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Jason Lowe-Power
Person information
- affiliation: University of California, Davis, USA
- affiliation (former): University of Wisconsin - Madison, USA
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2020 – today
- 2024
- [c23]Mark Hildebrand, Jason Lowe-Power, Venkatesh Akella:
CachedArrays: Optimizing Data Movement for Heterogeneous Memory Systems. IPDPS 2024: 545-555 - [i10]William Shaddix, Mahyar Samani, Marjan Fariborz, S. J. Ben Yoo, Jason Lowe-Power, Venkatesh Akella:
TEGRA - Scaling Up Terascale Graph Processing with Disaggregated Computing. CoRR abs/2404.03155 (2024) - [i9]Maryam Babaie, Ayaz Akram, Wendy Elsasser, Brent Haukness, Michael R. Miller, Taeksang Song, Thomas Vogelsang, Steven C. Woo, Jason Lowe-Power:
TDRAM: Tag-enhanced DRAM for Efficient Caching. CoRR abs/2404.14617 (2024) - [i8]Kunal Pai, Anusheel Nand, Jason Lowe-Power:
Potential and Limitation of High-Frequency Cores and Caches. CoRR abs/2408.03308 (2024) - 2023
- [j6]Hari Venugopalan
, Zain ul Abi Din
Aragorn: A Privacy-Enhancing System for Mobile Cameras. Proc. ACM Interact. Mob. Wearable Ubiquitous Technol. 7(4): 181:1-181:31 (2023) - [j5]Arash Tayyebi
Prediction of organic compound aqueous solubility using machine learning: a comparison study of descriptor-based and fingerprints-based models. J. Cheminformatics 15(1): 99 (2023) - [c22]Maryam Babaie, Ayaz Akram, Jason Lowe-Power:
Enabling Design Space Exploration of DRAM Caches for Emerging Memory Systems. ISPASS 2023: 340-342 - [c21]Venkatesh Akella, Marjan Fariborz, Mahyar Samani, S. J. Ben Yoo, Jason Lowe-Power:
Scalable Hardware Acceleration of Graph Processing with Photonic Interconnects. PSC 2023: 1-3 - [c20]Mark Hildebrand
Efficient Large Scale DLRM Implementation on Heterogeneous Memory Systems. ISC 2023: 42-61 - [i7]Maryam Babaie, Ayaz Akram, Jason Lowe-Power:
A Cycle-level Unified DRAM Cache Controller Model for 3DXPoint Memory Systems in gem5. CoRR abs/2303.13026 (2023) - [i6]Maryam Babaie, Ayaz Akram, Jason Lowe-Power:
Enabling Design Space Exploration of DRAM Caches in Emerging Memory Systems. CoRR abs/2303.13029 (2023) - [i5]Hari Venugopalan, Kaustav Goswami, Zain ul Abi Din, Jason Lowe-Power, Samuel T. King, Zubair Shafiq:
Centauri: Practical Rowhammer Fingerprinting. CoRR abs/2307.00143 (2023) - 2022
- [j4]Marjan Fariborz
A Model for Scalable and Balanced Accelerators for Graph Processing. IEEE Comput. Archit. Lett. 21(2): 149-152 (2022) - [c19]Ayaz Akram, Venkatesh Akella, Sean Peisert
SoK: Limitations of Confidential Computing via TEEs for High-Performance Compute Systems. SEED 2022: 121-132 - [c18]Marjan Fariborz, Mahyar Samani, Pouya Fotouhi, Roberto Proietti, Il-Min Yi, Venkatesh Akella, Jason Lowe-Power
LLM: Realizing Low-Latency Memory by Exploiting Embedded Silicon Photonics for Irregular Workloads. ISC 2022: 44-64 - 2021
- [c17]Zhengrong Wang, Jian Weng, Jason Lowe-Power
Stream Floating: Enabling Proactive and Decentralized Cache Optimizations. HPCA 2021: 640-653 - [c16]Ayaz Akram, Anna Giannakou, Venkatesh Akella, Jason Lowe-Power
Performance Analysis of Scientific Computing Workloads on General Purpose TEEs. IPDPS 2021: 1066-1076 - [c15]Bobby R. Bruce
Enabling Reproducible and Agile Full-System Simulation. ISPASS 2021: 183-193 - [c14]Mark Hildebrand, Julian T. Angeles, Jason Lowe-Power
A Case Against Hardware Managed DRAM Caches for NVRAM Based Systems. ISPASS 2021: 194-204 - [c13]Pouya Fotouhi
HTA: A Scalable High-Throughput Accelerator for Irregular HPC Workloads. ISC 2021: 176-194 - 2020
- [j3]Jason Power, Raymond Lynch, Oliver McGarr:
Difficulty and self-efficacy: An exploratory study. Br. J. Educ. Technol. 51(1): 281-296 (2020) - [c12]Mark Hildebrand, Jawad Khan, Sanjeev Trika, Jason Lowe-Power
AutoTM: Automatic Tensor Movement in Heterogeneous Memory Systems using Integer Linear Programming. ASPLOS 2020: 875-890 - [c11]Kramer Straube, Jason Lowe-Power
HCAPP: Scalable Power Control for Heterogeneous 2.5D Integrated Systems. ICPP 2020: 60:1-60:11 - [i4]Jason Lowe-Power, Abdul Mutaal Ahmad, Ayaz Akram, Mohammad Alian
The gem5 Simulator: Version 20.0+. CoRR abs/2007.03152 (2020) - [i3]Ayaz Akram, Anna Giannakou, Venkatesh Akella, Jason Lowe-Power, Sean Peisert
Performance Analysis of Scientific Computing Workloads on Trusted Execution Environments. CoRR abs/2010.13216 (2020) - [i2]Ayaz Akram, Jason Lowe-Power:
The Tribes of Machine Learning and the Realm of Computer Architecture. CoRR abs/2012.04105 (2020)
2010 – 2019
- 2019
- [c10]Bradley Wang, Ayaz Akram, Jason Lowe-Power
FlexCPU: A Configurable Out-of-Order CPU Abstraction. ISPASS 2019: 147-148 - [c9]Pouya Fotouhi
Enabling scalable chiplet-based uniform memory architectures with silicon photonics. MEMSYS 2019: 222-334 - [c8]Jason Lowe-Power
The Davis In-Order (DINO) CPU: A Teaching-focused RISC-V CPU Design. WCAE@ISCA 2019: 2:1-2:8 - 2018
- [c7]Hongil Yoon, Jason Lowe-Power
Filtering Translation Bandwidth with Virtual Caching. ASPLOS 2018: 113-127 - [c6]Kramer Straube, Jason Lowe-Power
Improving Provisioned Power Efficiency in HPC Systems with GPU-CAPP. HiPC 2018: 112-122 - [c5]Jason Lowe-Power
A case for exposing extra-architectural state in the ISA: position paper. HASP@ISCA 2018: 8:1-8:6 - 2016
- [i1]Jason Lowe-Power, Mark D. Hill, David A. Wood:
When to use 3D Die-Stacked Memory for Bandwidth-Constrained Big Data Workloads. CoRR abs/1608.07485 (2016) - 2015
- [j2]Jason Power
gem5-gpu: A Heterogeneous CPU-GPU Simulator. IEEE Comput. Archit. Lett. 14(1): 34-36 (2015) - [j1]Jason Power
Implications of Emerging 3D GPU Architecture on the Scan Primitive. SIGMOD Rec. 44(1): 18-23 (2015) - [c4]Jason Power
Toward GPUs being mainstream in analytic processing: An initial argument using simple scan-aggregate queries. DaMoN 2015: 11:1-11:8 - [c3]Lena E. Olson
Border control: sandboxing accelerators. MICRO 2015: 470-481 - 2014
- [c2]Jason Power
Supporting x86-64 address translation for 100s of GPU lanes. HPCA 2014: 568-578 - 2013
- [c1]Jason Power
Heterogeneous system coherence for integrated CPU-GPU systems. MICRO 2013: 457-467
Coauthor Index
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last updated on 2024-10-07 22:06 CEST by the dblp team
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