About: Electronic filter topology

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dbo:abstract	Electronic filter topology defines electronic filter circuits without taking note of the values of the components used but only the manner in which those components are connected. Filter design characterises filter circuits primarily by their transfer function rather than their topology. Transfer functions may be linear or nonlinear. Common types of linear filter transfer function are; high-pass, low-pass, bandpass, band-reject or notch and all-pass. Once the transfer function for a filter is chosen, the particular topology to implement such a prototype filter can be selected so that, for example, one might choose to design a Butterworth filter using the Sallen–Key topology. Filter topologies may be divided into passive and active types. Passive topologies are composed exclusively of passive components: resistors, capacitors, and inductors. Active topologies also include active components (such as transistors, op amps, and other integrated circuits) that require power. Further, topologies may be implemented either in unbalanced form or else in balanced form when employed in balanced circuits. Implementations such as electronic mixers and stereo sound may require arrays of identical circuits. (en) La topologia dei filtri elettronici definisce i circuiti dei filtri elettronici senza tenere conto dei valori dei componenti utilizzati ma solo del modo in cui tali componenti sono connessi. La progettazione di un filtro caratterizza principalmente i circuiti del filtro in base alla loro funzione di trasferimento piuttosto che in base alla loro topologia. Le funzioni di trasferimetno possono essere lineari o non lineari. I tipi comuni di funzione di trasferimento di filtri lineari sono: passa-alto, passa-basso, passa-banda, elimina-banda o notch e passa-tutto. Una volta scelta la funzione di trasferimento per un filtro, la particolare topologia per implementare per un tale filtro prototipo può essere selezionata in modo tale che, per esempio, si potrebbe scegliere di progettare un filtro Butterworth usiando la topologia Sallen-Key. Le topologie dei filtri possono essere divise in topologie di tipo passivo e di tipo attivo. Le topologie passive sono composte esclusivamente di componenti passivi: resistori, condensatori e induttori. Le topologie attive includono anche componenti attivi (quali transistor, amplificatori operazionali ed altri circuiti integrati) che richiedono potenza. Inoltre, possono essere implementate topologie o in forma sbilanciata o in forma bilanciata quando impiegate in . Implementazioni come e stereofonia possono richiedere array di circuiti identici. (it) Filtr drabinkowy (filtr Zobela, ang. ladder-type filter) – filtr utworzony poprzez połączenie ze sobą kilku filtrów (ogniw lub półogniw) podstawowych. Nazwa filtru pochodzi od sposobu rozmieszczenia elementów na schemacie elektrycznym. Kolejne elementy (ogniwa) filtru drabinkowego muszą być do siebie dopasowane falowo. Filtry Zobela (RC) stosuje się do korekcji charakterystyki impedancyjnej i częstotliwościowej w urządzeniach elektroakustycznych (na wyjściu wzmacniaczy mocy). (pl) Ett bikvadratiskt filter är en typ av linjärt filter vars överföringsfunktion utgörs av en kvot mellan två funktioner med kvadratiska termer (andragradstermer). Bikvadratiska filter implementeras oftast som . Ett specialfall av bikvadratiskt filter är lågpassfilter som har polynomet: med överföringsfunktionen Om dämpfaktorn definieras som blir beloppsfunktionen och Enligt figur 1 kan bikvadratiska filter ge upphov till en mer eller mindre uttalad puckel runt brytfrekvensen. Det går att visa att denna hamnar vid och amplituden hos puckeln är Ett , som alltså består av två RC-nät med samma tidskonstant (eller ) som är kopplade direkt efter varandra, har det normaliserade polynomet och alltså ett Q-värde på 0,5 alternativt en dämpfaktor, k, på 1,0. I figur 1 framgår att ett sådant filter har mindre branthet men är helt utan puckel. Ett Butterworthfilter har det normaliserade polynomet och alltså ett Q-värde på 0,707 alternativt en dämpfaktor, k, på 0,707. I figur 1 framgår att ett sådant filter har en högre branthet och gränsar till att ha en puckel, vilket är Butterworthfiltrets kännetecken. Tyvärr går det inte att direkt applicera denna teori på varken Tjebysjovfilter eller Besselfilter då deras polynom är av annan typ. Dock går det att förstå att om Q-värdet ökas fås instabiliteter i passbandet. Fast dessa är under kontroll vad gäller bikvadratiska filter, då det bara bildas en mer uttalad puckel, så analogin stämmer inte. Pucklar i frekvensplanet inte är de enda problemet med en liten dämpfaktor. Stegsvaret i tidsplanet får då ringningar, i enlighet med figur 2. (sv) 双二阶滤波器的传递函数有如下的形式或分子二项式中系数,决定滤波器的类型： (zh)
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rdfs:comment	Filtr drabinkowy (filtr Zobela, ang. ladder-type filter) – filtr utworzony poprzez połączenie ze sobą kilku filtrów (ogniw lub półogniw) podstawowych. Nazwa filtru pochodzi od sposobu rozmieszczenia elementów na schemacie elektrycznym. Kolejne elementy (ogniwa) filtru drabinkowego muszą być do siebie dopasowane falowo. Filtry Zobela (RC) stosuje się do korekcji charakterystyki impedancyjnej i częstotliwościowej w urządzeniach elektroakustycznych (na wyjściu wzmacniaczy mocy). (pl) 双二阶滤波器的传递函数有如下的形式或分子二项式中系数,决定滤波器的类型： (zh) Electronic filter topology defines electronic filter circuits without taking note of the values of the components used but only the manner in which those components are connected. Filter design characterises filter circuits primarily by their transfer function rather than their topology. Transfer functions may be linear or nonlinear. Common types of linear filter transfer function are; high-pass, low-pass, bandpass, band-reject or notch and all-pass. Once the transfer function for a filter is chosen, the particular topology to implement such a prototype filter can be selected so that, for example, one might choose to design a Butterworth filter using the Sallen–Key topology. (en) La topologia dei filtri elettronici definisce i circuiti dei filtri elettronici senza tenere conto dei valori dei componenti utilizzati ma solo del modo in cui tali componenti sono connessi. La progettazione di un filtro caratterizza principalmente i circuiti del filtro in base alla loro funzione di trasferimento piuttosto che in base alla loro topologia. Le funzioni di trasferimetno possono essere lineari o non lineari. I tipi comuni di funzione di trasferimento di filtri lineari sono: passa-alto, passa-basso, passa-banda, elimina-banda o notch e passa-tutto. Una volta scelta la funzione di trasferimento per un filtro, la particolare topologia per implementare per un tale filtro prototipo può essere selezionata in modo tale che, per esempio, si potrebbe scegliere di progettare un filtro B (it) Ett bikvadratiskt filter är en typ av linjärt filter vars överföringsfunktion utgörs av en kvot mellan två funktioner med kvadratiska termer (andragradstermer). Bikvadratiska filter implementeras oftast som . Ett specialfall av bikvadratiskt filter är lågpassfilter som har polynomet: med överföringsfunktionen Om dämpfaktorn definieras som blir beloppsfunktionen och Enligt figur 1 kan bikvadratiska filter ge upphov till en mer eller mindre uttalad puckel runt brytfrekvensen. Det går att visa att denna hamnar vid och amplituden hos puckeln är Ett Butterworthfilter har det normaliserade polynomet (sv)
rdfs:label	Electronic filter topology (en) Topologia dei filtri elettronici (it) Filtr drabinkowy (pl) 双二阶滤波器 (zh) Bikvadratiskt filter (sv)
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