In my short career as a model rocket launcher we did this. There was a tall pole near our launcher. I called the company that installed the pole and they told me it 73 feet tall.
Someone, usually my younger brother, would be located much farther away from the launch site. After each launch, his job was to estimate how high (or how many of those poles he thought) the rocket flew before falling back down.
Answer:Simple geometry is needed - after all you are using a rocket and must have some math and science skills. An observer at a distance follows the flight of a rocket along a moveable bar. The angle of the bar at the top of the trajectory and the distance of the observer from the launch pad is converted into altitude by the formula:
cot A =adjacent/opposite
where A id the observed angle fromthe horizontal, the adjacent is the distance to the pad from the observer, and opposite the height of the rocket.
All that's needed is to reorganize the equation and finf the cotangent of the angle:
Opposite = adjacent/cot A
A rocket (firework) achieves maximum height once the fuel plus upward thrust runs out. Then gravity takes over and the rocket falls back to the ground.
The highest point a rocket reaches during its flight is typically the apogee, which is the point of maximum altitude. This is the point where the rocket reaches its peak altitude before descending back to Earth.
The maximum height of a rocket can be calculated using its initial speed and angle of launch. By analyzing its projectile motion, you can determine the peak height using the equations of motion. The maximum height occurs when the vertical velocity component becomes zero before the rocket starts descending.
The maximum height reached by a rocket in a physics problem involving a rocket launch is determined by factors such as the initial velocity of the rocket, the force of gravity, and air resistance. This height is typically calculated using equations of motion and can vary depending on the specific conditions of the launch.
The rocket would attain a maximum height of 158.65 feet (63.65 feet from the top of the structure).
when the vertical component of its velocity is zero.
Air resistance acts against the motion of a rocket by creating drag, which can slow down the rocket's acceleration and decrease its maximum speed. The more streamlined a rocket is, the less air resistance it will face, allowing it to move more efficiently through the atmosphere. Overall, air resistance can impact the performance and efficiency of a rocket during its flight.
about one-forth of the height of the size of the rocket.
A model rocket reaches maximum velocity at the point where the thrust from the engine matches the drag from the air, or the point where the thrust goes to zero when the fuel burns out, whichever comes first.
The fuselage on a rocket is the main body structure that houses the propulsion system, payload, and other necessary components for its flight. It is typically a long, cylindrical structure that provides stability and support during launch and flight.
The Vostok 1 rocket that carried Yuri Gagarin into space on April 12, 1961, reached a maximum speed of approximately 27,400 kilometers per hour (17,000 miles per hour) during its flight.
The tip of a rocket is called the nose cone. It is designed to reduce aerodynamic drag and protect the payload during flight.