2. A new underwater robot is used to explore the corals in the West Philippine Sea. The seafloor lies in thexy-plane and the robot's point of release is the origin of the coordinates. The robot, which we represent as aand y - coordinates that vary with time according to x = 3.0 m - (0.50 4) t2 and y =point, has x(7.0 -)t+(0.090 )t3. Find the robot's average velocity vector during the time interval from t = 0.0 s tot = 5.0 s.3. The position vector of an underwater drone is given byf=xi+yj= [2.0m-(0.40 프) 2리i+((6.0 프): + (0.080 )-1,%3DFind the instantaneous acceleration at t = 7.00 s.

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2. A new underwater robot is used to explore the corals in the West Philippine Sea. The seafloor lies in the xy-plane and the robot's point of release is the origin of the coordinates. The robot, which we represent as a point, has x - and y - coordinates that vary with time according to x = 3.0 m- (0.50 )t2 and y = (7.0 )t+ (0.090 )t3. Find the robot's average velocity vector during the time interval from t = 0.0 s to t = 5.0 s.

2. A new underwater robot is used to explore the corals in the West Philippine Sea. The seafloor lies in the xy-plane and the robot's point of release is the origin of the coordinates. The robot, which we represent as a point, has x - and y - coordinates that vary with time according to x = 3.0 m- (0.50 )t2 and y = (7.0 )t+ (0.090 )t3. Find the robot's average velocity vector during the time interval from t = 0.0 s to t = 5.0 s.

Physics for Scientists and Engineers with Modern Physics

10th Edition

ISBN:9781337553292

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter4: Motion In Two Dimensions

Section: Chapter Questions

Problem 44AP: A projectile is launched from the point (x = 0, y = 0), with velocity (12.0i19.0j)m/s2, at t = 0....

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