Force*Time graph with respect to momentum

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The discussion focuses on calculating the final velocity of a 3.0 kg object over an 8.0-second time period using a Force-Time graph. The initial calculation yielded a final velocity of 267 m/s, which was questioned due to its high value. Participants clarified that the area under the Force-Time graph represents impulse, which equals the change in momentum. By calculating the area as a trapezoid, the correct impulse was determined to be 600 N*s, leading to a final velocity of 200 m/s when assuming the initial velocity is zero. This method emphasizes the importance of accurately interpreting the graph to derive the correct velocity.
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If the mass of the object is 3.0 kg, what is its final velocity over the 8.0 s time period?

This is the work I've done so far.

F∆t = m∆v
100 * 8.0 = 3.0 * v
v = 266.67

Now 267m/s seems quite high to me. So I think the problem I am having is that I'm reading the graph incorrectly and extrapolating the incorrect force from it. So basically, can anyone tell me if I have the correct amount of force listed down?
 
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One approach would be to re-scale the force axis by dividing by the mass of the object and effectively turning it into an acceleration-time graph. The change in speed is then given by the area under the graph.
 
The area under a Force-Time graph is Impulse (equivalent to change in momentum). You can find the area under the curve and that will equal your momentum change. This should allow you to calculate your velocity change.
 
DonnieB, Fizznerd is right, you need the area under the curve, and you do not need calculus, as that is a trapezoid. THe area of a trapezoid is the average of the bases times the height, which is (4 + 8)seconds/2*100 N = 600 N*s. Set this to mv - mv0, and assuming v0 is zero get v final = 200 m/s.
 
Thread 'Variable mass system : water sprayed into a moving container'

Thread 'Variable mass system : water sprayed into a moving container'

Starting with the mass considerations #m(t)# is mass of water #M_{c}# mass of container and #M(t)# mass of total system $$M(t) = M_{C} + m(t)$$ $$\Rightarrow \frac{dM(t)}{dt} = \frac{dm(t)}{dt}$$ $$P_i = Mv + u \, dm$$ $$P_f = (M + dm)(v + dv)$$ $$\Delta P = M \, dv + (v - u) \, dm$$ $$F = \frac{dP}{dt} = M \frac{dv}{dt} + (v - u) \frac{dm}{dt}$$ $$F = u \frac{dm}{dt} = \rho A u^2$$ from conservation of momentum , the cannon recoils with the same force which it applies. $$\quad \frac{dm}{dt}...
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