A Latent Representation Learning Framework for Hyperspectral Image Emulation in Remote Sensing
This work addresses the need for efficient hyperspectral image emulation in remote sensing applications, offering a method that improves accuracy and fidelity for tasks like simulation and algorithm development, though it is incremental as it builds on existing latent representation techniques.
The paper tackled the problem of generating synthetic hyperspectral images for remote sensing by proposing a latent representation-based framework, which outperformed classical regression-based emulators in reconstruction accuracy, spectral fidelity, and robustness to spatial variability, as demonstrated on PROSAIL-simulated vegetation data and Sentinel-3 OLCI imagery.
Synthetic hyperspectral image (HSI) generation is essential for large-scale simulation, algorithm development, and mission design, yet traditional radiative transfer models remain computationally expensive and often limited to spectrum-level outputs. In this work, we propose a latent representation-based framework for hyperspectral emulation that learns a latent generative representation of hyperspectral data. The proposed approach supports both spectrum-level and spatial-spectral emulation and can be trained either in a direct one-step formulation or in a two-step strategy that couples variational autoencoder (VAE) pretraining with parameter-to-latent interpolation. Experiments on PROSAIL-simulated vegetation data and Sentinel-3 OLCI imagery demonstrate that the method outperforms classical regression-based emulators in reconstruction accuracy, spectral fidelity, and robustness to real-world spatial variability. We further show that emulated HSIs preserve performance in downstream biophysical parameter retrieval, highlighting the practical relevance of emulated data for remote sensing applications.