05 Positioning systems Flashcards
1
Q
List applications of GPS
A
- Navigation system
- Cooperative systems (many different)
- Road curvature estimation (e.g. overtaking support)
- Intersection support
- Test-track experiments (high price OK)
- Automated vehicles
2
Q
Describe the principles of GPS
A
- 24 (+6) satellites
- ~20 000km orbit
- 3 ns time accuracy
- Exact positioning of satellites
- GPS-units – triangulates position with satellites.
- Several sources of error
- Differential GPS –increased accuracy
3
Q
Describe and reflect on main GPS issues
A
- Ionospheric Propagation Errors: Wave propagation. Error:1 m at night to 5-15 m daytime
- Tropospheric Propagation Errors: 2.5 m in the zenith direction to 10-15 m at low satellite elevation angles.
- The Multipath Problem: Dominant source of error in differential positioning. For example “Bouncing of buildings”
- Ephemeris Data Errors: Error <1m. Removed with DGPS
- Onboard Clock Errors: Error <1m. Removed with DGPS
4
Q
Understand how to “talk” to a GPS unit
A
- National Marine Electronics Association
- Standard 4800bits/s over RS-232
- Build-up:
– Starts with ‘$‘, ends with a CR/LF
– Maximum 80 characters
– Single line with data items separated by commas
– Data in ASCII text
5
Q
Map projections
A
WGS84
– “Standard” worldwide longitude/latitude
– Center in middle of earth
– Not very easy to convert to meters “on paper”
RT90
– Rikets Triangelnät
(Sverige) - SWEREF 99.
– In meters
* X increases to north
* Y increases to east
– Example (Göteborg): X=6404510
Y=1271140
6
Q
Map Matching
A
- Finding the “correct” road from positioning information and extract attributes
- Attribute examples:
– Road type
– Speed limit
– Number of lanes
– Distance to intersection
7
Q
SLAM - Simultaneous localization
and mapping
A
- Building a map of the surrounding while keeping track of where the ”agent” is in the map.
- Building the map as the vehicle moves forward
*Extension: using previous maps/information (e.g., static objects locations)
