The stone moves in a straight line when released due to inertia. It continues in the direction it was moving at the instant of release because no additional forces act on it, demonstrating that an object in motion stays in motion in a straight line.
The stone moves in a straight line when released due to inertia. It continues in the direction it was moving at the instant of release because no additional forces act on it, demonstrating that an object in motion stays in motion in a straight line.
An athlete running along a hexagonal track changes direction six times. At each vertex of the hexagon, the athlete must make a turn to continue along the path, resulting in a total of six direction changes for one complete lap around the track.
An athlete running along a hexagonal track changes direction six times. At each vertex of the hexagon, the athlete must make a turn to continue along the path, resulting in a total of six direction changes for one complete lap around the track.
The stone’s tangential motion upon release indicates that its direction of motion was continuously changing while in circular motion. At each point on the circular path, the stone's velocity was directed tangentially, showing a constant change in direction throughout the motion.
The stone’s tangential motion upon release indicates that its direction of motion was continuously changing while in circular motion. At each point on the circular path, the stone’s velocity was directed tangentially, showing a constant change in direction throughout the motion.
As the number of sides of the track increases indefinitely, the shape of the track approaches that of a circle. Each additional side makes the track more closely resemble a smooth, continuous curve, eventually forming a circular path with an infinite number of sides.
As the number of sides of the track increases indefinitely, the shape of the track approaches that of a circle. Each additional side makes the track more closely resemble a smooth, continuous curve, eventually forming a circular path with an infinite number of sides.
As the number of sides of the track increases, the length of each side decreases. Each additional side becomes shorter, making the track resemble a smooth, continuous curve more closely, ultimately approaching the form of a circle with an infinite number of infinitesimally small sides.
As the number of sides of the track increases, the length of each side decreases. Each additional side becomes shorter, making the track resemble a smooth, continuous curve more closely, ultimately approaching the form of a circle with an infinite number of infinitesimally small sides.
When the stone is released from its circular path, it moves in a straight line tangential to the circle at the point of release. This motion is due to inertia, which causes the stone to continue in the direction it was moving at that instant.
When the stone is released from its circular path, it moves in a straight line tangential to the circle at the point of release. This motion is due to inertia, which causes the stone to continue in the direction it was moving at that instant.
Uniform circular motion is the movement of an object at a constant speed along a circular path. Despite the constant speed, the object’s direction continuously changes, resulting in a constantly changing velocity due to the consistent centripetal acceleration directed towards the center of the circlRead more
Uniform circular motion is the movement of an object at a constant speed along a circular path. Despite the constant speed, the object’s direction continuously changes, resulting in a constantly changing velocity due to the consistent centripetal acceleration directed towards the center of the circle.
The motion of the athlete along a circular path is considered an example of accelerated motion because the athlete's direction of motion constantly changes, even if the speed remains constant. This change in direction results in a continuous change in velocity, which is acceleration. In circular motRead more
The motion of the athlete along a circular path is considered an example of accelerated motion because the athlete’s direction of motion constantly changes, even if the speed remains constant. This change in direction results in a continuous change in velocity, which is acceleration. In circular motion, this acceleration is called centripetal acceleration, always directed toward the center of the circle.
Why does the stone move in a straight line when released?
The stone moves in a straight line when released due to inertia. It continues in the direction it was moving at the instant of release because no additional forces act on it, demonstrating that an object in motion stays in motion in a straight line.
The stone moves in a straight line when released due to inertia. It continues in the direction it was moving at the instant of release because no additional forces act on it, demonstrating that an object in motion stays in motion in a straight line.
See lessHow many times does the athlete change direction while running along a hexagonal track?
An athlete running along a hexagonal track changes direction six times. At each vertex of the hexagon, the athlete must make a turn to continue along the path, resulting in a total of six direction changes for one complete lap around the track.
An athlete running along a hexagonal track changes direction six times. At each vertex of the hexagon, the athlete must make a turn to continue along the path, resulting in a total of six direction changes for one complete lap around the track.
See lessWhat does the stone’s tangential motion upon release indicate about its direction of motion while in circular motion?
The stone’s tangential motion upon release indicates that its direction of motion was continuously changing while in circular motion. At each point on the circular path, the stone's velocity was directed tangentially, showing a constant change in direction throughout the motion.
The stone’s tangential motion upon release indicates that its direction of motion was continuously changing while in circular motion. At each point on the circular path, the stone’s velocity was directed tangentially, showing a constant change in direction throughout the motion.
See lessWhat shape does the track approach as the number of sides increases indefinitely?
As the number of sides of the track increases indefinitely, the shape of the track approaches that of a circle. Each additional side makes the track more closely resemble a smooth, continuous curve, eventually forming a circular path with an infinite number of sides.
As the number of sides of the track increases indefinitely, the shape of the track approaches that of a circle. Each additional side makes the track more closely resemble a smooth, continuous curve, eventually forming a circular path with an infinite number of sides.
See lessWhat happens to the length of each side of the track as the number of sides increases?
As the number of sides of the track increases, the length of each side decreases. Each additional side becomes shorter, making the track resemble a smooth, continuous curve more closely, ultimately approaching the form of a circle with an infinite number of infinitesimally small sides.
As the number of sides of the track increases, the length of each side decreases. Each additional side becomes shorter, making the track resemble a smooth, continuous curve more closely, ultimately approaching the form of a circle with an infinite number of infinitesimally small sides.
See lessWhat happens to the stone when it is released from its circular path?
When the stone is released from its circular path, it moves in a straight line tangential to the circle at the point of release. This motion is due to inertia, which causes the stone to continue in the direction it was moving at that instant.
When the stone is released from its circular path, it moves in a straight line tangential to the circle at the point of release. This motion is due to inertia, which causes the stone to continue in the direction it was moving at that instant.
See lessWhat is the definition of uniform circular motion?
Uniform circular motion is the movement of an object at a constant speed along a circular path. Despite the constant speed, the object’s direction continuously changes, resulting in a constantly changing velocity due to the consistent centripetal acceleration directed towards the center of the circlRead more
Uniform circular motion is the movement of an object at a constant speed along a circular path. Despite the constant speed, the object’s direction continuously changes, resulting in a constantly changing velocity due to the consistent centripetal acceleration directed towards the center of the circle.
See lessWhy is the motion of the athlete along a circular path considered an example of accelerated motion?
The motion of the athlete along a circular path is considered an example of accelerated motion because the athlete's direction of motion constantly changes, even if the speed remains constant. This change in direction results in a continuous change in velocity, which is acceleration. In circular motRead more
The motion of the athlete along a circular path is considered an example of accelerated motion because the athlete’s direction of motion constantly changes, even if the speed remains constant. This change in direction results in a continuous change in velocity, which is acceleration. In circular motion, this acceleration is called centripetal acceleration, always directed toward the center of the circle.
See less