Efficient quantum tomography of a polynomial subspace

• URL: http://arxiv.org/abs/2503.00255v1
• Date: Sat, 01 Mar 2025 00:09:02 GMT
• Title: Efficient quantum tomography of a polynomial subspace
• Authors: Yat Wong, Ming Yuan, Kevin He, Srivatsan Chakram, Alireza Seif, David I. Schuster, Liang Jiang,
• Abstract summary: We develop a partial quantum tomography method based on direct fidelity estimation (DFE)<n>We investigate the efficiency of this approach under different sets of available measurements for various states.<n>This method can be applied in many situations, including characterizing quantum systems with confined dynamics.
• Score: 8.174725971516818
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: Quantum tomography is crucial for characterizing the quantum states of multipartite systems, but its practicality is often limited by the exponentially large dimension of the Hilbert space. Most existing approaches, such as compressed sensing and tensor network-based tomography, impose structural constraints on the state to enable more resource-efficient characterization. However, not all physical states can be well-approximated with highly structured states. Here, we develop a partial quantum tomography method based on direct fidelity estimation (DFE) that focuses on a neighborhood subspace -- the subspace spanned by states physically close to a given target state. Using this generalized DFE method, we estimate elements of the density operator within this subspace in a self-verifying manner. We investigate the efficiency of this approach under different sets of available measurements for various states and find that the set of available measurements significantly impacts the cost of DFE. For example, we show that Pauli measurements alone are insufficient for performing efficient DFE on all product states, whereas the full set of product measurements is sufficient. This method can be applied in many situations, including characterizing quantum systems with confined dynamics and verifying preparations of quantum states and processes.

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