This paper presents an ultra-low-power area-efficient non-volatile memory(NVM) in a 0.18μm singlepoly standard CMOS process for passive radio frequency identification(RFID) tags.In the memory cell,a novel low-power operation method is proposed to realize bi-directional Fowler-Nordheim tunneling during write operation. Furthermore,the cell is designed with PMOS transistors and coupling capacitors to minimize its area.In order to improve its reliability,the cell consists of double floating gates to store the data,and the 1 kbit NVM was implemented in a 0.18μm single-poly standard CMOS process.The area of the memory cell and 1 kbit memory array is 96μm^2 and 0.12 mm^2,respectively.The measured results indicate that the program/erase voltage ranges from 5 to 6 V.The power consumption of the read/write operation is 0.19μW/0.69μW at a read/write rate of (268 kb/s)/(3.0 kb/s).
This paper presents a low power 2.4 GHz transceiver for ZigBee applications.This transceiver adopts low power system architecture with a low-IF receiver and a direct-conversion transmitter.The receiver consists of a new low noise amplifier(LNA) with a noise cancellation function,a new inverter-based variable gain complex filter (VGCF) for image rejection,a passive quadrature mixer,and a decibel linear programmable gain amplifier(PGA). The transmitter adopts a quadrature mixer and a class-B mode variable gain power amplifier(PA) to reduce power consumption.This transceiver is implemented in 0.18μm CMOS technology.The receiver achieves—95 dBm of sensitivity,28 dBc of image rejection,and -8 dBm of third-order input intercept point(IIP3).The transmitter can deliver a maximum of+3 dBm output power with PA efficiency of 30%.The whole chip area is less than 4.32 mm^2. It only consumes 12.63 mW in receiving mode and 14.22 mW in transmitting mode,respectively.
This paper presents a 2.4 GHz CMOS transceiver for the wireless personal area network (WPAN) inte- grated in 0.18/zm CMOS technology. This transceiver adopts a low-IF receiver, a MUX based transmitter and a fast-setting fractional-N frequency synthesizer. For achieving low cost and low power consumption, an inductor- less receiver front-end, an adaptive analog baseband, a low power MUX and a current-reused phase-locked loop (PLL) have been proposed in this work. Measured results show that the receiver achieves-8 dBrn of lIP3 and 31 dB of image rejection. The transmitter delivers 0 dBm output power at a data rate of 2 Mbps. The current consumption is 7.2 mA in the receiving mode and 6.9 mA in the transmitting mode, respectively.
