Your search keyword '"Lauri Seitsonen"' showing total 10 results

1. Deep Neural Networks with Transfer Learning for Forest Variable Estimation Using Sentinel-2 Imagery in Boreal Forest

Author

Heikki Astola, Lauri Seitsonen, Eelis Halme, Matthieu Molinier, and Anne Lönnqvist

Subjects

deep learning, deep neural networks, transfer learning, sentinel-2, boreal forest, forest variables, Science

Abstract

Estimation of forest structural variables is essential to provide relevant insights for public and private stakeholders in forestry and environmental sectors. Airborne light detection and ranging (LiDAR) enables accurate forest inventory, but it is expensive for large area analyses. Continuously increasing volume of open Earth Observation (EO) imagery from high-resolution (|BIAS%| = 0.8%). We found 3×3 pixels to be the optimal size for the sampling window, and two to three hidden layer DNNs to produce the best results with relatively small improvement to single hidden layer networks. Including CHM features with S2 data and additional features led to reduced relative RMSE (RMSE% = 28.6–30.7%) but increased the absolute value of relative bias (|BIAS%| = 0.9–4.0%). Transfer learning was found to be beneficial mainly with training data sets containing less than 250 field plots. The performance differences of DNN and random forest models were marginal. Our results contribute to improved structural variable estimation performance in boreal forests with the proposed image sampling and input feature concept.

Published

2021

2. A Hierarchical Clustering Method for Land Cover Change Detection and Identification

Author

Tuomas Häme, Laura Sirro, Jorma Kilpi, Lauri Seitsonen, Kaj Andersson, and Timo Melkas

Subjects

change detection, optical, SAR, multi-temporal, forestry, land cover, Science

Abstract

A method to detect abrupt land cover changes using hierarchical clustering of multi-temporal satellite imagery was developed. The Autochange method outputs the pre-change land cover class, the change magnitude, and the change type. Pre-change land cover information is transferred to post-change imagery based on classes derived by unsupervised clustering, enabling using data from different instruments for pre- and post-change. The change magnitude and change types are computed by unsupervised clustering of the post-change image within each cluster, and by comparing the mean intensity values of the lower level clusters with their parent cluster means. A computational approach to determine the change magnitude threshold for the abrupt change was developed. The method was demonstrated with three summer image pairs Sentinel-2/Sentinel-2, Landsat 8/Sentinel-2, and Sentinel-2/ALOS 2 PALSAR in a study area of 12,372 km2 in southern Finland for the detection of forest clear cuts and tested with independent data. The Sentinel-2 classification produced an omission error of 5.6% for the cut class and 0.4% for the uncut class. Commission errors were 4.9% for the cut class and 0.4% for the uncut class. For the Landsat 8/Sentinel-2 classifications the equivalent figures were 20.8%, 0.2%, 3.4%, and 1.6% and for the Sentinel-2/ALOS PALSAR classification 16.7%, 1.4%, 17.8%, and 1.3%, respectively. The Autochange algorithm and its software implementation was considered applicable for the mapping of abrupt land cover changes using multi-temporal satellite data. It allowed mixing of images even from the optical and synthetic aperture radar (SAR) sensors in the same change analysis.

Published

2020

3. Continuous Ground Moisture Monitoring at Limestone Quarry Using Multi-Sensor SAR Images and in Situ IoT Sensors.

Author

Oleg Antropov, Matthieu Molinier, Lauri Seitsonen, Alireza Hamedianfar, Maarit Middleton, Kati Laakso, Heikki Sutinen, and Pauliina Liwata-Kenttälä

Published

2024

4. Automatic Cloud and Shadow Detection in Optical Satellite Imagery Without Using Thermal Bands—Application to Suomi NPP VIIRS Images over Fennoscandia

Author

Eija Parmes, Yrjö Rauste, Matthieu Molinier, Kaj Andersson, and Lauri Seitsonen

Subjects

cloud and shadow masking, optical satellite images, Suomi NPP VIIRS, Sentinel-2, surface reflectance, rule-based classification, Science

Abstract

In land monitoring applications, clouds and shadows are considered noise that should be removed as automatically and quickly as possible, before further analysis. This paper presents a method to detect clouds and shadows in Suomi NPP satellite’s VIIRS (Visible Infrared Imaging Radiometer Suite) satellite images. The proposed cloud and shadow detection method has two distinct features when compared to many other methods. First, the method does not use the thermal bands and can thus be applied to other sensors which do not contain thermal channels, such as Sentinel-2 data. Secondly, the method uses the ratio between blue and green reflectance to detect shadows. Seven hundred and forty-seven VIIRS images over Fennoscandia from August 2014 to April 2016 were processed to train and develop the method. Twenty four points from every tenth of the images were used in accuracy assessment. These 1752 points were interpreted visually to cloud, cloud shadow and clear classes, then compared to the output of the cloud and shadow detection. The comparison on VIIRS images showed 94.2% correct detection rates and 11.1% false alarms for clouds, and respectively 36.1% and 82.7% for shadows. The results on cloud detection were similar to state-of-the-art methods. Shadows showed correctly on the northern edge of the clouds, but many shadows were wrongly assigned to other classes in some cases (e.g., to water class on lake and forest boundary, or with shadows over cloud). This may be due to the low spatial resolution of VIIRS images, where shadows are only a few pixels wide and contain lots of mixed pixels.

Published

2017

5. Intercomparison of Earth Observation Data and Methods for Forest Mapping in the Context of Forest Carbon Monitoring.

Author

Oleg Antropov, Jukka Miettinen, Tuomas Häme, Yrjö Rauste, Lauri Seitsonen, Ronald E. McRoberts, Maurizio Santoro, Oliver Cartus, Natalia Malaga Duran, Martin Herold 0001, Matteo Pardini, Kostas Papathanassiou, and Irena Hajnsek

Published

2022

6. A text mining system for bioinformatics: requirements and architecture.

Author

Ilkka Karanta, Antti Pesonen, Lauri Seitsonen, and Paula Silvonen

Published

2006

7. Demonstration of large area forest volume and primary production estimation approach based on Sentinel-2 imagery and process based ecosystem modelling

Author

Jukka Miettinen, Juho Penttilä, Yrjö Rauste, Jan Pisl, Lauri Seitsonen, Xianglin Tian, Annikki Mäkelä, Simon Carlier, Francesco Minunno, Jussi Rasinmäki, Tuomas Häme, Lauri Häme, Department of Forest Sciences, Ecosystem processes (INAR Forest Sciences), and Forest Modelling Group

Subjects

0106 biological sciences, 1171 Geosciences, BOREAL, EFFICIENCY, 010504 meteorology & atmospheric sciences, Process (engineering), PREDICTION, ACCURACY, 010603 evolutionary biology, 01 natural sciences, SDG 13 - Climate Action, MANAGEMENT, Production (economics), Ecosystem, 0105 earth and related environmental sciences, Estimation, CALIBRATION, Biomass (ecology), 4112 Forestry, business.industry, Environmental resource management, Volume (computing), 15. Life on land, CARBON BALANCE MODEL, Climate change mitigation, 13. Climate action, DENSITY, MAP, General Earth and Planetary Sciences, Environmental science, GROWTH, business

Abstract

Forest biomass and carbon monitoring play a key role in climate change mitigation. Operational large area monitoring approaches are needed to enable forestry stakeholders to meet the increasing monitoring and reporting requirements. Here, we demonstrate the functionality of a cloud-based approach utilizing Sentinel-2 composite imagery and process-based ecosystem model to produce large area forest volume and primary production estimates. We describe the main components of the approach and implementation of the processing pipeline into the Forestry TEP cloud processing platform and produce four large area output maps: (1) Growing stock volume (GSV), (2) Gross primary productivity (GPP), (3) Net primary productivity (NPP) and (4) Stem volume increment (SVI), covering Finland and the Russian boreal forests until the Ural Mountains in 10 m spatial resolution. The accuracy of the forest structural variables evaluated in Finland reach pixel level relative Root Mean Square Error (RMSE) values comparable to earlier studies (basal area 39.4%, growing stock volume 58.5%, diameter 35.5% and height 33.5%), although most of the earlier studies have concentrated on smaller study areas. This can be considered a positive sign for the feasibility of the approach for large area primary production modelling, since forest structural variables are the main input for the process-based ecosystem model used in the study. The full coverage output maps show consistent quality throughout the target area, with major regional variations clearly visible, and with noticeable fine details when zoomed into full resolution. The demonstration conducted in this study lays foundation for further development of an operational large area forest monitoring system that allows annual reporting of forest biomass and carbon balance from forest stand level to regional analyses. The system is seamlessly aligned with process based ecosystem modelling, enabling forecasting and future scenario simulation.

Published

2021

8. Deep neural networks with transfer learning for forest variable estimation using sentinel-2 imagery in boreal forest

Author

Matthieu Molinier, Lauri Seitsonen, Eelis Halme, Anne Lönnqvist, and Heikki Astola

Subjects

010504 meteorology & atmospheric sciences, Mean squared error, Science, 0211 other engineering and technologies, 02 engineering and technology, 01 natural sciences, Deep neural networks, Boreal forest, Forest variables, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Remote sensing, Forest inventory, Pixel, business.industry, Deep learning, Sampling (statistics), 15. Life on land, Random forest, Transfer learning, Lidar, Feature (computer vision), deep learning, deep neural networks, transfer learning, sentinel-2, boreal forest, forest variables, stem volume, General Earth and Planetary Sciences, Environmental science, Artificial intelligence, Sentinel-2, business, Stem volume

Abstract

Estimation of forest structural variables is essential to provide relevant insights for public and private stakeholders in forestry and environmental sectors. Airborne light detection and ranging (LiDAR) enables accurate forest inventory, but it is expensive for large area analyses. Continuously increasing volume of open Earth Observation (EO) imagery from high-resolution (|BIAS%| = 0.8%). We found 3×3 pixels to be the optimal size for the sampling window, and two to three hidden layer DNNs to produce the best results with relatively small improvement to single hidden layer networks. Including CHM features with S2 data and additional features led to reduced relative RMSE (RMSE% = 28.6–30.7%) but increased the absolute value of relative bias (|BIAS%| = 0.9–4.0%). Transfer learning was found to be beneficial mainly with training data sets containing less than 250 field plots. The performance differences of DNN and random forest models were marginal. Our results contribute to improved structural variable estimation performance in boreal forests with the proposed image sampling and input feature concept.

Published

2021

9. A Hierarchical Clustering Method for Land Cover Change Detection and Identification

Author

Kaj Andersson, Laura Sirro, Lauri Seitsonen, Jorma Kilpi, Timo Melkas, and Tuomas Häme

Subjects

Synthetic aperture radar, Multi-temporal, Land cover, 010504 meteorology & atmospheric sciences, Science, 0211 other engineering and technologies, Magnitude (mathematics), 02 engineering and technology, 01 natural sciences, land cover, optical, Satellite imagery, change detection, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Remote sensing, Mathematics, SDG 15 - Life on Land, algorithm, Land cover change detection, multi-temporal, forestry, Forestry, Hierarchical clustering, Algorithm, Identification (information), General Earth and Planetary Sciences, Change detection, Optical, SAR

Abstract

A method to detect abrupt land cover changes using hierarchical clustering of multi-temporal satellite imagery was developed. The Autochange method outputs the pre-change land cover class, the change magnitude, and the change type. Pre-change land cover information is transferred to post-change imagery based on classes derived by unsupervised clustering, enabling using data from different instruments for pre- and post-change. The change magnitude and change types are computed by unsupervised clustering of the post-change image within each cluster, and by comparing the mean intensity values of the lower level clusters with their parent cluster means. A computational approach to determine the change magnitude threshold for the abrupt change was developed. The method was demonstrated with three summer image pairs Sentinel-2/Sentinel-2, Landsat 8/Sentinel-2, and Sentinel-2/ALOS 2 PALSAR in a study area of 12,372 km2 in southern Finland for the detection of forest clear cuts and tested with independent data. The Sentinel-2 classification produced an omission error of 5.6% for the cut class and 0.4% for the uncut class. Commission errors were 4.9% for the cut class and 0.4% for the uncut class. For the Landsat 8/Sentinel-2 classifications the equivalent figures were 20.8%, 0.2%, 3.4%, and 1.6% and for the Sentinel-2/ALOS PALSAR classification 16.7%, 1.4%, 17.8%, and 1.3%, respectively. The Autochange algorithm and its software implementation was considered applicable for the mapping of abrupt land cover changes using multi-temporal satellite data. It allowed mixing of images even from the optical and synthetic aperture radar (SAR) sensors in the same change analysis.

Published

2020

10. Ontology-based Knowledge in Interactive Maintenance Guide.

Author

Seppo Nyrkko, Lauri Carlson, Matti Keijola, Helena Ahonen-Myka, Jyrki Niemi, Jussi Piitulainen, Sirke Viitanen, Martti Meri, Lauri Seitsonen, Petri Mannonen, and Jani Juvonen

Published

2007