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Physics I 95.141 LECTURE 23 5/10/10 95.141, S2010, Lecture 23 Department of Physics and Applied Physics Exam Prep Question • A mass of 1kg is attached to a vertical spring. The spring deflects 2cm. • • • • • a) (10 pts) What is the spring constant k of the spring? b) (10 pts) A 50g bullet is shot at 100m/s from below into the mass, and ends embedded in the mass. What is the velocity of the mass/bullet after the collision? c) (5pts) What is the new equilibrium position of the spring/mass system after the collision? d) (5pts) What is the total energy of the spring/mass system immediately after the collision? (remember, the system has a new mass now, so it will have a new equilibrium position) e) (5pts) What is the amplitude of oscillation of the spring mass system after the collision? 95.141, S2010, Lecture 23 Department of Physics and Applied Physics k m=1kg v=500m/s m=50g Exam Prep Question • A mass of 1kg is attached to a vertical spring. The spring deflects 2cm. • a) (10 pts) What is the spring constant k of the spring? k m=1kg v=500m/s m=50g 95.141, S2010, Lecture 23 Department of Physics and Applied Physics Exam Prep Question • A mass of 1kg is attached to a vertical spring. The spring deflects 2cm. • b) (10 pts) A 50g bullet is shot at 100m/s from below into the mass, and ends embedded in the mass. What is the velocity of the mass/bullet after the collision? k m=1kg v=500m/s m=50g 95.141, S2010, Lecture 23 Department of Physics and Applied Physics Exam Prep Question • A mass of 1kg is attached to a vertical spring. The spring deflects 2cm. • c) (5pts) What is the new equilibrium position of the spring/mass system after the collision? k m=1kg v=500m/s m=50g 95.141, S2010, Lecture 23 Department of Physics and Applied Physics Exam Prep Question • A mass of 1kg is attached to a vertical spring. The spring deflects 2cm. • d) (5pts) What is the total energy of the spring/mass system immediately after the collision? (remember, the system has a new mass now, so it will have a new equilibrium position) k m=1kg v=500m/s m=50g 95.141, S2010, Lecture 23 Department of Physics and Applied Physics Exam Prep Question • A mass of 1kg is attached to a vertical spring. The spring deflects 2cm. • e) (5pts) What is the amplitude of oscillation of the spring mass system after the collision? k m=1kg v=500m/s m=50g 95.141, S2010, Lecture 23 Department of Physics and Applied Physics Administrative Notes • Physics I Final: – SATURDAY 5/15/10 – Olney 150 (HERE) – 3:00 P.M. • 8 total problems, 1 multiple choice • Extra Time: Starts at 12:00 pm – Meet at my office • Review Session Thursday (5/13), 6:30 pm, OH218. • 20 problems posted on-line. 5 will be on the Final. 95.141, S2010, Lecture 23 Department of Physics and Applied Physics Outline • • • Pendulums Damped and Forced Harmonic Motion What do we know? – Units – Kinematic equations – Freely falling objects – Vectors – Kinematics + Vectors = Vector Kinematics – Relative motion – Projectile motion – Uniform circular motion – Newton’s Laws – Force of Gravity/Normal Force – Free Body Diagrams – Problem solving – Uniform Circular Motion – Newton’s Law of Universal Gravitation – Weightlessness – Kepler’s Laws 95.141, S2010, Lecture 23 Department of Physics and Applied Physics – – – – – – – – – – – – – – – – – – – – – – – – – – – – – Work by Constant Force Scalar Product of Vectors Work done by varying Force Work-Energy Theorem Conservative, non-conservative Forces Potential Energy Mechanical Energy Conservation of Energy Dissipative Forces Gravitational Potential Revisited Power Momentum and Force Conservation of Momentum Collisions Impulse Conservation of Momentum and Energy Elastic and Inelastic Collisions2D, 3D Collisions Center of Mass and translational motion Angular quantities Vector nature of angular quantities Constant angular acceleration Torque Rotational Inertia Moments of Inertia Angular Momentum Vector Cross Products Conservation of Angular Momentum Oscillations Simple Harmonic Motion Review of Lecture 22 • Discussed, qualitatively, oscillatory motion of spring mass system: shifting of energy between elastic potential energy (spring) and kinetic energy (mass) • Quantitative description of motion of an object with constant restoring force 2 d x (t ) kx (t ) m dt 2 • Developed description of motion of spring mass from the differential equation x(t ) A cos(t ) , k m • Used this to determine velocity and acceleration v (t ) A sin( t ) functions 2 a ( t ) A cos(t ) • Energy of a SHO 1 1 1 2 1 2 2 2 E k ( x ( t )) m ( v ( t )) kA mv total max 95.141, S2010, Lecture 23 2 2 2 2 Department of Physics and Applied Physics The pendulum • A simple pendulum consists of a mass (M) attached to a massless string of length L. • We know the motion of the mass, if dropped from some height, resembles simple harmonic motion: oscillates back and forth. • Is this really SHO? Definition of SHO is motion resulting from a restoring force proportional to displacement. 95.141, S2010, Lecture 23 Department of Physics and Applied Physics Simple Pendulum L • We can describe displacement as: • The restoring Force comes from gravity, need to find component of force of gravity along x • Need to make an approximation here for small θ… 95.141, S2010, Lecture 23 Department of Physics and Applied Physics θ Δx Simple Pendulum • Now we have an expression for the restoring force F mg sin mg x L mg F x L • From this, we can determine the effective “spring” constant k • And we can determine the natural frequency of the pendulum 95.141, S2010, Lecture 23 Department of Physics and Applied Physics L θ Δx Simple Pendulum • If we know g L L θ • We can determine period T • And we can the equation of motion for displacement in x • …or θ 95.141, S2010, Lecture 23 Department of Physics and Applied Physics Δx Damped Harmonic Motion • If I let the pendulum swing, would it keep returning to the same original displacement? • In the real world there are other forces, in addition to the restoring force which act on the pendulum (or any oscillator). • The harmonic motion for these real-world oscillators is no longer simple. • Damped Harmonic Motion 95.141, S2010, Lecture 23 Department of Physics and Applied Physics Damped Harmonic Motion • Suppose there is a damping force acting on the oscillator which depends on velocity – This is a Force which acts against the oscillator, opposite the direction of motion. Fdamping dx bv b dt • The force equation now looks like: ma kx bv 95.141, S2010, Lecture 23 Department of Physics and Applied Physics Damped Harmonic Motion • The solution to this differential equation is trickier, but let’s try the following solution: x (t ) Ae t cos t k b2 m 4m 2 b 2m • Natural frequency decreases • Amplitude of oscillations decreases exponentially. 95.141, S2010, Lecture 23 Department of Physics and Applied Physics Simple Harmonic Oscillation 2 x(t) 1 0 -1 -2 0 1 2 3 4 Time (s) 95.141, S2010, Lecture 23 Department of Physics and Applied Physics 5 6 x ( t ) A cos o t k o m k 400 N m m 2kg Damped Harmonic Oscillation 2 x(t) 1 0 -1 -2 0 1 2 3 4 Time (s) 95.141, S2010, Lecture 23 Department of Physics and Applied Physics 5 6 x (t ) A cos t k b2 m 4m 2 k 400 N m m 2kg b 2 Ns m Damped Harmonic Oscillation x ( t ) Ae t k b2 m 4m 2 k 400 N m 2 m 2kg b 2 Ns m 1 x(t) x ( t ) A cos t 0 b 2m -1 -2 0 1 2 3 4 Time (s) 95.141, S2010, Lecture 23 Department of Physics and Applied Physics 5 6 Damped Harmonic Oscillation x ( t ) Ae t cos t k b2 m 4m 2 k 400 N m 2 x(t) m 2kg 1 b 2 Ns m 0 b 2m -1 -2 0 1 2 3 4 Time (s) 95.141, S2010, Lecture 23 Department of Physics and Applied Physics 5 6 Forced Harmonic Motion • In addition to damping, one can apply a force to an oscillator. If that external force is sinusoidal, the Force equation looks like: ma Fo cos t bv kx o d2x dx m 2 b kx Fo cos t dt dt k m • The solution to this differential equation is: x Ao sin( t o ) Ao Fo m ( 2 o2 ) 2 b 95.141, S2010, Lecture 23 Department of Physics and Applied Physics 2 2 o2 o tan (b m) 1 2 m2 Forced Harmonic Motion Ao m ( 2 o2 ) 2 b Fo 2 N b 2 Ns m 0.30 0.25 Amplitude (Ao) Fo 0.20 0.15 0.10 0.05 0.00 0 5 10 (rad/s) 95.141, S2010, Lecture 23 Department of Physics and Applied Physics 15 20 2 2 m2 Forced Harmonic Motion Ao m ( 2 o2 ) 2 b Fo 2 N b 1 Ns m 0.30 0.25 Amplitude (Ao) Fo 0.20 0.15 0.10 0.05 0.00 0 5 10 (rad/s) 95.141, S2010, Lecture 23 Department of Physics and Applied Physics 15 20 2 2 m2 Forced Harmonic Motion Ao m ( 2 o2 ) 2 b Fo 2 N b 0.5 Ns m 0.30 0.25 Amplitude (Ao) Fo 0.20 0.15 0.10 0.05 0.00 0 5 10 (rad/s) 95.141, S2010, Lecture 23 Department of Physics and Applied Physics 15 20 2 2 m2 In the real world? 95.141, S2010, Lecture 23 Department of Physics and Applied Physics Waves (Chapter 15) • A wave is a displacement that travels (almost always through a medium) with a velocity and carries energy. – It is the displacement that travels, not the medium!! – The wave travels over large distances, the displacement is small compared to these distances. – All forms of waves transport energy 95.141, S2010, Lecture 23 Department of Physics and Applied Physics Waves (Water Waves) • Example which most frequently comes to mind are waves on the ocean. – With an ocean wave, it is not the water that is travelling with the lateral velocity. – Water is displaced up and down – This displacement is what moves! 95.141, S2010, Lecture 23 Department of Physics and Applied Physics Waves (Earthquakes) • Earthquakes are waves where the displacement is of the surface of the Earth. – Again, the Earth’s surface is not travelling with any lateral velocity. It is the displacement which travels. – The surface of the Earth moves up and down. – Obviously a lot of Energy is transported! 95.141, S2010, Lecture 23 Department of Physics and Applied Physics Waves (Sound Waves) • Sound is also a form of wave. – The displacement for a sound wave is not an “up and down” displacement. It’s a compression. – The air is compressed, and it is the compression which travels through air. – Sound is not pockets of compressed air travelling, but the compression of successive portions of air. 95.141, S2010, Lecture 23 Department of Physics and Applied Physics Waves (Light) • Light is also a type of wave – The displacement of a light wave is a change in the Electric Field. – This propagates through space with the speed of light c 310 8m s – Light can carry energy: • Solar power • Radiative heating • Lasers – Green lasers can be especially damaging to the eyes, since our eyes are most sensitive to green light. 95.141, S2010, Lecture 23 Department of Physics and Applied Physics Characteristics of Waves • A continuous or periodic wave has a source which is continuous and oscillating – Think of a hand oscillating a piece of rope up and down – Or a speaker playing a note • This vibration is the source of the wave, and it is the vibration that propagates. • If we freeze that wave in time (take a picture) x 95.141, S2010, Lecture 23 Department of Physics and Applied Physics