B. The centripetal force of the car is also jointly related to the coefficient of static friction of the tire and road, mass, and acceleration to gravity. Now you want to investigate the possible maximum velocity speeds and possible radius of the curved path so the car can turn safely without skidding out of a curved road. To do this you must do and answer the following questions. 1. Set up the equation of the centripetal force of the moving object in both A and B. What type of variations are described in both equations? 2. Derive an equation for the squared velocity speed of the car relating both equations of centripetal force.

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)...
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number 1 & 2
Based on facts,
A. The centripetal force on a moving object (the car) varies jointly with its mass and
its squared velocity speed and varies inversely to the radius of the curved path.
B. The centripetal force of the car is also jointly related to the coefficient of static
friction of the tire and road, mass, and acceleration to gravity.
Now you want to investigate the possible maximum velocity speeds and possible radius
of the curved path so the car can turn safely without skidding out of a curved road.
To do this you must do and answer the following questions.
1. Set up the equation of the centripetal force of the moving object in both A and B.
What type of variations are described in both equations?
2. Derive an equation for the squared velocity speed of the car relating both
equations of centripetal force.
Transcribed Image Text:Based on facts, A. The centripetal force on a moving object (the car) varies jointly with its mass and its squared velocity speed and varies inversely to the radius of the curved path. B. The centripetal force of the car is also jointly related to the coefficient of static friction of the tire and road, mass, and acceleration to gravity. Now you want to investigate the possible maximum velocity speeds and possible radius of the curved path so the car can turn safely without skidding out of a curved road. To do this you must do and answer the following questions. 1. Set up the equation of the centripetal force of the moving object in both A and B. What type of variations are described in both equations? 2. Derive an equation for the squared velocity speed of the car relating both equations of centripetal force.
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