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Archive > Volume Issue 5 > 2025(5):601-614. DOI:10.16356/j.1005-1120.2025.05.004 Prev Next

Multi-frequency Jitter Detection and Modeling for Remote Sensing Satellite Platforms Using Non-collinear TDI CCD

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    Abstract:
    The advancement of imaging resolution has made the impact of multi-frequency composite jitter in satellite platforms on non-collinear time delay and integration (TDI) charge-coupled device (CCD) imaging systems increasingly critical. Moreover, the accuracy of jitter detection is constrained by the limited inter-chip overlap region inherent to non-collinear TDI CCDs. To address these challenges, a multi-frequency jitter detection method is proposed, achieving sub-pixel level error extraction. Furthermore, a multi-frequency jitter fitting approach utilizing a scale-adjustable sliding window is introduced. For composite multi-frequency jitter, spectral analysis decomposes the relative jitter error curve, while the scale-adjustable sliding window enables frequency-division fitting and modeling. Validation experiments using Gaofen-8 (GF-8) remote sensing satellite imagery detected jitter at 0.65, 20, and 100 Hz in the cross-track direction and at 0.5, 100, and 120 Hz in the along-track direction, demonstrating the method’s precision in detecting platform jitter at sub-pixel accuracy (<0.2 pixels) and its efficacy in fitting and modeling for non-collinear TDI CCD imaging systems subject to multi-frequency jitter.

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    Clc Number:
    P237

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