[paper] ChipNeMo

Mingjie Liu, Teo Ene, Robert Kirby, Chris Cheng, Nathaniel Pinckney, Rongjian LiangJonah Alben, Himyanshu Anand, Sanmitra Banerjee, Ismet Bayraktaroglu, Bonita Bhaskaran Bryan Catanzaro, Arjun Chaudhuri, Sharon Clay, Bill Dally, Laura Dang, Parikshit Deshpande Siddhanth Dhodhi, Sameer Halepete, Eric Hill, Jiashang Hu, Sumit Jain, Brucek Khailany Kishor Kunal, Xiaowei Li, Hao Liu, Stuart Oberman, Sujeet Omar, Sreedhar Pratty, Ambar Sarkar Zhengjiang Shao, Hanfei Sun, Pratik P Suthar, Varun Tej, Kaizhe Xu, Haoxing Ren

ChipNeMo: Domain-Adapted LLMs for Chip Design

arXiv:2311.00176 [cs.CL]

DOI: 10.48550/arXiv.2311.00176

* NVIDIA

Abstract: ChipNeMo aims to explore the applications of large language models (LLMs) for industrial chip design. Instead of directly deploying off-the-shelf commercial or open-source LLMs, we instead adopt the following domain adaptation techniques: custom tokenizers, domain-adaptive continued pretraining, supervised fine-tuning (SFT) with domain-specific instructions, and domain-adapted retrieval models. We evaluate these methods on three selected LLM applications for chip design: an engineering assistant chatbot, EDA script generation, and bug summarization and analysis. Our results show that these domain adaptation techniques enable significant LLM performance improvements over general-purpose base models across the three evaluated applications, enabling up to 5x model size reduction with similar or better performance on a range of design tasks. Our findings also indicate that there’s still room for improvement between our current results and ideal outcomes. We believe that further investigation of domain-adapted LLM approaches will help close this gap in the future.

Fig: LLM script generator integration with EDA tools

Acknowledgements: The authors would like to thank: NVIDIA IT teams for their support on NVBugs integration; NVIDIA Hardware Security team for their support on security issues; NVIDIA NeMo teams for their support and guidance on training and inference of ChipNeMo models; NVIDIA Infrastructure teams for supporting the GPU training and inference resources for the project; NVIDIA Hardware design teams for their support and insight.

MINIMAL

"Minimal Fab Promotion Organization" (MINIMAL) aim is to establish a completely new production method called this minimal fab and initiating a process revolution in Japan. The mission is to further expand the application fields of Minimal Fab as the only organization in the world to support the spread and development of high-mix low-volume of microdevices such as semiconductors and MEMS as innovative industrial systems. We are aiming to become an innovation platform to promote small businesses using the Minimal Fab through collaboration among various industries such as various toolmakers, materials, parts and device users [ read more...]

INUP-i2i - Idea to Innovation

INUP-i2i

Indian Nanoelectronics Users’ Programme

Idea to Innovation

Ministry of Electronics and Information Technology – MeitY, with the long-term vision of improving skilled manpower in the areas of micro and nanoelectronics had established the Indian Nanoelectronics Users’ Programme (INUP) about a decade back. The initiative enabled the researchers to travel from the country's remotest locations and implement their ideas at the state-of-art nanofabrication and characterization facilities available at Centres of Excellence established at the Indian Institute of Science Bangalore and Indian Institute of Technology Bombay. Over the years, the brand INUP has caught the imaginations of the scholars from numerous technical colleges and universities who could not afford to have such facilities to perform research. The user base grew from the first (2008-2014) to the second 2014-2019) phases of implementation. Thousands of researchers have received hands-on training at various levels in such state-of-art facilities in the multi-disciplinary areas of micro/nanoelectronics. Hundreds of them could implement their research ideas and produce scientific and technological outputs. The initiative resulted in unprecedented benefits to the budding scholars in developing cutting-edge research prototypes, which was found to be way beyond the traditional soft-teaching pathways through textbook knowledge. The initiative also helped the participants write and submit research proposals, budget the same, implement ideas at the ground level, schedule project work, submit project reports, prepare scientific manuscripts, and develop the devices.

INUP-i2i OBJECTIVES

• Enhance R&D ecosystem in the area of nanoelectronics by leveraging the Nano centres established by MeitY.
• Conduct training/workshops in the field of Nanoelectronics for wider dissemination of knowledge.
• Support the exploratory and innovative research for development of technologies in Nanoelectronics
• Mentor startups for commercialization of nanotechnologies.
• Conduct Hackathons/Grand Challenge targeting societal applications to develop Nano engineered solutions.

Hands-on training workshop are organized on the following different themes:

• Sensors and Microfluidics
• Organic Electronics
• 2D materials and devices
• Logic & Memory Devices
• Spintronics
• Compound Semiconductor Devices
• Photovoltaics
• MEMS

[read more...]

[paper] Cryogenic Devices for Quantum Technologies

Jorge Pérez-Bailón, Miguel Tarancón, Santiago Celma, and Carlos Sánchez-Azqueta

Cryogenic Measurement of CMOS Devices for Quantum Technologies

IEEE Transactions on Instrumentation and Measurement (2023)

Quantum Materials and Devices (Q-MAD) Group

Institute of Nanoscience and Materials of Aragón (INMA),

Group of Electronic Design (GDE), University of Zaragoza (SP)

Abstract: In this article we present the experimental characterization of active components of a standard 65nm CMOS technology for a temperature range from 313 to 5K, analyzing the variation of the main parameters over temperature and voltage, recovering their main parameters (threshold voltage Vth, transconductance Gm and channel conductance GDS). The measurement has been carried out wire-bonding the bare dies with the devices to a dedicated printed circuit board (PCB) that has been placed inside a dilution refrigerator. The ID-VDS curves for both NMOS and PMOS transistors shows an increase of ID in the cryogenic regime that is more relevant for high values of VGS because for lower values it is partially compensated by the variation of Vth. Also, a kink is observed in these curves for high VDS values, caused by the bulk current generated by impact ionization at the drain combined with the increased resistivity of the frozen-out substrate. The transconductance Gm reaches non-zero values for higher VGS as T decreases, and then peaks to higher values in the cryogenic regime. In turn, GDS increases for increasing T, following the behavior observed for ID. Both results are in accordance with other thermal characterizations carried out on CMOS transistors in different technologies.

Fig: Detail of the IC in the measurement setup to fit into the cryostat

Aknowlegemetns: This work was supported in part by the Spanish Ministry of Science and Innovation under Grant PID2020-114110RA-I00; and in part by the CSIC Program for the Spanish Recovery, Transformation and Resilience Plan funded by the Recovery and Resilience Facility of the European Union, established by the Regulation (EU) 2020/2094 under Grant 20219PT007

IWPSD 2023

XXII International Workshop on Physics of Semiconductor Devices

Research Park, IIT Madras, Chennai - 600036

Dec. 13-17, 2023

organised by

Indian Institute of Technology Madras

@ Research Park, IIT Madras

in association with

Society for Semiconductor Devices (SSD)

Semiconductor Society (India)

The XXII International Workshop on the Physics of Semiconductor Devices (IWPSD 2023) is being jointly organized by the Indian Institute of Technology Madras in collaboration with Society for Semiconductor Devices and Semiconductor Society (India). This series of biennial workshops, started in 1981, provides a global forum for interaction between scientists and technologists working in the area of semiconductor materials and devices.

The topics to be covered in the Workshop are, but not limited to:

• 2D Materials and Devices
• Crystal Growth and Epitaxy
• Device Modelling and Simulation
• Devices for Quantum Technology
• II - VI and Oxide Semiconductors
• III - V Semiconductors
• Memory and Logic Devices
• MEMS, NEMS and Sensors
• Organic and Flexible Electronics
• Photovoltaics
• Power Semiconductor Devices
• Optoelectronics

IWPSD 2023 Registration is open. Registration fees includes admission to all conference sessions, daily lunch and tea breaks, conference kit and dinner/banquet.

Contact: <admin.iwpsd2023@ee.iitm.ac.in>