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Autonomous Biometrical System on FPGA: Enhancing ICT Efficiency and Reducing Emissions

The autonomous biometrical system built on FPGA addresses critical challenges in Information and Communication Technology (ICT) infrastructure, which consumes 3% of global energy and contributes to 2% of CO2 emissions. This system aims to enhance adaptability and reconfigurability, accommodating multiple radio standards crucial for medical implants, including Bluetooth and UWB. By optimizing energy usage, it not only seeks to reduce ICT's carbon footprint but also serves as a tool for mitigating emissions across various human activities like transport and telecommuting.

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Autonomous Biometrical System on FPGA: Enhancing ICT Efficiency and Reducing Emissions

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  1. Autonomous biometrical system on FPGA

  2. Context & Motivation (1) • 3% of the world-wide energy is consumed by the ICT infrastructure which causes about 2% of the world-wide CO2 emissions [1] • ICT carbon footprint is comparable to the world-wide CO2 emissions by airplanes or one quarter of the world-wide CO2 emissions by cars. • CO2 reduction at two levels: • To reduce the ICT emission itself • Use ICT to reduce emission of other human activities (transport, tele-working, e-commerce,…..) [1] http://www.cwc.oulu.fi/workshops/W-Green2008.pdf

  3. Context & Motivation (2)

  4. Influence from CR environments

  5. Challenge • Mutli-standards • Reconfigurability and adaptability

  6. Multiple Radio standards in a medical Implant • TG6 (task group 6, IEEE 802.15.6) • Bluetooth 1.0, 2.0, 3.0 • MICS (402-405 MHz) • UWB(3.1-10.6 GHz) • ISM 900 MHz, 2.5 GHz

  7. Reconfigurability

  8. Proposed autonomous system • required

  9. Proposed autonomous system • Decision algorithm

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