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North America. During the tests, pages were issued to the 
Asset-Link sensors for their locations. Their locations were sent 
back to the server and instantly updated into iVCAMS3 and 
plotted onto the map. The accuracy of the location data was 
confirmed with the drivers of the cars and was high. Other 
commands, such as remote unlocking of doors, were also tested 
and were successfully received by the sensors and the correct 
operations performed. 
The total time necessary to complete all steps in paging an asset 
were also monitored during the course of tests. The times for 29 
pages are shown in Figure 2. These pages were sent to two 
assets; one asset traveling between Calgary and Edmonton 
while the second asset was in Fort Lauderdale, Florida. The 
average time for roundtrip of a page was found to be 9.25s, 
with a maximum time of 16s, which was reached by only one of 
the pages. The standard deviation was two seconds. 
Roundtrip Latency of Pages to Assets 
Latency (s) 
S 
+ 
+ 
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Figure 2. Page latencies 
4.2 System Testing 
To test the theoretical limits on the system, in terms of number 
of assets that can be supported, simulation testing was 
performed using several different computer systems acting as 
the Server. Simulation enabled precise control of variables and 
made it possible to quantify the limits of the Platform. In its 
development tools, Aeris provides software that simulates the 
Aeris AS and DS servers. This enables developers to create 
applications that are fully compatible with the Aeris protocol 
before using it with the real Aeris system. The simulated server 
is customizable and can be modified to send messages at any 
defined rate. In this way, we can simulate a different number of 
units by varying the frequency that messages are sent out by the 
simulated Aeris server. We can then determine the limitations 
of the system in terms of the number of units and assets that it 
can support, by monitoring the CPU and network bandwidth 
usage using PerfMon. These monitored attributes arc displayed 
in Figure 3. The server tested consisted of an Intel Pentium III 
933MHz system with 512MB of RAM and running the 
Microsoft Windows 2000 operating system. 
With an assumption that an asset will send a message once 
every 30s, 64 messages per second approximates to a fleet of 
about 1900 assets and 131 messages per second represents 
about 3900 assets. From the results of Figure 3, the CPU usage 
for even 3900 assets is not taxing the server, as it only ranges 
from 20% to 25%. For 1900 assets, the CPU usage is lower as 
would be expected, ranging from 7% to 15%. As for network 
bandwidth usage, the simulation results shows that this should 
not be a major concern as the usage is 15KB/s and 29KB/s for 
1900 and 3900 assets respectively and well within the limits of 
even home broadband Internet connections. 
Simulated Asset Testing 
FH oh ft fh be hd rh ng Adoni ht tr mith 
  
CPU Usage (%) 
KB/s Received 
  
o c à 
  
Time 
Figure 3. Simulated asset testing 
5. CONCLUSION 
A fully complete platform has been developed and is capable of 
addressing all major concerns in MAMS, including asset data 
acquisition, transmission and handling and analysis as well as 
unique capabilities for user access to asset data. It reduces the 
resource, time and cost needed to deploy a MAMS, thereby 
enhancing its benefits. It features a modular design separating 
the important functions of a MAMS and enables developers the 
flexibility to choose whether to use all or only certain 
capabilities of the Platform. 
This Platform was used as a basis for a real-world MAMS 
known as iVCAMS3. This system was built based on the 
requirements of industrial partners and field testing was 
conducted to ensure that the asset could send messages and 
locations back to the Office and that users could issue 
commands to the asset. Testing was completed successfully 
with vehicles with Asset-Links installed in multiple cities in 
Canada and the USA. It was possible to monitor vehicles when 
they were stationary and in motion. Roundtrip latency of 
messages was around 10s, making it possible to have real-time 
monitoring and control capabilities with assets. 
ACKNOWLEDGMENTS 
The research was supported by a NCE GEOIDE grant. 
REFERENCES 
Aeris.net, 2003. “MicroBurst Technical Details”, 
http://www.aeris.net/aeris web/products microburst technical. 
html (accessed 1 Feb. 2004) 
CSI Wireless, 2003. “Asset Management Products”, 
http://www.csi- 
wireless.com/products/documents/New AssetLink.pdf (accessed 
| Feb. 2004) 
FCC, 2003. FCC: Enhanced 911. 
http://www.fcc.gov/91 l/enhanced/ (accessed 14 Oct. 2003). 
Lee, S. and Y. Gao. ^Mobile Asset Tracking and Management 
Over the Web". Proccedings of Geodesy for Geotechnical and 
Structural Engineering. May 21-24, 2002, Berlin, Germanv. 
Peng, Z. and M. Tsou. Internet GIS — Distributed Geographic 
Information Services for the Internet and Wireless Networks. 
John Wiley & Sons, New Jersey, 2003. 
Based Services", 
Prasad, M., 2001. "Location 
http://gisdevelopment.net/technology/lbs/techlbs003pt.htm 
(accessed | Feb. 2004)