Title :
Micro-watt inductorless gm-boost LNA for biomedical implants
Author :
Goodarzy, Farhad ; Sedighi, Behnam ; Skafidas, Efstratios Stan
Author_Institution :
EEE Dept., Univ. of Melbourne & Victoria Res. Lab., Melbourne, VIC, Australia
Abstract :
In this paper a low power, inductor-less gm-boosted LNA architecture suitable for biomedical implants in the MICS band (402-405 MHz) together with an overview of some traditional architectures for designing LNAs are presented. These architectures are compared in terms of suitability for biomedical implants based on a conventional figure of merit (FOM) and two new modified FOMs more suitable for biomedical implants considering the emphasis for low power and small size requirements for such devices. Based on the post layout simulation results in 130 nm IBM technology, the proposed LNA achieves 26 dB gain with a 4dB noise figure (NF) while dissipating 20μW from a 1.2 supply and taking up 530μm2 of chip area. Also the detailed performances outlined in this paper, guide a designer to make better choices when designing LNA for biomedical implants and embedded systems.
Keywords :
biomedical communication; embedded systems; integrated circuit design; low noise amplifiers; low-power electronics; prosthetic power supplies; IBM technology; MICS band; biomedical implant; chip area; conventional figure of merit; embedded system; frequency 402 MHz to 405 MHz; gain 26 dB; inductor-less gm-boosted LNA architecture; low power device; microWatt inductorless gm-boost LNA; modified FOM; noise figure 4 dB; post layout simulation; power 20 muW; size 130 nm; small size requirement; traditional architecture; voltage 1.2 V; CMOS integrated circuits; Impedance matching; Implants; Inductors; Noise; Topology; Transistors;
Conference_Titel :
Circuits and Systems (ISCAS), 2013 IEEE International Symposium on
Conference_Location :
Beijing
Print_ISBN :
978-1-4673-5760-9
DOI :
10.1109/ISCAS.2013.6572241
