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ically. Which of the following would AP Physics I-Simple Harmonic Motion 1. A mass is attached...
Exercise 11: Simple Harmonic Motion 1. A spring-mass system oscillates with a frequency of 10 Hz when the mass is equal to 0.50 kg. What is the stiffness of the spring? With the same spring, what would the mass need to be to double the frequency? 2. A pendulum swings with a period of 1.50 seconds when the acceleration due to gravity is equal to 9.80 m/s? What is the length of the pendulum? How would this period change if...
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...
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...
A mass of 397 g is attached to a spring and set into simple harmonic motion with a period of 0.246 s. If the total energy of the oscillating system is 5.94 J, determine the following. (a) maximum speed of the object 6.49 When is the total energy of the mass-spring system equal to the kinetic energy of the mass? m/s (b) force constant N/m (c) amplitude of the motion Additional Materials Reading
A mass is attached to the end of a spring and set into simple harmonic motion with an amplitude A on a horizontal frictionless surface. Determine the following in terms of only the variable A. (a) Magnitude of the position in terms of A) of the oscillating mass when its speed is 20% of its maximum value. A (b) Magnitude of the position (in terms of A) of the oscillating mass when the elastic potential energy of the spring is...
A mass is attached to the end of a spring and set into simple harmonic motion with an amplitude A on a horizontal frictionless surface. Determine the following in terms of only the variable A. (a) Magnitude of the position (in terms of A) of the oscillating mass when its speed is 40% of its maximum value. A (b) Magnitude of the position (in terms of A) of the oscillating mass when the elastic potential energy of the spring is...
10. A 1.5 kg mass is attached to the end set into simple harmonic motion wit ned to the end of a horizontal spring of spring constant 60 N/m and a. What is the maximum potential energy of the system? b. What is the frequency of vibration? c. What is the period of vibration?
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)...