2. The following data were obtained with an Atwood's machine for which the total mass m,+m2 remains constant. For each of the values of difference in mass (m,-m.) shown in the table, the system's time to move x =1.000m was measured. (m2 – m) (kg) 0.010 0.020 0.030 0.040 0.050 t (s) 8.30 5.06 3.97 3.37 2.98 a (m/s) (m2- m)g (N) Fig. 7: Atwood Machine Data a) Determine the acceleration for each of the applied forces and record them in the table above. b) From the mass differences (m2-m1), evaluate the applied forces (m2-m1)g and record them in the table above. Assume 9.80 m/s for g.

2. The following data were obtained with an Atwood's machine for which the total mass m,+m2 remains constant. For each of the values of difference in mass (m,-m.) shown in the table, the system's time to move x =1.000m was measured. (m2 – m) (kg) 0.010 0.020 0.030 0.040 0.050 t (s) 8.30 5.06 3.97 3.37 2.98 a (m/s) (m2- m)g (N) Fig. 7: Atwood Machine Data a) Determine the acceleration for each of the applied forces and record them in the table above. b) From the mass differences (m2-m1), evaluate the applied forces (m2-m1)g and record them in the table above. Assume 9.80 m/s for g.

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter1: Units, Trigonometry. And Vectors

Section: Chapter Questions

Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...

See similar textbooks

Similar questions

1. Based on the values provided, complete the following table. Test No Weight (N) H, (cm) H2 (cm) P.E. (initial) (J) P.E. (final) (J) Loss in P.E. (J) 1.4 65 42.5 1.6 65 43.8 31 1.8 65 45.0 2.0 65 47.4 2.2 65 49.7 2. 4.
1. Based on the values provided, complete the following table. Test No Weight (N) H, (cm) H2 (cm) P.E. (initial) (J) P.E. (final) (J) Loss in P.E. (J) 1 1.4 60 40.5 1.6 60 41.8 3 1.8 60 43.0 4 2.0 60 44.4 5 2.2 60 45.7
Question 3. The cart shown in figure below moves with constant deceleration changing the speed from v0 = 5 m/s to v1 = 1 m/s. After 2 seconds when it reaches the speed v1 it suddenly stops. Write the displacement of the mass as a function of time. Mass m moves without friction on the surface of the cart. Assume positive direction from left to right (direction of motion of the cart). Numerical values: m = 2 kg, k = 1.152 kN/m. V k Ans: x(t) = 3.472 cos 24 t + 41.6 sin 24 t (mm) m L
Help
oubleshooter | Intera x J Course Home P Keyboard shortcuts for entering x + html?courseld=17221332&OpenVellumHMAC=93343914c857458c3d89df2d7be78e70#10001 Course Home V29L, so that the change in the hammer's gravitational potential energy, as it drives the nail into the block, is insignificant. Express the magnitude of the force terms of M, vo, and L. > View Available Hint(s) F= Vo V29L Submit Previous Answers X Incorrect; Try Again; One attempt remaining Part B
Mass #1 = 70g Mass #2 = 130g Acceleration #1 = 2.7248 Acceleration #2 = 2.7191 Acceleration #3 = 2.7283 Experimental Acceleration = Net Force (experimental) =
Determine the acceleration of gravity g using your (a) position versus time graph equation (b) velocity versus time graph equation. A Equation: y=-4.2238t^2-1.2466t+1.0791 B Equation: y=-8.152x-1.2934
i just have a question on the algebra on this portion of the problem, what happens to the negative sign that is factored out when you're trying to find the final velocity?
1. Based on the values provided, complete the following table. Test No Weight (N) H1 (cm) H2 (cm) P.E. (initial) (J) P.E. (final) (J) Loss in P.E. (J) 1 1.4 65 42.5 2 1.6 65 43.8 | 65 45. 3 1.8 4 2.0 65 47.4 5 2.2 65 49.7
Suppose you have collected the set of data below by measuring the amount of time it takes for a small steel ball to fall from a height of 1.5 m to the ground. What value would you report if I asked you for the fall-time of this small steel ball from a height of 1.5 m?
3. One newton is equivalent to: a) 1 kg · m/ s d) 1 kg / m b) 1 kg m/s? e) 1 kg m c) 1 kg - m² I s?
M2 = 5 kg uk = 0.1 M1 = 10 kg H = 3 m What is the velocity of the mass 1 when it hits the floor?