Complexity of Normalized Persistence Problems for Topological Data Analysis and Local Hamiltonians
Abstract
Topological data analysis (TDA) is a machine learning technique that uses topology to extract patterns from data and has shown the potential to exhibit quantum advantage. A key concept in TDA is persistent homology, which measures the robustness of topological information at different lengthscales. In this paper, we introduce and study the problem of normalized persistence, a practically motivated and easily interpretable version of persistent homology that counts the fraction of holes that persist at different lengthscales. We prove that a variant of normalized persistence is DQC1-hard and contained in BQP, giving evidence of an exponential quantum speedup for TDA under the standard assumption that DQC1 ⊂eq BPP. These are the first DQC1-hardness results that are directly applicable to TDA instances. We also find a close connection between normalized persistence and the complexity of estimating spectral quantities in the low-energy subspace of local Hamiltonians. We study a family of such problems, including a low-energy normalized subtrace and spectral density. We show that these are DQC1-hard for O(1)-local Hamiltonians, strengthening previous results that required log-local interactions. We also introduce a variant of DQC1 with perfect completeness (SDQC1) to characterize the hardness of problems normalized by an exact kernel. This includes normalized persistence for O(1)-local Hamiltonians, which we show is SDQC1-hard.
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