A certain car traveling at 34.0 mph skids to a stop in 29 meters from the...

A car traveling at 17.2 m/s skids to a stop in 188 m from the point...

A car traveling at 17.2 m/s skids to a stop in 188 m from the point where the brakes were applied. In what distance would the car have stopped had it been going 58.5 m/s , if tires and road condition were unchanged (i.e. if the acceleration were the same)?

A car traveling at 18.0 m/sm/s skids to a stop in 28.5 mm from the point...

A car traveling at 18.0 m/sm/s skids to a stop in 28.5 mm from the point where the brakes were applied. In what distance would the car have stopped had it been going 59.4 m/sm/s , if tires and road condition were unchanged (i.e. if the acceleration were the same)?

A car traveling at 45 mph on a poor, wet pavement has a braking efficiency of...

A car traveling at 45 mph on a poor, wet pavement has a braking efficiency of 87%. The brakes were applied 100 feet before hitting an obstacle in the road. The road is uphill for 40 feet and then is level for the remainder of the way. The car had a maximum coefficient of road adhesion in the sloped portion of the poor, wet roadway and but as soon as it started going on the level portion its coefficient of...

A car traveling at 45 mph on a poor, wet pavement has a braking efficiency of...

A car traveling at 45 mph on a poor, wet pavement has a braking efficiency of 87%. The brakes were applied 100 feet before hitting an obstacle in the road. The road is uphill for 40 feet and then is level for the remainder of the way. The car had a maximum coefficient of road adhesion in the sloped portion of the poor, wet roadway and but as soon as it started going on the level portion its coefficient of...

When traveling 40 mph (miles per hour), the distance that it takes Fred’s car to stop...

When traveling 40 mph (miles per hour), the distance that it takes Fred’s car to stop varies evenly between 120 and 155 feet. (This includes the reaction distance and the braking distance.) All of the questions are related to the stopping distance when Fred is traveling 40 mph. a) Let S be the distance it takes for Fred’s car to stop at when traveling 40 mph. Find the distribution, parameter(s), and support of S. b) What is the probability that...

A driver on Route 15 is traveling at 50 mph (~22 m/s) when they see a...

A driver on Route 15 is traveling at 50 mph (~22 m/s) when they see a dog in the road ahead. The driver’s reaction time to apply the brakes is 1.5 s. As the driver nears the dog they honk the horn and thankfully the dog runs to safety on the side of the road. The car finally comes to a stop 5 s after applying the brakes and 4 m past where the dog had been standing. How far...

A driver on Route 15 is traveling at 50 mph (~22 m/s) when they see a...

A driver on Route 15 is traveling at 50 mph (~22 m/s) when they see a dog in the road ahead. The driver’s reaction time to apply the brakes is 1.5 s. As the driver nears the dog they honk the horn and thankfully the dog runs to safety on the side of the road. The car finally comes to a stop 5 s after applying the brakes and 4 m past where the dog had been standing. How far...

A car traveling at 45 miles per hour is brought to a stop, at constant deceleration,...

A car traveling at 45 miles per hour is brought to a stop, at constant deceleration, 132 feet from where the brakes are applied. a) How far has the car moved when its speed has been reduced to 30 miles per hour? b) How far has the car moved when its speed has been reduced to 15 miles per hour? c) What is the car's rate of deceleration?

You slam on the brakes of your car in a panic, and skid a certain distance...

You slam on the brakes of your car in a panic, and skid a certain distance on a straight level road. If you had been traveling four times as fast, what distance would the car have skidded, under the same conditions?

Traveling at 40.2 m/s, a driver applies the brakes to his fast-moving car and skids out...

Traveling at 40.2 m/s, a driver applies the brakes to his fast-moving car and skids out of control on a wet concrete horizontal road. The 2000 kg car is headed directly toward a student waiting to catch a bus to campus who is standing 58.0 m down the road. Luckily, Superman is flying overhead and surveys the situation. Knowing that the coefficient of kinetic friction between rubber and rough wet concrete is .800, he determines that friction alone will not...