Please answer A through F. Thank you!
Please answer A through F. Thank you! (33%) Problem 3: A mass m 4.6 kg is...
(33%) Problem 1: A mass m = 1.2 kg is at the end of a horizontal spring of spring constant k = 440 N/m on a frictionless horizontal surface. The block is pulled, stretching the spring a distance A-3.5 cm from equilibrium, and released from rest ト 17% Part (a) Write an equation for the angular frequency ω of the oscillation Grade Summary Deductions Potential 100% 0% Submissions Attempts remaining: 7 % per attempt) detailed view 0 Submit Hint Hints:...
(13%) Problem 3: A mass m= 2.2 kg is at the end of a horizontal spring of spring constant k = 385 N/m on a frictionless surface. The block is pulled, stretching the spring a distance A = 6.5 cm from equilibrium, and released from rest. $ 17% Part (a) Write an equation for the angular frequency w of the oscillation. Grade Summary Deductions Potential 100% 7 8 4 5 1 2 0 V O BACKSPACE 9 6 3 ....
(10%) Problem 4: A mass m= 3.6 kg is at the end of a horizontal spring of spring constant k=185 N/m on a frictionless horizontal surface. The block is pulled, stretching the spring a distance A = 5.5 cm from equilibrium, and released from rest. A 17% Part (a) Write an equation for the angular frequency w of the oscillation. HA17% Part (b) Calculate the angular frequency w of the oscillation in rad/seconds. A 17% Part (c) Write an equation...
amework 1 Begin Date: 1/16/2019 12 01 00 AM (1 Due Date: 1/27/20 19 11 S9 00 PM End Dat 1756) Problem 2: A mass m- 11kg is at the end of a hor zontal prug ofspr ng constant k. 21S Nano af surface. The block is palled, stretching the spring a distance A 5.5 cm from equilibrium, and released from rest taleis zontal ヅ17% Part (a) Write an equation for the angular fequency ω ofthe oscillation ψ 17% Part...
need help with all parts O Virtual UTAH HW 15: Fluid HW 16 Oscill How to Trade The Bxpel X C Search Textb C in 0.715 S.A C in 0.810 5. AI L A mass m1 9 asm 42sc theexpertta.com/common/Take TutorialAssignments (129) Problem 5: A mass - 1.8 kg is at the end of a horizontal spring of spring constant k-125 N/m on a frictionless horizontal surface. The block is pulled, stretching the spring a distance 4 - 7.5 cm...
all answers please (25%) Problem 1: A mass m= 1.7 kg is at the end of a horizontal spring on a frictionless horizontal surface. The mass is oscillating with an amplitude A = 1.5 cm and a frequency f= 1.2 Hz. A 20% Part (a) Write an equation for the spring constant k. A 20% Part (b) Calculate the spring constant k, in Newtons per meter. A 20% Part (c) Write an equation for the total mechanical energy, E, of...
problem 17. fully explain parts e and f. I have answer need explanation as to why we multiply for part e. amplitude times angular frequency to get vmax um 16. A 0.250-kg block attached to a light spring U 23. Thev At t frictionless, horizontal table. The oscillation amplitude is 0.125 m and the block moves at 3.00 m/s as it passes through equilibrium at 0. (a) Find the spring constant, k. (b) Calculate the total energy of the block-spring...
(9%) Problem 9: Given position r 1-< rì rly, ri >-<-2.97 m, 5.89 m 4.37 m > and velocity v-< v ,Vy,V >-<-0.644 m/s, 2-402 m/s, 2.622 m/s >, what's the new position r 2 after a small time, t - 2.344 s 17% Part (a) Solve for the x-component ofr2 algebraically de Submit I give up! Hints:-for a 0%-deduction. Hints remaining: 0 Feedback: 0% deduction per feedback 17% Part (b) Solve for the y-component ofr2 algebraically Δ 17% Part...
(25%) Problem 3: A mass m = 0.65 kg hangs at the end of a vertical spring whose top end is fixed to the ceiling. The spring has spring constant k = 65 N/m and negligible mass The mass undergoes simple harmonic motion when placed in vertical motion, with its position given as a function of time by y(t) A cos(ot - *), with the positive y-axis pointing upward. At time t = 0 the mass is observed to be...
(8%) Problem 6: Amass m= 2.95 kg is at the end of a horizontal spring on a frictionless horizontal surface. The mass is oscillating with an amplitude A = 8.5 cm and a frequency f= 1.9 Hz 20% Part (a) Write an equation for the spring constant k. k(2fm Correct! 20% Part (b) Calculate the spring constant k, in Newtons per meter k= 420.4 Correct! 20% Part (c) Write an equation for the total mechanical energy, E, of the motion....