Diffractive Neural Network Enabled Spectral Object Detection
I tiakina i:
| I whakaputaina i: | Remote Sensing vol. 17, no. 19 (2025), p. 3381-3400 |
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| Kaituhi matua: | |
| Ētahi atu kaituhi: | , , |
| I whakaputaina: |
MDPI AG
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| Ngā marau: | |
| Urunga tuihono: | Citation/Abstract Full Text + Graphics Full Text - PDF |
| Ngā Tūtohu: |
Kāore He Tūtohu, Me noho koe te mea tuatahi ki te tūtohu i tēnei pūkete!
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| Whakarāpopotonga: | <sec sec-type="highlights"> What are the main findings? <list list-type="bullet"> <list-item> </list-item>We proposed an innovative DNN-SOD diffractive neural network architecture that leverages spectral characteristics and field-of-view segmentation to enable direct spectral feature reconstruction and target detection for infrared targets. <list-item> The architecture achieved 84.27% on an infrared target dataset, demonstrating its feasibility for large-scale remote sensing tasks. </list-item> What is the implication of the main finding? <list list-type="bullet"> <list-item> </list-item>This study presents a new paradigm of applying optical computing to spectral remote sensing target detection, overcoming the limitations of traditional optical computing methods that fail to fully exploit spectral properties of targets and handle large-scale data effectively. <list-item> It provides a novel pathway for integrated sensing-computing information processing in future sky-based remote sensing, highlighting the potential of optical computing inference in real-world applications. </list-item> This article introduces a diffractive neural network-enabled spectral object detection approach (DNN-SOD) to efficiently process massive sky-based multidimensional light field data. DNN-SOD combines the novel exploitation of target spectral features with the intrinsic parallelism of optical computing to process multidimensional information efficiently. DNN-SOD detects targets by segmenting the spectral data cube and processing it with the DNN. The DNN maps spectral intensity to the designated area of the detector, then reconstructs spectral curves, and differentiates targets by comparing them with reference spectral signatures. Classification results from individual sub-spectral data cubes are compiled in sequence, enabling accurate target detection. Simulation results indicate that the architecture achieved an accuracy of 91.56% on the MNIST multi-spectral dataset and 84.27% on the infrared target multi-spectral dataset, validating its feasibility for target detection. This architecture represents an innovative outcome at the intersection of remote sensing and optical computing, significantly advancing the dissemination and practical adoption of optical computing in the field. |
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| ISSN: | 2072-4292 |
| DOI: | 10.3390/rs17193381 |
| Puna: | Advanced Technologies & Aerospace Database |