Difference between revisions of "Kirchoff's 1st Law"
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*[[Kirchoff's 1st Law]] is used in network analysis techniques such as mesh analysis and nodal analysis. | *[[Kirchoff's 1st Law]] is used in network analysis techniques such as mesh analysis and nodal analysis. | ||
*[[Kirchoff's 1st Law]] applies to both [[Direct Current|DC]] and [[Alternating Current|AC]] circuits. | *[[Kirchoff's 1st Law]] applies to both [[Direct Current|DC]] and [[Alternating Current|AC]] circuits. | ||
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| + | ===Formula=== | ||
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| + | <math>\sum_{i=1}^n I_i</math> | ||
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===Examples=== | ===Examples=== | ||
*In a [[Parallel Circuit|parallel circuit]], the sum of currents through each branch equals the total [[Electrical Current|current]] entering the [[junction]]. | *In a [[Parallel Circuit|parallel circuit]], the sum of currents through each branch equals the total [[Electrical Current|current]] entering the [[junction]]. | ||
*Used to determine unknown currents in electrical network problems. | *Used to determine unknown currents in electrical network problems. | ||
Revision as of 09:02, 23 May 2024
Key Stage 5
Meaning
Kirchoff's 1st Law states that the total current entering a junction is equal to the total current leaving the junction.
About Kirchhoff's First Law
- Also known as the current law or junction rule.
- Kirchoff's 1st Law is based on the conservation of charge.
- Kirchoff's 1st Law is essential for analyzing complex electrical circuits.
- In Kirchoff's 1st Law the algebraic sum of currents at a junction is equal to zero.
- Kirchoff's 1st Law helps in solving circuit problems by setting up equations based on current conservation.
- Kirchoff's 1st Law is used in network analysis techniques such as mesh analysis and nodal analysis.
- Kirchoff's 1st Law applies to both DC and AC circuits.
Formula
\(\sum_{i=1}^n I_i\)
Examples
- In a parallel circuit, the sum of currents through each branch equals the total current entering the junction.
- Used to determine unknown currents in electrical network problems.