Reconfigurable high-order integrated circuit filters

摘要

Voltage and current mode reconfigurable nth-order filters (RNOFs) fabricated in a 0.18 μm CMOS process are disclosed. The RNOFs utilize an inverse-follow-the-leader-feedback (IFLF) signal path with summed outputs, resulting in a follow-the-leader-feedback-summed-outputs (FLF-SO) filter topology. The FLF-SO filter uses multi-output current amplifiers (CAs). Inverse-follow-the-leader-feedback-summed-outputs (IFLF-SO) and inverse-follow-the-leader-feedback-distributed-outputs (IFLF-DI) structures are realized by employing 3n+4 transconductance amplifiers (TCAs) for voltage mode processing and two TCAs for current mode signals. A plurality of programmable current division networks (CDNs) tune a digitally controlled current follower (DCCF). A multi-output Digitally Controlled Current Amplifier (MDCCA) controls gain by providing independent filter coefficient control. Forward path output gains are set to unity. Alternatively, a multi-output digitally controlled CCII block (MDCCCII) uses CCII in the first stage. Such filters provide independent tuning of both numerator as well as denominator coefficients and are reconfigurable without the need of switches due to CDNs setting undesired output current to zero.

主权项

1. A reconfigurable high-order integrated circuit filter, comprising:
a plurality of current followers (CFs) arranged in cascade, the cascade having:
a first stage current follower having an input, a single inverting output, and a single non-inverting output, the input being adapted for connection to a signal input to the filter;a final stage current follower having an input, a single inverting output, and first and second non-inverting outputs; andat least one intermediate stage current follower having an input, first and second inverting outputs, and first and second non-inverting outputs, the inverting output of the first stage current follower being connected to the input of the next succeeding current follower in the cascade, the first inverting output of the at least one intermediate stage current follower being connected to its own input; a plurality of resistor-capacitor (RC) integrators, the at least one intermediate stage current follower and the final stage current follower having a corresponding one of the RC integrators connected to its corresponding input, the first inverting output of the at least one intermediate stage current follower and the final stage current follower being connected to the corresponding RC integrator at its corresponding input; a plurality of external feedback current division networks (CDNs), the at least one intermediate stage current follower and the final stage current follower each having a corresponding one of the CDNs disposed in a feedback loop between the first non-inverting output of the respective one of the at least one intermediate stage current follower and the final stage current follower and the input of the first stage current follower; a summing current follower having an input and an output, the output of the summing current follower being the output of the filter; and a plurality of external feed forward current division networks (CDNs), the first stage current follower having a corresponding one of the feed forward CDNs connected in a feed forward loop from its non-inverting output to the input of the summing current follower, each of the succeeding current followers having a corresponding one of the feed forward CDNs disposed in a feed forward loop from its second non-inverting output to the input of the summing current follower; wherein each of the feedback CDNs has an input accepting a βf filter coefficient control signal unique to the feedback CDN and each of the feed forward CDNs has an input accepting a βg filter coefficient control signal unique to the feed forward CDN; whereby the filter has a transfer function characterized by the relation:im⁡(s)is⁡(s)=sm⁢βgm⁢∏i=mn-1⁢⁢1Ci+1⁢Risn+∑i=0n-1⁢⁢βfi⁢si⁢∏j=in-1⁢⁢1Cj+1⁢Rjfor⁢⁢m=0⁢⁢to⁢⁢n-1,in which βgm is the transfer function numerator coefficient parameter configurable by adjusting the control signals to the feed forward CDNs and βft is the transfer function denominator coefficient parameter configurable by adjusting the control signals to the feedback CDNs, where im (s) represents a Laplace transform of an output of the filter in the s-domain, and is (s) represents a Laplace transform of an input of the filter in the s-domain.