Vision is blurred if the head is vibrated at 29 Hz because the vibrations are resonant with the natural frequency of the eyeball held by the musculature in its socket.
If the mass of the eyeball is 7.1 g, what is the effective spring constant of the musculature attached to the eyeball?
Vision is blurred if the head is vibrated at 29 Hz because the vibrations are resonant...
ReviewI Constants Part A Vision is blurred if the head is vibrated at 29 Hz because the vibrations are resonant with the natural frequency of the eyeball held by the musculature in its socket If the mass of the eyeball is 7.3 g, what is the effective spring constant of the musculature attached to the eyeball? Express your answer to two significant figures and include the appropriate units. You may want to review (Pages 458 - 460) Value Units Submit
If the resonant frequency of the speaker is 1000 Hz, what mass and spring constant are required? You thought to consider a 20 g (0.020 kg) mass.
Q4: Bellows, diaphragm, and Bourdon tube pressure sensors all exhibit second-order time response. This means that a sudden change in pressure will cause an oscillation in the displacement and, therefore, in sensor output. Because they are like springs, they have an effective spring constant and mass, so the frequency can be estimated by the following Equation: ??=12?√?? Where fN= natural frequency in Hz k= spring constant in N/m m= seismic mass in kg Consider a bellows with an effective spring...
A spring is compressed 15 cm from its natural length. If it requires 100 N of force to compress the spring this distance, what is the spring constant of the spring? how much energy is stored in the spring? what will the angular frequency of the spring be if it is attached to a 100 g mass and released to oscillate?
7. [lpt] In a simple approximation, a diatomic molecule (e.g., H2) can be represented by two equal masses, m, on a frictionless surface, connected by a spring of constant k. Consider the oscillations of the masses and the connecting spring. Select true or false for each of the statements; e.g., if the first statement is true and the second false, enter TF You only have 1 try! i. During the oscillation of this mass-spring system, its centre of mass will...
please answer as many questions as possible. I will “thumb up” the answers. Thanks! 1. You are on a boat, which is bobbing up and down. The boat's vertical displacement y is given by y 1.2 cos(t). Find the amplitude, angular frequency, phase constant, frequency, and period of the motion. (b) Where is the boat at t 1 s? (c) Find the velocity and acceleration as functions of time t. (d) Find the initial values of the position, velocity, and...
The acceleration of gravity is 9.81 m/s How 'l is the tower? Answer in units of m. 004 10.0 points A mass of 0.22 kg is attached to a spring and is set into vibration with a period of 0.22 s. What is the spring constant of the spring? Answer in units of N/m 005 (part 1 of 6) 10.0 points Consider a pendulum of length 4.488 m. The acceleration of gravity is 9.832 m/s a) What is its period...
5. Solve problems (a) to (c) below. (a) A 60.0-kg block is attached to a massless spring with force constant k = 575 N/m. () Find the natural frequency for this simple harmonic oscillator, in Hatz (cycles/sec). (ii) If the amplitude is 0350 m, predict the maximum speed of the block (for Instructor use only) (b) A siren has an intensity of 10W/mat a distance of 10.0 m away. What is its intensity at a distance of 5.0 m? (BONUS,...
show all the work please 5. Solve problems (a) to (c) below. (a) A 60.0-kg block is attached to a massless spring with force constant k = 575 N/m. (1) Find the natural frequency for this simple harmonic oscillator, in Hatz (cycles/sec). (ii) If the amplitude is 0350 m, predict the maximum speed of the block (for Instructor use only) (b) A siren has an intensity of 10W/m²at a distance of 10.0 m away. What is its intensity at a...