Your search keyword '"Malek, Salim"' showing total 4 results

1. Metrological Analysis with Covariance Features of Micro-Channels Fabricated with a Femtosecond Laser.

Author

Verdi, Matteo, Bassi, Federico, Calabrese, Luigi, Azzolini, Martina, Malek, Salim, Battisti, Roberto, Grilli, Eleonora, Menna, Fabio, Gallus, Enrico, and Remondino, Fabio

Subjects

INDUSTRIAL lasers, OPTICAL interferometers, PRINCIPAL components analysis, ANALYSIS of covariance, SURFACE topography

Abstract

This study presents an automated methodology for evaluating micro-channels fabricated using a femtosecond laser on stainless steel substrates. We utilize 3D surface topography and metrological analyses to extract geometric features and detect fabrication defects. Standardized samples were analyzed using a light interferometer, and the resulting data were processed with Principal Component Analysis (PCA) and RANSAC algorithms to derive channel characteristics, such as depth, wall taper, and surface roughness. The proposed method identifies common defects, including bumps and V-defects, which can compromise the functionality of micro-channels. The effectiveness of the approach is validated by comparisons with commercial solutions. This automated procedure aims to enhance the reliability and precision of femtosecond laser micro-milling for industrial applications. The detected defects, combined with fabrication parameters, could be ingested in an AI-based process to optimize fabrication processes. [ABSTRACT FROM AUTHOR]

Published

2024

2. Colorizing the Past: Deep Learning for the Automatic Colorization of Historical Aerial Images.

Author

Farella, Elisa Mariarosaria, Malek, Salim, and Remondino, Fabio

Subjects

DEEP learning, IMAGE processing, MASS media industry, AUTOMATION

Abstract

The colorization of grayscale images can, nowadays, take advantage of recent progress and the automation of deep-learning techniques. From the media industry to medical or geospatial applications, image colorization is an attractive and investigated image processing practice, and it is also helpful for revitalizing historical photographs. After exploring some of the existing fully automatic learning methods, the article presents a new neural network architecture, Hyper-U-NET, which combines a U-NET-like architecture and HyperConnections to handle the colorization of historical black and white aerial images. The training dataset (about 10,000 colored aerial image patches) and the realized neural network are available on our GitHub page to boost further research investigations in this field. [ABSTRACT FROM AUTHOR]

Published

2022

3. Real-Time Indoor Scene Description for the Visually Impaired Using Autoencoder Fusion Strategies with Visible Cameras.

Author

Malek, Salim, Melgani, Farid, Mekhalfi, Mohamed Lamine, and Bazi, Yakoub

Subjects

*DATA fusion (Statistics), *FEATURE extraction, *CODING theory, *DEEP learning, *CLASSIFICATION

Abstract

This paper describes three coarse image description strategies, which are meant to promote a rough perception of surrounding objects for visually impaired individuals, with application to indoor spaces. The described algorithms operate on images (grabbed by the user, by means of a chest-mounted camera), and provide in output a list of objects that likely exist in his context across the indoor scene. In this regard, first, different colour, texture, and shape-based feature extractors are generated, followed by a feature learning step by means of AutoEncoder (AE) models. Second, the produced features are fused and fed into a multilabel classifier in order to list the potential objects. The conducted experiments point out that fusing a set of AE-learned features scores higher classification rates with respect to using the features individually. Furthermore, with respect to reference works, our method: (i) yields higher classification accuracies, and (ii) runs (at least four times) faster, which enables a potential full real-time application. [ABSTRACT FROM AUTHOR]

Published

2017

4. Optimizing Field Data Collection for Individual Tree Attribute Predictions Using Active Learning Methods.

Author

Malek, Salim, Miglietta, Franco, Gobakken, Terje, Næsset, Erik, Gianelle, Damiano, and Dalponte, Michele

Subjects

*LIDAR, *REMOTE sensing, *BIOMASS, *DATA analysis, *FINITE element method

Abstract

Light detection and ranging (lidar) data are nowadays a standard data source in studies related to forest ecology and environmental mapping. Medium/high point density lidar data allow to automatically detect individual tree crowns (ITCs), and they provide useful information to predict stem diameter and aboveground biomass of each tree represented by a detected ITC. However, acquisition of field data is necessary for the construction of prediction models that relate field data to lidar data and for validation of such models. When working at ITC level, field data collection is often expensive and time-consuming as accurate tree positions are needed. Active learning (AL) can be very useful in this context as it helps to select the optimal field trees to be measured, reducing the field data collection cost. In this study, we propose a new method of AL for regression based on the minimization of the field data collection cost in terms of distance to navigate between field sample trees, and accuracy in terms of root mean square error of the predictions. The developed method is applied to the prediction of diameter at breast heights (DBH) and aboveground biomass (AGB) of individual trees by using their height and crown diameter as independent variables and support vector regression. The proposed method was tested on two boreal forest datasets, and the obtained results show the effectiveness of the proposed selecting strategy to provide substantial improvements over the different iterations compared to a random selection. The obtained RMSE of DBH/AGB for the first dataset was 5.09 cm/95.5 kg with a cost equal to 8256/6173 m by using the proposed multi-objective method of selection. However, by using a random selection, the RMSE was 5.20 cm/102.1 kg with a cost equal to 28,391/30,086 m. The proposed approach can be efficient in order to get more accurate predictions with smaller costs, especially when a large forest area with no previous field data is subject to inventory and analysis. [ABSTRACT FROM AUTHOR]

Published

2019