This month’s challenge is around field goals in American football.
Create a Mathcad worksheet where you calculate the following angles from a given line of scrimmage for making a field goal:
How can you show how those angles change as a function of the line of scrimmage?
Factors to take into consideration:
We’re dealing with Euclidean geometry, so the math shouldn’t be that complicated. What matters is your execution. What tools (like plots and charts) can help you communicate the results?
Find the Mathcad Community Challenge Guidelines here!
By the way, the longest field goal in NFL history was kicked by Justin Tucker of the Baltimore Ravens in September 2021. It was 66 yards, meaning the line of scrimmage was the Detroit 49 yard line, and it was kicked from the Baltimore 44 yard line. Next time you’re on a football field, check out how far that is and how narrow the window looks. Field goal range is considered to be within the opposing team’s 35 yard line, which means the kick is 52 yards.
Solved! Go to Solution.
I didn't do the best job of documenting my trigonometry and what my variable names refer to, but I think I hit the two objectives!
So that I dont have to talk to Bill Belichick can the kicks be made from the extreme left and right offset or just the middle offsets?
For this challenge, the kick will be made from either the left or right hash mark in the middle of the field (the ones located 40 feet apart from each other). Not the ones along the sideline that help players judge whether they are in the field of play.
And you spelled Belicheat wrong.
Hmmm! Did I miss it? Or have you not specified the initial velocity or the impulse of the kick? If it's me kicking, the ball won't ever get to the goalposts! 😉
Maybe we have to assume that when the ball goes over the goal it’s vertical velocity is zero.
Then we can work out the time and then the required horizontal velocity.
So the ball stops falling as it gets to the goal? Does not continue to the ground? Does not bounce?
Hmmm!
Ignore the third bullet for now. I thought I had a solution that didn't involve initial velocity. Unfortunately I'm too booked up today to go back to research it. (I came up with this problem weeks ago.) Due to expediency, I will probably just take the third part out.
With my newly granted editing powers, the third bullet has been... removed!
Hopefully this should get the first brave soul to submit something?
Okay! Challenge to find required velocity? You're on!
But if I want to make it into a dissertation....
Does the field run the typical North-South direction? And are we kicking north or south?
Okay!
Express can't solve this for a general case. But a solve block can.
Prime 4 Express file attached.
Here is my go at it.
May have done better with soccer!
Prime 8 file attached.
PDF attached
I didn't do the best job of documenting my trigonometry and what my variable names refer to, but I think I hit the two objectives!
Quick reminder to everyone that November only has 30 days, so this is the last day the challenge will be open for canon submissions!
Thanks to those that participated (and PTC Community badges are given out). Here's Dave's write-up blog: https://www.mathcad.com/en/blogs/community-challenge-football-field-goal-geometry