Crail and Whipple design a loop-the-loop track for a small toy car (see figure below). The car starts at height \( y_i \), above the bottom of the loop, goes through the loop of radius \( R \), and then travels along a flat, horizontal track. Rolling friction is negligible. What is the minimum height \( y_i \) from which the car can be released so that the car just barely makes it around the loop? (Use the following as necessary: \( R \).)\[ \frac{y_i}{R} = \]**Diagram Explanation:**The diagram shows a side view of the track. The track begins with a long, sloped path leading to a vertical loop. The loop is circular with a radius labeled \( R \). Above the start of the slope is an indication of the initial height \( y_i \) where the toy car is placed. The horizontal axis is labeled \( x \) and the vertical axis is labeled \( y \). At the top of the loop, there's a small cart representing the toy car. The objective is to calculate \( \frac{y_i}{R} \), the ratio of the initial height to the loop's radius, ensuring enough energy is available for the car to traverse the loop without falling off.

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Description: Crail and Whipple design a loop-the-loop track for a small toy car (see figure below). The car starts at height \( y_i \), above the bottom of the loop, goes through the loop of radius \( R \), and then travels along a flat, horizontal track. Rollin

To barely make it around the loop, the normal force on the car at the top of the loop must be zero.…

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Crall and Whipple design a loop-the-loop track for a small toy car (see figure below). The car starts at height y, above the bottom of the loop, goes through the loop of radius R, and then travels along a flat, horizontal track. Rolling friction is negligible. What is the minimum height y, from which the car can be released so that the car just barely makes it around the loop? (Use the following as necessary: R.) Y =

Crall and Whipple design a loop-the-loop track for a small toy car (see figure below). The car starts at height y, above the bottom of the loop, goes through the loop of radius R, and then travels along a flat, horizontal track. Rolling friction is negligible. What is the minimum height y, from which the car can be released so that the car just barely makes it around the loop? (Use the following as necessary: R.) Y =

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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