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ORCIDAhmet Can Mert
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- affiliation: Graz University of Technology, Austria
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2020 – today
- 2024
[j15]Anisha Mukherjee, Aikata, Ahmet Can Mert, Yongwoo Lee, Sunmin Kwon, Maxim Deryabin, Sujoy Sinha Roy:
ModHE: Modular Homomorphic Encryption Using Module Lattices Potentials and Limitations. IACR Trans. Cryptogr. Hardw. Embed. Syst. 2024(1): 527-562 (2024)- [j14]Florian Hirner
, Ahmet Can Mert, Sujoy Sinha Roy:
Proteus: A Pipelined NTT Architecture Generator. IEEE Trans. Very Large Scale Integr. Syst. 32(7): 1228-1238 (2024) - [c18]Florian Hirner, Michael Streibl, Florian Krieger, Ahmet Can Mert, Sujoy Sinha Roy:
Whipping the Multivariate-based MAYO Signature Scheme using Hardware Platforms. CCS 2024: 3421-3435 - [c17]Andrey Kim, Ahmet Can Mert, Anisha Mukherjee, Aikata, Maxim Deryabin, Sunmin Kwon, HyungChul Kang, Sujoy Sinha Roy:
Exploring the Advantages and Challenges of Fermat NTT in FHE Acceleration. CRYPTO (3) 2024: 76-106 - [c16]Florian Krieger, Florian Hirner, Ahmet Can Mert, Sujoy Sinha Roy:
Aloha-HE: A Low-Area Hardware Accelerator for Client-Side Operations in Homomorphic Encryption. DATE 2024: 1-6 - [i23]Andrey Kim, Ahmet Can Mert, Anisha Mukherjee, Aikata, Maxim Deryabin, Sunmin Kwon, HyungChul Kang, Sujoy Sinha Roy:
Exploring the Advantages and Challenges of Fermat NTT in FHE Acceleration. IACR Cryptol. ePrint Arch. 2024: 314 (2024) - [i22]Florian Krieger, Florian Hirner, Ahmet Can Mert, Sujoy Sinha Roy:
OpenNTT: An Automated Toolchain for Compiling High-Performance NTT Accelerators in FHE. IACR Cryptol. ePrint Arch. 2024: 1740 (2024) - 2023
- [j13]Aikata, Ahmet Can Mert, David Jacquemin, Amitabh Das, Donald Matthews, Santosh Ghosh, Sujoy Sinha Roy:
A Unified Cryptoprocessor for Lattice-Based Signature and Key-Exchange. IEEE Trans. Computers 72(6): 1568-1580 (2023) - [j12]Aikata, Ahmet Can Mert, Malik Imran, Samuel Pagliarini, Sujoy Sinha Roy:
KaLi: A Crystal for Post-Quantum Security Using Kyber and Dilithium. IEEE Trans. Circuits Syst. I Regul. Pap. 70(2): 747-758 (2023) - [j11]Ahmet Can Mert, Aikata, Sunmin Kwon, Youngsam Shin, Donghoon Yoo, Yongwoo Lee, Sujoy Sinha Roy:
Medha: Microcoded Hardware Accelerator for computing on Encrypted Data. IACR Trans. Cryptogr. Hardw. Embed. Syst. 2023(1): 463-500 (2023) - [j10]Aikata, Andrea Basso, Gaëtan Cassiers, Ahmet Can Mert, Sujoy Sinha Roy:
Kavach: Lightweight masking techniques for polynomial arithmetic in lattice-based cryptography. IACR Trans. Cryptogr. Hardw. Embed. Syst. 2023(3): 366-390 (2023) - [c15]Ahmet Can Mert, Ferhat Yaman, Emre Karabulut, Erdinç Öztürk, Erkay Savas, Aydin Aysu:
A Survey of Software Implementations for the Number Theoretic Transform. SAMOS 2023: 328-344 - [c14]Can Ayduman, Emre Koçer, Selim Kirbiyik, Ahmet Can Mert, Erkay Savas:
Efficient Design-Time Flexible Hardware Architecture for Accelerating Homomorphic Encryption. VLSI-SoC 2023: 1-7 - [i21]Aikata, Ahmet Can Mert, Sunmin Kwon, Maxim Deryabin, Sujoy Sinha Roy:
REED: Chiplet-Based Scalable Hardware Accelerator for Fully Homomorphic Encryption. CoRR abs/2308.02885 (2023) - [i20]Florian Hirner, Ahmet Can Mert, Sujoy Sinha Roy:
PROTEUS: A Tool to generate pipelined Number Theoretic Transform Architectures for FHE and ZKP applications. IACR Cryptol. ePrint Arch. 2023: 267 (2023) - [i19]Aikata, Andrea Basso, Gaëtan Cassiers, Ahmet Can Mert, Sujoy Sinha Roy:
Kavach: Lightweight masking techniques for polynomial arithmetic in lattice-based cryptography. IACR Cryptol. ePrint Arch. 2023: 517 (2023) - [i18]Anisha Mukherjee, Aikata, Ahmet Can Mert, Yongwoo Lee, Sunmin Kwon, Maxim Deryabin, Sujoy Sinha Roy:
ModHE: Modular Homomorphic Encryption Using Module Lattices: Potentials and Limitations. IACR Cryptol. ePrint Arch. 2023: 895 (2023) - [i17]Aikata, Ahmet Can Mert, Sunmin Kwon, Maxim Deryabin, Sujoy Sinha Roy:
REED: Chiplet-Based Scalable Hardware Accelerator for Fully Homomorphic Encryption. IACR Cryptol. ePrint Arch. 2023: 1190 (2023) - [i16]Florian Hirner, Michael Streibl, Ahmet Can Mert, Sujoy Sinha Roy:
A Hardware Implementation of MAYO Signature Scheme. IACR Cryptol. ePrint Arch. 2023: 1267 (2023) - [i15]David Jacquemin, Anisha Mukherjee, Ahmet Can Mert, Sujoy Sinha Roy:
Parallel Hardware for Isogeny-based VDF: Attacker's Perspective. IACR Cryptol. ePrint Arch. 2023: 1396 (2023) - [i14]Florian Krieger, Florian Hirner, Ahmet Can Mert, Sujoy Sinha Roy:
Aloha-HE: A Low-Area Hardware Accelerator for Client-Side Operations in Homomorphic Encryption. IACR Cryptol. ePrint Arch. 2023: 1736 (2023) - 2022
- [j9]Kemal Derya, Ahmet Can Mert, Erdinç Öztürk, Erkay Savas:
CoHA-NTT: A Configurable Hardware Accelerator for NTT-based Polynomial Multiplication. Microprocess. Microsystems 89: 104451 (2022) - [j8]Ahmet Can Mert, Erdinç Öztürk, Erkay Savas:
Low-Latency ASIC Algorithms of Modular Squaring of Large Integers for VDF Evaluation. IEEE Trans. Computers 71(1): 107-120 (2022) - [j7]Ahmet Can Mert, Emre Karabulut, Erdinç Öztürk, Erkay Savas, Aydin Aysu:
An Extensive Study of Flexible Design Methods for the Number Theoretic Transform. IEEE Trans. Computers 71(11): 2829-2843 (2022) - [j6]Özgün Özerk, Can Elgezen, Ahmet Can Mert, Erdinç Öztürk, Erkay Savas:
Efficient number theoretic transform implementation on GPU for homomorphic encryption. J. Supercomput. 78(2): 2840-2872 (2022) - [c13]Enes Recep Türkoglu, Ali Sah Özcan, Can Ayduman, Ahmet Can Mert, Erdinç Öztürk, Erkay Savas:
An Accelerated GPU Library for Homomorphic Encryption Operations of BFV Scheme. ISCAS 2022: 1155-1159 - [i13]Ahmet Can Mert, Aikata, Sunmin Kwon, Youngsam Shin, Donghoon Yoo, Yongwoo Lee, Sujoy Sinha Roy:
Medha: Microcoded Hardware Accelerator for computing on Encrypted Data. CoRR abs/2210.05476 (2022) - [i12]Aikata, Ahmet Can Mert, David Jacquemin, Amitabh Das, Donald Matthews, Santosh Ghosh, Sujoy Sinha Roy:
A Unified Cryptoprocessor for Lattice-based Signature and Key-exchange. CoRR abs/2210.07412 (2022) - [i11]Maria Eichlseder, Ahmet Can Mert, Christian Rechberger, Markus Schofnegger:
Small MACs from Small Permutations. IACR Cryptol. ePrint Arch. 2022: 49 (2022) - [i10]Ahmet Can Mert, Aikata, Sunmin Kwon, Youngsam Shin, Donghoon Yoo, Yongwoo Lee, Sujoy Sinha Roy:
Medha: Microcoded Hardware Accelerator for computing on Encrypted Data. IACR Cryptol. ePrint Arch. 2022: 480 (2022) - [i9]Aikata, Ahmet Can Mert, Malik Imran, Samuel Pagliarini, Sujoy Sinha Roy:
KaLi: A Crystal for Post-Quantum Security. IACR Cryptol. ePrint Arch. 2022: 1086 (2022) - [i8]David Jacquemin, Ahmet Can Mert, Sujoy Sinha Roy:
Exploring RNS for Isogeny-based Cryptography. IACR Cryptol. ePrint Arch. 2022: 1289 (2022) - 2021
- [c12]Ferhat Yaman, Ahmet Can Mert, Erdinç Öztürk, Erkay Savas:
A Hardware Accelerator for Polynomial Multiplication Operation of CRYSTALS-KYBER PQC Scheme. DATE 2021: 1020-1025 - [i7]Özgün Özerk, Can Elgezen, Ahmet Can Mert, Erdinç Öztürk, Erkay Savas:
Efficient Number Theoretic Transform Implementation on GPU for Homomorphic Encryption. IACR Cryptol. ePrint Arch. 2021: 124 (2021) - [i6]Ferhat Yaman, Ahmet Can Mert, Erdinç Öztürk, Erkay Savas:
A Hardware Accelerator for Polynomial Multiplication Operation of CRYSTALS-KYBER PQC Scheme. IACR Cryptol. ePrint Arch. 2021: 485 (2021) - [i5]Aikata, Ahmet Can Mert, David Jacquemin, Amitabh Das, Donald Matthews, Santosh Ghosh, Sujoy Sinha Roy:
A Unified Cryptoprocessor for Lattice-based Signature and Key-exchange. IACR Cryptol. ePrint Arch. 2021: 1461 (2021) - [i4]Kemal Derya, Ahmet Can Mert, Erdinç Öztürk, Erkay Savas:
CoHA-NTT: A Configurable Hardware Accelerator for NTT-based Polynomial Multiplication. IACR Cryptol. ePrint Arch. 2021: 1527 (2021) - [i3]Sujoy Sinha Roy, Ahmet Can Mert, Aikata, Sunmin Kwon, Youngsam Shin, Donghoon Yoo:
Accelerator for Computing on Encrypted Data. IACR Cryptol. ePrint Arch. 2021: 1555 (2021) - 2020
- [j5]Ahmet Can Mert, Erdinç Öztürk, Erkay Savas:
FPGA implementation of a run-time configurable NTT-based polynomial multiplication hardware. Microprocess. Microsystems 78: 103219 (2020) - [j4]Ahmet Can Mert, Erdinç Öztürk, Erkay Savas:
Design and Implementation of Encryption/Decryption Architectures for BFV Homomorphic Encryption Scheme. IEEE Trans. Very Large Scale Integr. Syst. 28(2): 353-362 (2020) - [c11]Ahmet Can Mert, Emre Karabulut, Erdinç Öztürk, Erkay Savas, Michela Becchi, Aydin Aysu:
A Flexible and Scalable NTT Hardware : Applications from Homomorphically Encrypted Deep Learning to Post-Quantum Cryptography. DATE 2020: 346-351 - [i2]Ahmet Can Mert, Erdinç Öztürk, Erkay Savas:
Low-Latency ASIC Algorithms of Modular Squaring of Large Integers for VDF Applications. IACR Cryptol. ePrint Arch. 2020: 480 (2020)
2010 – 2019
- 2019
- [c10]Ahmet Can Mert, Hasan Azgin, Ercan Kalali, Ilker Hamzaoglu:
Novel Approximate Absolute Difference Hardware. DSD 2019: 190-193 - [c9]Ahmet Can Mert, Erdinç Öztürk, Erkay Savas:
Design and Implementation of a Fast and Scalable NTT-Based Polynomial Multiplier Architecture. DSD 2019: 253-260 - [i1]Ahmet Can Mert, Erdinç Öztürk, Erkay Savas:
Design and Implementation of a Fast and Scalable NTT-Based Polynomial Multiplier Architecture. IACR Cryptol. ePrint Arch. 2019: 109 (2019) - 2018
- [c8]Ahmet Can Mert, Ercan Kalali, Ilker Hamzaoglu:
A Low Power Versatile Video Coding (VVC) Fractional Interpolation Hardware. DASIP 2018: 43-47 - [c7]Hasan Azgin, Ahmet Can Mert, Ercan Kalali, Ilker Hamzaoglu:
A Reconfigurable Fractional Interpolation Hardware for VVC Motion Compensation. DSD 2018: 99-103 - [c6]Ahmet Can Mert, Hasan Azgin, Ercan Kalali, Ilker Hamzaoglu:
Efficient Multiple Constant Multiplication Using DSP Blocks in FPGA. FPL 2018: 331-334 - [c5]Hasan Azgin, Ahmet Can Mert, Ercan Kalali, Ilker Hamzaoglu:
An efficient FPGA implementation of HEVC intra prediction. ICCE 2018: 1-5 - [c4]Ahmet Can Mert, Ercan Kalali, Ilker Hamzaoglu:
An HEVC fractional interpolation hardware using memory based constant multiplication. ICCE 2018: 1-5 - 2017
- [j3]Ahmet Can Mert, Ercan Kalali, Ilker Hamzaoglu:
High performance 2D transform hardware for future video coding. IEEE Trans. Consumer Electron. 63(2): 117-125 (2017) - [j2]Hasan Azgin, Ahmet Can Mert, Ercan Kalali, Ilker Hamzaoglu:
Reconfigurable intra prediction hardware for future video coding. IEEE Trans. Consumer Electron. 63(4): 419-425 (2017) - [c3]Ahmet Can Mert, Ercan Kalali, Ilker Hamzaoglu:
An FPGA implementation of future video coding 2D transform. ICCE-Berlin 2017: 31-36 - [c2]Ercan Kalali, Ahmet Can Mert, Ilker Hamzaoglu:
Pixel correlation based computation and energy reduction techniques for HEVC fractional interpolation. ICCE-Berlin 2017: 37-41 - 2016
- [j1]Ercan Kalali, Ahmet Can Mert, Ilker Hamzaoglu:
A computation and energy reduction technique for HEVC Discrete Cosine Transform. IEEE Trans. Consumer Electron. 62(2): 166-174 (2016) - [c1]Ahmet Can Mert, Ercan Kalali, Ilker Hamzaoglu:
Low complexity HEVC sub-pixel motion estimation technique and its hardware implementation. ICCE-Berlin 2016: 159-162
Coauthor Index
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last updated on 2025-01-20 22:49 CET by the dblp team
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