Pelli Denis G, Tillman Katharine A, Freeman Jeremy, Su Michael, Berger Tracey D, Majaj Najib J
Psychology and Neural Science, New York University, New York, NY, USA.
J Vis. 2007 Oct 26;7(2):20.1-36. doi: 10.1167/7.2.20.
Bouma's law of crowding predicts an uncrowded central window through which we can read and a crowded periphery through which we cannot. The old discovery that readers make several fixations per second, rather than a continuous sweep across the text, suggests that reading is limited by the number of letters that can be acquired in one fixation, without moving one's eyes. That "visual span" has been measured in various ways, but remains unexplained. Here we show (1) that the visual span is simply the number of characters that are not crowded and (2) that, at each vertical eccentricity, reading rate is proportional to the uncrowded span. We measure rapid serial visual presentation (RSVP) reading rate for text, in both original and scrambled word order, as a function of size and spacing at central and peripheral locations. As text size increases, reading rate rises abruptly from zero to maximum rate. This classic reading rate curve consists of a cliff and a plateau, characterized by two parameters, critical print size and maximum reading rate. Joining two ideas from the literature explains the whole curve. These ideas are Bouma's law of crowding and Legge's conjecture that reading rate is proportional to visual span. We show that Legge's visual span is the uncrowded span predicted by Bouma's law. This result joins Bouma and Legge to explain reading rate's dependence on letter size and spacing. Well-corrected fluent observers reading ordinary text with adequate light are limited by letter spacing (crowding), not size (acuity). More generally, it seems that this account holds true, independent of size, contrast, and luminance, provided only that text contrast is at least four times the threshold contrast for an isolated letter. For any given spacing, there is a central uncrowded span through which we read. This uncrowded span model explains the shape of the reading rate curve. We test the model in several ways. We use a "silent substitution" technique to measure the uncrowded span during reading. These substitutions spoil letter identification but are undetectable when the letters are crowded. Critical spacing is the smallest distance between letters that avoids crowding. We find that the critical spacing for letter identification predicts both the critical spacing and the span for reading. Thus, crowding predicts the parameters that characterize both the cliff and the plateau of the reading rate curve. Previous studies have found worrisome differences across observers and laboratories in the measured peripheral reading rates for ordinary text, which may reflect differences in print exposure, but we find that reading rate is much more consistent when word order is scrambled. In all conditions tested--all sizes and spacings, central and peripheral, ordered and scrambled--reading is limited by crowding. For each observer, at each vertical eccentricity, reading rate is proportional to the uncrowded span.
布马拥挤定律预测,存在一个不拥挤的中央窗口,我们可以透过它进行阅读,而周边区域是拥挤的,无法进行阅读。早期的发现表明,读者每秒会进行多次注视,而不是在文本上连续扫视,这意味着阅读受到一次注视中能够获取的字母数量的限制,眼睛无需移动。“视觉广度”已经通过多种方式进行了测量,但仍未得到解释。在此我们表明:(1)视觉广度仅仅是未被拥挤的字符数量;(2)在每个垂直偏心度下,阅读速度与未被拥挤的广度成正比。我们测量了文本在原始和打乱单词顺序下的快速序列视觉呈现(RSVP)阅读速度,它是中央和周边位置字母大小和间距的函数。随着文本大小增加,阅读速度从零急剧上升到最大速度。这条经典的阅读速度曲线由一个悬崖和一个平台组成,其特征由两个参数决定,即临界印刷大小和最大阅读速度。将文献中的两个观点结合起来就能解释整个曲线。这两个观点分别是布马拥挤定律和莱格的猜想,即阅读速度与视觉广度成正比。我们表明,莱格的视觉广度就是布马定律所预测的未被拥挤的广度。这一结果将布马和莱格的观点结合起来,解释了阅读速度对字母大小和间距的依赖性。视力良好、阅读流畅且在光线充足条件下阅读普通文本的人,阅读受字母间距(拥挤)限制,而非大小(视敏度)。更普遍地说,似乎只要文本对比度至少是孤立字母阈值对比度的四倍,这一解释就成立,与大小、对比度和亮度无关。对于任何给定的间距,都存在一个我们用于阅读的中央未被拥挤的广度。这个未被拥挤的广度模型解释了阅读速度曲线的形状。我们通过多种方式对该模型进行了测试。我们使用“无声替换”技术来测量阅读过程中的未被拥挤的广度。这些替换会破坏字母识别,但当字母拥挤时则无法察觉。临界间距是避免拥挤的字母之间的最小距离。我们发现,字母识别的临界间距既能预测阅读的临界间距,也能预测阅读广度。因此,拥挤现象预测了表征阅读速度曲线悬崖和平台的参数。先前的研究发现,不同观察者和实验室测量的普通文本周边阅读速度存在令人担忧的差异,这可能反映了印刷品暴露程度的差异,但我们发现,当单词顺序打乱时,阅读速度更加一致。在所有测试条件下——所有大小和间距、中央和周边、有序和打乱——阅读都受拥挤现象限制。对于每个观察者,在每个垂直偏心度下,阅读速度与未被拥挤的广度成正比。
