Towards a platform for ambient intelligence

1. Towards a platform for ambient intelligence ICT DRC AdviesRaad 12 jan 2006

2. Project example (1) • BioSens (STW: TUD/UM, Medtronic, Vitatron, Twente Medical Systems, Maastricht Instruments, Systematic Design, Weijand Consultancy) • Biomedical signal processing platform for low-power real-time sensing of cardiac signals • Mathematical modeling of cardiac signals and pathologies • Design of WT-based algorithms for sensing and feature extraction • Low-power analog integrated circuits that implement the WT and artifact detection • Platform: • Database of relevant (recorded and synthesized) cardiac signals, annotated and clustered • Database of WT-based algorithms, specified, tested, … • ECG player (to generate test signals) • Various dedicated IC designs, specified, tested, …

3. Project example (2) • UWB for the process industry (Senter: Utellus/TUD/Shell/WIB) • For TUD a natural follow-up on the AIRLINK project • Platform: • UWB test bed • Protocols • Application layer designs • Measurement data • User experiments • Modular UWB radio • Analog front-end IC’s • Antennas • Modulation and signaling techniques • Signal processing algorithms • Routing and synchronization algorithms • Embedded software • Interfacing products • Standards (?) • Really new applications not possible with conventional technology • UWB based solutions and products

4. Project example (3) • SiMS (smart implantable medical systems) • TUD + Stryker, Medtronics, Vitatron, Twente Medical Systems, VUMC, AMC, EUR, Telemetronics, TNO-FEL, Philips Medical Systems, Philips Research (several groups), SystematIC, Maastricht University (math dept.) etc. • Platform: • Sensors • Digital architecture (processing/controlling unit) • Compiler (tool) • On-chip antennas • (On-chip) battery • Wireless modules

5. What? • Hard IP • Hard IP is optimized for power, size, and performance, and mapped to a specific technology. • Mask layouts • Library cells • Test chips • DSP • PCB • The best aspect of hard IP is guaranteed performance, be it speed, power consumption, and so on. • Soft IP • Soft IP is delivered in a synthesizable form, which must then be implemented into the target technology • Netlist • Hardware Description Language (HDL) • C/C++ code • MatLab/SimuLink code • Java • Soft IP is easy to retarget and configure. • Meta IP • User scenarios • Use cases

6. + what? • Design techniques • Design methodologies • Proofs of concept • Best practice • Interface definitions (I/O, API)

7. Why? (University) • Validate our research • Focus our research • Prove our research • You do not count if you cannot present your realizations • Marketing • PR • Acquisition • Students • Projects • Develop multi-disciplinary expertise

8. Why? (Industry) • IP gap: • IC complexity is growing at a rate of 58% per year, but design productivity is increasing at only 21% per year. • Most of the people we train will end up in industry (B.Sc.’s, M.Sc’s, PD Eng and Ph.D’s)

9. Why not? (University) • Will only pay off on the longer term • Additional work (burden) • Less papers • Not appreciated

10. Actions up to now • Discussions with and proposal for a framework from SystematIC Design • Proposal in NIRICT for a 'Platform Lab' in the context of the NIRICT Innovation action • Pilot to explore interested parties in the context of the Delft Innovation Lab (also part of the 3TU Program) - contract with Westfield BV

11. We need • Your comments • Your suggestions • Your ideas • Your input • Your contribution