2011-10-16, 01:07 PM
Hello. I am a 1st year Engineering Physics student and I am having a bit of a problem with one of the questions. I was wondering if anyone here could possibly help me, for instance show me what to do to be able to solve it. Here is the question:
"A cannon can project a cannonball from its barrel with a certain muzzle speed v[SUB]0[/SUB]. Ignoring the effects of air resistance, what formula expresses the distance the cannonball travels before it reaches the ground as a function of the angle 'theta' that the barrel makes with the ground? Unlike the projectile treated in Section 3-4, the cannonball is fired from the edge of a cliff of height h[SUB]0[/SUB] above the level plain at which it is aimed. Show that the angle 'theta' that gives the largest horizontal range is given by sin[SUP]2[/SUP]'theta' = v[SUB]0[/SUB][SUP]2[/SUP]/2(v[SUB]o[/SUB][SUP]2[/SUP] + 2gh[SUB]0[/SUB]). [Hint: In calculus, you learn that a function of a variable such as 'theta' has a maximum (or a minimum) at an angle 'theta[SUB]0[/SUB]', the angle for which the derivative of the function with respect to 'theta' is zero."
I finished the first part of the question, but am having a huge difficulty trying to get the second part. What I tried to do was split the function into components of y and x, where both are related to theta and time. I then had the y component = 0 to use the quadratic formula to find t, and then plugged t into x to relate x with respect to the angle. I then took the derivative (huge, long mother-f) and attempted to set it to 0 and simplify. But, I mess up. Any help from the smart people of Southperry is appreciated!
"A cannon can project a cannonball from its barrel with a certain muzzle speed v[SUB]0[/SUB]. Ignoring the effects of air resistance, what formula expresses the distance the cannonball travels before it reaches the ground as a function of the angle 'theta' that the barrel makes with the ground? Unlike the projectile treated in Section 3-4, the cannonball is fired from the edge of a cliff of height h[SUB]0[/SUB] above the level plain at which it is aimed. Show that the angle 'theta' that gives the largest horizontal range is given by sin[SUP]2[/SUP]'theta' = v[SUB]0[/SUB][SUP]2[/SUP]/2(v[SUB]o[/SUB][SUP]2[/SUP] + 2gh[SUB]0[/SUB]). [Hint: In calculus, you learn that a function of a variable such as 'theta' has a maximum (or a minimum) at an angle 'theta[SUB]0[/SUB]', the angle for which the derivative of the function with respect to 'theta' is zero."
I finished the first part of the question, but am having a huge difficulty trying to get the second part. What I tried to do was split the function into components of y and x, where both are related to theta and time. I then had the y component = 0 to use the quadratic formula to find t, and then plugged t into x to relate x with respect to the angle. I then took the derivative (huge, long mother-f) and attempted to set it to 0 and simplify. But, I mess up. Any help from the smart people of Southperry is appreciated!

