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

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

PLEASE DRAW THE FLOW CHART AND PSEUDO CODE FOR BELOW CASE ° If projectile with initial velocity u (m/sec) is fired at angle θ(with horizontal), then the horizontal range R is given by R =u² sin 2θ/g where g =9.81 m/sec2. °Draw a flowchart to compute each value of R when u varied from 20-150 m/s and 400 to 500 m/s at θ=50° .

A projectile is thrown with an initial speed v0 at an angle θ =240 as shown...

A projectile is thrown with an initial speed v0 at an angle θ =240 as shown in the figure. At time tA the projectile reaches the point A with coordinates (d,h) where d=33m and h=5.3m in the given coordinate system.

A projectile is fired at an angle of 28 degrees above the horizontal with an initial...

A projectile is fired at an angle of 28 degrees above the horizontal with an initial velocity of 1,800 feet per second from an altitude of 1,000 feet above the ground. A) Formulate the vector valued function (in simplified form) for the position of the projectile at any time, t. B) When and where (in terms of down range distance) does the projectile strike the ground? Be clear and label your results, including units. C) When does the projectile reach...

Using the average vertical range and the height, calculate the initial velocity (muzzle velocity) using equations...

Using the average vertical range and the height, calculate the initial velocity (muzzle velocity) using equations 5,6,7, & 8. x-coordinate axis 5y.) xf = (1/2)·ax·(Δt) 2 + vix·Δt + xi r = (1/2)·(0 m/s2 )·(Δt) 2 + vix·Δt + (0 m) 5x.) r = vix·Δt y-coordinate axis 6y.) yf = (1/2)·ay·(Δt) 2 + viy·Δt + yi 2y.) (0 m) = (1/2)·(-g)·(Δt) 2 + viy·Δt + (h) where g = 9.8 m/s2 where vix and viy are the components of the...

Use the model for projectile motion, assuming there is no air resistance and g=32 feet per...

Use the model for projectile motion, assuming there is no air resistance and g=32 feet per second per second. A bomber is flying at an altitude of 30,000 feet at a speed of v= 510 miles per hour (see figure). When should the bomb be released for it to hit the target? (Give your answer in terms of angle of depression from the plane to the target. Round your answer to two decimal places.) What is the speed of the...

You throw a tennis ball North with an initial speed of 24 feet per second, at...

You throw a tennis ball North with an initial speed of 24 feet per second, at an angle of elevation 30° above horizontal, releasing the ball 4 feet above the ground. A steady wind imparts a constant acceleration of 3 feet per second squared Eastward. Acceleration due to gravity is a constant 32 feet per second squared downward. Throughout the problem, let East be the positive x direction, North the positive y direction, and up the positive z direction. Let...

Let ?⃗(?)=〈(?0cos?)?,−12??2+(?0sin?)?〉r→(t)=〈(v0cos⁡θ)t,−12gt2+(v0sin⁡θ)t〉 on the time interval [0,2?0sin??][0,2v0sin⁡θg], where ?>0g>0; physically, this represents projectile motion with initial...

Let ?⃗(?)=〈(?0cos?)?,−12??2+(?0sin?)?〉r→(t)=〈(v0cos⁡θ)t,−12gt2+(v0sin⁡θ)t〉 on the time interval [0,2?0sin??][0,2v0sin⁡θg], where ?>0g>0; physically, this represents projectile motion with initial speed ?0v0 and angle of elevation ?θ (and ?∼9.81m/s2g∼9.81m/s2). Find speed as a function of time ?t, and find where speed is maximised/minimised on the interval [0,2?0sin??][0,2v0sin⁡θg].