Johnston James C, Ruthruff Eric, Lien Mei-Ching
NASA Ames Research Center, Moffett Field, California
University of New Mexico, Albuquerque.
Hum Factors. 2015 Mar;57(2):276-97. doi: 10.1177/0018720814545974. Epub 2014 Aug 4.
In this study, we examined how effectively people can monitor new stimuli on a peripheral display while carrying out judgments on an adjacent central display.
Improved situation awareness is critical for improved operator performance in aviation and many other domains. Given the limited extent of foveal processing, acquiring additional information from peripheral vision offers high potential gains.
Participants carried out a sequence of central perceptual judgments while simultaneously monitoring the periphery for new stimuli. Peripheral detection was measured as a function of central-judgment difficulty, the relative timing of the two tasks, and peripheral event rate.
Participants accurately detected and located peripheral targets, even at the highest eccentricity explored here (~30°). Peripheral detection was not reduced by increased central-task difficulty but was reduced when peripheral targets arrived later in the processing of central stimuli and when peripheral events were relatively rare.
Under favorable conditions-high-contrast stimuli and high event rate-people can successfully monitor peripheral displays for new events while carrying out an unrelated continuous task on an adjacent display.
In many fields, such as aviation, existing displays were designed with low-contrast stimuli that provide little opportunity for peripheral vision. With appropriate redesign, operators might successfully monitor multiple displays over a large visual field. Designers need to be aware of nonvisual factors, such as low event rate and relative event timing, that can lead to failures to detect peripheral stimuli.
在本研究中,我们考察了人们在对相邻中央显示屏进行判断时,能够多有效地监测周边显示屏上的新刺激。
提高态势感知能力对于提高航空及许多其他领域的操作员绩效至关重要。鉴于中央凹处理范围有限,从周边视觉获取额外信息具有很大的潜在收益。
参与者在对中央进行一系列感知判断的同时,还要监测周边是否有新刺激。周边检测作为中央判断难度、两项任务的相对时间以及周边事件发生率的函数进行测量。
参与者能够准确检测并定位周边目标,即使在此处探索的最高偏心度(约30°)下也是如此。周边检测不会因中央任务难度增加而降低,但当周边目标在中央刺激处理后期到达以及周边事件相对较少时,检测会降低。
在有利条件下——高对比度刺激和高事件发生率——人们在对相邻显示屏执行不相关的连续任务时,能够成功监测周边显示屏上的新事件。
在许多领域,如航空领域,现有的显示屏设计采用低对比度刺激,几乎没有利用周边视觉的机会。通过适当重新设计,操作员可能能够在大视野范围内成功监测多个显示屏。设计师需要意识到可能导致无法检测周边刺激的非视觉因素,如低事件发生率和相对事件时间。
