Accelerated motion is represented by a curved line on a distance-time graph. This curvature indicates that the distance covered changes at a varying rate over time, reflecting the object's acceleration. If the object is accelerating uniformly, the curve will be a parabola. In contrast, a straight line indicates constant velocity, where the distance changes at a steady rate.
A bobsled's distance-time graph indicates that it traveled 100 m in 25 s. What is the bobsled's speed
A bobsled's distance-time graph indicates that it traveled 100 m in 25 s. What is the bobsled's speed
In a nonlinear distance-time graph, accelerated motion is depicted by a curved line that indicates a change in the speed of the moving object over time. As the object accelerates, the slope of the curve increases, reflecting a rise in distance covered per unit of time. This contrasts with uniform motion, which is shown by a straight, diagonal line. Thus, the curvature of the line effectively conveys the varying velocity associated with acceleration.
the body is in accelerated motion.
instantaneous acceleration* * * * *No it does not.The graph is a distance-time graph so the coordinates of a point on the graph represent the position (distance) at the specified time. The gradient of the tangent to the curve at that point represents the instantaneous radial velocity. The second derivative at that point, if it exists, would represent the acceleration.
A bobsled's distance-time graph indicates that it traveled 100 m in 25 s. What is the bobsled's speed
A bobsled's distance-time graph indicates that it traveled 100 m in 25 s. What is the bobsled's speed
A bobsled's distance-time graph indicates that it traveled 100 m in 25 s. What is the bobsled's speed
A bobsled's distance-time graph indicates that it traveled 100 m in 25 s. What is the bobsled's speed
A bobsled's distance-time graph indicates that it traveled 100 m in 25 s. What is the bobsled's speed
the body is in accelerated motion.
instantaneous acceleration* * * * *No it does not.The graph is a distance-time graph so the coordinates of a point on the graph represent the position (distance) at the specified time. The gradient of the tangent to the curve at that point represents the instantaneous radial velocity. The second derivative at that point, if it exists, would represent the acceleration.
The displacement-time graph for uniformly accelerated motion is a curve that is concave upwards. It starts with a less steep slope and gradually becomes steeper as time progresses due to the acceleration being constant.
uniformly accelerated motion
distance = velocity x time so on the graph velocity is slope. If slope is zero (horizontal line) there is no motion
A distance time graph would show the distance traveled.
The slope of a position/time graph is the speed (magnitude of velocity).If the graph's slope is changing, that means the speed is changing, andthat would be accelerated motion.