In order to treat all-to-all-connected quadratic binary optimization problems (QUBOs) with hard- ware quantum annealers, an embedding of the original problem is required due to the sparsity of the topology of the hardware. The embedding of fully connected graphs-typically found in industrial applications incurs a quadratic space overhead and thus a significant overhead in the time to solution. Here, we investigate this embedding penalty of established planar embedding schemes such as square-lattice embedding, embedding on a chimera lattice, and the Lechner-Hauke-Zoller scheme, using simulated quantum annealing on classical hardware. Large-scale quantum Monte Carlo simulation suggests a polynomial time-to-solution overhead. Our results demon...
The observation of an unequivocal quantum speedup remains an elusive objective for quantum computing...
Quantum annealing (QA) has been proposed as a quantum enhanced optimization heuristic exploiting tun...
Quantum(-inspired) annealers show promise in solving combinatorial optimisation problems in practice...
Quantum computing aims to harness the properties of quantum systems to more effectively solve certai...
Embedding Overhead Scaling of Optimization Problems in Quantum Annealing PRX Quantum 2, 040322 (202...
Quantum annealing has the potential to find low energy solutions of NP-hard problems that can be exp...
To date, conventional computers have never been able to efficiently handle certain tasks, where the ...
Quantum annealing is getting increasing attention in combinatorial optimization. The quantum process...
There have been multiple attempts to demonstrate that quantum annealing and, in particular, quantum ...
Quantum annealing belongs to a family of quantum optimization algorithms designed to solve combinato...
We study large-scale applications using a GPU-accelerated version of the massively parallel Jülich u...
We analyze the performance of quantum annealing as a heuristic optimization method to find the absol...
© 2016 IEEE. Can quantum computers solve optimization problems much more quickly than classical comp...
The path integral Monte Carlo simulated quantum annealing algorithm is applied to the optimization o...
Quantum Annealing (QA) can be used to quickly obtain near-optimal solutions for Quadratic Unconstrai...
The observation of an unequivocal quantum speedup remains an elusive objective for quantum computing...
Quantum annealing (QA) has been proposed as a quantum enhanced optimization heuristic exploiting tun...
Quantum(-inspired) annealers show promise in solving combinatorial optimisation problems in practice...
Quantum computing aims to harness the properties of quantum systems to more effectively solve certai...
Embedding Overhead Scaling of Optimization Problems in Quantum Annealing PRX Quantum 2, 040322 (202...
Quantum annealing has the potential to find low energy solutions of NP-hard problems that can be exp...
To date, conventional computers have never been able to efficiently handle certain tasks, where the ...
Quantum annealing is getting increasing attention in combinatorial optimization. The quantum process...
There have been multiple attempts to demonstrate that quantum annealing and, in particular, quantum ...
Quantum annealing belongs to a family of quantum optimization algorithms designed to solve combinato...
We study large-scale applications using a GPU-accelerated version of the massively parallel Jülich u...
We analyze the performance of quantum annealing as a heuristic optimization method to find the absol...
© 2016 IEEE. Can quantum computers solve optimization problems much more quickly than classical comp...
The path integral Monte Carlo simulated quantum annealing algorithm is applied to the optimization o...
Quantum Annealing (QA) can be used to quickly obtain near-optimal solutions for Quadratic Unconstrai...
The observation of an unequivocal quantum speedup remains an elusive objective for quantum computing...
Quantum annealing (QA) has been proposed as a quantum enhanced optimization heuristic exploiting tun...
Quantum(-inspired) annealers show promise in solving combinatorial optimisation problems in practice...