NFC+: Breaking NFC Networking Limits through Resonance Engineering

Current UHF RFID systems suffer from two long-standing problems: 1) miss-reading non-line-of-sight or misoriented tags and 2) cross-reading undesired, distant tags due to multi-path reflections. This paper proposes a novel system, NFC+, to overcome the fundamental challenges. NFC+ is a magnetic field reader, which can inventory standard NFC tagged objects with a reasonably long range and arbitrary orientation. NFC+ achieves this by leveraging physical and algorithmic techniques based on magnetic resonance engineering. We build a prototype of NFC+ and conduct extensive evaluations in a logistic network. Comparing to UHF RFID, we find that NFC+ can reduce the miss-reading rate from 23% to 0.03%, and cross-reading rate from 42% to 0, for randomly oriented objects. NFC+ demonstrates high robustness for RFID unfriendly media (e.g., water bottles and metal cans). It can reliably read commercial NFC tags at a distance of up to 3 meters which, for the first time, enables NFC to be directly applied to practical logistics network applications.

[1]  Thomas H. Lee,et al.  The Design of CMOS Radio-Frequency Integrated Circuits: RF CIRCUITS THROUGH THE AGES , 2003 .

[2]  D. Deavours UHF EPC tag performance evaluation , 2005 .

[3]  Andrew S. Tanenbaum,et al.  A Platform for RFID Security and Privacy Administration (Awarded Best Paper!) , 2006, LISA.

[4]  Sozo Inoue,et al.  Systematic error detection for RFID reliability , 2006, First International Conference on Availability, Reliability and Security (ARES'06).

[5]  Diana Twede,et al.  Radio frequency identification (RFID) performance: the effect of tag orientation and package contents , 2006 .

[6]  V. Potdar,et al.  Improving RFID Read Rate Reliability by a Systematic Error Detection Approach , 2007, 2007 1st Annual RFID Eurasia.

[7]  Chimay J. Anumba,et al.  Radio-Frequency Identification (RFID) applications: A brief introduction , 2007, Adv. Eng. Informatics.

[8]  M. Soljačić,et al.  Wireless Power Transfer via Strongly Coupled Magnetic Resonances , 2007, Science.

[9]  ヒュプナー・ブルクハルト Apparatus for transmitting electrical energy , 2009 .

[10]  R. Fish,et al.  Conduction of Electrical Current to and Through the Human Body: A Review , 2009, Eplasty.

[11]  Jenshan Lin,et al.  A Loosely Coupled Planar Wireless Power System for Multiple Receivers , 2009, IEEE Transactions on Industrial Electronics.

[12]  Ani Nahapetian,et al.  Mobile Computing, Applications, and Services , 2011, Lecture Notes of the Institute for Computer Sciences, Social Informatics and Telecommunications Engineering.

[13]  C. A. Fernandes,et al.  RFID Reader Antennas for Tag Detection in Self-Confined Volumes at UHF , 2011, IEEE Antennas and Propagation Magazine.

[14]  KatabiDina,et al.  Efficient and reliable low-power backscatter networks , 2012 .

[15]  Klaus Finkenzeller,et al.  Theoretical Limits of ISO/IEC 14443 type A RFID Eavesdropping Attacks , 2012 .

[16]  Sangman Moh,et al.  NFC and its application to mobile payment: Overview and comparison , 2012, 2012 8th International Conference on Information Science and Digital Content Technology (ICIDT2012).

[17]  Deepak Ganesan,et al.  BLINK: a high throughput link layer for backscatter communication , 2012, MobiSys '12.

[18]  Piotr Indyk,et al.  Efficient and reliable low-power backscatter networks , 2012, CCRV.

[19]  Sachin Katti,et al.  Full duplex radios , 2013, SIGCOMM.

[20]  David Wetherall,et al.  Ambient backscatter: wireless communication out of thin air , 2013, SIGCOMM.

[21]  Ian F. Akyildiz,et al.  Beamforming for Magnetic Induction Based Wireless Power Transfer Systems with Multiple Receivers , 2014, 2015 IEEE Global Communications Conference (GLOBECOM).

[22]  Dina Katabi,et al.  Magnetic MIMO: how to charge your phone in your pocket , 2014, MobiCom.

[23]  Byungje Lee,et al.  NFC Antenna Design for Low-Permeability Ferromagnetic Material , 2014, IEEE Antennas and Wireless Propagation Letters.

[24]  Dina Katabi,et al.  RF-IDraw: virtual touch screen in the air using RF signals , 2014, S3 '14.

[25]  Lei Yang,et al.  Tagoram: real-time tracking of mobile RFID tags to high precision using COTS devices , 2014, MobiCom.

[26]  Petar M. Djuric,et al.  Proximity Detection with RFID: A Step Toward the Internet of Things , 2015, IEEE Pervasive Computing.

[27]  Lixin Shi,et al.  Wireless Power Hotspot that Charges All of Your Devices , 2015, MobiCom.

[28]  Mohammad Rostami,et al.  Enabling Practical Backscatter Communication for On-body Sensors , 2016, SIGCOMM.

[29]  Alanson P. Sample,et al.  High-Q, over-coupled tuning for near-field RFID systems , 2016, 2016 IEEE International Conference on RFID (RFID).

[30]  Samuel J. Ling,et al.  Magnetic Field of a Current Loop , 2016 .

[31]  Longfei Shangguan,et al.  The Design and Implementation of a Mobile RFID Tag Sorting Robot , 2016, MobiSys.

[32]  Fadel Adib,et al.  Drone Relays for Battery-Free Networks , 2017, SIGCOMM.

[33]  Y. Levron,et al.  MAGNETIC INDUCTION ANTENNA ARRAYS FOR MIMO AND MULTIPLE-FREQUENCY COMMUNICATION SYSTEMS , 2017 .

[34]  Fadel Adib,et al.  Minding the Billions: Ultra-wideband Localization for Deployed RFID Tags , 2017, MobiCom.

[35]  Xinyu Zhang,et al.  Gyro in the air: tracking 3D orientation of batteryless internet-of-things , 2016, MobiCom.

[36]  Omid Salehi-Abari,et al.  In-body backscatter communication and localization , 2018, SIGCOMM.

[37]  Fadel Adib,et al.  Enabling deep-tissue networking for miniature medical devices , 2018, SIGCOMM.

[38]  Swarun Kumar,et al.  Pushing the Range Limits of Commercial Passive RFIDs , 2019, NSDI.

[39]  Omid Salehi-Abari,et al.  Are RFID Sensing Systems Ready for the Real World? , 2019, MobiSys.

[40]  Renjie Zhao,et al.  M-Cube: a millimeter-wave massive MIMO software radio , 2020, MobiCom.