In this paper, a fourth-order continuous-time follow- the-leader-feedback (FLFB) low-pass (LP) filter is presented. The outstanding FLFB noise behavior is exploited to minimize power consumption. This is achieved by means of customized imple- mentation solutions based on combination of Active-RC/Active- g m -RC cells. The 0.18-μm CMOS prototype performs 22.5-MHz −3 dB LP frequency response. Large linearity and dynamic range were achieved resulting in 21.5-dBm in-band (iB) IIP3 and 87-μV RMS input referred iB integrated noise. The SNR for a −40 dB HD 3 is 63 dB. The overall power consumption is 12.6 mW (i.e., 7 mA from a 1.8-V supply). The efficiency of the proposed technique is demonstrated by the achieved figure- of-merit (150.8 dB · J −1 ), which favourably compares to the state-of-the-art active-RC analog filters.
A 63-dB DR 22.5-MHz 21.5-dBm IIP3 Fourth-Order FLFB Analog Filter
D'Amico, Stefano;
2017-01-01
Abstract
In this paper, a fourth-order continuous-time follow- the-leader-feedback (FLFB) low-pass (LP) filter is presented. The outstanding FLFB noise behavior is exploited to minimize power consumption. This is achieved by means of customized imple- mentation solutions based on combination of Active-RC/Active- g m -RC cells. The 0.18-μm CMOS prototype performs 22.5-MHz −3 dB LP frequency response. Large linearity and dynamic range were achieved resulting in 21.5-dBm in-band (iB) IIP3 and 87-μV RMS input referred iB integrated noise. The SNR for a −40 dB HD 3 is 63 dB. The overall power consumption is 12.6 mW (i.e., 7 mA from a 1.8-V supply). The efficiency of the proposed technique is demonstrated by the achieved figure- of-merit (150.8 dB · J −1 ), which favourably compares to the state-of-the-art active-RC analog filters.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.