Title :
A 90µW MICS/ISM band transmitter with 22% global efficiency
Author :
Pandey, Jagdish ; Otis, Brian
Author_Institution :
Dept. of Electr. Eng., Univ. of Washington, Seattle, WA, USA
Abstract :
For fully autonomous implantable or body-worn devices running on harvested energy, the peak and average power dissipation of the radio transmitter must be minimized. We propose a highly integrated 90 μW 400MHz MICS band transmitter with an output power of 20 μW leading to a 22% global efficiency - the highest reported to date for such systems. We introduce a new transmitter architecture based on cascaded multi-phase injection locking and frequency multiplication to enable low power operation and high global efficiency. Our architecture eliminates slow phase/delay-locked loops for frequency synthesis and uses injection locking to achieve a settling time <; 250 ns permitting very aggressive duty cycling of the transmitter to conserve energy. At a data-rate of 200 kbps, the transmitter achieves an energy efficiency of 450 pJ/bit. Our 400MHz local oscillator topology demonstrates a figure-of-merit of 204 dB.
Keywords :
injection locked oscillators; phase locked loops; radio transmitters; ISM band transmitter; MICS band transmitter; average power dissipation; bit rate 200 kbit/s; body-worn devices; frequency 400 MHz; frequency multiplication; global efficiency; medical implant communications service; multiphase injection locking; power 20 muW; power 90 muW; radio transmitter; Delay effects; Energy efficiency; Frequency conversion; Frequency locked loops; Frequency synthesizers; Injection-locked oscillators; Microwave integrated circuits; Power dissipation; Power generation; Radio transmitters;
Conference_Titel :
Radio Frequency Integrated Circuits Symposium (RFIC), 2010 IEEE
Conference_Location :
Anaheim, CA
Print_ISBN :
978-1-4244-6240-7
DOI :
10.1109/RFIC.2010.5477395
