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Conference Paper: Synthesis of impedance using switching converters
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TitleSynthesis of impedance using switching converters
 
AuthorsLiu, JCP1 2
Tse, CK2
Poon, FNK1
Pong, MH1
Lai, YM1
 
Issue Date2005
 
CitationProceedings Of The Ieee International Conference On Industrial Technology, 2005, v. 2005, p. 7-10 [How to Cite?]
DOI: http://dx.doi.org/10.1109/ICIT.2005.1600601
 
AbstractA general impedance synthesizer using a minimum number of switching converters is studied in this paper. We begin with showing that any impedance can be synthesized by a circuit consisting of only two simple power converters, one storage element (e.g., capacitor), and one dissipative element (e.g., resistor) or power source. The implementation of such a circuit for synthesizing any desired impedance can be performed by (i) programming the input current given the input voltage such that the desired impedance function is achieved; (ii) controlling the amount of power dissipation (generation) in the dissipative element (source) so as to match the required active power of the impedance to be synthesized. Then, the instantaneous power will automatically be balanced by the storage element. Such impedance synthesizers find a lot of applications in power electronics. For instance, a resistance synthesizer can be used for power factor correction (PFC), a programmable capacitor or inductor synthesizer (comprising of small high-frequency converters) can be used for control applications. © 2005 IEEE.
 
DOIhttp://dx.doi.org/10.1109/ICIT.2005.1600601
 
ReferencesReferences in Scopus
 
DC FieldValue
dc.contributor.authorLiu, JCP
 
dc.contributor.authorTse, CK
 
dc.contributor.authorPoon, FNK
 
dc.contributor.authorPong, MH
 
dc.contributor.authorLai, YM
 
dc.date.accessioned2012-08-08T08:59:43Z
 
dc.date.available2012-08-08T08:59:43Z
 
dc.date.issued2005
 
dc.description.abstractA general impedance synthesizer using a minimum number of switching converters is studied in this paper. We begin with showing that any impedance can be synthesized by a circuit consisting of only two simple power converters, one storage element (e.g., capacitor), and one dissipative element (e.g., resistor) or power source. The implementation of such a circuit for synthesizing any desired impedance can be performed by (i) programming the input current given the input voltage such that the desired impedance function is achieved; (ii) controlling the amount of power dissipation (generation) in the dissipative element (source) so as to match the required active power of the impedance to be synthesized. Then, the instantaneous power will automatically be balanced by the storage element. Such impedance synthesizers find a lot of applications in power electronics. For instance, a resistance synthesizer can be used for power factor correction (PFC), a programmable capacitor or inductor synthesizer (comprising of small high-frequency converters) can be used for control applications. © 2005 IEEE.
 
dc.description.natureLink_to_subscribed_fulltext
 
dc.identifier.citationProceedings Of The Ieee International Conference On Industrial Technology, 2005, v. 2005, p. 7-10 [How to Cite?]
DOI: http://dx.doi.org/10.1109/ICIT.2005.1600601
 
dc.identifier.doihttp://dx.doi.org/10.1109/ICIT.2005.1600601
 
dc.identifier.epage10
 
dc.identifier.scopuseid_2-s2.0-33847257812
 
dc.identifier.spage7
 
dc.identifier.urihttp://hdl.handle.net/10722/158455
 
dc.identifier.volume2005
 
dc.languageeng
 
dc.relation.ispartofProceedings of the IEEE International Conference on Industrial Technology
 
dc.relation.referencesReferences in Scopus
 
dc.titleSynthesis of impedance using switching converters
 
dc.typeConference_Paper
 
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<description.abstract>A general impedance synthesizer using a minimum number of switching converters is studied in this paper. We begin with showing that any impedance can be synthesized by a circuit consisting of only two simple power converters, one storage element (e.g., capacitor), and one dissipative element (e.g., resistor) or power source. The implementation of such a circuit for synthesizing any desired impedance can be performed by (i) programming the input current given the input voltage such that the desired impedance function is achieved; (ii) controlling the amount of power dissipation (generation) in the dissipative element (source) so as to match the required active power of the impedance to be synthesized. Then, the instantaneous power will automatically be balanced by the storage element. Such impedance synthesizers find a lot of applications in power electronics. For instance, a resistance synthesizer can be used for power factor correction (PFC), a programmable capacitor or inductor synthesizer (comprising of small high-frequency converters) can be used for control applications. &#169; 2005 IEEE.</description.abstract>
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Author Affiliations
  1. The University of Hong Kong
  2. Hong Kong Polytechnic University