A design technique for low-power continuous-time filters using digital CMOS technology is presented. The basic building block is a fully-balanced integrator with its unity-gain frequency determined by a small-signal transconductance and MOSFET gate capacitance. Integrator excess phase shift is reduced using balanced signal paths, and open-loop gain is increased using low-voltage cascode amplifiers. Two-pole bandpass and five-pole lowpass ladder filters have been implemented in a 1.2 /spl mu/m n-well CMOS process. The lowpass prototypes provided 300 kHz-1000 kHz bias-current-tunable -3 dB bandwidth, 67 dB dynamic range with 1% total harmonic distortion (THD), and 30 /spl mu/W/pole (300 kHz bandwidth) power dissipation with a 1.5 V supply; the bandpass prototypes had a tunable center frequency of 300 kHz-1000 kHz, Q of 8.5, and power dissipation of 75 /spl mu/W/pole (525 kHz center frequency) from a 1.5 V supply. The active filter area was 0.1 mm/sup 2//pole for both designs.