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10讲:虎克定律弹簧简谐运动摆小角近似

Lecture 10: Hooke's Law - Springs - Simple Harmonic Motion - Pendulum - Small Angle Approximation
课程网址: http://videolectures.net/mit801f99_lewin_lec10/  
主讲教师: Walter H. G. Lewin
开课单位: 麻省理工学院
开课时间: 2008-10-10
课程语种: 英语
中文简介:
* * 1。介绍了一个弹簧的恢复力: * * 一个弹簧的恢复力, 描述了胡克定律 (f =-kx)。莱文教授讨论了如何测量弹簧常数 k, 他给出了一个简短的演示。* * 2。在没有阻尼力的情况下, 导出了移位弹簧的动力学方程: * * 一个弹簧的微分方程。使用弹簧、喷漆和移动目标, 创建 x (t) 的草图, 表明 x 的正弦或余弦依赖时间。角频率 (因此也显示周期) 仅取决于 k 和 m (因此您可以动态测量 k)。振幅和相位取决于初始条件 (txx0 时的位移和速度)。通过一个例子来证明这一点。* * 3。测量弹簧系统的周期: * * 振荡周期是测量空气轨道上弹簧系统上的质量的周期 (以最大限度地减少摩擦)。测量周期为10个周期, 以减少相对误差。莱文教授证明, 周期是独立的振幅。质量增加一倍, 预测新的周期, 然后进行经验确认。* * 4。钟摆的动力学方程: * * 为质量, m, 悬浮在一个接近质量串的长度 l 的微分方程被导出。小角度近似定量地证明了并应用于一个简单的微分方程, 类似于弹簧。振荡周期与 lp 的平方根成正比;它独立于 m. * * 5。比较弹簧和钟摆周期: * * 直观的见解, 为什么振荡弹簧的周期取决于质量 (连接到弹簧) 和弹簧常数。然而, 钟摆的周期与挂在弦上的质量无关。通过几个非常长的钟摆实验, 这些见解得到了加强。考虑到测量中的不确定性。为了证明这个时期与波波的质量无关, 莱文教授将自己放在5米长的电缆的末端, 并测量这个时期。
课程简介: **1. Restoring Force of a Spring:** The restoring force of a spring, described by Hooke's Law (F=-kx) is introduced. Professor Lewin discusses how to measure the spring constant, k, and he gives a brief demonstration. **2. Dynamic Equations of a Displaced Spring:** A differential equation is derived for a spring in the absence of damping forces. Using springs, spray paint and a moving target, a sketch of x(t) is created, suggesting a sine or cosine dependence of x on time. The angular frequency (and therefore the period) is shown to depend only on k and m (so you can measure k dynamically). The amplitude and phase depend on initial conditions (the displacement and velocity at t=0). An example is worked out to demonstrate this. **3. Measuring the Period of a Spring System:** The period of oscillation is measured for a mass on a spring system on an air track (to minimize friction). A measurement is made of 10 periods to reduce the relative error. Professor Lewin demonstrates that the period is independent of the amplitude. The mass is doubled, the new period is predicted and then empirically confirmed. **4. Dynamic Equations of a Pendulum:** A pair of differential equations is derived for a mass, m, suspended on a near massless string of length L. The small angle approximation is quantitatively justified and applied to arrive at a simple differential equation analogous to that for a spring. The period of oscillation is shown to be proportional to the square root of L/g; it is independent of m. **5. Comparing the Spring and Pendulum Periods:** Intuitive insights are presented as to why the period of an oscillating spring depends on the mass (attached to the spring) and the spring constant. Yet the period of a pendulum is independent of the mass hanging from the string. These insights are reinforced with several experiments with a very long pendulum. The uncertainties in the measurements are taken into account. To demonstrate that the period is independent of the mass of the bob, Professor Lewin places himself at the end of the 5 meter long cable and measures the period.
关 键 词: 胡克定律; 动力学方程; 弹簧动力学
课程来源: 视频讲座网
最后编审: 2020-05-21:王淑红(课程编辑志愿者)
阅读次数: 219

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