Two automobiles of equal mass approach an intersection. One vehicle is traveling with velocity 13.0 m/s...
Two automobiles with equal mass approach an intersection. One vehicle is traveling eastward and the other vehicle is traveling northward. The vehicles collide and stick together. After impact they travel on the road and then travel on a gravel covered shoulder until both cars stop. Only the northward bound vehicle left skid marks at an angle of 55 degrees north of east. A police officer posted at the intersection clocked the eastward vehicle at 29 mph before impact. The northward...
A small compact car with a mass of 1000 kg is traveling north towards an intersection at a speed of 15 m/s. A truck with a mass of 2000 kg is traveling east at 10 m/s on the cross street approaching the same intersection. The two vehicles collide and stick together. a. What is the magnitude and direction of the velocity of both vehicles after the collision? b. How much energy was lost during the collision?
Two vehicles are approaching an intersection. One is a 2400 kg pickup traveling at 13.0 m/s from east to west (the −x- direction), and the other is a 1300 kg sedan going from south to north (the +y− direction at 21.0 m/s ). Part A Find the x -component of the net momentum of this system. Part B Find the y-component of the net momentum of this system. Part C What is the magnitude of the net momentum? Part D...
A car of mass m 2000.0kg is moving at speed vi25.0 m/s towards East. A truck of mass m2 6000.0kg is moving at speed v2i-10.0m/s towards North. They collide at an m1- intersection and get entangled (complete inelastic collision). 1. What is the magnitude and direction of the final velocity of the entangled automobiles? 2. How much kinetic energy is lost in the collision. That is, calculate the change in the kinetic energy of the system
Two cars approach an ice-covered intersection. One car, of mass 1.11*103 kg, is initially traveling north at 12.1 m/s. The other car, of mass 1.70*103 kg, is initially traveling east at 12.1 m/s. The cars reach the intersection at the same instant, collide, and move off coupled together. Find the velocity of the center of mass of the two-car system just after the collision. Magnitude= Directions = North of East
A car with a mass of 980 kg is initially traveling east toward
an intersection with a speed of vc = 20.9 m/s and a 1500 kg pickup
is traveling north toward the same intersection. The car and truck
collide at the intersection and stick together. After the
collision, the wreckage (car and truck) moves off in a direction of
44.0° above the x-axis. Determine the initial speed of the truck
and the final speed of the wreckage in meters...
Hint 1 Two cars approach an extremely icy four-way perpendicular intersection. Car A travels northward at 33 m/s and car B is traveling eastward. They collide and stick together, traveling at 380 north of east. What was the initial velocity of car B? You may assume that the cars have the same mass. Round your answer to one decimal place. m/s VB
Two cars approach an ice-covered intersection. One car, of mass 1.25 103 kg, is initially traveling north at 11.1 m/s. The other car, of mass 1.58 103 kg, is initially traveling east at 11.1 m/s. The cars reach the intersection at the same instant, collide, and move off coupled together. Find the velocity of the center of mass of the two-car system just after the collision. Please provide magnitude & direction (ex - 30 degrees North of West)
A vehicle of mass m moving North at 12 m/s collides with a vehicle of mass 2m moving East at 12 m/s. After collision the vehicles stick together and move as one body. The velocity of the combined vehicles after collision is: (all angles in Quadrant 1 = north of east) A. 8.94 m/s at 63.4 degress B. 8.94 m/s at 26.6 degrees C. 12.0 m/s at 63.4 degrees D. 12.0 m/s at 26.6 degrees E. 26.8 m/s at 63.4...
A car with mass 1500 kg traveling east at 25 m/s collides at an intersection with a 2500kg van traveling north at a speed of 20 m/s. Find the magnitude and direction of the velocity of the wreckage after the collision, assuming that the vehicles undergo a perfectly inelastic collision and assuming no friction.