Treating the effects of a time-dependent classical dephasing environment during quantum logic operations poses a theoretical challenge, as the application of noncommuting control operations gives rise to both dephasing and depolarization errors that must be accounted for in order to understand total average error rates. We develop a treatment based on effective Hamiltonian theory that allows us to efficiently model the effect of classical noise on nontrivial single-bit quantum logic operations composed of arbitrary control sequences. We present a general method to calculate the ensemble-averaged entanglement fidelity to arbitrary order in terms of noise filter functions, and provide explicit expressions to fourth order in the noise strength. In the weak noise limit we derive explicit filter functions for a broad class of piecewise-constant control sequences, and use them to study the performance of dynamically corrected gates, yielding good agreement with brute-force numerics.
Reference:
gGreen, T, Uys, H and Biercuk, MJ. 2012. High-order noise filtering in nontrivial quantum logic gates. Physical Review Letters, vol. 109, DOI: 10.1103/PhysRevLett.109.020501
Green, T., Uys, H., & Biercuk, M. (2012). High-order noise filtering in nontrivial quantum logic gates. http://hdl.handle.net/10204/5992
Green, T, H Uys, and MJ Biercuk "High-order noise filtering in nontrivial quantum logic gates." (2012) http://hdl.handle.net/10204/5992
Green T, Uys H, Biercuk M. High-order noise filtering in nontrivial quantum logic gates. 2012; http://hdl.handle.net/10204/5992.
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