voltage in parallel – RENAISSANCE PHYSICS

INTRODUCTION TO ELECTRONICS: Thevenin’s Theorem and Equivalent Circuits

In the diagram below, a circuit is placed within a box. Next, the circuit is opened on the opposite end of the voltage source inside so that two output terminals are visible. The current ( I ) and potential difference ( V ) in relation to the newly created output terminals is then measured: TheContinue reading “INTRODUCTION TO ELECTRONICS: Thevenin’s Theorem and Equivalent Circuits“

INTRODUCTION TO ELECTRONICS: The Unbalanced Wheatstone Bridge and Sensor Technology

A transducer is an electronic device that measures physical parameters such as mechanical strain, pressure, optical density, and/or temperature. If temperature is being measured, an instrument called a thermistor acts as a variable resistor at the R1 location of a Wheatstone bridge. At a known neutral temperature, a zero reference voltage ( Vout ) valueContinue reading “INTRODUCTION TO ELECTRONICS: The Unbalanced Wheatstone Bridge and Sensor Technology“

INTRODUCTION TO ELECTRONICS: The Balanced Wheatstone Bridge

The voltage ( V ) drops across parallel-circuit resistors ( R ) are equal in magnitude; conversely, the currents ( I ) traveling through parallel branches may or may not be the same. For this reason, parallel circuits are sometimes referred to as being current dividers. Take the following diagram into consideration: Since the R1Continue reading “INTRODUCTION TO ELECTRONICS: The Balanced Wheatstone Bridge“

INTRODUCTION TO ELECTRONICS: Bleeder Current in Multi-Tap Voltage-Divider Circuits

Adding a tap to a series circuit alters the untapped voltage ( V ) output across the resistor ( R ) downstream of it. We will now expand our studies to be inclusive of multi-tap voltage-divider circuits. The objective is to determine the magnitude of the bleeder current ( I3 ) flowing through the lowermostContinue reading “INTRODUCTION TO ELECTRONICS: Bleeder Current in Multi-Tap Voltage-Divider Circuits“

INTRODUCTION TO ELECTRONICS: Voltage Dividers With Resistive Loads ( Part 2 )

In a previous exercise, we saw how the addition of a stiff voltage divider to a two-resistor series circuit lowers the voltage ( V ) drop across the lattermost resistor. We are now ready to examine this phenomena with a circuit that contains unequal resistor values: Q: a. What is the unloaded output voltage? b.Continue reading “INTRODUCTION TO ELECTRONICS: Voltage Dividers With Resistive Loads ( Part 2 )“

INTRODUCTION TO ELECTRONICS: Voltage Dividers With Resistive Loads ( Part 1 )

A series circuit that contains two equal-value resistors ( R ) will split the amount of work ( J ) done by the charges equally: Prior to arrival at R1, a coulomb of charged particles ( I ) will contain 10.0 J of energy available to perform work. After passing through R1, the charges willContinue reading “INTRODUCTION TO ELECTRONICS: Voltage Dividers With Resistive Loads ( Part 1 )“

INTRODUCTION TO ELECTRONICS: Series-Parallel Circuit Branch Identification

Due to the complexity of some series-parallel circuits, it takes time to appropriately identify circuit branches that negate the larger circuit being classified as purely series or parallel. There is no substitute for practice! Prior to using the appropriate mathematics and equations to solve series-parallel circuit problems, visual engagement with a wide variety of circuitContinue reading “INTRODUCTION TO ELECTRONICS: Series-Parallel Circuit Branch Identification“

INTRODUCTION TO ELECTRONICS: Power in Parallel Circuits

Power is the rate at which energy is deposited within ( or liberated from ) some medium. As pertains to electronics, the watt is a measure of how many joules ( J ) of energy are deposited per second within the resistive elements of a circuit. The SI unit of power is the watt (Continue reading “INTRODUCTION TO ELECTRONICS: Power in Parallel Circuits“

INTRODUCTION TO ELECTRONICS: Parallel Circuits

In the study of parallel resistor ( Rx ) circuits, where “ x “ is the number of a particular resistor ( x = 1, 2, 3, … n ), a common point of confusion regards how the total resistance ( Rt ) of the circuit is always less than the lowest calculated resistor value.Continue reading “INTRODUCTION TO ELECTRONICS: Parallel Circuits“

INTRODUCTION TO ELECTRONICS: The Current-Divider Formula

As we have seen, the voltage ( V ) drops that occur across resistors ( R ) in parallel circuits are equal in magnitude to the voltage of the source. In addition to this, the currents ( I ) within parallel circuits split apart ( and later recombine ) at nodes. The magnitude of theContinue reading “INTRODUCTION TO ELECTRONICS: The Current-Divider Formula“