Your search keyword '"Hypergraph min-cut"' showing total 4 results

1. Multicriteria cuts and size-constrained k-cuts in hypergraphs

Author

Calvin Beideman, Karthekeyan Chandrasekaran, and Chao Xu

Subjects

Discrete mathematics, 021103 operations research, Multiobjective Optimization, Hypergraph-k-cut, General Mathematics, Numerical analysis, 0211 other engineering and technologies, Mathematics of computing → Combinatorial optimization, 0102 computer and information sciences, 02 engineering and technology, Hypergraph min-cut, 01 natural sciences, Computer Science::Discrete Mathematics, 010201 computation theory & mathematics, Contraction (operator theory), Software, MathematicsofComputing_DISCRETEMATHEMATICS, Mathematics

Abstract

We address counting and optimization variants of multicriteria global min-cut and size-constrained min-k-cut in hypergraphs. 1) For an r-rank n-vertex hypergraph endowed with t hyperedge-cost functions, we show that the number of multiobjective min-cuts is O(r2^{tr}n^{3t-1}). In particular, this shows that the number of parametric min-cuts in constant rank hypergraphs for a constant number of criteria is strongly polynomial, thus resolving an open question by Aissi, Mahjoub, McCormick, and Queyranne [Aissi et al., 2015]. In addition, we give randomized algorithms to enumerate all multiobjective min-cuts and all pareto-optimal cuts in strongly polynomial-time. 2) We also address node-budgeted multiobjective min-cuts: For an n-vertex hypergraph endowed with t vertex-weight functions, we show that the number of node-budgeted multiobjective min-cuts is O(r2^{r}n^{t+2}), where r is the rank of the hypergraph, and the number of node-budgeted b-multiobjective min-cuts for a fixed budget-vector b ∈ ℝ^t_+ is O(n²). 3) We show that min-k-cut in hypergraphs subject to constant lower bounds on part sizes is solvable in polynomial-time for constant k, thus resolving an open problem posed by Queyranne [Guinez and Queyranne, 2012]. Our technique also shows that the number of optimal solutions is polynomial. All of our results build on the random contraction approach of Karger [Karger, 1993]. Our techniques illustrate the versatility of the random contraction approach to address counting and algorithmic problems concerning multiobjective min-cuts and size-constrained k-cuts in hypergraphs.

Published

2021

2. Efficient Distribution of Quantum Circuits

Author

Ranjani G Sundaram and Himanshu Gupta and C. R. Ramakrishnan, G Sundaram, Ranjani, Gupta, Himanshu, Ramakrishnan, C. R., Ranjani G Sundaram and Himanshu Gupta and C. R. Ramakrishnan, G Sundaram, Ranjani, Gupta, Himanshu, and Ramakrishnan, C. R.

Abstract

Quantum computing hardware is improving in robustness, but individual computers still have small number of qubits (for storing quantum information). Computations needing a large number of qubits can only be performed by distributing them over a network of smaller quantum computers. In this paper, we consider the problem of distributing a quantum computation, represented as a quantum circuit, over a homogeneous network of quantum computers, minimizing the number of communication operations needed to complete every step of the computation. We propose a two-step solution: dividing the given circuit’s qubits among the computers in the network, and scheduling communication operations, called migrations, to share quantum information among the computers to ensure that every operation can be performed locally. While the first step is an intractable problem, we present a polynomial-time solution for the second step in a special setting, and a O(log n)-approximate solution in the general setting. We provide empirical results which show that our two-step solution outperforms existing heuristic for this problem by a significant margin (up to 90%, in some cases).

Published

2021

3. Multicriteria Cuts and Size-Constrained k-Cuts in Hypergraphs

Author

Calvin Beideman and Karthekeyan Chandrasekaran and Chao Xu, Beideman, Calvin, Chandrasekaran, Karthekeyan, Xu, Chao, Calvin Beideman and Karthekeyan Chandrasekaran and Chao Xu, Beideman, Calvin, Chandrasekaran, Karthekeyan, and Xu, Chao

Abstract

We address counting and optimization variants of multicriteria global min-cut and size-constrained min-k-cut in hypergraphs. 1) For an r-rank n-vertex hypergraph endowed with t hyperedge-cost functions, we show that the number of multiobjective min-cuts is O(r2^{tr}n^{3t-1}). In particular, this shows that the number of parametric min-cuts in constant rank hypergraphs for a constant number of criteria is strongly polynomial, thus resolving an open question by Aissi, Mahjoub, McCormick, and Queyranne [Aissi et al., 2015]. In addition, we give randomized algorithms to enumerate all multiobjective min-cuts and all pareto-optimal cuts in strongly polynomial-time. 2) We also address node-budgeted multiobjective min-cuts: For an n-vertex hypergraph endowed with t vertex-weight functions, we show that the number of node-budgeted multiobjective min-cuts is O(r2^{r}n^{t+2}), where r is the rank of the hypergraph, and the number of node-budgeted b-multiobjective min-cuts for a fixed budget-vector b ∈ ℝ^t_+ is O(n²). 3) We show that min-k-cut in hypergraphs subject to constant lower bounds on part sizes is solvable in polynomial-time for constant k, thus resolving an open problem posed by Queyranne [Guinez and Queyranne, 2012]. Our technique also shows that the number of optimal solutions is polynomial. All of our results build on the random contraction approach of Karger [Karger, 1993]. Our techniques illustrate the versatility of the random contraction approach to address counting and algorithmic problems concerning multiobjective min-cuts and size-constrained k-cuts in hypergraphs.

Published

2020

4. Efficient Distribution of Quantum Circuits

Author

G Sundaram, Ranjani, Gupta, Himanshu, and Ramakrishnan, C. R.

Subjects

Hypergraph Min-Cut, Computing methodologies → Distributed algorithms, Computing methodologies → Distributed computing methodologies, Distributed Quantum Computing

Abstract

Quantum computing hardware is improving in robustness, but individual computers still have small number of qubits (for storing quantum information). Computations needing a large number of qubits can only be performed by distributing them over a network of smaller quantum computers. In this paper, we consider the problem of distributing a quantum computation, represented as a quantum circuit, over a homogeneous network of quantum computers, minimizing the number of communication operations needed to complete every step of the computation. We propose a two-step solution: dividing the given circuit’s qubits among the computers in the network, and scheduling communication operations, called migrations, to share quantum information among the computers to ensure that every operation can be performed locally. While the first step is an intractable problem, we present a polynomial-time solution for the second step in a special setting, and a O(log n)-approximate solution in the general setting. We provide empirical results which show that our two-step solution outperforms existing heuristic for this problem by a significant margin (up to 90%, in some cases)., LIPIcs, Vol. 209, 35th International Symposium on Distributed Computing (DISC 2021), pages 41:1-41:20

Published

2021