Dimension Reduction Using Quantum Wavelet Transform on a High-Performance Reconfigurable Computer

El-Araby, Esam

doi:10.1155/2019/1949121

Cited by 6 publications

(2 citation statements)

References 37 publications

(72 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The works discussed so far (Khalid et al, 2004;Aminian et al, 2008;Lee et al, 2016;Pilch and Dlugopolski, 2019) demonstrate the promise for emulating quantum circuits on FPGAs, albeit for low number of emulated qubits. Mahmud and El-Araby (2019) focus on scalability, presenting two architectures for emulation. The first is a CMAC (complex multiply-and-accumulate) unit-based system, which for a given quantum circuit, relies on having the full algorithm matrix precomputed.…”

Section: Quantum Computer Simulations and Emulations Using Fpgasmentioning

confidence: 99%

“…However, most of the research so far only considered circuits with few ( < 10) qubits and also did not consider circuit transformation techniques for reducing the number of qubits. The work which demonstrated the most promise for scaling to a high number of qubits recently is Mahmud and El-Araby (2019) and Mahmud et al (2020) specialized kernel-based approach, using which they ran a 30-qubit QHT, and a 32-qubit Grover's search circuits on an FPGA. While this approach reaches the highest number of qubits simulated on an FPGA in the literature, of which we are aware, it is not very easily reusable.…”

Section: Quantum Computer Simulations and Emulations Using Fpgasmentioning

confidence: 99%

See 1 more Smart Citation

Investigating hardware acceleration for simulation of CFD quantum circuits

2022

View full text Add to dashboard Cite

Among the many computational models for quantum computing, the Quantum Circuit Model is the most well-known and used model for interacting with current quantum hardware. The practical implementation of quantum computers is a very active research field. Despite this progress, access to physical quantum computers remains relatively limited. Furthermore, the existing machines are susceptible to random errors due to quantum decoherence, as well as being limited in number of qubits, connectivity and built-in error correction. Simulation on classical hardware is therefore essential to allow quantum algorithm researchers to test and validate new algorithms in a simulated-error environment. Computing systems are becoming increasingly heterogeneous, using a variety of hardware accelerators to speed up computational tasks. One such type of accelerators, Field Programmable Gate Arrays (FPGAs), are reconfigurable circuits that can be programmed using standardized high-level programming models such as OpenCL and SYCL. FPGAs allow to create specialized highly-parallel circuits capable of mimicking the quantum parallelism properties of quantum gates, in particular for the class of quantum algorithms where many different computations can be performed concurrently or as part of a deep pipeline. They also benefit from very high internal memory bandwidth. This paper focuses on the analysis of quantum algorithms for applications in computational fluid dynamics. In this work we introduce novel quantum-circuit implementations of model lattice-based formulations for fluid dynamics, specifically the D1Q3 model using quantum computational basis encoding, as well as, efficient simulation of the circuits using FPGAs. This work forms a step toward quantum circuit formulation of the Lattice Boltzmann Method (LBM). For the quantum circuits implementing the nonlinear equilibrium distribution function in the D1Q3 lattice model, it is shown how circuit transformations can be introduced that facilitate the efficient simulation of the circuits on FPGAs, exploiting their fine-grained parallelism. We show that these transformations allow us to exploit more parallelism on the FPGA and improve memory locality. Preliminary results show that for this class of circuits the introduced transformations improve circuit execution time. We show that FPGA simulation of the reduced circuits results in more than 3× improvement in performance per Watt compared to the CPU simulation. We also present results from evaluating the same kernels on a GPU.

show abstract