Abstract The efficient preparation of quantum states is an important step in the execution of many quantum algorithms. In the noisy intermediate-scale quantum (NISQ) computing era, this is a significant challenge given quantum resources are scarce and typically only low-depth quantum circuits can be implemented on physical devices. We present a genetic algorithm for state preparation (GASP) which generates relatively low-depth quantum circuits for initialising a quantum computer in a specified quantum state. The method uses a basis set of $$R_x$$ R x , $$R_y$$ R y , $$R_z$$ R z , and CNOT gates and a genetic algorithm to systematically generate circuits to synthesize the target state to the required fidelity. GASP can produce more efficient...
In this paper we present an approach to find quantum circuits suitable to mimic probabilistic and se...
While advances in quantum hardware occur in modest steps, simulators running on classical computers ...
Due to the non- intuitive nature of Quantum algorithms, it becomes difficult for a classically train...
We study the approximate state preparation problem on noisy intermediate-scale quantum (NISQ) comput...
Quantum computing is an emerging technology that combines the principles of both computer science an...
Quantum Computing represents the next big step towards speed boost in computation, which promises ma...
Abstract: In this paper we focus on a general approach of using genetic algorithm (GA) to evolve Qua...
As noisy intermediate-scale quantum (NISQ) devices grow in number of qubits, determining good or eve...
Large faulttolerant universal gate quantum computers will provide a major speedup to a variety of ...
In this article we encompass the first comprehensive work in the process of translating modern optim...
Recent development in quantum technology have shown that quan-tum computer can provide a dramatic ad...
It has been experimentally proven that realizing universal quantum gates using higher-radices logic ...
Although the concept of quantum computing has existed for decades, the technology needed to successf...
Computationally expensive applications, including machine learning, chemical simulations, and financ...
We employ a machine learning-enabled approach to quantum state engineering based on evolutionary alg...
In this paper we present an approach to find quantum circuits suitable to mimic probabilistic and se...
While advances in quantum hardware occur in modest steps, simulators running on classical computers ...
Due to the non- intuitive nature of Quantum algorithms, it becomes difficult for a classically train...
We study the approximate state preparation problem on noisy intermediate-scale quantum (NISQ) comput...
Quantum computing is an emerging technology that combines the principles of both computer science an...
Quantum Computing represents the next big step towards speed boost in computation, which promises ma...
Abstract: In this paper we focus on a general approach of using genetic algorithm (GA) to evolve Qua...
As noisy intermediate-scale quantum (NISQ) devices grow in number of qubits, determining good or eve...
Large faulttolerant universal gate quantum computers will provide a major speedup to a variety of ...
In this article we encompass the first comprehensive work in the process of translating modern optim...
Recent development in quantum technology have shown that quan-tum computer can provide a dramatic ad...
It has been experimentally proven that realizing universal quantum gates using higher-radices logic ...
Although the concept of quantum computing has existed for decades, the technology needed to successf...
Computationally expensive applications, including machine learning, chemical simulations, and financ...
We employ a machine learning-enabled approach to quantum state engineering based on evolutionary alg...
In this paper we present an approach to find quantum circuits suitable to mimic probabilistic and se...
While advances in quantum hardware occur in modest steps, simulators running on classical computers ...
Due to the non- intuitive nature of Quantum algorithms, it becomes difficult for a classically train...