It would depend on the gravitational field and the density of the medium through which it travels.
Depends on the medium through which it is traveling.
Assuming that you travel 882 feet in a straight line, the average velocity is 882.5 = 176.4 feet per second.
16,200 feet per hour.
One light year, or the distance that a beam of light can travel in one year, at 186,000 miles per second.
You are traveling 10 min 2 seconds. Therefore, you are traveling 5 m per second. (or 300 m per minute or 18,000 m per hour).
Ignoring the effects of wind and air-resistance in general, maximum projectile range results when the projectile is launched/fired in a direction 45 degrees above the horizontal.
A half projectile refers to the projectile motion of an object where it is launched at an angle of 45 degrees to the horizontal. This angle maximizes the range of the projectile for a given initial velocity, making it travel the furthest distance before hitting the ground. The path of the projectile is a parabolic curve.
Assuming the angle is the angle the initial trajectory makes with the ground, that it's launched with the same speed in both cases, that it's launched from an initial height of zero, that it stops dead as soon as it touches the ground and doesn't bounce or roll, and that we can neglect air resistance (sorry for all that detail, but it does matter)... Both projectiles will end up with the same net displacement, though the 60 degree projectile will have taken a longer path to get there.
A trajectory is the angle made with the horizontal when a projectile is fired. Suppose the projectile is a cannon ball. Assuming air is frictionless, that cannon ball will travel the greatest distance if the trajectory is 45 degrees from horizontal.
Force affects a projectile by determining its initial velocity and direction. The force is responsible for propelling the projectile forward and influencing its trajectory. The greater the force applied, the faster and farther the projectile will travel.
An angle of 45 degrees will allow a ball to travel the furthest in a projectile motion, assuming ideal conditions with no air resistance. This angle corresponds to the optimal balance between the vertical and horizontal components of velocity.
If you keep th velocity of projection and change the angle of projection from 75 degrees to 45 degrees what will happen to the horizontal distance the projectile travels? if you finish the nova net lesson you might learn the answer! It will travel a greater distance!
A trajectory of 45 degrees elevation gives the longest horizontal travel- (not taking air drag into consideration nor any aerodynamic properties of a projectile.
Sky travel was first launched in 2003. It showed extensive programs about travel.
When the mass of the counterweight increases, the distance of the projectile will travel should increase in a linear path due to the relationship between gravity and the counterweight. As the force exerted on the projectile is equal to the mass of the counterweight times the gravitational constant, when the mass is increased, the force will also increase. Furthermore, because for every action there is an equal and opposite reaction (Newton's Third Law), the force that is put on the counterweight should be the same force exerted on the projectile. The distance traveled then should be directly related to the mass of the counterweight. In the second test, the distance the projectile travels should be the greatest when the angle of release is closest to 45 degrees. This is due to the fact that there will be no air resistance on the projectile allowing 45 degrees to be the perfect arc for maximum distance.
True, at relatively low speeds, if the projectile was launched at maybe the speed of light, improbable as it is, this may give it enough momentum to carry on past the point were the planet's gravity has a large effect on its motion and therefore carry on moving away from the planet until stopped by another force, however, even if the initial velocity of the projectile is the same as that planets escape velocity (the speed it needs to travel at to leve the planet) this speed is not constant and the projectile will feel a very large force from the gravity of the planet and hence be brought back down to its surface
6 degrees. There are 360 degrees in a full circle, and therefore for every second the hand moves through one sixtieth of a circle.