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Kirchhoff’s voltage law. The sum of all voltage drops around a single closed path in a circuit is equal to the total source voltage in that closed path. KVL applies to all circuits, but you must apply it to only one closed path. In a series circuit, this is (of course) the entire circuit.
In a series circuit, the resistors are connected end-to-end such that the current is the same through each resistor: The current has only one path available. The voltage drop across each resistor depends on the resistor value. For a series circuit, the total equivalent resistance, Req is: N. Req = R1 + R2 + R3 + · · · + RN = X Ri (16.1) i=1.
The objective of this lab is to study circuits with re-sistors connected in series, parallel, and combination. Theory. In the previous experiment, you constructed 4 circuits, each circuit built with one resistive element. In this experiment, you will construct circuits using multiple resistors.
The first type of circuit you will construct is called a series circuit. In a series circuit the resistors (or some other resistive component) are connected so that the current is the same through each resistor. See Figure 19-1. For a series circuit the total equivalent resistance Req in a circuit is given by: R eq=R 1+R 2+R 3+...+R N= R i
Objective: The objectives of this experiment are: to understand and use Ohm’s Law. to learn, understand, and use resistors connected in series and parallel. to learn the basic concepts and relationships of current and voltage measurements in DC circuits containing resistors wired in series and parallel.
Experiment No.3 R-L Series Circuit. 1. Introduction. A resistor-Inductor circuit (also known as an RL filter) is defined as an electrical circuit consisting of the passive circuit elements of a resistor (R) and an inductor (L) connected, in series, driven by a voltage source or current source. 2.
The experiment aims to study the electrical characteristics of an RLC circuit in series. Also, to study the relation between the input frequency f and the circuit impedance Z.