Series And Parallel Circuits

Information about Series And Parallel Circuits

Electrical circuit components can be connected together in one of two ways: series or parallel. These two names describe the method of attaching the components, that is one after the other or next to each other. If two or more circuit components are connected end to end like a daisy chain, it is said they are connected in series. A series circuit is a single path for current through all of its components. If two or more circuit components are connected like the rungs of a ladder it is said they are connected in parallel. A parallel circuit is a different path for current through each of its components. A parallel circuit provides the same voltage across all its components.

As an example, consider a very simple circuit consisting of two lightbulbs and one 9 V battery. If a wire joins the battery to one bulb, to the next bulb, then back to the battery, in one continuous loop, the bulbs are said to be in series. If each bulb is wired to the battery in a separate loop, the bulbs are said to be in parallel. If the two lightbulbs are connected in series the same current flows in both of them; each lightbulb experiences about 4.5 V. If the two lightbulbs are connected in parallel the currents flowing in the two lightbulbs combine to form the current flowing in the battery; each lightbulb experiences 9 V.

Series circuits

Series circuits are sometimes called cascade-coupled or daisy chain-coupled. The current that flows in a series circuit has to flow through every component in the circuit. Therefore, all components in a series connection carry the same current.

Resistors

To find the total resistance of all the components, add the individual resistances of each component:

for components in series with resistances $\text{[math]}$ , $\text{[math]}$ , etc. To find the current $\text{[math]}$ , use Ohm's law:

To find the voltage across a component with resistance $\text{[math]}$ , use Ohm's law again:

where $\text{[math]}$ is the current, as calculated above. The components divide the voltage according to their resistances, so, in the case of two resistors,

NOTE: The above formulae extend to impedances in series.

Inductors

Inductors follow the same law, in that the total inductance of non-coupled inductors in series is equal to the sum of their individual inductances:

A diagram of several inductors, connected end to end, with the same amount of current going through each.

However, in some situations it is difficult to prevent adjacent inductors from influencing each other, as the magnetic field of one device couples with the windings of its neighbours. This influence is defined by the mutual inductance M. For example, if you have two inductors in series, there are two possible equivalent inductances:

depending on how the magnetic fields of both inductors influence each other.

When there are more than two inductors, the mutual inductance between each of them and the way the coils influence each other complicates the calculation. For a larger number of coils the total combined inductance is given by the sum of all mutual inductances between the various coils including the mutual inductance of each given coil with itself, which we term self-inductance or simply inductance. For three coils, there are six mutual inductances , , $\text{[math]}$ and $\text{[math]}$ , $\text{[math]}$ and . There are also the three self-inductances of the three coils: $\text{[math]}$ , and .

Therefore

By reciprocity $\text{[math]}$ = so that the last two groups can be combined. The first three terms represent the sum of the self-inductances of the various coils. The formula is easily extended to any number of series coils with mututal coupling. The method can be used to find the self-inductance of large coils of wire of any cross-sectional shape by computing the sum of the mutual inductance of each turn of wire in the coil with every other turn since in such a coil all turns are in series.

Capacitors

Capacitors follow a different law. The total capacitance of capacitors in series is equal to the reciprocal of the sum of the reciprocals of their individual capacitances:

The working voltage of a series combination of identical capacitors is equal to the sum of voltage ratings of individual capacitors provided that equalizing resistors are used to ensure equal voltage division. This is all because of Ohm's law.

Parallel circuits

If two or more components are connected in parallel they have the same potential difference (voltage) across their ends. The potential differences across the components are the same in magnitude, and they also have identical polarities. Hence, the same voltage is applicable to all circuit components connected in parallel. The total current I is the sum of the currents through the individual components, in accordance with Kirchhoff's Current Law. The current in each individual resistor is found by Ohm's Law. Factoring out the voltage gives

Notation

The parallel property can be represented in equations by two vertical lines (as in geometry) to simplify the equations.

Resistors

To find the total resistance of all components, add the reciprocals of the resistances $\text{[math]}$ of each component and take the reciprocal of the sum:

To find the current in a component with resistance $\text{[math]}$ , use Ohm's law again:

The components divide the current according to their reciprocal resistances, so, in the case of two resistors,

NOTE: The above formulae extend to impedances in parallel.

Inductors

Inductors follow the same law, in that the total inductance of non-coupled inductors in parallel is equal to the reciprocal of the sum of the reciprocals of their individual inductances:

A diagram of several inductors, side by side, both leads of each connected to the same wires.

If the inductors are situated in each other's magnetic fields, this approach is invalid due to mutual inductance. If the mutual inductance between two coils in parallel is M, the equivalent inductor is:

If

The sign of $\text{[math]}$ depends on how the magnetic fields influence each other. For two equal tightly coupled coils the total inductance is close to that of each single coil. If the polarity of one coil is reversed so that M is negative, then the parallel inductance is nearly zero or the combination is almost non-inductive. We are assuming in the "tightly coupled" case M is very nearly equal to L. However, if the inductances are not equal and the coils are tightly coupled there can be near short circuit conditions and high circulating currents for both positive and negative values of M, which can cause problems.

More than 3 inductors becomes more complex and the mutual inductance of each inductor on each other inductor and their influence on each other must be considered. For three coils, there are three mutual inductances , and $\text{[math]}$ . This is best handled by matrix methods and summing the terms of the inverse of the $\text{[math]}$ matrix (3 by 3 in this case).

The pertinent equations are of the form:

Capacitors

Capacitors follow a different law. The total capacitance of capacitors in parallel is equal to the sum of their individual capacitances:

The working voltage of a parallel combination of capacitors is always limited by the smallest working voltage of an individual capacitor.

External links

diracdelta.co.uk calculators for resistors in series and parallel.

electrical network is an interconnection of electrical elements such as resistors, inductors, capacitors, transmission lines, voltage sources, current sources, and switches.
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Voltage (sometimes also called electric potential difference or electrical tension) is the potential similarity of electrical potential between two points of an electrical or electronic circuit, expressed in volts.
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battery is a device consisting of one or more electrochemical cells, which store chemical energy and make it available in an electrical form. There are many types of electrochemical cells, including galvanic cells, electrolytic cells, fuel cells, flow cells, and voltaic cells.
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daisy chain, in the most elementary sense, is a garland created from the daisy flower, generally as a children's game. The words "daisy chain", or "daisy chaining" also have a number of technical and social meanings (some given below), which likely stemmed from this pursuit.
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Electric current is the flow (movement) of electric charge. The SI unit of electric current is the ampere (A), which is equal to a flow of one coulomb of charge per second.

Definition

The amount of electric current (measured in amperes) through some surface, e.g.
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Electrical resistance is a measure of the degree to which an object opposes an electric current through it. The SI unit of electrical resistance is the ohm. Its reciprocal quantity is electrical conductance measured in siemens.
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Ohm's law states that, in an electrical circuit, the current passing through a conductor between two points is proportional to the potential difference (i.e. voltage drop or voltage) across the two points, and inversely proportional to the resistance between them.
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formula (plural: formulae, formulÃ¦ or formulas) is a concise way of expressing information symbolically (as in a mathematical or chemical formula), or a general relationship between quantities.
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Electrical impedance, or simply impedance, describes a measure of opposition to a sinusoidal alternating current (AC). Electrical impedance extends the concept of resistance to AC circuits, describing not only the relative magnitudes of the voltage and current, but also the
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An inductor is a passive electrical device employed in electrical circuits for its property of inductance. An inductor can take many forms.

Physics

Overview

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inductance, or more accurately self-inductance of the circuit. The term was coined by Oliver Heaviside in February 1886. It is customary to use the symbol for inductance, possibly in honour of the physicist Heinrich Lenz.
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capacitor is an electrical/electronic device that can store energy in the electric field between a pair of conductors (called "plates"). The process of storing energy in the capacitor is known as "charging", and involves electric charges of equal magnitude, but opposite polarity,
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Capacitance is a measure of the amount of electric charge stored (or separated) for a given electric potential. The most common form of charge storage device is a two-plate capacitor.
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multiplicative inverse for a number x, denoted by ¹⁄_x or x⁻¹, is a number which when multiplied by x yields the multiplicative identity, 1.
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Not to be confused with Kerckhoffs' principle.

Kirchhoff's circuit laws are a pair of laws that deal with the conservation of charge and energy in electrical circuits, and were first described in 1845 by Gustav Kirchhoff.
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Parallel is a term in geometry and in everyday life that refers to a property in Euclidean space of two or more lines or planes, or a combination of these. The existence and properties of parallel lines are the basis of Euclid's parallel postulate.
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Reciprocal may refer to:

Reciprocal (mathematics), the number 1/x, which multiplied by x gives the product 1
Reciprocal rule, a technique in calculus for calculating derivatives of reciprocal functions

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Electric current is the flow (movement) of electric charge. The SI unit of electric current is the ampere (A), which is equal to a flow of one coulomb of charge per second.

Definition

The amount of electric current (measured in amperes) through some surface, e.g.
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An inductor is a passive electrical device employed in electrical circuits for its property of inductance. An inductor can take many forms.

Physics

Overview

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A Wheatstone bridge is a measuring instrument invented by Samuel Hunter Christie in 1833 and improved and popularized by Sir Charles Wheatstone in 1843. It is used to measure an unknown electrical resistance by balancing two legs of a bridge circuit, one leg of which includes the
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In electronics, a voltage divider is a simple device designed to create a voltage (V_out) which is proportional to another voltage (V_in).
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Series And Parallel Circuits

Information about Series And Parallel Circuits

Series circuits

Resistors

Inductors

Capacitors

Parallel circuits

Notation

Resistors

Inductors

Capacitors

See also

External links

Definition

Physics

Overview

Definition

Physics

Overview