Recent content by haruspex

  1. haruspex

    Physics Problem on Tension in Water

    Yes, except that, as I wrote, the force is not constant. What you have calculated is the average. Is that what you are asked for?
  2. haruspex

    Physics Problem on Tension in Water

    Ok, so can you do what I suggested in post #8? Do I need to explain more?
  3. haruspex

    Physics Problem on Tension in Water

    I agree that is confusing, but since the question asks for a tension there was, presumably, some mention of a rope in the original text. Thus, F might be illustrating the force on the rope, not on the cylinder.
  4. haruspex

    Physics Problem on Tension in Water

    Yes, I think we all read it that way. @jbriggs444's point is that we have no info re the surface area of the reservoir, other than that the level is not shown as having risen. Maybe it's not circular - infinite into the page perhaps 😉.
  5. haruspex

    Physics Problem on Tension in Water

    You just have to draw the before and after pictures. You can consider the water as having gone from the volume that is occupied in the before picture but not in the after picture to the volume occupied in the after picture but not in the before picture.
  6. haruspex

    Physics Problem on Tension in Water

    Yes, but I am giving you another way to figure this out that's clearer. I asked how much water disappears from the top if the cylinder only descends a small distance ##\Delta y##, not the whole 0.5m. There is a reason for that, as you will see. Looking at where extra water appears at the...
  7. haruspex

    Physics Problem on Tension in Water

    Yes, but sketch where that water has come from. And where it has gone to. What is the change in PE? Btw, the force will not be constant.
  8. haruspex

    Physics Problem on Tension in Water

    You might find it clearest to think in terms of energy. If the cylinder descends a distance ##\Delta y##, what is the change in PE? Draw the region where the water goes from and where it goes to.
  9. haruspex

    Collision of a bullet on a rod-string system: query

    ok, thanks for checking it all out.
  10. haruspex

    Collision of a bullet on a rod-string system: query

    The answer looks rather different. Strange that theta does not appear in the final equation for T. This is troubling: "1. Angular momentum is conserved only about P." but later: "We now calculate the acceleration of P on the rod in the direction of the string" So is P accelerating or fixed...
  11. haruspex

    Toboggan on circular arcs

    I see no benefit in introducing V. You are to find a range of values for U First, identify the points of the trajectory which will determine the minimum and maximum speeds and what the constraints are on the speeds at those points. Then use energy conservation to relate those to U. As...
  12. haruspex

    Toboggan on circular arcs

    Correctly, the analysis considers the highest risk of losing contact is at A and B. F=ma is being applied along the normal, so at 45° to the vertical.
  13. haruspex

    Motion in 2 dimensions

    Yes, as I wrote in post #21, you can (only) elect to switch the sign of the tangential acceleration arbitrarily, but if you choose not to you must arrive at ##\dot{\omega}=0##. As in, the given differential equation accurately represents the dynamics, so applying it in a simulation should...
  14. haruspex

    Motion in 2 dimensions

    Ok, so it is the difference between a solution that satisfies a differential equation and one that corresponds to a physical process which the differential equation represents. If ##\dot x=f(x)## is cause and effect then once ##x## satisfies ##f(x)=0## then it is stuck there. This never struck...
  15. haruspex

    Motion in 2 dimensions

    It's not based on a solution, merely the fact that an explicit equation like ##\dot\omega=\sqrt{b^2-\omega^4}## (positive square root implied), together with the initial condition ##\omega=0##, should guarantee unique development. Moreover, 1) ##\omega## must be non-decreasing and bounded above...
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