Abstract
The dynamics of nonlinear systems qualitatively change depending on their parameters, which is called bifurcation. A quantum-mechanical nonlinear oscillator can yield a quantum superposition of two oscillation states, known as a Schrödinger cat state, via quantum adiabatic evolution through its bifurcation point. Here we propose a quantum computer comprising such quantum nonlinear oscillators, instead of quantum bits, to solve hard combinatorial optimization problems. The nonlinear oscillator network finds optimal solutions via quantum adiabatic evolution, where nonlinear terms are increased slowly, in contrast to conventional adiabatic quantum computation or quantum annealing, where quantum fluctuation terms are decreased slowly. As a result of numerical simulations, it is concluded that quantum superposition and quantum fluctuation work effectively to find optimal solutions. It is also notable that the present computer is analogous to neural computers, which are also networks of nonlinear components. Thus, the present scheme will open new possibilities for quantum computation, nonlinear science, and artificial intelligence.
Highlights
It is notable that the classical model can find optimal solutions with high probability
This result comes from the fact that the classical model can approximately solve the Ising problem
The high success probability for the classical model means that the approximation is fairly good
Summary
A cat state is generated via quantum adiabatic evolution as follows. If we have N independent KPOs, we will obtain a superposition of 2N oscillation states via the quantum-mechanical bifurcation described above. We show that the KPO network can solve the Ising problem via quantum adiabatic evolution.
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