The project has developed the core switches for NEM Switch technology (called 3T, 4T and 7T switches), reduced their size and operating voltage and proved their ability to withstand severe shock and vibration.
We have developed a software design system (or PDK) for NEM Switch technology. This PDK has software models of its switches, primitive cells such as logic (eg AND, NOR, MUX), memory and an FPGA computing cell. Also embedded in our PDK, is our previously mentioned work of using the unique characteristics NEM Switches to simplify the architecture of common components, such as by using 4T switches to reduce ADC size. Finally, our PDK has enabled quick circuit designs and die layouts, has been extensively used and tested in ZeroAMP, and could be available for future customers to design NEM Switch products.
The project has optimised its high-density integration method. It has used its PDK to design a proof-of-concept wafer containing a range of devices from the core NEM switches all the way up to more complex devices such as FPGA. It has now fabricated these wafers at one of XFAB’s wafer foundries.
ZeroAMP has developed a range of packaging solutions from tiny silicon lids bonded on top of the dies, to a multi-die assembly on a PCB (or System-in-Package) capable of 250oC.
Using all this technology, we have designed NEM Switch circuits, laid out these circuits for wafer production, developed assembly processes, and manufactured the component parts for a demonstrator that will record temperatures in a conveyor oven that will show case NEM Switch capabilities.
The project has developed exploitation plans, created product specifications, developed a cost model and a “Lab to Fab” roadmap for its future supply chain. This information has provided clearer goals for future NEM Switch commercial development. The project has also advertised its technology by many dissemination activities, such as scientific conferences, LinkedIn posts, and our website.
In summary, the project has carried out novel scientific work to develop a new class of microelectronic devices, developed plans to commercially exploit this work and disseminated its work to a wide audience.