Printed Microprocessors

Printed electronics holds the promise of meeting the cost and conformality needs of emerging disposable and ultra-low cost margin applications. Recent printed circuits technologies also have low supply voltage and can, therefore, be battery-powered. In this paper, we explore the design space of microprocessors implemented in such printing technologies - these printed microprocessors will be needed for battery-powered applications with requirements of low cost, conformality, and programmability. To enable this design space exploration, we first present the standard cell libraries for EGFET and CNT-TFT printed technologies - to the best of our knowledge, these are the first synthesis and physical design ready standard cell libraries for any low voltage printing technology. We then present an area, power, and delay characterization of several off-the-shelf low gate count microprocessors (Z80, light8080, ZPU, and openMSP430) in EGFET and CNT-TFT technologies. Our characterization shows that several printing applications can be feasibly targeted by battery-powered printed microprocessors. However, our results also show the need to significantly reduce area and power of such printed microprocessors. We perform a design space exploration of printed microprocessor architectures over multiple parameters - datawidths, pipeline depth, etc. We show that the best cores outperform pre-existing cores by at least one order of magnitude in terms of power and area. Finally, we show that printing-specific architectural and low-level optimizations further improve area and power characteristics of low voltage battery-compatible printed microprocessors. Program-specific ISA, for example, improves power, and area by up to 4.18x and 1.93x respectively. Crosspoint-based instruction ROM outperforms a RAM-based design by 5.77x, 16.8x, and 2.42x respectively in terms of power, area, and delay.