3D Surveys in Construction
BASIC DATA
course listing
A - main register
course code
EAT0001
course title in Estonian
3D mõõdistamine ehituses
course title in English
3D Surveys in Construction
course volume CP
-
ECTS credits
3.00
to be declared
yes
fully online course
not
assessment form
Pass/fail assessment
teaching semester
spring
language of instruction
Estonian
English
Study programmes that contain the course
code of the study programme version
course compulsory
no
Structural units teaching the course
EA - Department of Civil Engineering and Architecture
Timetable link
Version:
VERSION SPECIFIC DATA
course aims in Estonian
Õppeaine eesmärk on anda ülevaade ja praktilised oskused:
- kaasaegsete massandmehõive seadmete käsitsemiseks ehitiste 3D mõõdistamisel;
- 3D mõõteandmete esmasest töötlemisest ja täpsushinnangu võimalustest.
- kaasaegsete massandmehõive seadmete käsitsemiseks ehitiste 3D mõõdistamisel;
- 3D mõõteandmete esmasest töötlemisest ja täpsushinnangu võimalustest.
course aims in English
The aim of this course is to provide an overview and practical skills for:
- handling modern mass data acquisition devices in 3D surveying of buildings;
- the primary processing of 3D survey data and the possibilities of accuracy assessment.
- handling modern mass data acquisition devices in 3D surveying of buildings;
- the primary processing of 3D survey data and the possibilities of accuracy assessment.
learning outcomes in the course in Est.
Õppeaine läbinud üliõpilane:
- teab ehitiste 3D mõõdistamise teoreetilisi aluseid ja nende erinevaid liike, sh terrestriline, mobiilne ja aerolaserskaneerimine (TLS, MLS ja ALS), aga ka drooni-fotogramm-meetria;
- valib erinevate ehitiste mõõdistamiseks sobiva mõõdistusliigi ja seadmed;
- valib eriliigiliste ehitiste mõõdistamiseks optimaalsemad asukohad, mis võimaldavad tagada nõutud täpsuse ning mõõdistusandmete piisava ülekatte ja kontrollitavuse;
- rakendab ehitiste ja tehnokommunikatsioonide mõõdistamiseks elektrontahhümeetrit, käsilaser-kaugusmõõtjat, terrestrilist ning kaasaskantavat laserskännerit.
- teab ehitiste 3D mõõdistamise teoreetilisi aluseid ja nende erinevaid liike, sh terrestriline, mobiilne ja aerolaserskaneerimine (TLS, MLS ja ALS), aga ka drooni-fotogramm-meetria;
- valib erinevate ehitiste mõõdistamiseks sobiva mõõdistusliigi ja seadmed;
- valib eriliigiliste ehitiste mõõdistamiseks optimaalsemad asukohad, mis võimaldavad tagada nõutud täpsuse ning mõõdistusandmete piisava ülekatte ja kontrollitavuse;
- rakendab ehitiste ja tehnokommunikatsioonide mõõdistamiseks elektrontahhümeetrit, käsilaser-kaugusmõõtjat, terrestrilist ning kaasaskantavat laserskännerit.
learning outcomes in the course in Eng.
After completing this course the student:
- knows the theoretical foundations of 3D surveying of buildings of different types, including terrestrial, mobile and airborne laser scanning (TLS, MLS and ALS), as well as drone photogrammetry;
- chooses the appropriate surveying type and equipment for surveying different buildings;
- chooses the most optimal locations for surveying different types of buildings, which allow ensuring the required accuracy and sufficient overlap and controllability of survey data;
- uses an electronic total station, a handheld laser rangefinder, a terrestrial and portable laser scanner for surveying buildings and utilities.
- knows the theoretical foundations of 3D surveying of buildings of different types, including terrestrial, mobile and airborne laser scanning (TLS, MLS and ALS), as well as drone photogrammetry;
- chooses the appropriate surveying type and equipment for surveying different buildings;
- chooses the most optimal locations for surveying different types of buildings, which allow ensuring the required accuracy and sufficient overlap and controllability of survey data;
- uses an electronic total station, a handheld laser rangefinder, a terrestrial and portable laser scanner for surveying buildings and utilities.
brief description of the course in Estonian
Ruumiandmete 3D massandmehõive alused. Erinevate mõõdistusseademet käsitsemine, mh. elektron-tahhümeetrid, terrestrilised ja kaasaskantavad laserskännerid. Punktipilvede georefereerimine. Mõõteandmete esmane töötlemine ja tasandamine.
Laboratoorsed praktikumid (meeskonnatööna):
1. Ehitise gabariitide ja fassaadielementide mõõtmine elektrontahhümeetriga, kasutades vajadusel vastavat juhendit;
2. Väiksemapoolse hoone välisperimeetri terrestriline laserskaneerimine;
3. Laserskaneerimise mõõdistusandmete georefereerimine ning esmane täpsushinnang, mõõdistusandmetest 3D punktipilve moodustamine;
4. Digitaalse elektrontahhümeetriga moodustatud punktipilve kontrollmõõdistus;
5. Siseruumi 3D mõõdistamine kaasaskantava mobiilse laserskänneriga, kontrollmõõtmised käsilaser- kaugusmõõtjaga;
6. Tehnokommunikatsioonide laserskaneerimine iPad-iga, fotorealistliku punktipilve moodustamine.
Laboratoorsed praktikumid (meeskonnatööna):
1. Ehitise gabariitide ja fassaadielementide mõõtmine elektrontahhümeetriga, kasutades vajadusel vastavat juhendit;
2. Väiksemapoolse hoone välisperimeetri terrestriline laserskaneerimine;
3. Laserskaneerimise mõõdistusandmete georefereerimine ning esmane täpsushinnang, mõõdistusandmetest 3D punktipilve moodustamine;
4. Digitaalse elektrontahhümeetriga moodustatud punktipilve kontrollmõõdistus;
5. Siseruumi 3D mõõdistamine kaasaskantava mobiilse laserskänneriga, kontrollmõõtmised käsilaser- kaugusmõõtjaga;
6. Tehnokommunikatsioonide laserskaneerimine iPad-iga, fotorealistliku punktipilve moodustamine.
brief description of the course in English
Basics of 3D mass data acquisition of spatial data. Handling of various surveying devices, including electronic total stations, terrestrial and portable laser scanners. Georeferencing of point clouds. Initial processing and adjustment of measurement data.
Laboratory assignments (as a team):
1. Measuring the dimensions and facade elements of a building with an electronic total station, using the corresponding manual if necessary;
2. Terrestrial laser scanning of the outer perimeter of a smaller building;
3. Georeferencing of laser scanning survey data and initial accuracy assessment, formation of a 3D point cloud from the survey data;
4. Control survey of the formed point cloud with a digital electronic total station;
5. 3D survey of an interior space with a portable mobile laser scanner, control measurements with a handheld laser rangefinder;
6. Laser scanning of utility lines with an iPad, generating a photorealistic point cloud.
Laboratory assignments (as a team):
1. Measuring the dimensions and facade elements of a building with an electronic total station, using the corresponding manual if necessary;
2. Terrestrial laser scanning of the outer perimeter of a smaller building;
3. Georeferencing of laser scanning survey data and initial accuracy assessment, formation of a 3D point cloud from the survey data;
4. Control survey of the formed point cloud with a digital electronic total station;
5. 3D survey of an interior space with a portable mobile laser scanner, control measurements with a handheld laser rangefinder;
6. Laser scanning of utility lines with an iPad, generating a photorealistic point cloud.
type of assessment in Estonian
Mitteeristuv hindamine lävendikriteeriumi alusel
type of assessment in English
non-graded assessment
independent study in Estonian
-
independent study in English
-
study literature
Ehitusgeodeesia- õpik kõrgkoolidele 2025
Loengukonspekt
Veebimaterjalid
Loengukonspekt
Veebimaterjalid
study forms and load
daytime study: weekly hours
2.0
session-based study work load (in a semester):
lectures
0.5
lectures
-
practices
1.0
practices
-
exercises
0.5
exercises
-
lecturer in charge
Artu Ellmann, täisprofessor tenuuris (EA - ehituse ja arhitektuuri instituut)
LECTURER SYLLABUS INFO
semester of studies
teaching lecturer / unit
language of instruction
Extended syllabus
Course-teacher pairs of the corresponding version are missing!