Hue opponency: chromatic valence functions, individual differences, cortical winner-take-all opponent modeling, and the relationship between spikes and sensitivity

Vincent A. Billock

doi:10.1364/JOSAA.35.00B267

Journal of the Optical Society of America A
Vol. 35,
Issue 4,
pp. B267-B277
(2018)
•https://doi.org/10.1364/JOSAA.35.00B267

Hue opponency: chromatic valence functions, individual differences, cortical winner-take-all opponent modeling, and the relationship between spikes and sensitivity

Vincent A. Billock

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Vincent A. Billock, "Hue opponency: chromatic valence functions, individual differences, cortical winner-take-all opponent modeling, and the relationship between spikes and sensitivity," J. Opt. Soc. Am. A 35, B267-B277 (2018)

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- Color Appearance
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About this Article
History
- Original Manuscript: November 2, 2017
- Revised Manuscript: January 16, 2018
- Manuscript Accepted: January 31, 2018
- Published: March 16, 2018

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Abstract

Neural spike rate data are more restricted in range than related psychophysical data. For example, several studies suggest a compressive (roughly cube root) nonlinear relationship between wavelength-opponent spike rates in primate midbrain and color appearance in humans, two rather widely separated domains. This presents an opportunity to partially bridge a chasm between these two domains and to probe the putative nonlinearity with other psychophysical data. Here neural wavelength-opponent data are used to create cortical competition models for hue opponency. This effort led to creation of useful models of spiking neuron winner-take-all (WTA) competition and MAX selection. When fed with actual primate data, the spiking WTA models generate reasonable wavelength-opponent spike rate behaviors. An average psychophysical observer for red-green and blue-yellow opponency is curated from eight applicable studies in the refereed and dissertation literatures, with cancellation data roughly every 10 nm in 18 subjects for yellow-blue opponency and 15 subjects for red-green opponency. A direct mapping between spiking neurons with broadband wavelength sensitivity and human psychophysical luminance yields a power law exponent of 0.27, similar to the cube root nonlinearity. Similarly, direct mapping between the WTA model opponent spike rates and psychophysical opponent data suggests power law relationships with exponents between 0.24 and 0.41.

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Input/Intensity	Cross-Point (nm)	Peak (nm)
$+ R - G / Low$	586–603	633
$+ R - G / Med$	603–633	633
$+ R - G / High$	603–633	656
$Ave [+ R - G & + Y - B] / Low$	563–586	656
$Ave [+ R - G & + Y - B] / Med$	586–603	633
$Ave [+ R - G & + Y - B] / High$	563–586	633
$W Ave [+ R - G & + Y - B] / Low$	563–586	656
$W Ave [+ R - G & + Y - B] / Med$	586–603	633
$W Ave [+ R - G & + Y - B] / High$	586–603	633
$MAX [+ R - G & + Y - B] / Low$	563–586	603
$MAX [+ R - G & + Y - B] / Med$	563–586	603
$MAX [+ R - G & + Y - B] / High$	563–586	603

Reference #/Year	$r - g$ Subjects	$y - b$ Subjects	Range (nm)
[34]/(1955)	2	2	420–700
[37]/(1977)	5	5	420–650
[35] and [36]/(1976) and (1978)	2	2	420–700
[28]/(1978)	1	0	400–680
[4]/(1979)	3	3	400–700
[38]/(1983) ^a	1	3	420–690
[39]/(1989)	1	1	400–650
[40]/(1992) ^b	0	2	440–660
	15 total	18 total

$λ (nm)$	$r - g$	$y - b$	$y - b$ Class I	$y - b$ Class II
400	(+.0236)	(− .0749)	(−.1787)	(−.0413)
410	(+.0875)	(−.3484)	(−.4601)	(−.1453)
420	+.2463	−.9378	−.9763	−.7197
430	+.3403	− 1.3592	− 1.3894	− 1.2294
440	+.3659	− 1.6684	− 1.6684	− 1.6684
450	+.2992	− 1.4921	− 1.4410	− 1.5608
460	+.2186	− 1.2550	− 1.1010	− 1.5375
470	+.1067	− 1.0244	− 1.1013	− 1.3794
480	(−.1001)	−.6438	−.8484	−. 9762
490	−.2682	−.3429	−.4782	−.6478
500	−.5944	(−.2584)	−.1595	−.4267
510	− 1.0078	+.5615	+.5101	(−.2008)
520	− 1.3340	+.7025	+.7792	+.2046
530	− 1.4295	+.9427	+ 1.0350	+.3361
540	− 1.2968	+.9840	+ 1.1422	+.4147
550	− 1.0264	+ 1.0319	+ 1.1515	+.5305
560	−.6864	+ 1.0590	+ 1.0537	+.7165
570	−.3468	+ 1.1141	+.9630	+.9654
580	+.3507	+ 1.1515	+.9200	+ 1.1515
590	+.6050	+ 1.0889	+.8581	+ 1.1388
600	+.8619	+.8832	+.6937	+.8742
610	+.9689	+.6663	+.5543	+.6063
620	+.9004	+.4759	+.3765	+.4424
630	+.7150	+.3050	+.2443	+.2733
640	+.5099	+.1870	+.1536	+.1568
650	+.3284	+.1088	+.0907	+.0876
660	+.1993	+.0644	(+.0512)	+.0545
670	+.1137	(+.0286)	(+.0258)	(+.0207)
680	+.0575	(+.0126)	(+.0124)	(+.0093)
690	(+.0283)	(+.0066)	(+.0070)	(+.0040)
700	(+.0127)	(+.0026)	(+.0026)	(+.0021)

Condition	Exponent	$r^{2}$
Luminance	.265	.850
Long-wavelength red	.312	.955
Short-wavelength red	.268	.899
Green (no 480 nm)	.412	.847
Green (with 480 nm)	.176	.337
Blue	.268	.694
Yellow	.240	.453

Input/Intensity	Cross-Point (nm)	Peak (nm)
$+ R - G / Low$	586–603	633
$+ R - G / Med$	603–633	633
$+ R - G / High$	603–633	656
$Ave [+ R - G & + Y - B] / Low$	563–586	656
$Ave [+ R - G & + Y - B] / Med$	586–603	633
$Ave [+ R - G & + Y - B] / High$	563–586	633
$W Ave [+ R - G & + Y - B] / Low$	563–586	656
$W Ave [+ R - G & + Y - B] / Med$	586–603	633
$W Ave [+ R - G & + Y - B] / High$	586–603	633
$MAX [+ R - G & + Y - B] / Low$	563–586	603
$MAX [+ R - G & + Y - B] / Med$	563–586	603
$MAX [+ R - G & + Y - B] / High$	563–586	603

Abstract

Cited By

Figures (8)

Tables (4)

Equations (6)

Journal of the Optical Society of America A