A remote-controlled car is moving in a vacant parking lot. The velocity of the car as a function of time is given by υ⃗ =[5.00m/s−(0.0180m/s3)t^2]i^ + [2.00m/s+(0.550m/s^2)t]j^.
What is the direction (in degrees counterclockwise from +x-axis) of the acceleration of the car at t = 7.48 s ?
Express your answer to three significant figures and include the appropriate units.
A remote-controlled car is moving in a vacant parking lot. The velocity of the car as...
A remote-controlled car is moving in a vacant parking lot. The velocity of the car as a function of time is given by υ⃗ =[5.00m/s−(0.0180m/s3)t2]i^ + [2.00m/s+(0.550m/s2)t]j^ a> What is ax(t) the x-component of the acceleration of the car as function of time? ax(t)=(−0.0180m/s3)t ax(t)=(0.0360m/s3)t ax(t)=(−0.0360m/s3)t b> What is ay(t) the y-component of the acceleration of the car as function of time? ay(t)=2.00m/s2 ay(t)=0.550m/s2 ay(t)=(−0.550m/s2)t c> What is the magnitude of the velocity of the car at t = 6.59...
i already tried poaitive 65.2 A remote-controlled car is moving in a vacant parking lot. The velocity of the car as a function of time is given by v = [5.00 m/s - (0.0180 m/s^3)t^2]i + [2.00 m/s + (0.550 m/s^2)t]j. What is the direction (in degrees counterclockwise from +x-axis) of the acceleration of the car at t = 7.05 s ? Express your answer to three significant figures and include the appropriate units.
A remote-controlled car is moving in a vacant parking lot The velocity of the car as a function of time is given by U - [5.00 m/s (0.0180 m/')tli + [200 m/s + (0.550 m/s,tj We were unable to transcribe this imageWe were unable to transcribe this image
Exercise 3.8 Constants A remote-controlled car is moving in a vacant parking lot. The velocity of the car as a function of time is given by 0 15.00 m/s-(0.0180 m/s )li+ 2.00 m/s + (0.60 m/tj
Part C Constants A remote-controled car is moving in a vacant parking lot. The velocity of the car as a unction of Sime is given by5.00 m/s (0.0180 m/e +12.00 m/s+(00 What is the magnitude of he velecity of the car at t6.50 Express your answer to three signficant figures and include the appropriate units U- 1 Value Units Part D What is the direction (in degrees counherdlockwise from*-ais) of the velocity of the car at t6.50s Express your answer...
first picture has the information you need to do the other parts A remote-controlled car is moving in a vacant parking lot. The velocity of the car as a function of time is given by ū– (5.00 m/s – (0.0180 m/s”){%)+ [2.00 m/s + (0.550 m/s?)t)ì. Part C What is the magnitude of the velocity of the car at t = 6.73 s? Express your answer to three significant figures and include the app ? v= Value Units Submit Request...
A girl operates a radio-controlled model car in a vacant parking lot. The girl’s position is at the origin of the xy coordinate axes, and the surface of the parking lot lies in the xy plane. She drives the car in a straight line so that the x coordinate is defined by the relation x(t) = 0.5t3 - 3t2 + 3t + 2 where x and t are expressed in meters and seconds, respectively. Determine when the velocity is 0...
6. Two cars are moving in a flat parking lot. Car A is moving in a circle of radius 2 and it's position as a function of time,t, is FA(t)2cos(t), 2sin(t) >. A second car, Car B, starts at the edge of the lot at position re(0) =< 1,-2 >. At t-0, Car B accelerates from rest (initial velocity < 0,0 >) in a straight line with acceleration vector FB"(t)-0,c. Note: At t-0 Car A is at FA(0) 2,0and Car...
A small toy airplane is flying in the xy-plane parallel to the ground. In the time interval t=0 to t=10.0 s, its velocity as a function of time is given by υ⃗ =(1.30m/s2)ti^+[12.0m/s−(2.00m/s2)t]j^υ→=(1.30m/s2)ti^+[12.0m/s−(2.00m/s2)t]j^. At what value of t is the velocity of the plane perpendicular to its acceleration? Express your answer to three significant figures and include the appropriate units.
A car, traveling due north, has an initial velocity of 18 m/s accelerates for 9 s for a distance of 180 m. What is the velocity of the car after the acceleration? (5) A remote controlled car is moving through a parking lot described by the position function r(t) = [2.5 m - (0.015 m/s^2) t^2] i - [0.6 m - (0.1 m/s) t + (0.032 m/s2) t^2] j. What is the speed of the toy car at t =...