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Mark Hempstead
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2020 – today
- 2024
- [c45]Alexander Hankin, Abdulrahman Mahmoud, Mark Hempstead, David Brooks, Gu-Yeon Wei:
VelociTI: An Architecture-level Performance Modeling Framework for Trapped Ion Quantum Computers. IISWC 2024: 156-168 - 2023
- [c44]Cesar Gomes, Mark Hempstead:
CInC: Workload Characterization In Context of Resource Contention. IISWC 2023: 201-205 - [c43]Alexander Hankin, Abdulrahman Mahmoud, Mark Hempstead, David Brooks, Gu-Yeon Wei:
VelociTI: An Architecture-level Performance Modeling Framework for Trapped Ion Quantum Computers. IISWC 2023: 206-210 - [c42]Maziar Amiraski, David Werner, Alexander Hankin, Julien Sebot, Kaushik Vaidyanathan, Mark Hempstead:
Boreas: A Cost-Effective Mitigation Method for Advanced Hotspots using Machine Learning and Hardware Telemetry. ISPASS 2023: 295-305 - 2022
- [j8]Cesar Gomes, Maziar Amiraski, Mark Hempstead:
CASHT: Contention Analysis in Shared Hierarchies with Thefts. ACM Trans. Archit. Code Optim. 19(1): 12:1-12:27 (2022) - [c41]Liu Ke, Udit Gupta, Mark Hempstead, Carole-Jean Wu, Hsien-Hsin S. Lee, Xuan Zhang:
Hercules: Heterogeneity-Aware Inference Serving for At-Scale Personalized Recommendation. HPCA 2022: 141-154 - [c40]Lillian Pentecost, Alexander Hankin, Marco Donato, Mark Hempstead, Gu-Yeon Wei, David Brooks:
NVMExplorer: A Framework for Cross-Stack Comparisons of Embedded Non-Volatile Memories. HPCA 2022: 938-956 - [c39]Cesar Gomes, Xuesi Chen, Mark Hempstead:
PInTE: Probabilistic Induction of Theft Evictions. IISWC 2022: 1-13 - [i4]Liu Ke, Udit Gupta, Mark Hempstead, Carole-Jean Wu, Hsien-Hsin S. Lee, Xuan Zhang:
Hercules: Heterogeneity-Aware Inference Serving for At-Scale Personalized Recommendation. CoRR abs/2203.07424 (2022) - 2021
- [c38]Alexander Hankin, David Werner, Maziar Amiraski, Julien Sebot, Kaushik Vaidyanathan, Mark Hempstead:
HotGauge: A Methodology for Characterizing Advanced Hotspots in Modern and Next Generation Processors. IISWC 2021: 163-175 - [c37]Michael Lui, Yavuz Yetim, Özgür Özkan, Zhuoran Zhao, Shin-Yeh Tsai, Carole-Jean Wu, Mark Hempstead:
Understanding Capacity-Driven Scale-Out Neural Recommendation Inference. ISPASS 2021: 162-171 - [c36]Guru Prasad Srinivasa, David Werner, Mark Hempstead, Geoffrey Challen:
Thermal-Aware Overclocking for Smartphones. ISPASS 2021: 220-222 - [i3]Lillian Pentecost, Alexander Hankin, Marco Donato, Mark Hempstead, Gu-Yeon Wei, David Brooks:
NVMExplorer: A Framework for Cross-Stack Comparisons of Embedded Non-Volatile Memories. CoRR abs/2109.01188 (2021) - 2020
- [c35]Parnian Mokri, Mark Hempstead:
Early-stage Automated Identification Tool for Shared Accelerators. FCCM 2020: 217 - [c34]Parnian Mokri, Maziar Amiraskari, Yuelin Liu, Mark Hempstead:
Early-stage Automated Identification of Similar Hardware Implementations with Abstract-Syntax-Tree. FPGA 2020: 312 - [c33]Karthik Sangaiah, Michael Lui, Ragh Kuttappa, Baris Taskin, Mark Hempstead:
SnackNoC: Processing in the Communication Layer. HPCA 2020: 461-473 - [c32]Udit Gupta, Carole-Jean Wu, Xiaodong Wang, Maxim Naumov, Brandon Reagen, David Brooks, Bradford Cottel, Kim M. Hazelwood, Mark Hempstead, Bill Jia, Hsien-Hsin S. Lee, Andrey Malevich, Dheevatsa Mudigere, Mikhail Smelyanskiy, Liang Xiong, Xuan Zhang:
The Architectural Implications of Facebook's DNN-Based Personalized Recommendation. HPCA 2020: 488-501 - [c31]Parnian Mokri, Mark Hempstead:
Early-stage Automated Accelerator Identification Tool for Embedded Systems with Limited Area. ICCAD 2020: 115:1-115:8 - [c30]Liu Ke, Udit Gupta, Benjamin Youngjae Cho, David Brooks, Vikas Chandra, Utku Diril, Amin Firoozshahian, Kim M. Hazelwood, Bill Jia, Hsien-Hsin S. Lee, Meng Li, Bert Maher, Dheevatsa Mudigere, Maxim Naumov, Martin Schatz, Mikhail Smelyanskiy, Xiaodong Wang, Brandon Reagen, Carole-Jean Wu, Mark Hempstead, Xuan Zhang:
RecNMP: Accelerating Personalized Recommendation with Near-Memory Processing. ISCA 2020: 790-803 - [c29]Cesar Gomes, Mark Hempstead:
C^2AFE: Capacity Curve Annotation and Feature Extraction for Shared Cache Analysis. ISPASS 2020: 113-115 - [i2]Michael Lui, Yavuz Yetim, Özgür Özkan, Zhuoran Zhao, Shin-Yeh Tsai, Carole-Jean Wu, Mark Hempstead:
Understanding Capacity-Driven Scale-Out Neural Recommendation Inference. CoRR abs/2011.02084 (2020)
2010 – 2019
- 2019
- [c28]Alexander Hankin, Tomer Shapira, Karthik Sangaiah, Michael Lui, Mark Hempstead:
Evaluation of Non-Volatile Memory Based Last Level Cache Given Modern Use Case Behavior. IISWC 2019: 143-154 - [c27]Guru Prasad Srinivasa, Scott Haseley, Geoffrey Challen, Mark Hempstead:
Quantifying Process Variations and Its Impacts on Smartphones. ISPASS 2019: 117-126 - [i1]Liu Ke, Udit Gupta, Carole-Jean Wu, Benjamin Youngjae Cho, Mark Hempstead, Brandon Reagen, Xuan Zhang, David M. Brooks, Vikas Chandra, Utku Diril, Amin Firoozshahian, Kim M. Hazelwood, Bill Jia, Hsien-Hsin S. Lee, Meng Li, Bert Maher, Dheevatsa Mudigere, Maxim Naumov, Martin Schatz, Mikhail Smelyanskiy, Xiaodong Wang:
RecNMP: Accelerating Personalized Recommendation with Near-Memory Processing. CoRR abs/1912.12953 (2019) - 2018
- [j7]Karthik Sangaiah, Michael Lui, Radhika Jagtap, Stephan Diestelhorst, Siddharth Nilakantan, Ankit More, Baris Taskin, Mark Hempstead:
SynchroTrace: Synchronization-Aware Architecture-Agnostic Traces for Lightweight Multicore Simulation of CMP and HPC Workloads. ACM Trans. Archit. Code Optim. 15(1): 2:1-2:26 (2018) - [c26]David Werner, Kyle Juretus, Ioannis Savidis, Mark Hempstead:
Machine Learning on the Thermal Side-Channel: Analysis of Accelerator-Rich Architectures. ICCD 2018: 83-91 - [c25]Michael Lui, Karthik Sangaiah, Mark Hempstead, Baris Taskin:
Towards Cross-Framework Workload Analysis via Flexible Event-Driven Interfaces. ISPASS 2018: 169-178 - 2017
- [c24]Guru Prasad Srinivasa, Rizwana Begum, Scott Haseley, Mark Hempstead, Geoffrey Challen:
Separated By Birth: Hidden Differences Between Seemingly-Identical Smartphone CPUs. HotMobile 2017: 103-108 - 2016
- [c23]Rizwana Begum, Mark Hempstead, Guru Prasad Srinivasa, Geoffrey Challen:
Algorithms for CPU and DRAM DVFS under inefficiency constraints. ICCD 2016: 161-168 - 2015
- [j6]Trevor E. Carlson, Siddharth Nilakantan, Mark Hempstead, Wim Heirman:
Epoch Profiles: Microarchitecture-Based Application Analysis and Optimization. IEEE Comput. Archit. Lett. 14(1): 30-33 (2015) - [c22]Karthik Sangaiah, Mark Hempstead, Baris Taskin:
Uncore RPD: Rapid Design Space Exploration of the Uncore via Regression Modeling. ICCAD 2015: 365-372 - [c21]Cesar Gomes, Mark Hempstead:
Combative cache efficacy techniques: Cache replacement in the context of independent prefetching in last level cache. ICCD 2015: 423-426 - [c20]Rizwana Begum, Mark Hempstead:
Power-agility metrics: Measuring dynamic characteristics of energy proportionality. ICCD 2015: 643-650 - [c19]Rizwana Begum, David Werner, Mark Hempstead, Guru Prasad, Geoffrey Challen:
Energy-Performance Trade-offs on Energy-Constrained Devices with Multi-component DVFS. IISWC 2015: 34-43 - [c18]Siddharth Nilakantan, Karthik Sangaiah, Ankit More, Giordano Salvador, Baris Taskin, Mark Hempstead:
Synchrotrace: synchronization-aware architecture-agnostic traces for light-weight multicore simulation. ISPASS 2015: 278-287 - [c17]Giordano Salvador, Siddharth Nilakantan, Baris Taskin, Mark Hempstead, Ankit More:
Effects of Nondeterminism in Hardware and Software Simulation with Thread Mapping. VLSID 2015: 129-134 - [c16]Siddharth Nilakantan, Scott Lerner, Mark Hempstead, Baris Taskin:
Can You Trust Your Memory Trace? A Comparison of Memory Traces from Binary Instrumentation and Simulation. VLSID 2015: 135-140 - 2014
- [c15]Giordano Salvador, Siddharth Nilakantan, Baris Taskin, Mark Hempstead, Ankit More:
Static thread mapping for NoCs via binary instrumentation traces. ICCD 2014: 517-520 - 2013
- [j5]Siddharth Nilakantan, Steven J. Battle, Mark Hempstead:
Metrics for Early-Stage Modeling of Many-Accelerator Architectures. IEEE Comput. Archit. Lett. 12(1): 25-28 (2013) - [c14]Steven J. Battle, Mark Hempstead:
Characterizing the costs and benefits of hardware parallelism in accelerator cores. ICCD 2013: 26-32 - [c13]Steven J. Battle, Mark Hempstead:
Register allocation and VDD-gating algorithms for out-of-order architectures. ICCD 2013: 108-114 - [c12]Siddharth Nilakantan, Mark Hempstead:
Platform-independent analysis of function-level communication in workloads. IISWC 2013: 196-206 - 2012
- [j4]Michael J. Lyons, Mark Hempstead, Gu-Yeon Wei, David M. Brooks:
The accelerator store: A shared memory framework for accelerator-based systems. ACM Trans. Archit. Code Optim. 8(4): 48:1-48:22 (2012) - [c11]Steven J. Battle, Andrew D. Hilton, Mark Hempstead, Amir Roth:
Flexible register management using reference counting. HPCA 2012: 273-284 - 2011
- [j3]Mark Hempstead, David M. Brooks, Gu-Yeon Wei:
An Accelerator-Based Wireless Sensor Network Processor in 130 nm CMOS. IEEE J. Emerg. Sel. Topics Circuits Syst. 1(2): 193-202 (2011) - [c10]Siddharth Nilakantan, Srikanth Annangi, Nikhil Gulati, Karthik Sangaiah, Mark Hempstead:
Evaluation of an accelerator architecture for speckle reducing anisotropic diffusion. CASES 2011: 185-194 - [c9]Geoffrey Challen, Mark Hempstead:
The Case for Power-Agile Computing. HotOS 2011 - 2010
- [j2]Michael J. Lyons, Mark Hempstead, Gu-Yeon Wei, David M. Brooks:
The Accelerator Store framework for high-performance, low-power accelerator-based systems. IEEE Comput. Archit. Lett. 9(2): 53-56 (2010)
2000 – 2009
- 2009
- [c8]Mark Hempstead, Gu-Yeon Wei, David M. Brooks:
An accelerator-based wireless sensor network processor in 130nm CMOS. CASES 2009: 215-222 - 2008
- [j1]Mark Hempstead, Michael J. Lyons, David M. Brooks, Gu-Yeon Wei:
Survey of Hardware Systems for Wireless Sensor Networks. J. Low Power Electron. 4(1): 11-20 (2008) - [c7]Mark Hempstead, Gu-Yeon Wei, David M. Brooks:
System design considerations for sensor network applications. ISCAS 2008: 2566-2569 - 2006
- [c6]Mark Hempstead, Gu-Yeon Wei, David M. Brooks:
Architecture and circuit techniques for low-throughput, energy-constrained systems across technology generations. CASES 2006: 368-378 - [c5]Qin Wang, Mark Hempstead, Woodward Yang:
A Realistic Power Consumption Model for Wireless Sensor Network Devices. SECON 2006: 286-295 - 2005
- [c4]Mark Hempstead, Nikhil Tripathi, Patrick Mauro, Gu-Yeon Wei, David M. Brooks:
An Ultra Low Power System Architecture for Sensor Network Applications. ISCA 2005: 208-219 - [c3]Yingmin Li, Mark Hempstead, Patrick Mauro, David M. Brooks, Zhigang Hu, Kevin Skadron:
Power and thermal effects of SRAM vs. Latch-Mux design styles and clock gating choices. ISLPED 2005: 173-178 - 2004
- [c2]Mark Hempstead, Matt Welsh, David M. Brooks:
TinyBench: The Case For A Standardized Benchmark Suite for TinyOS Based Wireless Sensor Network Devices. LCN 2004: 585-586 - [c1]Victor Shnayder, Mark Hempstead, Bor-rong Chen, Geoffrey Werner-Allen, Matt Welsh:
Simulating the power consumption of large-scale sensor network applications. SenSys 2004: 188-200
Coauthor Index
aka: David M. Brooks
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last updated on 2024-12-13 19:06 CET by the dblp team
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