WEBVTT 00:02.730 --> 00:03.400 Hello. 00:03.570 --> 00:13.350 Now that we have completed our simulation, let's go to the digital section and try to plot our results, 00:13.860 --> 00:15.780 so I'll go to reserve. 00:17.810 --> 00:22.460 Right, click on the result and then click on one deployed group. 00:25.000 --> 00:35.170 Inside the one deployed group, I can right click again and then click on Global Globe is mainly used. 00:35.510 --> 00:43.060 Uh, I already discussed in my previous lecture that it is mainly used to plant scalar data as like 00:43.360 --> 00:46.990 the data for our current and voltage in the electrical circuit. 00:48.100 --> 00:57.340 So in the expression I will click on add expression, go to electric current devices. 00:58.400 --> 01:08.850 Capacitor, and then I will double click current through the capacitor and the X unit, our time and 01:08.850 --> 01:17.090 the unit is milliseconds now and just click on the one deployed group and click on Plott. 01:18.230 --> 01:26.540 When I click on Plott, I see there is a beautiful blood showing the variation of current. 01:27.810 --> 01:39.750 Through time now, what is happening here is that we have of all sorts of one for you and suddenly the 01:39.750 --> 01:40.970 circuit is turned on. 01:41.910 --> 01:54.120 So since we have a capacitor and inductor in parallel with time, we have an oscillating current through 01:54.120 --> 01:55.100 the capacitor. 01:55.110 --> 01:58.980 So it will go from left to right and then from right to left and so on. 02:00.540 --> 02:04.100 So this is how the current is plotted. 02:04.380 --> 02:07.230 Now let us plot the voltage. 02:07.530 --> 02:20.790 So what I can do is I can just duplicate this plot group and here I can just sort of current I can select 02:20.800 --> 02:21.750 Voltage V.. 02:23.460 --> 02:30.420 Probably the expression is not correct, so I would better go to an expression, lift the circuit devices, 02:31.080 --> 02:34.050 see one and then voltage across devices. 02:34.440 --> 02:38.250 Okay, so it is Malfi and I'll click on Blood. 02:39.890 --> 02:47.720 Now, even you can see that the voltage across the device is also fluctuating like a Sanker, which 02:47.720 --> 02:53.840 is exponentially decaying and the voltage approaches zero. 02:54.020 --> 02:55.490 Now the simulation is done. 02:55.500 --> 02:57.100 Deal one millisecond. 02:57.500 --> 02:58.750 There's very strong black. 03:00.190 --> 03:03.850 But if it's similar to higher time, it will eventually reach zero. 03:04.390 --> 03:12.220 Now it is clear from the circuit itself that for any D.C. current, when an inductor is connected, 03:12.550 --> 03:17.370 definitely the current will pass through the inductor for larger time. 03:17.380 --> 03:21.760 Right, because the capacitor will block since it is a DC source. 03:22.660 --> 03:30.500 So this is how you plot the data so you can always plot through different components. 03:30.790 --> 03:37.690 For example, let's say you want to plot through R one the current through R one. 03:37.690 --> 03:38.670 You can do that. 03:39.880 --> 03:45.670 It will also oscillate because it is in CDs with the whole circuit. 03:46.900 --> 03:47.680 So that's it. 03:48.010 --> 03:56.350 In our next lecture, we will learn how we can verify the resonant frequency from the computer simulation 03:56.350 --> 03:57.030 results. 03:57.040 --> 03:59.530 So till then, goodbye and take care. 03:59.560 --> 04:02.080 We'll be back in our next lecture.