1. Mobile Networking for Smart Dust J.M. Kahn, R.H. Katz and K.S.J. Pister
Department of Electrical Engineering
and Computer Sciences
University of California, Berkeley
Berkeley, CA 94720
Supported by DARPA MTO MEMS Program
2. Outline Smart Dust
What is it?
Applications
Power Management
Delivery and Interrogation
Smart Dust Networking
Radio-frequency communication
Optical communication: passive dust mote transmitters
Optical communication: active dust mote transmitters
Summary
3. Smart Dust A dust mote is an autonomous node incorporating sensing, computing, communications and a power source in a mm3 volume
A collection of dust motes is dispersed throughout an environment
Dust motes use wireless communication to relay information to a base station over distances of 10s to 1000s of m
4. Smart Dust Mote
5. Applications of Smart Dust Civilian
Surveillance
Meteorological or geophysical monitoring
Non-invasive measurement
Measurement in hostile environments
Military
Stealthy monitoring of hostile environments
Perimeter surveillance
Chemical or biological monitoring
Identification of friend or foe
6. Power Management Sources
Solar cells
Thermopiles
Storage
Batteries ~1 J/mm3
Capacitors ~1 mJ/mm3
Usage
Digital control: nW
Analog circuitry: nJ/sample
Communication: nJ/bit
7. Delivery and Interrogation Delivery Systems
Manual
Micro air vehicle
Projectile
Wind-borne (“maple seeds”)
Interrogation
Hand-held “binoculars”
Micro air vehicle
8. Radio-Frequency Communications Pros
Long range
Line-of-sight path not required
Not severely affected by rain, fog or atmospheric turbulence
Cons
Antenna may be too large for dust motes
Requires modulator, demodulator, filtering (power consumption)
Requires complex multiplexing scheme (TDMA, FDMA, CDMA)
9. Corner-Cube Retroreflector Fabricate CCR using MEMS technology.
Light striking within about ±30° of body diagonal undergoes 3 bounces and returns to source in a narrow beam (<< 1°).
Can deflect one mirror electrostatically, modulating return beam at up to ~10 kbps.
Dust mote can transmit passively: without radiating energy and without aiming beam.
10. First-Generation Dust Mote
11. Optical Communication Using�Passive Dust Mote Transmitters
12. Optical Communication Using�Passive Dust Mote Transmitters (cont.) Requires each dust mote to have a line-of-sight path to the base station.
Uplink transmissions are multiplexed using space-division multiplexing.
13. Optical Communication Using�Passive Dust Mote Transmitters (cont.) Protocol
Dust motes are asleep.
Base station broadcasts a wakeup/query, then a periodic interrogating signal synchronized to its camera.
Dust motes wake up, transmit simultaneously to base station, synchronized to its camera.
Reliability
Dust mote positions and orientations are random, and some are not in field-of-view of base station. To insure coverage, use an excess of dust motes.
Base station is only single point of failure.
14. Optical Communication Using�Passive Dust Mote Transmitters (cont.) Pros
Dust motes need not radiate power, nor steer beam
Exploits asymmetry: powerful base station, low-power dust motes
Utilizes space-division multiplexing
Only baseband electronics are required
Cons
Requires line-of-sight path to base station
Short range (up to about 1 km)
Bit rate limited to about 10 kbps
Affected by rain, fog, atmospheric turbulence
15. Active Dust Mote Transmitter Beams should have divergence << 1ş and be steerable over a hemisphere.
16. Optical Communication Using�Active Dust Mote Transmitters Base station uses CCD or CMOS camera (up to 1 Mbps)
Using multi-hop routing, not all dust motes need to have a line-of-sight path to the base station.
17. Optical Communication Using�Active Dust Mote Transmitters (cont.) Minimizing transmitted energy/bit:
Dust mote should transmit in short bursts at high bit rate
Link Acquisition
Need protocols for dust motes to aim their directional transmitters at other nodes
Dust motes should execute raster scan using a narrow (not wide) beam
18. Optical Communication Using�Active Dust Mote Transmitters (cont.) Link Non-Reciprocity
Arises because dust motes use directional transmitters but non-directional receivers
May cause a dust mote to waste power transmitting to nodes unable to receive from it. A dust mote should transmit only to nodes that acknowledge its transmissions.
May cause collisions at dust motes during mote-to-mote communications.
Routing
How to acquire, propagate and update routing information?
19. Optical Communication Using�Active Dust Mote Transmitters (cont.) Pros
Longer range than passive links (up to about 10 km)
Higher bit rates than passive links (up to about 1 Mbps)
With multi-hop, avoids need for every dust mote to have line-of-sight path to base station
Utilizes space-division multiplexing
Only baseband electronics are required
Cons
Requires protocol to steer directional transmitters
Requires higher power than passive transmitter
Affected by rain, fog, atmospheric turbulence
20. Atmospheric Turbulence Enhancing signal detection reliability
Adaptive optics on imaging receiver
Spatial receiver diversity (multiple receivers)
Temporal receiver diversity
Maximum-likelihood sequence detection based on Markov model of scintillation process
Interleaving and forward error correction
21. Summary Smart dust motes incorporate sensing, computation, communications and power in a mm3 volume.
Free-space optical communication offers advantages in terms of size, power and network throughput.
Passive dust mote optical transmitters:
Use corner-cube retroreflector
Consume very little power
Require line-of-sight path to base station
Active dust mote optical transmitters:
Use laser and beam-steering mirror
Enable higher bit rates, longer ranges, multi-hop routing
