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Engin Ipek
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- affiliation: Microsoft Research
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2020 – today
- 2024
- [i2]Ryan Wong, Nikita Kim, Kevin Higgs, Sapan Agarwal, Engin Ipek, Saugata Ghose, Ben Feinberg:
TCAM-SSD: A Framework for Search-Based Computing in Solid-State Drives. CoRR abs/2403.06938 (2024) - 2021
- [c30]Ben Feinberg, Ryan Wong, T. Patrick Xiao, Christopher H. Bennett, Jacob N. Rohan, Erik G. Boman, Matthew J. Marinella, Sapan Agarwal, Engin Ipek:
An Analog Preconditioner for Solving Linear Systems. HPCA 2021: 761-774 - 2020
- [j20]Darya Mikhailenko, Yujin Nakamoto, Ben Feinberg, Engin Ipek:
Adapting In Situ Accelerators for Sparsity with Granular Matrix Reordering. IEEE Comput. Archit. Lett. 19(2): 143-146 (2020) - [c29]Ben Feinberg, Benjamin C. Heyman, Darya Mikhailenko, Ryan Wong, An C. Ho, Engin Ipek:
Commutative Data Reordering: A New Technique to Reduce Data Movement Energy on Sparse Inference Workloads. ISCA 2020: 1076-1088
2010 – 2019
- 2019
- [j19]Engin Ipek:
Memristive Accelerators for Dense and Sparse Linear Algebra: From Machine Learning to High-Performance Scientific Computing. IEEE Micro 39(1): 58-61 (2019) - [j18]Shibo Wang, Mahdi Nazm Bojnordi, Xiaochen Guo, Engin Ipek:
Content Aware Refresh: Exploiting the Asymmetry of DRAM Retention Errors to Reduce the Refresh Frequency of Less Vulnerable Data. IEEE Trans. Computers 68(3): 362-374 (2019) - 2018
- [j17]Engin Ipek, Florian Longnos, Shihai Xiao, Wei Yang:
Bit-Level Load Balancing: A New Technique for Improving the Write Throughput of Deeply Scaled STT-MRAM. IEEE Comput. Archit. Lett. 17(2): 139-142 (2018) - [j16]Engin Ipek, Florian Longnos, Shihai Xiao, Wei Yang:
Vertical Writes: Closing the Throughput Gap between Deeply Scaled STT-MRAM and DRAM. IEEE Comput. Archit. Lett. 17(2): 151-154 (2018) - [j15]Matthew J. Marinella, Sapan Agarwal, Alexander H. Hsia, Isaac Richter, Robin Jacobs-Gedrim, John Niroula, Steven J. Plimpton, Engin Ipek, Conrad D. James:
Multiscale Co-Design Analysis of Energy, Latency, Area, and Accuracy of a ReRAM Analog Neural Training Accelerator. IEEE J. Emerg. Sel. Topics Circuits Syst. 8(1): 86-101 (2018) - [j14]Xiaochen Guo, Mahdi Nazm Bojnordi, Qing Guo, Engin Ipek:
Sanitizer: Mitigating the Impact of Expensive ECC Checks on STT-MRAM Based Main Memories. IEEE Trans. Computers 67(6): 847-860 (2018) - [c28]Ben Feinberg, Shibo Wang, Engin Ipek:
Making Memristive Neural Network Accelerators Reliable. HPCA 2018: 52-65 - [c27]Ben Feinberg, Uday Kumar Reddy Vengalam, Nathan Whitehair, Shibo Wang, Engin Ipek:
Enabling Scientific Computing on Memristive Accelerators. ISCA 2018: 367-382 - 2017
- [j13]Mahdi Nazm Bojnordi, Engin Ipek:
The Memristive Boltzmann Machines. IEEE Micro 37(3): 22-29 (2017) - [c26]Yuxin Bai, Victor W. Lee, Engin Ipek:
Voltage Regulator Efficiency Aware Power Management. ASPLOS 2017: 825-838 - [i1]Matthew J. Marinella, Sapan Agarwal, Alexander H. Hsia, Isaac Richter, Robin Jacobs-Gedrim, John Niroula, Steven J. Plimpton, Engin Ipek, Conrad D. James:
Multiscale Co-Design Analysis of Energy, Latency, Area, and Accuracy of a ReRAM Analog Neural Training Accelerator. CoRR abs/1707.09952 (2017) - 2016
- [j12]Ravi Patel, Xiaochen Guo, Qing Guo, Engin Ipek, Eby G. Friedman:
Reducing Switching Latency and Energy in STT-MRAM Caches With Field-Assisted Writing. IEEE Trans. Very Large Scale Integr. Syst. 24(1): 129-138 (2016) - [j11]Yuxin Bai, Yanwei Song, Mahdi Nazm Bojnordi, Alexander E. Shapiro, Eby G. Friedman, Engin Ipek:
Back to the Future: Current-Mode Processor in the Era of Deeply Scaled CMOS. IEEE Trans. Very Large Scale Integr. Syst. 24(4): 1266-1279 (2016) - [c25]Mahdi Nazm Bojnordi, Engin Ipek:
Memristive Boltzmann machine: A hardware accelerator for combinatorial optimization and deep learning. HPCA 2016: 1-13 - [c24]Shibo Wang, Engin Ipek:
Reducing data movement energy via online data clustering and encoding. MICRO 2016: 32:1-32:13 - 2015
- [j10]Qing Guo, Xiaochen Guo, Yuxin Bai, Ravi Patel, Engin Ipek, Eby G. Friedman:
Resistive Ternary Content Addressable Memory Systems for Data-Intensive Computing. IEEE Micro 35(5): 62-71 (2015) - [j9]Mohammad Kazemi, Engin Ipek, Eby G. Friedman:
Energy-Efficient Nonvolatile Flip-Flop With Subnanosecond Data Backup Time for Fine-Grain Power Gating. IEEE Trans. Circuits Syst. II Express Briefs 62-II(12): 1154-1158 (2015) - [c23]Yanwei Song, Mahdi Nazm Bojnordi, Engin Ipek:
Energy-efficient data movement with sparse transition encoding. ICCD 2015: 399-402 - [c22]Yuxin Bai, Yanwei Song, Mahdi Nazm Bojnordi, Alexander E. Shapiro, Engin Ipek, Eby G. Friedman:
Architecting a MOS current mode logic (MCML) processor for fast, low noise and energy-efficient computing in the near-threshold regime. ICCD 2015: 527-534 - [c21]Shibo Wang, Yanwei Song, Mahdi Nazm Bojnordi, Engin Ipek:
Enabling energy efficient Hybrid Memory Cube systems with erasure codes. ISLPED 2015: 67-72 - [c20]Yanwei Song, Engin Ipek:
More is less: improving the energy efficiency of data movement via opportunistic use of sparse codes. MICRO 2015: 242-254 - 2014
- [j8]Ravi Patel, Engin Ipek, Eby G. Friedman:
2T-1R STT-MRAM memory cells for enhanced on/off current ratio. Microelectron. J. 45(2): 133-143 (2014) - [c19]Ravi Patel, Engin Ipek, Eby G. Friedman:
Field driven STT-MRAM cell for reduced switching latency and energy. ISCAS 2014: 2173-2176 - 2013
- [j7]Mahdi Nazm Bojnordi, Engin Ipek:
Programmable DDRx Controllers. IEEE Micro 33(3): 106-115 (2013) - [j6]Mahdi Nazm Bojnordi, Engin Ipek:
A programmable memory controller for the DDRx interfacing standards. ACM Trans. Comput. Syst. 31(4): 11 (2013) - [c18]Qing Guo, Xiaochen Guo, Ravi Patel, Engin Ipek, Eby G. Friedman:
AC-DIMM: associative computing with STT-MRAM. ISCA 2013: 189-200 - [c17]Mahdi Nazm Bojnordi, Engin Ipek:
DESC: energy-efficient data exchange using synchronized counters. MICRO 2013: 234-246 - 2012
- [c16]Janani Mukundan, Saugata Ghose, Robert Karmazin, Engin Ipek, José F. Martínez:
Overcoming single-thread performance hurdles in the core fusion reconfigurable multicore architecture. ICS 2012: 101-110 - [c15]Mahdi Nazm Bojnordi, Engin Ipek:
PARDIS: A programmable memory controller for the DDRx interfacing standards. ISCA 2012: 13-24 - [c14]Ravi Patel, Engin Ipek, Eby G. Friedman:
STT-MRAM memory cells with enhanced on/off ratio. SoCC 2012: 148-152 - 2011
- [c13]Qing Guo, Xiaochen Guo, Yuxin Bai, Engin Ipek:
A resistive TCAM accelerator for data-intensive computing. MICRO 2011: 339-350 - 2010
- [j5]Benjamin C. Lee, Engin Ipek, Onur Mutlu, Doug Burger:
Phase change memory architecture and the quest for scalability. Commun. ACM 53(7): 99-106 (2010) - [j4]Benjamin C. Lee, Ping Zhou, Jun Yang, Youtao Zhang, Bo Zhao, Engin Ipek, Onur Mutlu, Doug Burger:
Phase-Change Technology and the Future of Main Memory. IEEE Micro 30(1): 143 (2010) - [c12]Engin Ipek, Jeremy Condit, Edmund B. Nightingale, Doug Burger, Thomas Moscibroda:
Dynamically replicated memory: building reliable systems from nanoscale resistive memories. ASPLOS 2010: 3-14 - [c11]Xiaochen Guo, Engin Ipek, Tolga Soyata:
Resistive computation: avoiding the power wall with low-leakage, STT-MRAM based computing. ISCA 2010: 371-382
2000 – 2009
- 2009
- [j3]José F. Martínez, Engin Ipek:
Dynamic Multicore Resource Management: A Machine Learning Approach. IEEE Micro 29(5): 8-17 (2009) - [c10]Benjamin C. Lee, Engin Ipek, Onur Mutlu, Doug Burger:
Architecting phase change memory as a scalable dram alternative. ISCA 2009: 2-13 - [c9]Jeremy Condit, Edmund B. Nightingale, Christopher Frost, Engin Ipek, Benjamin C. Lee, Doug Burger, Derrick Coetzee:
Better I/O through byte-addressable, persistent memory. SOSP 2009: 133-146 - 2008
- [j2]Engin Ipek, Sally A. McKee, Karan Singh, Rich Caruana, Bronis R. de Supinski, Martin Schulz:
Efficient architectural design space exploration via predictive modeling. ACM Trans. Archit. Code Optim. 4(4): 1:1-1:34 (2008) - [c8]Engin Ipek, Onur Mutlu, José F. Martínez, Rich Caruana:
Self-Optimizing Memory Controllers: A Reinforcement Learning Approach. ISCA 2008: 39-50 - [c7]Ramazan Bitirgen, Engin Ipek, José F. Martínez:
Coordinated management of multiple interacting resources in chip multiprocessors: A machine learning approach. MICRO 2008: 318-329 - 2007
- [j1]Karan Singh, Engin Ipek, Sally A. McKee, Bronis R. de Supinski, Martin Schulz, Rich Caruana:
Predicting parallel application performance via machine learning approaches. Concurr. Comput. Pract. Exp. 19(17): 2219-2235 (2007) - [c6]Christopher LaFrieda, Engin Ipek, José F. Martínez, Rajit Manohar:
Utilizing Dynamically Coupled Cores to Form a Resilient Chip Multiprocessor. DSN 2007: 317-326 - [c5]Engin Ipek, Meyrem Kirman, Nevin Kirman, José F. Martínez:
A Reconfigurable Chip Multiprocessor Architecture to Accommodate Software Diversity. IPDPS 2007: 1-6 - [c4]Engin Ipek, Meyrem Kirman, Nevin Kirman, José F. Martínez:
Core fusion: accommodating software diversity in chip multiprocessors. ISCA 2007: 186-197 - 2006
- [c3]Engin Ipek, Sally A. McKee, Rich Caruana, Bronis R. de Supinski, Martin Schulz:
Efficiently exploring architectural design spaces via predictive modeling. ASPLOS 2006: 195-206 - [c2]Engin Ipek, José F. Martínez, Bronis R. de Supinski, Sally A. McKee, Martin Schulz:
Dynamic program phase detection in distributed shared-memory multiprocessors. IPDPS 2006 - 2005
- [c1]Engin Ipek, Bronis R. de Supinski, Martin Schulz, Sally A. McKee:
An Approach to Performance Prediction for Parallel Applications. Euro-Par 2005: 196-205
Coauthor Index
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last updated on 2024-10-07 21:22 CEST by the dblp team
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