A stochastic-computing based deep learning framework using adiabatic quantum-flux-parametron superconducting technology

Cai, Ruizhe; Ren, Ao; Chen, Olivia; Liu, Ning; Ding, Caiwen; Qian, Xuehai; Han, Jie; Luo, Weiwei; Yoshikawa, Nobuyuki; Wang, Yanzhi

doi:10.1145/3307650.3322270

Cited by 33 publications

(10 citation statements)

References 50 publications

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“…The minimum distance between pulses increases with the number of inputs. counting network (M inputs, one output) where M is a power of two [4,6,31]. A balancer (Figure 6a) is the building block for counting networks.…”

Section: Unary Sfq Additionmentioning

confidence: 99%

“…To address SFQ constraints, Cai, et al [6], proposed a stochastic computing-based deep learning framework using adiabatic Quantum-Flux-Parametron technology. Also, Tzimpragos et al [51] adapted RL to RSFQ.…”

Section: Related Workmentioning

confidence: 99%

“…Previous work has explored unary approaches such as SSC and RL in SFQ technology, demonstrating beneficial trade-offs between area and energy/power consumption for selected applications [6,51]. Stream-based methods, such as SSC, are particularly efficient for mathematical operations yet sacrifice accuracy to latency.…”

Section: Introductionmentioning

confidence: 99%

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Temporal and SFQ pulse-streams encoding for area-efficient superconducting accelerators

Gonzalez-Guerrero

Bautista

Lyles

2022

Proceedings of the 27th ACM International Conference on Architectural Support for Programming Languages and Operating Systems

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Superconducting technology is a prime candidate for the future of computing. However, current superconducting prototypes are limited to small-scale examples due to stringent area constraints and complex architectures inspired from voltage-level encoding in CMOS; this is at odds with the 𝑝𝑠-wide Single Quantum Flux (SFQ) pulses used in superconductors to carry information. In this work, we propose a wave-pipelined Unary SFQ (U-SFQ) architecture that leverages the advantages of two data representations: pulse-streams and Race Logic (RL). We introduce novel building blocks such as multipliers, adders, and memory cells, which leverage the natural properties of SFQ pulses to mitigate area constraints. We then design and simulate three popular hardware accelerators: i) a Processing Element (PE), typically used in spatial architectures; ii) A dot-product-unit (DPU), one of the most popular accelerators in artificial neural networks and digital signal processing (DSP); and iii) A Finite Impulse Response (FIR) filter, a popular and computationally demanding DSP accelerator. The proposed U-SFQ building blocks require up to 200× fewer JJs compared to their SFQ binary counterparts, exposing an area-delay trade-off. This work mitigates the stringent area constraints of superconducting technology. CCS CONCEPTS• Hardware → Emerging technologies; • Theory of computation → Modal and temporal logics; • Computer systems organization → Architectures.

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Section: Unary Sfq Additionmentioning

confidence: 99%

Section: Related Workmentioning

confidence: 99%

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Temporal and SFQ pulse-streams encoding for area-efficient superconducting accelerators

Gonzalez-Guerrero

Bautista

Lyles

2022

Proceedings of the 27th ACM International Conference on Architectural Support for Programming Languages and Operating Systems

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“…However, this design choice compromises the advantage speed of SFQ technology [4] as the number of execution cycles per instruction increases with the number of bit slices. Moreover, the use of shift register-based memories -given the lack of dense, fast, and robust cryogenic memory blocks -seems to be the only reasonable choice at the moment; still not a viable solution though for large-scale designs 3 .…”

Section: Computing With Superconductorsmentioning

confidence: 99%

“…Another promising effort is the stochastic computingbased deep learning acceleration framework presented by R. Cai, et al [3]. The authors of this work took advantage of stochastic computing's time-independent bit sequence value representation and the small hardware footprint of its operators to redesign the basic neural network components in AQFP and were able to achieve orders of magnitude energy improvements compared to CMOS.…”

Section: Computing With Superconductorsmentioning

confidence: 99%

A Computational Temporal Logic for Superconducting Accelerators

Tzimpragos

Vasudevan

Tsiskaridze

et al. 2020

Proceedings of the Twenty-Fifth International Conference on Architectural Support for Programming Languages and Operating Syste

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Superconducting logic offers the potential to perform computation at tremendous speeds and energy savings. However, a "semantic gap" lies between the level-driven logic that traditional hardware designs accept as a foundation and the pulse-driven logic that is naturally supported by the most compelling superconducting technologies. A pulse, unlike a level signal, will fire through a channel for only an instant. Arranging the network of superconducting components so that input pulses always arrive simultaneously to "logic gates" to maintain the illusion of Boolean-only evaluation is a significant engineering hurdle. In this paper, we explore computing in a new and more native tongue for superconducting logic: time of arrival. Building on recent work in delay-based computations we show that superconducting logic can naturally compute directly over temporal relationships between pulse arrivals, that the computational relationships between those pulse arrivals can be formalized through a functional extension to a temporal predicate logic used in the verification community, and that the resulting architectures can operate asynchronously and describe real and useful computations. We verify our hypothesis through a combination of detailed analog circuit models, a formal analysis of our abstractions, and an evaluation in the context of several superconducting accelerators.

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A hardware-friendly logarithmic quantization method for CNNs and FPGA implementation

Jiang,

Xing,

et al. 2024

J Real-Time Image Proc

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A stochastic-computing based deep learning framework using adiabatic quantum-flux-parametron superconducting technology

Cited by 33 publications

References 50 publications

Temporal and SFQ pulse-streams encoding for area-efficient superconducting accelerators

Temporal and SFQ pulse-streams encoding for area-efficient superconducting accelerators

A Computational Temporal Logic for Superconducting Accelerators

A hardware-friendly logarithmic quantization method for CNNs and FPGA implementation

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