Turning perception on its head: cephalic perception of whole and partial length of a wielded object

Wagman, Jeffrey B.; Langley, Matthew D.; Higuchi, Tatsuo

doi:10.1007/s00221-016-4778-2

Cited by 22 publications

(14 citation statements)

References 36 publications

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“…Previous research has found evidence of both task-specificity and anatomical independence in perception of properties of wielded objects. In particular, people can direct attention to different exteroceptive properties of wielded object (e.g., object length), and perception of such properties remains invariant across transformations including the anatomical component used to wield the object (see Hajnal, Fonseca, Harrison, et al, 2007a;Wagman et al, 2017). Such flexibility is grounded in sensitivity to task-specific (in this case, exterospecific) components of an invariant mechanical stimulation pattern-the rotational inertia (I) of the person-object system.…”

Section: Discussionmentioning

confidence: 99%

“…Previous experiments have shown (1) that people can perceive exteroceptive properties of an object wielded with the hand (e.g., whole or partial length of that object), (2) that these abilities generalize to objects wielded by other body parts (including the foot, the torso, and the head), and (3) that perception of such properties is supported by analogous sensitivities to exterospecific components of I across anatomical components (Hajnal, Fonseca, Kinsella-Shaw, et al, 2007b;Palatinus et al, 2011;Wagman et al, 2017).…”

Section: Methodsmentioning

confidence: 99%

“…A specific property of the personobject system can be perceived when a given object is wielded in different ways, by different effectors, about different joints. For example, people can perceive the length of an object when it is freely wielded or held with minimal movement (Burton & Turvey, 1990;Carello Fitzpatrick, Domaniewicz, Chan, & Turvey, 1992); when it is wielded with the hand about the wrist, the elbow, or the shoulder (Pagano, Fitzpatrick, & Turvey, 1993); or when it is wielded by the hand, foot, torso, or head (Hajnal, Fonseca, Harrison, Kinsella-Shaw, & Carello, 2007a;Palatinus, Carello, & Turvey, 2011;Wagman, Langley, & Higuchi, 2017).…”

mentioning

confidence: 99%

“…The invariant nature of I is highlighted not only by the ability to perceive a given property within and across bouts of wielding but also by the ability to perceive a given property by different means of wielding-including cases in which an object is wielded by disparate anatomical components. Studies investigating this latter ability have shown that people can perceive exteroceptive properties of a wielded object such as whole or partial length when an object is wielded by the hand, the torso, the foot, and even the head (Hajnal, Fonseca, Kinsella-Shaw, et al, 2007b;Wagman et al, 2017). Moreover, they can differentiate between two different (but related) exteroceptive properties (e.g., whole length vs. partial length, probe length vs. distance of surface probed) under such circumstances (Hajnal, Fonseca, Kinsella-Shaw, et al, 2007a;Palatinus et al, 2011;Wagman et al, 2017;Wagman & Mason, 2019).…”

mentioning

confidence: 99%

“…Doing so provides a relatively strong test of both the task-specificity and the anatomical independence of perception of (proexteroceptive) properties of the person-object system by dynamic or effortful touch (cf. Wagman et al, 2017).…”

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confidence: 99%

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Where is your head? Perception of relative position of the head on a wielded object

Wagman

Higuchi

2019

Atten Percept Psychophys

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Perception of exteroceptive properties (e.g., object length) by effortful or dynamic touch is both task-specific and anatomically independent. We investigate whether task-specificity and anatomical independence generalize to perception of proexteroceptive properties of the person-object system (i.e., relative position of the body on a wielded object). Moreover, we do so when objects are wielded by a body part that is unlikely to be well practiced in such tasks-the head. Experiment 1 found that participants can perceive the relative location of the head on a wielded object and that such perception is likely supported by task-specific sensitivity to an invariant mechanical stimulation pattern-rotational inertia. Experiment 2 found that participants have at least some ability to differentiate between this property and a related exteroceptive property (i.e., partial length of a wielded object extending to one side of the head). The results are discussed in terms of information for perception by effortful touch and a description of the haptic system as a biotensegrity structure.

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Where is your head? Perception of relative position of the head on a wielded object

Wagman

Higuchi

2019

Atten Percept Psychophys

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Evaluating the contributions of muscle activity and joint kinematics to weight perception across multiple joints

Waddell

Amazeen

2017

Exp Brain Res

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Perceived heaviness is clearly a function of muscle activity: objects feel heavy, in part because they are lifted with more force than lighter feeling objects. Recent research showed that participants scale their perceptions to the ratio of muscle activity to lift acceleration during elbow lifts (Waddell et al. J Exp Psychol Hum Percept Perform 42:363-374, 2016). The current study sought psychophysiological functions relating perceived heaviness to EMG and peak lift acceleration across multiple lifts employing different muscles as prime movers. Participants lifted objects with three arm lifts-shoulder, elbow, and wrist-and reported perceived heaviness. In each lift, EMG was recorded from the anterior deltoid, biceps brachii, and forearm flexors, and peak angular acceleration was recorded about each joint. The resulting psychophysiological functions revealed the hypothesized ratio of muscle activity to peak lift acceleration in all lifts. Principal component regressions showed that the EMG of the forearm flexors and peak acceleration of the lifting joint were most relevant for perceived heaviness. The special role of forearm flexors in perceiving heaviness across different lifts was interpreted in terms of the invariant structure of the inertia tensor about the wrist.

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Temperature influences perception of the length of a wielded object via effortful touch

2017

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Individuals can perceive the properties of an attached or grasped object by wielding it through muscular effort-an ability referred to as dynamic or effortful touch. Sensitivity to the forces required to move such objects and to the resulting global patterns of tissue deformation underlies such perception. Given that perception via dynamic touch is movement-based, we hypothesized that manipulations that affect the ability to produce and control muscular movements might affect perception via dynamic touch. Cooling muscles from 40 to 10 °C impedes the development and transmission of muscular force and diminishes muscle stretch-reflex sensitivity. Accordingly, we anticipated that changes in hand temperature would alter the ability to detect patterns of tissue deformation and thus perception of the properties of wielded objects. In two experiments, participants wielded dowels with different lengths and rotational inertias (Experiment 1) and objects with identical lengths and different rotational inertias (Experiment 2). They reported perceived lengths of these objects, in the absence of vision, in cool (~ 10 °C), neutral (~ 30 °C), and warm temperature conditions (~ 40 °C). Actual length predicted perceived length of the dowels (Experiment 1), and rotational inertia predicted perceived length of the objects (Experiment 2); perceived lengths were longer in the warm condition than in the cool condition. In consideration of known temperature-induced changes in tissue structure and function, our results support the hypothesis that comparable processes underlie the control of movement and perception via dynamic touch.

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Turning perception on its head: cephalic perception of whole and partial length of a wielded object

Cited by 22 publications

References 36 publications

Where is your head? Perception of relative position of the head on a wielded object

Where is your head? Perception of relative position of the head on a wielded object

Evaluating the contributions of muscle activity and joint kinematics to weight perception across multiple joints

Temperature influences perception of the length of a wielded object via effortful touch

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