Question 13 5 pts Given the graph of displacement vs time below, determine the period of...
Question 10 5 pts Refer to the graph below to determine the maximum charge stored on the capacitor (in mC), given that the total capacitance is 5000 12. Answer with at least 2 significant figures. Voltage drop across the capacitor as a function of time 11.5 Voltage Drop Across Capacitor (V) O 0.25 0.5 0.75 1 1.25 1.5 1.75 2 2.25 2.5 2.75 3 3.25 3.5 3.75 4 4.25 4.5 4.75 5 Time (s) Note, because Canvas often does not...
Find the spring constant for the given data in the static method by plotting Displacement (along y-axis) vs. Added Mass (along x-axis). Recall: the slope of the trend line corresponds to g/k. Copy and paste your graph here. (2 pts) Added Mass (kg) Displacement (m) 0.05 0.11 0.10 0.20 0.15 0.31 0.20 0.43 0.25 0.54 0.30 0.62 0.35 0.78 0.40 0.90 Again, find the spring constant for the same spring using the dynamic method, i.e. by plotting T2 (along y-axis)...
The period for oscillation of the cart is given by T = Sketch a graph of the displacement of the spring as a function of time in Fig. 12.7, again assuming that the spring was stretched by 2.0 cm when the cart was released from rest. Make sure that you put appropriate numbers on the vertical and horizontal axes. Figure 12.7: Simple harmonic motion of the cart.
A student must determine how the mass of a block affects the
period of oscillation when the block is attached to a vertical
spring. The value of the spring constant is known. The student
writes the following experimental procedure.
1. Use an electronic balance to measure the mass of the
block.
2. Attach the block to the vertical spring.
3. Displace the block from the system’s equilibrium position to a
new vertical position.
4. Release the block from rest.
5....
Position vs. Time of a Mass-Spring System in Simple Harmonic Motion 0.85. 080 0.75 0.70 13 12 11 10 7 9 6 Times) 5 1. Make a sketch to predict what the graph of position vs. time would look like. There's no need for numbers -just the basic shape, assuming that the motion sens the mass is at its hiahest point.2 pts or clock starts when Pick up the handout of an actual graph of position motion sensor. Make any...
Homework for Lab 15: Simple Harmonic Motion Name Date Section 15 10 -5 -15-10-5 0 5 10 15 Displacement (em) Figure 15.6: Force vs displacement graph for a 0.75 kg cart on a horizontal spring. 1. Figure 15.6 shows the force exerted by the spring on a 0.75 kg cart, as a function of its displacement from equilibrium. Positive displacements (in cm) represent stretching of the spring; negative displacements represent compression. Find the spring constant. 2. The cart is moved...
1. The left figure is a history graph that shows the displacement D of a traveling wave at a given position as a function of time. The right figure is a snapshot graph that shows the displacement of the same wave as a function of position. D (cm) D (cm) -1 -2 2/3 4 67 8 -2 (a) Determine the period T, the frequency f, and the angular frequency o for this wave. (b) Determine the wavelength 2, wavenumber K,...
An object's motion is represented by the x vs. t graph shown below Hint: Velocity is the slope of x vs. t graph, and acceleration is slope of v vs. t graph. 130 points: 5 points each r (s) t (a) a. Draw the corresponding v vs. t graph on the axes provided. b. Draw the corresponding a vs. t graph on the axes provided. c. At what times is the position a maximum (most positive)? At those times, is...
A student must determine how the mass of a block affects the period of oscillation when the block is attached to a vertical spring. The value of the spring constant is known. The student writes the following experimental procedure.Use an electronic balance to measure the mass of the block.Attach the block to the vertical spring.Displace the block from the system’s equilibrium position to a new vertical position.Release the block from rest.Use a meterstick to measure the vertical displacement of the...
(1 point) The graph shows the displacement from equilibrium of a mass-spring system as a function of time after the vertically hanging system was set in motion at time t0. Assume that the units of time are seconds, and the units of displacement are centimeters. The first t-intercept is (0.75, 0) and the first minimum has coordinates (1.25,-1) (a) What is the period T of the periodic motion? seconds (b) What is the frequency f in Hertz? What is the...