We show how to represent the state and the evolution of a quantum computer (or any system with an $N$--dimensional Hilbert space) in phase space. For this purpose we use a discrete version of the Wigner function which, for arbitrary $N$, is defined in a phase space grid of $2N\times 2N$ points. We compute such Wigner function for states which are relevant for quantum computation. Finally, we discuss properties of quantum algorithms in phase space and present the phase space representation of Grover's quantum search algorithm
Submitted in partial fulfillment of the requirements for the degree of Doctor of Philosophy in Physi...
Schwinger's finite (D) dimensional periodic Hilbert space representations are studied on the toroida...
Since its introduction in the 1930s by Wigner, and its generalisations by Moyal and Weyl, the abilit...
The original Wigner function provides a way of representing in phase space the quantum states of sys...
We analyse some features of the class of discrete Wigner functions that was recently introduced by G...
We introduce quantum states associated with single phase space points in the Wigner formalism for fi...
We analyze the Wigner function constructed on the basis of the discrete rotation and displacement op...
The action-angle representation in quantum mechanics is conceptually quite different from its classi...
We define a Wigner distribution function for a one-dimensional finite quantum system, in which the p...
The phase‐space formulation of quantum mechanics has recently seen increased use in testing quantum ...
The Gottesman–Knill theorem established that stabilizer states and Clifford operations can be effici...
In this research, we construct Wigner functions on discrete phase spaces to represent quantum states...
Generally, quantum states are abstract states that carry probabilistic information of position and ...
We study the Wigner function for a quantum system with a discrete, infinite-dimensional Hilbert spac...
Focusing particularly on one-qubit and two-qubit systems, I explain how the quantum state of a syste...
Submitted in partial fulfillment of the requirements for the degree of Doctor of Philosophy in Physi...
Schwinger's finite (D) dimensional periodic Hilbert space representations are studied on the toroida...
Since its introduction in the 1930s by Wigner, and its generalisations by Moyal and Weyl, the abilit...
The original Wigner function provides a way of representing in phase space the quantum states of sys...
We analyse some features of the class of discrete Wigner functions that was recently introduced by G...
We introduce quantum states associated with single phase space points in the Wigner formalism for fi...
We analyze the Wigner function constructed on the basis of the discrete rotation and displacement op...
The action-angle representation in quantum mechanics is conceptually quite different from its classi...
We define a Wigner distribution function for a one-dimensional finite quantum system, in which the p...
The phase‐space formulation of quantum mechanics has recently seen increased use in testing quantum ...
The Gottesman–Knill theorem established that stabilizer states and Clifford operations can be effici...
In this research, we construct Wigner functions on discrete phase spaces to represent quantum states...
Generally, quantum states are abstract states that carry probabilistic information of position and ...
We study the Wigner function for a quantum system with a discrete, infinite-dimensional Hilbert spac...
Focusing particularly on one-qubit and two-qubit systems, I explain how the quantum state of a syste...
Submitted in partial fulfillment of the requirements for the degree of Doctor of Philosophy in Physi...
Schwinger's finite (D) dimensional periodic Hilbert space representations are studied on the toroida...
Since its introduction in the 1930s by Wigner, and its generalisations by Moyal and Weyl, the abilit...