A Logarithm Depth Quantum Converter: From One-hot Encoding to Binary Encoding

TL;DR

This paper introduces a quantum circuit that efficiently converts between one-hot and binary encoding of vectors using the Edick state, achieving exponential speedup with logarithmic depth.

Contribution

The authors propose a novel quantum circuit for encoding conversion that significantly improves speed and resource efficiency over previous methods.

Findings

Achieves exponential speedup with O(log^2 N) depth

Uses O(N) circuit size

Efficiently converts between encoding schemes

Abstract

Within the quantum computing, there are two ways to encode a normalized vector $\{ \alpha_i \}$. They are one-hot encoding and binary coding. The one-hot encoding state is denoted as $\left | \psi_O^{(N)} \right \rangle=\sum_{i=0}^{N-1} \alpha_i \left |0 \right \rangle^{\otimes N-i-1} \left |1 \right \rangle \left |0 \right \rangle ^{\otimes i}$ and the binary encoding state is denoted as $\left | \psi_B^{(N)} \right \rangle=\sum_{i=0}^{N-1} \alpha_i \left |b_i \right \rangle$, where $b_i$ is interpreted in binary of $i$ as the tensor product sequence of qubit states. In this paper, we present a method converting between the one-hot encoding state and the binary encoding state by taking the Edick state as the transition state, where the Edick state is defined as $\left | \psi_E^{(N)} \right \rangle=\sum_{i=0}^{N-1} \alpha_i \left |0 \right \rangle^{\otimes N-i-1} \left |1 \right \rangle ^{\otimes i}$. Compared with the early work, our circuit achieves the exponential speedup with $O(\log^2 N)$ depth and $O(N)$ size.