Tian Lan scite author profile

We present a novel graph-neural-network-based system to effectively represent large-scale 3D point clouds with the applications to autonomous driving. Many previous works studied the representations of 3D point clouds based on two approaches, voxelization, which causes discretization errors and learning, which is hard to capture huge variations in largescale scenarios. In this work, we combine voxelization and learning: we discretize the 3D space into voxels and propose novel graph inception networks to represent 3D points in each voxel. This combination makes the system avoid discretization errors and work for large-scale scenarios. The entire system for large-scale 3D point clouds acts like the blocked discrete cosine transform for 2D images; we thus call it the point cloud neural transform (PCT). We further apply the proposed PCT to represent real-time LiDAR sweeps produced by selfdriving cars and the PCT with graph inception networks significantly outperforms its competitors.

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Electrospun nanofibrous cellulose diacetate nitrate membrane for protein separation

Lan¹,

Shao²,

Gu³

et al. 2015

Journal of Membrane Science

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Tian Lan

Coupled hydrogeophysical inversion to identify non-Gaussian hydraulic conductivity field by jointly assimilating geochemical and time-lapse geophysical data

Convenient fabrication of carboxymethyl cellulose electrospun nanofibers functionalized with silver nanoparticles

Fabrication of hydroxyapatite nanoparticles decorated cellulose triacetate nanofibers for protein adsorption by coaxial electrospinning

PCT: Large-Scale 3d Point Cloud Representations Via Graph Inception Networks with Applications to Autonomous Driving

Electrospun nanofibrous cellulose diacetate nitrate membrane for protein separation

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