Thomas Edison: Series and parallel circuits

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Series and parallel circuits


In electrical circuits series and parallel are two basic ways of wiring
components. As a demonstration, consider a very simple circuit consisting of
two lightbulbs and one 9V 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, on the other hand, each bulb is wired
separately to the battery in two loops, the bulbs are said to be in
parallel.

The measurable quantities used here are R, resistance, measured in ohms
(Ω), I, current, measured in amperes (coulomb per second), and V,
voltage (joule per columb), measured in volts.

Series Circuits

The same current has to pass through all the components in the loop. An
ammeter placed anywhere in the circuit would measure the same amount.

   * To find the total resistance of all the components, add together the
     individual resistance of each component;

     Rtotal = R1 + R2

     for two components in series, having resistance R1 and R2 respectively.
     For more than two components, add in their respective resistances.

   * To find the current, I, use Ohm's law.

     I = V/Rtotal

   * To find the voltage across any particular component with resistance Ri
     , use Ohm's law again.

     V=IRi
     Where I is the current, as calculated above.

Note, that the components divide the voltage according to their resistances,
so V1/V2 = R1/R2

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

     Ltotal = L1 + L2 + ...

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:

     [{1\over{C_{total}}}={1\over{C_1}}+{1\over{C_2}}+...]

Parallel Circuits

The voltage is the same across all the components in the loop.

   * To find the total current, I, use Ohm's law in each loop then sum.(See
     Kirchhoff's Laws for an explanation of why this works)

     Itotal = V/(R1 + R2 + ...)

   * To find the total resistance of all the components, add together the
     individual reciprocal of each resistance of each component, and take
     the reciprocal;

     1 / Rtotal = 1 / R1 + 1 / R2

     for two components in parallel, having resistance R1 and R2
     respectively. For more than two components, add in their respective
     reciprocals of resistances, and take the reciprocal.

The above rule can be calculated by using Ohm's law for the whole circuit

     Rtotal =V/Itotal

and substituting for Itotal

   * To find the current in any particular component with resistance Ri ,
     use Ohm's law again.

     Ii = V/Ri

Note, that the components divide the current according to their reciprocal
resistances, so I1/I2 = R2/R1

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

     [{1\over{L_{total}}}={1\over{L_1}}+{1\over{L_2}}+...]

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

     Ctotal = C1 + C2 + ...

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