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424 results on '"Huang, Shi-yu"'

1. Low Latency Edge Classification GNN for Particle Trajectory Tracking on FPGAs

Author

Huang, Shi-Yu, Yang, Yun-Chen, Su, Yu-Ru, Lai, Bo-Cheng, Duarte, Javier, Hauck, Scott, Hsu, Shih-Chieh, Hu, Jin-Xuan, and Neubauer, Mark S.

Subjects
Computer Science - Hardware Architecture, Computer Science - Machine Learning, High Energy Physics - Experiment
Abstract

In-time particle trajectory reconstruction in the Large Hadron Collider is challenging due to the high collision rate and numerous particle hits. Using GNN (Graph Neural Network) on FPGA has enabled superior accuracy with flexible trajectory classification. However, existing GNN architectures have inefficient resource usage and insufficient parallelism for edge classification. This paper introduces a resource-efficient GNN architecture on FPGAs for low latency particle tracking. The modular architecture facilitates design scalability to support large graphs. Leveraging the geometric properties of hit detectors further reduces graph complexity and resource usage. Our results on Xilinx UltraScale+ VU9P demonstrate 1625x and 1574x performance improvement over CPU and GPU respectively.

Published
2023

4. Graph Neural Networks for Charged Particle Tracking on FPGAs

Author

Elabd, Abdelrahman, Razavimaleki, Vesal, Huang, Shi-Yu, Duarte, Javier, Atkinson, Markus, DeZoort, Gage, Elmer, Peter, Hauck, Scott, Hu, Jin-Xuan, Hsu, Shih-Chieh, Lai, Bo-Cheng, Neubauer, Mark, Ojalvo, Isobel, Thais, Savannah, and Trahms, Matthew

Subjects
Physics - Instrumentation and Detectors, Computer Science - Hardware Architecture, Computer Science - Machine Learning, High Energy Physics - Experiment, Statistics - Machine Learning
Abstract

The determination of charged particle trajectories in collisions at the CERN Large Hadron Collider (LHC) is an important but challenging problem, especially in the high interaction density conditions expected during the future high-luminosity phase of the LHC (HL-LHC). Graph neural networks (GNNs) are a type of geometric deep learning algorithm that has successfully been applied to this task by embedding tracker data as a graph -- nodes represent hits, while edges represent possible track segments -- and classifying the edges as true or fake track segments. However, their study in hardware- or software-based trigger applications has been limited due to their large computational cost. In this paper, we introduce an automated translation workflow, integrated into a broader tool called $\texttt{hls4ml}$, for converting GNNs into firmware for field-programmable gate arrays (FPGAs). We use this translation tool to implement GNNs for charged particle tracking, trained using the TrackML challenge dataset, on FPGAs with designs targeting different graph sizes, task complexites, and latency/throughput requirements. This work could enable the inclusion of charged particle tracking GNNs at the trigger level for HL-LHC experiments., Comment: 28 pages, 17 figures, 1 table, published version

Published
2021
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5. Graph Neural Networks for Charged Particle Tracking on FPGAs

Author

Elabd, Abdelrahman, Razavimaleki, Vesal, Huang, Shi-Yu, Duarte, Javier, Atkinson, Markus, DeZoort, Gage, Elmer, Peter, Hauck, Scott, Hu, Jin-Xuan, Hsu, Shih-Chieh, Lai, Bo-Cheng, Neubauer, Mark, Ojalvo, Isobel, Thais, Savannah, and Trahms, Matthew

Subjects
Information and Computing Sciences, Machine Learning, Networking and Information Technology R&D (NITRD), graph neural networks, FPGAs, tracking, LHC, trigger, Data management and data science, Information systems
Abstract

The determination of charged particle trajectories in collisions at the CERN Large Hadron Collider (LHC) is an important but challenging problem, especially in the high interaction density conditions expected during the future high-luminosity phase of the LHC (HL-LHC). Graph neural networks (GNNs) are a type of geometric deep learning algorithm that has successfully been applied to this task by embedding tracker data as a graph-nodes represent hits, while edges represent possible track segments-and classifying the edges as true or fake track segments. However, their study in hardware- or software-based trigger applications has been limited due to their large computational cost. In this paper, we introduce an automated translation workflow, integrated into a broader tool called hls4ml, for converting GNNs into firmware for field-programmable gate arrays (FPGAs). We use this translation tool to implement GNNs for charged particle tracking, trained using the TrackML challenge dataset, on FPGAs with designs targeting different graph sizes, task complexites, and latency/throughput requirements. This work could enable the inclusion of charged particle tracking GNNs at the trigger level for HL-LHC experiments.

Published
2022

10. A Check-and-Balance Scheme in Multiphase Delay-Locked Loop

Author

Chang, Shu-Yu and Huang, Shi-Yu

Abstract

Multiphase delay-locked loop (MP-DLL) is a technique employed in DDR memory controllers to achieve the required fixed timing delay (tSD) for deskew functionality. Traditionally, the tunable delay line (TDL) that consists of the MP-DLL will surfer the delay period mismatch under the same control code, which is mainly caused by the process variation. In this work, a feature called check and balance (CAB) scheme is developed to fix the delay mismatch among each delay stage, thereby providing a more robust and accurate fixed tSD for double-date-rate (DDR) memory controller with a reasonable amount of area overhead. Compared to the baseline MP-DLL design, MP-DLL with CAB can lower the maximum peak-to-peak (P2P) delay mismatch between delay stages from 51.32 to 6.76 ps at 1.6 GHz, utilizing only a 90-nm CMOS process. This improvement comes with an additional area of 0.0045 mm2 and 0.55-mW power consumption at a 1.0-V supply voltage compared to the baseline MP-DLL.

Published
2024
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11. Effects of Synchronous Bias Mode and Duty Cycle on Microstructure and Mechanical Properties of AlTiN Coatings Deposited via HiPIMS.

Author

Tang, Jian-Fu, Huang, Shi-Yu, Chen, I-Hong, Shen, Guan-Lun, and Chang, Chi-Lung

Subjects
ELECTRON probe microanalysis, MECHANICAL properties of metals, METAL nitrides, PROTECTIVE coatings, SURFACE coatings, MAGNETRON sputtering, ION bombardment
Abstract

The good mechanical properties of metal nitrides make them ideal surface coatings for cutting tools and mold components. Conventional TiN coatings have largely been replaced by AlTiN due to their superior mechanical properties and resistance to high temperatures. In this study, we investigated the application of bias voltage to the substrate to enhance ion bombardment during the synthesis of protective AlTiN coatings using high-power impulse magnetron sputtering (HiPIMS) with synchronous trigger-direct current (ST-DC) bias voltage. The ST-DC parameters included the duty cycle duration (3%, 6%, 12%, 18%) and turn-on time, which included synchronous (TD0) or a trigger delay of 50 μs (TD50). Scanning electron microscope images revealed that the highest deposition rate (22.1 nm/min) was achieved using TD50 with a duty cycle of 3%. The results obtained using an electron probe microanalyzer and X-ray diffractometer revealed the formation of an h-AlN structure when the Al/Ti ratio was between 0.71 and 0.74. Transmission electron microscopy and nanoindentation results revealed that transforming DC bias into synchronous bias to boost the bias output time (i.e., increasing the duty cycle) increased AlTiN grain refinement (from ~100 nm to ~55 nm) with a corresponding increase in hardness (from 22.7 GPa to 24.7 GPa) as well as an increase in residual stress within the AlTiN coating (from 0.16 GPa to −51 GPa). The excellent adhesion performance of the coatings provided further evidence indicating the importance of duty cycle and trigger delay when using pulsed-DC bias in HiPIMS. [ABSTRACT FROM AUTHOR]

Published
2023
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23. Introduction

Author

Huang, Shi-Yu, Cheng, Kwang-Ting, Agrawal, Vishwani D., editor, Huang, Shi-Yu, and Cheng, Kwang-Ting (Tim)

Published
1998
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26. CTD2022: Graph Neural Networks for Charged Particle Tracking on FPGAs

Author

Elabd, Abdelrahman, Duarte, Javier Mauricio, Lai, Bo-Cheng, DeZoort, Gage, Ojalvo, Isobel, Neubauer, Mark, Atkinson, Markus Julian, Trahms, Matthew, Elmer, Peter, Thais, Savannah Jennifer, Hauck, Scott, Huang, Shi-Yu, Hsu, Shih-Chieh, and Razavimaleki, Vesal

Abstract

The determination of charged particle trajectories in collisions at the CERN Large Hadron Collider (LHC) is an important but challenging problem, especially in the high interaction density conditions expected during the future high-luminosity phase of the LHC (HL-LHC). Graph neural networks (GNNs) are a type of geometric deep learning algorithm that has successfully been applied to this task by embedding tracker data as a graph---nodes represent hits, while edges represent possible track segments---and classifying the edges as true or fake track segments. However, their study in hardware- or software-based trigger applications has been limited due to their large computational cost. In this talk, we introduce an automated translation workflow, integrated into a broader tool called hls4ml, for converting GNNs into firmware for field-programmable gate arrays (FPGAs). We use this translation tool to implement GNNs for charged particle tracking, trained using the TrackML challenge dataset, on FPGAs with designs targeting different graph sizes, task complexites, and latency/throughput requirements. This work could enable the inclusion of charged particle tracking GNNs at the trigger level for HL-LHC experiments.

Published
2022
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27. ETS 2022 ORGANIZING COMMITTEE

Author

Manich Bou, Salvador, Rodríguez Montañés, Rosa, Bernardi, Paolo, Tille, Daniel, Mir, Salvador, Bosio, Alberto, Arumi Delgado, Daniel, Gómez Pau, Álvaro, Cassano, Luca, Jiao, Hailong, Miclea, Liviu, Sanchez, Ernesto, Savino, Alessandro, Canal Corretger, Ramon, Eggersglüß, Stephan, Fransi, Sergi, Taouil, Mottaqiallah, Calomarde Palomino, Antonio, Weiner, Michael, Michael, Maria K., Sonza Reorda, Matteo, Larsson, Erik, Vatajelu, Elena-Ioana, Stratigopoulos, Haralampos-G., Parisi Baradad, Vicenç, Huang, Junlin, Li, Huawei, Chillarige, Sameer, Kameyama, Shuichi, Carro, Luigi, Su, Fei, Nicolici, Nicola, Huang, Shi-Yu, Manich Bou, Salvador, Rodríguez Montañés, Rosa, Bernardi, Paolo, Tille, Daniel, Mir, Salvador, Bosio, Alberto, Arumi Delgado, Daniel, Gómez Pau, Álvaro, Cassano, Luca, Jiao, Hailong, Miclea, Liviu, Sanchez, Ernesto, Savino, Alessandro, Canal Corretger, Ramon, Eggersglüß, Stephan, Fransi, Sergi, Taouil, Mottaqiallah, Calomarde Palomino, Antonio, Weiner, Michael, Michael, Maria K., Sonza Reorda, Matteo, Larsson, Erik, Vatajelu, Elena-Ioana, Stratigopoulos, Haralampos-G., Parisi Baradad, Vicenç, Huang, Junlin, Li, Huawei, Chillarige, Sameer, Kameyama, Shuichi, Carro, Luigi, Su, Fei, Nicolici, Nicola, and Huang, Shi-Yu

Published
2022

28. Graph Neural Networks for Charged Particle Tracking on FPGAs

Author

Elabd, Abdelrahman, primary, Razavimaleki, Vesal, additional, Huang, Shi-Yu, additional, Duarte, Javier, additional, Atkinson, Markus, additional, DeZoort, Gage, additional, Elmer, Peter, additional, Hauck, Scott, additional, Hu, Jin-Xuan, additional, Hsu, Shih-Chieh, additional, Lai, Bo-Cheng, additional, Neubauer, Mark, additional, Ojalvo, Isobel, additional, Thais, Savannah, additional, and Trahms, Matthew, additional

Published
2022
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29. Compiler of Reed–Solomon Codec for 400-Gb/s IEEE 802.3bs Standard

Author

Liu, Lin, Chi, Lai, Huang, Shi-Yu, and Yeh, Ka-Yi

Abstract

Error correction is often indispensable in a modern digital communication system that transmits data at a very high speed. Recently published IEEE Std 802.3bs requires an astounding throughput of 400 Gb/s while using the Reed–Solomon code (RS-Code) to protect the integrity of the transmitted data. An RS-Codec supporting such a high throughput demands a significant silicon area. Improper decisions on the parameters of the parallel architecture could lead to unnecessarily high costs in the implementation. We have developed a compiler to solve this problem. First, the Codec satisfying IEEE Std 802.3bs using RS(544, 514) is parameterized, in a way that the throughput can be boosted on demand by setting some “configuration.” Second, an area- and power-efficient RS-Codec design satisfying a target throughput using a specific process can be inferred by our compiler in just minutes, and thereby easy process migration is supported. Experimental results using 28 and 90-nm CMOS processes are presented to demonstrate their effectiveness.

Published
2023
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30. Clock-Latency-Aware Fault-Tolerant DLL for Multi-Die Clock Synchronization

Author

Su, Yung-Chuan and Huang, Shi-Yu

Abstract

A delay-locked loop (DLL) circuit is indispensable for clock synchronization in a chip incorporating several heterogeneous dice. It has been shown previously that a fault and soft-error-tolerant DLL can be achieved by triple-module redundancy (TMR) enhanced with a timing correction scheme. However, the prior work still has a severe limitation—it does not consider the latency of the clock tree, and this limitation will make it infeasible in realistic situations. We demonstrate in this article that this limitation can be overcome by a new “clock-latency-aware” architecture, thereby making a fault and soft-error-tolerant DLL truly realistic.

Published
2023
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40. A resilient and power-efficient automatic-power-down sense amplifier for SRAM design

Author

Lai, Ya-Chun and Huang, Shi-Yu

Subjects
Circuit design -- Evaluation, Static random access memory -- Equipment and supplies, Circuit designer, Integrated circuit design, SRAM, Business, Computers and office automation industries, Electronics, Electronics and electrical industries
Abstract

A conventional latch-type sense amplifier in a static random access memory (SRAM) could trigger sensing failure under severe process variation. On the other hand, a traditional current-mirror sense amplifier could consume too much power. To strike a good balance, this paper presents an automatic-power-down (APD) sense amplifier, which can avoid sensing failure while keeping the power dissipation low. In this scheme, the operation window of the sense amplifier is adaptive to the real silicon speed of its associated column through Schmitt--Trigger-based dual-[V.sub.HL] APD circuitry. A 64-kb SRAM design using the proposed technique in a 22-nm predictive technology model demonstrates that a power savings of 28%-87% over the traditional current-mirror sense amplifier is achievable. Index Terms--Automatic-power-down (APD) circuitry, sense amplifier, static random access memory (SRAM).

Published
2008

41. Research on Control Technology of Virtual Synchronous Generator for Distributed Power

Author

Shi Shang Ying and Huang Shi Yu

Subjects
Electric power system, business.industry, Computer science, Distributed generation, Interface (computing), Process (computing), Distributed power, Inverter, Control engineering, Electric power industry, business, Power (physics)
Abstract

In the current development process of the energy industry, the application of distributed energy in power systems is increasing, and at the same time, it has brought new impacts and challenges to the safety and stability of power system operations. Because the distributed power source based on the power electronic inverter interface does not have the rotational inertia and damping components to keep the system stable. These are the inherent characteristics of synchronous generators in the development of traditional power systems. Virtual synchronous generator control technology, as an important method to effectively control distributed inverter power sources and ensure that they have similar characteristics to synchronous generators, can greatly improve the stability of power systems. Therefore, in order to ensure the effective application of distributed power in the power system, research and analysis on the control technology of virtual synchronous generators are needed. Only in this way can the active role of virtual synchronous generator control technology in distributed power be fully brought into play, and the safe and stable operation of China's power system can be ensured, while promoting the long-term sustainable development of the power industry.

Published
2020

42. Electronic Sensors for Monitoring Electrical Equipment

Author

Shi Shang Ying and Huang Shi Yu

Subjects
Engineering, Reliability (semiconductor), Work (electrical), business.industry, Process (engineering), Electrical equipment, media_common.quotation_subject, Quality (business), Electric power industry, business, Automotive engineering, media_common
Abstract

In recent years, the development of China’s power industry has been particularly fast, and people’s requirements for the safety and reliability of the power industry have become higher and higher. Therefore, there are higher requirements for the quality of electrical equipment monitoring work. In the current monitoring process of electrical equipment, the role of electronic sensors is very important. Research and analysis of electronic sensors are discussed to discuss the application of electronic sensors in the monitoring process of electrical equipment. It is of great significance to promote the widespread application of electronic sensors in the construction of electrical equipment, and also has a positive effect on promoting the stable and safe development of the power industry.

Published
2020

44. Diagnosis by image recovery: finding mixed multiple timing faults in a scan chain

Author

Tzeng, Chao-Wen and Huang, Shi-Yu

Subjects
Medical equipment -- Analysis, Physiological apparatus -- Analysis, Business, Computers and office automation industries, Electronics, Electronics and electrical industries
Abstract

In this brief, we present a robust new paradigm for diagnosing a scan chain with multiple faults that could have different fault types. As compared to previous methods, the major advantage of ours is the ability to not only target mixed multiple types of timing faults in the same scan chain but also tolerate non-ideal conditions, e.g., when these faults only manifest themselves intermittently. Unlike the previous matching-based algorithms, we formulate the diagnosis problem as an image recovery process featuring a dynamic windowing technique and a running sequence handling technique. Experimental results on a number of real designs show that this paradigm can successfully deal with some situations beyond existing methods. Index Terms--Fault diagnosis, scan chain.

Published
2007

48. Process-Resilient Fault-Tolerant Delay-Locked Loop Using TMR With Dynamic Timing Correction.

Author

Yang, Jun-Yu and Huang, Shi-Yu

Subjects
*FIELD-effect transistors, *DELAY lines
Abstract

A delay-locked loop (DLL) circuit is often useful for the clock synchronization in a chip incorporating multiple functional dies. In this work, we present a process-resilient fault-tolerant DLL design. We will first show that a naïve triple-module redundancy (TMR) technique cannot work well unless with a simple yet powerful static timing correction scheme to nullify the adversary effect caused by the voter circuit’s delay. Furthermore, we enhance it with a dynamic scheme so that the overall performance is immune to process variation. Through the proposed schemes, the maximum phase error over 1000 clock cycles between the DLL’s input and output clock signals after locking, which is often considered as the most important performance metric, can be reduced tremendously from 130 ps using only naïve TMR to 20 ps using static timing correction, and then further down to 11 ps using the dynamic timing correction. [ABSTRACT FROM AUTHOR]

Published
2022
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