Richter, Martin; Illmann, Raik; Rosenberger, Maik; Notni, Gunther:
Alignment of multi-camera spectral images using wavelet transform
In: Instrumentation and measurement for a sustainable future : I2MTC 2024, May 20-23,2024, Glasgow, Scotland : conference proceedings - IEEE International Instrumentation and Measurement Technology Conference (Glasgow, 20.-23.05.2024); I2MTC (Glasgow, 20.-23.05.2024) - Piscataway, NJ: IEEE, 2024, 6 Seiten
2024Conference paper in Conference proceedingsClosed Access
Technische Universität Ilmenau (1992-) » Department of Mechanical Engineering (1992-) » Without Institute Allocation (1992-) » Fachgebiet Qualitätssicherung und Industrielle Bildverarbeitung (2015-)
Title in English:
Alignment of multi-camera spectral images using wavelet transform
Author:
Richter, MartinTU
SCOPUS
58609079300
Other
connected with university
;
Illmann, RaikTU
GND
1302247573
ORCID
0000-0001-9660-579XORCID iD
SCOPUS
57202830193
Other
connected with university
;
Rosenberger, MaikTU
GND
137000901
SCOPUS
7004031349
Other
connected with university
;
Notni, GuntherTU
GND
172636973
ORCID
0000-0001-7532-1560ORCID iD
SCOPUS
57225127198
SCOPUS
7004204934
Other
connected with university
Year of publication:
2024
Open-Access-Way of publication:
Closed Access
Scopus ID
Language of text:
English
Keyword, Topic:
multi camera ; multispectral imaging ; vegetation index
Media:
online resources
Type of resource:
Text
Licence type:
all rights reserved
Peer Reviewed:
Yes
Part of statistic:
Yes

Abstract in English:

Multispectral imaging is a valuable tool for monitoring plant health in agriculture and forestry. These methods are based on the calculation of different vegetation indices consisting of at least two spectral channels. In order to obtain accurate results, these two images must perfectly overlap. For cost-effective multispectral monitoring of plants with several single-channel cameras, we propose an image alignment technique that utilizes the structure of the scene itself and edge detection by means of wavelet transform. By transforming the spectral images into the frequency domain, we can calculate the average displacements of the scene by determining the distance between the peak amplitudes of the two spectral channels for each image line and axis. Originally, we used the haar wavelet function to extract the frequency domain, which yielded initial good results for vegetation and structures. Other wavelet functions were tested, which allowed further improvements. However, compared to edge extraction with the non-wavelet Sobel operator, only the rbio3.1 wavelet showed improved capabilities in merging the spectral channels, requiring on average one iteration of the proposed algorithm, while maintaining the success rate of Sobel.