Experiment 1 resulted in clear evidence that mask-target interactions exit in CFS. However, in real life as well as many laboratory experiments, there may be and frequently are more than just one feature and therefore more than one dimension of similarity between masks and target. It is unclear in which way different features contained in both mask in target may interact, or if different features affect suppression independently. Extending from Experiment 1, we added a second controlled dimension to our stimuli.
In an isoluminant color domain, we designed stimuli to modulate along one of two orthogonal color axes (referred to as red-green and blue-yellow) in addition to the orientational tuning from Experiment 1. If similarity between target and masks are important for continuous flash suppression, we would predict that suppression duration will be longer when mask and target vary along the same color direction (both red-green or blue-yellow) than when they vary along different color directions (red-green and blue-yellow, or blue-yellow and red-green).
We also investigated whether the orientational alignment between stimuli always dominates the suppression duration, or if the alignment effect in the orientation domain will interact with the color domain – if mask and stimulus are designed along different (orthogonal) color axis rather than identical ones, will there still be an effect of orientational alignment, or will the orthogonality in the color domain allow the visual system to “circumvent” the orientational domain and allow the target stimulus to break through faster?
Methods
Apparatus
The experimental apparatus was the same as in Experiment 1. The monitor was characterized with a X-Rite i1 pro 2. CIE1931 chromaticity coordinates and luminance of the monitor primaries were R = (0.6275, 0.3420, 18.8), G = (0.2870, 0.6108, 62.8), and B = (0.1483, 0.07232, 12.2). Gamma corrections without bit loss were applied based on the measured gamma curves of the monitor primaries.
Stimuli
Targets and Masks are illustrated in Figure 5. Similarity between target and masks was varied in orientation (as in Experiment 1) as well as color. Orientation was manipulated similar to Experiment 1. Mask stimuli were designed in the same four orientations as in Experiment 1, and target stimuli were designed in 11 angles of deviation, identical to Experiment 1, but omitting the angles of 1.5° and 3° in either direction to limit the overall number of conditions.
The color variation defining the stimuli could either be the same for target and masks, or different (orthogonal). We represented colors in CIELAB color space to manipulate color contrast along orthogonal dimensions. CIELAB allowed us to approximately control perceived contrasts because it is a color appearance model that aims at compensating nonlinearities of color perception and approximates perceived color differences 50,51. The adapting white-point was set to monitor white (xyY1931 = 0.2729, 0.2877, 93.7), and the grey background of all stimuli was achromatic (i.e., same chromaticities as white-point) at a lightness of L* = 70, which corresponds to a luminance of Y1931 = 38.2cd/m². The contrast of the Gabor patches was modulated either along a* (green-red) or along the orthogonal b* (blue-yellow) with a maximum CIELAB chroma of 40.
Continuous flash suppression strongly depends on contrast 29. While sensitivity to luminance contrast is band-pass with a peak at about 3-5cpd, chromatic contrast sensitivity is low-pass reaching the maximum at about 0.5cpd with little decrease towards lower frequencies 52 (for a rewiew see 53). This implies that chromatic contrasts are more difficult to see for medium and high spatial frequencies compared to low spatial frequencies. For this reason, target stimuli were designed with a four times lower spatial frequency (1 cpd) than in Experiment 1 (4 cpd). We also added a second kind of noise mask. For one condition, we created masks with pink noise (1/f) as in Experiment 1, and for the additional condition, masks with brown noise (1/f²). Compared to pink noise, brown noise features precisely the same amplitude at the spatial frequency of the target (1 cpd) but allocates a larger amount of spectral energy on lower spatial frequencies and may therefore have higher potency as a mask when targeting the (low-pass) color system.
Procedure
Modified from Experiment 1, the experiment consisted of 2 masking conditions (Pink noise and Brown noise) with 8 subconditions each (2 different color axis in 4 orientations), paired with 22 target conditions (2 different color axis in 11 deviations each), with a sum of 176 condition pairs for each masking condition and an additional 176 trials without masking, resulting in a total of 528 target-present trials plus an additional 10 catch trials (target absent). As before, the +90° and -90° mask orientations were pooled for the statistical analysis (see below). The order of all trials was randomized within each participant.
Participants
Fifteen individuals participated in the experiment (5 female, aged 19-35: mean = 23.3, SD = 4.3). All participants were students recruited from Yunnan University and were paid for their participation. The participants reported normal/corrected-to-normal vision and were naive to the purpose of the experiment.
Statistical Analysis
The median of the breakthrough contrast for each condition was computed per participant, and break-through contrast was analyzed by an ANOVA designs for repeated measures (see below). We report the original degrees of freedom, but corrected p-values and the Greenhouse–Geisser epsilon (εGG) where appropriate.
Results
Of the 15 participants, one had to be removed due to a large number of no-response trials (8% of the total number of trials, leading to conditions without data), and a second one due to too many responses in catch trials (60%). The remaining participants responded to an average 3% of catch trials (range: 0-10%), showed no response in 0.5% of trials (range: 0-1.7%) and responded too early (before target onset) in 0.5% of trials (range: 0-2.1%).
As in Experiment 1, we calculated median response times for each condition and participant to assess suppression effects. Figure 6 illustrates median response times averaged per stimulus condition. The comparison between the blue curve and the other curves suggests that pink noise produced the stronger suppression compared to brown noise, in particular when mask and target were designed along the same color axis (same-color pairings).
First, we conducted a one-way, repeated-measures ANOVA with the factor mask type (Pink noise, Brown noise or no masking) to test the statistical significance of continuous flash suppression in this experiment. The effect of mask type was significant (F(2,24)=31.15, p<0.001, η2=0.363, εGG=0.66), indicating significant continuous flash suppression even though isoluminant stimuli were used. We then examined whether all masks produced suppression effects. For this purpose, we conducted separate t-tests comparing each color pairing and noise-type condition (colored curves in Figure 6) with the baseline (grey curve in Figure 6). All t-test were significant (min t = 3.79, max p < 0.005, Bonferroni-corrected), suggesting that all masks produced some level of continuous flash suppression.
We then concentrated on the difference between pink and brown noise, removing the control condition without masking from the analysis. We calculated a four-way repeated ANOVA design for repeated measures with the noise type (pink noise or brown noise, 2 levels), mask orientation (4 different angles: [-45 0 45 90]), orientational deviation (10 angles: [±90 -45 -22.5 -11.25 -6.1 0 6.1 11.25 22.5 45]) and color pairing (same vs. different color between mask and target, 2 levels) as within-subject factors. Mean response time in the baseline condition was 1436ms, in the brown noise condition 1839ms (128% of baseline) with different-color pairings and 1841ms (128% of baseline) with same-color pairings, in the pink noise condition 2323ms (162% of baseline) with different-color pairings and 2435ms (170% of baseline) with same-color pairings. For the pink-noise, same-color pairings the minimum response time was 2146ms (146% of baseline) and the maximum was 2801ms (195% of baseline), resulting in a difference of 655ms or a 92% increase in suppression duration after baseline subtraction.
All four main effects were significant: First, the effects of the similarity between target and mask orientation (F(9,108) = 4.39, p=0.007, η2=0.268, εGG=0.386), and second, the effects of mask orientation (F(3,36)=3.27, p=0.032, η2=0.214) were similar to those observed in Experiment 1 (cf. Figure 3). The effect of color pairing between target and mask confirmed our prediction: suppression effects were generally stronger when target and mask were designed along the same color axis rather than different (F(1,12) = 5.50, p=0.037, η2=.314). This effect appears to be caused by the peak in suppression when mask and target orientations are aligned, which is strongly diminished if not entirely absent in different-color pairings. This indicates that same vs. different-color pairings achieve approximately the same overall suppression, however the increased suppression duration from orientational alignment between mask and target is mostly absent in different-color stimulus pairings. Fourth, and contrary to our prediction, pink noise yielded a higher suppression than brown noise masks (F(1,12)=40.43, p<0.001, η2=.771).
All two-way interactions were also significant: First, we reproduced the interaction between mask orientation and orientational deviation (F(27,324)=2.73, p<0.001, η2=0.185) observed in Experiment 1 (cf. Figure 3). Second, the significant interaction between orientational deviation and color congruence (pairing) (F(9,108)=3.08, p=0.020, η2=0.204) indicated a higher effect of orientation similarity with same-color pairings than with different-color pairings (cf. Figure 6). This is in line with the idea that suppression effects are highest for masks that are most similar to targets. Third, the interaction between type of noise (pink vs brown) and orientation similarity (F(9,108)=21.89, p=0.005, η2=0.98, εGG=0.37) showed that the effect of orientation similarity strongly occurred with pink noise masks, but barely with brown noise masks (different profile between red and blue, but similar profile for yellow and cyan curves in Figure 6). Fourth, the interaction between noise type and color congruence (F(1,12)=5.96, p=0.031, η2=0.332), implies that there was only an effect of color with pink, but barely any with brown noise masks (different height between red and blue, but similar height of yellow and cyan curves in Figure 6).
A three-way interaction further occurred between noise type, orientational deviation and color pairing (F(9,108)=2.22, p=0.026, η2=0.156). This interaction reflects the fact that the strongest suppression occurred when colors and orientations were very similar or the same for masks and targets, and when pink-noise was used for the mask (cf. center of blue curve in Figure 6). There was also a three-way interaction between noise type, mask orientation and orientation similarity (F(27,324)=1.52, p=0.049, η2=0.113), showing that oblique orientations of masks had strongest suppression effects in the condition with pink noise and different-color stimulus pairings (local maxima of red curve in Figure 6). There was no four-way interaction.
Discussion
Experiment 2 delivered clear evidence that isoluminant conditions can elicit CFS. An emphasis of lower spatial frequencies in the masks (brown noise), intended to improve suppression when using isoluminant color-defined stimuli, did however not lead to an improvement in suppression duration, and in fact reduced suppression duration similar to what one might have expected with luminance-based masks 21,29. It appears that pink noise is an optimal masking stimulus even under the increased perceptual demands placed on the visual system by the use of isoluminant stimuli. With Pink noise, in those conditions where both mask and target were designed along the same color axis, a strong effect of orientational alignment was found, similar to Experiment 1. This effect however was diminished when mask and target were of opposite color, suggesting that the effect of orientation on masking duration can be circumvented by the visual system by means of other, un-aligned feature dimensions. The suppression duration for orthogonal orientations was very similar between same color and different color pairings, indicating that basic suppression effectiveness with isoluminant stimuli is unaffected by differences in color, while the increased suppression duration from orientational alignment also requires alignment in the color domain. With the Brown noise masks, no effect of the orientational alignment became apparent, even in same-color conditions – even though overall significant suppression still occurred, as is evident from the comparison with the baseline condition.
In sum, both orientation and color similarity affected continuous flash suppression, but only with a pink-noise mask. The brown noise mask produced overall much weaker continuous flash suppression and barely varied as a function of orientation and color similarity (Figure 6).
The weaker suppression by brown-noise masks is in line with previous observations for achromatic (luminance) stimuli 29. If the congruence of spatial frequencies between targets and masks were key to the suppression effects, we expected similar effects of brown and pink noise for targets of 1 cpd. This, however, was not the case, suggesting a more complicated relationship between spatial frequencies of masks and targets. The precise nature of this relationship could be investigated by varying the spatial frequency of the target and the spatial frequency components of the noise mask to test what characteristics of spatial frequencies modulate continuous flash suppression.
Our results suggest that any kind of mask produces some level of continuous flash suppression, but that similarity may increase suppression effects. The role of similarity in continuous flash suppression is reminiscent of general forward and backward masking effects (i.e., without continuous flash). It has been suggested that forward and backward masking have similar effects to continuous flash suppression when tasks are designed to be comparable 54.