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Cooperative Localization

Kooperative Lokalisierung

Sebastian Papierok

Delphi Deutschland GmbH

Content

Motivation

Basic Working Principle

System Overview

Results

Conclusions

18.09.2013 Cooperative Localization 2

Motivation

• The exchange of perception data is useless without a

‚precise‘ and inexpensive positioning system

• Precise positioning systems contribute to safety

Why Relative Positioning?

Global Coordinates

Why Relative Positioning?

Relative Coordinates

Working Principle

GPS Error Sources

Satellite position, satellite clock, and receiver clock error

Ionospheric, tropospheric, and multipath effects

Other errors

Normal GPS

Error Sources

Working Principle

GPS Error Sources

Satellite position, satellite clock, and receiver clock error

Ionospheric, tropospheric, and multipath effects

Other errors

Normal GPS Cooperative Localization

Error Sources Error Sources

Message: Correlated errors have low impact in

relative coordinates

Working Principle

Direct difference of two positions

• Satellites for estimation unknown

• Fuse output of different algorithms?

• Impact on relative error?

Cooperative Localization 8 18.09.2013

Working Principle

Low level sensor data fusion

• Exchange of GPS raw data

between the vehicles

• Determine common satellites

• Process pseudorange measurements

• Calculate satellite positions

• Estimate GPS position

• Calculate relative vector

• Data fusion with other data

(e.g. velocity, yaw rate)

System Overview

Navigation Data

• Satellite orbit information

Observation Data

• Receiver sampling time

• Satellite number

• Carrier-phase measurement

• Pseudorange measurement

• Doppler measurement

• Signal strength

Vehicles equipped with

Raw data GPS, GPS ground truth, V2V communication

Hardware Testsetup

Cooperative

Localization CLM CLM

Results

GPS Position A

GPS Position B

Model A

Model B

Model B + relative Vector

t=9 t=14

51.23551.2355 51.23651.2365

7.1585

7.1595

7.1605

51.23551.2355 51.23651.2365 51.23751.2375 51.2387.1575

7.1585

7.1595

7.1605

Results

GPS Position A

GPS Position B

Model A

Model B

Model B + relative Vector

Conclusions

Innovations

• Usage of raw data GPS receivers

• Exchange of GPS raw data via V2V communication

• Elimination of systematical errors

Challenges

• Complex hardware architecture

• Synchronisation

• Effective information transfer

Future Directions

• Test different fusion algorithms

Thank You

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