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A VLSI Implementation of Low Power, Low Data Rate UWB Transceiver for Location and Tracking Applications

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Abstract

A low power, low data rate ultra wideband (UWB) impulse radio transceiver for location and tracking applications is presented in this paper. The UWB receiver is based on a non-coherent, energy collection approach, which makes the receiver highly independent of the shape of the transmitted waveform. The UWB signal is generated by a pulse generator and band-pass filter fixing the signal bandwidth to 1 GHz in the band from 3.1 GHz to 4.1 GHz. The modulation scheme used in this time division multiple access system (TDMA) is Binary Pulse Position Modulation (BPPM). In this paper the system concept, system architecture and RF parts of the VLSI implementation are peresented. The transceiver is implemented in a 0.35 μm SiGe process provided by Austria Microsystems.

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References

  1. I. Oppermann, M. Hamalainen and J. Iinatti, UWB Theory and Applications, John Wiley & Sons Inc., 2004.

  2. FCC, Federal Communications Commission, “First Report and Order,” in FCC 02-48, April 2002.

  3. A. Rabbachin, L. Stoica, S. Tiuraniemi and I. Oppermann, “A Low Cost, Low Power UWB Based Sensor Network,” International Workshop on Wireless Ad-Hoc Networks (IWWAN), Finland, 2004.

  4. A. Rabbachin and I. Oppermann, “Synchronization Analysis for UWB Systems with a Low-Complexity Energy Collection Receiver,” International Workshop on UWB (IWUWBS) Joint with Conference on UWB Systems and Technologies (UWBST)-(Joint UWBST & IWUWBS'04), Japan, 2004.

  5. A. Rabbachin, R. Tesi and I. Oppermann, “Bit Error Rate Analysis for UWB Systems with a Low-Complexity, Non-Coherent Energy Collection Receiver,” IEEE International Symposium on Telecommuniactions, (IST'04), vol. 2, France, 2004.

  6. S. Tiuraniemi “A CMOS Pulse Generator Design for TH-PPM UWB System,” Finnish Wireless Communications Workshop (FWCW'03), Finland, 2003.

  7. L. Stoica, H. Repo, S. Tiuraniemi, A. Rabbachin and I. Oppermann, “A Low Complexity UWB Circuit Transceiver Architecture for Low Cost Sensor Tag Systems,” IEEE 15th Symposium on Personal Indoor Mobile Radio Communications (PIMRC'04), Spain, September 2004.

  8. B. Gilbert “A Precise Four-Quadrant Multiplier with Subnanosecond Response,” IEEE Journal of Solid State Circuits, vol. SC-3, No. 6, December 1968.

  9. A. Ismail and A. Abidi, “A 3-10 GHz Low-Noise Amplifier With Wideband LC-Ladder Matching Network,” IEEE Journal of Solid-State Citcuits, vol. 39, No. 12, December 2004.

  10. S.-W. Chung, S.-Y. Lee and K.-H. Park “Wideband Impedance Matching of Integrated Antennas and CMOS Low Noise Amplifiers for a Multi-Band UWB Receiver,” IEEE Radio and Wireless Conference, September 2004.

  11. F. Lee, D. Wentzloff and A. Chandrakasan, “An Ultra-Wideband Baseband Front-End,” IEEE Radio Frequency Integrated Circuits Symposium, 2004.

  12. I. Oppermann, L. Stoica, A. Rabbachin, Z. Shelby and J. Haapola, “UWB wireless sensor networks: Uwen–-a Practical Example,” IEEE Commun. Mag., vol. 42, December 2004.

  13. R. Fontana, E. Richley and J. Barney, “Commercialization of an Ultra Wideband Precision Asset Location System,” (IEEE) Conference on Ultra Wideband Systems and Technology, (UWBST'03), USA, November 2003.

  14. J. G. Proakis Digital Communications, McGraw-Hill Co., 1995.

  15. J. Foerster and Q. Li, “UWB Channel Modelling Contribution from Intel,” in IEEE P.802.15-02/279-SG3a, 2002.

  16. A. Wyszynski, R. Schaumann, S. Szczepanski and P. Van Halen, “Design of a 2.7-GHz Linear OTA and a 250-MHz Elliptic Filter in Bipolar Transistor-Array Technology,” IEEE Transactions on Circuits and Systems - II: Analog and Digital Signal Processing, vol. 40, NO. 1, January 1993.

  17. V. Vintola, M. Matilainen, S. Kalajo and E. Jarvinen, “Variable-Gain Power Amplifier for Mobile WCDMA Appliactions,” IEEE Transactions on Microwave Theory and Techniques, vol. 49, NO. 12, December 2001.

  18. K.W. Kobayashi, K.T. Ip, A.K. Oki, D.K. Umemoto, S. Claxton, M. Pope and J. Wiltz, “GaAs HBT 0.75-5-GHz multifunctional microwave-analog variable gain amplifier,” IEEE Journal of Solid State Circuits, vol. 29, October 1994.

  19. R.G. Meyer and W.D. Mack, “A DC to 1-GHz differential monolithic variable-gain amplifier,” IEEE Journal of Solis State Circuits, vol. 26, November 1991.

  20. L.W. Couch II, Digital and Analog Communication Systems, Macmillan Publishing Co., Inc., 1983.

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Authors and Affiliations

  1. Centre for Wireless Communications, University of OULU, P.O. Box 4500, FIN-90014

    Sakari Tiuraniemi, Lucian Stoica, Alberto Rabbachin & Ian Oppermann

Authors
  1. Sakari Tiuraniemi
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  2. Lucian Stoica
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  3. Alberto Rabbachin
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  4. Ian Oppermann
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Corresponding author

Correspondence to Sakari Tiuraniemi.

Additional information

Sakari Tiuraniemi was born in Kolari, Finland, on March 10, 1977. He received his M.Sc. degree in 2003 in electrical engineering from the University of Oulu, Finland, where he then continued his research on transceiver integration and implementation issues for two years. In 2005 he joined the CERN in Geneva, Switzerland, where he is working towards the PhD degree in electrical engineering. His current research focuses on detector readout electronics for high energy physics applications.

Lucian Stoica was born in Roman, Romania, on December 8, 1975. He received the M.S. degree in electrical engineering from the Technical University of Iasi, Romania, in 2000. He was with Telecommunications Department at the Technical University of Iasi from 2000 to 2003. As a teaching assistant he was involved in development of digital design and FPGA prototyping. In 2003, he joined Centre for Wireless Communications, University of Oulu, Oulu, Finland where he is working towards the PhD degree in electrical engineering. His current research focuses on low complexity SiGe BiCMOS circuit transceivers design for wireless communications, particularly on ultrawideband impulse radio systems.

Alberto Rabbachin received the M.S. from the University of Bologna, Italy, in 2001. In 2001, during his undergraduate studies, he visited the Centre for Wireless Communications, University of Oulu, Finland. In 2002 he joined Agilent Technologies for an internship and since 2003 he is working towards the PhD degree at the Centre for Wireless Communications. His research interests include UWB systems with emphasis on receiver structures, synchronization and ranging techniques.

Ian Oppermann was born in Maryborough, Australia, in 1969. He completed a BSc, BE and PhD at the University of Sydney Australia in 1990, 1992 and 1997, respectively. His PhD was related to physical layer aspects of novel spread spectrum/CDMA systems. In 1996 he founded SP Communications, a company which developed network planning tools for 3G mobile systems and IP cores for WLAN chipsets. He became a Docent (Adjunct Professor) at the University of Oulu, Finland in 2001 and subsequently joined the Centre for Wireless Communications (CWC) in 2002 as Assistant Director, becoming Director in 2003. From the beginning of 2005 is the acting Director for Short Range Communications Research at CWC. His main research interests are spread spectrum systems and UWB. Dr. Oppermann has co-edited several books, holds several patents for wireless communications and has over 80 publications in international journals and conferences.

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Tiuraniemi, S., Stoica, L., Rabbachin, A. et al. A VLSI Implementation of Low Power, Low Data Rate UWB Transceiver for Location and Tracking Applications. J VLSI Sign Process Syst Sign Image Video Technol 43, 43–58 (2006). https://doi.org/10.1007/s11265-006-7279-x

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  • DOI: https://doi.org/10.1007/s11265-006-7279-x

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