Conrad M Albrecht

Advancing Sea Ice Surface Classification by Self-Supervised Contrastive Learning for Radar Altimetry

(2026)

Authors:

Lena Happ, Stefan Hendricks, Conrad M Albrecht, Lars Kaleschke, Sonali Patil, Riccardo Fellegara, Dirk A Lorenz

Multispectral to Hyperspectral Using Pretrained Foundational Model

IGARSS 2025 - 2025 IEEE International Geoscience and Remote Sensing Symposium IEEE (2025) 785-789

Authors:

Ruben Gonzalez, Conrad M Albrecht, Nassim Ait Ali Braham, Devyani Lambhate, Joao Lucas De Sousa Almeida, Paolo Fraccaro, Benedikt Blumenstiel, Thomas Brunschwiler, Ranjini Bangalore

Multimodal GNSS-R self-supervised learning as a generalist Earth surface monitor

International Journal of Applied Earth Observation and Geoinformation Elsevier BV 142 (2025) 104658

Authors:

Daixin Zhao, Konrad Heidler, Milad Asgarimehr, Conrad M Albrecht, Jens Wickert, Xiao Xiang Zhu, Lichao Mou

Lossy neural compression for geospatial analytics: a review

IEEE Geoscience and Remote Sensing Magazine IEEE 13:3 (2025) 97-135

Authors:

Carlos Gomes, Isabelle Wittmann, Damien Robert, Johannes Jakubik, Tim Reichelt, Stefano Maurogiovanni, Rikard Vinge, Jonas Hurst, Erik Scheurer, Rocco Sedona, Thomas Brunschwiler, Stefan Kesselheim, Matej Batic, Philip Stier, Jan Dirk Wegner, Gabriele Cavallaro, Edzer Pebesma, Michael Marszalek, Miguel A Belenguer-Plomer, Kennedy Adriko, Paolo Fraccaro, Romeo Kienzler, Rania Briq, Sabrina Benassou, Michele Lazzarini, Conrad M Albrecht

Abstract:

Over the past decades, there has been an explosion in the amount of available Earth observation (EO) data. The unprecedented coverage of Earth’s surface and atmosphere by satellite imagery has resulted in large volumes of data that must be transmitted to ground stations, stored in data centers, and distributed to end users. Modern Earth system models (ESMs) face similar challenges, operating at high spatial and temporal resolutions, producing petabytes of data per simulated day. Data compression has gained relevance over the past decade, with neural compression (NC) emerging from deep learning and information theory, making EO data and ESM outputs ideal candidates because of their abundance of unlabeled data.

In this review, we outline recent developments in NC applied to geospatial data. We introduce the fundamental concepts of NC, including seminal works in its traditional applications to image and video compression domains with a focus on lossy compression. We discuss the unique characteristics of EO and ESM data, contrasting them with “natural images,” and we explain the additional challenges and opportunities they present. Additionally, we review current applications of NC across various EO modalities and explore the limited efforts in ESM compression to date. The advent of self-supervised learning (SSL) and foundation models (FMs) has advanced methods to efficiently distill representations from vast amounts of unlabeled data. We connect these developments to NC for EO, highlighting the similarities between the two fields and elaborate on the potential of transferring compressed feature representations for machine-to-machine communication. Based on insights drawn from this review, we devise future directions relevant to applications in EO and ESMs.

A Practical Guide to Hyperspectral Foundation Models

(2025)

Authors:

Conrad Albrecht, Ruben Gonzalez, Nassim Ait Ali Braham, Ranjini Bangalore, Thomas Brunschwiler

Abstract:

Hyperspectral imagery (HSI) provides rich spectral information that is the basis for applications such as mineral mapping, trace gas identification, and precision agriculture. Yet, the development of HSI Foundation Models (FMs) is less advanced compared to multi-spectral remote sensing modalities.In this study, we leverage the SpectralEarth dataset [1] to explore practical aspects of training robust HSI FMs. In particular, we shed light on the role of:the impact of model architecture (transformers vs. convolutional networks), self-supervised learning methods (contrastive vs. masked autoencoders), model size & training data volume, and the resulting computational requirements. Through extensive experiments, this study aims to provide concrete guidelines for the development and effective application of FMs in the HSI domain. Moreover, we report on findings to identify downstream applications where hyperspectral imagery has an edge over multi-spectral photos [2], and where such an advantage is less likely to expect. References[1] Braham, Nassim Ait Ali, et al. "SpectralEarth: Training Hyperspectral Foundation Models at Scale." arXiv preprint arXiv:2408.08447 (2024)[2] Bangalore, Ranjini, et al. "Hyperspectral foundation model trained by spectral reconstruction for greenhouse gas emission estimation", annual meeting of the American Geophysical Union (2024)