Ohm's Law: Difference between revisions

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==What is it?==
==What is it?==
Ohm's Law is named after Georg Ohm, a German physicist who postulated it in 1827. His treatise described measurements of voltage and current in simple circuits, using various lengths of wire as resistors. The following diagram shows a voltage source V passing through a resistor R creating a current I
[[Image:Ohms_law_voltage_source.svg.png | 120px ]]
The following diagram shows a current source I through a resistor R, causing a potential drip (voltage V)
[[Image:Ohmslawcurrentsource.png |165px]]


Ohm's Law states that the current that passes between two points on a conductor is directly proportional to the [[Voltage | potential difference]] (voltage) between the points and inversely proportional to the to the [[Resistors |resistance]] of the conductor between the points.
Ohm's Law states that the current that passes between two points on a conductor is directly proportional to the [[Voltage | potential difference]] (voltage) between the points and inversely proportional to the to the [[Resistors |resistance]] of the conductor between the points.

Latest revision as of 02:29, 30 April 2009

Related wiki pages : Electronic Theory, Voltage, Current, Impedance, Resistors

What is it?

Ohm's Law is named after Georg Ohm, a German physicist who postulated it in 1827. His treatise described measurements of voltage and current in simple circuits, using various lengths of wire as resistors. The following diagram shows a voltage source V passing through a resistor R creating a current I

Ohms law voltage source.svg.png

The following diagram shows a current source I through a resistor R, causing a potential drip (voltage V)

Ohmslawcurrentsource.png

Ohm's Law states that the current that passes between two points on a conductor is directly proportional to the potential difference (voltage) between the points and inversely proportional to the to the resistance of the conductor between the points.

so, <math>I = \frac{V}{R}</math>

where

"I" is the current in amperes,
"V" is the potential difference between the ends of the resistor in volts, and
"R" is the resistance of the resistor, measured in ohms

Ohms Law can also be used in impedance (resistance to AC) calculations thus:

<math>I = \frac{V}{Z}</math>

where

"I" is the current in amperes,
"V" is the potential difference between the ends of the resistor in volts, and
"Z" is the Impedance (AC resistance) of the resistor, measured in ohms


Electronic Theory
Physical quantities Current * Gain * Impedance * Power * Q of a circuit * Radiated Power Measurement * Reactance* Resistivity * Resonance * Voltage
Components Baluns * Bipolar-Junction Transistors * Capacitors * Diodes * Inductors* Lasers * Microphones * Resistors * Transformers * Wire
Circuits Attenuators * Digital Signal Processing (DSP) * Dummy load * Filters * LC filters * Power Supply Design * Rectifier Circuits
Design Amplifier Design * Oscillator Design
Electromagnetic Waves Relative power (Decibels) * Harmonics * Interference and BPL