Course Photo Technology 2

Responsible: Prof. Dr.-Ing. Gregor Fischer

Course

Meets requirements of following modules(MID)

Course Organization

Version
created 2011-12-09
VID 1
valid from WS 2012/13
valid to
Course identifiers
Long name Photo Technology 2
CID F07_PHO2
CEID (exam identifier)

Contact hours per week (SWS)
Lecture 2
Exercise (unsplit) 1
Exercise (split)
Lab 1
Project
Seminar
Tutorial(voluntary) 2
Total contact hours
Lecture 30
Exercise (unsplit) 15
Exercise (split)
Lab 15
Project
Seminar
Tutorial (voluntary) 30
Max. capacity
Exercise (unsplit)
Exercise (split) 40
Lab 18
Project
Seminar

Total effort (hours): 150

Instruction language

  • 70% German
  • 30% English

Study Level

  • Undergraduate

Prerequisites

  • tba

Textbooks, Recommended Reading

  • Allgemein
    • Pedrotti/Bausch/Schmitt, Optik für Ingenieure, Springer
    • Naumann/Schröder, Bauelemente der Optik, Hanser
    • G. Schröder, Technische Optik, Vogel
    • G. Schröder, Technische Fotografie, Vogel
  • Licht- und Beleuchtungstechnik
    • H.A.E. Keitz, Lichtberechnungen und Lichtmessungen, Philips TB
    • E. Helbig, Grundlagen der Lichtmesstechnik, Akademische Verlagsgesselschaft Geest & Portig, 1972

Instructors

  • Prof. Dr.-Ing. Gregor Fischer
  • Prof. Dr.-Ing. Dirk Poggemann

Supporting Scientific Staff

  • tba

Transcipt Entry

Photo Technology 2

Assessment

Type
wE

Total effort [hours]
wE

Frequency: 2-3/year

Course components

Lecture/Exercise

Objectives

Contents
  • Photometry
    • Radiometric, spectral and photometric measures
    • Photometric laws
    • Secondary radiators
      • Lambert radiator
      • Mirror surfaces
    • Photometric calculations
  • Radiant sources
    • Emission mechanisms
    • Spectral distribution
    • Directional characteristic
    • Temperature radiant laws
    • Color temperature and color conversion
    • Technical light sources
    • Operating laws for tungsten lamps and LEDs
  • Radiation detectors
    • Spectral sensitivity
    • Directional sensitivity
    • Radiant propagation through lens optics
    • Exposure control
  • Illuminating engineering
    • Head lamp technology
    • Light formers
    • Flash technology
    • Basics of the illumination
    • Illumination models

Acquired Skills
  • understand the physical definition of the radiometric, spectral and photometric measures
  • apply photometric laws and calculate simple illuminating set-ups
  • know the principles and technical embodiments for light generation
  • know the principles and technical embodiments for light detection
  • model the light propagation through a photographic lens and apply it to the exposure control in digital cameras
  • understand and analyse the geometric and spectral radiant flux to apply it to the illumination of a scene and to the spectral adaptation of a camera

Additional Component Assessment

Type
fPS excercise (on course and self study)

Contribution to course grade
fPS not rated

Frequency: 1/year

Lab

Objectives

Acquired Skills
  • apply photographic and illuminating measurement techniques
  • measure the directional sensitivity (detector) and the light distribution curve (source)
  • apply optical and electronic means for the spectral adaptation between light source and detector effectively

Operational Competences
  • apply measurement technique for exposure control and white balance
  • install the lighting set-up for illumination uniformity and contrast control
  • document the results

Additional Component Assessment

Type
fSC lab experiment (4h)
fTP 4 lab experiments (each 4h) per project team
oR presentation on fTP (20min per project team)

Contribution to course grade
fSC Attestation
fTP Attestation
oR prerequisite to course exam

Frequency: 1/year

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