\otimes n}}$
5. Permute the total ${\displaystyle 3n}$-qubit register by ${\displaystyle \pi _{k_{1}}}$ according to the key ${\displaystyle k_{1}}$
6. Apply a Pauli encryption ${\displaystyle P_{k_{2}}}$ according to key ${\displaystyle k_{2}}$

• Decoding:

1. Input: ${\displaystyle \rho ^{\prime }}$ (state after encoding), pair of keys ${\displaystyle k=(k_{1},k_{2})}$
2. Apply ${\displaystyle P_{k_{2}}}$ according to key ${\displaystyle k_{2}}$
3. Apply inverse permutation ${\displaystyle \pi _{k_{1}}^{\dagger }}$ according to the key ${\displaystyle k_{1}}$
4. Measure the last ${\displaystyle n}$ qubits in the Hadamard basis
5. Measure the second last ${\displaystyle n}$ qubits in the computational basis
   a. If the two measurements result in ${\displaystyle |+\rangle \langle +|}$ and ${\displaystyle |0\rangle \langle 0|}$, an additional flag qubit in state ${\displaystyle |\mathrm {ACC} \rangle \langle \mathrm {ACC} |}$ is appended and the quantum message is decoded according to the error correction code
   b. Otherwise, an additional flag qubit in state ${\displaystyle |\mathrm {REJ} \rangle \langle \mathrm {REJ} |}$ is appended and the (disturbed) encoded quantum message is replaced by a fixed state ${\displaystyle \Omega }$

References

1. Broadbent et al. (2012)
2. Broadbent and Wainewright (2016).