To determine the vertical velocity of a projectile, you can use the formula: vertical velocity initial vertical velocity (acceleration due to gravity x time). The initial vertical velocity is the speed at which the projectile is launched upwards or downwards. Acceleration due to gravity is typically -9.8 m/s2 (negative because it acts downwards). Time is the duration for which the projectile has been in motion. By plugging in these values, you can calculate the vertical velocity of the projectile.
To determine the maximum height reached by a projectile, you can use the formula: maximum height (initial vertical velocity)2 / (2 acceleration due to gravity). This formula calculates the height based on the initial vertical velocity of the projectile and the acceleration due to gravity.
To determine the launch velocity of a projectile, you can use the projectile motion equations. By measuring the initial height, horizontal distance traveled, and the angle of launch, you can calculate the launch velocity using trigonometry and kinematic equations.
When a projectile's horizontal and vertical velocities are independent, it means that the horizontal velocity does not affect the vertical velocity, and vice versa. This means that the projectile will continue to move horizontally at a constant velocity regardless of its vertical motion, and its vertical motion will be affected only by gravity.
To determine the vertical velocity of an object, you can use the formula: vertical velocity initial vertical velocity (acceleration due to gravity x time). This formula takes into account the object's initial velocity and how gravity affects its motion over time.
That means the if you change one you do not necessarily change the other. In the case of the projectile the vertical component is dependent on time (if it is a projectile near a large mass like the earth) gravity acts on it accelerating the projectile in a downward direction. The horizontal component remains the same during the entire flight (if we disregard air resistance and such things).
To determine the maximum height reached by a projectile, you can use the formula: maximum height (initial vertical velocity)2 / (2 acceleration due to gravity). This formula calculates the height based on the initial vertical velocity of the projectile and the acceleration due to gravity.
One that goes directly up - the velocity having no horizontal component.
To determine the launch velocity of a projectile, you can use the projectile motion equations. By measuring the initial height, horizontal distance traveled, and the angle of launch, you can calculate the launch velocity using trigonometry and kinematic equations.
When a projectile's horizontal and vertical velocities are independent, it means that the horizontal velocity does not affect the vertical velocity, and vice versa. This means that the projectile will continue to move horizontally at a constant velocity regardless of its vertical motion, and its vertical motion will be affected only by gravity.
To determine the vertical velocity of an object, you can use the formula: vertical velocity initial vertical velocity (acceleration due to gravity x time). This formula takes into account the object's initial velocity and how gravity affects its motion over time.
That means the if you change one you do not necessarily change the other. In the case of the projectile the vertical component is dependent on time (if it is a projectile near a large mass like the earth) gravity acts on it accelerating the projectile in a downward direction. The horizontal component remains the same during the entire flight (if we disregard air resistance and such things).
To determine the final vertical velocity of an object, you can use the equation: final velocity initial velocity (acceleration x time). This equation takes into account the initial velocity of the object, the acceleration due to gravity, and the time the object has been falling. By plugging in the values for these variables, you can calculate the final vertical velocity of the object.
A projectile has an initial forward velocity.
The effect that gravity has on the vertical component of the projectile is that as the projectile is going upward it is decreasing 10m/s ever second it is going upward until it reaches its peak. at its peak its vertical component is zero. Then as it is going back to earth it is increasing at 10 m/s every second that is it going downward. for example, a boy throws a ball at 20 m/s upward its velocity after 2 seconds will be zero due to the fact that gravity canceled out the force and then.. what is the velocity after 4 seconds? it is 20 m/s.. gravity added 10 m/s ever second that it was falling to the earth. hope this helps
To determine the vertical acceleration of an object, you can use the formula: acceleration change in velocity / time. Measure the change in velocity of the object moving vertically and divide it by the time it took for the change to occur. This will give you the vertical acceleration of the object.
Common projectile problems in physics include determining the initial velocity, angle of launch, maximum height, range, and time of flight of a projectile. These problems can be solved using equations of motion, such as the kinematic equations, and applying principles of projectile motion, such as the independence of horizontal and vertical motion. By breaking down the problem into horizontal and vertical components, one can analyze the motion of the projectile and calculate the desired quantities.
One challenging YouTube physics problem I encountered involved calculating the trajectory of a projectile launched at an angle with a given initial velocity. To solve it, I used the kinematic equations for projectile motion and applied trigonometry to break down the initial velocity into horizontal and vertical components. By analyzing the forces acting on the projectile and considering factors like air resistance, I was able to accurately predict the projectile's path.