Photo: San Onofre Nuclear Generating Station

About This Presentation

Title:

Photo: San Onofre Nuclear Generating Station

Description:

Title: San Onofre Nuclear Generating Station Author: Valued Sony Customer Last modified by: culler Created Date: 11/11/2002 5:30:54 PM Document presentation format – PowerPoint PPT presentation

Number of Views:48

Avg rating:3.0/5.0

Slides: 15

Provided by: Valued310

Learn more at: https://people.eecs.berkeley.edu

Category:

more less

Transcript and Presenter's Notes

Title: Photo: San Onofre Nuclear Generating Station

1
Photo San Onofre Nuclear Generating Station
Radio Channel Quality inIndustrial Sensor
Networks
Daniel Sexton, Jay WerbSICon 05February 9th 2005
2
(No Transcript)
3
Generic Mesh Network Features

Bi-directional ? Acknowledgements and commands
Multi-hop ? Extend solutions and resiliency
Self-healing ? Reliable and flexible
Standards ? IEEE 802.15.4
Secure ? Symmetric link to link encryption

4
Anatomy of an installed system
Bridge nodes interface the sensor network to the
IP world
Mesh nodes form a reliable backbone for routing
sensor data
Sensors connect to end nodes to access the network
5
Value Proposition
? 25.61C
Motor Replaced
6
IEEE 802.15.4Standard

Desirable features
250 kbps ? Flexibility, low duty cycle
2.4 GHz ? International
Lightweight MAC ? low complexity
Simple ASIC ? many sources ? low cost
Network Security
But will it work in a harsh factory environment?

7
Does the promise match the reality?

Research focuses on radio reliability in
factories
Channel fading multipath
Channel coherence
Radio performance
In simulation
On the wire
Statistical lost packets in factories
Will channel diversity help?

8
Channel Fading

Multipath effects
Varies by position
Varies by frequency
Varies over time
Overcome with diversity
Path diversity
Costs more routing nodes
Frequency diversity
Free with certain protocols

9
Fading Factors
Path Loss L(dB) 40 10NLogD L path loss at
2.4GHz D distance in meters NExponential Path
Loss Factor N2 for free space Observed values of
N 1.3ltNlt3.7 Factors Building Construction,
Channel Obstructions
This equation represents a single static channel
L(dB) 40 10Ne LogD Ne Value based on
installation type
Large ScaleL(dB) 40 10Ne LogD Ll LlRV
based on loss from Obstructions (Walls, Doors,
Ceilings) Ll usually a log normal distribution
from installations of same type
Small Scale L(dB) 40 10NeLogD Ls Ll Ls
RV based on measured Channel Characteristics Bot
h in time and space (Rayleigh, Rician, Nakagami,
etc).
The better we characterize Ne the less variance
in Ll
10
Frequency Diversity In situ experiment
11
Diversity Gains
NLOS Channel Rayleigh Faded
Methods to Obtain Diversity Gain (Small Scale)

Frequency Diversity (Greater than Coherence
Bandwidth)
Good Margin for fading and interference
Path Diversity (Greater than 1 wave length)
Good Margin for fading, some for interference
Time Diversity (Greater than Coherence Time)
Good Margin for interference, some for fading

We use all Three Need to quantify Large Scale
Diversity Gain
12
Power Level

How much power is enough?
1 mW (0 dBm) is typical power level for 802.15.4
Not enough for target 100 meter range
Especially when no line of sight available
Interference from Bluetooth and WiFi
Need similar power level to be heard
Supporting tests and simulations to be published
Regulatory limits
36 dBm in US 20 dBm in Europe (FH) 10 dBm some
countries
Transmitter energy consumption
Transmitter percentage 35 at 15 dBm inflection
point
Tested at 15 dBm
Seems about right more field experience needed

13
Covering the Bases
Static Multipath Time VariantMultipath StaticInterference(e.g. Microwave) Time VariantInterference(Other Networks)
Spatial Diversity(Mesh Routing) ? ? ? ?
Frequency Diversity (Channel Hopping) ? ? ? ?
Temporal Diversity(Retries) ? ? ? ?
Transmit Power(15 dBm) ? ? ? ?
Overall Risk Coverage ? ? ? ?