A 440pJ/bit 1Mb/s 2.4GHz multi-channel FBAR-based TX and an integrated pulse-shaping PA
VLSIC(2012)
摘要
A 2.4GHz TX in 65nm CMOS defines three channels using three high-Q FBARs and supports OOK, BPSK and MSK. The oscillators have −132dBc/Hz phase noise at 1MHz offset, and are multiplexed to an efficient resonant buffer. Optimized for low output power ≈−10dBm, a fully-integrated PA implements 7.5dB dynamic output power range using a dynamic impedance transformation network, and is used for amplitude pulse-shaping. Peak PA efficiency is 44.4% and peak TX efficiency is 33%. The entire TX consumes 440pJ/bit at 1Mb/s. Introduction Body Area Networks (BANs) for continuous health monitoring applications require radios that are both reliable and energy efficient in order to minimize device size and extend battery lifetime. Due to short transmit distances and an energyasymmetric star topology, a low output power of −10dBm is sufficient for the sensor node [1]. Low PA power consumption places stringent power constraints on LO generation and modulation to maintain high overall TX efficiency. Recent work shows that high-Q direct-RF resonators, such as FBAR and SAW, provide low-power and stable LOs [2, 3], avoiding slowstarting, power-hungry PLLs. Low tuning range, however, limits operation to a single channel. Typical PAs are not optimized for low output power, and this presents additional challenges. This work proposes a high-Q RF resonator-based frequency generation architecture that scales to multiple channels by multiplexing resonators. A three-channel FBAR-based TX operating in the 2.4GHz ISM band demonstrates the idea. Additionally, a PA optimized for low output power is proposed, with an integrated tunable impedance transformation network capable of amplitude pulse-shaping for improved spectral efficiency. Multi-Channel Transmitter Architecture Fig. 1 shows the TX architecture. Three FBAR oscillators are multiplexed to an efficient resonant buffer which directly drives the PA. The buffer stage also incorporates matched delays with inverted phase to provide BPSK modulation. Since the output power is low, overall TX efficiency is critical, and informs the design choices for LO generation, modulation, and channel multiplexing. A low voltage design (0.7V) coupled with rail-to-rail swing on all RF nodes is used for improved power efficiency. Full swing on the oscillator minimizes shortcircuit current in the buffers, while full swing at the input of the PA maximizes overdrive. The TX is designed for a datarate of 1Mb/s and supports three simple modulation schemes: OOK, BPSK and MSK, all with pulse-shaping capability. Fig. 1 also shows the schematic of a Pierce oscillator [2] used for one channel. This inverter-based circuit provides rail-to-rail output swing and reduces power consumption by ∗The authors acknowledge the financial support of the Interconnect Focus Center, one of six research centers funded under the FCRP, an SRC entity. The authors thank TSMC University Shuttle Program for chip fabrication and Dr. Richard Ruby and Avago Technologies for providing FBARs. -10dBm PA 2.4GHz ULP-TX Resonant Buffer F B A R O sc ill at or s
更多查看译文
关键词
CMOS analogue integrated circuits,UHF integrated circuits,UHF oscillators,UHF power amplifiers,UHF resonators,acoustic resonators,amplitude shift keying,bulk acoustic wave devices,minimum shift keying,phase noise,phase shift keying,BPSK,CMOS technology,MSK,OOK,amplitude pulse-shaping,binary phase shift keying,bit rate 1 Mbit/s,dynamic impedance transformation network,efficiency 33 percent,efficiency 44.4 percent,film bulk acoustic resonator,frequency 2.4 GHz,high-Q FBAR,integrated pulse-shaping PA,minimum shift keying,multichannel FBAR-based TX,on-off keying,oscillators,phase noise,resonant buffer,size 65 nm,
AI 理解论文
溯源树
样例
生成溯源树,研究论文发展脉络