Why won't my graph plot
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x = (v^2*sin(theta)^2)/g; % Where the projectile lands if it does not split it up
y = x*tan(theta)-(g*x^2)/(2*v^2*cos(theta)^2);% The trajectory the projectile takes.
plot(x,y)
5 Kommentare
Rik
am 23 Jan. 2019
Probably because you are using matrix operation ( like ^ * and / ) instead of the element-wise operations ( .^ .* and ./)
Kevin Phung
am 23 Jan. 2019
can you provide more information on the other variables? Are theta and V constant?
If so then x is a constant and so is your y value-- so plotting would just give a point.
Can you also elaborate on 'Why wont my graph plot'.
Is no figure appearing at all? Is there an error message?
Osamah Ahmed
am 23 Jan. 2019
Kevin Phung
am 23 Jan. 2019
So it is plotting, but just a point.
You cant get a curve if you dont have a variable in your equation.
Walter Roberson
am 23 Jan. 2019
Where is time in your equations ?
Antworten (2)
Image Analyst
am 25 Jan. 2019
Bearbeitet: Image Analyst
am 25 Jan. 2019
1 Stimme
My attached projectile program (developed by me duing my son's college physics class) plots and computes just about everything you could possibly want regarding a drag-free projectile.
madhan ravi
am 24 Jan. 2019
0 Stimmen
Put dots in front of ^ and * (element wise operation ) since x is a vector , you will get a curve.
7 Kommentare
Walter Roberson
am 25 Jan. 2019
No they won't. They have no time component in their equations. They said that theta and v are constant; that is going to give constant x and constant y unless g is non-scalar. And if your gravity is not a constant, then you definitely need to include a time component in your equations.
Image Analyst
am 25 Jan. 2019
Bearbeitet: Image Analyst
am 25 Jan. 2019
Gravity is not exactly a constant (as you know). It changes with the projectile's altitude, and since the altitude changes with time of flight, the gravity changes with time, though probably negligibly.
In fact one thing people don't realize is that the gravity in the International Space Station is almost the same as on earth. You weigh more in the "weightless" environment of the ISS than on the moon! Surprising, to most people. Just calculate it using Newton's gravitational force formula and see for yourself:
F_earth = G*m1*m2/6371^2 m1 = mass of earth, m2 = mass of human
F_ISS = G*m1*m2/(6371 + 400)^2 400 is distance of ISS above earth's surface in km
ratio = 6331^2 / (6731^2) = 88.4% as much on ISS as on earth.
Just another astronomical, non-intuitive, fun fact (like meteorites being burning hot when they land, etc.)
I really admire rocket scientists (like my late father) who were able to do all those calculations, with complicating things like drag, multiple moving bodies, changing gravity, etc., with the primitive computers at the time.
madhan ravi
am 25 Jan. 2019
oops ! didn’t read the comment given by the user thank you both.
Image Analyst
am 25 Jan. 2019
Interesting. So they have all kinds of temperatures. Well there are at least enough of them falling on the Antarctic such that NASA has a team of people on snowmobiles searching the Antarctic for them. The ones they find were evidently cooled down enough by the frigid -60 degree upper atmosphere air that they land on the snow and just sit there - they don't melt through. Or at least the ones they find don't, and they find more in the Antarctic than anywhere because they're easy to see. I wonder if Answers contributor Chad Greene has personally found any of these at the Antarctic.
Chad Greene
am 15 Feb. 2019
@ImageAnalyst, they're easiest to find in the McMurdo Dry Valleys, where there's very little weathering. Footprints can stick around for decades there.
Image Analyst
am 16 Feb. 2019
Are they sitting on the snow, or gravel? How do they find them? By sight (sitting on snow) or my metal detectors?
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