The textbook shows that the period of a pendulum is given by the equation: T =...

Chapter 15 1. By what percent does the period of a simple pendulum change if you...

Chapter 15 1. By what percent does the period of a simple pendulum change if you double its (a) amplitude; (b) mass; (c) length? Period of a simple pendulum, T = 2(pi) sqrt(l/g)

The period T of a simple pendulum is the amount of time required for it to...

The period T of a simple pendulum is the amount of time required for it to undergo one complete oscillation. If the length of the pendulum is L and the acceleration of gravity is g, then T is given by T=2πLpgq Find the powers p and q required for dimensional consistency. Enter your answers numerically separated by a comma.

T=2pi *square root* L/g based on the equation a) Suppose you decrease the mass of the...

T=2pi *square root* L/g based on the equation a) Suppose you decrease the mass of the pendulum bob, but keep the length and angle the same. Will the period increase, decrease, or stay the same? b) Suppose you decrease the angle of the oscillation, but keep the length and mass the same. Will the period increase, decrease, or stay the same? c) Suppose you decrease the length of the pendulum string, but keep the mass and angle the same. Will...

Consider the differential equation L[y] = y′′ + p(t)y′ + q(t)y = f(t) + g(t), and...

Consider the differential equation L[y] = y′′ + p(t)y′ + q(t)y = f(t) + g(t), and suppose L[yf] = f(t) and L[yg] = g(t). Explain why yp = yf + yg is a solution to L[y] = f + g. Suppose y and y ̃ are both solutions to L[y] = f + g, and suppose {y1, y2} is a fundamental set of solutions to the homogeneous equation L[y] = 0. Explain why y = C1y1 + C2y2 + yf...

LAB 4 – PENDULUM Objective: The overall objective of the lab is to investigate the period...

LAB 4 – PENDULUM Objective: The overall objective of the lab is to investigate the period of oscillation of a pendulum which all depends on its mass, length, amplitude. Table 1 Dependence of Period on Mass for a Fixed Length and Amplitude Trial Mass, m (kg) Period, T (s) 1 0.20 2.46 2 0.40 2.46 3 0.60 2.46 4 0.80 2.46 5 1.00 2.46 6 1.50 2.46 Length = 1.5 m                       Amplitude = 150 Table 2 Dependence of Period on Length...

pendulum of mass m= 0.8 kg and length l=1 m is hanging from the ceiling. The...

pendulum of mass m= 0.8 kg and length l=1 m is hanging from the ceiling. The massless string of the pendulum is attached at point P. The bob of the pendulum is a uniform shell (very thin hollow sphere) of radius r=0.4 m, and the length l of the pendulum is measured from the center of the bob. A spring with spring constant k= 7 N/m is attached to the bob (center). The spring is relaxed when the bob is...

Find an equation of the tangent line to the curve at the given point. 1.) y=...

Find an equation of the tangent line to the curve at the given point. 1.) y= sqrt(5x+ 9), at x= 10. 2.) y= cos(x) + cos^3(x), at x=π/6.

A simple pendulum of length L = 1 m oscillates with its angular displacement as function...

A simple pendulum of length L = 1 m oscillates with its angular displacement as function of time given by θ(t)=10°cos⁡(πt ‒ π/2). At time t = 2T/3, where T is the period of oscillation, the values the velocity and tangential acceleration are: v = ‒ (√3/2) v_max , and a_t = ‒ (1/2) a_max v = 0, and a_t = ‒ a_max v = ‒ (1/2) v_max ), and a_t = + (√3/2) a_max v = (√3/2) v_max ,...

Consider a ‘physical pendulum’ made of a meter stick (length L = 1 m, mass 0.2...

Consider a ‘physical pendulum’ made of a meter stick (length L = 1 m, mass 0.2 kg) with a hole drilled through it at the 5 cm mark. The stick is free to rotate (in a vertical plane) around a nail that goes through the hole and into a wall. Assume no friction between the nail and the hole. The stick’s moment of inertia about the nail is I=0.1 kgm2. (Use g=10 m/s2) If the pendulum is released from rest...

The wave function of a wave is given by the equation D(x,t)=(0.2m)sin(2.0x−4.0t+π), where x is in...

The wave function of a wave is given by the equation D(x,t)=(0.2m)sin(2.0x−4.0t+π), where x is in metres and t is in seconds. a. What is the phase constant of the wave? b. What is the phase of the wave at t=1.0s and x=0.5m? c. At a given instant, what is the phase difference between two points that are 0.5m apart? d. At what speed does a crest of the wave move?