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Scott-samuel, Nicholas E.; Ashida, Hiroshi; Lovell, P. George; Meese, Tim S. and Schwarzkopf, D. Samuel (2018). Stacking chairs:local sense and global nonsense. i-Perception, 9 (1), pp. 1-5.
Meese, Tim S. (2015). Debazzled:a blue and black ship, dressed to deceive. i-Perception, 6 (2), pp. 111-115.
Summers, Robert J.; Baker, Daniel H. and Meese, Tim S. (2015). Area summation of first- and second-order modulations of luminance. Journal of Vision, 15 (1),
Baldwin, Alex S.; Husk, Jesse S.; Meese, Tim S. and Hess, Robert F. (2014). A two-stage model of orientation integration for Battenberg-modulated micropatterns. Journal of Vision, 14 (1),
Baker, Daniel H. and Meese, Tim S. (2013). Regarding the benefit of zero-dimensional noise. Journal of Vision, 13 (10),
Baker, Daniel H.; Meese, Tim S. and Georgeson, Mark A. (2013). Paradoxical psychometric functions ("swan functions") are explained by dilution masking in four stimulus dimensions. i-Perception, 4 (1), pp. 17-35.
Georgeson, Mark A.; Wallis, Stuart A.; Meese, Tim S. and Baker, Daniel H. Contrast and lustre:a model that accounts for eleven different forms of contrast discrimination in binocular vision. Vision Research, 129 , pp. 98-118.
Baker, Daniel H. and Meese, Tim S. Contrast integration over area is extensive: a three-stage model of spatial summation. Journal of Vision, 11 (14), pp. 1-16.
Baldwin, Alex S. and Meese, Tim S. Fourth-root summation of contrast over area:no end in sight when spatially inhomogeneous sensitivity is compensated by a witch's hat. Journal of Vision, 15 (15), pp. 1-12.
Baker, Daniel H. and Meese, Tim S. Grid-texture mechanisms in human vision:contrast detection of regular sparse micro-patterns requires specialist templates. Scientific Reports, 6 ,
Meese, Tim S. and Baker, Daniel H. A common rule for integration and suppression of luminance contrast across eyes, space, time, and pattern. i-Perception, 4 (1), pp. 1-16.
Meese, Tim S. A re-evaluation of achromatic spatiotemporal vision:nonoriented filters are monocular, they adapt and can be used for decision-making at high flicker speeds. i-Perception, 2 (4), p. 417.