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Kirchhoff’s laws & EMF

Kirchhoff’s laws & EMF. Problem Solving. Introduction. Kirchhoff's laws are a natural consequence of the principles of conservation of charge and conservation of energy. They are fundamental to our understanding of electrical circuits, and really helpful in solving circuit problems.

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Kirchhoff’s laws & EMF

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  1. Kirchhoff’s laws & EMF Problem Solving

  2. Introduction Kirchhoff's laws are a natural consequence of the principles of conservation of charge and conservation of energy. They are fundamental to our understanding of electrical circuits, and really helpful in solving circuit problems.

  3. Kirchhoff’s 1st Law • The sum of the currents flowing into any point in a circuit is equal to the sum of the currents flowing out of that point. • Also known as the junction rule

  4. Kirchhoff’s 2nd Law – The loop rule • The sum of the electromotive forces (EMFs) around any loop in a circuit is equal to the sum of the PDs around the loop. This is conservation of energy. If you think about voltage (EMF and PD) as energy per unit charge, then whatever energy is given to charge must be taken away. The EMF is giving charge energy and the PD is taking it away. The only difficulty you might find with this law is choosing suitable loops to make a circuit problem easier to understand.

  5. The branch current method To analyze a circuit using the branch-current method involves three steps: • Label the current and the current direction in each branch. Sometimes it's hard to tell which is the correct direction for the current in a particular loop. That does NOT matter. Simply pick a direction. If you guess wrong, you’ll get a negative value. The value is correct, and the negative sign means that the current direction is opposite to the way you guessed. You should use the negative sign in your calculations, however. • Use Kirchoff's first rule to write down current equations for each junction that gives you a different equation. For a circuit with two inner loops and two junctions, one current equation is enough because both junctions give you the same equation. • Use Kirchoff's second rule to write down loop equations for as many loops as it takes to include each branch at least once. To write down a loop equation, you choose a starting point, and then walk around the loop in one direction until you get back to the starting point. As you cross batteries and resistors, write down each voltage change. Add these voltage gains and losses up and set them equal to zero.

  6. The branch current method • When you cross a battery from the - side to the + side, that's a positive change. Going the other way gives you a drop in potential, so that's a negative change. • When you cross a resistor in the same direction as the current, that's also a drop in potential so it's a negative change in potential. Crossing a resistor in the opposite direction as the current gives you a positive change in potential.

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