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Prof. Dr. Josef Kölbl

Faculty of Applied Natural Sciences and Industrial Engineering

Professors

Professor

L 202

0991/3615-542

Sortierung:
Contribution
  • Josef Kölbl
  • Peter Sperber

Clock Distribution in SLR Stations. Proceedings of the 11th International Workshop on Laser Ranging, Volume 1 + 2.

In: Mitteilungen des Bundesamtes für Kartographie und Geodäsie. pg. 526

Frankfurt/Main

  • (1999)
Contribution
  • Peter Sperber
  • Andreas Baumgartner
  • Josef Kölbl
  • H. Tauscher
  • J. Kellner

Hochgenaues optisches Entfernungsmesssystem für industrielle Anwendungen.

In: Bericht über angewandte Forschung und Entwicklung sowie wissenschaftlichen Technologietransfer der Fachhochschule Deggendorf, 2000-2002.

  • (2002)
Lecture
  • Peter Sperber
  • T. Stautmeister
  • Andreas Baumgartner
  • Josef Kölbl
  • H. Tauscher
  • J. Kellner

High accuracy short range laser meter for system calibration and installation.

In: 13th International Workshop on Laser Ranging

Washington, DC, USA

  • 2002 (2002)
Contribution
  • Peter Sperber
  • T. Stautmeister
  • Andreas Baumgartner
  • Josef Kölbl
  • H. Tauscher
  • J. Kellner

High accuracy short range laser meter for system calibration and installation.

In: Proceedings of the 13th International Workshop on Laser Ranging, Washington, DC, USA.

  • (2002)
Contribution
  • Josef Kölbl
  • M. Fröschl
  • A. Seedsman
  • Peter Sperber

Near-Infrared Laser Range Finder, using kHz Repetition Rate.

In: SPIE Proceedings Vol. 7115. Technologies for Optical Countermeasures V, Cardiff, Wales, Großbritannien

  • (2008)

DOI: 10.1117/12.800132

show abstract

The paper deals with laser range finding (LRF) technology for tracking fast-moving objects with kHz laser repetition rates. The LRF is based on time-of-flight measurement, where a short emitting laser pulse is transmitted and its time-of-flight is accurately measured by the electronics with respect to the received impulse from a non-cooperative target. The emitted laser energy is in the near infrared wavelength region. The detector is based on a single-photon detection principle of a silicon Avalanche photodiode, operated in so-called Geiger mode. A solution was devised to utilise single photon detection even at strong daylight conditions. The LRF has been integrated in a robust and compact technology demonstrator, and has successfully ranged to rapidly-moving and accelerating small targets. A detailed mathematical model was developed to predict the ranging performance of the LRF for evolution of application-specific designs. The current technology allows ranging up to a maximum range of 1.5 km with ± 0.5 m accuracy against large stationary targets, as well as tracking of small targets of 75 mm diameter moving up to a range of 300 m with a speed resolution of ± 5 m/s. The LRF device uses a standard serial protocol for device communication and control, and operates at a temperature range from 0 °C - 55 °C.