right triangles
Use the rule of Pythagoras - calculate the distance as squareroot(deltax2 + deltay2), where deltax and deltay are the differences in the x and y coordinates, respectively.Use the rule of Pythagoras - calculate the distance as squareroot(deltax2 + deltay2), where deltax and deltay are the differences in the x and y coordinates, respectively.Use the rule of Pythagoras - calculate the distance as squareroot(deltax2 + deltay2), where deltax and deltay are the differences in the x and y coordinates, respectively.Use the rule of Pythagoras - calculate the distance as squareroot(deltax2 + deltay2), where deltax and deltay are the differences in the x and y coordinates, respectively.
It is Pythagoras' theorem that is applicable to any right angle triangle.
Pythagoras's' theorem or "got an want" on a right angled triangle but use sine rule on a non right angled triangle !! ..
Pythagoras' theorem is applicable to right angle triangles
I think you can't use 'being' out of sorts I've been out of sorts and I'd like a chat. I'm feeling out of sorts.
No. Sine rule (and cosine rule) apply to all triangles in Euclidean space (plane geometry). A simplification occurs when there is a right angle because the sine of the right angle is 1 and the cosine is 0. Thus you get Pythagoras theorem for right triangles.
Use the Pythagoras formula. In this case, squareroot(3002 + 4002) = 500.Use the Pythagoras formula. In this case, squareroot(3002 + 4002) = 500.Use the Pythagoras formula. In this case, squareroot(3002 + 4002) = 500.Use the Pythagoras formula. In this case, squareroot(3002 + 4002) = 500.
Yes
Geometry
Use Pythagoras' Theorem - the hypothenuse of a right triangle is square root of (a2 + b2)Use Pythagoras' Theorem - the hypothenuse of a right triangle is square root of (a2 + b2)Use Pythagoras' Theorem - the hypothenuse of a right triangle is square root of (a2 + b2)Use Pythagoras' Theorem - the hypothenuse of a right triangle is square root of (a2 + b2)
they use it by eating cake
You use shapes in architecture, and the shapes you use are geometric ones.