A Surface Geometry Model for LiDAR Depth Completion
- URL: http://arxiv.org/abs/2104.08466v1
- Date: Sat, 17 Apr 2021 06:48:01 GMT
- Title: A Surface Geometry Model for LiDAR Depth Completion
- Authors: Yiming Zhao, Lin Bai, Ziming Zhang and Xinming Huang
- Abstract summary: LiDAR depth completion is a task that predicts depth values for every pixel on the corresponding camera frame.
Most of the existing state-of-the-art solutions are based on deep neural networks, which need a large amount of data and heavy computations for training the models.
In this letter, a novel non-learning depth completion method is proposed by exploiting the local surface geometry that is enhanced by an outlier removal algorithm.
- Score: 19.33116596688515
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: LiDAR depth completion is a task that predicts depth values for every pixel
on the corresponding camera frame, although only sparse LiDAR points are
available. Most of the existing state-of-the-art solutions are based on deep
neural networks, which need a large amount of data and heavy computations for
training the models. In this letter, a novel non-learning depth completion
method is proposed by exploiting the local surface geometry that is enhanced by
an outlier removal algorithm. The proposed surface geometry model is inspired
by the observation that most pixels with unknown depth have a nearby LiDAR
point. Therefore, it is assumed those pixels share the same surface with the
nearest LiDAR point, and their respective depth can be estimated as the nearest
LiDAR depth value plus a residual error. The residual error is calculated by
using a derived equation with several physical parameters as input, including
the known camera intrinsic parameters, estimated normal vector, and offset
distance on the image plane. The proposed method is further enhanced by an
outlier removal algorithm that is designed to remove incorrectly mapped LiDAR
points from occluded regions. On KITTI dataset, the proposed solution achieves
the best error performance among all existing non-learning methods and is
comparable to the best self-supervised learning method and some supervised
learning methods. Moreover, since outlier points from occluded regions is a
commonly existing problem, the proposed outlier removal algorithm is a general
preprocessing step that is applicable to many robotic systems with both camera
and LiDAR sensors.
Related papers
- TanDepth: Leveraging Global DEMs for Metric Monocular Depth Estimation in UAVs [5.6168844664788855]
This work presents TanDepth, a practical, online scale recovery method for obtaining metric depth results from relative estimations at inference-time.
Tailored for Unmanned Aerial Vehicle (UAV) applications, our method leverages sparse measurements from Global Digital Elevation Models (GDEM) by projecting them to the camera view.
An adaptation to the Cloth Simulation Filter is presented, which allows selecting ground points from the estimated depth map to then correlate with the projected reference points.
arXiv Detail & Related papers (2024-09-08T15:54:43Z) - Deep Richardson-Lucy Deconvolution for Low-Light Image Deblurring [48.80983873199214]
We develop a data-driven approach to model the saturated pixels by a learned latent map.
Based on the new model, the non-blind deblurring task can be formulated into a maximum a posterior (MAP) problem.
To estimate high-quality deblurred images without amplified artifacts, we develop a prior estimation network.
arXiv Detail & Related papers (2023-08-10T12:53:30Z) - Single Image Depth Prediction Made Better: A Multivariate Gaussian Take [163.14849753700682]
We introduce an approach that performs continuous modeling of per-pixel depth.
Our method's accuracy (named MG) is among the top on the KITTI depth-prediction benchmark leaderboard.
arXiv Detail & Related papers (2023-03-31T16:01:03Z) - Depth Refinement for Improved Stereo Reconstruction [13.941756438712382]
Current techniques for depth estimation from stereoscopic images still suffer from a built-in drawback.
A simple analysis reveals that the depth error is quadratically proportional to the object's distance.
We propose a simple but effective method that uses a refinement network for depth estimation.
arXiv Detail & Related papers (2021-12-15T12:21:08Z) - Differentiable Diffusion for Dense Depth Estimation from Multi-view
Images [31.941861222005603]
We present a method to estimate dense depth by optimizing a sparse set of points such that their diffusion into a depth map minimizes a multi-view reprojection error from RGB supervision.
We also develop an efficient optimization routine that can simultaneously optimize the 50k+ points required for complex scene reconstruction.
arXiv Detail & Related papers (2021-06-16T16:17:34Z) - Deterministic Guided LiDAR Depth Map Completion [0.0]
This paper presents a non-deep learning-based approach to densify a sparse LiDAR-based depth map using a guidance RGB image.
The evaluation of this work is executed using the KITTI depth completion benchmark, which validates the proposed work.
arXiv Detail & Related papers (2021-06-14T09:19:47Z) - Depth Completion using Plane-Residual Representation [84.63079529738924]
We introduce a novel way of interpreting depth information with the closest depth plane label $p$ and a residual value $r$, as we call it, Plane-Residual (PR) representation.
By interpreting depth information in PR representation and using our corresponding depth completion network, we were able to acquire improved depth completion performance with faster computation.
arXiv Detail & Related papers (2021-04-15T10:17:53Z) - Virtual Normal: Enforcing Geometric Constraints for Accurate and Robust
Depth Prediction [87.08227378010874]
We show the importance of the high-order 3D geometric constraints for depth prediction.
By designing a loss term that enforces a simple geometric constraint, we significantly improve the accuracy and robustness of monocular depth estimation.
We show state-of-the-art results of learning metric depth on NYU Depth-V2 and KITTI.
arXiv Detail & Related papers (2021-03-07T00:08:21Z) - Depth Completion using Piecewise Planar Model [94.0808155168311]
A depth map can be represented by a set of learned bases and can be efficiently solved in a closed form solution.
However, one issue with this method is that it may create artifacts when colour boundaries are inconsistent with depth boundaries.
We enforce a more strict model in depth recovery: a piece-wise planar model.
arXiv Detail & Related papers (2020-12-06T07:11:46Z) - Balanced Depth Completion between Dense Depth Inference and Sparse Range
Measurements via KISS-GP [14.158132769768578]
Estimating a dense and accurate depth map is the key requirement for autonomous driving and robotics.
Recent advances in deep learning have allowed depth estimation in full resolution from a single image.
Despite this impressive result, many deep-learning-based monocular depth estimation algorithms have failed to keep their accuracy yielding a meter-level estimation error.
arXiv Detail & Related papers (2020-08-12T08:07:55Z) - Occlusion-Aware Depth Estimation with Adaptive Normal Constraints [85.44842683936471]
We present a new learning-based method for multi-frame depth estimation from a color video.
Our method outperforms the state-of-the-art in terms of depth estimation accuracy.
arXiv Detail & Related papers (2020-04-02T07:10:45Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.