In coming to a stop, a car leaves skid marks 69 mm long on the highway....

In coming to a stop, a car leaves skid marks 73 m long on the highway....

In coming to a stop, a car leaves skid marks 73 m long on the highway. Assuming a deceleration of 6.50 m/s2 , estimate the speed of the car just before braking.

In coming to a stop, a car leaves skid marks 73 m long on the highway....

In coming to a stop, a car leaves skid marks 73 m long on the highway. a.)Assuming a deceleration of 3.80 m/s2 , estimate the speed of the car just before braking. Graphically determine the resultant of the following three vector displacements: (1) 24 m, 36? north of east; (2) 18 m, 37? east of north; and (3) 26 m, 33? west of south. a.)Determine the resultant length. b.)Determine the resultant direction.

You are driving on a mountain highway in your car, which is sloped downward at an...

You are driving on a mountain highway in your car, which is sloped downward at an angle of 7 degrees below the horizontal. Your car has a mass of 1200kg and your speed is 25 m/s. A moose steps out into the highway and you slam on your brakes, skidding to a stop. The force of kinetic friction between your car and the road is 9500.0 N. a) Using an energy analysis, compute how far you skid before you come...

An automobile is traveling on a long, straight highway at a steady 77.0 mi/h when the...

An automobile is traveling on a long, straight highway at a steady 77.0 mi/h when the driver sees a wreck 200 m ahead. At that instant, she applies the brakes (ignore reaction time). Between her and the wreck are two different surfaces. First there is 100 m of ice, where the deceleration is only 1.30 m/s2 . From then on, it is dry concrete, where the deceleration is a more normal 7.60 m/s2 Part A. What was the car’s speed...

The coefficient of friction between a tire and dry asphalt is 0.7. For a car with...

The coefficient of friction between a tire and dry asphalt is 0.7. For a car with mass of 1700 kg and an initial speed of 31 mph: (A) Calculate the magnitude of the friction force on the car. Assume the road is flat (i.e. is not inclined at an angle). (B) Calculate the distance the car will slide when coming to rest. (C) Calculate the time the car will take to slide to rest. (D) If the speed of the...

A car is at rest at a stop sign and there is another stop sign 100...

A car is at rest at a stop sign and there is another stop sign 100 m down the road. The car can brake with an acceleration of 16 m/s/s. The car accelerates with a constant rate for some time before accelerating with that braking rate to come to a stop at the second stop sign. The entire trip takes 10 seconds. Let right be positive. Don’t round until the end. Report using 3 digits. Don't enter units. (1) With...

A car is at rest at a stop sign and there is another stop sign 100...

A car is at rest at a stop sign and there is another stop sign 100 m down the road. The car can brake with an acceleration of 16 m/s/s. The car accelerates with a constant rate for some time before accelerating with that braking rate to come to a stop at the second stop sign. The entire trip takes 10 seconds. Let right be positive. Don't round until the end. Report using 3 digits. Don't enter units. 1/ With...

A 1500kg car traveling east with speed 25 m/s collides and sticks to another car traveling...

A 1500kg car traveling east with speed 25 m/s collides and sticks to another car traveling north. The combined wreck skids to a stop. The skid marks are 13m long and make an angle 23° north of east. Determine the mass and speed of the northbound car. You will need to look up the appropriate coefficient of friction. Cite sources.

A 1000 kg car is driving at a speed of 35 m/s on flat level ground....

A 1000 kg car is driving at a speed of 35 m/s on flat level ground. A road hazard ahead causes the driver to slam on the brakes, and the tires start to skid. a) If the pavement is dry (and thus μk = 0.7) how far will they travel before coming to a stop? b) If the pavement is wet, μk is reduced to 0.3. Now how far would they travel before coming to a stop?

During a very quick stop, a car decelerates at 6.2 m/s2. Assume the forward motion of...

During a very quick stop, a car decelerates at 6.2 m/s2. Assume the forward motion of the car corresponds to a positive direction for the rotation of the tires (and that they do not slip on the pavement). Randomized Variables at = 6.2 m/s2 r = 0.275 m ω0 = 93 rad/s Part (a) What is the angular acceleration of its tires in rad/s2, assuming they have a radius of 0.275 m and do not slip on the pavement? α...