The momentum-time graph is the integral of the force-time graph. that is, it is the area under the curve of the f-t graph.
The momentum-time graph is the integral of the force-time graph. that is, it is the area under the curve of the f-t graph.
The momentum-time graph is the integral of the force-time graph. that is, it is the area under the curve of the f-t graph.
The momentum-time graph is the integral of the force-time graph. that is, it is the area under the curve of the f-t graph.
Sure, as long as the object is moving at a constant speed.And by the way ... It's easy to draw a speed/time graph, butI'm pretty sure it's not possible to draw a velocity/time one.
you can't....it's merely impossible! Assuming it is a graph of velocity vs time, it's not impossible, it's simple. Average velocity is total distance divided by total time. The total time is the difference between finish and start times, and the distance is the area under the graph between the graph and the time axis.
this time is basically the instant when an object has a particular velocity(instantaneous velocity). so on the graph draw a line from the particular value of the velocity and then draw a vertical line on time axis to find the time for that velocity.
Because impulse is the integral of the force over the time during which it was applied. Graphically, this is the area under the curve of force against time.Force is rate of change of momentum. Even if you hit a brick wall you impart momentum to some of the atoms in it. The area under a graph of force against time is mathematically speaking the integral of the force with respect to time, as stated above. So it is the integral of the rate of change of momentum. But the integral of a rate of change of anything, is simply the total change. In this case, the total change of momentum. For a large force applied for a very small time, that is called (defined to be) an impulse, and it results in a change of momentum. Strictly it doesn't have to be a small time for this to be true, but impulses are generally imagined as being short time events.
To create an acceleration-time graph from a velocity-time graph, you need to find the slope of the velocity-time graph at each point. The slope represents the acceleration at that specific instant. Plot these acceleration values against time to get the acceleration-time graph.
Force
The impulse on a force-time graph is equal to the change in momentum of an object.
The slope of a force vs. time graph is equal to the change in momentum or the Impulse.
A Force-time graph shows the variation of force with respect to time. More usefully the area under such a graph gives the quantity Ft or impulse, which is equal to the change in momentum of an object. Ft = Mv-Mu
Sure, as long as the object is moving at a constant speed.And by the way ... It's easy to draw a speed/time graph, butI'm pretty sure it's not possible to draw a velocity/time one.
To determine the impulse from a force-time graph, you can find the area under the curve of the graph. Impulse is equal to the change in momentum, which is calculated by multiplying the force applied by the time over which it is applied. The area under the force-time graph represents the impulse exerted on an object.
The slope of the speed/time graph is the magnitude of acceleration. (It's very difficult to draw a graph of velocity, unless the direction is constant.)
simply draw separate graph from the graph from which you have to find the subgraphs, remove exact one edge ont time and proceed to the till end.
Based on the graph, it can be concluded that the popularity of the keyword has been steadily increasing over time.
you can't....it's merely impossible! Assuming it is a graph of velocity vs time, it's not impossible, it's simple. Average velocity is total distance divided by total time. The total time is the difference between finish and start times, and the distance is the area under the graph between the graph and the time axis.
this time is basically the instant when an object has a particular velocity(instantaneous velocity). so on the graph draw a line from the particular value of the velocity and then draw a vertical line on time axis to find the time for that velocity.
Momentum