Part B: 20 points each. 3. A simple harmonic motion of an obiect of mass m...
1. A simple harmonic motion of an object of mass m = 11 kg attached with a spring is represented as time vs displacement graph in the following figure. Find the following parameters. AM -1.5m (a) Amplitude = (b) Time Period = ( time for 1 wavelength distance) (c) Frequency = (d) Spring Constant = (e) Angular frequency = (f) Maximum Potential Energy stored in the spring (g) Maximum Kinetic Energy of the block (h) total energy of the spring...
1. A simple harmonic motion of an object of mass m = 11 kg attached with a spring is represented as time vs displacement graph in the following figure. Find the following parameters. 1.5m - АААААА 0.3 23 23 tis) -1.5m (a) Amplitude = (b) Time Period = (time for 1 wavelength distance) (c) Frequency = (d) Spring Constant = (e) Angular frequency = (f) Maximum Potential Energy stored in the spring (g) Maximum Kinetic Energy of the block (h)...
1. A simple harmonic motion of an object of mass m = 11 kg attached with a spring is represented as time vs displacement graph in the following figure. Find the following parameters. (a) Amplitude = (b) Time Period = ( time for 1 wavelength distance) (c) Frequency = (d) Spring Constant = (e) Angular frequency = (f) Maximum Potential Energy stored in the spring (g) Maximum Kinetic Energy of the block (h) total energy of the spring -block system
1. A simple harmonic motion of an object of mass m = 11 kg attached with a spring is represented as time vs displacement graph in the following figure. Find the following parameters. ТАЛААР (a) Amplitude = (b) Time Period =( time for 1 wavelength distance) (c) Frequency = (d) Spring Constant = (e) Angular frequency = (1) Maximum Potential Energy stored in the spring (g) Maximum Kinetic Energy of the block (h) total energy of the spring -block system
1. A simple harmonic motion of an object of mass m = 11 kg attached with a spring is represented as time vs displacement graph in the following figure. Find the following parameters. VAAAA (a) Amplitude = (b) Time Period = ( time for 1 wavelength distance) (c) Frequency = (d) Spring Constant = (e) Angular frequency = (f) Maximum Potential Energy stored in the spring (g) Maximum Kinetic Energy of the block (h) total energy of the spring -block...
Test 5 Venice a Page Version A 5. A simple harmonic motion of an object of m Part B: 20 points each notion of an object of mass m 8 kg attached with a springs represented as time vs displacement graph in the following gue following parameters. gan in the following figure. Find the 1.5mm x (a) Amplitude = (b) Time Period = (time for I wavelength distance) (c) Frequency = (d) Spring Constant = (e) Angular frequency =
7. An object attached with a spring undergoes simple harmonic motion, represented by the displacement = (1.0m) Cos (1.5m t) . Compare with the standard equation for simple harmonic equation: x = A cos (w t). (i) Find the amplitude of oscillation? ute ew m .s (ii) Calculate the displacement x at t 0, 1, 2, 3, 4 and 5 seconds and filled the table below (calculator should be in radian mode for finding x values ) Displacement x (m)...
Question 3: "Simple” Harmonic Motion As a skeptical physicist, you decide to go to the lab to test whether or not masses on springs really exhibit simple harmonic motion. You attach a large block of mass m = 0.5 kg to the biggest spring you can find. You setup this over-sized experiment so that the mass is oscillating horizontally, an ultrasonic sensor is used to measure its motion - the resulting data is plotted in figure 3. Assume that there...
An object with mass 2.3 kg is executing simple harmonic motion, attached to a spring with spring constant 270 N/m . When the object is 0.015 mfrom its equilibrium position, it is moving with a speed of 0.65 m/s . A) Calculate the amplitude of the motion. B) Calculate the maximum speed attained by the object.
A 0.8 kg mass attached to a vertical spring undergoes simple harmonic motion with a frequency of 0.5 Hz. a) What is the period of the motion and the spring constant? b) If the amplitude of oscillation is 10 cm and the mass starts at its lowest point at time zero, write the equation describing the displacement of the mass as a function of time and find the position of the mass at times 1, 2, 1.5 s, and 1.25...