U ltra W ide B and Wireless Communications

1. Department of Computer Science & Engineering University of California, Riverside Ultra Wide Band Wireless Communications Ioannis Broustis March 23rd, 2004

2. Motivation • Current wireless solutions (IEEE 802.11, Bluetooth…) face some of the following problems: • Limited channel capacity • High power consumption • Multipath fading

3. Why UWB? • Advantages: • Low-power operation. • Low cost. • Low probability of detection and low probability of jamming capabilities. • Low interference levels to existing services. • Higher immunity to multi-path fading effects. • Ability to penetrate walls, etc. • Availability of precise location information.

4. What are we trying to do… • There are no sufficient solutions for the MAC layer. • Limited previous work exists for UWB based ad hoc networks. • We will address the problem of a suitable MAC protocol for UWB ad hoc wireless networks.

5. Roadmap • UWB definition and applications • Possible PHY layer implementations • MAC principles • Previous Work on MAC layer • Conclusions

6. UWB: What is it? • Any signal that: • Occupies at least 500MHz of BW, or • More than 25% of a center frequency: • Wireless Personal Area Networks (WPANs) • FCC allocates 7,500 MHz in the 3.1 to 10.6 GHz band.

7. UWB Applications • Stream DVD content to HDTVs simultaneously. • Wirelessly synchronize appliance clocks. • Connect high-data rate peripherals. • Move huge files between digital cameras, camcorders, and computers. • Military applications (radars, penetrate walls, etc.)

8. What makes UWB so interesting? • Manufacturers are still jumping on the UWB band wagon even with the frequency and power restrictions. • Why? Let an old friend explain: Shannon’s theorem:

9. PHY: Single-Band and Multi-Band • Single-Band Implementation • One pulse occupies the whole BW. • Multi-Band Implementation • The 7.5GHz are divided into multiple bands. • Information is independently encoded in the different bands. • The lower limit of 500MHz must be maintained.

10. Single-Band and Multi-Band

11. Single-Band and Multi-Band Multi-band signals transmitted at different discrete times. The sequence repeats at each symbol. Center frequencies are shown in the vertical axis.

12. Adaptive band selection  Avoids interference. Low complexity Smaller transceiver cost. Low circuit frequency  Power conservation. Why prefer Multi-Band ? Sacrifice one band for co-existence

13. IEEE 802.15.3a Requirements

14. MAC Principles • Two main aspects: • Intra-WPAN interference • Polling schemes (master/slave) • CSMA • CDMA • TDMA • A new idea... • Inter-WPAN interference • Time Hopping Spread Spectrum techniques.

15. UWB ad-hoc MAC - Previous Work • [1] Jin Ding, Li Zhao, Sirisha Medidi and K. M. Sivalingam, "MAC Protocols for Ultra-Wide-Band Wireless Networks: Impact of Channel Acquisition Time", in SPIE ITCOM Conf. 4869, Boston, July 2002. • The channel acquisition time is large enough and prohibits CSMA or TDMA approaches: TDMA CSMA-CA

16. UWB ad-hoc MAC - Previous Work • [2] H. Yomo, P. Popovski, C. Wijting, I. Z. Kovacs, N. Deblauwe, A. F. Baena, and R. Prasad, "Medium Access Techniques in Ultra-wideband Ad Hoc Networks", the 6th national conference of ETAI, 2003 September, 2003, Ohrid, Skopia. • They examine the Inter-WPAN interference approach of the MAC layer. • “The only way to control this kind of interference is to determine appropriate values for some Time-Hopping pattern parameters”.

17. UWB ad-hoc MAC - Previous Work • [3] Jean-Yves Le Boudec, Ruben Merz, Bozidar Radunovic, Joerg Widmer, “A MAC protocol for UWB very low power mobile ad-hoc networks based on dynamic channel coding with interference mitigation”, EPFL Technical Report ID: IC/2004/02 • It is the 1st ad hoc MAC with Dynamic Channel Coding. • Time-Hopping for Inter-WPAN interference. • Schemes for: • Interference mitigation. • Synchronization between transmitter and receiver. • Dynamic channel coding with incremental redundancy. • “Private MAC”: Enforce that several senders cannot communicate simultaneously with one destination. 

18. UWB ad-hoc MAC - Previous Work • PRIVATE MAC: • Request  Response  Data Ack. • The request is sent to the receiver’s THS (Time-Hopping sequence). • Response, Data and Ack are transmitted using a common Sender-Receiver THS. • If no feedback is received, the sender will re-transmit after a random backoff.

19. UWB ad-hoc MAC - Previous Work PRIVATE MAC(contd.) • Assume that B is transmitting to A. • An interfering node C will send a request to A and will wait listening to A’s THS. • After the end of a successful transmission, A & B issue a beacon to their THS to inform other nodes that they are idle. • If multiple nodes wait for A, they start counting a backoff timer as soon as they hear the beacon. • With a proper synchronization scheme, collisions are avoided.

20. Conclusions • UWB is an excellent solution for high-speed WPANs • Many times the maximum required data rate • Power efficiency and no multi-path fading. • The Multi-Band approach provides with even more advantages. • A lot of work has been done in PHY. • Upper layers must be examined in detail. • Above MAC, nothing has been proposed.

21. Questions?(References available upon request) General Atomics Multi-Band Transceiver Prototype