This is a easy mathematical equation in my opinion take what ever number in this case 100 m and subtract it by 35 so it's 100m-35m=65m
it would be 100 - 35 = 65 m
compare the movement of the slide, left and right or forward and backward to the movement of the eyepiece image? compare the movement of the slide, left and right or forward and backward to the movement of the eyepiece image? compare the movement of the slide, left and right or forward and backward to the movement of the eyepiece image?
The person's feet push backward on the sidewalk; the sidewalk pushes forward on the person.
No, 'laser' is not a palindrome because it is not spelled the same way forward and backward.
A ton
it would be 100 - 35 = 65 m
The displacement would be 24 yards from the line of scrimmage. The distance traveled would be 56 yards.
Your displacement is 20 metres.
If you have moved forward and backward, hence ending up at the same point you started, then displacement is zero. That's because Displacement takes into account the direction - hence a vector quantity.The distance only bothers about the distance - hence it doesn't matter if you came to where you started. So in total, 5 meters up and 5 down is 10. Distance = 10
The distance a piston travels backward and forward.
Displacement is the distance from initial to ending point. Suppose you took 3 steps forward and then 2 steps back. Your displacement in 1 step forward. Distance is distance travelled in total. If you took 3 steps forward and 2 steps back, your distance travelled is 5 steps.
Displacement is the distance from initial to ending point. Suppose you took 3 steps forward and then 2 steps back. Your displacement in 1 step forward. Distance is distance travelled in total. If you took 3 steps forward and 2 steps back, your distance travelled is 5 steps.
20 meters.
What stops a car from moving forward or backward
Examples: -- up and down, but not sideways or forward and backward -- forward and backward, but not sideways or up and down -- left and right, but not forward and backward or up and down
axial shift of a steam turbine is the shifting of turbine rotor in the forward and backward direction due to steam thrust on blades of rotor.
A backward pass is one that does not go forward. Often, the receiver of a backward pass may then pass the ball forward. Once the ball has been passed forward, it may not be passed forward again during the same play.