A Parallel and Distributed Quantum SAT Solver Based on Entanglement and Teleportation
Boolean satisfiability (SAT) solving is a fundamental problem in computer science. Finding efficient algorithms for SAT solving has broad implications in many areas of computer science and beyond. Quantum SAT solvers have been proposed in the literature based on Grover’s algorithm. Although existing quantum SAT solvers can consider all possible inputs at once, they evaluate each clause in the formula one by one sequentially, making the time complexity O(m), linear to the number of clauses m, per Grover iteration. In this work, we develop a parallel quantum SAT solver, which reduces the time complexity in each iteration to constant time O(1) by utilising extra entangled qubits. To further improve the scalability of our solution in case of extremely large problems, we develop a distributed version of the proposed parallel SAT solver based on quantum teleportation such that the total qubits required are shared and distributed among a set of quantum computers (nodes), and the quantum SAT solving is accomplished collaboratively by all the nodes. We prove the correctness of our approaches and evaluate them in simulations and real quantum computers.
Funding
MOE-T1-1/2022-43
History
Journal/Conference/Book title
30th International Conference on Tools and Algorithms for the Construction and Analysis of Systems,TACAS 2024Publication date
2024-04-05Version
- Published