Bonnen Kathryn, Burge Johannes, Yates Jacob, Pillow Jonathan, Cormack Lawrence K
Department of Psychology and Institute for Neuroscience, University of Texas at Austin, Austin, TX, USA.
Department of Psychology, University of Pennsylvania, Philadelphia, PA, USA.
J Vis. 2015 Mar 20;15(3):14. doi: 10.1167/15.3.14.
We introduce a novel framework for estimating visual sensitivity using a continuous target-tracking task in concert with a dynamic internal model of human visual performance. Observers used a mouse cursor to track the center of a two-dimensional Gaussian luminance blob as it moved in a random walk in a field of dynamic additive Gaussian luminance noise. To estimate visual sensitivity, we fit a Kalman filter model to the human tracking data under the assumption that humans behave as Bayesian ideal observers. Such observers optimally combine prior information with noisy observations to produce an estimate of target position at each time step. We found that estimates of human sensory noise obtained from the Kalman filter fit were highly correlated with traditional psychophysical measures of human sensitivity (R2 > 97%). Because each frame of the tracking task is effectively a "minitrial," this technique reduces the amount of time required to assess sensitivity compared with traditional psychophysics. Furthermore, because the task is fast, easy, and fun, it could be used to assess children, certain clinical patients, and other populations that may get impatient with traditional psychophysics. Importantly, the modeling framework provides estimates of decision variable variance that are directly comparable with those obtained from traditional psychophysics. Further, we show that easily computed summary statistics of the tracking data can also accurately predict relative sensitivity (i.e., traditional sensitivity to within a scale factor).
我们引入了一种新颖的框架,该框架利用连续目标跟踪任务并结合人类视觉表现的动态内部模型来估计视觉敏感度。观察者使用鼠标光标跟踪二维高斯亮度斑点的中心,该斑点在动态加性高斯亮度噪声场中进行随机游走。为了估计视觉敏感度,我们在假设人类行为如同贝叶斯理想观察者的前提下,将卡尔曼滤波器模型拟合到人类跟踪数据上。此类观察者会最优地将先验信息与噪声观测相结合,以在每个时间步长生成目标位置的估计值。我们发现,从卡尔曼滤波器拟合中获得的人类感官噪声估计值与人类敏感度的传统心理物理学测量值高度相关(R2 > 97%)。由于跟踪任务的每一帧实际上都是一次“微型试验”,与传统心理物理学相比,该技术减少了评估敏感度所需的时间。此外,由于该任务快速、简单且有趣,它可用于评估儿童、某些临床患者以及其他可能对传统心理物理学不耐烦的人群。重要的是,该建模框架提供的决策变量方差估计值可直接与从传统心理物理学中获得的估计值相比较。此外,我们表明,跟踪数据的易于计算的汇总统计量也能够准确预测相对敏感度(即传统敏感度在比例因子范围内)。