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Classification

Dependent sources can be classified as follows:

• Voltage-controlled voltage source: The source delivers the voltage as per the voltage of the dependent element. V = f a ( v x ) {\displaystyle V={f_{a}}({v_{x}})}
• Voltage-controlled current source: The source delivers the current as per the voltage of the dependent element. I = f b ( v x ) {\displaystyle I={f_{b}}({v_{x}})}
• Current-controlled current source: The source delivers the current as per the current of the dependent element. I = f c ( i x ) {\displaystyle I={f_{c}}({i_{x}})}
• Current-controlled voltage source: The source delivers the voltage as per the current of the dependent element. V = f d ( i x ) {\displaystyle V={f_{d}}({i_{x}})}

Dependent sources are not necessarily linear. For example, MOSFET switches can be modeled as a voltage-controlled current source when V D S > V G S − V T {\displaystyle V_{\rm {DS}}>V_{\rm {GS}}-V_{T}} and V G S > V T {\displaystyle V_{\rm {GS}}>V_{T}} .

However, the relationship between the current flowing through it and V D S {\displaystyle V_{\rm {DS}}} is approximately:

I D = μ n C o x 2 W L ( V G S − V t h ) 2 ( 1 + λ ( V D S − V D S s a t ) ) . {\displaystyle I_{\rm {D}}={\frac {\mu _{n}C_{\rm {ox}}}{2}}{\frac {W}{L}}(V_{\rm {GS}}-V_{\rm {th}})^{2}\left(1+\lambda (V_{\rm {DS}}-V_{\rm {DSsat}})\right).} ³⁴

In this case, the current is not linear to V D S {\displaystyle V_{\rm {DS}}} , but rather approximately proportional to the square of V D S − V T {\displaystyle V_{\rm {DS}}-V_{T}} .

As for the case of linear dependent sources, the proportionality constant between dependent and independent variables is dimensionless if they are both currents (or both voltages). A voltage controlled by a current has a proportionality factor expressed in units of resistance (ohms), and this constant is sometimes called "transresistance". A current controlled by a voltage has units of conductance (siemens), and is called "transconductance". Transconductance is a commonly used specification for measuring the performance of field effect transistors and vacuum tubes.⁵

See also

• Electronics portal

• Circuit theory
• Ground (electricity)
• Mathematical methods in electronics
• Open-circuit voltage
• Lumped-element model
• Distributed-element model
• Series and parallel circuits
• Superposition theorem
• SPICE
• Topology (electronics)
• Trancitor
• Mesh analysis

References

1. I. D. Mayergoyz, Wes Lawson Basic electric circuit theory: a one-semester text Gulf Professional Publishing, 1996 ISBN 0-12-480865-4, Chapter 8 "Dependent sources and operational amplifiers" /wiki/ISBN_(identifier) ↩

2. I. D. Mayergoyz, Wes Lawson Basic electric circuit theory: a one-semester text Gulf Professional Publishing, 1996 ISBN 0-12-480865-4, Chapter 8 "Dependent sources and operational amplifiers" /wiki/ISBN_(identifier) ↩

3. PR Gray; PJ Hurst; SH Lewis; RG Meyer (27 March 2001). §1.5.2 p. 45. Wiley. ISBN 0-471-32168-0. 0-471-32168-0 ↩

4. A. S. Sedra; K.C. Smith (2004). Microelectronic circuits (Fifth ed.). New York: Oxford. p. 552. ISBN 0-19-514251-9. 0-19-514251-9 ↩

5. I. D. Mayergoyz, Wes Lawson Basic electric circuit theory: a one-semester text Gulf Professional Publishing, 1996 ISBN 0-12-480865-4, Chapter 8 "Dependent sources and operational amplifiers" /wiki/ISBN_(identifier) ↩