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Wei Zhang 0002
Person information
- affiliation: Virginia Commonwealth University, Compiler, Architecture, and Realtime Systems Lab, Richmond, VA, USA
- affiliation: Southern Illinois University
- affiliation (PhD): Pennsylvania State University
Other persons with the same name
- Wei Zhang — disambiguation page
- Wei Zhang 0001
— University of New South Wales, Sydney, NSW, Australia (and 2 more)
- Wei Zhang 0003 — Apple, Santa Clara, CA, USA (and 2 more)
- Wei Zhang 0004 — Peking University, Institute of Software, Beijing, China
- Wei Zhang 0005
- Wei Zhang 0006 — Tsinghua University, Department of Industrial Engineering, Beijing, China
- Wei Zhang 0007 — Bell Mobility, Mississauga, Canada (and 1 more)
- Wei Zhang 0008 — Amazon, Seattle, WA, USA (and 2 more)
- Wei Zhang 0009 — Xidian University, Key Laboratory of Intelligent Perception and Image Understanding of Ministry of Education of China, Xi'an, China
- Wayne Zhang 0001
- Wei Zhang 0011 — The University of Texas, M. D. Anderson Cancer Center, TX, USA
- Wei Zhang 0012
- Wei Zhang 0013
- Wei Zhang 0014 — Google (and 1 more)
- Wei Zhang 0015 — Boeing Research (and 1 more)
- Wei Zhang 0016
- Wei Zhang 0017 — Harbin Institute of Technology, School of Computer Science and Technology, China
- Wei Zhang 0018 — SAIC, VA, USA (and 2 more)
- Wei Zhang 0019 — Peking University, College of Chemistry and Molecular Engineering, Beijing, China
- Wei Zhang 0020
- Wei Zhang 0021
- Wei Zhang 0022 — IBM Thomas J. Watson Research Center, Yorktown Heights, NY, USA (and 1 more)
- Wei Zhang 0023 — Quantlab Financial (and 1 more)
- Wei Zhang 0024 — Worcester Polytechnic Institute
- Wei Zhang 0025 — Huazhong University of Science and Technology, Department of Electronics and Information Engineering, Hubei, China (and 2 more)
- Wei Zhang 0026 — Tianjin University, College of Management and Economics, Beijing, China
- Wei Zhang 0027 — National University of Defence Technology, ChangSha, China
- Wei Zhang 0028 — Henan Polytechni University, School of Electrical Engineering and Automation, China
- Wei Zhang 0029
- Wei Zhang 0030 — University of Sussex, UK
- Wei Zhang 0031
- Wei Zhang 0032 — University of Minnesota, Minneapolis, MN, USA
- Wei Zhang 0033
- Wei Zhang 0034 — McGill University
- Wei Zhang 0035
- Wei Zhang 0036 — FernUniversität Hagen, Germany
- Wei Zhang 0037 — Rockwell Collions Government Systems (and 1 more)
- Wei Zhang 0038 — National University of Singapore
- Wei Zhang 0039 — Illinois Institute of Technology
- Wei Zhang 0040 — Tsinghua University, Network Architecture Lab, Beijing, China
- Wei Zhang 0041 — Texas A&M University, Department of Computer Science and Engineering, TX, USA
- Wei Zhang 0042 — China University of Mining and Technology, School of Information and Electrical Engineering, Xuzhou, China
- Wei Zhang 0043 — Chinese Academy of Sciences, Institute of Computing Technology, Beijing, China
- Wei Zhang 0044
- Wei Zhang 0045 — China Academy of Engineering Physics (CAEP), Institute of Electronic Engineering, Mianyang, China
- Wei Zhang 0046 — South China Normal University, School of Psychology, Guangzhou, Guangdong, China
- Wei Zhang 0047 — National Library of China, Digital Resources and Services Department, Beijing, China
- Wei Zhang 0048
- Wei Zhang 0049
- Wei Zhang 0050 — Xi'an Jiaotong University, College of Science, Xi'an, Shanxi, China
- Wei Zhang 0051 — Oracle Corporation, Redwood City, USA
- Wei Zhang 0052
- Wei Zhang 0053 — Amazon, Seattle, WA, USA
- Wei Zhang 0054
- Wei Zhang 0055
- Wei Zhang 0056
- Wei Zhang 0057
- Wei Zhang 0058 — University of Wisconsin-Madison, WI, USA (and 1 more)
- Wei Zhang 0059 — Twitter, Inc. (and 1 more)
- Wei Zhang 0060 — University of Texas at Arlington, TX, USA
- Wei Zhang 0061 — QUALCOMM, Inc., San Diego, CA, USA (and 1 more)
- Wei Zhang 0062 — Brown University, Providence, RI, USA
- Wei Zhang 0063 — University of Kentucky, Lexington, KY, USA
- Wei Zhang 0064 — Florida Atlantic University, Boca Raton, FL, USA
- Wei Zhang 0065
- Wei Zhang 0067
- Wei Zhang 0068
- Wei Zhang 0069
- Wei Zhang 0070
- Wei Zhang 0071
- Wei Zhang 0072
- Wei Zhang 0073
- Wei Zhang 0074
- Wei Zhang 0075
- Wei Zhang 0076
- Wei Zhang 0077
- Wei Zhang 0078 — Tsinghua University, Institute of Microelectronics, Beijing, China
- Wei Zhang 0079
- Wei Zhang 0080 — Bohai University, College of New Energy, Jinzhou, China
- Wei Zhang 0081
- Wei Zhang 0082
- Wei Zhang 0083 — Zhejiang University, Institute of Microelectronics and Optoelectronics, China
- Wei Zhang 0084
- Wei Zhang 0085 — Fudan University, School of Computer Science, Shanghai, China
- Wei Zhang 0086 — Huazhong University of Science and Technology, School of Computer Science and Technology, Wuhan, China
- Wei Zhang 0087 — Beijing University of Posts and Telecommunications, MoE Key Laboratory of Optical Communication and Lightwave Technologies, China
- Wei Zhang 0088
- Wei Zhang 0089
- Wei Zhang 0090 — University of Georgia, Department of Computer Science / Bioimaging Research Center, Cortical Architecture Imaging and Discovery Lab, Athens, GA, USA
- Wei Zhang 0091
- Wei Zhang 0092
- Wei Zhang 0093
- Wei Zhang 0094 — Beijing Information Technology Institute, Sensing Technique Research Center, China
- Wei Zhang 0095 — Northwestern Polytechnical University, School of Aeronautics, Xi'an, China
- Wei Zhang 0096 — Central China Normal University, School of Psychology, Wuhan, China
- Wei Zhang 0097
- Wei Zhang 0098
- Wei Zhang 0099
- Wei Zhang 0100
- Wei Zhang 0101
- Wei Zhang 0102
- Wei Zhang 0103
- Wei Zhang 0104
- Wei Zhang 0105
- Wei Zhang 0106
- Wei Zhang 0107
- Wei Zhang 0108
- Wei Zhang 0109
- Wei Zhang 0110
- Wei Zhang 0111
- Wei Zhang 0112
- Wei Zhang 0113
- Wei Zhang 0114
- Wei Zhang 0115
- Wei Zhang 0116 — Royal Holloway, University of London, Egham, UK
- Wei Zhang 0117 — University of California, Los Angeles, Department of Materials Science and Engineering, CA, USA
- Wei Zhang 0118 — University of California, Santa Barbara, USA
- Wei Zhang 0119
- Wei Zhang 0121
- Wei Zhang 0122
- Wei Zhang 0123
- Wei Zhang 0124
- Wei Zhang 0125
- Wei Zhang 0126
- Wei Zhang 0127 — Alibaba Group, AZFT Joint Lab of Knowledge Engine, Hangzhou, China
- Wei Zhang 0128 — Beijing Jiaotong University, State Key Laboratory of Traffic Control and Safety, Beijing, China
- Wei Zhang 0129
- Wei Zhang 0130
- Wei Zhang 0131
- Wei Zhang 0132
- Wei Zhang 0133
- Wei Zhang 0134
- Wei Zhang 0135
- Wei Zhang 0136
- Wei Zhang 0137
- Wei Zhang 0138
- Wei Zhang 0139
- Wei Zhang 0140
- Wei Zhang 0141
- Wei Zhang 0142
- Wei Zhang 0143
- Wei Zhang 0144
- Wei Zhang 0145
- Wei Zhang 0146
- Wei Zhang 0147
- Wei Zhang 0148
- Wei Zhang 0149
- Wei Zhang 0150
- Wei Zhang 0152 — Google Inc., Mountain View, USA
- Wei Zhang 0154
- Wei Zhang 0155
- Wei Zhang 0156
- Wei Zhang 0157
- Wei Zhang 0158
- Wei Zhang 0159
- Wei Zhang 0160
- Wei Zhang 0161
- Wei Zhang 0162
- Wei Zhang 0163
- Wei Zhang 0164
- Wei Zhang 0165
- Wei Zhang 0166
- Wei Zhang 0167
- Wei Zhang 0168 — Central China Normal University, Department of Computer Science, Wuhan, Hubei, China
- Wei Zhang 0169 — Zaozhuang University, School of Information Science and Engineering, China
- Wei Zhang 0170
- Wei Zhang 0171
- Wei Zhang 0172
- Wei Zhang 0173
- Wei Zhang 0174
- Wei Zhang 0175 — University of Notre Dame, Department of Computer Science and Engineering, IN, USA
- Wei Zhang 0176
- Wei Zhang 0177 — Army Academy of Armored Forces, Beijing, China
- Wei Zhang 0178
- Wei Zhang 0179
- Wei Zhang 0180
- Wei Zhang 0181
- Wei Zhang 0182
- Wei Zhang 0183
- Wei Zhang 0184
- Wei Zhang 0185
- Wei Zhang 0186
- Wei Zhang 0187
- Wei Zhang 0188
- Wei Zhang 0189
- Wei Zhang 0190 — McGill University, Department of Linguistics, Montreal, Canada (and 1 more)
- Wei Zhang 0191
- Wei Zhang 0192
- Wei Zhang 0193
- Wei Zhang 0194 — Chinese Academy of Sciences, Institute of Information Engineering, State Key Laboratory of Information Security, Beijing, China (and 1 more)
- Wei Zhang 0195 — Xidian University, National Lab of Radar Signal Processing, Xi'an, China
- Wei Zhang 0196 — Huawei Technologies, Noah's Ark Lab
- Wei Zhang 0197 — Baidu Inc., Department of Computer Vision Technology, China
- Wei Zhang 0198
- Wei Zhang 0199 — Dalian University of Technology, School of Computer Science and Technology, Dalian, China
- Wei Zhang 0200
- Wei Zhang 0202
- Wei Zhang 0203
- Wei Zhang 0204
- Wei Zhang 0205
- Wei Zhang 0206 — University of Electronic Science and Technology of China, School of Information and Communication Engineering, Chengdu, China (and 1 more)
- Wei Zhang 0207 — University of Guelph, School of Engineering, Guelph, Canada
- Wei Zhang 0208 — Engineering University of People's Armed Police, College of Cryptography Engineering, Key Laboratory of Network & Information Security under the People's Armed Police, Xi'an, China
- Wei Zhang 0209
- Wei Zhang 0210
- Wei Zhang 0211
- Wei Zhang 0212
- Wei Zhang 0213
- Wei Zhang 0214
- Wei Zhang 0215
- Wei Zhang 0216
- Wei Zhang 0217
- Wei Zhang 0218
- Wei Zhang 0219
- Wei Zhang 0220 — Harbin Institute of Technology, Research Center for Space Optical Engineering, Harbin, China
- Wei Zhang 0221
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2020 – today
- 2021
- [j59]Hao Wen, Wei Zhang
Cache Leakage Reduction Techniques for Hybrid SPM-Cache Architectures. J. Circuits Syst. Comput. 30(1): 2150008:1-2150008:22 (2021) - 2020
- [j58]Hao Wen, Wei Zhang:
Reducing CPU-GPU Interferences to Improve CPU Performance in Heterogeneous Architectures. J. Comput. Sci. Eng. 14(4): 131-145 (2020) - [c95]Xin Wang, Wei Zhang:
Packing Narrow-Width Operands to Improve Energy Efficiency of General-Purpose GPU Computing. HPEC 2020: 1-7 - [c94]Hao Wen, Wei Zhang:
Denial of Service in CPU-GPU Heterogeneous Architectures. HPEC 2020: 1-5 - [c93]Xin Wang, Wei Zhang:
pacSCA: A Profiling-Assisted Correlation-based Side-Channel Attack on GPUs. ICCD 2020: 525-528
2010 – 2019
- 2019
- [c92]Hao Wen, Wei Zhang:
Heterogeneous Cache Hierarchy Management for Integrated CPU-GPU Architecture. HPEC 2019: 1-6 - [c91]Hao Wen, Wei Zhang:
Improving Parallelism of Breadth First Search (BFS) Algorithm for Accelerated Performance on GPUs. HPEC 2019: 1-7 - [c90]Xin Wang, Wei Zhang:
Cracking Randomized Coalescing Techniques with An Efficient Profiling-Based Side-Channel Attack to GPU. HASP@ISCA 2019: 2:1-2:8 - [c89]Hangjun Che
A Collaborative Neurodynamic Approach to Sparse Coding. ISNN (1) 2019: 454-462 - [c88]Xin Wang, Wei Zhang:
Execution Units Power-Gating to Improve Energy Efficiency of GPGPUs. iThings/GreenCom/CPSCom/SmartData 2019: 711-718 - [c87]Xin Wang, Wei Zhang:
An Efficient Profiling-Based Side-Channel Attack on Graphics Processing Units. NCS 2019: 126-139 - 2018
- [j57]Lan Wu, Wei Zhang
Cache-Aware SPM Allocation to Reduce Worst-Case Execution Time for Hybrid SPM-Caches. J. Circuits Syst. Comput. 27(5): 1850080:1-1850080:23 (2018) - [j56]Xin Wang, Wei Zhang:
Packing Narrow-Width Operands to Improve GPU Performance. J. Comput. Sci. Eng. 12(2): 37-49 (2018) - [j55]Xin Wang, Wei Zhang:
Improving CPU and GPU Performance through Sample-Based Dynamic LLC Bypassing. J. Comput. Sci. Eng. 12(2): 50-62 (2018) - [j54]Lan Wu, Wei Zhang:
Cache-Aware SPM Allocation Algorithms for Performance and Energy Optimization on Hybrid SPM-Cache Architecture. J. Comput. Sci. Eng. 12(3): 91-105 (2018) - [j53]Hao Wen, Wei Zhang:
Exploring GPU Data Cache Leakage Management Techniques. J. Comput. Sci. Eng. 12(3): 106-114 (2018) - [j52]Yijie Huangfu, Wei Zhang:
Estimating the Worst-Case Execution Time of the Shared Data Cache in Integrated CPU-GPU Architectures. J. Comput. Sci. Eng. 12(4): 139-148 (2018) - [c86]Yijie Huangfu, Wei Zhang:
WCET Analysis of GPU L1 Data Caches. HPEC 2018: 1-7 - [c85]Xin Wang, Wei Zhang:
Energy-Efficient DNN Computing on GPUs Through Register File Management. HPEC 2018: 1-7 - [c84]Hao Wen, Wei Zhang:
Regression Based WCET Analysis For Sampling Based Motion Planning. HPEC 2018: 1-6 - [c83]Hao Wen, Wei Zhang:
Exploiting GPU with 3D Stacked Memory to Boost Performance for Data-Intensive Applications. HPEC 2018: 1-6 - [c82]Hao Wen, Wei Zhang:
Reducing Inter-Application Interferences in Integrated CPU-GPU Heterogeneous Architecture. ICCD 2018: 278-281 - 2017
- [j51]Yijie Huangfu, Wei Zhang:
Warp-Based Load/Store Reordering to Improve GPU Time Predictability. J. Comput. Sci. Eng. 11(2) (2017) - [j50]Yijie Huangfu, Wei Zhang:
Enhancing GPU Performance by Efficient Hardware-Based and Hybrid L1 Data Cache Bypassing. J. Comput. Sci. Eng. 11(2) (2017) - [c81]Yijie Huangfu, Wei Zhang:
WCET analysis of the shared data cache in integrated CPU-GPU architectures. HPEC 2017: 1-7 - [c80]Yijie Huangfu, Wei Zhang:
Leakage energy reduction for hard real-time caches. HPEC 2017: 1-6 - [c79]Xin Wang, Wei Zhang:
Drowsy Register Files for Reducing GPU Leakage Energy. ICPADS 2017: 632-639 - [c78]Yijie Huangfu, Wei Zhang:
Static WCET Analysis of GPUs with Predictable Warp Scheduling. ISORC 2017: 101-108 - [c77]Xin Wang, Wei Zhang:
GPU Register Packing: Dynamically Exploiting Narrow-Width Operands to Improve Performance. TrustCom/BigDataSE/ICESS 2017: 745-752 - [c76]Xin Wang, Wei Zhang:
A Sample-Based Dynamic CPU and GPU LLC Bypassing Method for Heterogeneous CPU-GPU Architectures. TrustCom/BigDataSE/ICESS 2017: 753-760 - 2016
- [j49]Jun Yan, Wei Zhang:
Priority L2 cache design for time predictability. Int. J. Embed. Syst. 8(5/6): 427-439 (2016) - [c75]Xin Wang, Wei Zhang:
Cache locking vs. partitioning for real-time computing on integrated CPU-GPU processors. IPCCC 2016: 1-8 - [c74]Yijie Huangfu, Wei Zhang:
Warp-Based Load/Store Reordering to Improve GPU Data Cache Time Predictability and Performance. ISORC 2016: 166-173 - 2015
- [j48]Yu Liu, Wei Zhang:
Scratchpad Memory Architectures and Allocation Algorithms for Hard Real-Time Multicore Processors. J. Comput. Sci. Eng. 9(2) (2015) - [j47]Yiqiang Ding, Wei Zhang:
Exploiting Static Non-Uniform Cache Architectures for Hard Real-Time Computing. J. Comput. Sci. Eng. 9(4) (2015) - [j46]Yijie Huangfu, Wei Zhang:
Profiling-based L1 data cache bypassing to improve GPU performance and energy efficiency. SIGBED Rev. 12(1): 7-11 (2015) - [c73]Yijie Huangfu, Wei Zhang:
Boosting GPU Performance by Profiling-Based L1 Data Cache Bypassing. CCGRID 2015: 1119-1122 - [c72]Yijie Huangfu, Wei Zhang:
Hardware-Based and Hybrid L1 Data Cache Bypassing to Improve GPU Performance. HPCC/CSS/ICESS 2015: 972-976 - [c71]Yijie Huangfu, Wei Zhang:
Hardware-Based Performance Enhancement Guaranteed Caches. ISORC 2015: 166-173 - [c70]Yijie Huangfu, Wei Zhang:
Real-Time GPU Computing: Cache or No Cache? ISORC 2015: 182-189 - [c69]Lan Wu, Wei Zhang:
Cache-aware SPM allocation algorithms for hybrid SPM-cache architectures. ISQED 2015: 123-129 - [c68]Hao Wen, Wei Zhang:
Exploring shared memory and cache to improve GPU performance and energy efficiency. ISQED 2015: 402-405 - 2014
- [j45]Yijie Huangfu, Wei Zhang:
PEG-C: Performance Enhancement Guaranteed Cache for Hard Real-Time Systems. IEEE Embed. Syst. Lett. 6(2): 17-20 (2014) - [j44]Lan Wu, Yiqiang Ding, Wei Zhang:
Comparing Separate and Statically-Partitioned Caches for Time-Predictable Multicore Processors. J. Comput. Sci. Eng. 8(1): 25-33 (2014) - [j43]Wei Zhang, Yiqiang Ding:
Exploiting Standard Deviation of CPI to Evaluate Architectural Time-Predictability. J. Comput. Sci. Eng. 8(1): 34-42 (2014) - [j42]Yu Liu, Wei Zhang:
Two-Level Scratchpad Memory Architectures to Achieve Time Predictability and High Performance. J. Comput. Sci. Eng. 8(4): 215-227 (2014) - [c67]Hao Wen, Wei Zhang:
Reducing cache leakage energy for hybrid SPM-cache architectures. CASES 2014: 21:1-21:9 - [c66]Yiqiang Ding, Wei Zhang:
Hop-Based Priority Scheduling to Improve Worst-Case Inter-core Communication Latency. EUC 2014: 52-57 - [c65]Yu Sun, Wei Zhang:
Improving Energy Efficiency with Dynamic Compiler-Directed Function Unit Power Control. EUC 2014: 329-333 - [c64]Matthew Loach, Wei Zhang:
Performance Implication of Multicore Cache Locking on General-Purpose Processors. HPCC/CSS/ICESS 2014: 328-331 - [c63]Wei Zhang, Lan Wu:
Exploiting Hybrid SPM-Cache Architectures to Reduce Energy Consumption for Embedded Computing. HPCC/CSS/ICESS 2014: 340-347 - [c62]Lan Wu, Yiqiang Ding, Wei Zhang:
Characterizing Energy Consumption of Real-Time and Media Benchmarks on Hybrid SPM-Caches. HPCC/CSS/ICESS 2014: 526-533 - [c61]Yiqiang Ding, Wei Zhang:
Bounding the Worst-Case Execution Time of Static NUCA Caches. HPCC/CSS/ICESS 2014: 1181-1184 - [c60]Yiqiang Ding, Wei Zhang:
WCET analysis of static NUCA caches. IPCCC 2014: 1-6 - [c59]Yijie Huangfu, Wei Zhang:
Worst-case performance guaranteed data cache. IPCCC 2014: 1-2 - [c58]Yijie Huangfu, Wei Zhang:
A Real-Time Instruction Cache with High Average-Case Performance. ISORC 2014: 109-116 - [c57]Yijie Huangfu, Wei Zhang:
Compiler-directed leakage energy reduction for instruction scratch-pad memories. ISQED 2014: 392-399 - 2013
- [j41]Yiqiang Ding, Lan Wu, Wei Zhang:
Bounding Worst-Case DRAM Performance on Multicore Processors. J. Comput. Sci. Eng. 7(1): 53-66 (2013) - [j40]Yiqiang Ding, Wei Zhang:
Multicore Real-Time Scheduling to Reduce Inter-Thread Cache Interferences. J. Comput. Sci. Eng. 7(1): 67-80 (2013) - [j39]Yu Sun, Wei Zhang:
Overview of Real-Time Java Computing. J. Comput. Sci. Eng. 7(2): 89-98 (2013) - [j38]Yiqiang Ding, Wei Zhang:
Counter-Based Approaches for Efficient WCET Analysis of Multicore Processors with Shared Caches. J. Comput. Sci. Eng. 7(4): 285-299 (2013) - [j37]Yu Liu, Wei Zhang:
Static worst-case lifetime estimation of wireless sensor networks: A case study on VigilNet. J. Syst. Archit. 59(4-5): 224-233 (2013) - [c56]Wei Zhang, Yiqiang Ding:
Standard deviation of CPI: A new metric to evaluate architectural time predictability. ASAP 2013: 111-112 - [c55]Wei Zhang, Yiqiang Ding:
Hybrid SPM-cache architectures to achieve high time predictability and performance. ASAP 2013: 297-304 - [c54]Yijie Huangfu, Wei Zhang:
Compiler-based approach to reducing leakage energy of instruction scratch-pad memories. ICCD 2013: 439-442 - [c53]Lan Wu, Wei Zhang:
Reducing worst-case execution time of hybrid SPM-caches. IPCCC 2013: 1-9 - [c52]Wei Zhang:
Defend GPUs against DoS attacks. IPCCC 2013: 1-2 - [c51]Yiqiang Ding, Wei Zhang:
On the interactions between real-time scheduling and inter-thread cached interferences for multicore processors. ISQED 2013: 627-634 - 2012
- [j36]Yiqiang Ding, Wei Zhang:
Multicore-Aware Code Co-Positioning to Reduce WCET on Dual-Core Processors with Shared Instruction Caches. J. Comput. Sci. Eng. 6(1): 12-25 (2012) - [j35]Yu Sun, Wei Zhang:
Time-Predictable Java Dynamic Compilation on Multicore Processors. J. Comput. Sci. Eng. 6(1): 26-38 (2012) - [j34]Yu Sun, Wei Zhang:
On-line Trace Based Automatic Parallelization of Java Programs on Multicore Platforms. J. Comput. Sci. Eng. 6(2): 105-118 (2012) - [j33]Wei Zhang, Jun Yan:
Static Timing Analysis of Shared Caches for Multicore Processors. J. Comput. Sci. Eng. 6(4): 267-278 (2012) - [j32]Yiqiang Ding, Wei Zhang:
Architectural time-predictability factor (ATF): a metric to evaluate time predictability of processors. SIGBED Rev. 9(4): 6-15 (2012) - [j31]Lan Wu, Wei Zhang:
A Model Checking Based Approach to Bounding Worst-Case Execution Time for Multicore Processors. ACM Trans. Embed. Comput. Syst. 11(S2): 56:1-56:19 (2012) - [c50]Yu Liu, Wei Zhang:
Exploiting SPM-aware Scheduling on EPIC architectures for high-performance real-time systems. HPEC 2012: 1-2 - [c49]Yu Liu, Wei Zhang:
Exploiting multi-level scratchpad memories for time-predictable multicore computing. ICCD 2012: 61-66 - 2011
- [j30]Abhishek Pillai, Wei Zhang:
Exploiting Instruction Reuse to Improve the Performance of Dual Instruction Execution. J. Circuits Syst. Comput. 20(5): 899-913 (2011) - [j29]Jun Yan, Wei Zhang:
Bounding Worst-Case Performance for Multi-Core Processors with Shared L2 Instruction Caches. J. Comput. Sci. Eng. 5(1): 1-18 (2011) - [j28]Jun Yan, Wei Zhang:
Computing and Reducing Transient Error Propagation in Registers. J. Comput. Sci. Eng. 5(2): 121-130 (2011) - [j27]Jun Yan, Wei Zhang:
An Interference Matrix Based Approach to Bounding Worst-Case Inter-Thread Cache Interferences and WCET for Multi-Core Processors. J. Comput. Sci. Eng. 5(2): 131-140 (2011) - [c48]Yu Sun, Wei Zhang:
On-Line Trace Based Automatic Parallelization of Java Programs on Multicore Platforms. Interaction between Compilers and Computer Architectures 2011: 35-43 - [c47]Wei Zhang:
Work in progress - Course development of programming for general-purpose multicore processors. FIE 2011: S3 - [c46]Yu Liu, Wei Zhang:
Static Worst-Case Lifetime Estimation of Vigil Net. GreenCom 2011: 1-8 - [c45]Yiqiang Ding, Wei Zhang:
Multicore-Aware Code Positioning to Improve Worst-Case Performance. ISORC 2011: 225-232 - [c44]Yu Liu, Wei Zhang:
Exploiting time predictable two-level scratchpad memory for real-time systems. SAC 2011: 395-396 - [c43]Yu Liu, Wei Zhang:
Stack distance based worst-case instruction cache performance analysis. SAC 2011: 723-728 - 2010
- [j26]Jun Yan, Wei Zhang:
Design and implementation of hybrid multicore simulators. Int. J. Embed. Syst. 4(3/4): 270-275 (2010) - [j25]Wei Zhang:
Replica victim caching to improve cache reliability against transient errors. Int. J. High Perform. Syst. Archit. 2(3/4): 229-239 (2010) - [j24]Shu-Hui Yin, Yufang Liu, Wei Zhang, Ming-Xing Guo, Peng Song:
Time-dependent density functional theory study on the hydrogen bonding-induced twisted intramolecular charge-transfer excited states of 2-(4'-N, N-dimethylaminophenyl)imidazo[4, 5-b]pyridine. J. Comput. Chem. 31(10): 2056-2062 (2010) - [j23]Yu Liu, Wei Zhang, Kemal Akkaya:
Static Worst-Case Energy and Lifetime Estimation of Wireless Sensor Networks. J. Comput. Sci. Eng. 4(2): 128-152 (2010) - [j22]Yiqiang Ding, Wei Zhang:
Loop-Based Instruction Prefetching to Reduce the Worst-Case Execution Time. IEEE Trans. Computers 59(6): 855-864 (2010) - [c42]Satya Mohan Raju Gudidevuni, Wei Zhang:
A time-predictable dual-core prototype on FPGA. ACM Southeast Regional Conference 2010: 7 - [c41]Yiqiang Ding, Wei Zhang:
Improving the static real-time scheduling on multicore processors by reducing worst-case inter-thread cache interferences. ACM Southeast Regional Conference 2010: 108 - [c40]Jun Yan, Wei Zhang:
Time-Predictable L2 Cache Design for High-Performance Real-Time Systems. RTCSA 2010: 357-366
2000 – 2009
- 2009
- [j21]Yu Sun, Wei Zhang:
Improving Java performance and energy dissipation through efficient code caching. Des. Autom. Embed. Syst. 13(3): 179-192 (2009) - [j20]Wei Zhang:
Computing and Minimizing Cache Vulnerability to Transient Errors. IEEE Des. Test Comput. 26(2): 44-51 (2009) - [j19]Yu Sun, Wei Zhang:
Studying Energy-Oriented Dynamic Optimizations in Java Virtual Machines. J. Circuits Syst. Comput. 18(1): 103-120 (2009) - [j18]Wei Zhang:
Boosting the Performance of Software-Based Transient Errors Tolerant Techniques through Compiler Optimizations. J. Circuits Syst. Comput. 18(4): 771-786 (2009) - [j17]Yiqiang Ding, Jun Yan, Wei Zhang:
Optimizing Instruction Prefetching to Improve Worst-Case Performance for Real-Time Applications. J. Comput. Sci. Eng. 3(1): 59-71 (2009) - [j16]Yu Liu, Wei Zhang:
Bounding Worst-Case Data Cache Performance by Using Stack Distance. J. Comput. Sci. Eng. 3(4): 195-215 (2009) - [c39]Yu Liu, Wei Zhang, Kemal Akkaya:
Static worst-case energy and lifetime estimation of wireless sensor networks. IPCCC 2009: 17-24 - [c38]Yu Sun, Wei Zhang:
Exploiting Multi-core Processors to Improve Time Predictability for Real-Time Java Computing. RTCSA 2009: 447-454 - [c37]Wei Zhang, Jun Yan:
Accurately Estimating Worst-Case Execution Time for Multi-core Processors with Shared Direct-Mapped Instruction Caches. RTCSA 2009: 455-463 - [c36]Yu Liu, Wei Zhang:
Exploiting stack distance to estimate worst-case data cache performance. SAC 2009: 1979-1983 - 2008
- [j15]Jun Yan, Wei Zhang:
A time-predictable VLIW processor and its compiler support. Real Time Syst. 38(1): 67-84 (2008) - [j14]Jun Yan, Wei Zhang:
Exploiting virtual registers to reduce pressure on real registers. ACM Trans. Archit. Code Optim. 4(4): 3:1-3:18 (2008) - [j13]Jun Yan, Wei Zhang:
Analyzing the worst-case execution time for instruction caches with prefetching. ACM Trans. Embed. Comput. Syst. 8(1): 7:1-7:19 (2008) - [c35]Yu Sun, Wei Zhang:
Efficient code caching to improve performance and energy consumption for java applications. CASES 2008: 119-126 - [c34]Yu Sun, Wei Zhang:
On the Energy Efficiency of Java Virtual Machine. ESA 2008: 29-33 - [c33]Yu Sun, Wei Zhang:
Adaptive Drowsy Cache Control for Java Applications. EUC (1) 2008: 185-191 - [c32]Yu Sun, Wei Zhang:
Improving code caching performance for Java applications. IPDPS 2008: 1-5 - [c31]Jun Yan, Wei Zhang:
WCET Analysis for Multi-Core Processors with Shared L2 Instruction Caches. IEEE Real-Time and Embedded Technology and Applications Symposium 2008: 80-89 - 2007
- [j12]Wei Zhang:
Compiler-Assisted Leakage Energy Reduction for Cache Memories. Adv. Comput. 69: 155-189 (2007) - [j11]Jun Yan, Wei Zhang:
Hybrid multi-core architecture for boosting single-threaded performance. SIGARCH Comput. Archit. News 35(1): 141-148 (2007) - [j10]Jun Yan, Wei Zhang:
Evaluating instruction cache vulnerability to transient errors. SIGARCH Comput. Archit. News 35(4): 21-28 (2007) - [j9]Wei Zhang, Bramha Allu:
Reducing branch predictor leakage energy by exploiting loops. ACM Trans. Embed. Comput. Syst. 6(2): 11 (2007) - [c30]Abhishek Pillai, Wei Zhang, Laurence Tianruo Yang:
Exploring Functional Unit Design Space of VLIW Processors for Optimizing Both Performance and Energy Consumption. AINA Workshops (1) 2007: 792-797 - [c29]Mallik Kandala, Wei Zhang, Laurence Tianruo Yang:
An Area-Efficient Approach to Improving Register File Reliability against Transient Errors. AINA Workshops (1) 2007: 798-803 - [c28]Abhishek Pillai, Wei Zhang, Dimitrios Kagaris:
Detecting VLIW Hard Errors Cost-Effectively through a Software-Based Approach. AINA Workshops (1) 2007: 811-815 - [c27]Jun Yan, Wei Zhang:
Virtual Registers: Reducing Register Pressure Without Enlarging the Register File. HiPEAC 2007: 57-70 - [c26]Wei Zhang, Gregory J. Zelinsky, Dimitris Samaras:
Real-time Accurate Object Detection using Multiple Resolutions. ICCV 2007: 1-8 - [c25]Jun Yan, Wei Zhang:
WCET analysis of instruction caches with prefetching. LCTES 2007: 175-184 - 2006
- [j8]Wei Zhang:
Compiler-guided next sub-bank prediction for reducing instruction cache leakage energy. J. Embed. Comput. 2(1): 35-48 (2006) - [j7]Bramha Allu, Wei Zhang:
Reducing Instruction Translation Look-Aside Buffer Energy Through Compiler-Directed Resizing. J. Low Power Electron. 2(2): 140-147 (2006) - [j6]Wei Zhang, Yuh-Fang Tsai, David Duarte, Narayanan Vijaykrishnan, Mahmut T. Kandemir, Mary Jane Irwin:
Reducing dynamic and leakage energy in VLIW architectures. ACM Trans. Embed. Comput. Syst. 5(1): 1-28 (2006) - [c24]Nagm Mohamed, Nazeih Botros, Wei Zhang:
The Impact of Cache Organization in Optimizing Microprocessor Power Consumption. CDES 2006: 84-90 - 2005
- [j5]Wei Zhang:
Exploiting loop behavior for data cache leakage reduction. J. Embed. Comput. 1(4): 501-508 (2005) - [j4]Bramha Allu, Wei Zhang:
Exploiting the replication cache to improve performance for multiple-issue microprocessors. SIGARCH Comput. Archit. News 33(3): 63-71 (2005) - [j3]Wei Zhang:
Replication Cache: A Small Fully Associative Cache to Improve Data Cache Reliability. IEEE Trans. Computers 54(12): 1547-1555 (2005) - [j2]Wei Zhang, Mahmut T. Kandemir, Mustafa Karaköy, Guangyu Chen:
Reducing data cache leakage energy using a compiler-based approach. ACM Trans. Embed. Comput. Syst. 4(3): 652-678 (2005) - [c23]Wei Zhang, Bing Yu, Gregory J. Zelinsky, Dimitris Samaras:
Object Class Recognition Using Multiple Layer Boosting with Heterogeneous Features. CVPR (2) 2005: 323-330 - [c22]Wei Zhang:
Computing Cache Vulnerability to Transient Errors and Its Implication. DFT 2005: 427-435 - [c21]Jun Yan, Wei Zhang:
Compiler-guided register reliability improvement against soft errors. EMSOFT 2005: 203-209 - [c20]Gregory J. Zelinsky, Wei Zhang, Bing Yu, Xin Chen, Dimitris Samaras:
The Role of Top-down and Bottom-up Processes in Guiding Eye Movements during Visual Search. NIPS 2005: 1569-1576 - [c19]Wei Zhang, Hyejin Yang, Dimitris Samaras, Gregory J. Zelinsky:
A Computational Model of Eye Movements during Object Class Detection. NIPS 2005: 1609-1616 - 2004
- [j1]Wei Zhang, Jie S. Hu, Vijay Degalahal, Mahmut T. Kandemir, Narayanan Vijaykrishnan, Mary Jane Irwin:
Reducing instruction cache energy consumption using a compiler-based strategy. ACM Trans. Archit. Code Optim. 1(1): 3-33 (2004) - [c18]Wei Zhang:
Replica Victim Caching to Improve Reliability of In-Cache Replication. Asia-Pacific Computer Systems Architecture Conference 2004: 2-15 - [c17]Bramha Allu, Wei Zhang:
Static next sub-bank prediction for drowsy instruction cache. CASES 2004: 124-131 - [c16]Wei Zhang, Bramha Allu:
Loop-based leakage control for branch predictors. CASES 2004: 149-155 - [c15]Wei Zhang:
Enhancing data cache reliability by the addition of a small fully-associative replication cache. ICS 2004: 12-19 - [c14]Wei Zhang:
Compiler-Directed Data Cache Leakage Reduction. ISVLSI 2004: 305-306 - 2003
- [c13]Wei Zhang, Mahmut T. Kandemir, Anand Sivasubramaniam, Mary Jane Irwin:
Performance, energy, and reliability tradeoffs in replicating hot cache lines. CASES 2003: 309-317 - [c12]Wei Zhang, Guangyu Chen, Mahmut T. Kandemir, Mustafa Karaköy:
Interprocedural optimizations for improving data cache performance of array-intensive embedded applications. DAC 2003: 887-892 - [c11]Hendra Saputra, Narayanan Vijaykrishnan, Mahmut T. Kandemir, Mary Jane Irwin, Richard R. Brooks, Soontae Kim, Wei Zhang:
Masking the Energy Behavior of DES Encryption. DATE 2003: 10084-10089 - [c10]Mahmut T. Kandemir, Guangyu Chen, Wei Zhang, Ibrahim Kolcu:
Data Space Oriented Scheduling in Embedded Systems. DATE 2003: 10416-10421 - [c9]Mahmut T. Kandemir, Wei Zhang, Mustafa Karaköy:
Runtime Code Parallelization for On-Chip Multiprocessors. DATE 2003: 10510-10515 - [c8]Mahmut T. Kandemir, Ibrahim Kolcu, Wei Zhang:
Implementation and Evaluation of an On-Demand Parameter-Passing Strategy for Reducing Energy. DATE 2003: 11058-11063 - [c7]Wei Zhang, Mahmut T. Kandemir, Narayanan Vijaykrishnan, Mary Jane Irwin, Vivek De:
Compiler Support for Reducing Leakage Energy Consumption. DATE 2003: 11146-11147 - [c6]Guilin Chen, Guangyu Chen, Ismail Kadayif, Wei Zhang, Mahmut T. Kandemir, Ibrahim Kolcu, Ugur Sezer:
Compiler-Directed Management of Instruction Accesses. DSD 2003: 459-462 - [c5]Wei Zhang, Sudhanva Gurumurthi, Mahmut T. Kandemir, Anand Sivasubramaniam:
ICR: In-Cache Replication for Enhancing Data Cache Reliability. DSN 2003: 291-300 - [c4]Wei Zhang, Mustafa Karaköy, Mahmut T. Kandemir, Guangyu Chen:
A compiler approach for reducing data cache energy. ICS 2003: 76-85 - [p3]Mahmut T. Kandemir, Guangyu Chen, Wei Zhang, Ibrahim Kolcu:
Data Space Oriented Scheduling. Embedded Software for SoC 2003: 231-243 - [p2]Mahmut T. Kandemir, Wei Zhang, Mustafa Karaköy:
Dynamic Parallelization of Array Based On-Chip Multiprocessor Applications. Embedded Software for SoC 2003: 305-318 - [p1]Mahmut T. Kandemir, Ibrahim Kolcu, Wei Zhang:
Energy-Aware Parameter Passing. Embedded Software for SoC 2003: 499-512 - 2002
- [c3]Jie S. Hu, Mahmut T. Kandemir, Narayanan Vijaykrishnan, Mary Jane Irwin, Hendra Saputra, Wei Zhang:
Compiler-directed cache polymorphism. LCTES-SCOPES 2002: 165-174 - [c2]Wei Zhang, Jie S. Hu, Vijay Degalahal, Mahmut T. Kandemir, Narayanan Vijaykrishnan, Mary Jane Irwin:
Compiler-directed instruction cache leakage optimization. MICRO 2002: 208-218 - 2001
- [c1]Wei Zhang, Narayanan Vijaykrishnan, Mahmut T. Kandemir, Mary Jane Irwin, David Duarte, Yuh-Fang Tsai:
Exploiting VLIW schedule slacks for dynamic and leakage energy reduction. MICRO 2001: 102-113
Coauthor Index
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