Course Details
Photogrammetry II
Academic Year 2022/23
HE05 course is part of 1 study plan
N-P-C-GK / GD Summer Semester 1st year
Use of GNSS and IMU in aerotriangulation, additional parrameters, accuracy analysis, systemathic errors, geometric image transformation, improvement of images, extraction , filtering, mosaiking, integrated technologies.
Physical fundamentals of remote sensing, sensors and their parameters, satellite orbits. Remote sensing tasks, digital processing remote sensing data, remote sensing applications.
Physical fundamentals of remote sensing, sensors and their parameters, satellite orbits. Remote sensing tasks, digital processing remote sensing data, remote sensing applications.
Credits
5 credits
Language of instruction
Czech
Semester
summer
Course Guarantor
Institute
Forms and criteria of assessment
course-unit credit and examination
Entry Knowledge
The ability to use of advanced technology for determination of elements of exterior orientations - aerotriangulation with GNSS/IMU measurements.
Detailed analysis of results. Use of basic method of classification on aerial and sattelite images.
Detailed analysis of results. Use of basic method of classification on aerial and sattelite images.
Aims
Advanced photogrammetric technologies, accuracy analysis, remote sensing sensors, remote sensing tasks and applications.
Basic Literature
Hanzl, V., Plánka, L.: Fotogrammetrie a dálkový průzkum. VUT v Brně, studijní podpora (4 moduly), 2007. [https://intranet.fce.vutbr.cz/pedagog/predmety/opory.asp] (cs)
Syllabus
1. Principles of inertial navigation, Kalman filter.
2. Use GNSS/IMU instruments in aerotriangulation.
3. Additional parameters in image triangulations.
4. Accuracy analysis, systemathic errors.
5. Integrated technologies.
6. Geometric and radiometric image transformation.
7. Improvement of images, extractions of image elements, filtering.
8. Physical fundamentals of remote sensing.
9. Sensors and their parameters, satellite orbits.
10.Remote sensing taks, digital processing of data, remote sensing applications.
2. Use GNSS/IMU instruments in aerotriangulation.
3. Additional parameters in image triangulations.
4. Accuracy analysis, systemathic errors.
5. Integrated technologies.
6. Geometric and radiometric image transformation.
7. Improvement of images, extractions of image elements, filtering.
8. Physical fundamentals of remote sensing.
9. Sensors and their parameters, satellite orbits.
10.Remote sensing taks, digital processing of data, remote sensing applications.
Prerequisites
Methos of digital images acquisition, image triangulation
Specification of controlled instruction, the form of instruction, and the form of compensation of the absences
Extent and forms are specified by guarantor’s regulation updated for every academic year.
Offered to foreign students
Not to offer
Course on BUT site
Lecture
13 weeks, 2 hours/week, elective
Syllabus
1. Principles of inertial navigation, Kalman filter.
2. Use GNSS/IMU instruments in aerotriangulation.
3. Additional parameters in image triangulations.
4. Accuracy analysis, systemathic errors.
5. Integrated technologies.
6. Geometric and radiometric image transformation.
7. Improvement of images, extractions of image elements, filtering.
8. Physical fundamentals of remote sensing.
9. Sensors and their parameters, satellite orbits.
10.Remote sensing taks, digital processing of data, remote sensing applications.
2. Use GNSS/IMU instruments in aerotriangulation.
3. Additional parameters in image triangulations.
4. Accuracy analysis, systemathic errors.
5. Integrated technologies.
6. Geometric and radiometric image transformation.
7. Improvement of images, extractions of image elements, filtering.
8. Physical fundamentals of remote sensing.
9. Sensors and their parameters, satellite orbits.
10.Remote sensing taks, digital processing of data, remote sensing applications.
Exercise
13 weeks, 2 hours/week, compulsory
Syllabus
Aerotriangulation - advanced solutions: input directly observed projection centers, option of parameters for automatic measurement of tie points - 2 weeks.
Calibration of camera for close range photogrammetry, choice of additional parameters - 2 weeks.
Accuracy analysis of coordinates of determined point - 1 week.
Planning of image flight - 1 week.
Classification of remote sensig images - 2 weeks.
Calibration of camera for close range photogrammetry, choice of additional parameters - 2 weeks.
Accuracy analysis of coordinates of determined point - 1 week.
Planning of image flight - 1 week.
Classification of remote sensig images - 2 weeks.