We define rewinding operators that invert quantum measurements. Then, we define complexity classes ${\sf RwBQP}$, ${\sf CBQP}$, and ${\sf AdPostBQP}$ as sets of decision problems solvable by polynomial-size quantum circuits with a polynomial number of rewinding operators, cloning operators, and adaptive postselections, respectively. Our main result is that ${\sf BPP}^{\sf PP}\subseteq{\sf RwBQP}={\sf CBQP}={\sf AdPostBQP}\subseteq{\sf PSPACE}$. As a byproduct of this result, we show that any problem in ${\sf PostBQP}$ can be solved with only postselections of outputs whose probabilities are polynomially close to one. Under the strongly believed assumption that ${\sf BQP}\nsupseteq{\sf SZK}$, or the shortest independent vectors problem canno...
We use the powerful tools of counting complexity and generic oracles to help understand the limitati...
The limited computational power of constant-depth quantum circuits can be boosted by adapting future...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Mathematics, 2019Cataloged from...
We define rewinding operators that invert quantum measurements. Then, we define complexity classes R...
AbstractWe use the powerful tools of counting complexity and generic oracles to help understand the ...
The complexity class $PSPACE$ includes all computational problems that can be solved by a classical ...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Electrical Engineering and Comp...
One can fix the randomness used by a randomized algorithm, but there is no analogous notion of fixin...
Previous work by Aaronson and others has es-tablished the complexity class PostBQP, the class of pro...
From the general difficulty of simulating quantum systems using classical systems, and in particular...
Quantum algorithms theoretically outperform classical algorithms in solving problems of increasing s...
In this paper, we extend the techniques used in our previous work to show that there exists a probab...
The class of commuting quantum circuits known as IQP (instantaneous quantum polynomial-time) has bee...
We consider quantum computations comprising only commuting gates, known as IQP computations, and pro...
We consider the tasks of learning quantum states, measurements and channels generated by continuous-...
We use the powerful tools of counting complexity and generic oracles to help understand the limitati...
The limited computational power of constant-depth quantum circuits can be boosted by adapting future...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Mathematics, 2019Cataloged from...
We define rewinding operators that invert quantum measurements. Then, we define complexity classes R...
AbstractWe use the powerful tools of counting complexity and generic oracles to help understand the ...
The complexity class $PSPACE$ includes all computational problems that can be solved by a classical ...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Electrical Engineering and Comp...
One can fix the randomness used by a randomized algorithm, but there is no analogous notion of fixin...
Previous work by Aaronson and others has es-tablished the complexity class PostBQP, the class of pro...
From the general difficulty of simulating quantum systems using classical systems, and in particular...
Quantum algorithms theoretically outperform classical algorithms in solving problems of increasing s...
In this paper, we extend the techniques used in our previous work to show that there exists a probab...
The class of commuting quantum circuits known as IQP (instantaneous quantum polynomial-time) has bee...
We consider quantum computations comprising only commuting gates, known as IQP computations, and pro...
We consider the tasks of learning quantum states, measurements and channels generated by continuous-...
We use the powerful tools of counting complexity and generic oracles to help understand the limitati...
The limited computational power of constant-depth quantum circuits can be boosted by adapting future...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Mathematics, 2019Cataloged from...