Analyzing Prospects for Quantum Advantage in Topological Data Analysis
Lloyd et al. were first to demonstrate the promise of quantum algorithms for computing Betti numbers, a way to characterize topological features of data sets. Here, we propose, analyze, and optimize an improved quantum algorithm for topological data analysis (TDA) with reduced scaling, including a m...
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| creator | Berry, Dominic W Su, Yuan Casper Gyurik King, Robbie Basso, Joao Alexander Del Toro Barba Rajput, Abhishek Wiebe, Nathan Dunjko, Vedran Ryan Babbush |
| description | Lloyd et al. were first to demonstrate the promise of quantum algorithms for computing Betti numbers, a way to characterize topological features of data sets. Here, we propose, analyze, and optimize an improved quantum algorithm for topological data analysis (TDA) with reduced scaling, including a method for preparing Dicke states based on inequality testing, a more efficient amplitude estimation algorithm using Kaiser windows, and an optimal implementation of eigenvalue projectors based on Chebyshev polynomials. We compile our approach to a fault-tolerant gate set and estimate constant factors in the Toffoli complexity. Our analysis reveals that super-quadratic quantum speedups are only possible for this problem when targeting a multiplicative error approximation and the Betti number grows asymptotically. Further, we propose a dequantization of the quantum TDA algorithm that shows that having exponentially large dimension and Betti number are necessary, but insufficient conditions, for super-polynomial advantage. We then introduce and analyze specific problem examples which have parameters in the regime where super-polynomial advantages may be achieved, and argue that quantum circuits with tens of billions of Toffoli gates can solve seemingly classically intractable instances. |
| doi_str_mv | 10.48550/arxiv.2209.13581 |
| format | Article |
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| subjects | Algorithms Chebyshev approximation Data analysis Eigenvalues Fault tolerance Heuristic methods Homology Optimization Physics - Quantum Physics Polynomials Projectors Topology |
| title | Analyzing Prospects for Quantum Advantage in Topological Data Analysis |
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