Can NP-complete problems be solved efficiently in the physical universe? I survey proposals including soap bubbles, protein folding, quantum computing, quantum advice, quantum adiabatic algorithms, quantum-mechanical nonlinearities, hidden variables, relativistic time dilation, analog computing, Malament-Hogarth spacetimes, quantum gravity, closed timelike curves, and “anthropic computing.” The section on soap bubbles even includes some “experimental ” results. While I do not believe that any of the proposals will let us solve NP-complete problems efficiently, I argue that by studying them, we can learn something not only about computation but also about physics
There is good evidence that quantum computers are more powerful than classical computers, and that v...
Computer science is based on classical, discreet models of computation such as the Turing machine or...
In theoretical computer science, researchers usually distinguish between feasible problems (that can...
Can NP-complete problems be solved efficiently in the physical universe? I survey proposals includin...
Many real-life problems are, in general, NP-complete, i.e., informally speaking, are difficult to so...
Can NP-complete problems be solved efficiently in the physical universe? Some researchers have claim...
Many real-life problems are, in general, NP-complete, i.e., informally speaking, are difficult to so...
Paper presented at the AIP Conference Proceedings Vol.864 on Quantum Computation: Back Action, Edite...
For some problems, we know feasible algorithms for solving them. Other computational problems (such ...
A concatenation Model for the NP complete problems is given. Stability analysis, Solutional behavior...
I'll discuss how computational complexity---the study of what can and can't be feasibly computed---h...
The theory of NP-completeness [GJ79] is arguably the most important intellectual contribution of The...
Physical modeling translates measured data into a physical model. Physical modeling is a major objec...
In this paper, we show that the satisfiability problem (SAT, for short) can be solved by a quantum T...
Traditional physics assumes that space and time are continuous. However, this reasonable model leads...
There is good evidence that quantum computers are more powerful than classical computers, and that v...
Computer science is based on classical, discreet models of computation such as the Turing machine or...
In theoretical computer science, researchers usually distinguish between feasible problems (that can...
Can NP-complete problems be solved efficiently in the physical universe? I survey proposals includin...
Many real-life problems are, in general, NP-complete, i.e., informally speaking, are difficult to so...
Can NP-complete problems be solved efficiently in the physical universe? Some researchers have claim...
Many real-life problems are, in general, NP-complete, i.e., informally speaking, are difficult to so...
Paper presented at the AIP Conference Proceedings Vol.864 on Quantum Computation: Back Action, Edite...
For some problems, we know feasible algorithms for solving them. Other computational problems (such ...
A concatenation Model for the NP complete problems is given. Stability analysis, Solutional behavior...
I'll discuss how computational complexity---the study of what can and can't be feasibly computed---h...
The theory of NP-completeness [GJ79] is arguably the most important intellectual contribution of The...
Physical modeling translates measured data into a physical model. Physical modeling is a major objec...
In this paper, we show that the satisfiability problem (SAT, for short) can be solved by a quantum T...
Traditional physics assumes that space and time are continuous. However, this reasonable model leads...
There is good evidence that quantum computers are more powerful than classical computers, and that v...
Computer science is based on classical, discreet models of computation such as the Turing machine or...
In theoretical computer science, researchers usually distinguish between feasible problems (that can...