No. Regardless of where you throw the ball, its vertical acceleration is
always roughly 9.8 m/s2 downward after it leaves your hand, and its
horizontal acceleration is always roughly zero.
The reason we have to say "roughly" is because of the air resistance
that the ball runs into.
When you apply force at an angle to the direction of movement, the force gets divided into two components: one perpendicular to the direction of movement and the other parallel to the direction of movement. The component parallel to the direction of movement affects the acceleration of the object, while the component perpendicular to the direction of movement does not contribute to the acceleration in that direction.
To find the acceleration of an object in motion when the height and angle are given, you can use trigonometry to resolve the height and angle into their horizontal and vertical components. Once you have these components, you can use the equations of motion to calculate the acceleration in each direction separately. Then, you can combine these accelerations using vector addition to find the total acceleration of the object.
Yes, a body can move horizontally with acceleration in the vertical direction if it is subject to a force that is acting at an angle. This can cause the body to experience motion in both the horizontal and vertical directions simultaneously, resulting in acceleration in the vertical direction while still moving horizontally.
The acceleration in the vertical direction is due to gravity and is approximately 9.8 m/s^2 downward. The vertical acceleration remains constant throughout the ball's flight trajectory.
The equation "a = gsinθ" represents the component of acceleration (a) in the direction of the force due to gravity acting on an object on an inclined plane. Here, 'g' is the acceleration due to gravity and 'θ' is the angle of inclination of the plane. The acceleration in the direction of the incline is calculated as gsinθ.
either 00 or 1800A straight angle is an "angle" that doesn't affect the direction of a line. A 00angle sends the line in the opposite direction.
The contribution of the acceleration of gravity in the direction of motion increases as the angle of the incline increases. Or in other words, as the angle between the direction of motion and the force of gravity goes to zero, the acceleration of the object goes to the gravitational acceleration. a = g cos(theta) Where theta is the angle between the direction of motion and verticle, which is in fact (theta = 90 - angle of the incline)Where a is the acceleration of the object down the incline plane and g is the acceleration due to gravity. Theta is the angle between the direction of motion of the accelerating object and the acceleration of gravity. Initially, the angle between a and g is 90 degrees (no incline) and therefore g contributes nothing to the objects acceleration. a = g cos(90) = 0 As the angle of the inclined is increased, the angle between a and g approaches zero, at which point a = g. With no other forces acting upon the object, g is its maximum acceleration.
The ratio is the M/cos(x). where M is the mass on which the force is acting and x is the angle between the direction of the force and the direction of the acceleration.
When you apply force at an angle to the direction of movement, the force gets divided into two components: one perpendicular to the direction of movement and the other parallel to the direction of movement. The component parallel to the direction of movement affects the acceleration of the object, while the component perpendicular to the direction of movement does not contribute to the acceleration in that direction.
In a polygon, it is the next angle along - in either direction.
To find the acceleration of an object in motion when the height and angle are given, you can use trigonometry to resolve the height and angle into their horizontal and vertical components. Once you have these components, you can use the equations of motion to calculate the acceleration in each direction separately. Then, you can combine these accelerations using vector addition to find the total acceleration of the object.
Yes, a body can move horizontally with acceleration in the vertical direction if it is subject to a force that is acting at an angle. This can cause the body to experience motion in both the horizontal and vertical directions simultaneously, resulting in acceleration in the vertical direction while still moving horizontally.
The acceleration in the vertical direction is due to gravity and is approximately 9.8 m/s^2 downward. The vertical acceleration remains constant throughout the ball's flight trajectory.
The equation "a = gsinθ" represents the component of acceleration (a) in the direction of the force due to gravity acting on an object on an inclined plane. Here, 'g' is the acceleration due to gravity and 'θ' is the angle of inclination of the plane. The acceleration in the direction of the incline is calculated as gsinθ.
Factors that can affect acceleration include the mass of an object (heavier objects accelerate more slowly), the force applied to the object (greater force leads to faster acceleration), and friction or air resistance (which can slow down acceleration). Additionally, the angle of incline or the surface on which the object is moving can also impact acceleration.
To find acceleration with mass and angle, you can use the formula: acceleration (force sin(angle)) / mass. This formula takes into account the force acting on an object at an angle and divides it by the mass of the object to determine its acceleration.
The acceleration of the object would still be g downward, regardless of the angle at which it is thrown upward. The acceleration due to gravity always acts in the downward direction towards the center of the Earth. The only difference would be the horizontal component of the velocity due to the initial angle of the throw.