Study on Analog Front End of Passive UHF RFID Transponder

In this paper, an overview of passive Ultra High Frequency (UHF) Radio Frequency Identification (RFID) is presented. This literature review emphasis on the analog front end part of the RFID transponder based on several published papers conducted by previous researchers. A passive UHF RFID transponder chip design was proposed using 0.18 μm standard CMOS process. It is estimated to have power of 1μW and high efficiency that greater than 32%. This design will work in the range of frequency between 900MHz to 960MHz

A Low-Power Passive UHF Tag With High-Precision Temperature Sensor for Human Body Application

Radio frequency identification (RFID) tags are widely used in various electronic devices due to their low cost, simple structure, and convenient data reading. This topic aims to study the key technologies of ultra-high frequency (UHF) RFID tags and high-precision temperature sensors, and how to reduce the power consumption of the temperature sensor and the overall circuits while maintaining minimal loss of performance. Combined with the biomedicine, an innovative high-precision human UHF RFID chip for body temperature monitoring is designed. In this study, a ring oscillator whose output frequency is linearly related to temperature is designed and proposed as a temperature-sensing circuit by innovatively combining auxiliary calibration technology. Then, a binary counter is used to count the pulses, and the temperature is ultimately calculated. This topic designed a relaxation oscillator independent of voltage and current. The various types of resistors were used to offset the temperature deviation. A current mirror array calibration circuit is used to calibrate the process corner deviation of the clock circuit with a self-calibration algorithm. This study mainly contributes to reducing power consumption and improving accuracy. The total power consumption of the RF/analog front-end and temperature sensor is 7.65µW. The measurement error of the temperature sensor in the range of 0 to 60◦C is less than ±0.1%, and the accuracy of the output frequency of the clock circuit is ±2.5%

Hybrid RFID-Based System Using Active Two-Way Tags

Ultra High Frequency (UHF) Radio Frequency Identification (RFID) is a promising technology that has experienced tremendous growth by revolutionizing a variety of industry sectors and applications, such as automated data management, the tracking of a specified object, highway toll collection, library inventory tracking, multi-level asset tracking, and airport baggage control. For many RFID applications, it is desired to maximize the operating distance or read range. This thesis proposes a design of an analog front-end architecture and the baseband controller for a Class-4 Active Two-Way (C4-ATW) RFID tag in order to maximize or increase the tracking range by implementing a tag-hopping technique. In tag-hopping, C4-ATW RFID tags power their own communication with other C4-ATW RFID tags and existing passive RFID tag while the reader\u27s functionality remains unchanged. The simulation results indicate that the C4-ATW RFID tag can detect a minimum incident RF input power of -20 dBm at a 120 Kbps data rate. For -20 dBm input power; the achieved read range between a reader and tag is 36.7 meters at 4 W of reader power and between two tags, the read range is 2.15 meters at 25 mW tag power. Combined, the analog front end and baseband controller consume 50.3 mW of power and the area of the chip, including pads, is 854 µm x 542 µm

Introduction to Radio-frequency Identification (RFID)

This project presents the fundamental aspects of the RFID (Radio-frequency identifica-tion) technology used to establish wireless communications. The project focuses on thepassive mode of RFID, where the receiver does not have any power supply, which allowsits miniaturization and low cost.On the other hand, two articles from different authors are analyzed. The first consists onthe design of a very low power passive receiver through various techniques of optimizationin the hardware’s manufacture.In the second, a drone is used as an intermediate element between the transmitter and thereceiver to extend up to 10 times the typical range of passive RFID. The study focuses onthe treatment of the RF signal to considerably eliminate the interferences and to preciselylocalize the receiver.Outgoin

A Design of a High-Performance Analog Front-End for Passive UHF RFID Tag EPC C1G2

This paper introduces a high-performance analog front end for passive UHF RFID tag compatible with the EPC Class-1 Generation 2 (EPC C1G2) standard protocol. The proposed front end of a passive tag which contains the following modules: a power generation circuit which is composed of a matching circuit and an RF-limiter circuit, an NMOS rectifier, a DC limiter, a voltage regulation, a modulation and ASK demodulation circuit, a power-on-reset circuit, a ring oscillator which generates a clock of 1.28 MHz. The originality of this work is the proposal of a voltage regulation circuit composed of two distinct LDO regulators that share the same reference voltage and are designed to generate a Vdd1 (0.5 V) for the analog supply and Vdd2 (1 V) for digital power supply, under conditions of 50 Ω antenna, 900 MHz, a sensitivity of -24 dBm and a maximum consumption of 1 µW. The operating distance of the RFID is more than 25 meters based on the regulated 4 W effective isotropic radiated power (EIRP). The chip area of the proposed analog front end is only 79 μm × 83 μm. The simulation results in 90 nm CMOS process confirm the performance of the proposed analog front-end

UHF Power Transmission for Passive Sensor Transponders

Passive transponder tags operating in the ultra high frequency (UHF) range receive their power supply from the electromagnetic carrier wave from a remote base station. The maximum range is largely determined by the circuits’ current consumption and the rectifier efficiency. Reading ranges of several meters have recently been reported for several state of the art RFID (Radio frequency IDentification) tags [1]. The presented UHF transponder chip with integrated temperature sensor was designed for a 0.35 ?m CMOS process with EEPROM, Schottky diodes, and double poly layers. Due to a more complex architecture and additional functionality, the power consumption of the presented sensor transponder tag is significantly larger than that of simple RFID tags. The A/D conversion requires a stable, ripple-free supply voltage with a relatively large DC value. A novel rectifier circuit generates the supply voltage from the high frequency antenna signal. The circuit requires only -11.4 dBm input power and is insensitive to temperature and process variations. The maximum operating distance is approximately 4.5 m