视听时、空一致性对Pip-and-Pop效应的影响

doi:10.3724/SP.J.1041.2022.01310

摘要/Abstract

摘要：

多感觉整合遵循空间原则和时间原则, 有研究表明Pip-and-Pop效应产生的原因是多感觉整合, 那么Pip-and-Pop效应是否同样遵循空间原则和时间原则呢?本研究采用动态视觉搜索范式, 通过两个眼动实验考察空间一致性(实验1)和时间一致性(实验2)对Pip-and-Pop效应的影响。结果发现：(1)当视觉目标颜色变化伴随一个同侧的听觉刺激时所产生的Pip-and-Pop效应最大, 对侧条件没有发现Pip-and-Pop效应。(2)视听刺激同时呈现所产生的Pip-and-Pop效应最大, 随视听刺激呈现时间间隔的增加Pip-and-Pop效应逐渐减弱直至消失。结果表明, 视听时、空一致性对Pip-and-Pop效应具有调节作用, 这为多感觉整合在产生Pip-and-Pop效应中的作用提供了证据。

关键词: Pip-and-Pop效应, 视听空间一致性, 视听时间一致性, 动态视觉搜索范式, 眼动技术

Abstract:

Previous studies usually used the dynamic visual search paradigm to explore the Pip-and-Pop effect, which suggests that the Pip-and-Pop effect is influenced by multiple factors. But the impact of temporal and spatial consistency of audiovisual stimuli on the Pip-and-Pop effect is still controversial. In the present study, we applied the eye movement technology to the dynamic visual search paradigm to systematically investigate the impact of temporal and spatial consistency of audiovisual stimuli on the Pip-and-Pop effect. Based on the results of previous studies, we expected that the spatial and temporal consistency of audiovisual modulated the Pip-and-Pop effect. The more consistent the spatial location of audiovisual stimuli are, the greater the Pip-and-Pop effect will be. The more consistent the temporal audiovisual stimuli are, the greater the Pip-and-Pop effect will be.

Experiment 1 was a 3 (set sizes: 36, 48, 60) × 4 (spatial consistency conditions: ipsilateral, contralateral, bilateral, no sound) within-subjects design, recruited 24 participants (5 males; age range: 19~28 years; mean age: 22.5 ± 2.3 years). The visual search displays consisted of 24, 36, or 48 red (13.9 cd/m²) or green (46.4 cd/m²) line segments (0.57°×0.17°) on a black (0.4 cd/m²) background. The auditory stimulus was 1000 Hz pure tone (65 dB, 60 ms, including 5 ms fade-in and 5 ms fade-out time), presented through speakers on the left and right sides behind the screen. Each trial started with a drift calibration point. The drift calibration point would not disappear until the participant gazed upon this point. This was followed by a central fixation point of 1000ms, and finally a search screen. The participants were required to find the target line segment and judge whether the target line segment was vertical or horizontal by pressing the key (Z key or M key) as quickly and accurately as possible. Experiment 2 was a 2 (set sizes: 36, 60) × 6 (temporal consistency conditions: -200 ms, -100 ms, 0 ms, 100 ms, 200 ms, no sound) within-subjects design, recruited 27 participants (5 males; age range: 18~25 years; mean age: 20.7 ± 2.4 years). These temporal consistency conditions represent the tone sounded before (-200, -100 ms), simultaneous with (0 ms), or after (100, 200 ms) the visual target event. The tone could also be absent (no sound). The experimental materials and procedures of Experiment 2 were identical to those in Experiment1.

Regarding the results in Experiment 1, compared with the baseline condition (no sound), the search response time was the shortest under the condition of ipsilateral, the mean fixation number was the least, and the mean saccade amplitude was the smallest, indicating that the search efficiency was the highest in the ipsilateral condition, the Pip-and-Pop effect was the largest in the ipsilateral condition. The bilateral condition was the second. The contralateral condition showed no significant difference in the above indicators compared with the no sound condition, indicating that no Pip-and-Pop effect was found in the contralateral condition. The results showed that the more consistent the spatial location of audiovisual stimuli were, the greater the Pip-and-Pop effect was. In Experiment 2, compared with the no sound condition, we found that the response time of the search was significantly shorter, the mean fixation number in search decreased, the mean saccade amplitude increased, and the mean fixation duration became longer under the conditions of 0 ms, -100 ms and 100 ms. Compared with the no sound condition, conditions -200 ms and 200 ms showed no significant difference in the above indicators. This indicated that the conditions of 0 ms, -100 ms and 100 ms produced the Pip-and-Pop effect, and the Pip-and-Pop effect was the largest under the condition of 0ms, while the Pip-and-Pop effect did not find under the condition of -200 ms and 200 ms. The results showed that the more consistent the temporal audiovisual stimuli were, the greater the Pip-and-Pop effect was.

In summary, the results showed that the more consistent the audiovisual stimuli were in space and time, the larger the Pip-and-Pop effect was. Therefore, the findings in the present study suggest that the temporal and spatial consistency of audiovisual stimuli modulates the Pip-and-Pop effect. The results provide evidence that the reason for the Pip-and-Pop effect is multisensory integration.

Key words: Pip-and-Pop effect, audiovisual spatial consistency, audiovisual temporal consistency, dynamic visual search, eye movement technique

中图分类号:

B842

唐晓雨, 崔鑫忠, 高敏, 袁梦莹. (2022). 视听时、空一致性对Pip-and-Pop效应的影响. 心理学报, 54(11), 1310-1324.

TANG Xiaoyu, CUI Xinzhong, GAO Min, YUAN Mengying. (2022). The impact of temporal and spatial consistency of audiovisual stimuli on Pip-and-Pop effect. Acta Psychologica Sinica, 54(11), 1310-1324.

图/表 5

图1 实验1流程图和视听刺激呈现条件图注：图1a为实验1流程图, 首先进行漂移校准, 校准后呈现中央注视点, 1000 ms后呈现搜索屏。搜索屏以视听刺激条件中的无声音条件为例, 视觉刺激以搜索集36为例, 包括35个干扰线段, 1个目标线段。图1b分别为视听刺激条件中的同侧条件、对侧条件、双侧条件(详情阅读方法部分)。

图2 实验1结果图注：图a、b、c、d分别为不同条件下的反应时(s)、平均注视次数(次)、平均眼跳幅度(度)、平均注视时间(ms)的结果。

图3 实验1眼动轨迹和热点图注：图3a分别为4种声音条件的眼动轨迹图, 其中黄色线路代表眼动轨迹, 小圆圈代表注视次数。图3b为各个条件之间对比的差异热点图, 其中每个热点图中vs左侧条件为蓝色, 右侧条件为红色。

图4 实验2流程和视听刺激条件图注：图4a为实验2流程图, 首先进行漂移校准, 校准后呈现中央注视点, 1000 ms后呈现搜索屏。搜索屏以视听刺激条件中的无声音条件为例, 视觉刺激以搜索集36为例, 包括35个干扰线段, 1个目标线段。图4b是6种TTI (听觉刺激与视觉刺激之间的时间间隔：tone-target-interval)条件, 其中黑色线段是指目标线段颜色变化; 灰色线段是指干扰线段颜色变化; 小喇叭是指发出听觉刺激(详情阅读方法部分)。

图5 实验2结果图注：图a、b、c、d分别为不同条件下的反应时(s)、平均注视次数(次)、平均眼跳幅度(度)、平均注视时间(ms)的结果。

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