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将空间频率信息从粗到细地编码到视觉短期记忆中,用于面孔,但没有偏见的衰退。

Coarse-to-fine encoding of spatial frequency information into visual short-term memory for faces but impartial decay.

机构信息

Department of Psychology, Zhejiang University, Hangzhou, People’s Republic of China.

出版信息

J Exp Psychol Hum Percept Perform. 2011 Aug;37(4):1051-64. doi: 10.1037/a0023091.

DOI:10.1037/a0023091
PMID:21500938
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3240681/
Abstract

Face perception studies investigated how spatial frequencies (SF) are extracted from retinal display while forming a perceptual representation, or their selective use during task-imposed categorization. Here we focused on the order of encoding low-spatial frequencies (LSF) and high-spatial frequencies (HSF) from perceptual representations into visual short-term memory (VSTM). We also investigated whether different SF-ranges decay from VSTM at different rates during a study-test stimulus-onset asynchrony. An old/new VSTM paradigm was used in which two broadband faces formed the positive set and the probes preserved either low or high SF ranges. Exposure time of 500 ms was sufficient to encode both HSF and LSF in the perceptual representation (experiment 1). Nevertheless, when the positive-set was exposed for 500 ms, LSF-probes were better recognized in VSTM compared with HSF-probes; this effect vanished at 800-ms exposure time (experiment 2). Backward masking the positive set exposed for 800 ms re-established the LSF-probes advantage (experiment 3). The speed of decay up to 10 seconds was similar for LSF- and HSF-probes (experiment 4). These results indicate that LSF are extracted and consolidated into VSTM faster than HSF, supporting a coarse-to-fine order, while the decay from VSTM is not governed by SF.

摘要

面孔知觉研究调查了在形成知觉表象的过程中,视网膜显示器如何提取空间频率(SF),或者在任务强制分类过程中如何有选择地使用这些频率。在这里,我们专注于从知觉表象中编码低空间频率(LSF)和高空间频率(HSF)到视觉短期记忆(VSTM)的顺序。我们还研究了在研究-测试刺激呈现时间间隔期间,不同 SF 范围是否以不同的速率从 VSTM 中衰减。使用了一种旧/新的 VSTM 范式,其中两个宽带面孔形成了正集,而探针保留了低或高 SF 范围。500ms 的曝光时间足以在知觉表象中编码 HSF 和 LSF(实验 1)。然而,当正集曝光 500ms 时,与 HSF 探针相比,LSF 探针在 VSTM 中更好地被识别;这种效应在 800ms 的曝光时间下消失(实验 2)。800ms 曝光的正向掩蔽重新建立了 LSF 探针的优势(实验 3)。LSF-和 HSF-探针的衰减速度在 10 秒内相似(实验 4)。这些结果表明,LSF 比 HSF 更快地被提取并整合到 VSTM 中,支持从粗到细的顺序,而 VSTM 的衰减不受 SF 控制。

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