Q5: - At any instant the horizontal position of helicopter is defined by x = (4t)...

At any instant the horizontal position of the weather balloon is defined by x = (8t)...

At any instant the horizontal position of the weather balloon is defined by x = (8t) ft, where t is in seconds. If the equation of the path is y = x2/10, determine the magnitude of the velocity and acceleration when t = 2s. For a short time, the path of the pane is described by y = (0.001x2) m. If the plane is rising with a constant velocity of 10 m/s, determine the magnitudes of the velocity and acceleration...

At any instant, the horizontal and vertical position of the weather balloon in given Fig is...

At any instant, the horizontal and vertical position of the weather balloon in given Fig is defined by x = (12t) m and y=(5t2 )m, respectively where t is in seconds. Determine the magnitude and direction of the velocity when t = 2 s

A particle travels along the path defined by the parabola y=0.2x^2. If the component of velocity...

A particle travels along the path defined by the parabola y=0.2x^2. If the component of velocity along t he x axis is Vx=(2.9t)ft/s, where t is in seconds. determine the magnitude of the particle's acceleration when t = 1s. when t = 0 , x =0 and y = 0.

A particle is constrained to travel along a path on the xy-plane. r_x=(4t^4)m and r_y=2(sqrt(x)) where...

A particle is constrained to travel along a path on the xy-plane. r_x=(4t^4)m and r_y=2(sqrt(x)) where t is in seconds(rx and ry are the direction vectors of the particle), determine the magnitude of the particle's velocity and acceleration when t=0.5s

1-The velocity of a particle is v = { 6 i + ( 28 - 2...

1-The velocity of a particle is v = { 6 i + ( 28 - 2 t ) j } m/s, where t is in seconds. If r=0 when t=0, determine particle displacement during time interval t = 3 s to t = 8 s in the y direction. 2-A particle, originally at rest and located at point (1 ft, 4 ft, 5 ft), is subjected to an acceleration of a={ 3 t i + 17 t2k} ft/s. Determine magnitude...

1)A particle moves along the x axis. Its position is given by the equation x =...

1)A particle moves along the x axis. Its position is given by the equation x = 1.8 + 2.5t − 3.9t2 with x in meters and t in seconds. (a) Determine its position when it changes direction. (b) Determine its velocity when it returns to the position it had at t = 0? (Indicate the direction of the velocity with the sign of your answer.) 2)The height of a helicopter above the ground is given by h = 3.10t3, where...

The position of a model helicopter of weight 3.50 x 105 N under test is given...

The position of a model helicopter of weight 3.50 x 105 N under test is given in unit vector notation by ?⃗ =[(15.0??)? + (0.30 ??3)?3]?̂−(0.850 ??2)?2?̂. a. Determine the velocity in magnitude-direction notation of the helicopter at t = 2.50 s. b. What net force is acting on the helicopter in unit vector notation at t = 2.50 s?

1. The position of a bird in the xy-plane is given by ?⃗ = (3.0?−∝ ?)?̂+...

1. The position of a bird in the xy-plane is given by ?⃗ = (3.0?−∝ ?)?̂+ ?? 2 ?̂where ∝= 1.6 ?/? and ? = 0.8 ?/? 2 . a) What are Vx(t) and Vy(t), x and y components of the velocity of the bird as a function of time? b) What is the bird’s net velocity at 3.0 s (magnitude and direction)? c) What are ax(t) and ay(t), x and y components of the acceleration of the bird as...

The x and y components of the velocity of a particle are Vx=(2t + 4)ft/s &...

The x and y components of the velocity of a particle are Vx=(2t + 4)ft/s & Vy=(8/y)ft/s. Initially, the particle if found at coordinates x=1 and y=0. Determine the position, magnitude of velocity, and magnitude of the acceleration of the particle when t = 2s

The position ? of a particle moving in space from (t=0 to 3.00 s) is given...

The position ? of a particle moving in space from (t=0 to 3.00 s) is given by ? = (6.00?^2− 2.00t^3 )i+ (3.00? − ?^2 )j+ (7.00?)? in meters and t in seconds. Calculate (for t = 1.57 s): a. The magnitude and direction of the velocity (relative to +x). b. The magnitude and direction of the acceleration (relative to +y). c. The angle between the velocity and the acceleration vector. d. The average velocity from (t=0 to 3.00 s)....