Your search keyword '"luminous maps"' showing total 4 results

1. A Parametric Method for Remapping and Calibrating Fisheye Images for Glare Analysis

Author

Ayman Wagdy, Veronica Garcia-Hansen, Gillian Isoardi, and Kieu Pham

Subjects

pixel remapping, image remapping, fisheye lens calibration, field of view, photometric calibration, smartphones, fisheye projections, equidistant, equisolid angle, orthographic, glare analysis, luminous maps, daylighting, Building construction, TH1-9745

Abstract

High Dynamic Range (HDR) imaging using a fisheye lens has provided new opportunities to evaluate the luminous environment in visual comfort research. For glare analysis, strict calibration is necessary to extract accurate luminous maps to achieve reliable glare results. Most studies have focused on correcting the vignetting effect in HDR imaging during post-calibration. However, the lens projection also contributes to luminous map errors because of its inherent distortion. To date, there is no simple method to correct this distortion phenomenon for glare analysis. This paper presents a parametric-based methodology to correct the projection distortion from fisheye lenses for the specific use in glare analysis. HDR images were captured to examine two devices: a 190° equisolid SIGMA 8 mm F3.5 EX DG fisheye lens mounted on a Canon 5D camera, and a 195° fisheye commercial lens with an unknown projection, mounted on the rear camera of a Samsung Galaxy S7. A mathematical and geometrical model was developed to remap each pixel to correct the projection distortion using Grasshopper and MATLAB. The parametric-based method was validated using Radiance and MATLAB through checking the accuracy of pixel remapping and measuring color distortion with Structural Similarity Index (SSIM). Glare scores were used to compare the results between both devices, which validates the use of mobile phones in photometric research. The results showed that this method can be used to correct HDR images projection distortion for more accurate evaluation of the luminous environment in glare research.

Published

2019

2. A parametric method for remapping and calibrating fisheye images for glare analysis

Author

Ibrahim, Ayman Wagdy Mohamed, Garcia Hansen, Veronica, Isoardi, Gillian, Pham, Kieu-Mien, Ibrahim, Ayman Wagdy Mohamed, Garcia Hansen, Veronica, Isoardi, Gillian, and Pham, Kieu-Mien

Abstract

High Dynamic Range (HDR) imaging using a fisheye lens has provided new opportunities to evaluate the luminous environment in visual comfort research. For glare analysis, strict calibration is necessary to extract accurate luminous maps to achieve reliable glare results. Most studies have focused on correcting the vignetting effect in HDR imaging during post-calibration. However, the lens projection also contributes to luminous map errors because of its inherent distortion. To date, there is no simple method to correct this distortion phenomenon for glare analysis. This paper presents a parametric-based methodology to correct the projection distortion from fisheye lenses for the specific use in glare analysis. HDR images were captured to examine two devices: a 190° equisolid SIGMA 8 mm F3.5 EX DG fisheye lens mounted on a Canon 5D camera, and a 195° fisheye commercial lens with an unknown projection, mounted on the rear camera of a Samsung Galaxy S7. A mathematical and geometrical model was developed to remap each pixel to correct the projection distortion using Grasshopper and MATLAB. The parametric-based method was validated using Radiance and MATLAB through checking the accuracy of pixel remapping and measuring color distortion with Structural Similarity Index (SSIM). Glare scores were used to compare the results between both devices, which validates the use of mobile phones in photometric research. The results showed that this method can be used to correct HDR images projection distortion for more accurate evaluation of the luminous environment in glare research.

Published

2019

3. A Parametric Method for Remapping and Calibrating Fisheye Images for Glare Analysis

Author

Gillian Isoardi, Kieu-Mien Pham, Veronica Garcia Hansen, and Ayman Wagdy Mohamed Ibrahim

Subjects

Computer science, lcsh:TH1-9745, law.invention, law, Architecture, Computer vision, Projection (set theory), Civil and Structural Engineering, luminous maps, Vignetting, Pixel, business.industry, orthographic, Distortion (optics), glare analysis, Orthographic projection, daylighting, Glare (vision), Building and Construction, image remapping, fisheye projections, smartphones, Lens (optics), photometric calibration, Fisheye lens, fisheye lens calibration, pixel remapping, Artificial intelligence, business, field of view, equidistant, equisolid angle, lcsh:Building construction

Abstract

High Dynamic Range (HDR) imaging using a fisheye lens has provided new opportunities to evaluate the luminous environment in visual comfort research. For glare analysis, strict calibration is necessary to extract accurate luminous maps to achieve reliable glare results. Most studies have focused on correcting the vignetting effect in HDR imaging during post-calibration. However, the lens projection also contributes to luminous map errors because of its inherent distortion. To date, there is no simple method to correct this distortion phenomenon for glare analysis. This paper presents a parametric-based methodology to correct the projection distortion from fisheye lenses for the specific use in glare analysis. HDR images were captured to examine two devices: a 190&deg, equisolid SIGMA 8 mm F3.5 EX DG fisheye lens mounted on a Canon 5D camera, and a 195&deg, fisheye commercial lens with an unknown projection, mounted on the rear camera of a Samsung Galaxy S7. A mathematical and geometrical model was developed to remap each pixel to correct the projection distortion using Grasshopper and MATLAB. The parametric-based method was validated using Radiance and MATLAB through checking the accuracy of pixel remapping and measuring color distortion with Structural Similarity Index (SSIM). Glare scores were used to compare the results between both devices, which validates the use of mobile phones in photometric research. The results showed that this method can be used to correct HDR images projection distortion for more accurate evaluation of the luminous environment in glare research.

Published

2019

4. A Parametric Method for Remapping and Calibrating Fisheye Images for Glare Analysis.

Author

Wagdy, Ayman, Garcia-Hansen, Veronica, Isoardi, Gillian, and Pham, Kieu

Subjects

IMAGE analysis, CANON camera, GEOMETRIC modeling, VISUAL environment, CELL phones, STRUCTURAL colors, PIXELS

Abstract

High Dynamic Range (HDR) imaging using a fisheye lens has provided new opportunities to evaluate the luminous environment in visual comfort research. For glare analysis, strict calibration is necessary to extract accurate luminous maps to achieve reliable glare results. Most studies have focused on correcting the vignetting effect in HDR imaging during post-calibration. However, the lens projection also contributes to luminous map errors because of its inherent distortion. To date, there is no simple method to correct this distortion phenomenon for glare analysis. This paper presents a parametric-based methodology to correct the projection distortion from fisheye lenses for the specific use in glare analysis. HDR images were captured to examine two devices: a 190° equisolid SIGMA 8 mm F3.5 EX DG fisheye lens mounted on a Canon 5D camera, and a 195° fisheye commercial lens with an unknown projection, mounted on the rear camera of a Samsung Galaxy S7. A mathematical and geometrical model was developed to remap each pixel to correct the projection distortion using Grasshopper and MATLAB. The parametric-based method was validated using Radiance and MATLAB through checking the accuracy of pixel remapping and measuring color distortion with Structural Similarity Index (SSIM). Glare scores were used to compare the results between both devices, which validates the use of mobile phones in photometric research. The results showed that this method can be used to correct HDR images projection distortion for more accurate evaluation of the luminous environment in glare research. [ABSTRACT FROM AUTHOR]

Published

2019