Measurable Krylov Spaces and Eigenenergy Count in Quantum State Dynamics
Abstract
We define a new Krylov space for the time evolution of a quantum state, which is both quantum-mechanically measurable. Based on our defined spaces, an effective dimension is introduced that provides insight into how expressive the quantum system is. The understanding of the time evolution operator as a map onto a Krylov space is evident from the Taylor expansion of said operator. Current literature focuses on computing different powers of the Hamiltonian to construct a basis for the Krylov state space. One challenge this approach faces is that computing higher powers of the Hamiltonian becomes increasingly difficult for larger systems. Since each basis state is constructed from a different power of the Hamiltonian, the basis states have varying lengths, making the ortho-normalization process challenging. Furthermore, computing high powers of the Hamiltonian increases rounding errors, which can lead to a wrongly increased Krylov space dimension. The first part of our work challenges these issues by defining an equivalent space, where the original basis consists of states of the same length. We demonstrate that a set of different time-evolved states can be used to construct a basis. We subsequently verify the results through numerical analysis, demonstrating that every time-evolved state can be reconstructed using the defined vector space. Based on this new space, we define an effective dimension and analyze its influence on finite-dimensional systems. Our method gives insight into the basis construction of the time evolution operator, which can be computed experimentally. We further show that the Krylov space dimension is equal to the number of pairwise distinct eigenvalues of the Hamiltonian, enabling a method to determine the number of eigenenergies the system has experimentally.
- Publication:
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arXiv e-prints
- Pub Date:
- April 2024
- DOI:
- 10.48550/arXiv.2404.13089
- arXiv:
- arXiv:2404.13089
- Bibcode:
- 2024arXiv240413089C
- Keywords:
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- Quantum Physics;
- High Energy Physics - Theory