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Huapeng Wu
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2020 – today
- 2024
- [j49]Xi Zhang, Ye Yang, Xin Zhang, Youmin Hu
, Huapeng Wu, Ming Li, Heikki Handroos, Haifeng Wang, Bo Wu:
A multi-level digital twin construction method of assembly line based on hybrid worker digital twin models. Adv. Eng. Informatics 62: 102597 (2024) - [j48]Huapeng Wu
A hybrid U-shaped and transformer network for change detection in high-resolution remote sensing images. IET Image Process. 18(5): 1373-1384 (2024) - [j47]Huapeng Wu, Hui Xu, Tianming Zhan:
A novel spatial and spectral transformer network for hyperspectral image super-resolution. Multim. Syst. 30(3): 165 (2024) - [j46]Huapeng Wu, Chenyun Wang, Chenyang Lu, Tianming Zhan:
HCT: a hybrid CNN and transformer network for hyperspectral image super-resolution. Multim. Syst. 30(4): 185 (2024) - [e2]Benjamin Smith, Huapeng Wu:
Selected Areas in Cryptography - 29th International Conference, SAC 2022, Windsor, ON, Canada, August 24-26, 2022, Revised Selected Papers. Lecture Notes in Computer Science 13742, Springer 2024, ISBN 978-3-031-58410-7 [contents] - 2023
- [j45]Qi Wang
Parameter Identification of Heavy-Duty Manipulator Using Stochastic Gradient Hamilton Monte Carlo Method. IEEE Access 11: 78561-78583 (2023) - [j44]Guodong Qin, Qi Wang, Changyang Li, Aihong Ji, Huapeng Wu
Design and development of a cable-driven elephant trunk robot with variable cross-sections. Ind. Robot 50(3): 520-529 (2023) - [j43]Dongyi Li
Synchronization control of blanket remote maintenance robot based on MPC-CCC algorithm. Robotica 41(11): 3380-3408 (2023) - [j42]Huapeng Wu
Feedback Pyramid Attention Networks for Single Image Super-Resolution. IEEE Trans. Circuits Syst. Video Technol. 33(9): 4881-4892 (2023) - 2022
- [j41]Amin Hekmatmanesh
A Combined Projection for Remote Control of a Vehicle Based on Movement Imagination: A Single Trial Brain Computer Interface Study. IEEE Access 10: 6165-6174 (2022) - [j40]Amin Hekmatmanesh
Imaginary Control of a Mobile Vehicle Using Deep Learning Algorithm: A Brain Computer Interface Study. IEEE Access 10: 20043-20052 (2022) - [j39]Stanislav Ustinov
A Hybrid Model for Fast and Efficient Simulation of Fluid Power Circuits With Small Volumes Utilizing a Recurrent Neural Network. IEEE Access 10: 48824-48835 (2022) - [j38]Qi Wang
Friction-Identification of Harmonic Drive Joints Based on the MCMC Method. IEEE Access 10: 125893-125907 (2022) - [j37]Huapeng Wu
Pyramidal dense attention networks for single image super-resolution. IET Image Process. 16(12): 3247-3257 (2022) - [j36]Chen Zhang, Huapeng Wu, Chunhong Chen
Area-Efficient Finite Field Multiplication Using Hybrid SET-MOS Technology. IEEE Trans. Circuits Syst. I Regul. Pap. 69(11): 4358-4366 (2022) - [j35]Huapeng Wu
An Efficient Cross-Modality Self-Calibrated Network for Hyperspectral and Multispectral Image Fusion. IEEE Trans. Geosci. Remote. Sens. 60: 1-12 (2022) - [j34]Tianming Zhan
A Novel Cross-Scale Octave Network for Hyperspectral and Multispectral Image Fusion. IEEE Trans. Geosci. Remote. Sens. 60: 1-16 (2022) - [j33]Ruochen Yin
FusionLane: Multi-Sensor Fusion for Lane Marking Semantic Segmentation Using Deep Neural Networks. IEEE Trans. Intell. Transp. Syst. 23(2): 1543-1553 (2022) - [i5]Ruochen Yin, Huapeng Wu, Ming Li, Yong Cheng, Yuntao Song, Heikki Handroos:
Mastering Autonomous Assembly in Fusion Application with Learning-by-doing: a Peg-in-hole Study. CoRR abs/2208.11737 (2022) - 2021
- [j32]Yashar Shabbouei Hagh
Active Fault-Tolerant Control Design for Actuator Fault Mitigation in Robotic Manipulators. IEEE Access 9: 47912-47929 (2021) - [j31]Changyang Li
Design and Multi-Objective Optimization of a Dexterous Mobile Parallel Mechanism for Fusion Reactor Vacuum Vessel Assembly. IEEE Access 9: 153796-153810 (2021) - [j30]Tao Zhang
A novel method to identify DH parameters of the rigid serial-link robot based on a geometry model. Ind. Robot 48(1): 157-167 (2021) - [j29]Changyang Li
Mobile parallel robot machine for heavy-duty double-walled vacuum vessel assembly. Ind. Robot 48(4): 523-531 (2021) - [j28]Huapeng Wu
Multi-Grained Attention Networks for Single Image Super-Resolution. IEEE Trans. Circuits Syst. Video Technol. 31(2): 512-522 (2021) - [c37]Chen Zhang, Chunhong Chen, Huapeng Wu:
Area-Efficient Finite Field Multiplication in $\text{GF} (2^{n})$ Using Single-Electron Transistors. APCCAS 2021: 25-28 - [c36]Huapeng Wu, Xi Gao:
Efficient Multiplier and FPGA Implementation for NTRU Prime. CCECE 2021: 1-5 - [i4]Huapeng Wu, Jie Gui, Jun Zhang, James T. Kwok, Zhihui Wei:
Feedback Pyramid Attention Networks for Single Image Super-Resolution. CoRR abs/2106.06966 (2021) - [i3]Huapeng Wu, Jie Gui, Jun Zhang, James T. Kwok, Zhihui Wei:
Pyramidal Dense Attention Networks for Lightweight Image Super-Resolution. CoRR abs/2106.06996 (2021) - 2020
- [j27]Reza Mohammadi Asl
Fuzzy-Based Parameter Optimization of Adaptive Unscented Kalman Filter: Methodology and Experimental Validation. IEEE Access 8: 54887-54904 (2020) - [j26]Amin Hekmatmanesh
A combination of CSP-based method with soft margin SVM classifier and generalized RBF kernel for imagery-based brain computer interface applications. Multim. Tools Appl. 79(25-26): 17521-17549 (2020) - [c35]Mehar Ullah, Amin Hekmatmanesh, Dimitri Savchenko, Renan Cipriano Moioli
Providing Facilities in Health Care via Brain-Computer Interface and Internet of Things. MIPRO 2020: 971-976 - [i2]Ruochen Yin, Biao Yu, Huapeng Wu, Yuntao Song, Runxin Niu:
FusionLane: Multi-Sensor Fusion for Lane Marking Semantic Segmentation Using Deep Neural Networks. CoRR abs/2003.04404 (2020)
2010 – 2019
- 2019
- [j25]Amin Hekmatmanesh
EEG Control of a Bionic Hand With Imagination Based on Chaotic Approximation of Largest Lyapunov Exponent: A Single Trial BCI Application Study. IEEE Access 7: 105041-105053 (2019) - [j24]Tao Zhang
Deformation modeling of remote handling EAMA robot by recurrent neural networks. Ind. Robot 46(2): 300-310 (2019) - [j23]Amin Hekmatmanesh
Combination of discrete wavelet packet transform with detrended fluctuation analysis using customized mother wavelet with the aim of an imagery-motor control interface for an exoskeleton. Multim. Tools Appl. 78(21): 30503-30522 (2019) - [c34]Amin Hekmatmanesh, Reza Mohammadi Asl
Optimizing Largest Lyapunov Exponent Utilizing an Intelligent Water Drop algorithm: A Brain Computer Interface Study. EBCCSP 2019: 1-5 - [i1]Huapeng Wu, Zhengxia Zou, Jie Gui, Wen-Jun Zeng, Jieping Ye, Jun Zhang, Hongyi Liu, Zhihui Wei:
Multi-grained Attention Networks for Single Image Super-Resolution. CoRR abs/1909.11937 (2019) - 2018
- [j22]Huapeng Wu, Jun Zhang
High Resolution Similarity Directed Adjusted Anchored Neighborhood Regression for Single Image Super-Resolution. IEEE Access 6: 25240-25247 (2018) - [c33]Bingyam Mao, Zhijiang Xie, Yongbo Wang, Huapeng Wu
A Self-adaptive Artificial Bee Colony Algorithm with Guard Stage for Global Optimization. CEC 2018: 1-8 - [c32]Shanshuang Shi, Yong Cheng, Hongtao Pan, Wenlong Zhao, Huapeng Wu
Development and Error Compensation of a Flexible Multi-Joint Manipulator Applied in Nuclear Fusion Environment. IROS 2018: 3587-3592 - 2017
- [j21]Shanshuang Shi, Huapeng Wu
Mechanical design and error prediction of a flexible manipulator system applied in nuclear fusion environment. Ind. Robot 44(6): 711-719 (2017) - [j20]Shoaleh Hashemi Namin
Low-Power Design for a Digit-Serial Polynomial Basis Finite Field Multiplier Using Factoring Technique. IEEE Trans. Very Large Scale Integr. Syst. 25(2): 441-449 (2017) - [c31]Jing Wu
Soft computing methods compensation for EAST articulated maintenance arm position disturbance. IEEE SENSORS 2017: 1-3 - 2016
- [j19]Manfen Han, Huapeng Wu
Intelligent method for tuning H2 PID controller of water hydraulic manipulator of CFETR blanket maintenances. Ind. Robot 43(2): 164-171 (2016) - [c30]Bingxin Liu, Huapeng Wu:
Efficient multiplication architecture over truncated polynomial ring for NTRUEncrypt system. ISCAS 2016: 1174-1177 - 2015
- [c29]Huapeng Wu:
Efficient radix conversions for classes of radices. ISCAS 2015: 2185-2188 - [c28]Bingxin Liu, Huapeng Wu:
Efficient architecture and implementation for NTRUEncrypt system. MWSCAS 2015: 1-4 - 2014
- [c27]Walid M. Mahmoud, Bingxin Liu, Raqib A. Asif, Huapeng Wu:
LFSR based low complexity montgomery multiplier in GF(2m) for a class of fields. CCECE 2014: 1-4 - [c26]Wangchen Dai
Time-efficient computation of digit serial Montgomery multiplication. ISIC 2014: 212-215 - 2013
- [c25]Huapeng Wu:
Low complexity LFSR based bit-serial montgomery multiplier in GF(2m). ISCAS 2013: 1962-1965 - [c24]Saif Rahman, Yiruo He, Huapeng Wu:
Public-Key Based Efficient Key Distribution in Bluetooth. ITNG 2013: 727-728 - [e1]Lars R. Knudsen
Selected Areas in Cryptography, 19th International Conference, SAC 2012, Windsor, ON, Canada, August 15-16, 2012, Revised Selected Papers. Lecture Notes in Computer Science 7707, Springer 2013, ISBN 978-3-642-35998-9 [contents] - 2012
- [j18]Ashkan Hosseinzadeh Namin, Huapeng Wu, Majid Ahmadi:
High-Speed Architectures for Multiplication Using Reordered Normal Basis. IEEE Trans. Computers 61(2): 164-172 (2012) - [j17]Ashkan Hosseinzadeh Namin, Huapeng Wu, Majid Ahmadi:
An Efficient Finite Field Multiplier Using Redundant Representation. ACM Trans. Embed. Comput. Syst. 11(2): 31:1-31:14 (2012) - [c23]Suhas Sreehari, Huapeng Wu, Majid Ahmadi:
Fast modular reduction for large-integer multiplication for cryptosystem application. DICTAP 2012: 226-229 - [c22]Shoaleh Hashemi Namin, Huapeng Wu, Majid Ahmadi:
Power efficiency of digit level polynomial basis finite field multipliers in GF(2283). ICECS 2012: 897-900 - [c21]Ashley Novak, Farinoush Saffar, Mitra Mirhassani, Huapeng Wu:
Current mode multiple-valued adder for cryptography processors. ISCAS 2012: 1460-1463 - 2011
- [j16]Ashkan Hosseinzadeh Namin, Huapeng Wu, Majid Ahmadi:
A Word-Level Finite Field Multiplier Using Normal Basis. IEEE Trans. Computers 60(6): 890-895 (2011) - [c20]Yiruo He, Huapeng Wu:
Efficient architectures for modular exponentiation using Montgomery powering ladder. CCECE 2011: 1202-1205 - 2010
- [j15]Ashkan Hosseinzadeh Namin, Karl Leboeuf, Roberto Muscedere, Huapeng Wu, Majid Ahmadi:
High-speed hardware implementation of a serial-in parallel-out finite field multiplier using reordered normal basis. IET Circuits Devices Syst. 4(2): 168-179 (2010)
2000 – 2009
- 2009
- [j14]Ashkan Hosseinzadeh Namin, Huapeng Wu, Majid Ahmadi:
A High-Speed Word Level Finite Field Multiplier in BBF2m Using Redundant Representation. IEEE Trans. Very Large Scale Integr. Syst. 17(10): 1546-1550 (2009) - [c19]Ashkan Hosseinzadeh Namin, Karl Leboeuf, Roberto Muscedere, Huapeng Wu, Majid Ahmadi:
High speed VLSI implementation of a finite field multiplier using redundant representation. ECCTD 2009: 161-164 - [c18]Majid Ahmadi, Ashkan Hosseinzadeh Namin, Karl Leboeuf, Huapeng Wu:
Artificial neural networks activation function HDL coder. EIT 2009: 389-392 - [c17]Yongbo Wang, Huapeng Wu, Heikki Handroos:
Parameter Identification of a Hybrid Redundant Robot by using Differential Evolution Algorithm. ICINCO-RA 2009: 287-292 - [c16]Ashkan Hosseinzadeh Namin, Karl Leboeuf, Roberto Muscedere, Huapeng Wu, Majid Ahmadi:
Efficient Hardware Implementation of the Hyperbolic Tangent Sigmoid Function. ISCAS 2009: 2117-2120 - 2008
- [j13]Huapeng Wu
Mobile parallel robot for assembly and repair of ITER vacuum vessel. Ind. Robot 35(2): 160-168 (2008) - [j12]Ashkan Hosseinzadeh Namin, Huapeng Wu, Majid Ahmadi:
A New Finite-Field Multiplier Using Redundant Representation. IEEE Trans. Computers 57(5): 716-720 (2008) - [j11]Huapeng Wu:
Bit-Parallel Polynomial Basis Multiplier for New Classes of Finite Fields. IEEE Trans. Computers 57(8): 1023-1031 (2008) - [c15]Ashkan Hosseinzadeh Namin, Huapeng Wu, Majid Ahmadi:
A high speed word level finite field multiplier using reordered normal basis. ISCAS 2008: 3278-3281 - [c14]Huapeng Wu
A Hybrid Parallel Robot. RAM 2008: 640-644 - [c13]Yongbo Wang, Huapeng Wu
On the Error Modeling of a Novel Mobile Hybrid Parallel Robot. RAM 2008: 1217-1222 - [c12]Shushan Zhao, Akshai K. Aggarwal, Shuping Liu, Huapeng Wu:
A Secure Routing Protocol in Proactive Security Approach for Mobile Ad-Hoc Networks. WCNC 2008: 2627-2632 - 2007
- [j10]Bijan Ansari, Huapeng Wu:
Efficient finite field processor for GF(2163) and its implementation. Int. J. High Perform. Syst. Archit. 1(2): 106-112 (2007) - [j9]Ashkan Hosseinzadeh Namin, Huapeng Wu, Majid Ahmadi:
Comb Architectures for Finite Field Multiplication in F(2^m). IEEE Trans. Computers 56(7): 909-916 (2007) - [c11]Bijan Ansari, Huapeng Wu:
Efficient Finite Field Processor for GF(2^163) and its VLSI Implementation. ITNG 2007: 1021-1026 - 2006
- [c10]Payman Samadi, Huapeng Wu, Majid Ahmadi:
The 2-D Quantized DCT with Distributed Arithmetic. CCECE 2006: 2049-2052 - [c9]Ashkan Hosseinzadeh Namin, Huapeng Wu, Majid Ahmadi:
A Parallel-In Serial-Out Multiplier Using Redundant Representation for A Class of Finite Fields. ICECS 2006: 502-505 - [c8]Huapeng Wu
A Mobile Hybrid Parallel Robot with Redundant Kinematic Structure. ROBIO 2006: 1157-1162 - 2002
- [j8]Huapeng Wu:
Montgomery Multiplier and Squarer for a Class of Finite Fields. IEEE Trans. Computers 51(5): 521-529 (2002) - [j7]Huapeng Wu:
Bit-Parallel Finite Field Multiplier and Squarer Using Polynomial Basis. IEEE Trans. Computers 51(7): 750-758 (2002) - [j6]Huapeng Wu, M. Anwarul Hasan, Ian F. Blake, Shuhong Gao:
Finite Field Multiplier Using Redundant Representation. IEEE Trans. Computers 51(11): 1306-1316 (2002) - 2001
- [j5]Huapeng Wu, M. Anwar Hasan:
Efficient exponentiation using weakly dual basis. IEEE Trans. Very Large Scale Integr. Syst. 9(6): 874-879 (2001) - [c7]Guang Gong, Lein Harn, Huapeng Wu:
The GH Public-Key Cryptosystem. Selected Areas in Cryptography 2001: 284-300 - 2000
- [c6]Haixia Zhang, Huapeng Wu, Lv Jungang, Chen Darong:
Collaborative Design System for Performance. AIWoRC 2000: 59-64 - [c5]Huapeng Wu:
Montgomery Multiplier and Squarer in GF(2m). CHES 2000: 264-276 - [c4]Huapeng Wu, Heikki Handroos:
Utilization of differential evolution in inverse kinematics solution of a parallel redundant manipulator. KES 2000: 812-815 - [c3]Huapeng Wu:
On Complexity of Polynomial Basis Squaring in F2m. Selected Areas in Cryptography 2000: 118-129
1990 – 1999
- 1999
- [j4]Huapeng Wu, M. Anwarul Hasan:
Closed-Form Expression for the Average Weight of Signed-Digit Representations. IEEE Trans. Computers 48(8): 848-851 (1999) - [c2]Huapeng Wu, M. Anwarul Hasan, Ian F. Blake:
Highly Regular Architectures for Finite Field Computation Using Redundant Basis. CHES 1999: 269-279 - [c1]Huapeng Wu:
Low Complexity Bit-Parallel Finite Field Arithmetic Using Polynomial Basis. CHES 1999: 280-291 - 1998
- [j3]Huapeng Wu, M. Anwarul Hasan:
Low Complexity Bit-Parallel Multipliers for a Class of Finite Fields. IEEE Trans. Computers 47(8): 883-887 (1998) - [j2]Huapeng Wu, M. Anwarul Hasan, Ian F. Blake:
New Low-Complexity Bit-Parallel Finite Field Multipliers Using Weakly Dual Bases. IEEE Trans. Computers 47(11): 1223-1234 (1998) - 1997
- [j1]Huapeng Wu, M. Anwarul Hasan:
Efficient Exponentiation of a Primitive Root in GF(2^m). IEEE Trans. Computers 46(2): 162-172 (1997)
Coauthor Index
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last updated on 2024-09-07 02:01 CEST by the dblp team
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