Difference between revisions of "Hall Effect Switches"
(Created page with "Category:Switches{{Knoppen}} <noinclude><!------------------------------------------------ * READ THIS FIRST * Only edit this page if you can improve the content. * Impr...") |
|||
| Line 7: | Line 7: | ||
* Please start editing this page after the /noinclude | * Please start editing this page after the /noinclude | ||
* -------------------------------------------------></noinclude> | * -------------------------------------------------></noinclude> | ||
'''Hall Effect Switches''' are generation of an electric potential perpendicular to both an electric current flowing along a conducting material and an external magnetic field applied at right angles to the current upon application of the magnetic field. | |||
The Hall effect principle is named for physicist Edwin Hall. In 1879 he discovered that when a conductor or semiconductor with current flowing in one direction was introduced perpendicular to a magnetic field a voltage could be measured at right angles to the current path. The common analogy popular at the time of Hall's discovery was of electric current in a wire to a flowing liquid in a pipe. Hall's theory equated the magnetic force on the current resulting in a crowding to one side of the pipe or wire. Electromagnetic field theory has allowed a more refined interpretation of the physics responsible for the Hall effect. | |||
Revision as of 11:05, 20 December 2012
Hall Effect Switches are generation of an electric potential perpendicular to both an electric current flowing along a conducting material and an external magnetic field applied at right angles to the current upon application of the magnetic field.
The Hall effect principle is named for physicist Edwin Hall. In 1879 he discovered that when a conductor or semiconductor with current flowing in one direction was introduced perpendicular to a magnetic field a voltage could be measured at right angles to the current path. The common analogy popular at the time of Hall's discovery was of electric current in a wire to a flowing liquid in a pipe. Hall's theory equated the magnetic force on the current resulting in a crowding to one side of the pipe or wire. Electromagnetic field theory has allowed a more refined interpretation of the physics responsible for the Hall effect.