Akademia Górniczo-Hutnicza logotyp
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Architecture applications of Photogrammetry and TLS
Course description sheet

Basic information

Field of study
Geodesy, Surveying and Cartography
Major
Geoinformation, Photogrammetry and Remote Sensing
Organisational unit
Faculty of Geo-Data Science, Geodesy, and Environmental Engineering
Study level
Second-cycle (engineer) programme
Form of study
Full-time studies
Profile
General academic
Didactic cycle
2024/2025
Course code
DGIKGFS.IIi4.01632.24
Lecture languages
English
Mandatoriness
Elective
Block
Elective Modules in Foreign Language
Course related to scientific research
Yes
Course coordinator
Antoni Rzonca
Lecturer
Antoni Rzonca
Period
Semester 3
Method of verification of the learning outcomes
Completing the classes
Activities and hours
Project classes: 30
Number of ECTS credits
3

Goals

C1 Zapoznanie się studentów z metodami inwentaryzacji zabytków architektury wraz z przyswojeniem podstawowej wiedzy z zakresy historii architektury.

Course's learning outcomes

Code Outcomes in terms of Learning outcomes prescribed to a field of study Methods of verification
Knowledge – Student knows and understands:
W1 basical methodes, techniques, tools and materials applied to complex engineering tasks solution of photogrammetry and laser scanning. GIK2A_W05 Project
W2 an extended knowledge of acquisition, analysis, modeling and visualization of photogrammetric and laser scanning data and their changes due to natural and technological processes GIK2A_W06 Project
Skills – Student can:
U1 work in a team, The student can estimate documentation task and guide the executive team GIK2A_U05 Project
U2 assess the usefulness and usability of photogrammetry and laser scanning GIK2A_U08 Project
Social competences – Student is ready to:
K1 think and act in a creative way GIK2A_K01 Project
K2 understands the need to communicate to the public the achievements of photogrammetry and TLS in an understandable way and taking into account the various aspects of engineering GIK2A_K02 Project

Program content ensuring the achievement of the learning outcomes prescribed to the module

The course is focused on knowlegde of specialistic English vocabulary of photogrammetry and laser scanning applied for architecture documentation.

Student workload

Activity form Average amount of hours* needed to complete each activity form
Project classes 30
Preparation for classes 10
Realization of independently performed tasks 5
Contact hours 5
Preparation of project, presentation, essay, report 30
Examination or final test/colloquium 2
Student workload
Hours
82
Workload involving teacher
Hours
30

* hour means 45 minutes

Program content

No. Program content Course's learning outcomes Activities
1.

Introduction: Presentation of the rules of the project laboratories.
Presentation of photogrammetry and laser scanning technologies for architectural documentation applications. Data integration aspects. Advantages and disadvantages of the method.

 W1, W2, U1, U2, K1, K2 Project classes
2.

Photogrammetric and laser scanning project preparation for selected object inventory.: Selection of the measurement object and proper documentation product with its parameters. Proper instruments selection.

 W1, W2, U1, U2, K1, K2 Project classes
3.

Measurements in the sight.: Measurment preparation works.
Control measurements.
Taking photographs.

 W1, W2, U1, U2, K1, K2 Project classes
4.

Laboratory works: Preparation works.
Scanning project creation using proper software.
Photogrammetric project creation using proper software.
External orientation of the photogrammes and point clouds.

 W1, W2, U1, U2, K1, K2 Project classes
5.

Inventory products realisation.: DSM generation by data integration methodes.
Skaning orthophotogrammes and orthoscans generation.

 W1, W2, U1, U2, K1, K2 Project classes
6.

Test.: Test.

 W1, W2, U1, U2, K1, K2 Project classes

Extended information/Additional elements

Teaching methods and techniques :

Discussion, E-learning

Activities Methods of verification Credit conditions
Project classes Project

Conditions and the manner of completing each form of classes, including the rules of making retakes, as well as the conditions for admission to the exam

Test

Method of determining the final grade

The result of test 0.5 The project result 0.5

Manner and mode of making up for the backlog caused by a student justified absence from classes

Addictional homework

Prerequisites and additional requirements

General knowledge of photogrammetry.
Knowledge of surveying and control establishment.

Rules of participation in given classes, indicating whether student presence at the lecture is obligatory

Project classes: Studenci wykonują prace praktyczne mające na celu uzyskanie kompetencji zakładanych przez syllabus. Ocenie podlega sposób wykonania projektu oraz efekt końcowy.

Literature

Obligatory
  1. Karl Kraus "Photogrammetry,geometry from images and laser scans", second edition, Berlin 2007
Optional
  1. Luhmann, Thomas, Robson, Stuart, Kyle, Stephen and Boehm, Jan. Close-Range Photogrammetry and 3D Imaging, Berlin, Boston: De Gruyter, 2019. https://doi.org/10.1515/9783110607253

Scientific research and publications

Publications
  1. Rzonca A., 2001 – Trójwymiarowa inwentaryzacja i wizualizacja biblioteki byłego klasztoru Cystersów w Lubiążu (3D sensing and visualization of former Cistercian Abbey library in Lubiąż), M.S. Thesis, AGH, Kraków 2001.
  2. Rzonca A., 2002 – Wizualizacja biblioteki byłego klasztoru OO. Cystersów w Lubiążu (Visualization of former Cistercian Abbey library in Lubiąż), Geodezja (Geodesy), vol. 8, Zeszyt (Book) 2, Kraków 2002.
  3. Mierzwa W., Rzonca A., 2003 - Skanowanie powierzchni jako nowa metoda rejestracji i interpretacji szczegółów architektonicznych (Surface scanning as a new method of recording and interpreting architectural details), Archiwum Fotogrametrii (Photogrammetry Archive), Wroclaw 2003.
  4. Rzonca A., 2004 – Współczesne metody kompleksowej inwentaryzacji zabytków na przykładzie parafialnego kościoła w Michalicach (Modern methods of comprehensive sensing of heritage sites: Case study of the Michalice parish church), Archiwum Fotogrametrii (Photogrammetry Archive), Warszawa 2004.
  5. Rzonca A., 2006 – Integracja danych skanerowych i fotogrametrycznych dla celów inwentaryzacji architektonicznej (Scanning and photogrammetric data integration in digital architectural documentation projects), Geodezja (Geodesy), vol. 13, Zeszyt (Book) 1, Kraków 2006.
  6. Boroń A., Rzonca A., Wróbel A., 2007 - Metody fotogrametrii cyfrowej i skanowania laserowego w inwentaryzacji zabytków (Digital photogrammetry and laser scanning methods for heritage site documentation), Geoinformatica Polonica, Kraków 2007.
  7. Mitka B., Rzonca A., 2009 - Integration of photogrammetric and 3D laser scanning data as a flexible and effective approach to heritage site documentation, International Archives Of Photogrammetry, Remote Sensing And Spatial Information Sciences, Vol. XXXVIII-5/W1, Trento 2009.
  8. Rzonca A., 2013 - Integracja danych pozyskiwanych metodami fotogrametrycznymi i skanowania laserowego przy inwentaryzacji obiektów zabytkowych Integration of photogrammetric and 3D laser scanning data for monumental objects documentation - Monography, Wydawnictwo AGH, Kraków 2013.
  9. Gabor K., Rzonca A., 2014 - Development of a system for monitoring of technical condition of a historical site on the example of barracks in the former Auschwitz-Birkenau camp - Opracowanie systemu monitoringu obrazowego stanu technicznego obiektu zabytkowego na przykładzie baraków byłego obozu Auschwitz-Birkenau. Pomiary, Automatyka, Kontrola. 2014 vol. 60 nr 2, s. 122-125.