Scaling reconfigurable emulation of quantum algorithms at high precision and high throughput

Abstract: Summary The general approach for emulating quantum algorithms on classical platforms has been through representing them as gate‐based quantum circuits. However, direct implementation of quantum circuits significantly increases the hardware resource utilization and system latency of classical emulators. In this paper, we investigate multiple implementation models alternative to conventional emulation approaches, as feasible solutions to the scalability problem in classical emulation of quantum circuits. In the … Show more

“…In this section, we elaborate our methodology that uses QHT to achieve dimension reduction. We also detail the corresponding emulation hardware architectures that were implemented [41].…”

“…Our proposed methodology for dimension reduction using quantum wavelet transforms is shown in Figure 2 [41]. In our proposed approach, each pixel of the input image is encoded as a basis coefficient of a quantum state.…”

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

“…In this section, we elaborate our methodology that uses QHT to achieve dimension reduction. We also detail the corresponding emulation hardware architectures that were implemented [41].…”

“…Our proposed methodology for dimension reduction using quantum wavelet transforms is shown in Figure 2 [41]. In our proposed approach, each pixel of the input image is encoded as a basis coefficient of a quantum state.…”

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

“…业内长期以来认为Shor算法是唯一有效的攻击 RSA的量子计算算法, 且在抗量子密码的研究方面几 乎仅考虑到Shor算法的潜在威胁. 至今已有很多研究 者尝试各种量子系统来实现Shor算法 [1][2][3][4] . 目前分解n 位大数需要2n+1到3n+0.002nlgn逻辑量子比特(Qubits) [5,6] , 由于受限于量子比特数与精度, 目前Shor算法 最大可实现整数85的分解 [7] .…”

Quantum annealing distributed integer decomposition study of local field coefficient <italic>h</italic> and coupling coefficient <italic>J</italic> with stability Ising model

“…Mahmud et al proposed multiple alternative models as feasible solutions to the scalability problem of emulating quantum circuits using the classical resources, and they further used these models to develop a highly scalable hardware emulator that is based on reconfigurable technology, which can efficiently simulate full quantum algorithms and circuits with improved and lower resource utilization and circuit latencies. Their hardware emulators can support single floating‐point precision for high precision and contain a fully pipelined architecture for high throughput.…”

A novel approach for emulating quantum computers on classical platforms