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

Palafox, Pablo; Betz, Johannes; Nobis, Felix; Riedl, Konstantin; Lienkamp, Markus

doi:10.3390/s19143224

Cited by 19 publications

(12 citation statements)

References 26 publications

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“…Accuracy and depth range: based on our evaluations, DeepV2D [50] marginally achieved the best performance compared to BTS [49] and the rest of the methods. On KITTI [31] dataset the model achieved 2.005 RMSE and threshold accuracy of 0.977 with δ < 1.25 3 . On NYUD-v2 [29] dataset it achieved 0.403 RMSE and threshold accuracy of 0.996 with δ < 1.25 3 .…”

Section: Comparison Analysis Based On Performancementioning

confidence: 94%

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Deep Learning-Based Monocular Depth Estimation Methods—A State-of-the-Art Review

Khan

Salahuddin

Javidnia

2020

Sensors

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Monocular depth estimation from Red-Green-Blue (RGB) images is a well-studied ill-posed problem in computer vision which has been investigated intensively over the past decade using Deep Learning (DL) approaches. The recent approaches for monocular depth estimation mostly rely on Convolutional Neural Networks (CNN). Estimating depth from two-dimensional images plays an important role in various applications including scene reconstruction, 3D object-detection, robotics and autonomous driving. This survey provides a comprehensive overview of this research topic including the problem representation and a short description of traditional methods for depth estimation. Relevant datasets and 13 state-of-the-art deep learning-based approaches for monocular depth estimation are reviewed, evaluated and discussed. We conclude this paper with a perspective towards future research work requiring further investigation in monocular depth estimation challenges.

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Section: Comparison Analysis Based On Performancementioning

confidence: 94%

“…Monocular depth estimation is a fundamental challenge in computer vision and has potential applications in robotics, scene understanding, 3D reconstruction and medical imaging [1][2][3][4]. This problem remains challenging as there are no reliable cues for perceiving depth from a single image.…”

Section: Introductionmentioning

confidence: 99%

Deep Learning-Based Monocular Depth Estimation Methods—A State-of-the-Art Review

Khan

Salahuddin

Javidnia

2020

Sensors

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“…As mentioned above, recent research studies use a method of adding a network reinforcing feature or segmentation information [36,40] and a loss model for geometry or light [16,33]. Intuitively, feature and semantic information are not appropriate for depth prediction due to the characteristics of colonoscopy images.…”

Section: Improved Self-supervised Trainingmentioning

confidence: 99%

Unsupervised Monocular Depth Estimation for Colonoscope System Using Feedback Network

Hwang

Park

Kim

et al. 2021

Sensors

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A colonoscopy is a medical examination used to check disease or abnormalities in the large intestine. If necessary, polyps or adenomas would be removed through the scope during a colonoscopy. Colorectal cancer can be prevented through this. However, the polyp detection rate differs depending on the condition and skill level of the endoscopist. Even some endoscopists have a 90% chance of missing an adenoma. Artificial intelligence and robot technologies for colonoscopy are being studied to compensate for these problems. In this study, we propose a self-supervised monocular depth estimation using spatiotemporal consistency in the colon environment. It is our contribution to propose a loss function for reconstruction errors between adjacent predicted depths and a depth feedback network that uses predicted depth information of the previous frame to predict the depth of the next frame. We performed quantitative and qualitative evaluation of our approach, and the proposed FBNet (depth FeedBack Network) outperformed state-of-the-art results for unsupervised depth estimation on the UCL datasets.

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“…In addition we had the possibility to create the track map by measuring the boundaries of the track manually with high-precision GPS. Another alternative for creating the track map was by using a deep learning semantic segmentation algorithm that was fused with a monocular depth estimation and was presented in [30]. Because the online performance of the automatic map creation was currently not reliable enough the manual map creation method by measuring the GPS was used.…”

Section: The Autonomous Software Stack From Tummentioning

confidence: 99%

Autonomous Driving—A Crash Explained in Detail

et al. 2019

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Since 2017, a research team from the Technical University of Munich has developed a software stack for autonomous driving. The software was used to participate in the Roborace Season Alpha Championship. The championship aims to achieve autonomous race cars competing with different software stacks against each other. In May 2019, during a software test in Modena, Italy, the greatest danger in autonomous driving became reality: A minor change in environmental influences led an extensively tested software to crash into a barrier at speed. Crashes with autonomous vehicles have happened before but a detailed explanation of why software failed and what part of the software was not working correctly is missing in research articles. In this paper we present a general method that can be used to display an autonomous vehicle disengagement to explain in detail what happened. This method is then used to display and explain the crash from Modena. Firstly a brief introduction into the modular software stack that was used in the Modena event, consisting of three individual parts—perception, planning, and control—is given. Furthermore, the circumstancescausing the crash are elaborated in detail. By presented and explaining in detail which softwarepart failed and contributed to the crash we can discuss further software improvements. As a result, we present necessary functions that need to be integrated in an autonomous driving software stack to prevent such a vehicle behavior causing a fatal crash. In addition we suggest an enhancement of the current disengagement reports for autonomous driving regarding a detailed explanation of the software part that was causing the disengagement. In the outlook of this paper we present two additional software functions for assessing the tire and control performance of the vehicle to enhance the autonomous.

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

Cited by 19 publications

References 26 publications

Deep Learning-Based Monocular Depth Estimation Methods—A State-of-the-Art Review

Deep Learning-Based Monocular Depth Estimation Methods—A State-of-the-Art Review

Unsupervised Monocular Depth Estimation for Colonoscope System Using Feedback Network

Autonomous Driving—A Crash Explained in Detail

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