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Article Released Thu-21st-February-2019 01:02 GMT
Contact: Ngaroma Riley Institution: Tohoku University
 Development of nonvolatile spintronics-based 50μW microcontroller unit operating at 200MHz

Researchers at Tohoku University have announced the development of a nonvolatile microcontroller unit (MCU) which achieves both high performance and ultra-low power by utilizing spintronics-based VLSI design technology.

Development of nonvolatile spintronics-based 50μW microcontroller unit operating at 200MHz
Photo of the fabricated microcontroller unit chip.
Copyright : IEEE
Researchers at Tohoku University have announced the development of a nonvolatile microcontroller unit (MCU) which achieves both high performance and ultra-low power by utilizing spintronics-based VLSI design technology.

The demand for low-power, high-performance microcontroller units (MCUs) has been increasing for power-supply-critical Internet-of-Things (IoT) sensor node applications. In sensor node applications, a distributed network of sensors extracts and gathers information, which is processed by MCUs and transmitted to a cloud-based data center. Various low-power MCUs for sensor node applications have been actively researched and developed, however, the required operation speed and signal processing throughput combined with low power consumption has not been achieved until now.

The research team led by Professors Tetsuo Endoh, Takahiro Hanyu and Associate Professor Masanori Natsui has developed an MCU using spintronics-based VLSI technology. In the newly developed spintronics-based MCU, all modules are made non-volatile using spintronics devices, and wasteful power consumption is entirely eliminated by controlling the power supply for each module independently.

In addition, the data transfer bottleneck of logic and memory is relaxed by a memory controller that can speed up the entire system and a reconfigurable accelerator module is incorporated for executing application specific signal processing. These modifications enable the MCU to achieve ultra-low power consumption of 47.14μW at a high-speed operating frequency of 200MHz, which was confirmed from the measurement results of the fabricated chip.

This MCU chip provides both the world's highest processing performance and energy efficiency for highly functional IoT sensor nodes powered by harvested energy, which is derived from external sources such as solar power, thermal energy.

The research is part of the "Achieving Ultimate Green IT Devices with Long Usage Time without Charging" project managed by Masashi Sahashi and supported by the Impulsing Paradigm Change through Disruptive Technologies Program (ImPACT), run by Japan's Council for Science, Technology and Innovation.

Results will be presented at 2019 IEEE International Solid-State Circuits Conference held in San Francisco, USA from February 17~21, 2019.

Contact:
Tetsuo Endoh
Director of Center for Innovative Integrated Electronic Systems
Tohoku University
Email: support-officecies.tohoku.ac.jp
Website: http://www.cies.tohoku.ac.jp/english/
Development of nonvolatile spintronics-based 50μW microcontroller unit operating at 200MHz
Performance comparison of the fabricated MCU and reported work.
Copyright : Tohoku University
Development of nonvolatile spintronics-based 50μW microcontroller unit operating at 200MHz
Ultra low power consumption performance of developed spintronics-based nonvolatile MCU.
Copyright : Tohoku University

Associated links

Journal information

Title: An FPGA-Accelerated Fully Nonvolatile Microcontroller Unit for Sensor-Node Applications in 40nm CMOS/MTJ-Hybrid Technology Achieving 47.14μW Operation at 200MHz
Authors: Masanori Natsui, Daisuke Suzuki, Akira Tamakoshi, Toshinari Watanabe, Hiroaki Honjo, Hiroki Koike, Takashi Nasuno, Yitao Ma, Takaho Tanigawa, Yasuo Noguchi, Mitsuo Yasuhira, Hideo Sato, Shoji Ikeda, Hideo Ohno, Tetsuo Endoh, and Takahiro Hanyu
Journal: 2019 IEEE International Solid-State Circuits Conference (ISSCC2019)

Meeting information

2019 IEEE International Solid-State Circuits Conference

Funding information

Impulsing Paradigm Change through Disruptive Technologies Program (ImPACT)

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