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Accelerating hybrid XOR-CNF Boolean satisfiability problems natively with in-memory computing.

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Summary
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This study introduces a novel hardware accelerator for solving hybrid XOR-CNF Boolean satisfiability (SAT) problems. The memristor-based in-memory computing accelerator significantly enhances speed and energy efficiency for complex cryptographic applications.

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Area of Science:

  • Computer Science
  • Electrical Engineering
  • Computational Complexity

Background:

  • Boolean satisfiability (SAT) is a critical problem in many industries.
  • Hybrid XOR-CNF representations offer efficient solutions for specific SAT instances.
  • Existing methods often require complex translations, impacting performance.

Purpose of the Study:

  • To propose a hardware accelerator architecture for native XOR-CNF SAT problem solving.
  • To leverage in-memory computing with memristor crossbar arrays for efficient computation.
  • To demonstrate performance improvements over conventional approaches.

Main Methods:

  • Developed a novel algorithm for solving hybrid XOR-CNF problems.
  • Implemented the algorithm using memristor crossbar arrays for in-memory computing.
  • Validated the approach through experimental and simulation-based analysis.

Main Results:

  • The proposed accelerator achieved approximately 10x improvement in speed, energy efficiency, and area utilization compared to pure CNF translation.
  • Demonstrated a 10x speedup and 1000x energy efficiency gain over state-of-the-art CPU-based SAT solvers.
  • Successfully solved hard cryptographic benchmarking problems.

Conclusions:

  • Native in-memory computing of XOR-CNF SAT problems offers substantial performance benefits.
  • Memristor-based accelerators are a promising solution for computationally intensive SAT problems.
  • This approach significantly advances the efficiency of SAT solvers in critical applications.