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相关概念视频

Apparent Weight01:09

Apparent Weight

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True weight is the measure of the gravitational force acting on an object. However, if the object accelerates, its measured weight is different from its true weight. Similar observations can be made when the object is submerged in water. An object's weight in water is its apparent weight, which is equal to the difference between its true weight and the buoyant forces.
Consider a person standing on a bathroom scale inside an elevator. If the scale is accurate at rest, its reading equals the...
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Weightlessness01:01

Weightlessness

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When an object is dropped, it accelerates toward the center of the Earth. If the net external force on the object is its weight, it is said to be in free fall; that is, the only force acting on the object is gravity. Galileo was instrumental in showing that, in the absence of air resistance, all objects fall with the same acceleration g. However, when objects on the Earth fall downward, they are never truly in free fall, because there is always some upward resistance force from the air acting...
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Variation in Acceleration due to Gravity near the Earth's Surface01:20

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An object's apparent weight is its weight measured by a spring balance at its location. It is different from its true weight, the force with which the Earth pulls it, because of the Earth's rotation. Mathematically, an object's apparent weight equals its true weight minus the centripetal force that keeps it in a circular motion along with the Earth's surface every 24 hours.
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Measuring Acceleration Due to Gravity01:12

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Consider a coffee mug hanging on a hook in a pantry. If the mug gets knocked, it oscillates back and forth like a pendulum until the oscillations die out.
A simple pendulum can be described as a point mass and a string. Meanwhile, a physical pendulum is any object whose oscillations are similar to a simple pendulum, but cannot be modeled as a point mass on a string because its mass is distributed over a larger area. The behavior of a physical pendulum can be modeled using the principles of...
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Principle of Equivalence01:18

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According to Albert Einstein (1897-1955), free-falling and feeling weightless are intrinsically linked. If a person were in free-fall under gravity, for example, diving towards the Earth from an airplane, they would feel completely weightless. Similarly, a person descending in a lift may feel partially weightless. Broadly speaking, it is assumed that an object in a uniform gravitational field and an object undergoing constant acceleration in the absence of gravity are under the same...
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相关实验视频

Updated: Jul 22, 2025

Applying Incongruent Visual-Tactile Stimuli during Object Transfer with Vibro-Tactile Feedback
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一个触觉幻觉是由重力创造的.

Laurent Opsomer1,2, Benoit P Delhaye1,2, Vincent Théate1,2

  • 1Institute of Neuroscience, Université catholique de Louvain, 1200 Brussels, Belgium.

iScience
|July 24, 2023
PubMed
概括
此摘要是机器生成的。

引力创造了一个幻觉,使上升的力量比下降的力量更强大. 这种效应在超重力中被放大,在微重力中消失,影响握力控制.

关键词:
航空航天工程是航空航天工程.神经科学是一个神经科学.太空科学 空间科学

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科学领域:

  • 人类运动控制器
  • 感官反是一种感官反.
  • 人与计算机的互动.

背景情况:

  • 人类的灵敏度取决于精确的指尖力量控制,整合皮肤和自身感知反.
  • 了解外力 (如重力) 对运动控制的影响对于人类的表现至关重要.

研究的目的:

  • 为了研究重力对等方力控制的影响.
  • 检查微重力和超重力如何改变力量感知和运动指令.

主要方法:

  • 参与者使用指和食指动力表仪复制了对称的垂直力.
  • 在抛物线飞行期间进行了实验,以模拟微重力和超重力条件.
  • 在这些条件下,还评估了握力控制.

主要成果:

  • 引力创造了一个感知错觉,上升的力量比同等的下降力更大.
  • 这种幻觉在超重力条件下加剧,在微重力条件下被消除.
  • 引力显著影响了保持稳定的抓地力所需的抓地力.

结论:

  • 引力会影响触觉感知力,影响运动控制.
  • 这些发现对设计用于航空航天和其他环境的触觉反系统有意义.
  • 自身感知反集成是由重力调节的.