最近研究发现, 注意力会对个体基于光流的自身运动方向感知的准确性和辨别阈限产生影响, 并提出该影响作用可能符合贝叶斯推理理论, 但尚未有研究明确建构一个计算模型对此进行验证。为此, 研究构建了一个贝叶斯推理模型。该模型假设在不同注意力负荷下不同方向似然分布的标准差 (即自身运动方向确定性) 各不相同。结果发现该模型可以很好地预测在不同注意力负荷下自身运动方向估计值的变化趋势。因此, 研究明确揭示了注意力对基于光流自身运动方向感知的影响符合贝叶斯推理模型, 且注意力可能通过调节自身运动方向内部表征的确定性来产生影响。
Abstract
Studies have shown that the perception of self-motion direction (i.e., heading) from optic flow is consistent with a Bayesian inference account when all attentional resources are allocated to this perception process. These studies generally proposed that the heading perception was a sensory-information driven process. Sun et al. (2024) were the first to demonstrate that attention affected the perception process. Specifically, when the attentional resources allocated to the heading estimation and discrimination task were reduced, both the estimation accuracy and discrimination sensitivity were reduced; additionally, when the attentional focus was biased towards one side of the center of the computer display, the heading estimates were systematically biased towards the attentional focus. Therefore, Sun et al. (2024) demonstrated that heading perception from optic flow was sensory-information and cognition driven process. However, no study was conducted to explore the computational mechanism underlying the effects of attention on the heading estimation from optic flow.
To address the above question, the current study developed a Bayesian inference model to explain the effects of attention on the heading perception from optic flow behaviorally observed in Sun et al. (2024). In the model, we proposed that participants’ heading estimates were derived from a posterior distribution ($p\left(\theta_{l} \mid M\right)$) that is the optimal combination between the prior ($p\left(M \mid 0\right)$) and the likelihood ($p\left(M \mid \theta_{l}\right)$), given as:
$p\left(\theta_{l} \mid M\right) \propto p(M \mid 0) \times p\left(M \mid \theta_{l}\right)$ Equation 1.
where M represents the heading estimate, is the actual heading. According to the previous studies (Saunders & Niehorster, 2010; Xing & Saunders, 2016; Xu et al., 2022), we propose that the likelihood distributions follow a Gaussian distribution, given as:
$p(M \mid 0)=\frac{1}{\sqrt{2 \pi} \sigma_{p}} e^{-\left(\frac{M-0}{\sqrt{2} \sigma_{p}}\right)^{2}}$ Equation 2.
$p\left(M \mid \theta_{l}\right)=\frac{1}{\sqrt{2 \pi} \sigma_{l}} e^{-\left(\frac{M-\theta_{l}}{\sqrt{2} \sigma_{l}}\right)^{2}},$ Equation 3.
In Equations 2 and 3, σp is the standard deviation of prior distribution. σl is the standard deviation of likelihood distribution. Previous studies typically took the discrimination threshold as the standard deviation of likelihood distribution (σl ) (Xing & Saunders, 2016). In Experiment 3 of Sun et al. (2024), they directly evaluated the σl s in the baseline and attention load conditions with the heading discrimination task. Therefore, only the standard deviation of prior distribution σp was free. We firstly developed a Bayesian inference model with the σl given by Experiment 3 to test the efficiency of the model. Following this step, we then set the σl to be free to predict the finding of Experiments 1b, 2a, and 2b in Sun et al. (2024). A Markov Chain, the Monte Carlo (MCMC) sampling method was employed to determine the best value of parameters.
The results showed that our model well explained the effects of attention on heading estimation from optic flow revealed in Sun et al. (2024). Meanwhile, the standard deviation of the likelihood distributions increased with the attentional load and was shifted by the attentional focus: the standard deviations were smaller for the headings close to the attentional focus than those far away from the attentional focus. These were all consistent with the behavioral findings of Sun et al. (2024).
In summary, the current study reveals that the effects of attention on heading estimation from optic flow can be predicted by the Bayesian inference model and attention affects heading perception by potentially modulating the certainties of headings’ internal representations, which increases our understanding of the computational process underlying heading perception from optic flow. It should be noted that our model is developed based on the fact that attention affects the activity of sensory neurons Dubin and Duffy (2007, 2009) that are positively correlated with the likelihood distributions. Next, we should directly build the likelihood distribution based on the tuning function of populational neurons to uncover the neural basis of the computational process, which will help us to understand the heading estimation mechanisms comprehensively.
关键词
注意力 /
自身运动方向感知 /
光流 /
贝叶斯推理模型
Key words
attention /
heading perception /
optic flow /
bayesian inference model
{{custom_sec.title}}
{{custom_sec.title}}
{{custom_sec.content}}
参考文献
[1] Angelaki D. E., Gu Y., & DeAngelis G. C. (2011). Visual and vestibular cue integration for heading perception in extrastriate visual cortex. The Journal of Physiology, 589(4), 825-833.
[2] Butts, D. A., & Goldman, M. S. (2006). Tuning curves, neuronal variability, and sensory coding. PLoS Biology, 4(4), e92.
[3] Crowell, J. A., & Banks, M. S. (1993). Perceiving heading with different retinal regions and types of optic flow. Perception and Psychophysics, 53(3), 325-337.
[4] Crowell, J. A., & Banks, M. S. (1996). Ideal observer for heading judgments. Vision Research, 36, 471-490.
[5] Dubin, M. J., & Duffy, C. J. (2007). Behavioral influences on cortical neuronal responses to optic flow. Cerebral Cortex, 17(7), 1722-1732.
[6] Dubin, M. J., & Duffy, C. J. (2009). Neuronal encoding of the distance traversed by covert shifts of spatial attention. Neuroreport, 20(1), 49-55.
[7] Gibson, J. J. (1950). The perception of the visual world. Houghton Mifflin.
[8] Girshick A. R., Landy M. S., & Simoncelli E. P. (2011). Cardinal rules: Visual orientation perception reflects knowledge of environmental statistics. Nature Neuroscience, 14(7), 926-932.
[9] Gu Y., Fetsch C. R., Adeyemo B., DeAngelis G. C., & Angelaki D. E. (2010). Decoding of MSTd population activity accounts for variations in the precision of heading perception. Neuron, 66(4), 596-609.
[10] Hahn, M., & Wei, X. X. (2024). A unifying theory explains seemingly contradictory biases in perceptual estimation. Nature Neuroscience, 27(4), 793-804.
[11] Harris L. R., Jenkin M., & Zikovitz D. C. (2000). Visual and non-visual cues in the perception of linear self motion. Experimental Brain Research, 135, 12-21.
[12] Jazayeri, M., & Shadlen, M. N. (2010). Temporal context calibrates interval timing. Nature Neuroscience, 13(8), 1020-1026.
[13] Lepsien, J., & Nobre, A. C. (2007). Attentional modulation of object representations in working memory. Cerebral Cortex, 17(9), 2072-2083.
[14] Ma W. J., Beck J. M., & Pouget A. (2008). Spiking networks for Bayesian inference and choice. Current Opinion in Neurobiology, 18(2), 217-222.
[15] Mao, J., & Stocker, A. A. (2024). Sensory perception is a holistic inference process. Psychological Review, 131(4), 858-890.
[16] Noel J. P., Zhang L. Q., Stocker A. A., & Angelaki D. E. (2021). Individuals with autism spectrum disorder have altered visual encoding capacity. PLoS Biology, 19(5), e3001215.
[17] Saunders, J. A., & Niehorster, D. C. (2010). A Bayesian model for estimating observer translation and rotation from optic flow and extra-retinal input. Journal of Vision, 10(10), 1-22.
[18] Stocker, A. A., & Simoncelli, E. P. (2006). Noise characteristics and prior expectations in human visual speed perception. Nature Neuroscience, 9(4), 578-585.
[19] Sun Q., Gong X. M., & Sun Q. (2025). Impact of conflicts between long-and short-term priors on the weighted prior integration in visual perception. Cognition, 254, 106006.
[20] Sun Q., Yan R., Wang J., & Li X. (2022). Heading perception from optic flow is affected by heading distribution. I-Perception, 13(6), 1-17.
[21] Sun Q., Zhan L. Z., Zhang B. Y., Jia S., & Gong X. M. (2023). Heading perception from optic flow occurs at both perceptual representation and working memory stages with EEG evidence. Vision Research, 208, 108235.
[22] Sun Q., Zhan L. Z., You F. H., & Dong X. F., (2024). Effects of attention on the perception of self-motion direction from optic flow, iScience, 27(4), 109373.
[23] Sun Q., Zhang H., Alais D., & Li L. (2020). Serial dependence and center bias in heading perception from optic flow. Journal of Vision, 20(10), 1-15.
[24] Theeuwes J., Kramer A. F., & Irwin D. E. (2011). Attention on our mind: The role of spatial attention in visual working memory. Acta Psychologica, 137(2), 248-251.
[25] Tomassini A., Morgan M. J., & Solomon J. A. (2010). Orientation uncertainty reduces perceived obliquity. Vision Research, 50(5), 541-547.
[26] Valenti L., Wada P. I., Basso G. R., Jackson M. C., & Galera C. (2021). Attentional load effects on emotional content in face working memory. Quarterly Journal of Experimental Psychology, 76(7). 1-41.
[27] Wang X. Y., Gong X. M., Sun Q., & Li X. (2022). Attractive effects of previous form information on heading estimation from optic flow occur at perceptual stage. Journal of Vision, 22(12), 1-18.
[28] Warren Jr, W. H., & Saunders, J. A. (1995). Perceiving heading in the presence of moving objects. Perception, 24(3), 315-331.
[29] Wei, X. X., & Stocker, A. A. (2012). Efficient coding provides a direct link between prior and likelihood in perceptual Bayesian inference. Advances in Neural Information Processing Systems, 25, 1-9.
[30] Wei, X. X., & Stocker, A. A. (2015). A Bayesian observer model constrained by efficient coding can explain 'anti-Bayesian' percepts. Nature Neuroscience, 18(10), 1509-1517.
[31] Wei, X. X., & Stocker, A. A. (2017). Lawful relation between perceptual bias and discriminability. Proceedings of the National Academy of Sciences, 114(38), 10244-10249.
[32] Xing, X., & Saunders, J. (2016). Center bias in perceived heading from optic flow. Journal of Vision, 16(12), 884.
[33] Xu L. H., Sun Q., Zhang B., & Li X. (2022). Attractive serial dependence in heading perception from optic flow occurs at the perceptual and postperceptual stages. Journal of Vision, 22(12), 1-11.
[34] Zhang L. Q., Mao J., Aguirre G. K., & Stocker A. A. (2024). The tilt illusion arises from an efficient reallocation of neural coding resources at the contextual boundary. bioRxiv.
基金
*本研究得到国家自然科学基金项目(32200842)的资助
PDF(2222 KB)
