Riemann–Lebesgue lemma: Difference between revisions

Revision as of 18:32, 26 August 2013

Template:More footnotes In electronics, a common-drain amplifier, also known as a source follower, is one of three basic single-stage field effect transistor (FET) amplifier topologies, typically used as a voltage buffer. In this circuit (NMOS) the gate terminal of the transistor serves as the input, the source is the output, and the drain is common to both (input and output), hence its name. The analogous bipolar junction transistor circuit is the common-collector amplifier. This circuit is also commonly called a "stabilizer."

In addition, this circuit is used to transform impedances. For example, the Thévenin resistance of a combination of a voltage follower driven by a voltage source with high Thévenin resistance is reduced to only the output resistance of the voltage follower (a small resistance). That resistance reduction makes the combination a more ideal voltage source. Conversely, a voltage follower inserted between a driving stage and a high load (i.e. a low resistance) presents an infinite resistance (low load) to the driving stage—an advantage in coupling a voltage signal to a large load.

Characteristics

At low frequencies, the source follower pictured at right has the following small signal characteristics.^[1]

	Definition	Expression	Approximate expression	Conditions
Current gain	${A_{\mathrm {i} }}={i_{\mathrm {out} } \over i_{\mathrm {in} }}$	$\infty \$	$\infty \$
Voltage gain	${A_{\mathrm {v} }}={v_{\mathrm {out} } \over v_{\mathrm {in} }}$	${\frac {g_{m}R_{\text{S}}}{g_{m}R_{\text{S}}+1}}$	$\approx 1$	$(g_{m}R_{\text{S}}\gg 1)$
Input resistance	$r_{\mathrm {in} }={\frac {v_{in}}{i_{in}}}$	$\infty \$	$\infty \$
Output resistance	$r_{\mathrm {out} }={\frac {v_{out}}{i_{out}}}$	$R_{\text{S}}\\|{\frac {1}{g_{m}}}={\frac {R_{\text{S}}}{g_{m}R_{\text{S}}+1}}$	$\approx {\frac {1}{g_{m}}}$	$(g_{m}R_{S}\gg 1)$

The variable g_m that is not listed in the schematic is the transconductance of the device (usually given in units of siemens).

References

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↑ Common Drain Amplifier or Source Follower—Circuit analysis, low frequency, high frequency, and impedance calculations.

[circuit_analysis-1] Common Drain Amplifier or Source Follower—Circuit analysis, low frequency, high frequency, and impedance calculations.

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+{{More footnotes|date=April 2009}}
+In [[electronics]], a '''common-drain''' [[electronic amplifier|amplifier]], also known as a '''source follower''', is one of three basic single-stage [[field effect transistor]] (FET) amplifier topologies, typically used as a [[voltage]] [[buffer amplifier|buffer]]. In this circuit (NMOS) the gate terminal of the transistor serves as the input, the source is the output, and the drain is common to both (input and output), hence its name. The analogous [[bipolar junction transistor]] circuit is the [[common collector|common-collector amplifier]]. This circuit is also commonly called a "stabilizer."
+In addition, this circuit is used to transform [[Electrical impedance|impedance]]s. For example, the [[Thevenin's theorem|Thévenin resistance]] of a combination of a voltage follower driven by a voltage source with high Thévenin resistance is reduced to only the output resistance of the voltage follower (a small resistance). That resistance reduction makes the combination a more ideal voltage source. Conversely, a voltage follower inserted between a driving stage and a high load (i.e. a low resistance) presents an infinite resistance (low load) to the driving stage—an advantage in coupling a voltage signal to a large load.
+== Characteristics ==
+[[Image:N-channel JFET source follower.svg|thumb|Basic N-channel JFET source follower circuit (neglecting [[biasing]] details).]]
+At low frequencies, the source follower pictured at right has the following [[small signal]] characteristics.<ref name="circuit analysis">[http://webpages.eng.wayne.edu/cadence/ECE7570/doc/cdrain3.pdf Common Drain Amplifier or Source Follower]—Circuit analysis, low frequency, high frequency, and impedance calculations.</ref>
+{| class="wikitable" style="background:white;text-align:left"
+!  !! Definition !! Expression !! Approximate expression !! Conditions
+|-
+! '''[[gain#Current gain|Current gain]]'''
+|<math> {A_\mathrm{i}} = {i_\mathrm{out} \over i_\mathrm{in}} </math>
+|<math> \infty\ </math>
+|<math> \infty\ </math>
+|
+|-
+! '''[[gain#Voltage gain|Voltage gain]]'''
+|<math> {A_\mathrm{v}} = {v_\mathrm{out} \over v_\mathrm{in}} </math>
+|<math> \frac{g_m R_{\text{S}}}{g_m R_{\text{S}} + 1} </math>
+|<math> \approx 1 </math>
+|<math> (g_m R_{\text{S}} \gg 1)</math>
+|-
+! '''[[Input resistance]]'''
+|<math> r_\mathrm{in} = \frac{v_{in}}{i_{in}}</math>
+|<math> \infty\  </math>
+|<math> \infty\ </math>
+|
+|-
+! '''[[Output resistance]]'''
+|<math> r_\mathrm{out} = \frac{v_{out}}{i_{out}}</math>
+|<math> R_{\text{S}} \| \frac{1}{g_m} = \frac{ R_{\text{S}} }{ g_m R_{\text{S}} + 1 }</math>
+|<math> \approx \frac{1}{g_m}</math>
+|<math> (g_m R_S \gg 1)</math>
+|}
+The variable ''g<sub>m</sub>'' that is not listed in the schematic is the [[transconductance]] of the device (usually given in units of [[siemens (unit)|siemens]]).
+==See also==
+{{Portal|Electronics}}
+{{colbegin|3}}
+*[[Negative feedback amplifier]]
+*[[Buffer amplifier]]
+*[[Two-port network]]s
+*[[Hybrid-pi model]]
+*[[Common collector]]
+*[[Common emitter]]
+*[[Common base]]
+*[[Common source]]
+*[[Common gate]]
+*[[Common emitter#Emitter degeneration|Emitter degeneration]]
+{{colend}}
+== References ==
+{{reflist}}
+{{Transistor amplifiers}}
+[[Category:Single-stage transistor amplifiers]]
+{{electronics-stub}}

Riemann–Lebesgue lemma: Difference between revisions

Revision as of 18:32, 26 August 2013

Characteristics

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