An adaptively pipelined mixed synchronous-asynchronous digital FIR filter chip operating at 1.3 gigahertz

Abstract

A high-throughput low-latency digital finite impulse response (FIR) filter has been designed for use in partial-response maximum-likelihood (PRML) read channels of modern disk drives. The filter is a hybrid synchronous-asynchronous design. The speed-critical portion of the filter is designed as a high-performance asynchronous pipeline sandwiched between synchronous input and output portions, making it possible for the entire filter to be embedded within a clocked system. A novel feature of the filter is that the degree of pipelining is dynamically variable, depending upon the input data rate. This feature is critical in obtaining a very low filter latency throughout the range of operating frequencies. The filter is a ten-tap six-bit FIR filter, fabricated in a 0.18-$\mu \hbox {m}$ CMOS process. Resulting chips were fully functional over a wide range of supply voltages, and exhibited throughputs of over 1.3 giga-items/s, and latencies of 25 clock cycles. Interestingly, the filter throughput was limited by the synchronous portion of the chip; the internal asynchronous pipeline was estimated to be capable of significantly higher throughputs, around 1.8 giga-items/s. More importantly though, the adaptively pipelined nature of the filter allows it to offer a worst-case latency of only 10 ns, which is half the worst-case latency of the best previously reported comparable fully-synchronous implementation by Rylov © 2006 IEEE.