A Floating-Gate-Based Field-Programmable Analog Array

Abstract

A field-programmable analog array (FPAA) with 32 computational analog blocks (CABs) and occupying 3 × 3 mm2 in 0.35-μm CMOS is presented. Each CAB has a wide variety of subcircuits ranging in granularity from multipliers and programmable offset wide-linear-range Gm blocks to nMOS and pMOS transistors. The programmable interconnects and circuit elements in the CAB are implemented using floating-gate (FG) transistors, the total number of which exceeds fifty thousand. Using FG devices eliminates the need for SRAM to store configuration bits since the switch stores its own configuration. This system exhibits significant performance enhancements over its predecessor in terms of achievable dynamic range (> 9 b of FG voltage) and speed (≈ 20 gates/s) of accurate FG current programming and isolation between ON and OFF switches. An improved routing fabric has been designed that includes nearest neighbor connections to minimize the penalty on bandwidth due to routing parasitic. A maximum bandwidth of 57 MHz through the switch matrix and around 5 MHz for a first-order low-pass filter is achievable on this chip, the limitation being a “program” mode switch that will be rectified in the next chip. Programming performance improved drastically by implementing the entire algorithm on-chip with an SPI digital interface. Measured results of the individual subcircuits and two system examples including an AM receiver and a speech processor are presented.