3 research outputs found
An ultralow-power mixed-signal back end for passive sensor UHF RFID transponders
This paper describes the design of mixed-signal back end for an ultrahigh-frequency sensor-enabled radio-frequency identification transponder in full compliance with the Electronic Product Code Class-1 Generation-2 protocol, defined in the standard ISO 18000-6C. The chip, implemented in a low-cost 0.35-μm CMOS technology process, includes a baseband processor, an analog-to-digital converter (ADC) to digitize the signal acquired from the external sensor, and some auxiliary circuitry for voltage regulation and reference generation. The proposed solution uses two different supply voltages, one for the processor and the other for the mixed-signal circuitry, and defines a novel communication protocol between both blocks so that analog readouts are minimally affected by the digital activity of the tag. The whole system was first functionally validated by exhaustively testing with external dc power supplies ten prototype samples, and then, the two main blocks, processor, and ADC were individually tested to assess their performance limits. Regarding the baseband processor, experiments were performed toward the calculation of its packet error rate (PER) under two typical biasing configurations of passive tags, using either crude clamps or regulators. It was found that the regulated biasing outperforms the clamping solution and obtains a PER of 3 × 10 -3 with a supply voltage of 0.75 V. The current consumption of the processor during the reception and response to a Read command at maximum backward rate is only 2.2 μA from a 0.9-V supply. Regarding the ADC, it is a 10-b successive approximation register converter which obtains 9.41 b of effective resolution at 2-kS/s sampling frequency with a power consumption of 250 nW, including the dissipation of a current generation cell and the clock generation circuitry, from 1-V supply. © 2011 IEEE.Peer Reviewe
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Design and Modelling of Passive UHF RFID Tags for Energy Efficient Liquid Level Detection Applications. A study of various techniques in the design, modelling, optimisation and deployment of RFID reader and passive UHF RFID tags to achieve effective performance for liquid sensing applications
Sewer and oil pipeline spillage issues have become major causes of pollution in urban and rural areas usually caused by blockages in the water storage and drainage system, and oil spillage of underground oil pipelines. An effective way of avoiding this problem will be by deploying some mechanism to monitor these installations at each point in time and reporting unusual liquid activity to the relevant authorities for prompt action to avoid a flooding or spillage occurrence. This research work presents a low cost energy efficient liquid level monitoring technique using Radio Frequency Identification Technology. Passive UHF RFID tags have been designed, modelled and optimized. A simple rectangular tag, the P-shaped tag and S-shaped tag with UHF band frequency of operation (850-950 MHz) has been designed and modelled. Detailed parametric analysis of the rectangular tag is made and the optimised design results analysed and presented in HFSS and Matlab. The optimised rectangular tag designs are then deployed as level sensors in a gully pot. Identical tags were deployed to detect 4 distinct levels in alternate positions and a few inches in seperation distance within the gully pot height (Low, Mid, High and Ultra high). The radiation characteristic of tag sensors in deployment as modelled on HFSS is observed to show consistent performance with application requirements. An in-manhole chamber antenna for an underground communication system is analysed, designed, deployed and measured. The antenna covers dual-band impedance bandwidths (i.e. 824 to 960 MHz, and 1710 to 2170 MHz). The results show that the antenna prototype exhibits sufficient impedance bandwidth, suitable radiation characteristics, and adequate gains for the required underground wireless sensor applications.
Finally, a Linearly Shifted Quadrifilar Helical Antenna (LSQHA) designed using Genetic Algorithm optimisation technique for adoption as an RFID reader antenna is proposed and investigated. The new antenna confirms coverage of the RFID bandwidth 860-960 MHz with acceptable power gain of 13.1 dBi.Petroleum Technology Development Fund (PTDF) and National Space Research and Development Agency (NASRDA)
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Analysis and solutions for RFID tag and RFID reader deployment in wireless communications applications. Simulation and measurement of linear and circular polarised RFID tag and reader antennas and analysing the tags radiation efficiency when operated close to the human body.
The aim of this study is to analysis, investigate and find out the solutions for the
problems associated with the implementations of antennas RFID Reader and Tag
for various applications. In particular, the efficiency of the RFID reader antenna
and the detection range of the RFID tag antenna, subject to a small and compact
antenna¿s design configuration have been studied.
The present work has been addressed directly to reduce the cost, size and increase
the detection range and communication reliability of the RFID framework
antennas. Furthermore, the modelling concept of RFID passive tags mounted on
various materials including the novel design of RFID reader antenna using
Genetic Algorithm (GA) are considered and discussed to maintain reliable and
efficient antenna radiation performances.
The main benefit of applying GA is to provide fast, accurate and reliable solutions
of antenna¿s structure. Therefore, the GA has been successfully employed to
design examples: meander-line, two linear cross elements and compact Helical-
Spiral antennas.
In addition, a hybrid method to model the human body interaction with RFID tag
antenna operating at 900MHz has been studied. The near field distribution and the
radiation pattern together with the statistical distribution of the radiation
efficiency and the absorbed power in terms of cumulative distribution functions
for different orientation and location of RFID¿s tag antenna on the human body
have been demonstrated.
Several tag antennas wi th symmetrical and unsymmetrical structure configurations
operating in the European UHF band 850-950 MHz have been fabricated and
tested. . The measured and simulated results have been found to be in a good
agreement with reasonable impedance matching to the typical input impedance of
an RFID integrated circuit chip and nominal power gain and radiation patterns