Your search keyword '"Kukkonen, Mikko"' showing total 4 results

1. Detection of standing retention trees in boreal forests with airborne laser scanning point clouds and multispectral imagery.

Author

Hardenbol, Alwin A., Korhonen, Lauri, Kukkonen, Mikko, and Maltamo, Matti

Subjects

AIRBORNE lasers, TAIGAS, POINT cloud, DEAD trees, FOREST conservation, FOREST management

Abstract

Copyright of Methods in Ecology & Evolution is the property of Wiley-Blackwell and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

2. Using ALS Data to Improve Co-Registration of Photogrammetry-Based Point Cloud Data in Urban Areas.

Author

Gopalakrishnan, Ranjith, Ali-Sisto, Daniela, Kukkonen, Mikko, Savolainen, Pekka, and Packalen, Petteri

Subjects

CITIES & towns, POINT cloud, SUBURBS, DIGITAL photogrammetry, AERIAL photogrammetry, CLOUD storage

Abstract

Globally, urban areas are rapidly expanding and high-quality remote sensing products are essential to help guide such development towards efficient and sustainable pathways. Here, we present an algorithm to address a common problem in digital aerial photogrammetry (DAP)-based image point clouds: vertical mis-registration. The algorithm uses the ground as inferred from airborne laser scanning (ALS) data as a reference surface and re-aligns individual point clouds to this surface. We demonstrate the effectiveness of the proposed method for the city of Kuopio, in central Finland. Here, we use the standard deviation of the vertical coordinate values as a measure of the mis-registration. We show that such standard deviation decreased substantially (more than 1.0 m) for a large proportion (23.2%) of the study area. Moreover, it was shown that the method performed better in urban and suburban areas, compared to vegetated areas (parks, forested areas, and so on). Hence, we demonstrate that the proposed algorithm is a simple and effective method to improve the quality and usability of DAP-based point clouds in urban areas. [ABSTRACT FROM AUTHOR]

Published

2020

3. Utility of image point cloud data towards generating enhanced multitemporal multisensor land cover maps.

Author

Gopalakrishnan, Ranjith, Seppänen, Aku, Kukkonen, Mikko, and Packalen, Petteri

Subjects

LAND cover, POINT cloud, AIRBORNE lasers, BAYESIAN analysis, SHRUBLANDS, MARKOV processes

Abstract

• Mulitemporal urban land cover classification is challenging, but topical. • Image point cloud (IPC) data helps better differentiate between land cover classes. • IPC data can be used in conjunction with Bayesian techniques to yield consistent, multitemporal land cover maps (accuracy observed = 92%, kappa = 0.89) Multitemporal land cover classification over urban areas is challenging, especially when using heterogeneous data sources with variable quality attributes. A prominent challenge is that classes with similar spectral signatures (such as trees and grass) tend to be confused with one another. In this paper, we evaluate the efficacy of image point cloud (IPC) data combined with suitable Bayesian analysis based time-series rectification techniques to improve the classification accuracy in a multitemporal context. The proposed method uses hidden Markov models (HMMs) to rectify land covers that are initially classified by a random forest (RF) algorithm. This land cover classification method is tested using time series of remote sensing data from a heterogeneous and rapidly changing urban landscape (Kuopio city, Finland) observed from 2006 to 2014. The data consisted of aerial images (5 years), Landsat data (all 9 years) and airborne laser scanning data (1 year). The results of the study demonstrate that the addition of three-dimensional image point cloud data derived from aerial stereo images as predictor variables improved overall classification accuracy, around three percentage points. Additionally, HMM-based post processing reduces significantly the number of spurious year-to-year changes. Using a set of 240 validation points, we estimated that this step improved overall classification accuracy by around 3.0 percentage points, and up to 6 to 10 percentage points for some classes. The overall accuracy of the final product was 91% (kappa = 0.88). Our analysis shows that around 1.9% of the area around Kuopio city, representing a total area of approximately 0.61 km2, experienced changes in land cover over the nine years considered. [ABSTRACT FROM AUTHOR]

Published

2020

4. A method for vertical adjustment of digital aerial photogrammetry data by using a high-quality digital terrain model.

Author

Ali-Sisto, Daniela, Gopalakrishnan, Ranjith, Kukkonen, Mikko, Savolainen, Pekka, and Packalen, Petteri

Subjects

DIGITAL elevation models, DIGITAL photogrammetry, AERIAL photogrammetry, POINT cloud, AIRBORNE lasers

Abstract

• Quality of DAP data enhanced by vertical co-registration with ALS-based DTM. • Co-registration decreased the errors of forest height and volume predictions. Near-ALS-quality was achieved even for vertically misaligned DAP-data. • Endlap image pairs outperformed sidelap pairs in forest attribute prediction. The accuracy of vertical position information can be degraded by various sources of error in digital aerial photogrammetry (DAP) based point clouds. To address this issue, we propose a relatively straightforward method for automated correction of such point clouds. This method can be used in conjunction with any 3D reconstruction method in which a point cloud is generated from a pair of aerial images. The crux of the method involves separately co-registering each DAP point cloud (formed by the overlap of two or more images) to a common airborne laser scanning (ALS) based digital terrain model. The proposed method has the following essential steps: (1) Ground surface patches are identified in the normalized DAP point clouds by selecting areas in which standard deviation of vertical height is low, (2) height differences between the DAP and ALS point clouds are calculated at these patches, and (3) a correction surface is interpolated from these height differences and is then used to rectify the entire DAP point cloud. The performance of the proposed method is verified using plot data (n = 250) from a forested study area in Eastern Finland. We observed that DAP data from the area corrected using our proposed method resulted in significant increases in prediction accuracy of key forest variables. Specifically, the root mean squared error (RMSE) values for dominant height predictions decreased by up to 23.2%, while the associated model R2 values increased by 16.9%. As for stem volume, RMSEs dropped by 20.6%, while the model R2 improved by 14.6%, respectively. Hence, prediction accuracies were almost as good as with ALS data. The results suggest that vertically misaligned DAP data, if rectified using an algorithm such as the one presented here, could deliver near ALS data quality at a fraction of the cost. [ABSTRACT FROM AUTHOR]

Published

2020