2. http://www.eet.bme.hu Budapest University of Technology & Economy Department of Electron Devices

3. The Department of Electron Devices The only university department in Hungary dealing with all aspects of microelectronics. Highly acknowledged European research center

4. The Department of Electron Devices Expertise in device physics, microelectronics CAD tools –esp. thermal simulation & circuit simulation, IC & MEMS design, gas sensors, thermal issues, multimedia, internet applications

5. Education (continued) Special subjects: –Microelectronics CAD (basic concepts in digital VLSI design, CAD systems, basics of layout level & analog design) –ASIC & FPGA Laboratory (design of an MSI circuit) –High level synthesis (VHDL, hardware synthesis methods) –VLSI Laboratory (introduction to Cadence Opus, design of a standard cell in Opus)

6. Education (continued) Special subjects: –Monolyth technology (+ processing practice in the semiconductor laboratory) –Integrated microsystems –Testing laboratory (for ICs, semiconductor materials, MEMS packages and structures,) –Course laboratories (topics are selected from all above issues)

7. Research European projects: BARMINT, THERMINIC, HIPERLOGIC, TALENT, DETERMIN, PROFIT, REASON, PATENT thermal measurements (IR, LC, transient) thermal simulation thermal testing electro-thermal simulation compact dynamic thermal modeling MEMS design, simulation and characterisation

8. Research facilities Laboratories: Thermal laboratories VLSI CAD Laboratory Semiconductor laboratory FPGA Laboratory

9. Research facilities CAD Laboratory Facilities (hardware) –SUN Enterprise Ultra server, WNT server, –10 SUN workstations –100/10 Mbps LAN, 4 network printers –20 Linux workstations –Tektronix LV500 IC tester

10. Facilities Installed software tools: –Cadence Opus AMS 0.8 ST 0.25 Mietec 2.4 CMP MEMS Engineering Kit –Atmel-ES2 SOLO 1400 (for education only) –HSpice, Spectre –THERMAN & SUNRED tools of MicReD

11. Facilities Using Cadence Opus in the SUN Laboratory

12. Facilities Tektronix LV500 IC tester

13. Facilities - Thermal laboratory LC based thermal imaging system Aga 782 IR camera with PC interface

14. Facilities - Thermal laboratory The department’s thermal transient tester Commercialized version of the transient tester

15. Facilities - semiconductor laboratory Scanning electron-microscope with PC interface

16. Facilities - semiconductor laboratory Diffusion furnace Sputtering and evaporation are also available

17. Facilities - semiconductor laboratory Spreading resistance meter

18. ….without contacts on the surface Facilities - semiconductor laboratory

19. Some research results Design of CMOS temperature sensors Generic designs, almost process independent behavior Frequency output version

20. Some research results Design of thermal test dies Following this experiences, a more sophisticated chip has been designed together with the MicReD company... 5x5 dissipator / sensor cells Tester-on-the-die: dissipator + sensor + boundary scan - first realization

21. Some research results Design of thermal test dies Our recent design: 81 individually programmable dissipator / temperature cells with boundary scan interface: improved implementation of the two older designs, 6x6 mm 2, 8 W

22. Some former research results Electro-thermal simulation Experimental system implemented in Cadence Opus on top of the ECPD07 design kit of Atmel-ES2

23. Some former research results Liquid crystal thermal imaging of ICs

24. Some research results Sophisticated post- processing of IR images Thermal transient recording using the IR camera

25. Some recent research results Thermal transient testing of IC packages Identification of properties of the chip-to-ambient heat- conduction path based on thermal transient measurements The so called structure functions provide the required information

26. Detecting die attach and soldering failures The differential structure function of the reference device 1: the transistor case 2: the copper island of the mounting plate 3: the total mounting plate 4: the cold plate R th of the soldering R th of the plastic coating

27. Detecting die attach and soldering failures Comparison of the differential structure functions of C02 and C08 R th between 2 and 3 increased The soldering error can be noticed even visually 33

28. Some recent research results Thermal transient testing of IC packages Identification of properties of the chip-to-ambient heat- conduction path based on thermal transient measurements Identification of the partial thermal resistances in the heat flow path enabling detection of die attach and soldering failures Calculation of effective thermal conductivity and emissivity values from the measured results, etc

29. Some recent research results Compact thermal model generation A package The generated BCI (Boundary condition independent) compact model

30. Some recent research results BCI Compact thermal model generation The transient results (FS=field solver, CM=compact model)

31. Some recent research results Investigation of surface potentials on different materials Vibrating capacitor with transparent reference electrode

32. Some recent research results Gas sensing: the adsorption induced shifts in work function differences at 460-360K (Pd-Ag-Au-Pt-V-Pt-SnO 2 ) (Kelvin method) PdAgAuPtV SnO 2 C 30mm 25mm 1% H 2 -air mixtureNH 4 OH vapour (NH 3 ) CHCl 3 vapourC 2 H 5 OH vapour  460K  360K

33. Further research in progress Enabling board level simulators to accept packages with their compact thermal models Design for testability of MEMS structures Thermal transient examination of power circuits Development of a fast and user friendly electro-static solver Development of a methodology to detect die attach failures in packages with transient thermal testing Research in low power circuit design Research in surface potential measurement Development of gas sensors Characterisation of solar cells by different methods, etc