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Part A (Figure 1) shows the motion diagram for a rider on a Ferris wheel that...
The figure below is a simplified model of a Ferris wheel with diameter 210 feet. The top of the wheel is 220 feet above the ground. If the central angle formed as rider moves from position Po to positions, find the rider's height above the ground h when 0 120°. (Round your answer to one decimal place.) Need Help? Tale Tutor Submit Answer MY NOTES ASK YOUR TEACHER PRACTICE ANOTHER
The figure below is a simplified model of a Ferris wheel with diameter 210 feet. The top of the wheel is 222 feet above the ground. If O is the central angle formed as a rider moves from position Po to position P1, find the rider's height above the ground h when 0 is 120°. (Round your answer to one decimal place.) h = X ft Р. Ро h Need Help? Read It Watch It Talk to a Tutor
A Ferris wheel with radius 14.0 m is turning about a horizontal axis through its center in (Figure 1). The linear speed of a passenger on the rim is constant and equal to 8.00 m/s. Part A What is the magnitude of the passenger's acceleration as she passes through the lowest point in her circular motion? Part B What is the direction of the passenger's acceleration as she passes through the lowest point in her circular motion?Part CWhat is the magnitude of the passenger's...
Part B Review The following figure shows the first three points of a motion diagram.(Figure 1) Find the average acceleration vector at point 1. Draw the completed motion diagram, showing the velocity vectors and acceleration vector (v is velocity between points 0 and 1 and v is velocity between points 1 and 2) Draw the velocity vectors starting at the appropriate black dots and acceleration vector. The location, orientation and length of the velocity vectors will be graded. The orientation...
Item 7 Find the magnitude of the passenger's acceleration at this instant. Constants The Ferris wheel in the figure (Figure 1), which rotates counterclockwise, is just starting up. At a given instant, a passenger on the rim of the wheel and passing through the lowest point of his circular motion is moving at 3.12 m/s and is gaining speed at a rate of 0.288 m/s2 9.11 m/s2 Submit Previous Answers Request Answer Figure 1 of 1 XIncorrect; Try Again; 5...
Draw the vectors. Part A Figure shows two dots of a motion diagram and vector vh Draw the vector t if the acceleration vector a at dot 3 points to the right Draw the vector starting at the Ыack dot 3. The location and orientation of the vector will be graded. The oxactlengn of your recor-. not beg ideaal heke b en ereder n-lth.gr . No elements selected Select the elements from the list and add them to the cavas...
Constants I Periodic Table Consider the wheel shown in (Figure 1) Part A Calculate the net torque about the axle of the wheel, which starts its motion from rest. Assume that a friction torque of 0.60 n N opposes the motion Assume 25 N, F-41 N, F = 26 N Express your answer to two significant figures and include the appropriate units. ? Value Units T= Figure 1 of 1 Request Answer Submit Next > Provide Feedback 135 12 cm...
Part D In the slidewire generator of (Figure 1), you reverse the rod's motion so that it moves to the left rather than to the right. The moving rod is 5.00 cm long and moves at 2.40 m/s, and the uniform magnetic field has magnitude 0.150 T. If the resistance of the circuit at a given instant is 0.0200 12, find the current in the circuit. Express your answer with the appropriate units. ? OTH HÅR I= Value O a...
Part A Enter coordinates of point A Figure 1 of 1 Enter coordinates separated by comma: ΡΟ ΑΣΦ | 11 vec ? mm. F-400N 6 m Submit Previous Answers Request Answer * Incorrect; Try Again: 2 attempts remaining 5 m Part B Enter coordinates of point B Enter coordinates separated by comma: Figure 1 of 1 190 AED 11 vec h ? A mm F400N Submit Request Answer Part position vector from A to B Part position vector from A...
Problem 23.38 Part A The figure(Figure 1) shows a zero-resistance rod sliding to the night on two zero-resistance rails separated by the distance L 0.359 m. The rails are connected by a 116 resistor, and the entire system is in a uniform magnetic field with a magnitude of 0.733 T Find the force that must be exerted on the rod to maintain a constant current of 0 164 A in the resistor | ΑΣΦ και ? mN Submit Request Answer...