GIS-Assisted Object Detection and Geospatial Localization

Ardeshir, Shervin; Zamir, Amir; Torroella, Alejandro; Shah, Mubarak

doi:10.1007/978-3-319-10599-4_39

Cited by 52 publications

(57 citation statements)

References 27 publications

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“…3. Impressive recent work by Ardeshir et al (2014) exploits GIS databases that contain geolocations of small scale objects, such as fire hydrants, traffic signals, trash cans, etc. to generate densely sampled hypothesized ground projections from query image view point.…”

Section: Related Workmentioning

confidence: 99%

Geo-localization using Volumetric Representations of Overhead Imagery

2015

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This paper addresses the problem of determining the location of a ground level image by using geo-referenced overhead imagery. The input query image is assumed to be given with no meta-data and the content of the image is to be matched to a priori constructed reference representations. The semantic breakdown of the content of the query image is provided through manual labeling; however, all processing involving the reference imagery and matching are fully automated. In this paper, a volumetric representation is proposed to fuse different modalities of overhead imagery and construct a 3D reference world. Attributes of this reference world such as orientation of the world surfaces, types of land cover, depth order of fronto-parallel surfaces are indexed and matched to the attributes of the surfaces manually marked on the query image. An exhaustive but highly parallelizable matching scheme is proposed and the performance is evaluated on a set of query images located in a coastal region in Eastern United States. The performance is compared to a baseline region reduction algorithm and to a landmark existence matcher that uses a 2D representation of the reference world. The proposed 3D geo-localization framework performs better than the 2D approach for 75 % of the query images.

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Section: Related Workmentioning

confidence: 99%

Geo-localization using Volumetric Representations of Overhead Imagery

2015

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“…The GSV imagery is employed in [16,17] in conjunction with social media, such as Twitter, to perform visualization and 3D rendering. Methods proposed in [22,23] target the inverse problem to the one addressed in this work: the street view camera position is inferred from access to geolocations of stationary objects. Much work has been done on monitoring and mapping from mobile LiDAR [24][25][26] and unmanned aerial vehicle (drones) [27,28].…”

Section: Related Workmentioning

confidence: 99%

Automatic Discovery and Geotagging of Objects from Street View Imagery

2018

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Abstract:Many applications, such as autonomous navigation, urban planning, and asset monitoring, rely on the availability of accurate information about objects and their geolocations. In this paper, we propose the automatic detection and computation of the coordinates of recurring stationary objects of interest using street view imagery. Our processing pipeline relies on two fully convolutional neural networks: the first segments objects in the images, while the second estimates their distance from the camera. To geolocate all the detected objects coherently we propose a novel custom Markov random field model to estimate the objects' geolocation. The novelty of the resulting pipeline is the combined use of monocular depth estimation and triangulation to enable automatic mapping of complex scenes with the simultaneous presence of multiple, visually similar objects of interest. We validate experimentally the effectiveness of our approach on two object classes: traffic lights and telegraph poles. The experiments report high object recall rates and position precision of approximately 2 m, which is approaching the precision of single-frequency GPS receivers.

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“…We can define G i as the set of 3D GPS coordinates belonging to the i th semantic segment in the GIS database which is in the field of view of the camera (in our case either a specific building or street) 1 , and g i as the two dimensional locations of the i th set of point in the image plane. A point from GIS will be projected as a vertical line on the image plane(as shown in figure 4).…”

Section: Projecting Gis Segmentsmentioning

confidence: 99%

“…In the context of utilizing GIS information, different computer vision applications have been proposed. Authors in [11,12] used GIS for registering aerial images using semantic segments and [1] leveraged GIS to improve the performance of object detection; however, to the best of our knowledge, leveraging GIS for the purpose of performing semantic/geo-semantic segmentation has not been pursued.…”

Section: Introductionmentioning

confidence: 99%

Geo-semantic segmentation

Ardeshir

Collins-Sibley

Shah

2015

2015 IEEE Conference on Computer Vision and Pattern Recognition (CVPR)

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The availability of GIS (Geographical Information System) databases for many urban areas, provides a valuable source of information for improving the performance of many computer vision tasks. In this paper, we propose a method which leverages information acquired from GIS databases to perform semantic segmentation of the image alongside with geo-referencing each semantic segment with its address and geo-location. First, the image is segmented into a set of initial super-pixels. Then, by projecting the information from GIS databases, a set of priors are obtained about the approximate location of the semantic entities such as buildings and streets in the image plane. However, there are significant inaccuracies (misalignments) in the projections, mainly due to inaccurate GPS-tags and camera parameters. In order to address this misalignment issue, we perform data fusion such that it improves the segmentation and GIS projections accuracy simultaneously with an iterative approach. At each iteration, the projections are evaluated and weighted in terms of reliability, and then fused with the super-pixel segmentations. First segmentation is performed using random walks, based on the GIS projections. Then the global transformation which best aligns the projections to their corresponding semantic entities is computed and applied to the projections to further align them to the content of the image. The iterative approach continues until the projections and segments are well aligned.

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GIS-Assisted Object Detection and Geospatial Localization

Cited by 52 publications

References 27 publications

Geo-localization using Volumetric Representations of Overhead Imagery

Geo-localization using Volumetric Representations of Overhead Imagery

Automatic Discovery and Geotagging of Objects from Street View Imagery

Geo-semantic segmentation

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