Newton's 2nd Law of Motion: Force = mass * acceleration.
So, for a fixed mass, if acceleration increases, the force causing the acceleration has to be increasing too.
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The force is determined by the machine or the muscle that's applying the force.
The mass of an object has no effect on it. You can easily apply the same force
to a battleship, a brick wall, or a little red wagon.
The response to the force (acceleration) is determined by the mass, and also by
any other forces that may also be acting on it at the same time.
If the angle of a mass is increased, the horizontal acceleration would decrease due to the component of gravitational force acting perpendicular to the direction of motion increasing. This component would counteract some of the horizontal acceleration.
It decreases.
The acceleration of the person on a swing can be increased by increasing the angle of release, as a greater angle results in a longer pendulum length and thus greater acceleration. Additionally, increasing the initial height from which the person is released can also lead to higher acceleration due to the increased potential energy. Finally, reducing air resistance by swinging in a more aerodynamic position can help increase acceleration.
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.
If air resistance is neglected, the motion of an object projected at an angle consists of a uniform downward acceleration due to gravity combined with constant horizontal motion at a constant velocity. The vertical component of the velocity changes uniformly due to gravity, while the horizontal component remains constant throughout the motion.
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.
The steeper the slope (greater angle), the faster the ball will roll downhill due to the increased gravitational force acting on it. This increased force results in a greater acceleration, causing the ball to gain speed more quickly.
.50g
A horizontal angle is an angle between lines on a horizontal plane.
The acceleration of the person on a swing can be increased by increasing the angle of release, as a greater angle results in a longer pendulum length and thus greater acceleration. Additionally, increasing the initial height from which the person is released can also lead to higher acceleration due to the increased potential energy. Finally, reducing air resistance by swinging in a more aerodynamic position can help increase acceleration.
this is horizontal: ---------------------------- / / this is at an angle: / / /
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.
If angled downward while increased, acceleration is increased also, as in if something were sliding down the ramp, it would go faster if angle downward is increased.
If air resistance is neglected, the motion of an object projected at an angle consists of a uniform downward acceleration due to gravity combined with constant horizontal motion at a constant velocity. The vertical component of the velocity changes uniformly due to gravity, while the horizontal component remains constant throughout the motion.
The angle formed by a horizontal line is 180o.
If the angle is increased, the tangential component of the weight will increase, while the normal component - the one that causes friction - will decrease.
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.
horizontal lines are lines which may be at the angle of 00,1800,3600.if vertical lines stand on horizontal lines it is in the angle of 900
The angle of inclination.