On Performance Evaluation And Enhancement Of Rfid Systems Complying With Iso 18000 3, Iso 18000-7 Standards

Tez (Yüksek Lisans) -- İstanbul Teknik Üniversitesi, Fen Bilimleri Enstitüsü, 2013Thesis (M.Sc.) -- İstanbul Technical University, Institute of Science and Technology, 2013Bu Yüksek Lisans Tezi iki ana kısımdan oluşmaktadır. Birinci kısım, ISO 18000-3 ve ISO 18000-7 standartlarına uygun pasif ve aktif RFID sistemlerinin performans değerlendirmesini içermektedir. İkinci kısım ise, 18000-7 standardına uygun RFID sistemlerinin çoklu antenlerle başarım iyileştirilmesini içermektedir. Bu kısım ayrıca değişik sınırlı geri besleme metotlarının çoklu antenlerle birlikte etiket ve okuyucu tarafındaki detaylı karşılaştırmalarını da kapsamaktadır. Radyo frekans tanımlama (RFID) teknolojisi, kablosuz haberleşme alanında oldukça popüler olmaya başlamış ve birçok uygulama alanında yaygın bir şekilde dağılmıştır: temassız kredi kartları, e-pasaport, bilet sistemleri, giriş-çıkış kontrolleri, oyunlar, sağlık, ilaç, doküman ve basın yönetimi... Bu teknoloji, radyo dalgaları yardımıyla herhangi bir nesne ya da canlıyı tanımlama veya takip etmeyi kablosuz olarak sağlamaktadır. RFID sistemleri, kullandıkları frekans bantlarına göre üç gruba ayrılırlar: Düşük frekans (LF, 30-300 KHz), Yüksek Frekans (HF 3-30MHz) ve ultra yüksek frekans (UHF,300MHz-3GHz) / Mikrodalga (>3 GHz). RFID etiketleri ve okuyucuları birbirleriyle havadan haberleşirler. Haberleşme kanalının güvensiz olması ve hafif-siklet etiketlerin sınırlı kapasiteleri güvenlik ve mahremiyet açıklarına neden olur. Bir saldırgan etiketi taklit edebilir, izleyebilir, dinleyebilir veya DoS saldırısında bulunabilir. Bu açıklıklara ek olarak, bir etiket, bir düşman tarafından yaşam döngüsü boyunca farkedilememelidir. Eğer bir saldırgan bir etiketi tanıdıysa, artık onu kolayca takip de edebilir. Bu durumda, iki saldırı söz konusudur: (i) Bir saldırgan etiketin bütün geçmiş konuşmalarını deşifre edebilir veya (ii) gelecek konuşmalarında onu takip edebilir. Bu saldırılar sırasıyla geri dönük takip edilebilme ve ileriye dönük takip edilebilme atağı olarak adlandırılmaktadır. Litaratürde güvenlik ve mahremiyet sorunlarına çözüm olacak açık-anahtar şifreleme çözümleri bulunmaktadır, fakat bu çözümlerin hiçbir tanesi, sınırlı kapasiteleri nedeniyle birçok uygulamada kullanılan hafif-siklet etiketler için uygun bir çözüm değildir. Bu yüzden, saldırganların sınırlı kapasitedeki etiketleri kandırmasını engellemek için çok sayıda hafi-siklet asıllama prokolleri önerilmiştir. Önemi artan güvenlik ve mahremiyet konuları genellikle yakın alan haberleşmelerinde kullanılan (kablosuz akıllı kartlar) HF RFID sistemleriyle ilgilidir. çünkü bu sistemler, birçok RFID uygulamalarında (e-pasaport, akıllı nüfus kartı, kredi kartları vb.) güvenlik ve mahremiyet gerektiren kişisel bilgileri saklamaktadır. Birçok araştırmacı, standartlara uygun olacak şekilde güvenlik ve mahremiyet problemlerine farklı protokol tasarımlarıyla çözümler sunmuşlardır. Bu protokollerin güvenlik ve mahremiyet konularındaki analizleri oldukça önemli olmasına rağmen, onların gerçek hayattaki verimlilikleri ise önem arz eden başka bir konudur. Maalesef, her bir yeni protokol tasarımının fiziksel olarak test edilebilmesi maliyet, zaman ve pratik uygulama açısından oldukça zordur. Protokollerin performansları, HF RFID uygulamalarının kalitesini etkilemektedir. Bu yüzden, farklı protokolleri değerlendirmek için birçok simülasyon ortamları geliştirilmiştir. Bunlardan hiçbiri kablosuz kanal etkisini göz önüne alacak şekilde protokollerin başarı sınırlarını göstermemiştir. Bu motivasyonla biz, bu tez çalışmasında PETRA simülasyon ortamına AWGN ve Rayleigh sönümlemeli kanal modellerini ekleyerek iyileştirmede bulunduk. Bu kanallarda haberleşen ISO/IEC 18000-3 standardına uygun olan RFID sistemlerindeki protokollerin performans sınırlarını gösterdik. Bu amaca yönelik olarak, güvenli ve mahrem bir kimlik tanıma protokolünü, yeni geliştirdiğimiz simülasyon ortamına uyguladık ve pasif RFID sistemlerin gerçek hayatta kullanılmadan önceki performans değerlendirmesini gözlemledik. Biz RFID protkollerinin en iyi başarıyı AWGN kanalı altında sergilediğini gösterdik. Bu başarım göstergesi bize aslında protokolün başarım üst sınırını vermektedir çünkü AWGN kanal kablosuz haberleşme ortamları içerisinde ideal kanal olarak kabul edilmektedir. Ayrıca, kablosuz kanalın etilerini göstermek için Petra simülasyon ortamının sonuçlarını ekledik. Bunun aynı sıra, Rayleigh sönümlemeli kanalda başarım sonuçlarını elde ettik. Bu sonuçlar ise bize RFID protokollerin başarım alt sınırını vermektedir çünkü Rayleigh sönümlemeli kanalın bozucu etikeleri AWGN kanalına göre daha çoktur ve en kötü kanal yapılarında birisidir. AWGN kanalında çerçeve hata oranı sinyal gürültü oranına göre üstsel olarak azalırken, Rayleigh sönümlemeli kanalda linear olarak azaldığı simülasyonlarla gösterilmiştir. RFID etiketleri aynı zamanda enerji kaynaklarına göre üç gruba ayrılır: pasif, yarı-pasif ve aktif etiketler. Pasif RFID etiketlerin kendi enerji kaynakları yoktur. Bunun yerine bu etiketler, okuyucudan yayınlanan enerjiyi kullanırlar. Yarı-pasif ve aktif etiketlerde ise kendilerine ait bir enerji kaynakları vardır. Aktif etiketlerle yarı-pasif etiketlerin farkı ise yarı-pasif etiketlerin ilk konuşmayı başlatmaması ve okuyucudan gelen sorgu ile konuşabilmesidir. Kendi enerji kaynağını, okuyucudan gelen sorgu ile kullanmaya başlar. Aktif RFID etiketleri ise okuyucu ile kendi konuşma başlatabildiği gibi ondan gelen sorgu ile de konuşmaya başlayabilir. Aktif RFID etiketleri, birçok uygulamada sahip oldukları görünürlük, güvenlik, kaliteli ve uzak mesafeli haberleşme kabiliyetleri açısından tercih edilebilmektedir. Bir aktif RFID etiketi, içerisindeki veriyi iç enerji kaynağı yardımıyla oldukça uzak mesafelere iletilebilir. Ancak batarya süresi, etiketin aktif parçaları sebebiyle azalmaktadır. Böylece bu, haberleşme mesafesiyle enerji tüketimi arasında kayıp-kazanç dengesine dönüşmektedir (yani mesafe artarken, enerji tüketiminde artma veya tam tersi). Bununla birlikte iletim mesafesinin artması, girişim problemlerine de neden olabilir çünkü bir okuyucunun okuma ortamında olabilecek etiketler ve/veya okuyucular haberleşmede zorluklara zemin hazırlayabilir. ISO/IEC 18000-7 bir aktif RFID standardıdır. Bu standardın etiketleri 433 MHz frekansında çalışmaktadır. Biz fark ettik ki, bu standartta uyan aktif bir RFID etiketi, Rayleigh sönümlemeli kanalda tatmin edici bir haberleşme gerçekleştirebilmesi için oldukça fazla enerji tüketmektedir. Bu tezde ikinci olarak biz, ISO/IEC 18000-7 standardındaki aktif RFID sistemlerinin haberleşme kalitesi ve enerji verimliliği açısından performanslarını iyileştirdik. Simülasyon sonuçlarımız göstermiştir ki, gerek etiket gerekse hem etiket hem de okuyucu tarafındaki çoklu anten tasarımları, sınırlı geri besleme tekniklerinin kullanılmasıyla çerçeve hata oranlarını düşürmüş ve enerji kaynağının yaşam süresini arttırmıştır.This M.Sc. thesis is mainly two folds: First part includes the performance evaluation of passive and active RFID systems complying with ISO 18000-3 and ISO 18000-7 standards respectively. Second part shows the performance improvement of active RFID systems with multiple antennas in ISO 18000-7 standard. It also includes a detailed comparison of different limited feedback schemes for multiple antennas at tag side and both tag-reader side. Radio Frequency IDentification (RFID) has become very popular in wireless technologies and pervasively deployed in many applications area, such as contactless credit cards, e-passports, ticketing systems, access control, gaming, healthcare, pharmaceuticals, document and media management. This technology provides wireless communication with an object or someone to automatically identify or track by using radio waves. RFID systems can be grouped into three basic ranges by their using operating frequency: Low frequency (LF, 30-300 KHz), high fequency (HF 3-30MHz) and ultra high frequency (300MHz-3GHz) / microwave (>3 GHz). RFID tags and readers communicate with each other over air interface. This insecure channel and the limited capabilities of RFID tags cause security and privacy vulnerabilities. An adversary may do tag impersonating, tracking, eavesdropping, and denial of service (DoS) attack. Besides the vulnerabilities, a tag might be distinguishable in its life-span by an attacker. If it is once recognized by an adversary, it will be easily able to be traceable. At that situation, there might be two attacks. (i) An attacker might track the previous interactions of the tag or (ii) he may track the future ones. These two attacks are called backward traceability and forward traceability, respectively. There are public-key cryptography solutions in literature but none of them are convenient for the low-cost tags used in lots of applications because of their limitations. It needs to find much light-weight approaches. Therefore, many light-weight authentication protocols are proposed to have a win against the adversaries that deceive the capacity-restricted tags. A growing security and privacy concerns are most commonly related with high frequency (HF) RFID devices, using near field communication (NFC), such as contactless smart cards (CSC), because they are used to store secure and private personal information in many RFID applications: e-passport, govern ID, credit cards etc. Many researches offer different protocol designs to overcome the security and privacy problems for the standards. Although, their security and privacy analysis are quite important, their effectiveness is also another vital point for real world RFID applications/systems. Unfortunately, it is a troublesome to physically test every new protocol desings because of cost, time and it is also impractical. The performance of the protocols affects the quality of HF RFID applications. Therefore, many simulation environments have been improved to evaluate the performance of these kinds of protocols. However, none of them shows the success bounds of the protocols by considering wireless channel effect. Motivated by this need, in this thesis, firstly, we improve the PETRA simulation environment by adding two channel models, AWGN channel, Rayleigh fading channel and show the performance bounds of an RFID authentication protocol in these channels for ISO/IEC 18000-3 standard. For this purpose, we implement a secure authentication protocol in our new simulation environment to understand the effect of the wireless channel in a real life scenario. This work may guide the protocol designers to test their protocols and observe the performance of passive RFID systems before using them on real systems. We show that RFID protocols perform best performance in AWGN channel. This performance gives us the upper bound performance because the AWGN channel is an ideal case in wireless communication environment. We added the results of Petra simulation environment to evaluate the wireless channel effect. On the other hand, the performance of RFID protocols in Rayleigh fading channels gives the lower bound of the performance. The effects of the Rayleigh fading channel are extremely severe when it is compared to the AWGN channel. The FER curve is inversely linear proportional with the SNR for Rayleigh fading while it is exponentially decreasing for AWGN channel. RFID tags can also be categorized in three groups by using energy source such as passive, semi-passive and active (battery assisted) tags. Passive RFID tags do not have own internal energy source. Instead, they use the radio energy transmitted by the reader. Semi-passive and active RFID tags have their own energy source. The difference between them is that semi-passive tags do not talk first and they are powered up by the reader’s request. The energy source is used after the request. Active tags might talk to RFID reader first or answer its first request. Active RFID tags are preferred in many applications for their advantages: Visibility, security, quality and high distance communication. An active tag can transmit its data at great range by using its internal source. However, the battery life is decreased by the active parts of the tag. Hence, it causes a trade-off between communication distance and power consumption. In addition to this, the increased transmission distance might also cause interference problem because a large number of tags or multi-reader multi-tag environment within the range of a reader grounds communication difficulties. ISO/IEC 18000-7 is an active RFID standard that their tags operatea at 433 MHz. We realize that a tag consumes too much energy source to perform a satisfactory communication compliance with the standard in Rayleigh fading channel. In this thesis, secondly, we aim to ameliorate an active RFID system performance from the perspective of better communication and energy efficiency. Our simulation results show that multiple-antenna designs at tag side and tag-reader side using limited feedback schemes significantly decreases the frame error rates and increases the battery lifetime.Yüksek LisansM.Sc

Performance of Multiple-Antennas in ISO 18000-7 Standard with Using Limited Feedback Schemes

Radio Frequency Identification (RFID) is a pervasive wireless technology to automatically identify, track, and locate objects or people. RFID technology falls into three categories with respect to tags' energy source: passive, semi-passive and active. Active RFID tags are preferred in many applications for their advantages: Visibility, security, quality and high distance communication. Active RFID systems present a couple of challenges that are vital and should be overcome before enjoying their benefits. One of the most important new challenges is energy-efficient data gathering. ISO/IEC 18000-7, operating at 433 MHz, is one of the active RFID standards. We realize that a tag consumes too much energy source to perform a satisfactory communication compliance with the standard in Rayleigh fading channel. Motivated by this need, in this paper, we aim to ameliorate a RFID system performance from the perspective of better communication and energy efficiency. Detailed and extensively simulations show that using multiple antennas with limited feedback schemes significantly diminish the frame error rates and increase the battery lifetime. Moreover, we have evaluated the performance of the limited feedback schemes when the wireless channels are correlated and multiple antennas are present at the reader

Multi-RFID embedded Ticketing Kernel for MaaS

Trabalho de projeto de mestrado, Engenharia Informática (Engenharia de Software) Universidade de Lisboa, Faculdade de Ciências, 2020The fast-growing human population is causing an ever-increasing trend of hyper urbanisation and globalisation, along with the popularisation of private cars to commute, which contributes to several environmental and health problems, for instance, high lev els of noise, congestion, and pollution. Hence, most cities are facilitating and enhancing commuting travel, thus, fostering the development of transportation. Today’s urban transport networks are part of the daily lives of millions of people around the world, and in this era of digitalisation, servicising, and cashless economy the public transportation must also readjust. Therefore, contactless bank cards will make it reasonable to travel by public transport. It will be the first time in Portugal that a contactless bank card enables public transport to be accessed, travelled and charged. Such a solution would encourage the contactless debit or credit card to be an alternative to the proprietary transit card, thereby helping to enhance the usability and accessibility of public transport. With the launch of the contactless solution in public transport, a metropolitan area in Portugal will very well integrate a growing list of the world’s major cities such as London, Singapore, Rio de Janeiro and New York. Moreover, new passengers gradually shift from maintaining a private car to the use of public transport means, which allows a diminution on the emission of fuel gases, and a reduction of the global pollution. In addition to that, public transport operators pains also decrease because proprietary cards are handled and managed by financial institutions, enabling the transport agencies to turn their attention to the core of their business, like the multi-modal mass transit and fare calculation. This pioneering project in Portugal involved several stakeholders, including Card4B, Visa, and Unicre. Accordingly, the project aimed to provide an open-loop model with con tactless and post-paid payments to integrate into the existing operation of transportation ticketing. Finally, the developed solution supports contactless transactions, and followed the “Contactless Specifications for Payment Systems”. Successfully, the delivered solution was certified with an EMV Level 3 Certification for both Visa PayWave and MasterCard Contactless transactions

A Novel Long-Range Passive UHF RFID System over Twisted-pair Cable

Radio Frequency Identification (RFID) is one of the most representative, rapidly growing, and highly extendable technologies, which uses electromagnetic waves in accordance with specific communications standards and regulations to identify, track, or even localise desired objects. However, due to its high cost, limited read range, and uncertain reliability, its adoption still lags, especially in large-scale organisations. Even though an RFID distributed antenna system (DAS) can greatly improve the detection range and read rate of a single reader when system uses different combinations of antenna states with frequency and phase hopping, the lossy and heavy coaxial cables between reader and antennas still limits the system coverage and design flexibility for wide-area passive UHF RFID applications. In order to develop a cost-efficient and flexibly-installed passive RFID DAS, a novel large-range passive UHF RFID system over twisted-pair cable is proposed in this dissertation. This new system consists of one baseband central controller and one antenna subsystem, connected by a commonly used twisted-pair cable. It is shown that transmitting/receiving low frequency baseband signals over a twisted-pair cable can significantly reduce cable attenuation and extend the communication distance. A simulation is conducted to demonstrate that frequency and phase hopping can also be remotely controlled to fit this system structure by slightly varying the frequency or phase of the input reference signal of the frequency synthesis system. The features of twisted-pair cable in terms of its low cost, light weight, and bend radius greatly improve the design and installation flexibility of an RFID system. The implemented system is designed based on the ISO 18000-6C and EPC Class 1 Generation 2 standards, and can operate according to FCC (902-928 MHz) and ETSI (865-868MHz) regulations. The results of the measurement show the reader can achieve a sensitivity of - 94.5 dBm over 30 m Cat5e cable, and its sensitivity can still remain at around -94.2 dBm over 150 m Cat5e cable. The experimental results of tag detection show that the passive tags can be successfully detected over a 6 m wireless range following a 300 m of twisted-pair cable between the central controller and antenna. This detection range cannot be achieved by existing commercial RFID systems. Since the transmission and reception in a RFID system are simultaneous, finite isolation of the circulator/directional coupler and environmentally dependent reflection ratio of the antenna lead to serious leakage problems. Leakage can directly cause sensitivity degradation due to saturation of the RF components. A fast leakage suppression block is developed in efforts to solve this problem. Measurements show that this new canceller can deliver an average suppression of 36.9 dB, and this excellent performance remains when the system uses frequency hopping. With help of an improved scanning algorithm, this canceller can find its optimal status within 38 ms, and this settling time is short enough for most commercial RFID readers. By reducing the number of voltage samples taken, the convergence time can be further improved. To fully investigate this new passive UHF RFID system value, a comparison study between the new system and a commercial system is conducted. This new automatic passive UHF RFID system is confirmed to deliver high performance long-range passive tag detection. Particular advantages are shown in the fast tag read rate and capability of uplink SNR improvement. This novel system is also superior to conventional RFID systems in terms of link distance, link cost, and installation flexibility

RFID Technologies & Internet of Things

n/

Advanced Radio Frequency Identification Design and Applications

Radio Frequency Identification (RFID) is a modern wireless data transmission and reception technique for applications including automatic identification, asset tracking and security surveillance. This book focuses on the advances in RFID tag antenna and ASIC design, novel chipless RFID tag design, security protocol enhancements along with some novel applications of RFID

Ultra Low Power IEEE 802.15.4/ZIGBEE Compliant Transceiver

Low power wireless communications is the most demanding request among all wireless users. A battery life that can survive for years without being replaced, makes it realistic to implement many applications where the battery is unreachable (e.g. concrete walls) or expensive to change (e.g underground applications). IEEE 802.15.4/ZIGBEE standard is published to cover low power low cost applications, where the battery life can last for years, because of the 1% duty cycle of operation. A fully integrated 2.4GHz IEEE802.15.4 Compliant transceiver suitable for low power, low cost ZIGBEE applications is implemented. Direct conversion architecture is used in both Receiver and Transmitter, to achieve the minimum possible power and area. The chip is fabricated in a standard 0.18um CMOS technology. In the transmit mode, the transmitter chain (Modulator to PA) consumes 25mW, while in the receive mode, the iv receiver chain (LNA to Demodulator) consumes 5mW. The Integer-N Frequency Synthesizer consumes 8.5mW. Other Low power circuits are reported; A 13.56 Passive RFID tag and a low power ADC suitable for Built-In-Testing applications