To give you just a little more review on that. These are the equations that we have you learn to used so far in this class. We know how to use Kirchhoff's Laws. They are two of them, they can use separately or together. In each of this cases, the arrows on the left are telling us the input information, and the arrows on the right are telling us the output information. The boxes in between are equations that I'm assuming that you already know from the class. For example, in Kirchhoff's Voltage Law, we know the summation of voltage differences, that's what the delta means. Voltage difference around a loop is equal to 0. Kirchhoff's Current Law, we know that the sum of incoming currents is equal to the sum of the outgoing currents, and these are the branch currents. So, if we knew for example our voltage source, our current, and our resistance, we could calculate voltage differences around the loops. If we knew the incoming and the outgoing, incoming current, we could find the outgoing current. If we knew the outgoing current, we could find the ingoing current. If we combine these, if we do a series of loops plus at least one node, we can take in our sources, our current or voltage sources, and our resistance, we can find the branch currents. Resistors in Series and Parallel are simply used to combine many resistors into a simpler one. Voltage Dividers are used to start with our source voltage and resistance, and find voltage difference. Current Dividers are used to start with our current source, our resistance which we convert R to G, remember that G is equal to one over R. And that gives us the output branch current, but Ohm's Law equation, we use current. So suppose, for example, that we know a voltage difference and a current, we can get resistance. If we know a voltage difference and resistance, we can get current. If we know current and resistance, we can get voltage difference. Tell this thing to go away. Okay, the Power equation, if we know voltage difference and current, we can get Power. If we know voltage difference and resistance, we can get Power, and current, and resistance, we can also get power. This equation is telling us about node voltages. This is the only card that we have that talks about node voltages, so this is the only way we can find them. If we know one node voltage and voltage difference, we can find all the other nodes. If we know two node voltages, we can find the voltage difference, or if we know one node voltage, and I and R, we can find all the other nodes. So, let's just see a little bit about a couple of these cards. I would particularly like to talk about how to use this card right here if we have voltage differences. What you do is you line up this current with the current in your circuit, and then you can see the two nodes on either side, and you use this equation right here. Voltage difference or the Va- Vb. So this is our electrical engineering toolbox, we have Kirchhoff's Laws. We have No Voltage equations, we have Ohm's law which tells us about different voltages, the power which uses voltage and current to get power. This method of combining resistors and series in parallel to simplify them, voltage dividers that use the volt source voltage and resistance to get voltage difference. Current divider that uses the source difference and conductance in work to get current through each branch. We can combine these by looking at what comes in on the left and what goes out on the right. What I do usually, is I take all of the things I know, and I put them on the left, and I put the things that I want on the right. And then I make myself a track, so that I can follow through from left to right, until I'm able to solve the problem. For example, the problem that we just did, we had Kirchhoff's, that it gave us current. We then used our current and our resistance to find our voltage difference, and we used our voltage difference and one node to be able to find all of the other node voltages. Other things we might have done, is we might have first combined resistors in series and parallel, in order to make this simpler over here. So we could have used this one first, and sometimes we might use voltage dividers in place of Kirchhoff's laws, or current dividers in place of Kirchhoff's laws. So we can use these particular sets of equations to be able to solve for the voltages and currents in our circuit. In the next section of the class, what we're going to do is add a few more tools. Particularly, we're going to add node voltage equations that often replace our Kirchhoff's Laws.