This work generalizes Shor’s algorithm into quasi-Shor algorithms by replacing the modular exponentiation with alternative unitary operations. By using the quantum circuits to generate Bell states as the unitary operations, a specific example called the Bell–Shor algorithm was constructed. The system density matrices in the quantum circuits with four distinct input states were calculated in ideal conditions and illustrated through chromatic graphs to witness the evolution of quantum states in the quantum circuits. For the real part of the density matrices, it was revealed that the number of zero elements dramatically declined to only a few points after the operation of the inverse quantum Fourier transformation. Based on this property, a pr...
Quantum computation is becoming an increasingly interesting field, especially with the rise of real ...
The experimental implementation of a quantum algorithm requires the decomposition of unitary operato...
Simulating quantum mechanical evolutions in general is difficult on classical computers because the ...
This work generalizes Shor’s algorithm into quasi-Shor algorithms by replacing the modular exponenti...
In recent years, the field of quantum computation has evolved to a promising research area, with the...
This paper will explore how quantum computers work from a base level and look at mathematical functi...
This work describes the implementation of a compiled version of Shor's algorithm in a photonic syste...
This report discusses Shor’s quantum factorization algorithm and ρ–Pollard’s factorization algorithm...
© 2015 Kieran WoolfeWe develop simulation methods for matrix product operators, and perform simulati...
Recently, a team of scientists from Google claims to have carried a computation on their noisy, inte...
The most spectacular discovery of quantum computation, Shor's algorithm, efficiently solves the prim...
In this paper we will analyse two quantum algorithms that sparked interest in the potential of quant...
In ensemble (or bulk) quantum computation, all computations are performed on an ensemble of computer...
In this diploma paper we present the Shor’s algorithm for factorising numbers, which runs on quantum...
In this research notebook on universal quantum computation for quantum engineers, researchers, and s...
Quantum computation is becoming an increasingly interesting field, especially with the rise of real ...
The experimental implementation of a quantum algorithm requires the decomposition of unitary operato...
Simulating quantum mechanical evolutions in general is difficult on classical computers because the ...
This work generalizes Shor’s algorithm into quasi-Shor algorithms by replacing the modular exponenti...
In recent years, the field of quantum computation has evolved to a promising research area, with the...
This paper will explore how quantum computers work from a base level and look at mathematical functi...
This work describes the implementation of a compiled version of Shor's algorithm in a photonic syste...
This report discusses Shor’s quantum factorization algorithm and ρ–Pollard’s factorization algorithm...
© 2015 Kieran WoolfeWe develop simulation methods for matrix product operators, and perform simulati...
Recently, a team of scientists from Google claims to have carried a computation on their noisy, inte...
The most spectacular discovery of quantum computation, Shor's algorithm, efficiently solves the prim...
In this paper we will analyse two quantum algorithms that sparked interest in the potential of quant...
In ensemble (or bulk) quantum computation, all computations are performed on an ensemble of computer...
In this diploma paper we present the Shor’s algorithm for factorising numbers, which runs on quantum...
In this research notebook on universal quantum computation for quantum engineers, researchers, and s...
Quantum computation is becoming an increasingly interesting field, especially with the rise of real ...
The experimental implementation of a quantum algorithm requires the decomposition of unitary operato...
Simulating quantum mechanical evolutions in general is difficult on classical computers because the ...