WEBVTT 00:00:03.660 --> 00:00:06.180 I would now like to calculate the potential function for two 00:00:06.180 --> 00:00:07.560 other conservative forces that we 00:00:07.560 --> 00:00:10.380 encounter all the time, spring forces 00:00:10.380 --> 00:00:11.880 and gravitational forces. 00:00:11.880 --> 00:00:13.440 Will begin with spring forces. 00:00:13.440 --> 00:00:17.250 So first off, let's begin with some type of coordinate system. 00:00:17.250 --> 00:00:18.990 Suppose we have a spring. 00:00:18.990 --> 00:00:20.400 We have a block. 00:00:20.400 --> 00:00:24.330 This is my point x equilibrium, unstretched 00:00:24.330 --> 00:00:25.800 length of the spring. 00:00:25.800 --> 00:00:28.620 And now whether we stretch it or compress it here, 00:00:28.620 --> 00:00:29.880 I'll stretch it. 00:00:29.880 --> 00:00:32.210 I'll introduce a coordinate function x. 00:00:32.210 --> 00:00:36.720 Union vector i, and my spring force, f, 00:00:36.720 --> 00:00:42.030 is -kxi, where x can be positive for a stretch spring, 00:00:42.030 --> 00:00:44.270 force is in the negative i-hat direction. 00:00:44.270 --> 00:00:47.220 When x is negative, negative times negative, 00:00:47.220 --> 00:00:51.120 means the spring force is in the positive i-hat direction when 00:00:51.120 --> 00:00:52.110 it's compressed. 00:00:52.110 --> 00:00:54.330 So this is a force that's a restoring force, 00:00:54.330 --> 00:00:56.160 always back to equilibrium. 00:00:56.160 --> 00:00:59.340 This is an example of a conservative force. 00:00:59.340 --> 00:01:03.030 And now let's calculate the change in potential energy. 00:01:03.030 --> 00:01:05.730 And then introduce a zero reference point 00:01:05.730 --> 00:01:08.140 and get a potential function for this force. 00:01:08.140 --> 00:01:11.380 So the first calculation is straightforward. 00:01:11.380 --> 00:01:16.260 So, if we took our displacement to be dx i-hat. 00:01:16.260 --> 00:01:19.950 And we take the dot product of fds, 00:01:19.950 --> 00:01:25.440 we get dx i-hat dot i-hat is 1, times dx. 00:01:25.440 --> 00:01:30.360 And that's just the x component of the force displacement. 00:01:30.360 --> 00:01:37.180 And minus sign because the x component of the force is -kx. 00:01:37.180 --> 00:01:40.320 And so now, if we were to start our system, 00:01:40.320 --> 00:01:44.840 so, again, for our initial state, 00:01:44.840 --> 00:01:52.410 let's say that the block from the unstretched position, 00:01:52.410 --> 00:01:55.170 is stretched xi. 00:01:55.170 --> 00:01:58.500 And our final state, whether it's stretched or compressed, 00:01:58.500 --> 00:02:02.970 it won't matter, but we'll just stretch it out a little bit 00:02:02.970 --> 00:02:06.540 more to x-final. 00:02:06.540 --> 00:02:09.780 So now let's calculate the change 00:02:09.780 --> 00:02:13.800 in potential energy between our initial and our final states. 00:02:13.800 --> 00:02:15.840 Now, recall there's a minus sign, 00:02:15.840 --> 00:02:18.780 because it's -w conservative. 00:02:18.780 --> 00:02:28.410 That's minus the integral x-initial to x-final of -kxdx. 00:02:28.410 --> 00:02:31.620 We have 2 minus signs. 00:02:31.620 --> 00:02:33.360 That's our integration variable, if you 00:02:33.360 --> 00:02:35.520 want to see all the detail. 00:02:35.520 --> 00:02:38.910 And when you simply integrate x-prime dx-prime, 00:02:38.910 --> 00:02:41.130 you get x-prime squared over 2. 00:02:41.130 --> 00:02:47.220 And so the change in potential energy between these two states 00:02:47.220 --> 00:02:56.220 is 1/2 kx-final squared, minus 1/2 kx-initial squared. 00:02:56.220 --> 00:03:02.410 And that's physically meaningful if I take my system initially. 00:03:02.410 --> 00:03:05.820 And the system ends up in the final state. 00:03:05.820 --> 00:03:08.580 Then what I'm calculating is minus the work 00:03:08.580 --> 00:03:12.150 done by the spring force on the block 00:03:12.150 --> 00:03:14.700 as it goes from the initial state to the final state. 00:03:14.700 --> 00:03:17.280 I'm not talking about the work that an external agent 00:03:17.280 --> 00:03:19.320 does in stretching or compressing it. 00:03:19.320 --> 00:03:23.430 This is explicitly the work done by the spring 00:03:23.430 --> 00:03:26.670 force on the block as it goes from the initial state 00:03:26.670 --> 00:03:28.440 to the final state. 00:03:28.440 --> 00:03:30.810 I introduced the minus sign in our definition 00:03:30.810 --> 00:03:32.340 of potential energy. 00:03:32.340 --> 00:03:35.730 And so this quantity represents the negative 00:03:35.730 --> 00:03:37.980 of the work done by the spring force 00:03:37.980 --> 00:03:41.550 as a system goes from the initial to the final states. 00:03:41.550 --> 00:03:43.800 Now, you may have already thought about it, 00:03:43.800 --> 00:03:47.370 but the reference point that we're going to use 00:03:47.370 --> 00:03:49.900 is x equals zero. 00:03:49.900 --> 00:03:52.740 The unstretched length of the spring. 00:03:52.740 --> 00:03:57.210 And our reference potential at that point will be zero. 00:03:57.210 --> 00:04:01.350 So our reference point is actually the zero-point 00:04:01.350 --> 00:04:04.200 for the potential. 00:04:04.200 --> 00:04:10.870 And then our arbitrary state, we can call this 00:04:10.870 --> 00:04:13.630 the referent state, if you like. 00:04:13.630 --> 00:04:16.680 That's probably better than the reference point. 00:04:16.680 --> 00:04:21.430 Our arbitrary state will be at some arbitrary 00:04:21.430 --> 00:04:23.710 stretch or compress. 00:04:23.710 --> 00:04:26.440 And our potential energy function, 00:04:26.440 --> 00:04:30.550 at that reference, minus the potential energy 00:04:30.550 --> 00:04:33.200 at the arbitrary state, minus the reference state. 00:04:33.200 --> 00:04:37.990 Well, if we set xi equal to 0 and x-final equal 00:04:37.990 --> 00:04:40.720 to x, as we have in this expression, 00:04:40.720 --> 00:04:44.290 we simply get 1/2 kx squared. 00:04:44.290 --> 00:04:49.300 So the potential energy function equals our reference potential, 00:04:49.300 --> 00:04:51.790 plus 1/2 kx squared. 00:04:51.790 --> 00:04:55.150 And we have defined that our reference potential to be zero, 00:04:55.150 --> 00:04:56.680 it could have been anything. 00:04:56.680 --> 00:05:02.060 But we're making it 0 so that we get a nice function, 1/2 kx 00:05:02.060 --> 00:05:03.430 square. 00:05:03.430 --> 00:05:06.460 And again, it's always worthwhile to plot 00:05:06.460 --> 00:05:08.120 that function. 00:05:08.120 --> 00:05:10.190 It's a nice parabola. 00:05:10.190 --> 00:05:12.370 U of x, x. 00:05:12.370 --> 00:05:16.560 And you can see down here, that's our reference point.