Subjects: Psychology >> Social Psychology submitted time 2023-03-27 Cooperative journals: 《心理学报》
Abstract: Working memory representations can guide attention toward memory-matching objects. When the memory items match the targets of a visual search task, the allocation of working memory (WM) resources contributes to the establishment of attentional templates. The memory item that receives less WM resources than others does not guide attention, even when it is stored in WM. On the other hand, two memory items that receive equal amount of WM resources guide attention simultaneously. However, it is still controversial how WM representations guide attention when the memory items match the distractors of a visual search task. Some studies found that due to cognitive control, attention cannot be guided by WM representations when they match distractors. On the other hand, other studies found that attention can be guided by even two WM representations. Could the allocation of WM resources also influence attentional guidance, when the memory items match the distractors of a visual search task? In the present study, to answer the above question the allocation of WM resources was manipulated by varying the precision requirement of WM representations. Four experiments were carried out. Participants were asked to encode colors of items into WM and perform a subsequent memory test or a gap-location search task, which were presented randomly with an equal probability. The precision requirement of WM representations was manipulated by varying the magnitude of change between two memory test items. More precise memory representations were required to detect small changes between two memory test items than large changes. In Experiment 1, we investigated whether memory-based attentional capture was influenced by the precision requirement of WM representations. Participants were asked to memorize a color under a high or low precision requirement. In some trials, the memory color reappeared in the search task as a distractor. In Experiment 2, we investigated whether the memory-based attentional capture observed was related to the different active states of WM representations. Participants were asked to memorize two colors under a high or low precision requirement. An informative cue was presented simultaneously with the target colors to indicate which color would be tested more frequently. Each color reappeared in the search task with an equal probability. In Experiment 3, we investigated whether the precision requirement of WM representations influenced the number of WM representations that can simultaneously guide attention. Participants were asked to memorize one (memory-1) or two (memory-2) colors under high or low precision requirement conditions. Zero (match-0), one (match-1) or two (match-2) memory colors reappeared as distractors in the search task. In Experiment 4, we further explored the underlying mechanism by which precision requirement of WM representations influenced attentional guidance. The event-related potential (ERP) technique and the same experimental design as in Experiment 1 were used. The behavioral results showed that when retaining one item in WM, the capture effect under high precision requirement was larger than that under low precision requirement. When retaining two memory items under low precision requirement, the capture effect for distractors that matched with high-priority items was larger than that for distractors that matched with low-priority items, whereas when retaining two items under high precision requirement the capture effect for distractors that matched with high- and low-priority items showed no difference. Under high precision requirement, the capture effect for the memory-2/match-2 condition was larger than that for the memory-2/match-1 and memory-1/match-1 conditions, while under low precision requirement the capture effect for the memory-2/match-2 and memory-1/match-1 conditions showed no difference, with their capture effects being larger than that for the memory-2/match-1 condition. The ERP results showed that during the maintenance phase of WM, items under high precision requirement elicited larger negative slow waves (NSW) and a larger late positive component (LPC) than items under low precision requirement. During the search task, larger N2 for distractors and smaller N2-posterior contralateral component (N2pc) for targets were elicited under high precision requirement, when the distractors matched with the memory items than when the distractors mismatched with the memory items, whereas equal N2 and N2pc were elicited under low precision requirement, when the distractors matched or mismatched with the memory items. It can be concluded that in the contingent attentional capture paradigm, WM representations under high precise requirement can capture more attention than that under low precise requirement. Its underlying mechanism is that maintaining WM representations under high precision requirement costs more resources than that under low precision requirement, and therefore the resource for searching targets declines and the attention captured by memory-matching distractors increases.
Subjects: Psychology >> Experimental Psychology submitted time 2021-02-09
Abstract: 采用注意捕获范式,通过行为和事件相关脑电位(ERP)实验,探讨工作记忆表征精度加工需求对注意引导的影响,行为结果发现,在低精度加工需求条件下,只有一个工作记忆表征引导注意,且处于高激活状态的工作记忆表征产生的注意捕获大于低激活状态;而在高精度加工需求条件下,有两个工作记忆表征引导注意,且处于高、低激活状态的工作记忆表征产生的注意捕获没有差异。ERP结果显示,高精度加工需求条件下诱发的NSW和LPC大于低精度加工需求条件;在高精度加工需求条件下,干扰项与记忆项匹配比不匹配时,诱发更大的N2和更小的N2pc,而在低精度加工需求条件下,干扰项与记忆项匹配和不匹配时诱发的N2、N2pc没有差异。研究表明,工作记忆表征精度加工需求影响注意引导的机制可能是高精度加工需求下,工作记忆表征消耗的认知资源增加,搜索目标获得的资源减少,干扰项捕获的注意增加。
Peer Review Status:
Awaiting Review
Subjects: Psychology >> Experimental Psychology submitted time 2019-03-08
Abstract: Selective attention plays an important role in processing relevant information and ignoring irrelevant distractors. The relationship between visual working memory (VWM) and visual selective attention has been extensively studied. VWM is a complex system consisting of not only visual maintenance functions, but also executive control functions. High load on visual maintenance functions drains the capacity for perception and prevents distractors from being perceived, while high load on executive control functions drains the capacity available for active control and results in increased processing of irrelevant distractors. There are two types of load in VWM: capacity load referring to the number of items to be stored, and resolution load emphasizing the precision of the stored representations. It has been found that these two types of load exert opposite effects on selective attention. However the mechanism underlying the effects of different types of VWM load on selective attention is still unclear. In the present study, four experiments were designed to investigate how different types of VWM load affect selective attention. Thirty-six participants were enrolled in Experiment 1, 2 and 3, respectively, and 14 participants were enrolled in Experiment 4. Participants were asked to perform both a VWM task and a visual search task. In the VWM task, participants had to retain colors in VWM to perform a change detection task. There were three levels of VWM load: baseline load, high-capacity load and high-resolution load. In the baseline load condition, participants were required to retain two colors and the change between the memory colors and the probe colors was large. In the high-capacity load condition, participants had to retain four colors and the change between the memory colors and the probe colors was also large. In the high-resolution load condition, participants had to retain two colors and the change between the memory colors and the probe colors was small. In Experiment 1 and 2, the visual search task was a Flanker task that was presented either in the periphery or in the center of the memory array. The Flanker task was presented with the memory array simultaneously in Experiment 1 and sequentially in Experiment 2. In Experiment 3, the visual search task was a Navon task. It was presented after the memory array and only in the center of the memory array. In Experiment 4, a Flanker task was presented after the memory array and only in the center of the memory array. EEG data during the memory interval were recorded by a 64-channel amplifier using a standard 10-20 system. The results showed that high-capacity load and high-resolution load reduced Flanker interference, compared with baseline load, when the VWM task and the Flanker task were presented simultaneously, regardless of whether the Flanker task was presented in the periphery or in the center of the memory array. High-capacity load and high-resolution load also reduced Flanker interference, compared with baseline load, when the VWM task and the Flanker task were presented sequentially and the Flanker task was presented in the periphery of the memory array. Compared with baseline load, high-capacity load increased Flanker interference and high-resolution load reduced Flanker interference when the VWM task and the Flanker task were presented sequentially and the Flanker task was presented in the center of the memory array. Under the high-capacity load condition, the Navon interference for attending to global level was larger than that for attending to local level; under the high-resolution load condition, the Navon interference for attending to global level was smaller than that for attending to local level. ERP results showed that relative to the baseline load condition, the high-capacity load condition elicited smaller N2, whereas the high-resolution load condition elicited larger N2. In conclusion, when the Flanker task is presented during encoding stage of VWM, high-capacity load and high-resolution load reduce interference. When the Flanker task is presented in the periphery of the memory array during maintaining stage of VWM, high-capacity load and high-resolution load reduce interference. These findings support the load theory of selective attention. However, when the Flanker task is presented in the center of the memory array during the maintenance stage, high-capacity load and high-resolution load lead to opposite effects. High-resolution load reduce interference, while high-capacity load increase interference. The underlying mechanism is that the different patterns of neural activity associated with the two types of VWM load may result in different distribution of cognitive control resources to selective attention.
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