Methodology for optimization of electrical parameters in the design of very large-scale integrated circuits

[1] Arafin, S., & Coldren, L. A. (2017). Advanced InP photonic integrated circuits for communication and sensing. IEEE Journal of Selected Topics in Quantum Electronics, 24(1), 1-12. Search in Google Scholar

[2] Li, J., Liu, X., Mao, W., Chen, T., & Yu, H. (2021). Advances in neural recording and stimulation integrated circuits. Frontiers in Neuroscience, 15, 663204. Search in Google Scholar

[3] Myny, K. (2018). The development of flexible integrated circuits based on thin-film transistors. Nature electronics, 1(1), 30-39. Search in Google Scholar

[4] Ferraz, O., Subramaniyan, S., Chinthala, R., Andrade, J., Cavallaro, J. R., Nandy, S. K., ... & Falcao, G. (2021). A survey on high-throughput non-binary LDPC decoders: ASIC, FPGA, and GPU architectures. IEEE Communications Surveys & Tutorials, 24(1), 524-556. Search in Google Scholar

[5] Disney, D., Letavic, T., Trajkovic, T., Terashima, T., & Nakagawa, A. (2017). High-voltage integrated circuits: History, state of the art, and future prospects. IEEE Transactions on Electron Devices, 64(3), 659-673. Search in Google Scholar

[6] Eslami, M., Ghavami, B., Raji, M., & Mahani, A. (2020). A survey on fault injection methods of digital integrated circuits. Integration, 71, 154-163. Search in Google Scholar

[7] Bogaerts, W., & Chrostowski, L. (2018). Silicon photonics circuit design: methods, tools and challenges. Laser & Photonics Reviews, 12(4), 1700237. Search in Google Scholar

[8] Siew, S. Y., Li, B., Gao, F., Zheng, H. Y., Zhang, W., Guo, P., ... & Lo, G. Q. (2021). Review of silicon photonics technology and platform development. Journal of Lightwave Technology, 39(13), 4374-4389. Search in Google Scholar

[9] Amirsoleimani, A., Alibart, F., Yon, V., Xu, J., Pazhouhandeh, M. R., Ecoffey, S., ... & Drouin, D. (2020). In-Memory Vector-Matrix Multiplication in Monolithic Complementary Metal–Oxide–Semiconductor-Memristor Integrated Circuits: Design Choices, Challenges, and Perspectives. Advanced Intelligent Systems, 2(11), 2000115. Search in Google Scholar

[10] Zhang, Q., Zhang, Y., Luo, Y., & Yin, H. (2024). New structure transistors for advanced technology node CMOS ICs. National Science Review, 11(3), nwae008. Search in Google Scholar

[11] Matsui, H., Takeda, Y., & Tokito, S. (2019). Flexible and printed organic transistors: From materials to integrated circuits. Organic Electronics, 75, 105432. Search in Google Scholar

[12] Gupta, S., Navaraj, W. T., Lorenzelli, L., & Dahiya, R. (2018). Ultra-thin chips for high-performance flexible electronics. npj Flexible Electronics, 2(1), 8. Search in Google Scholar

[13] Afacan, E., Lourenço, N., Martins, R., & Dündar, G. (2021). Machine learning techniques in analog/RF integrated circuit design, synthesis, layout, and test. Integration, 77, 113-130. Search in Google Scholar

[14] Zhu, K., Wen, C., Aljarb, A. A., Xue, F., Xu, X., Tung, V., ... & Lanza, M. (2021). The development of integrated circuits based on two-dimensional materials. Nature Electronics, 4(11), 775-785. Search in Google Scholar

[15] Nardi, A., Camdzic, S., Armato, A., & Lertora, F. (2019, April). Design-for-safety for automotive IC design: Challenges and opportunities. In 2019 IEEE Custom Integrated Circuits Conference (CICC) (pp. 1-8). IEEE. Search in Google Scholar

[16] Mina, R., Jabbour, C., & Sakr, G. E. (2022). A review of machine learning techniques in analog integrated circuit design automation. Electronics, 11(3), 435. Search in Google Scholar

[17] Yan, Y., Zhao, Y., & Liu, Y. (2022). Recent progress in organic field‐effect transistor‐based integrated circuits. Journal of Polymer Science, 60(3), 311-327. Search in Google Scholar

[18] Shen, Y., Dong, Z., Sun, Y., Guo, H., Wu, F., Li, X., ... & Ren, T. L. (2022). The trend of 2D transistors toward integrated circuits: scaling down and new mechanisms. Advanced Materials, 34(48), 2201916. Search in Google Scholar

[19] Li, E. P., Ma, H., Ahmed, M., Tao, T., Gu, Z., Chen, M., ... & Chen, W. (2023). An electromagnetic perspective of artificial intelligence neuromorphic chips. Electromagnetic Science, 1(3), 1-18. Search in Google Scholar

[20] Rogozhin A. E. & Glaz O. G..(2024).Materials for Interconnections of Integrated Circuits with Design Standards Less Than 5 nm.Russian Microelectronics(1),91-103. Jie Yang,Shiqi Zhao,Junzhe Wang,Siyu Lin,Qiming Hou & Mohamad Sawan.(2024).Precise and low-power closed-loop neuromodulation through algorithm-integrated circuit co-design.Frontiers in Neuroscience1340164-1340164. Search in Google Scholar

[21] Fath Patrick,Moser Manuel,Zachl Georg & Pretl Harald.(2024).Open-source design of integrated circuits.e+i Elektrotechnik und Informationstechnik(1),76-87. Search in Google Scholar

[22] Rashid Ria,Raghunath Gopavaram,Badugu Vasant & Nambath Nandakumar.(2023).Performance evaluation of evolutionary algorithms for analog integrated circuit design optimisation.Microelectronics Journal. Search in Google Scholar

Language:: English

Publication timeframe:: 1 times per year
Journal Subjects:: Life Sciences, Life Sciences, other, Mathematics, Applied Mathematics, General Mathematics, Physics, Physics, other

Journal RSS Feed

Methodology for optimization of electrical parameters in the design of very large-scale integrated circuits

Guang Yue

Lin Ren

Xianwei Wu

Published Online: Oct 04, 2024

Received: Apr 23, 2024

Accepted: Aug 16, 2024

DOI: https://doi.org/10.2478/amns-2024-2651

KeywordsElectrical parameters, Reinforcement learning, Integrated circuits, Parametric optimization

© 2024 Guang Yue et al., published by Sciendo

This work is licensed under the Creative Commons Attribution 4.0 International License.

Keywords
Electrical parameters, Reinforcement learning, Integrated circuits, Parametric optimization