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Example Problem A car is traveling on a dry road with a velocity of +32.0 m/s. The driver slams on the brakes and skids to a halt with an acceleration.

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Presentation on theme: "Example Problem A car is traveling on a dry road with a velocity of +32.0 m/s. The driver slams on the brakes and skids to a halt with an acceleration."— Presentation transcript:

1 Example Problem A car is traveling on a dry road with a velocity of m/s. The driver slams on the brakes and skids to a halt with an acceleration of –8.00 m/s2. On an icy road, the car would have skidded to a halt with an acceleration of –3.00 m/s2. How much further would the car have skidded on the icy road compared to the dry road? Solution: Given: v0 = 32.0 m/s in positive x-direction adry = m/s2 in positive x-direction aicy = m/s2 in postive x-direction Also, v=0, assume t0=0, x0=0 Find xdry and xicy, or xicy-xdry

2 Example Problem A Boeing 747 Jumbo Jet has a length of 59.7 m. The runway on which the plane lands intersects another runway. The width of the intersection is 25.0 m. The plane decelerates through the intersection at a rate of 5.70 m/s2 and clears it with a final speed of 45.0 m/s. How much time is needed for the plane to clear the intersection? Solution: Given: a = m/s2 in x-direction v = 45.0 m/s in x-direction Lplane = 59.7 m, Lintersection = 25.0 m Assume, t0 = 0 when nose of Jet enters intersection. Find t when tail of Jet clears intersection.

3 Example Problem (you do)
An electron with an initial speed of 1.0x104 m/s enters the acceleration grid of a TV picture tube with a width of 1.0 cm. It exits the grid with a speed of 4.0x106 m/s. What is the acceleration of the electron while in the grid and how long does it take for the electron to cross the grid? Solution: Given: v0 = 1.0x104 m/s in x-direction v = 4.0x106 m/s in x-direction x=1.0 cm Find a (=8.0x1014 m/s2) and t (=5.0 ns).

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