Orthographic Gaussian Splatting from Axially Stacked Radiographs via SfM-Guided Novel ViewSynthesis

dc.contributor.authorRidun, Tasrefee Mahmood
dc.contributor.authorMushfique, MD Mushfiqur Rahman
dc.contributor.authorJishan, Kazi Jawadul Islam
dc.date.accessioned2026-06-24T08:38:59Z
dc.date.issued2025-10-25
dc.descriptionSupervised by Mr. Tareque MohmudChowdhury, Assistant Professor, Department of Computer Science and Engineering (CSE) Islamic University of Technology (IUT) Board Bazar, Gazipur, Bangladesh This thesis is submitted in partial fulfillment of the requirement for the degree of Bachelor of Science in Software Engineering, 2025
dc.description.abstractWe present a Gaussian-splatting pipeline tailored to axially stacked radiographs that breaks with the perspective and alpha-blending assumptions of standard 3DGS. Clini cal CT data are orthographic and exhibit little cross-slice feature continuity, causing classical SfM and vanilla splat renderers to fail (edge-biased splats, central collapse). Our method first converts ordered CT slices into a metric volume, then renders **ra diographic** projections that obey Beer–Lambert attenuation to synthesize multi-view images with controlled overlap. From these, we obtain poses and train a **rectified radiative Gaussian** model that replaces alpha compositing with additive X-ray ac cumulation and includes a density-rectification term so each Gaussian’s parameter encodes true 3D density rather than view-integrated mass. We initialize Gaussians directly from the slice volume with a lightweight sampler that seeds positions, scales, and densities, and stabilize optimization with gentle TV-on-voxel readouts and adap tive clone/split densification. On a 1.8k-slice brain CT (HiP-CT family), using 1.2k synthetic projections, our system reconstructs coherent anatomy and produces faithful novel projections after 45 minutes of training, visibly restoring central structures and suppressing edge-only artifacts compared to a cinematic-GS baseline. The approach is code-practical (no reliance on FDK/TIGRE), data-efficient, and compatible with DICOM geometry, offering a reproducible path to fast, radiography-consistent 3D reconstructions from orthographic medical stacks. We discuss remaining limits (pose accuracy, scatter, regularization strength) and outline ablations and metrics (L1/SSIM on held-out views, orthogonal-slice fidelity) to guide future clinical validation.
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dc.identifier.urihttps://repository.iutoic-dhaka.edu/handle/123456789/2632
dc.language.isoen
dc.publisherDepartment of Computer Science and Engineering(CSE), Islamic University of Technology(IUT), Board Bazar, Gazipur-1704, Bangladesh
dc.titleOrthographic Gaussian Splatting from Axially Stacked Radiographs via SfM-Guided Novel ViewSynthesis
dc.typeThesis

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