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IIT Bombay Memory Innovations in SemiconIndia 2022

  • Shri Rajeev Chandrasekhar, MoS, Electronics and IT, displaying the 8 inch wafer of OTP memory integrated with 180 nm CMOS technology. The IITB-SCL team has successfully proven production-ready eight-bit memory technology on a CMOS 180 nanometer technology platform. (From L-R: Dr. Sangeeta Semwal, Meity. Prof. Swaroop Ganguly, Professor, IITB. Shri Rajeev Chandrasekar, MoS, Shri Kumar Priyadarshi, IITB.)

MoS Rajeev Chandrashekar showcases 200 mm wafer with indigenous IITB-SCL secure memory technology

Innovation to Catalyze India's Semiconductor Ecosystem

IIT Bombay showcased indigenous technology development in the inaugural session of the 'SemiconIndia 2022' Conference that was conducted by the India Semiconductor Mission in collaboration with industries and industry organizations. Hon'ble Prime Minister Shri Narendra Modi inaugurated the event. The conference's theme this year was "Catalyzing India's Semiconductor Ecosystem."

Innovation is a critical component for ecosystem catalysis. Translation of technologies from R&D labs to manufacturing, powers the global ecosystem. India has developed academic R&D in semiconductors through the Centers of Excellence in Nanoelectronics (CENs), where IIT Bombay is a pioneering institution.

Naturally, Shri Rajeev Chandrasekhar, Minister of State, Electronics and IT, visited the IIT Bombay indigenous technology display. Prof. Swaroop Ganguly and Kumar Priyadarshi, Scientist IITB, informed him of the various innovation translations at IIT Bombay. This included indigenously developed agricultural sensors, RF solutions based on GaN and CMOS Technology based non-volatile memory solutions were showcased.

First Indigenous Memory Technology

A key deliverable of the semiconductor ecosystem building led by the Minister is to establish Silicon manufacturing and innovation ecosystem. Hence, the first indigenous memory developed on a 180 nm CMOS technology platform was of significant interest to the MoS. The MoS showcased the 8-inch wafer containing the pioneering one time programmable (OTP) memory translated from IITB Lab to SCL Fab for productization.

Shri Chandrasekhar discussed future possibilities and applications of this product with the team of Prof. Swaroop Ganguly (R&D Leader), Mr. Kumar Priyadarshi (Executive Research Scientist), and Dr. Sangeeta Semwal (R&D Funding at MeitY). Prof Swaroop Ganguly informed him of the wide range of applications from secure memory to hardware encryption. The applications enable products like secure microprocessors, smart cards for driver’s license, e-passport, secure SIM card etc. These are of critical interest to national security of public, strategic and private infrastructure for data communications/storage and authentication from smart cities to strategic asset management to home IoT systems.

One Time Programmable(OTP) Memory Basics

What is One Time Programmable(OTP) memory? Researchers at IIT Bombay led by Prof. Udayan Ganguly invented a "memory technology" that has the potential to revolutionize the indigenous semiconductor product landscape by providing a secure memory and hardware encryption. Unlike the ubiquitous Flash memories which are rewritable, some secure memories require that the information once written is never tampered with. The one-time programmable memory (OTP) is written once, stored for a lifetime, and read multiple times.

How does the technology work? The researchers utilized eight memory cells, each of which could store one "bit" of the corrected value (that is a value of zero or one). Each memory cell is made up of a layer of silicon dioxide that is only a few atomic layers thick. This is deposited uniformly over an 8-inch silicon wafer (the size of a dinner plate) to create millions of nanoscale capacitors. The pristine silicon dioxide layer is insulating, passing very little current [which is read as a "0" in digital electronics]. The capacitor is blown by nanoscale lightning caused by a low 3.3 volts, resulting in a short circuit and high current [this is a "1"]. Throughout its lifespan, the OTP memory recalls either the "0" or "1" state it was programmed to.

This is a pioneering indigenous technology by a multi-agency team. It is the first indigenous semiconductor memory technology to be manufactured at the 180-nanometer node - a national milestone for semiconductor technology development. The original technology was based on know-how at IIT Bombay contained in a PhD thesis. It was jointly transferred to manufacturing through a collaboration between teams of IIT Bombay and SCL Chandigarh. The memory development is supported by MeitY while the Hardware Encryption Technology is supported by DST. The translation of hardware encryption to products is funded and managed by O/o PSA with partnership with DRDO, SETS Chennai and IIT Delhi.

Large Security Market for OTP Memory

OTP Memory has Widespread Utility. There are various uses of the OTP memory.

1. Chip Calibration: Consider a thermometer chip that measures temperature. The chip may read 100 degrees Celsius as 101 degrees Celsius due to a tiny manufacturing error. By putting the error correction parameter in the OTP memory, this 1 degree "offset" can be fixed. This is done once for each chip, and the memory corrects the chip's output for the rest of its life.

2. Secure Memory for Smart Cards like e-passports & Driver’s Licenses etc: OTP memories store information with excellent fidelity. Information cannot be changed once it is written. This is used for ID cards for various applications e.g. e-passport, driver’s license etc.

3. Hardware Encryption for IoT Devices: The OTP memory delivers a unique fingerprint of a chip (known as Physical Unclonable Function). It is used for Trusted Platform Management and other IoT and Human ID security with applications in credit cards, SIMS cards etc.

The total market size for various applications is around 100M$ (750 Crores INR) per year. A startup Numelo Technologies has been incubated to accelerate commercialization.

The success of the Indian government's Atmanirbhar Bharat is subject to our country's ability to manufacture semiconductor devices through indigenous innovation. Translating R&D from lab to manufacturing is key for strategic and commercial products for self-reliance in semiconductors. The collaboration between IITB and SCL to develop this memory technology for the first time illustrates the country's increased potential in innovative semiconductor technology manufacturing.

Article written by:

Kumar Priyadarshi

Image/ Graphic Credit:

Ankit Bende & Shashi Kumar

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