1. Budapest University of Technology and Economics Department of Electron Devices eet.bme.hu Research and Development at the Ferenc Ender ender@eet.bme.hu www.eet.bme.hu

2. © BME Department of Electron Devices, 2012. eet.bme.hu February 6, 2013 2 Budapest University of Technology and Economics

3. © BME Department of Electron Devices, 2012. eet.bme.hu February 6, 2013 3 Budapest University of Technology and Economics Department of Electron Devices ► The only university department in Hungary dealing with all aspects of (monolithic) microelectronics. These include  devices physics and technology,  analog and digital integrated circuit design  MEMS simulation and design  LEDs and solar cells  Complex hardware and system design  thermal issues in IC & packaging design  Space technology  Photovoltaic devices  Chip sized biomedical devices ► The department is one of the main organizators of THERMINIC and DTIP conferences

4. © BME Department of Electron Devices, 2012. eet.bme.hu February 6, 2013 4 Research activities – tematic summary ► Advanced measurement techniques ► Thermal transient testing and structure function analysis of device packages ► Meterial characterization and in-situ monitoring of aging of thermal interface materials ► Combined thermal and radiometric/photometric measurement of power LEDs ► Novel simulation algorithms and models ► Algorithmic formal languages for System-on-Chip design ► Thermal aware design of complex digital ICs with logithermal simulation ► Modeling of photovoltaic devices ► Modeling of biomedical microdevices with two phase flows ► Novel device design ► Development of novel biomedical microreactor devices ► Thermo-electric logical circuits (TELC) ► Novel organic compound solar cells

5. © BME Department of Electron Devices, 2012. eet.bme.hu February 6, 2013 5 Current Research – projects (summary) ► 14 accomplished projects from the last 5 years (10 EU projects, 5 national projects) ► 2 industrial standards (JEDEC), technology transfer: Mentor Graphics Ltd., MicReD division, C4S Llc ► Currently running 4 projects including ► H2020 ICT Project ► EuroCPS (2015-2018) ► Delphi4LED (2016-2019) ► 1 joint Educational Project ► Smart Systems Integration (2013-2018) ► 2 national and industrial Projects

6. © BME Department of Electron Devices, 2012. eet.bme.hu February 6, 2013 6 Facilities – Integrated Smart Systems Laboratories ► Thermal and Reliability Testing Facility  Thermal imaging, micro cooling, thermal transient testing, combined thermal, optic/radiatic measurements ► Semiconductor Technology Laboratory  Class 1000 clean room, basic MEMS, solar cell, MOS technology capabilities, device characterisation laboratory ► Chip Based Biomedical Devices Laboratory  Single and multiphase microfluidics, MNP based LoC devices, device characterisation ► Integrated Smart System Design Laboratory  Up to date industrial standard MEMS, digital and analog CAD tools and characterisation capabilities

7. © BME Department of Electron Devices, 2012. eet.bme.hu July 22, 2014 BME EET R&D 2014 7 Advanced measurement techniques ► Themal transient measurements and structure function analysis ► A non-destructive analyisis method of the device’s fine thermal structure ► Technology transfer: MicRED Ltd, later acquired by Mentor Graphics

8. © BME Department of Electron Devices, 2012. eet.bme.hu July 22, 2014 BME EET R&D 2014 8 Reliability analysis and life-time estimation of power electronics modules ► Standard power cycling combined with thermal transient testing and die attach quality analysis ► SMARTPOWER EU FP7

9. © BME Department of Electron Devices, 2012. eet.bme.hu July 22, 2014 BME EET R&D 2014 9 Novel simulation algorithms and models ► Thermal aware device design – power dissipation per unit area increases ► 3D stacked structures – new challanges of heat removal ► System on chips – run-time configurable, application specific macrocells

10. © BME Department of Electron Devices, 2012. eet.bme.hu July 22, 2014 BME EET R&D 2014 10 Optimized RTL design by AMDL ► Koncepció, érthető magyarázat, ábra (ha nem ez akkor csere)

11. © BME Department of Electron Devices, 2012. eet.bme.hu July 22, 2014 BME EET R&D 2014 11 Optimized RTL design by AMDL ► Eredmények, főleg ábrák, táblázatok stb

12. © BME Department of Electron Devices, 2012. eet.bme.hu July 22, 2014 BME EET R&D 2014 12 Thermal aware design of complex digital ICs ► Koncepció: hogy vannak összerakva a különböző megoldók rendszer szinten, miért jó ez stb, magyarázó ábra

13. © BME Department of Electron Devices, 2012. eet.bme.hu July 22, 2014 BME EET R&D 2014 13 Thermal aware design of complex digital ICs ► Eredmények, ha van, egy időfüggő eset videón? Ha nem akkor temperature map ábrák, akár az ami az előző dián van csak jobb minőségben

14. © BME Department of Electron Devices, 2012. eet.bme.hu July 22, 2014 BME EET R&D 2014 14 Multi-domain characterization of power LEDs ► Koncepció, rövid leírás, célkitűzés stb, ez az ábra jobb minőségben ha lehet

15. © BME Department of Electron Devices, 2012. eet.bme.hu July 22, 2014 BME EET R&D 2014 15 Multi-domain characterization of power LEDs ► Eredmények, ha lehet inkább ábrák, táblázatok stb

16. © BME Department of Electron Devices, 2012. eet.bme.hu July 22, 2014 BME EET R&D 2014 16 Novel device design ► ‘More Moore’: development beyond the Moore’s law: pushing the red brick wall ► ‘More than Moore’ – utilizing of nanotechnologies in electronics and bioMEMS

17. © BME Department of Electron Devices, 2012. eet.bme.hu July 22, 2014 BME EET R&D 2014 17 Thermal Electric Logic Circuit for nanoelectronics ► Koncepció, magyarázó ábrák, fém-félvezető átmenet stb.

18. © BME Department of Electron Devices, 2012. eet.bme.hu July 22, 2014 BME EET R&D 2014 18 Thermal Electric Logic Circuit for nanoelectronics ► Látványosabb eredmények, diagramok, táblázat stb.