Georg Ohm: Difference between revisions

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<math>{&Delta;V}_{battery} = {I}{R}_{1} + {I}{R}_{2} + {I}{R}_{3}
<math>{&Delta;V}_{battery} = {I}{R}_{1} + {I}{R}_{2} + {I}{R}_{3}


<math>{I} = {&Delta;V}_{battery}/({R}_{1} + {R}_{2} + {R}_{3})</math>
V = 9 Volts
R_1 = 3 kilo Ohms
R_1 = 3 kilo Ohms
R_2 = 10 kilo Ohms
R_3 = 5 kilo Ohms
I = (9/(3000+10000+5000)) = .0005 Amperes
===Difficult===
===Difficult===
https://www.youtube.com/watch?v=WwGstDT9HR8


==Connectedness==
==Connectedness==
Line 54: Line 67:
== See also ==
== See also ==


===Further reading===
Books, Articles or other print media on this topic


===External links===
===External links===
Line 68: Line 76:
This section contains the the references you used while writing this page
This section contains the the references you used while writing this page


[[Category:Which Category did you place this in?]]
[[Category:Notable Scientists]]

Revision as of 21:37, 4 December 2015

Georg Ohm WIP Claimed by Raghav Gupta

The Main Idea

Georg Ohm was a German who worked to discover a relationship between the potential difference across a resistor and the current. This was named after him, called Ohm's Law. The unit to measure resistance is named ohms after him as well.

Summary of Ohm

Georg Ohm was born in 1789 in Erlangen, Bavaria in Germany. He is the brother of famous mathematician Martin Ohm. Ohm attended Erlangen University before becoming a professor. During his time as a professor at Jesuits' College at Cologne, Ohm published a pamphlet called Die galvanische Kette, mathematisch bearbeitet (1827; The Galvanic Circuit Investigated Mathematically) which contained his findings about the current through a conductor. However, many people did not accept this law so Ohm left his job at Cologne. After almost 15 years, Ohm was given the Copley Medal by the Royal Society of London in 1841. Ohm soon started gaining recognition from German scientists and continued to gain recognition until his death in 1854.


A Mathematical Model

Ohm had a simple equation. His equation can be modeled as [math]\displaystyle{ {&Delta;V} = {I}{R} }[/math] where ΔV is the total potential drop across a resistor (measured in volts), I is the current across a particular resistor (measured in amps) and R is the resistance of the resistor across which current is travelling (measured in ohms).

Examples

[math]\displaystyle{ {&Delta;V}_{battery} = {I}{R} }[/math]

Be sure to show all steps in your solution and include diagrams whenever possible

Simple


What is the current in this system?

[math]\displaystyle{ {&Delta;V}_{battery} = {I}{R} }[/math] R = 5 Ohms V = 10 Volts

[math]\displaystyle{ {I} = {&Delta;V}_{battery}/{R} }[/math]

I = 10 Volts/5 Ohms = 2 Amperes

Middling


What is the current in this system?

You need to use the loop rule to help solve this ([math]\displaystyle{ {&Delta;V}_{loop}={0} }[/math])


[math]\displaystyle{ {&Delta;V}_{battery} = {I}{R}_{1} + {I}{R}_{2} + {I}{R}_{3} \lt math\gt {I} = {&Delta;V}_{battery}/({R}_{1} + {R}_{2} + {R}_{3}) }[/math]

V = 9 Volts R_1 = 3 kilo Ohms R_2 = 10 kilo Ohms R_3 = 5 kilo Ohms

I = (9/(3000+10000+5000)) = .0005 Amperes

Difficult

https://www.youtube.com/watch?v=WwGstDT9HR8


Connectedness

Circuits are very intriguing to me. I don't understand them completely but it makes sense to think about Ohm's Law. It is also very good that Ohm developed his law because it is used in nearly all modern circuitry. This is also very closely related to my major because every engineer needs to have some understanding of circuits and it is impossible to understand circuits without Ohm's findings. In almost every electric device, there are circuits that involve some kind of resistor, current and voltage. The relation between these would be impossible to understand without Ohm's laws.


See also

External links

Internet resources on this topic

References

This section contains the the references you used while writing this page