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• Norton's_theorem abstract "Known in Europe as the Mayer–Norton theorem, Norton's theorem holds, to illustrate in DC circuit theory terms, that (see image):Any linear electrical network with voltage and current sources and only resistances can be replaced at terminals A-B by an equivalent current source INO in parallel connection with an equivalent resistance RNO.This equivalent current INO is the current obtained at terminals A-B of the network with terminals A-B short circuited.This equivalent resistance RNO is the resistance obtained at terminals A-B of the network with all its voltage sources short circuited and all its current sources open circuited.For AC systems the theorem can be applied to reactive impedances as well as resistances.The Norton equivalent circuit is used to represent any network of linear sources and impedances at a given frequency.Norton's theorem and its dual, Thévenin's theorem, are widely used for circuit analysis simplification and to study circuit's initial-condition and steady-state response.Norton's theorem was independently derived in 1926 by Siemens & Halske researcher Hans Ferdinand Mayer (1895–1980) and Bell Labs engineer Edward Lawry Norton (1898–1983).To find the equivalent, Find the Norton current INo. Calculate the output current, IAB, with a short circuit as the load (meaning 0 resistance between A and B). This is INo. Find the Norton resistance RNo. When there are no dependent sources (all current and voltage sources are independent), there are two methods of determining the Norton impedance RNo. Calculate the output voltage, VAB, when in open circuit condition (i.e., no load resistor – meaning infinite load resistance). RNo equals this VAB divided by INo.or Replace independent voltage sources with short circuits and independent current sources with open circuits. The total resistance across the output port is the Norton impedance RNo.This is equivalent to calculating the Thevenin resistance.However, when there are dependent sources, the more general method must be used. This method is not shown below in the diagrams. Connect a constant current source at the output terminals of the circuit with a value of 1 Ampere and calculate the voltage at its terminals. This voltage divided by the 1 A current is the Norton impedance RNo. This method must be used if the circuit contains dependent sources, but it can be used in all cases even when there are no dependent sources.↑ ↑ ↑ ↑ ↑".
• Norton's_theorem thumbnail Norton_equivelant.png?width=300.
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• Norton's_theorem wikiPageExternalLink 9.html.
• Norton's_theorem wikiPageExternalLink paper1.pdf.
• Norton's_theorem wikiPageExternalLink paper2.pdf.
• Norton's_theorem wikiPageID "226856".
• Norton's_theorem wikiPageRevisionID "599546031".
• Norton's_theorem hasPhotoCollection Norton's_theorem.
• Norton's_theorem subject Category:Circuit_theorems.
• Norton's_theorem type Abstraction100002137.
• Norton's_theorem type CircuitTheorems.
• Norton's_theorem type Communication100033020.
• Norton's_theorem type Message106598915.
• Norton's_theorem type Proposition106750804.
• Norton's_theorem type Statement106722453.
• Norton's_theorem type Theorem106752293.
• Norton's_theorem comment "Known in Europe as the Mayer–Norton theorem, Norton's theorem holds, to illustrate in DC circuit theory terms, that (see image):Any linear electrical network with voltage and current sources and only resistances can be replaced at terminals A-B by an equivalent current source INO in parallel connection with an equivalent resistance RNO.This equivalent current INO is the current obtained at terminals A-B of the network with terminals A-B short circuited.This equivalent resistance RNO is the resistance obtained at terminals A-B of the network with all its voltage sources short circuited and all its current sources open circuited.For AC systems the theorem can be applied to reactive impedances as well as resistances.The Norton equivalent circuit is used to represent any network of linear sources and impedances at a given frequency.Norton's theorem and its dual, Thévenin's theorem, are widely used for circuit analysis simplification and to study circuit's initial-condition and steady-state response.Norton's theorem was independently derived in 1926 by Siemens & Halske researcher Hans Ferdinand Mayer (1895–1980) and Bell Labs engineer Edward Lawry Norton (1898–1983).To find the equivalent, Find the Norton current INo. ".
• Norton's_theorem label "Norton's theorem".
• Norton's_theorem label "Norton-Theorem".
• Norton's_theorem label "Stelling van Norton".
• Norton's_theorem label "Teorema de Norton".
• Norton's_theorem label "Teorema de Norton".
• Norton's_theorem label "Teorema di Norton".
• Norton's_theorem label "Théorème de Norton".
• Norton's_theorem label "Twierdzenie Nortona".
• Norton's_theorem label "نظرية نورتون".
• Norton's_theorem label "ノートンの定理".
• Norton's_theorem label "諾頓定理".
• Norton's_theorem sameAs Norton-Theorem.
• Norton's_theorem sameAs Teorema_de_Norton.
• Norton's_theorem sameAs Nortonen_teorema.
• Norton's_theorem sameAs Théorème_de_Norton.
• Norton's_theorem sameAs Teorema_Norton.
• Norton's_theorem sameAs Teorema_di_Norton.
• Norton's_theorem sameAs ノートンの定理.
• Norton's_theorem sameAs 노턴의_정리.
• Norton's_theorem sameAs Stelling_van_Norton.
• Norton's_theorem sameAs Twierdzenie_Nortona.
• Norton's_theorem sameAs Teorema_de_Norton.
• Norton's_theorem sameAs m.01h21b.
• Norton's_theorem sameAs Q651593.
• Norton's_theorem sameAs Q651593.
• Norton's_theorem sameAs Norton's_theorem.
• Norton's_theorem wasDerivedFrom Norton's_theorem?oldid=599546031.
• Norton's_theorem depiction Norton_equivelant.png.
• Norton's_theorem isPrimaryTopicOf Norton's_theorem.