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2020 – today
- 2024
[j6]Athira Sunil, Masud Rana SK, Maximilian Lederer, Yannick Raffel, Franz Müller, Ricardo Olivo, Raik Hoffmann, Konrad Seidel, Thomas Kämpfe, Bhaswar Chakrabarti, Sourav De
:
Ferroelectric Field Effect Transistors-Based Content-Addressable Storage-Class Memory: A Study on the Impact of Device Variation and High-Temperature Compatibility. Adv. Intell. Syst. 6(4) (2024)- [j5]Taixin Li, Boran Sun, Hongtao Zhong, Yixin Xu, Vijaykrishnan Narayanan, Liang Shi, Tianyi Wang, Yao Yu, Thomas Kämpfe, Kai Ni, Huazhong Yang, Xueqing Li:
ProtFe: Low-Cost Secure Power Side-Channel Protection for General and Custom FeFET-Based Memories. ACM Trans. Design Autom. Electr. Syst. 29(1): 3:1-3:18 (2024) - [c55]Alptekin Vardar, Franz Müller, Ipek Geçin, Nellie Laleni, Thomas Kämpfe:
Adaptive Mixed MLC-SLC FeFET Mapping for CIM AI Applications Through Simulated Annealing. AICAS 2024: 258-262 - [c54]V. Lasserre, S. Koop-Brinkmann, M. Caruso, D. Dal Maistro, G. Volpato, Q. H. Le, Thomas Kämpfe, C. Ziegler, Finn Stapelfeldt, Vadim Issakov:
A 5.6 dB NF Two-Stage 110 - 125 GHz LNA Gain-Boosted by RC-over-Neutralization for Radar Applications in 28 nm CMOS. BCICTS 2024: 146-149 - [c53]Yu Qian, Kai Ni, Thomas Kämpfe, Cheng Zhuo, Xunzhao Yin:
C-Nash: A Novel Ferroelectric Computing-in-Memory Architecture for Solving Mixed Strategy Nash Equilibrium. DAC 2024: 226:1-226:6 - [c52]Yu Qian, Zeyu Yang, Kai Ni, Alptekin Vardar, Thomas Kämpfe, Xunzhao Yin:
HyCiM: A Hybrid Computing-in-Memory QUBO Solver for General Combinatorial Optimization Problems with Inequality Constraints. DAC 2024: 241:1-241:6 - [c51]Chao Li, Zhicheng Xu, Bo Wen, Ruibin Mao, Can Li, Thomas Kämpfe, Kai Ni, Xunzhao Yin:
FeBiM: Efficient and Compact Bayesian Inference Engine Empowered with Ferroelectric In-Memory Computing. DAC 2024: 246:1-246:6 - [c50]Zeyu Yang, Qingrong Huang, Yu Qian, Kai Ni, Thomas Kämpfe, Xunzhao Yin:
Energy Efficient Dual Designs of FeFET-Based Analog In-Memory Computing with Inherent Shift-Add Capability. DAC 2024: 290:1-290:6 - [c49]Qingrong Huang, Hamza Errahmouni Barkam, Zeyu Yang, Jianyi Yang, Thomas Kämpfe, Kai Ni, Grace Li Zhang, Bing Li, Ulf Schlichtmann, Mohsen Imani, Cheng Zhuo, Xunzhao Yin:
A FeFET-based Time-Domain Associative Memory for Multi-bit Similarity Computation. DATE 2024: 1-6 - [c48]Taixin Li, Hongtao Zhong, Juejian Wu, Thomas Kämpfe, Kai Ni, Vijaykrishnan Narayanan, Huazhong Yang, Xueqing Li:
CafeHD: A Charge-Domain FeFET-Based Compute-in-Memory Hyperdimensional Encoder with Hypervector Merging. DATE 2024: 1-6 - [c47]Zhicheng Xu, Che-Kai Liu, Chao Li, Ruibin Mao, Jianyi Yang, Thomas Kämpfe, Mohsen Imani, Can Li, Cheng Zhuo, Xunzhao Yin:
FeReX: A Reconfigurable Design of Multi-Bit Ferroelectric Compute-in-Memory for Nearest Neighbor Search. DATE 2024: 1-6 - [c46]Haotian Xu, Jianyi Yang, Cheng Zhuo, Thomas Kämpfe, Kai Ni, Xunzhao Yin:
Reconfigurable Frequency Multipliers Based on Complementary Ferroelectric Transistors. DATE 2024: 1-6 - [c45]Sukhrob Abdulazhanov, Q. H. Le, David Lehninger, Ayse Sünbül, Thomas Kämpfe, G. Gerlach:
Improved Tunability of BEoL-integrated Hafnium Zirconium Oxide Varactors for mmWave Applications. DRC 2024: 1-2 - [c44]Maximilian Lederer, Franz Müller, Raik Hoffmann, Ricardo Olivo, Yannick Raffel, Shouzhuo Yang, Sourav De, Roman Potjan, Oliver Ostien, Abdelrahman Altawil, Ayse Sünbül, David Lehninger, Thomas Kämpfe, Konrad Seidel:
Enhanced reliability and trapping behavior in ferroelectric FETs under cryogenic conditions. IMW 2024: 1-4 - [c43]Ayse Sünbül, David Lehninger, Raik Hoffmann, Hannes Mähne, Kerstin Bernert, Steffen Thiem, Thomas Kämpfe, Konrad Siedel, Maximilian Lederer, Lukas M. Eng:
Improved Endurance Reliability of Ferroelectric Hafnium Oxide-Based BEoL Integrated MFM Capacitors. IRPS 2024: 1-5 - [c42]Nellie Laleni, Sahana Padma, Thomas Kämpfe, Taekwang Jang:
Single Slope ADC with Reset Counting for FeFET-based In-Memory Computing. ISCAS 2024: 1-5 - [c41]Nellie Laleni, Thomas Kämpfe:
An Efficient FeFET-Based Compute-In-Memory Macro Readout Inspired by the 3T Pixel Array Cell. SMACD 2024: 1-4 - [i14]Zhicheng Xu, Che-Kai Liu, Chao Li, Ruibin Mao, Jianyi Yang, Thomas Kämpfe, Mohsen Imani, Can Li, Cheng Zhuo, Xunzhao Yin:
FeReX: A Reconfigurable Design of Multi-bit Ferroelectric Compute-in-Memory for Nearest Neighbor Search. CoRR abs/2401.05708 (2024) - [i13]Yu Qian, Kai Ni, Thomas Kämpfe, Cheng Zhuo, Xunzhao Yin:
C-Nash: A Novel Ferroelectric Computing-in-Memory Architecture for Solving Mixed Strategy Nash Equilibrium. CoRR abs/2408.04169 (2024) - [i12]Yu Qian, Zeyu Yang, Kai Ni, Alptekin Vardar, Thomas Kämpfe, Xunzhao Yin:
HyCiM: A Hybrid Computing-in-Memory QUBO Solver for General Combinatorial Optimization Problems with Inequality Constraints. CoRR abs/2410.14111 (2024) - [i11]Xunzhao Yin, Hamza Errahmouni Barkam, Franz Müller, Yu Jiang, Mohsen Imani, Sukhrob Abdulazhanov, Alptekin Vardar, Nellie Laleni, Zijian Zhao, Jiahui Duan, Zhiguo Shi, Siddharth Joshi, Michael T. Niemier, Xiaobo Sharon Hu, Cheng Zhuo, Thomas Kämpfe, Kai Ni:
A Remedy to Compute-in-Memory with Dynamic Random Access Memory: 1FeFET-1C Technology for Neuro-Symbolic AI. CoRR abs/2410.15296 (2024) - [i10]Chao Li, Zhicheng Xu, Bo Wen, Ruibin Mao, Chien-Mo James Li, Thomas Kämpfe, Kai Ni, Xunzhao Yin:
FeBiM: Efficient and Compact Bayesian Inference Engine Empowered with Ferroelectric In-Memory Computing. CoRR abs/2410.19356 (2024) - [i9]Zeyu Yang, Qingrong Huang, Yu Qian, Kai Ni, Thomas Kämpfe, Xunzhao Yin:
Energy Efficient Dual Designs of FeFET-Based Analog In-Memory Computing with Inherent Shift-Add Capability. CoRR abs/2410.19593 (2024) - 2023
- [j4]Vivek Parmar, Franz Müller, Jing-Hua Hsuen, Sandeep Kaur Kingra, Nellie Laleni, Yannick Raffel, Maximilian Lederer, Alptekin Vardar, Konrad Seidel, Taha Soliman, Tobias Kirchner, Tarek Ali, Stefan Dünkel, Sven Beyer, Tian-Li Wu, Sourav De, Manan Suri, Thomas Kämpfe:
Demonstration of Differential Mode Ferroelectric Field-Effect Transistor Array-Based in-Memory Computing Macro for Realizing Multiprecision Mixed-Signal Artificial Intelligence Accelerator. Adv. Intell. Syst. 5(6) (2023) - [j3]Xunzhao Yin, Franz Müller, Qingrong Huang, Chao Li, Mohsen Imani, Zeyu Yang, Jiahao Cai, Maximilian Lederer, Ricardo Olivo, Nellie Laleni, Shan Deng, Zijian Zhao, Zhiguo Shi, Yiyu Shi, Cheng Zhuo, Thomas Kämpfe, Kai Ni:
An Ultracompact Single-Ferroelectric Field-Effect Transistor Binary and Multibit Associative Search Engine. Adv. Intell. Syst. 5(7) (2023) - [c40]Sukhrob Abdulazhanov, Quang Huy Le, Dang Khoa Huynh, David Lehninger, Thomas Kämpfe, Gerald Gerlach:
Permittivity Characterization of Ferroelectric Thin-Film Hafnium Zirconium Oxide Varactors up to 170 GHz. DRC 2023: 1-2 - [c39]Sukhrob Abdulazhanov, Quang Huy Le, Dang Khoa Huynh, Maximilian Lederer, Yannick Raffel, Kai Ni, Xunzhao Yin, Thomas Kämpfe, Gerald Gerlach:
Reconfigurable ferroelectric hafnium oxide FeFET fabricated in 28 nm CMOS technology for mmWave applications. ESSDERC 2023: 113-116 - [c38]Dirk Schöttke, Aaron Zielstorff, Thomas Kämpfe, Vasil Denkov, Stephan Schäfer:
Leveraging the Asset Administration Shell: A Ticket-Based Test Environment for Industry 4.0 Components. ETFA 2023: 1-8 - [c37]Aaron Zielstorff, Dirk Schöttke, Antonius Hohenhövel, Thomas Kämpfe, Stephan Schäfer, Frank Schnicke:
Overcoming Challenges in Integrating Legacy Devices with Asset Administration Shells - An OPC UA Case Study. ETFA 2023: 1-8 - [c36]Nellie Laleni, Taha Soliman, Cecilia De la Parra, Franz Müller, Tobias Kirchner, Andre Guntoro, Thomas Kämpfe, Norbert Wehn, T. Jang:
Torwards Variability Immune Scalable FeFET-based Macros for IMC DNN Accelerators. ICECS 2023: 1-4 - [c35]Alptekin Vardar, Aamir Munir, Nellie Laleni, Sourav De, Thomas Kämpfe:
Hardware Aware Spiking Neural Network Training and Its Mixed-Signal Implementation for Non-Volatile In-Memory Computing Accelerators. ICECS 2023: 1-4 - [c34]David Lehninger, Ayse Sünbül, Ricardo Olivo, Thomas Kämpfe, Konrad Seidel, Maximilian Lederer:
Ferroelectric HfO2/ZrO2 Superlattices with Improved Leakage at Bias and Temperature Stress. IMW 2023: 1-4 - [c33]Franz Müller, Sourav De, Maximilian Lederer, Raik Hoffmann, Ricardo Olivo, Thomas Kämpfe, Konrad Seidel, Tarek Ali, Halid Mulaosmanovic, Stefan Dünkel, Johannes Müller, Sven Beyer, Gerald Gerlach:
Multi-Level Operation of Ferroelectric FET Memory Arrays for Compute-In-Memory Applications. IMW 2023: 1-4 - [c32]Konrad Seidel, David Lehninger, Franz Müller, Yannick Raffel, Ayse Sünbül, Ricardo Revello, Raik Hoffmann, Sourav De, Thomas Kämpfe, Maximilian Lederer:
Hafnium oxide-based Ferroelectric Memories: Are we ready for Application? IMW 2023: 1-4 - [c31]Aaron Zielstorff, Dirk Schöttke, Antonius Hohenhövel, Thomas Kämpfe, Stephan Schäfer, Frank Schnicke:
Harmonizing Heterogeneity: A Novel Architecture for Legacy System Integration with Digital Twins in Industry 4.0. IN4PL 2023: 68-87 - [c30]Dirk Schöttke, Aaron Zielstorff, Thomas Kämpfe, Vasil Denkov, Fiona Büttner, Stephan Schäfer, Bernd Tauber:
Approach of a Ticket-Based Test Strategy for Industry 4.0 Components with Asset Administration Shells. IN4PL 2023: 88-106 - [c29]Stephan Schäfer, Dirk Schöttke, Thomas Kämpfe, Vasil Denkov, Aaron Zielstorff:
Component Test - Test Strategies with Asset Administration Shells. ISIE 2023: 1-7 - [c28]Alptekin Vardar, Li Zhang, Saiyam Bherulal Jain, Shaown Mojumder, Nellie Laleni, Sourav De, Thomas Kämpfe:
The True Cost of Errors in Emerging Memory Devices: A Worst-Case Analysis of Device Errors in IMC for Safety-Critical Applications. SMACD 2023: 1-4 - [i8]Yixin Xu, Yi Xiao, Zijian Zhao, Franz Müller, Alptekin Vardar, Xiao Gong, Sumitha George, Thomas Kämpfe, Vijaykrishnan Narayanan, Kai Ni:
Embedding Security into Ferroelectric FET Array via In-Situ Memory Operation. CoRR abs/2306.01863 (2023) - [i7]Xunzhao Yin, Yu Qian, Alptekin Vardar, Marcel Gunther, Franz Müller, Nellie Laleni, Zijian Zhao, Zhouhang Jiang, Zhiguo Shi, Yiyu Shi, Xiao Gong, Cheng Zhuo, Thomas Kämpfe, Kai Ni:
A Ferroelectric Compute-in-Memory Annealer for Combinatorial Optimization Problems. CoRR abs/2309.13853 (2023) - [i6]Haotian Xu, Jianyi Yang, Cheng Zhuo, Thomas Kämpfe, Kai Ni, Xunzhao Yin:
Reconfigurable Frequency Multipliers Based on Complementary Ferroelectric Transistors. CoRR abs/2312.17444 (2023) - 2022
- [j2]Arman Kazemi, Mohammad Mehdi Sharifi, Ann Franchesca Laguna, Franz Müller, Xunzhao Yin, Thomas Kämpfe, Michael T. Niemier, X. Sharon Hu:
FeFET Multi-Bit Content-Addressable Memories for In-Memory Nearest Neighbor Search. IEEE Trans. Computers 71(10): 2565-2576 (2022) - [j1]Taha Soliman, Nellie Laleni, Tobias Kirchner, Franz Müller, Ashish Shrivastava, Thomas Kämpfe, Andre Guntoro, Norbert Wehn:
FELIX: A Ferroelectric FET Based Low Power Mixed-Signal In-Memory Architecture for DNN Acceleration. ACM Trans. Embed. Comput. Syst. 21(6): 84:1-84:25 (2022) - [c27]Sukhrob Abdulazhanov, Dang Khoa Huynh, Quang Huy Le, David Lehninger, Thomas Kämpfe, Gerald Gerlach:
BEoL integrated hafnium zirconium oxide varactors for tunable mmWave applications. ESSDERC 2022: 253-256 - [c26]Stephan Schäfer, Dirk Schöttke, Thomas Kämpfe, Oliver Lachmann, Aaron Zielstorff, Bernd Tauber:
Migration and synchronization of plant segments with Asset Administration Shells. ETFA 2022: 1-8 - [c25]Yannick Raffel, Sunanda Thunder, Maximilian Lederer, Ricardo Olivo, Raik Hoffmann, Luca Pirro, Sven Beyer, Talha Chohan, Po-Tsang Huang, Sourav De, Thomas Kämpfe, Konrad Seidel, Johannes Heitmann:
Interfacial Layer Engineering to Enhance Noise Immunity of FeFETs for IMC Applications. ICICDT 2022: 8-11 - [c24]Stephan Schäfer, Dirk Schöttke, Thomas Kämpfe, Oliver Lachmann, Aaron Zielstorff, Bernd Tauber:
Integration of PLC for synchronization of plant segments with Asset Administration Shells. IECON 2022: 1-6 - [c23]Tarek Ali, Ricardo Olivo, S. Kerdilès, David Lehninger, Maximilian Lederer, Sourav De, A.-S. Royet, Ayse Sünbül, A. Prabhu, Kati Kühnel, Malte Czernohorsky, M. Rudolph, Raik Hoffmann, Christelle Charpin-Nicolle, Laurent Grenouillet, Thomas Kämpfe, Konrad Seidel:
Study of Nanosecond Laser Annealing on Silicon Doped Hafnium Oxide Film Crystallization and Capacitor Reliability. IMW 2022: 1-4 - [c22]David Lehninger, Hannes Mähne, Tarek Ali, Raik Hoffmann, Ricardo Olivo, Maximilian Lederer, Konstantin Mertens, Thomas Kämpfe, Kati Biedermann, Matthias Landwehr, Andreas Heinig, Defu Wang, Yukai Shen, Kerstin Bernert, Steffen Thiem, Konrad Seidel:
Integration of BEoL Compatible 1T1C FeFET Memory Into an Established CMOS Technology. IMW 2022: 1-4 - [c21]Yannick Raffel, Ricardo Olivo, Maximilian Lederer, Franz Müller, Raik Hoffmann, Tarek Ali, Konstantin Mertens, Luca Pirro, Maximilian Drescher, Sven Beyer, Thomas Kämpfe, Konrad Seidel, Lukas M. Eng, Johannes Heitmann:
Endurance improvements and defect characterization in ferroelectric FETs through interface fluorination. IMW 2022: 1-4 - [c20]Stephan Schäfer, Dirk Schöttke, Thomas Kämpfe, Oliver Lachmann, Aaron Zielstorff, Bernd Tauber:
Industrial Controls and Asset Administration Shells: An Approach to the Synchronization of Plant Segments. IN4PL 2022: 75-84 - [c19]Ayse Sünbül, Tarek Ali, Raik Hoffmann, Ricardo Revello, Yannick Raffel, Pardeep Duhan, David Lehninger, Kati Kühnel, Matthias Rudolph, Sebastian Oehler, Philipp Schramm, Malte Czernohorsky, Konrad Seidel, Thomas Kämpfe, Lukas M. Eng:
Impact of Temperature on Reliability of MFIS HZO-based Ferroelectric Tunnel Junctions. IRPS 2022: 11-1 - [c18]Sourav De, Maximilian Lederer, Yannick Raffel, Franz Müller, Konrad Seidel, Thomas Kämpfe:
Roadmap for Ferroelectric Memory: Challenges and Opportunities for IMC Applications. ISOCC 2022: 167-168 - [c17]Chirag Sudarshan, Taha Soliman, Thomas Kämpfe, Christian Weis, Norbert Wehn:
FeFET versus DRAM based PIM Architectures: A Comparative Study. VLSI-SoC 2022: 1-6 - [c16]Konrad Seidel, David Lehninger, Raik Hoffmann, Tarek Ali, Maximilian Lederer, Ricardo Revello, Konstantin Mertens, Kati Biedermann, Yukai Shen, Defu Wang, Matthias Landwehr, Andreas Heinig, Thomas Kämpfe, Hannes Mähne, Kerstin Bernert, Steffen Thiem:
Memory Array Demonstration of fully integrated 1T-1C FeFET concept with separated ferroelectric MFM device in interconnect layer. VLSI Technology and Circuits 2022: 355-356 - [i5]Xunzhao Yin, Franz Müller, Qingrong Huang, Chao Li, Mohsen Imani, Zeyu Yang, Jiahao Cai, Maximilian Lederer, Ricardo Olivo, Nellie Laleni, Shan Deng, Zijian Zhao, Cheng Zhuo, Thomas Kämpfe, Kai Ni:
An Ultra-Compact Single FeFET Binary and Multi-Bit Associative Search Engine. CoRR abs/2203.07948 (2022) - [i4]Xinrui Guo, Xiaoyang Ma, Franz Müller, Kai Ni, Thomas Kämpfe, Yongpan Liu, Vijaykrishnan Narayanan, Xueqing Li:
Ferroelectric FET-based strong physical unclonable function: a low-power, high-reliable and reconfigurable solution for Internet-of-Things security. CoRR abs/2208.14678 (2022) - [i3]Xunzhao Yin, Qingrong Huang, Franz Müller, Shan Deng, Alptekin Vardar, Sourav De, Zhouhang Jiang, Mohsen Imani, Cheng Zhuo, Thomas Kämpfe, Kai Ni:
A Homogeneous Processing Fabric for Matrix-Vector Multiplication and Associative Search Using Ferroelectric Time-Domain Compute-in-Memory. CoRR abs/2209.11971 (2022) - 2021
- [c15]Arman Kazemi, Mohammad Mehdi Sharifi, Ann Franchesca Laguna, Franz Müller, Ramin Rajaei, Ricardo Olivo, Thomas Kämpfe, Michael T. Niemier, X. Sharon Hu:
In-Memory Nearest Neighbor Search with FeFET Multi-Bit Content-Addressable Memories. DATE 2021: 1084-1089 - [c14]Xinrui Guo, Xiaoyang Ma, Franz Müller, Ricardo Olivo, Juejian Wu, Kai Ni, Thomas Kämpfe, Yongpan Liu, Huazhong Yang, Xueqing Li:
Exploiting FeFET Switching Stochasticity for Low-Power Reconfigurable Physical Unclonable Function. ESSCIRC 2021: 119-122 - [c13]Xinrui Guo, Xiaoyang Ma, Franz Müller, Ricardo Olivo, Juejian Wu, Kai Ni, Thomas Kämpfe, Yongpan Liu, Huazhong Yang, Xueqing Li:
Exploiting FeFET Switching Stochasticity for Low-Power Reconfigurable Physical Unclonable Function. ESSDERC 2021: 119-122 - [c12]Stephan Schäfer, Dirk Schöttke, Thomas Kämpfe, Oliver Lachmann, Aaron Zielstorff:
Synchronizing Devices Using Asset Administration Shells. IN4PL (Revised Selected Papers) 2021: 70-92 - [c11]Stephan Schäfer, Dirk Schöttke, Thomas Kämpfe, Kiril Ralinovski, Bernd Tauber, Ralf Lehmann:
Design and Deployment of Digital Twins for Programmable Logic Controllers in Existing Plants. IN4PL 2021: 145-150 - [c10]Patrick Aichroth, Christoph Antes, Pierre Gembatzka, Holger Graf, David S. Johnson, Matthias Jung, Thomas Kämpfe, Thomas Kleinberger, Thomas Köllmer, Thomas Kuhn, Christoph Kutter, Jens Krüger, Dominik Marek Loroch, Hanna M. Lukashevich, Nellie Laleni, Lei Zhang, Johannes Leugering, Rodrigo Martín Fernández, Loreto Mateu, Shaown Mojumder, Benjamin Prautsch, Ferdinand Pscheidl, Karsten Roscher, Sören Schneickert, Frank Vanselow, Paul Wallbott, Oliver Walter, Nico Weber:
SEC-Learn: Sensor Edge Cloud for Federated Learning - Invited Paper. SAMOS 2021: 432-448 - [i2]Xunzhao Yin, Franz Müller, Ann Franchesca Laguna, Chao Li, Wenwen Ye, Qingrong Huang, Qinming Zhang, Zhiguo Shi, Maximilian Lederer, Nellie Laleni, Shan Deng, Zijian Zhao, Michael T. Niemier, Xiaobo Sharon Hu, Cheng Zhuo, Thomas Kämpfe, Kai Ni:
Deep Random Forest with Ferroelectric Analog Content Addressable Memory. CoRR abs/2110.02495 (2021) - 2020
- [c9]Taha Soliman, Ricardo Olivo, Tobias Kirchner, Cecilia De la Parra, Maximilian Lederer, Thomas Kämpfe, Andre Guntoro, Norbert Wehn:
Efficient FeFET Crossbar Accelerator for Binary Neural Networks. ASAP 2020: 109-112 - [c8]Tarek Ali, Kati Kühnel, Malte Czernohorsky, Matthias Rudolph, Björn Pätzold, Ricardo Olivo, David Lehninger, Konstantin Mertens, Franz Müller, Maximilian Lederer, Raik Hoffmann, Clemens Mart, Mahsa N. Kalkani, Philipp Steinke, Thomas Kämpfe, Johannes Müller, Jan Van Houdt, Konrad Seidel, Lukas M. Eng:
Impact of Ferroelectric Wakeup on Reliability of Laminate based Si-doped Hafnium Oxide (HSO) FeFET Memory Cells. IRPS 2020: 1-9 - [c7]Taha Soliman, Ricardo Olivo, Tobias Kirchner, Maximilian Lederer, Thomas Kämpfe, Andre Guntoro, Norbert Wehn:
A Ferroelectric FET Based In-memory Architecture for Multi-Precision Neural Networks. SoCC 2020: 96-101 - [i1]Arman Kazemi, Mohammad Mehdi Sharifi, Ann Franchesca Laguna, Franz Müller, Ramin Rajaei, Ricardo Olivo, Thomas Kämpfe, Michael T. Niemier, Xiaobo Sharon Hu:
In-Memory Nearest Neighbor Search with FeFET Multi-Bit Content-Addressable Memories. CoRR abs/2011.07095 (2020)
2010 – 2019
- 2019
- [c6]Quang Huy Le, Dang Khoa Huynh, Defu Wang, Thomas Kämpfe, Zhixing Zhao, Steffen Lehmann:
Assessment of a Thick-Oxide Transistor from the 22FDX® Platform for 5G NR sub-6 GHz FEMs. 5G World Forum 2019: 7-10 - [c5]Quang Huy Le, Dang Khoa Huynh, Defu Wang, Thomas Kämpfe, Steffen Lehmann:
DC-110 GHz Characterization of 22FDX® FDSOI Transistors for 5G Transmitter Front-End. ESSDERC 2019: 218-221 - 2017
- [c4]Milan Pesic, Michael Hoffmann, Claudia Richter, Stefan Slesazeck, Thomas Kämpfe, Lukas M. Eng, Thomas Mikolajick, Uwe Schroeder:
Anti-ferroelectric ZrO2, an enabler for low power non-volatile 1T-1C and 1T random access memories. ESSDERC 2017: 160-163 - 2016
- [c3]Stephan Schäfer, Dirk Schöttke, Thomas Kämpfe, Dietrich Kronke, Ulrich Berger, Bernd Tauber:
Increasing the flexibility of manufacturing: A service-oriented approach in automation. ETFA 2016: 1-4 - 2015
- [c2]Stephan Schäfer, Dirk Schöttke, Thomas Kämpfe, Dominik Matura, Ulrich Berger:
Collaborating robots in a museum environment: Modular systems for 3D documentation. ETFA 2015: 1-5 - 2013
- [c1]Stephan Schäfer, Dirk Schöttke, Thomas Kämpfe, Ulrich Berger:
Technical conditions for the use of autonomous systems: A general approach on an example. ETFA 2013: 1-9
Coauthor Index
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