Your search keyword '"Monocular depth estimation"' showing total 465 results

451. Perceptual monocular depth estimation

Author

Pan, Janice S.

Subjects

Monocular depth estimation, Natural scene statistics, Depth estimation, Perceptual depth estimation, Bivariate natural scene statistics, Bivariate correlation

Abstract

Monocular depth estimation (MDE), which is the task of using a single image to predict scene depths, has gained considerable interest, in large part owing to the popularity of applying deep learning methods to solve “computer vision problems”. Monocular cues provide sufficient data for humans to instantaneously extract an understanding of scene geometries and relative depths, which is evidence of both the processing power of the human visual system and the predictive power of the monocular data. However, developing computational models to predict depth from monocular images remains challenging. Hand-designed MDE features do not perform particularly well, and even current “deep” models are still evolving. Here we propose a novel approach that uses perceptually-relevant natural scene statistics (NSS) features to predict depths from monocular images in a simple, scale-agnostic way that is competitive with state-of-the-art systems. While the statistics of natural photographic images have been successfully used in a variety of image and video processing, analysis, and quality assessment tasks, they have never been applied in a predictive end-to-end deep-learning model for monocular depth. Here we accomplish this by developing a new closed-form bivariate model of image luminances and use features extracted from this model and from other NSS models to drive a novel deep learning framework for predicting depth given a single image. We then extend our perceptually-based MDE model to fisheye images, which suffer from severe spatial distortions, and we show that our method that uses monocular cues performs comparably to our best fisheye stereo matching approach. Fisheye cameras have become increasingly popular in automotive applications, because they provide a wider (approximately 180 degrees) field-of-view (FoV), thereby giving drivers and driver assistance systems more visibility with minimal hardware. We explore fisheye stereo as it pertains to the problem of automotive surround-view (SV), specifically, which is a system comprising four fisheye cameras positioned on the front, right, rear, and left sides of a vehicle. The SV system perspectively transforms the images captured by these four cameras and stitches them together in a birdseye-view representation of the scene centered around the ego vehicle to display to the driver. With the camera axes oriented orthogonally away from each other and with each camera capturing approximately 180 degrees laterally, there exists an overlap in FoVs between adjacent cameras. It is within these regions where we have stereo vision, and can thus triangulate depths with an appropriate correspondence matching method. Each stereo system within the SV configuration has a wide baseline and two orthogonally-divergent camera axes, both of which make traditional methods for estimating stereo correspondences perform poorly. Our stereo pipeline, which relies on a neural network trained for predicting stereo correspondences, performs well even when the stereo system has limited overlap in FoVs and two dissimilar views. Our monocular approach, however, can be applied to entire fisheye images and does not rely on the underlying geometry of the stereo configuration. We compare these two depth-prediction methods in both performance and application. To explore stereo correspondence matching using fisheye images and MDE in non-fisheye images, we also generated a large-scale photorealistic synthetic database containing co-registered RGB images and depth maps using a simulated SV camera configuration. The database was first captured using fisheye cameras with known intrinsic parameters, and the fisheye distortions were then removed to create the non-fisheye portion of the database. We detail the process of creating the synthetic-but-realistic city scene in which we captured the images and depth maps along with the methodology for generating such a large, varied, and generalizable dataset

Published

2020

452. On the benefit of adversarial training for monocular depth estimation.

Author

Groenendijk, Rick, Karaoglu, Sezer, Gevers, Theo, and Mensink, Thomas

Subjects

IMAGE reconstruction, STEREO image, PIXELS

Abstract

In this paper we address the benefit of adding adversarial training to the task of monocular depth estimation. A model can be trained in a self-supervised setting on stereo pairs of images, where depth (disparities) are an intermediate result in a right-to-left image reconstruction pipeline. For the quality of the image reconstruction and disparity prediction, a combination of different losses is used, including L1 image reconstruction losses and left–right disparity smoothness. These are local pixel-wise losses, while depth prediction requires global consistency. Therefore, we extend the self-supervised network to become a Generative Adversarial Network (GAN), by including a discriminator which should tell apart reconstructed (fake) images from real images. We evaluate Vanilla GANs, LSGANs and Wasserstein GANs in combination with different pixel-wise reconstruction losses. Based on extensive experimental evaluation, we conclude that adversarial training is beneficial if and only if the reconstruction loss is not too constrained. Even though adversarial training seems promising because it promotes global consistency, non-adversarial training outperforms (or is on par with) any method trained with a GAN when a constrained reconstruction loss is used in combination with batch normalisation. Based on the insights of our experimental evaluation we obtain state-of-the art monocular depth estimation results by using batch normalisation and different output scales. • GANs are useful when the reconstruction loss is not too constrained. • When using a constrained loss, non-adversarial training outperforms GAN training. • Evaluating reconstruction losses at many scales over-regularises the final disparity. • Batch normalisation improves depth prediction quality significantly. [ABSTRACT FROM AUTHOR]

Published

2020

453. Monocular Depth Estimation with Joint Attention Feature Distillation and Wavelet-Based Loss Function.

Author

Liu P, Zhang Z, Meng Z, and Gao N

Abstract

Depth estimation is a crucial component in many 3D vision applications. Monocular depth estimation is gaining increasing interest due to flexible use and extremely low system requirements, but inherently ill-posed and ambiguous characteristics still cause unsatisfactory estimation results. This paper proposes a new deep convolutional neural network for monocular depth estimation. The network applies joint attention feature distillation and wavelet-based loss function to recover the depth information of a scene. Two improvements were achieved, compared with previous methods. First, we combined feature distillation and joint attention mechanisms to boost feature modulation discrimination. The network extracts hierarchical features using a progressive feature distillation and refinement strategy and aggregates features using a joint attention operation. Second, we adopted a wavelet-based loss function for network training, which improves loss function effectiveness by obtaining more structural details. The experimental results on challenging indoor and outdoor benchmark datasets verified the proposed method's superiority compared with current state-of-the-art methods.

Published

2020

454. Real-Time Single Image Depth Perception in the Wild with Handheld Devices.

Author

Aleotti F, Zaccaroni G, Bartolomei L, Poggi M, Tosi F, and Mattoccia S

Abstract

Depth perception is paramount for tackling real-world problems, ranging from autonomous driving to consumer applications. For the latter, depth estimation from a single image would represent the most versatile solution since a standard camera is available on almost any handheld device. Nonetheless, two main issues limit the practical deployment of monocular depth estimation methods on such devices: (i) the low reliability when deployed in the wild and (ii) the resources needed to achieve real-time performance, often not compatible with low-power embedded systems. Therefore, in this paper, we deeply investigate all these issues, showing how they are both addressable by adopting appropriate network design and training strategies. Moreover, we also outline how to map the resulting networks on handheld devices to achieve real-time performance. Our thorough evaluation highlights the ability of such fast networks to generalize well to new environments, a crucial feature required to tackle the extremely varied contexts faced in real applications. Indeed, to further support this evidence, we report experimental results concerning real-time, depth-aware augmented reality and image blurring with smartphones in the wild.

Published

2020

455. Unsupervised Monocular Depth Estimation Based on Residual Neural Network of Coarse–Refined Feature Extractions for Drone.

Author

Huang, Tao, Zhao, Shuanfeng, Geng, Longlong, and Xu, Qian

Subjects

FEATURE extraction, BINOCULAR vision, IMAGE processing, IMAGE reconstruction, SUPERVISED learning, MODEL railroads, DECONVOLUTION (Mathematics)

Abstract

To take full advantage of the information of images captured by drones and given that most existing monocular depth estimation methods based on supervised learning require vast quantities of corresponding ground truth depth data for training, the model of unsupervised monocular depth estimation based on residual neural network of coarse–refined feature extractions for drone is therefore proposed. As a virtual camera is introduced through a deep residual convolution neural network based on coarse–refined feature extractions inspired by the principle of binocular depth estimation, the unsupervised monocular depth estimation has become an image reconstruction problem. To improve the performance of our model for monocular depth estimation, the following innovations are proposed. First, the pyramid processing for input image is proposed to build the topological relationship between the resolution of input image and the depth of input image, which can improve the sensitivity of depth information from a single image and reduce the impact of input image resolution on depth estimation. Second, the residual neural network of coarse–refined feature extractions for corresponding image reconstruction is designed to improve the accuracy of feature extraction and solve the contradiction between the calculation time and the numbers of network layers. In addition, to predict high detail output depth maps, the long skip connections between corresponding layers in the neural network of coarse feature extractions and deconvolution neural network of refined feature extractions are designed. Third, the loss of corresponding image reconstruction based on the structural similarity index (SSIM), the loss of approximate disparity smoothness and the loss of depth map are united as a novel training loss to better train our model. The experimental results show that our model has superior performance on the KITTI dataset composed by corresponding left view and right view and Make3D dataset composed by image and corresponding ground truth depth map compared to the state-of-the-art monocular depth estimation methods and basically meet the requirements for depth information of images captured by drones when our model is trained on KITTI. [ABSTRACT FROM AUTHOR]

Published

2019

456. SemanticDepth: Fusing Semantic Segmentation and Monocular Depth Estimation for Enabling Autonomous Driving in Roads without Lane Lines.

Author

Palafox, Pablo R., Betz, Johannes, Nobis, Felix, Riedl, Konstantin, and Lienkamp, Markus

Subjects

*BRAIN-computer interfaces, *OPEN source software, *POINT cloud, *DRIVER assistance systems

Abstract

Typically, lane departure warning systems rely on lane lines being present on the road. However, in many scenarios, e.g., secondary roads or some streets in cities, lane lines are either not present or not sufficiently well signaled. In this work, we present a vision-based method to locate a vehicle within the road when no lane lines are present using only RGB images as input. To this end, we propose to fuse together the outputs of a semantic segmentation and a monocular depth estimation architecture to reconstruct locally a semantic 3D point cloud of the viewed scene. We only retain points belonging to the road and, additionally, to any kind of fences or walls that might be present right at the sides of the road. We then compute the width of the road at a certain point on the planned trajectory and, additionally, what we denote as the fence-to-fence distance. Our system is suited to any kind of motoring scenario and is especially useful when lane lines are not present on the road or do not signal the path correctly. The additional fence-to-fence distance computation is complementary to the road's width estimation. We quantitatively test our method on a set of images featuring streets of the city of Munich that contain a road-fence structure, so as to compare our two proposed variants, namely the road's width and the fence-to-fence distance computation. In addition, we also validate our system qualitatively on the Stuttgart sequence of the publicly available Cityscapes dataset, where no fences or walls are present at the sides of the road, thus demonstrating that our system can be deployed in a standard city-like environment. For the benefit of the community, we make our software open source. [ABSTRACT FROM AUTHOR]

Published

2019

457. A Semi-Supervised Monocular Stereo Matching Method.

Author

Zhang, Zhimin, Qiao, Jianzhong, and Lin, Shukuan

Subjects

*PIPELINES

Abstract

Supervised monocular depth estimation methods based on learning have shown promising results compared with the traditional methods. However, these methods require a large number of high-quality corresponding ground truth depth data as supervision labels. Due to the limitation of acquisition equipment, it is expensive and impractical to record ground truth depth for different scenes. Compared to supervised methods, the self-supervised monocular depth estimation method without using ground truth depth is a promising research direction, but self-supervised depth estimation from a single image is geometrically ambiguous and suboptimal. In this paper, we propose a novel semi-supervised monocular stereo matching method based on existing approaches to improve the accuracy of depth estimation. This idea is inspired by the experimental results of the paper that the depth estimation accuracy of a stereo pair as input is better than that of a monocular view as input in the same self-supervised network model. Therefore, we decompose the monocular depth estimation problem into two sub-problems, a right view synthesized process followed by a semi-supervised stereo matching process. In order to improve the accuracy of the synthetic right view, we innovate beyond the existing view synthesis method Deep3D by adding a left-right consistency constraint and a smoothness constraint. To reduce the error caused by the reconstructed right view, we propose a semi-supervised stereo matching model that makes use of disparity maps generated by a self-supervised stereo matching model as the supervision cues and joint self-supervised cues to optimize the stereo matching network. In the test, the two networks are able to predict the depth map directly from a single image by pipeline connecting. Both procedures not only obey geometric principles, but also improve estimation accuracy. Test results on the KITTI dataset show that this method is superior to the current mainstream monocular self-supervised depth estimation methods under the same condition. [ABSTRACT FROM AUTHOR]

Published

2019

458. SemanticDepth: Fusing Semantic Segmentation and Monocular Depth Estimation for Enabling Autonomous Driving in Roads without Lane Lines.

Author

R Palafox P, Betz J, Nobis F, Riedl K, and Lienkamp M

Abstract

Typically, lane departure warning systems rely on lane lines being present on the road.However, in many scenarios, e.g., secondary roads or some streets in cities, lane lines are eithernot present or not sufficiently well signaled. In this work, we present a vision-based method tolocate a vehicle within the road when no lane lines are present using only RGB images as input.To this end, we propose to fuse together the outputs of a semantic segmentation and a monoculardepth estimation architecture to reconstruct locally a semantic 3D point cloud of the viewed scene.We only retain points belonging to the road and, additionally, to any kind of fences or walls thatmight be present right at the sides of the road. We then compute the width of the road at a certainpoint on the planned trajectory and, additionally, what we denote as the fence-to-fence distance.Our system is suited to any kind of motoring scenario and is especially useful when lane lines arenot present on the road or do not signal the path correctly. The additional fence-to-fence distancecomputation is complementary to the road's width estimation. We quantitatively test our methodon a set of images featuring streets of the city of Munich that contain a road-fence structure, so asto compare our two proposed variants, namely the road's width and the fence-to-fence distancecomputation. In addition, we also validate our system qualitatively on the Stuttgart sequence of thepublicly available Cityscapes dataset, where no fences or walls are present at the sides of the road,thus demonstrating that our system can be deployed in a standard city-like environment. For thebenefit of the community, we make our software open source.

Published

2019

459. Detekce a klasifikace objektů zájmu zalévacího robotu zpracováním obrazu

Author

Krejsa, Jiří, Šnajder, Jan, Sladký, Jiří, Krejsa, Jiří, Šnajder, Jan, and Sladký, Jiří

Abstract

Tato práce se zabývá obrazovým zpracováním na autonomním zaléváním mobilním robotu s využitím embedded počítače NVIDIA Jetson Nano. Vybrána a aplikována byla metoda pro detekci objektů YOLOv5, která sloužila k detekci květin a květináčů. Pomocí metody pro monokulární predikci MiDaS byla predikována relativní hloubková mapa. Vytvořen byl algoritmus, který pomocí dat z LiDARu převedl tuto mapu na metrickou. Díky tomu mohla být určena vzdálenost detekovaných květin. Vytvořené nástroje byly implementovány v prostředí ROS a otestovány na reálných datech z vnitřního prostředí., This thesis deals with image processing on autonomous watering mobile robot using embedded computer NVIDIA Jetson Nano. A method for object detection, YOLOv5, was chosen, which served for detection of flowers and flower pots. Using a method for monocular depth estimation, MiDaS, relative depth map was predicted. An algorithm was created, which converted this map to metric depth map using data from LiDAR. Thanks to that, distance of the detected flowers could be estimated. The created tools were implemented in ROS framework and tested on real data form indoor environment.

460. Detekce a klasifikace objektů zájmu zalévacího robotu zpracováním obrazu

Author

Krejsa, Jiří, Šnajder, Jan, Sladký, Jiří, Krejsa, Jiří, Šnajder, Jan, and Sladký, Jiří

Abstract

Tato práce se zabývá obrazovým zpracováním na autonomním zaléváním mobilním robotu s využitím embedded počítače NVIDIA Jetson Nano. Vybrána a aplikována byla metoda pro detekci objektů YOLOv5, která sloužila k detekci květin a květináčů. Pomocí metody pro monokulární predikci MiDaS byla predikována relativní hloubková mapa. Vytvořen byl algoritmus, který pomocí dat z LiDARu převedl tuto mapu na metrickou. Díky tomu mohla být určena vzdálenost detekovaných květin. Vytvořené nástroje byly implementovány v prostředí ROS a otestovány na reálných datech z vnitřního prostředí., This thesis deals with image processing on autonomous watering mobile robot using embedded computer NVIDIA Jetson Nano. A method for object detection, YOLOv5, was chosen, which served for detection of flowers and flower pots. Using a method for monocular depth estimation, MiDaS, relative depth map was predicted. An algorithm was created, which converted this map to metric depth map using data from LiDAR. Thanks to that, distance of the detected flowers could be estimated. The created tools were implemented in ROS framework and tested on real data form indoor environment.

461. Detekce a klasifikace objektů zájmu zalévacího robotu zpracováním obrazu

Author

Krejsa, Jiří, Šnajder, Jan, Krejsa, Jiří, and Šnajder, Jan

Abstract

Tato práce se zabývá obrazovým zpracováním na autonomním zaléváním mobilním robotu s využitím embedded počítače NVIDIA Jetson Nano. Vybrána a aplikována byla metoda pro detekci objektů YOLOv5, která sloužila k detekci květin a květináčů. Pomocí metody pro monokulární predikci MiDaS byla predikována relativní hloubková mapa. Vytvořen byl algoritmus, který pomocí dat z LiDARu převedl tuto mapu na metrickou. Díky tomu mohla být určena vzdálenost detekovaných květin. Vytvořené nástroje byly implementovány v prostředí ROS a otestovány na reálných datech z vnitřního prostředí., This thesis deals with image processing on autonomous watering mobile robot using embedded computer NVIDIA Jetson Nano. A method for object detection, YOLOv5, was chosen, which served for detection of flowers and flower pots. Using a method for monocular depth estimation, MiDaS, relative depth map was predicted. An algorithm was created, which converted this map to metric depth map using data from LiDAR. Thanks to that, distance of the detected flowers could be estimated. The created tools were implemented in ROS framework and tested on real data form indoor environment.

462. Detekce a klasifikace objektů zájmu zalévacího robotu zpracováním obrazu

Author

Krejsa, Jiří, Šnajder, Jan, Krejsa, Jiří, and Šnajder, Jan

Abstract

Tato práce se zabývá obrazovým zpracováním na autonomním zaléváním mobilním robotu s využitím embedded počítače NVIDIA Jetson Nano. Vybrána a aplikována byla metoda pro detekci objektů YOLOv5, která sloužila k detekci květin a květináčů. Pomocí metody pro monokulární predikci MiDaS byla predikována relativní hloubková mapa. Vytvořen byl algoritmus, který pomocí dat z LiDARu převedl tuto mapu na metrickou. Díky tomu mohla být určena vzdálenost detekovaných květin. Vytvořené nástroje byly implementovány v prostředí ROS a otestovány na reálných datech z vnitřního prostředí., This thesis deals with image processing on autonomous watering mobile robot using embedded computer NVIDIA Jetson Nano. A method for object detection, YOLOv5, was chosen, which served for detection of flowers and flower pots. Using a method for monocular depth estimation, MiDaS, relative depth map was predicted. An algorithm was created, which converted this map to metric depth map using data from LiDAR. Thanks to that, distance of the detected flowers could be estimated. The created tools were implemented in ROS framework and tested on real data form indoor environment.

463. Detekce a klasifikace objektů zájmu zalévacího robotu zpracováním obrazu

Author

Krejsa, Jiří, Šnajder, Jan, Krejsa, Jiří, and Šnajder, Jan

Abstract

Tato práce se zabývá obrazovým zpracováním na autonomním zaléváním mobilním robotu s využitím embedded počítače NVIDIA Jetson Nano. Vybrána a aplikována byla metoda pro detekci objektů YOLOv5, která sloužila k detekci květin a květináčů. Pomocí metody pro monokulární predikci MiDaS byla predikována relativní hloubková mapa. Vytvořen byl algoritmus, který pomocí dat z LiDARu převedl tuto mapu na metrickou. Díky tomu mohla být určena vzdálenost detekovaných květin. Vytvořené nástroje byly implementovány v prostředí ROS a otestovány na reálných datech z vnitřního prostředí., This thesis deals with image processing on autonomous watering mobile robot using embedded computer NVIDIA Jetson Nano. A method for object detection, YOLOv5, was chosen, which served for detection of flowers and flower pots. Using a method for monocular depth estimation, MiDaS, relative depth map was predicted. An algorithm was created, which converted this map to metric depth map using data from LiDAR. Thanks to that, distance of the detected flowers could be estimated. The created tools were implemented in ROS framework and tested on real data form indoor environment.

464. Depth Estimation for Egocentric Rehabilitation Monitoring Using Deep Learning Algorithms

Author

Yasaman Izadmehr, Héctor F. Satizábal, Kamiar Aminian, and Andres Perez-Uribe

Subjects

Fluid Flow and Transfer Processes, single-image depth prediction, Process Chemistry and Technology, monocular depth estimation, free-living monitoring, wearable devices, context awareness, upper-limb neurological disorders, quality of movement, rehabilitation, General Engineering, stroke, Computer Science Applications, General Materials Science, activity recognition, Instrumentation

Abstract

Upper limb impairment is one of the most common problems for people with neurological disabilities, affecting their activity, quality of life (QOL), and independence. Objective assessment of upper limb performance is a promising way to help patients with neurological upper limb disorders. By using wearable sensors, such as an egocentric camera, it is possible to monitor and objectively assess patients’ actual performance in activities of daily life (ADLs). We analyzed the possibility of using Deep Learning models for depth estimation based on a single RGB image to allow the monitoring of patients with 2D (RGB) cameras. We conducted experiments placing objects at different distances from the camera and varying the lighting conditions to evaluate the performance of the depth estimation provided by two deep learning models (MiDaS & Alhashim). Finally, we integrated the best performing model for depth-estimation (MiDaS) with other Deep Learning models for hand (MediaPipe) and object detection (YOLO) and evaluated the system in a task of hand-object interaction. Our tests showed that our final system has a 78% performance in detecting interactions, while the reference performance using a 3D (depth) camera is 84%.

465. Detekce a klasifikace objektů zájmu zalévacího robotu zpracováním obrazu

Author

Krejsa, Jiří, Šnajder, Jan, Sladký, Jiří, Krejsa, Jiří, Šnajder, Jan, and Sladký, Jiří

Abstract

Tato práce se zabývá obrazovým zpracováním na autonomním zaléváním mobilním robotu s využitím embedded počítače NVIDIA Jetson Nano. Vybrána a aplikována byla metoda pro detekci objektů YOLOv5, která sloužila k detekci květin a květináčů. Pomocí metody pro monokulární predikci MiDaS byla predikována relativní hloubková mapa. Vytvořen byl algoritmus, který pomocí dat z LiDARu převedl tuto mapu na metrickou. Díky tomu mohla být určena vzdálenost detekovaných květin. Vytvořené nástroje byly implementovány v prostředí ROS a otestovány na reálných datech z vnitřního prostředí., This thesis deals with image processing on autonomous watering mobile robot using embedded computer NVIDIA Jetson Nano. A method for object detection, YOLOv5, was chosen, which served for detection of flowers and flower pots. Using a method for monocular depth estimation, MiDaS, relative depth map was predicted. An algorithm was created, which converted this map to metric depth map using data from LiDAR. Thanks to that, distance of the detected flowers could be estimated. The created tools were implemented in ROS framework and tested on real data form indoor environment.