Efficient Analog Circuits for Boolean Satisfiability

Yin, Xunzhao; Sedighi, Behnam; Varga, Melinda; Ercsey-Ravasz, Mária; Toroczkai, Zoltán; Hu, Xiaobo Sharon

doi:10.1109/tvlsi.2017.2754192

Cited by 30 publications

(26 citation statements)

References 38 publications

(75 reference statements)

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“…The power consumption of the total MTJ and heavy metal layer structures is approximately about 20% of the total power consumption of the system. Similarly, a recent work of a hardware realization 16 of an analog approach 8 , also explains that their overall power consumption to be significant (numerical value not specified), due to the usage of op-amps. In another design 15 , the CNN based SAT solving algorithm 9 used in our work was realized using op-amp based integrators.…”

Section: Resultsmentioning

confidence: 99%

“…However, implementing this set of analog formulae using a digital computer will diminish the polynomial time benefits, due to varying computational complexities between different time steps. Also, a hardware implementation of this analog k -SAT solver 8 is not ideal 16 , due to the exponential energy fluctuations in the system. Consequently, a Cellular Neural Network (CNN) based analog SAT solver with bounded variables was proposed 9 , and it is more appealing for hardware implementations.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Analog Approach to Constraint Satisfaction Enabled by Spin Orbit Torque Magnetic Tunnel Junctions

Wijesinghe

Liyanagedera

Roy

2018

Sci Rep

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Boolean satisfiability (k-SAT) is an NP-complete (k ≥ 3) problem that constitute one of the hardest classes of constraint satisfaction problems. In this work, we provide a proof of concept hardware based analog k-SAT solver, that is built using Magnetic Tunnel Junctions (MTJs). The inherent physics of MTJs, enhanced by device level modifications, is harnessed here to emulate the intricate dynamics of an analog satisfiability (SAT) solver. In the presence of thermal noise, the MTJ based system can successfully solve Boolean satisfiability problems. Most importantly, our results exhibit that, the proposed MTJ based hardware SAT solver is capable of finding a solution to a significant fraction (at least 85%) of hard 3-SAT problems, within a time that has a polynomial relationship with the number of variables(<50).

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Analog Approach to Constraint Satisfaction Enabled by Spin Orbit Torque Magnetic Tunnel Junctions

Wijesinghe

Liyanagedera

Roy

2018

Sci Rep

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“…These numbers certainly depend on the digital hardware used. Note that in an analog circuit implementation, the current flow or voltage behavior would correspond to the equations of the solver, eliminating numerical integration issues and thus the algorithm should run much faster ( 46 shows a possible 10 4 speedup).…”

Section: Resultsmentioning

confidence: 99%

“…Instead of a numerical implementation on a digital computer, one would ideally like to use a direct implementation by analog circuits, the feasibility of which has been shown in ref. 46 , as it promises to be a faster (by orders of magnitude) and more efficient approach. One reason for this is that in such analog circuits the von Neumann bottleneck is eliminated, with the circuit itself serving its own processor and memory, see ref.…”

Section: Discussionmentioning

confidence: 99%

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A continuous-time MaxSAT solver with high analog performance

Molnár

Varga

et al. 2018

Nat Commun

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Many real-life optimization problems can be formulated in Boolean logic as MaxSAT, a class of problems where the task is finding Boolean assignments to variables satisfying the maximum number of logical constraints. Since MaxSAT is NP-hard, no algorithm is known to efficiently solve these problems. Here we present a continuous-time analog solver for MaxSAT and show that the scaling of the escape rate, an invariant of the solver’s dynamics, can predict the maximum number of satisfiable constraints, often well before finding the optimal assignment. Simulating the solver, we illustrate its performance on MaxSAT competition problems, then apply it to two-color Ramsey number R(m, m) problems. Although it finds colorings without monochromatic 5-cliques of complete graphs on N ≤ 42 vertices, the best coloring for N = 43 has two monochromatic 5-cliques, supporting the conjecture that R(5, 5) = 43. This approach shows the potential of continuous-time analog dynamical systems as algorithms for discrete optimization.

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OIM: Oscillator-Based Ising Machines for Solving Combinatorial Optimisation Problems

Wang

Roychowdhury

2019

Lecture Notes in Computer Science

138

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We present a new way to make Ising machines, i.e., using networks of coupled self-sustaining nonlinear oscillators. Our scheme is theoretically rooted in a novel result that establishes that the phase dynamics of coupled oscillator systems, under the influence of subharmonic injection locking, are governed by a Lyapunov function that is closely related to the Ising Hamiltonian of the coupling graph. As a result, the dynamics of such oscillator networks evolve naturally to local minima of the Lyapunov function. Two simple additional steps (i.e., adding noise, and turning sub-harmonic locking on and off smoothly) enable the network to find excellent solutions of Ising problems. We demonstrate our method on Ising versions of the MAX-CUT and graph colouring problems, showing that it improves on previously published results on several problems in the G benchmark set. Our scheme, which is amenable to realisation using many kinds of oscillators from different physical domains, is particularly well suited for CMOS IC implementation, offering significant practical advantages over previous techniques for making Ising machines. We present working hardware prototypes using CMOS electronic oscillators.

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Efficient Analog Circuits for Boolean Satisfiability

Cited by 30 publications

References 38 publications

Analog Approach to Constraint Satisfaction Enabled by Spin Orbit Torque Magnetic Tunnel Junctions

Analog Approach to Constraint Satisfaction Enabled by Spin Orbit Torque Magnetic Tunnel Junctions

A continuous-time MaxSAT solver with high analog performance

OIM: Oscillator-Based Ising Machines for Solving Combinatorial Optimisation Problems

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