Abstract
The identifiability of a system is concerned with whether the unknown parameters in the system can be uniquely determined with all the possible data generated by a certain experimental setting. A test of quantum Hamiltonian identifiability is an important tool to save time and cost when exploring the identification capability of quantum probes and experimentally implementing quantum identification schemes. In this paper, we generalize the identifiability test based on the Similarity Transformation Approach (STA) in classical control theory and extend it to the domain of quantum Hamiltonian identification. We employ STA to prove the identifiability of spin-1/2 chain systems with arbitrary dimension assisted by single-qubit probes. We further extend the traditional STA method by proposing a Structure Preserving Transformation (SPT) method for non-minimal systems. We use the SPT method to introduce an indicator for the existence of economic quantum Hamiltonian identification algorithms, whose computational complexity directly depends on the number of unknown parameters (which could be much smaller than the system dimension). Finally, we give an example of such an economic Hamiltonian identification algorithm and perform simulations to demonstrate its effectiveness.
Highlights
T HERE is growing interest in quantum system research, aiming to develop advanced technology, including quantum computation, quantum communication [1], and quantum sensing [2]
We have extended the similarity transformation approach (STA) method in classical control theory to the domain of quantum Hamiltonian identification and employed the STA method to study the concept of identifiability of time-independent Hamiltonians
The STA has been demonstrated to be a powerful tool to analyze the identifiability for quantum systems with arbitrary dimension, which is helpful for further designing identification algorithms
Summary
T HERE is growing interest in quantum system research, aiming to develop advanced technology, including quantum computation, quantum communication [1], and quantum sensing [2]. We employ the SPT method to prove that it is always possible to estimate one unknown parameter in the system matrix using a designed experimental setting This conclusion serves as an indicator for the existence of “economic” quantum Hamiltonian identification algorithms, whose computational complexity directly depends on the number of unknown parameters. 3) To analyze general nonminimal systems, an SPT application is developed to present an indicator for the existence of economic Hamiltonian identification algorithms, which have computational complexity directly depending on the number of unknown parameters. One example of such identification algorithms is presented. Define x the largest integer that is not larger than x
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
