PLEASE DRAW THE FLOW CHART AND PSEUDO CODE FOR BELOW CASE ° If projectile with initial...

The range R of a projectile is shown below, where v0 is the initial velocity in...

The range R of a projectile is shown below, where v0 is the initial velocity in feet per second and θ is the angle of elevation. R =( v sub 02 /32) (sin 2θ) Use differentials to approximate the change in the range when v0 = 2700 feet per second and θ is changed from 10° to 9°. (Round your answer to the nearest whole number.)

A projectile is fired with an initial speed of 48.6 m/sat an angle of 44.2 ∘...

A projectile is fired with an initial speed of 48.6 m/sat an angle of 44.2 ∘ above the horizontal on a long flat firing range. Part A Determine the maximum height reached by the projectile. ymax = nothing   m   SubmitRequest Answer Part B Determine the total time in the air. t = nothing   s   SubmitRequest Answer Part C Determine the total horizontal distance covered (that is, the range). Δx = nothing   m   SubmitRequest Answer Part D Determine the speed of...

Projectile in 2D: A ball is thrown with initial speed V , at an angle θ...

Projectile in 2D: A ball is thrown with initial speed V , at an angle θ above the horizontal, over flat ground. Show that the motion is restricted to a single plane. Neglecting air resistance, find (a) the time taken for the ball to reach the ground; (b) the maximum height reached by the ball; (c) the horizontal distance travelled by the ball before hitting the ground (range); (d) the kinetic and potential energies at the position of maximum height...

. A mortar is a simple projectile which is launched at a fixed velocity v0, but...

. A mortar is a simple projectile which is launched at a fixed velocity v0, but the angle θ at which it is launched can be varied. An artillery officer finds that he can hit a target a maximum distance of 2.25 kilometers away when launched on the flat horizontal practice range. The officer is later charged with using the same mortar to strike an enemy ammunition depot before it can be moved. He determines that the depot is a...

please use Projectile simulator, for the Lab Projectile Motion in 2-D and answer question below 14....

please use Projectile simulator, for the Lab Projectile Motion in 2-D and answer question below 14. Solve for t. [Hint, you can factor one of the variables.] 15. What is the smaller answer referring to? Given that your larger answer should be the time it takes to land, use that in your x-position equation, i.e. rewrite your equation for x, replacing t with what you got in #14. 16. How far does it travel in the x-direction before it lands?...

A projectile motion (i.e. cannon) can be modeled via the following equations: x=u cos⁡θ t y=-0.5...

A projectile motion (i.e. cannon) can be modeled via the following equations: x=u cos⁡θ t y=-0.5 g t^2+u sin⁡θ t Where: x: Position of the cannonball after t seconds in the x-direction (meters) y: Position of the cannonball after t seconds in the y-direction (meters) u: Initial velocity of the cannonball (meters per second) g: Acceleration due to gravity (meters per second squared) t: Time (seconds) In this question, we are trying to see the effects of the angle ϴ...