1 / 27

Imaging System for Mesopic Vision

CHIBA UNIV. Imaging System for Mesopic Vision. H.Yaguchi, Y.Ushio, K.Kikuchi, D.K.Thahn, J.Shin, and S.Shioiri* Chiba University and Tohoku University*. Rod Scotopic vision. Cone Photopic vision. Introduction. Human visual system covers Illuminance range from 10 -3 lx to 10 5 lx.

ethan
Download Presentation

Imaging System for Mesopic Vision

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. CHIBA UNIV. Imaging System for Mesopic Vision H.Yaguchi, Y.Ushio, K.Kikuchi, D.K.Thahn, J.Shin, and S.Shioiri* Chiba University and Tohoku University*

  2. Rod Scotopic vision Cone Photopic vision Introduction Human visual system covers Illuminance range from 10-3 lx to 105 lx. Rod and cone Mesopic vision

  3. How does color appearance change with illuminance? To predict color appearance in mesopic vision from the photopic image.

  4. Outline • Experiment of the haploscopic color matching. • A mesopic color appearance model. • A imaging system for mesopic color appearance. • Examples of mesopic color images.

  5. Color appearance in mesopic vision 10 1000 lx 0.01 1000 lx 0.1 1000 lx 1 1000 lx 100 1000 lx •Haploscopic color matching technique 1000 1000 lx

  6. Color appearance in mesopic vision •Stimuli Test field 48 Munsel color chips …chromatic: 45,achromatic: 3 Matching field 21” CRT display (SONY Multiscan G500) Controlled by VSG (15 bits color, Cambridge System) Stimulus size… 1010º

  7. Results: Hue and Chroma • Chroma reduces continuously with decrease of the illuminance level until 0.01 lx. • The loci of matching color on the a*-b* diagram are not straight for many test color chips, indicating that hue shifts with the change in illuminance level.

  8. Results: Chroma • Reddish and yellowish color (Y, YR, R, RP, P):Chroma rapidly decreases from 100 to 1 lx, and constant below 0.1 lx. • Greenish and bluish color (PB, B,BG, G, GY): Chroma rapidly decreases from 1000 to 1 lx, does not change below 1 lx.

  9. Results: Lightness • Reddish and yellowish color: Lightness gradually reduces from 10 to 0.01 lx. • Greenish and bluish color: Minimum lightness is observed around 10 to 1 lx.

  10. Results: Achromatic Lightness • The Stevens effect: Perceived lightness range is reduced with decreasing illuminance.

  11. Correlation between perceived lightness at 0.01 lx and photopic and scotopic luminance Photopic luminance Scotopic luminance

  12. A Color Appearance Model in Mesopic Vision • Luminance channel: L+M • Red/green opponent-color: L-2M • Yellow-blue opponent-color: L+M-S

  13. Luminance as a function of illuminance A(E) = (E)100 ((Lp+Mp) / (Lp+Mp)w)+(E) 78.4(Y ’ / Y ’w) Lp , Mp , Sp: cone outputs at photopic condition Y’: scotopic luminance factor (Lp+Mp)w , Y’w: each output of luminance channels for white (being 100 = Kw)  (E),  (E):Weighting coefficients for functions of illuminance E

  14. Change of cone- and rod-signal as a function of illuminance A(E) = (E)100 ((Lp+Mp) / (Lp+Mp)w)+(E)78.4(Y ’ / Y ’w)

  15. Red/green- and yellow/blue opponent channel as a function of illuminance Outputs of r/gandy/bchannelsat illuminancelevel of E r/g(E) = l(E)(Lp-2Mp) + (E) Y ’ y/b(E) = m(E)(Lp+Mp-Sp) + (E) Y ’ Lp , Mp , Sp: cone outputs at photopic condition Y’: scotopic luminance factor l (E),  (E)and m (E), (E):Weighting coefficients for functions of illuminance E

  16. Comparison between Experimental Results and Prediction: Hue and Chroma

  17. Comparison between Experimental Results and Prediction: Lightness

  18. A Color Appearance Model in Mesopic Vision • Chromatic components decrease with decreasing illuminance. • Hue shifts are predicted by introducing a different process for red/green and yellow/blue opponent-color channel.

  19. Performance of a model • Average E*ab in mesopic range is around 3.

  20. Imaging System for Mesopic Vision

  21. Imaging System for Mesopic Vision

  22. Xp R Yp G Zp B Yp’ To obtain XYZ and Y’ from Digital Camera RGB Predicted Value Measured Value X Camera model Y Minimize error Z Y’

  23. Calibration of Camera Color Sample・・・Macbeth Color Checker and GretagMacbeth ColorCheker Digital Camera・・・Canon,EOS1-Ds ・Image size4064×2704 pixels ・QuantizationRGB 12 bits

  24. R3 G3 B3 R2G R2B ・ ・ ・ BR R G B 1 a1 b1 c1 ・・・・・・・・r1 s1 t1 a2 b2 c2 ・・・・・・・・r2 s2 t2 a3 b3 c3 ・・・・・・・・r3 s3 t3 a4 b4 c4 ・・・・・・・・r4 s4 t4 Xp Yp Zp Yp’ = Camera Model Coefficients a, b,,,t are obtained by the pseudo-inverse method.

  25. Camera performance as a colorimeter Average color difference⊿E*ab =2.23 Maximum color difference ⊿Eab =9.03 Original Macbeth Color Checker Predicted by a Camera Macbeth Color Checker

  26. : 0.998 Coefficient of Correlation : 1.000 Slope Prediction of scotopic luminance Y’ by camera RGB Predicted value Measured value

  27. 10(lx) 100(lx) 1(lx) 0.1(lx) 0.01(lx) Examples of mesopic color image Original

More Related