Psychology

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Now showing 1 - 5 of 5
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    Adaptive echolocation and flight behaviors in free-flying bats, Eptesicus fuscus
    (2008-10-22) Chiu, Chen; Moss, Cynthia F; Neuroscience and Cognitive Science; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Echolocating bats emit ultrasonic sonar pulses and listen to returning echoes, which are reflected from targets or obstacles, to probe their surroundings. Their biological sonar system is well-developed and highly adaptive to the dynamic acoustic environment. Bats are also agile flyers and they can modify their flight behavior in order to capture insects efficiently. Adaptable echolocation and flight behaviors evolved in bats in response to environmental demands. This study employed changes in the external ear of bats and in the acoustic environment to examine how the big brown bat, Eptesicus fuscus, modifies its echolocation call design and flight patterns to cope with these new experimental conditions. Study one investigated the influences of changes in sound localization cues on prey capture behavior. The tragus, which is part of the external ear, is believed to contribute to sound localization in the vertical plane. Deflecting the tragus affected prey capture performance of the bat, but it adapted to this manipulation by adjusting its flight behavior. The tragus-deflected bat tended to attack the prey item from above and show lower tangential velocity and larger bearing from the side, compared with its flight pattern in the tragus intact conditions. The bat did not change its echolocation call design in the tragus-deflected condition. Study two paired two bats together and allowed them to perform a prey capture task in a large flight room. Echolocating bats showed two adaptive strategies in their echolocation behavior when flying with another conspecific. The bat either stopped vocalizing or increased its difference in call design from the other bat. In addition, one bat tended to follow another bat when flying together and antagonistic behavior was found in male-male and female-male pairs. The pursuit strategy the bat uses to track another bat is different from the strategy it uses to capture flying insects. This thesis confirms that the big brown bat's echolocation and flight behaviors are highly adaptable and describes several strategies the bat employs to cope with changes in sound localization cues and conspecific interference.
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    Testing a dynamic account of neural processing: Behavioral and electrophsyiological studies of semantic satiation
    (2008-08-13) Tian, Xing; Dougherty, Michael; Neuroscience and Cognitive Science; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    In everyday perception, we easily and automatically identify objects. However, there is evidence that this ability results from complicated interactions between levels of perception. An example of hierarchical perception is accessing the meaning of visually presented words through the identification of line segments, letters, lexical entries, and meaning. Studies of word reading demonstrate a dynamic course to identification, producing benefits following brief presentations (excitation) but deficits following longer presentations (habituation). This dissertation investigates hierarchical perception and the role of transient excitatory and habituation dynamics through behavioral and neural studies of word reading. More specifically, the effect of interest is 'semantic satiation', which refers to the gradual loss of meaning when repeating a word. The reported studies test the hypothesis that habituation occurs in the associations between levels. As applied to semantic satiation, this theory supposes that there is not a loss of meaning, but, rather, an inability to access meaning from a repeated word. This application was tested in three behavioral experiments using a speeded matching task, demonstrating that meaning is lost when accessing the meaning of a repeated category label, but is not lost when accessing the category through new exemplars, or when the matching task is changed to simple word matching. To model these results, it is assumed that speeded matching results from detection of novel meaning to the target word after presentation of the cue word. This model was tested by examining neural dynamics with MEG recordings. As predicted by semantic satiation through loss of association, repeated cue words produced smaller M170 responses. M400 responses to the cue also diminished, as expected by a hierarchy in which lower levels drive higher levels. If the M400 corresponds to the post-lexical detection of new meaning, this model predicted that the M400 to targets following repeated cues would increase. This unique prediction was confirmed. These results were tested using a new method of analyzing MEG data that can differentiate between response magnitude versus differences in activity patterns. By considering hierarchical perception and processing dynamics, this work presents a new understanding of transient habituation and a new interpretation of electrophysiological data.
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    Sonar Beam Direction and Flight Control in an Echolocating Bat
    (2006-04-10) Ghose, Kaushik; Moss, Cynthia F; Horiuchi, Timothy K; Psychology; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Echolocating insectivorous bats are nocturnal mammals that capture fast, erratically moving insects in flight. Bats emit short ultrasonic pulses that form beams of sound and use the returning echoes to guide behavior. The frequency, duration and timing of the sonar pulses, along with the spatial direction of the sonar beam restrict the information returning to the bat, and can be considered a component of the acoustic gaze of bats. A great deal is known about the time-frequency structure of bat echolocation calls and their relationship to the stages of foraging flight in bats. It is however not known how bats direct their sonar beam in flight or how beam direction is related to flight control. This is the first study of the sonar beam direction in freely flying bats as they chase and capture insects. An apparatus and method to measure the sonar beam pattern of echolocating bats (<it>Eptesicus fuscus</it>, big brown bats) as they fly in a laboratory flight room is described. It is shown that the bat locks its sonar beam tightly onto a target during pursuit (Chapter 2). The flying bat's sonar beam consists of two lobes directed apart in the vertical plane (Chapter 3). There is a coupling between acoustic gaze (sonar beam axis) direction and flight turn rate that can be expressed as a delayed linear control law. The gain of this law (steepness of the relationship) varies with the bat's behavioral state (Chapter 4). The bat, when pursuing erratically flying insects, adopts a strategy that keeps the absolute direction to the target a constant. This strategy is shown, under some assumptions, to minimize time-to-intercept of erratically maneuvering targets and is similar to parallel navigation implemented in guided missiles (Chapter 5). The bat is not helpless against ultrasound-triggered evasive dives evolved by some hearing insects. The bat adopts flight strategies to counter such dives (Chapter 6). This work allows us to compare spatial behaviors well studied in visual animals, with similar behaviors in an animal that is guided by hearing and make inferences about common computational strategies employed by nervous systems.
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    Allometric comparison of brain structure volumes in three species of bowerbird: satin bowerbirds (Ptilonorhynchus violaceus), spotted bowerbirds (Chlamydera maculata), and green catbirds (Ailuroedus crassirostris)
    (2005-08-03) Bentz, Shannon Carson; Brauth, Steven E; Psychology; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    In three species of Australian bowerbirds the volumes of several brain structures were determined based on areal measurements of fixed tissue. Allometric comparisons, i.e., those that take into account the gross interspecies and intersexual differences in body mass and overall size, were made among these three species. Sexual dimorphisms were detected in the vocal control nuclei of each species. Most intriguingly, a putatively novel nucleus in the dorsal hyperstriatum of all three species has been identified. These findings are discussed in a functional context, in which the bower-building habits of these three species of bowerbird are considered.
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    Spatial Contrast Sensitivity of Birds
    (2003-12-05) Ghim, Mimi M; Hodos, William; Psychology
    Contrast sensitivity (CS) is the ability of the observer to discriminate between adjacent stimuli on the basis of their differences in relative luminosity (contrast) rather than their absolute luminances. Prior to this study, birds had been thought to have low contrast detection thresholds relative to mammals and fishes. This was a surprising phenomenon because birds had been traditionally attributed with superior vision. In addition, the low CS of birds could not be explained by retinal or optical factors, or secondary stimulus characteristics. Unfortunately, avian contrast sensitivity functions (CSFs) were sparse in the literature, so it was unknown whether low contrast sensitivity was a general phenomenon in birds. This study measured CS in six species of birds sampled across different taxa and different ecological backgrounds in order to answer this very question. The species chosen for this experiment were American kestrels (Falco sparverius), Barn owls (Tyto alba), Japanese quail (Coturnix coturnix japonica), White Carneaux Pigeons (Columba livia), Starlings (Sturnus vulgaris), and Red-bellied woodpeckers (Melanerpes carolinus). CSFs were obtained from these birds using the pattern electroretinogram (PERG), and compared with CSFs from the literature. The quail and pigeon data obtained in this experiment fit well with existing CS data for these species. The kestrel data were not similar to kestrel data in the literature; however the data in the literature were collected from a single subject. All of the birds studied had contrast sensitivities that were consistent with their retinal or optical morphologies relative to other birds (in species for which such data exists) and seem well suited for their natural environments. In addition, all of these birds exhibited low CS relative to humans and most mammals, which suggests that low CS is a general phenomenon of birds. Explanations for this avian low CS phenomenon include a possible trade-off between contrast mechanisms and UV mechanisms in cone systems, and lateral inhibitory mechanisms that are perhaps categorically different from mammals. Lateral inhibition affects contrast gain, and has been shown to differ according to ganglion cell types, which in turn will differ in vertebrate species.