--- author: Akbar Rahman date: \today title: MMME2051 // Electrical Engineering Fundamentals tags: [ mmme2051 ] uuid: 412c8cb8-ec0c-4d6f-b899-f1296f4fc639 --- # Across Variable vs Through Variable Across variables: - Appears across two terminal of an element - Measured relative to a reference point - e.g. voltage Through variables: - Value is same at both terminals of an element - e.g. current # Ohm's Law For all components that follow Ohm's law: $$V = IR$$ where $V$ is voltage across a component, $I$ is current through it, and $R$ is resistance of the component. # Impedance vs Resistance - Impedance is used when there are energy storage elements to a component. - Resistance, a special case of impedance, can be used when there is no storage element ## Admittance $$Y \frac1Z$$ # Kirchhoff's Laws ## Current The sum of current entering a node is 0 $$\sum_n I_n = 0$$ ## Voltage The sum of voltage around a closed loop is 0 $$\sum_n V_n = 0$$ # Energy Storing Elements --- Reactive Elements When you apply a voltage to a reactive element, the reactive element will start storing energy. When the voltage is removed, it will push current until all energy is dissipated. There are two types of Reactive Elements ## Inductors A coil of wire wound around a magnetic core, such as iron. They have a property, inductance, with SI unit henry and symbol H. For an inductor: $$V = L\frac{\mathrm{d}I}{\mathrm{d}t}$$ where $L$ is the inductance of the coil. Energy is stored in the magnetic flux around the coil. This creates the behaviour of trying to minimize change in current. If you remove the voltage source and open the circuit, the inductor would have a voltage approaching infinity, causing problems if the energy stored in the inductor is high enough. ## Capacitor For a capacitor: $$I = C\frac{\mathrm{d}V}{\mathrm{d}t}$$ Energy is stored in the form of electrostatic attraction in the adjacent plates. Capacitors try to minimize changes in voltage. If a capacitor is shorted, the current through the connecting wires will be extremely high, causing the wires to heat up. # Root Mean Square (RMS) $$x_{\text{RMS}} = \sqrt{\frac{x_1^2 + \dots + x_n^2}{n}}$$ For a sinusoidal wave: $$x_\text{RMS} = \frac{A}{\sqrt2}$$