imported>John R. Brews |
imported>John R. Brews |
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| {{Image|Two-port with Thevenin driver.PNG|right|350px| Two-port network with symbol definitions. A [[Thevenin voltage source]] with [[Thevenin impedance]] ''Z<sub>Th</sub>'' drives port 1, and impedance ''Z<sub>L</sub>'' loads port 2}}
| | The '''hybrid-pi model''' is a popular [[circuit]] model used for analyzing the [[small signal]] behavior of [[transistors]]. The model can be quite accurate for low-frequency circuits and can easily be adapted for higher frequency circuits with the addition of appropriate inter-electrode [[capacitance]]s and other parasitic elements. |
| A '''two-port network''' is an [[electrical circuit]] with two ''pairs'' of terminals. As shown in the figure, two terminals constitute a '''port''' ''only'' if they satisfy the essential requirement known as the '''port condition''', namely, the same current must enter and leave a port.<ref name=Gray/><ref name=Jaeger/>
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| Examples include small-signal models for transistors (such as the [[hybrid-pi model]]), [[electronic filter|filter]]s and [[matching network]]s. The analysis of passive two-port networks is an outgrowth of reciprocity theorems first derived by Lorentz.<ref name=Jasper/>
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| A two-port network makes possible the replacement of either a complete circuit or part of it by a "[[black box]]" with a only four distinct parameters, enabling us to separate its behavior from that of its internal constituents, thus simplifying analysis. Any linear circuit with four terminals can be transformed into a two-port network provided that it does not contain an independent source and satisfies the port conditions.
| | ==BJT parameters== |
| | The hybrid-pi model is a linearized [[two-port network]] approximation to the transistor using the small-signal base-emitter voltage <math>v_{be}</math> and collector-emitter voltage <math>v_{ce}</math> as independent variables, and the small-signal base current <math>i_{b}</math> and collector current <math>i_{c}</math> as dependent variables. (See Jaeger and Blalock.<ref name=Jaeger1> |
| | {{cite book |
| | |author=R.C. Jaeger and T.N. Blalock |
| | |title=Microelectronic Circuit Design |
| | |year= 2004 |
| | |edition=Second Edition |
| | |publisher=McGraw-Hill |
| | |location=New York |
| | |isbn=0-07-232099-0 |
| | |pages=Section 13.5, esp. Eqs. 13.19 |
| | |url=http://worldcat.org/isbn/0072320990}} |
| | </ref>) |
| | [[Image:H pi model.png|frame|Figure 1: Simplified, low-frequency hybrid-pi [[BJT]] model.]] |
| | A basic, low-frequency hybrid-pi model for the [[bipolar transistor]] is shown in figure 1. The various parameters are as follows. |
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| The parameters used to describe a two-port network are the following: z, y, h, g. Each choice corresponds to a different choice for which pair of variables from port 1 and port 2 are chosen to be independent, externally applied sources and which two will be the dependent resultant variables determine by the two-port parameters (see the figure). The port currents and voltages are denoted as follows:
| | *<math>g_m = \frac{i_{c}}{v_{be}}\Bigg |_{v_{ce}=0} = \begin{matrix}\frac {I_\mathrm{C}}{ V_\mathrm{T} }\end{matrix} </math> is the [[transconductance]] in [[Siemens (unit)|siemens]], evaluated in a simple model (see Jaeger and Blalock<ref name=Jaeger> |
| :<math>{V_1}</math> = Port 1 voltage | | {{cite book |
| :<math>{I_1}</math> = Port 1 current
| | |author=R.C. Jaeger and T.N. Blalock |
| :<math>{V_2}</math> = Port 2 voltage
| | |title=Eq. 5.45 pp. 242 and Eq. 13.25 p. 682 |
| :<math>{I_2}</math> = Port 2 current | | |isbn=0-07-232099-0 |
| The relations between inputs and outputs usually are expressed in matrix notation.
| | |url=http://worldcat.org/isbn/0072320990}} |
| | </ref>) |
| | |
| | :where: |
| | :* <math>I_\mathrm{C} \,</math> is the [[quiescent]] collector current (also called the collector bias or DC collector current) |
| | :* <math>V_\mathrm{T} = \begin{matrix}\frac {kT}{ q}\end{matrix}</math> is the ''[[Boltzmann constant#Role in semiconductor physics: the thermal voltage|thermal voltage]]'', calculated from [[Boltzmann's constant]], the [[elementary charge|charge on an electron]], and the transistor temperature in [[kelvin]]s. At 300 K (approximately room temperature) <math>V_\mathrm{T}</math> is about 26 mV ([http://www.google.com/search?hl=en&q=300+kelvin+*+k+%2F+elementary+charge+in+millivolts+%3D Google calculator]). |
| | * <math>r_{\pi} = \frac{v_{be}}{i_{b}}\Bigg |_{v_{ce}=0} = \frac{\beta_0}{g_m} = \frac{V_\mathrm{T}}{I_\mathrm{B}} \,</math> in [[Ohm (unit)|ohm]]s |
| | :where: |
| | :* <math>\beta_0 = \frac{I_\mathrm{C}}{I_\mathrm{B}} \,</math> is the current gain at low frequencies (commonly called h<sub>FE</sub>). Here <math>I_B</math> is the Q-point base current. This is a parameter specific to each transistor, and can be found on a datasheet; <math>\beta</math> is a function of the choice of collector current. |
| | *<math> r_O = \frac{v_{ce}}{i_{c}}\Bigg |_{v_{be}=0} = \begin{matrix}\frac {V_A+V_{CE}}{I_C}\end{matrix} \approx \begin{matrix} \frac {V_A}{I_C}\end{matrix}</math> is the output resistance due to the [[Early effect]]. |
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| These variables are most useful at low to moderate frequencies. At high frequencies (for example, microwave frequencies) power and energy are more useful variables, and the two-port approach based on current and voltages that is discussed here is replaced by an approach based upon [[scattering parameters]].<ref name=Pozar/>
| | ===Related terms=== |
| | The reciprocal of the output resistance is named the '''output conductance''' |
| | :*<math>g_{ce} = \frac {1} {r_O} </math>. |
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| Though some authors use the terms ''two-port network'' and ''four-terminal network'' interchangeably, the latter represents a more general concept. '''Not all four-terminal networks are two-port networks.''' A pair of terminals can be called a ''port'' only if the current entering one is equal to the current leaving the other (the '''port condition'''). Only those four-terminal networks in which the four terminals can be paired into two ports can be called two-ports.<ref name=Gray/><ref name=Jaeger/>
| | The reciprocal of g<sub>m</sub> is called the '''intrinsic resistance''' |
| | :*<math>r_{E} = \frac {1} {g_m} </math>. |
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| == Impedance parameters (z-parameters)== | | ==MOSFET parameters== |
| {{Image|Z-equivalent two-port.PNG|right|350px| Z-equivalent two port showing independent variables ''I<sub>1</sub>'' and ''I<sub>2</sub>''.}}
| | [[Image:MOSFET Small Signal.png|thumbnail|250px||Figure 2: Simplified, low-frequency hybrid-pi [[MOSFET]] model.]] |
| The figure shows the two-port driven by two external current sources, making the input currents ''I<sub>1</sub>'' and ''I<sub>2</sub>'' the independent variables controlled from outside the two-port. The port voltages are determined in terms of these input currents by the ''z''-parameters defined by:
| | A basic, low-frequency hybrid-pi model for the [[MOSFET]] is shown in figure 2. The various parameters are as follows. |
| :<math> \left[ \begin{array}{c} V_1 \\ V_2 \end{array} \right] = \left[ \begin{array}{cc} z_{11} & z_{12} \\ z_{21} & z_{22} \end{array} \right] \left[ \begin{array}{c}I_1 \\ I_2 \end{array} \right] </math>.
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| :<math>z_{11} = {V_1 \over I_1 } \bigg|_{I_2 = 0} \qquad z_{12} = {V_1 \over I_2 } \bigg|_{I_1 = 0}</math>
| | *<math>g_m = \frac{i_{d}}{v_{gs}}\Bigg |_{v_{ds}=0}</math> |
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| :<math>z_{21} = {V_2 \over I_1 } \bigg|_{I_2 = 0} \qquad z_{22} = {V_2 \over I_2 } \bigg|_{I_1 = 0}</math>
| | is the [[transconductance]] in [[Siemens (unit)|siemens]], evaluated in the Shichman-Hodges model in terms of the [[Q-point]] drain current <math> I_D</math> by (see Jaeger and Blalock<ref name=Jaeger2> |
| | | {{cite book |
| Notice that all the series connected elements represented by z-parameters have dimensions of ohms, as do the dependent source parameters.
| | |author=R.C. Jaeger and T.N. Blalock |
| | | |title=Eq. 4.20 pp. 155 and Eq. 13.74 p. 702 |
| ===Example: bipolar [[current mirror]] with emitter degeneration===
| | |isbn=0-07-232099-0 |
| {{Image|Bipolar current mirror with emitter resistors.PNG|left|200px| Bipolar current mirror: ''I<sub>1</sub>'' is the ''reference current'' and ''I<sub>2</sub>'' is the ''output current''.}}
| | |url=http://worldcat.org/isbn/0072320990}} |
| {{Image|Small-signal circuit for bipolar mirror.PNG|right|300px| Small-signal circuit for bipolar current mirror: ''I<sub>1</sub>'' is the amplitude of the small-signal ''reference current'' and ''I<sub>2</sub>'' is the amplitude of the small-signal ''output current''.}}
| | </ref>): |
| The figure at left shows a bipolar current mirror with emitter resistors to increase its output resistance.<ref name=feedback/> Transistor ''Q<sub>1</sub>'' is ''diode connected'', which is to say its collector-base voltage is zero. The figure at right shows the small-signal circuit equivalent to the transistor circuit. Transistor ''Q<sub>1</sub>'' is represented by its emitter resistance ''r<sub>E</sub>'' ≈ ''V<sub>T</sub> / I<sub>E</sub>'' (''V<sub>T</sub>'' = thermal voltage, ''I<sub>E</sub>'' = [[Q-point]] emitter current), a simplification made possible because the dependent current source in the hybrid-pi model for ''Q<sub>1</sub>'' draws the same current as a resistor 1 / ''g<sub>m</sub>'' connected across ''r<sub>π</sub>''. The second transistor ''Q<sub>2</sub>'' is represented by its [[hybrid-pi model]]. Table 1 below shows the z-parameter expressions that make the z-equivalent two-port electrically equivalent to the small-signal circuit for the mirror.
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| {| class="wikitable" style="background:white;text-align:center;margin: 1em auto 1em auto"
| |
| !Table 1 !! Expression !! Approximation
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| | |
| |-valign="center"
| |
| |<math>R_{21} = \begin{matrix} {V_\mathrm{2} \over I_\mathrm{1} }\end{matrix} \Big|_{I_{2}=0} </math>
| |
| |<math> - ( \beta r_O - R_E ) </math> <math> \begin{matrix} \frac {r_E +R_E }{r_{ \pi}+r_E +2R_E} \end{matrix} </math>
| |
| |<math> - \beta r_o </math><math> \begin{matrix} \frac {r_E+R_E }{r_{ \pi} +2R_E}\end{matrix} </math>
| |
| | |
| |-valign="center" | |
| |<math>R_{11}= \begin{matrix} \frac{V_{1}}{I_{1}}\end{matrix} \Big|_{I_{2}=0} </math> | |
| |<math> (r_E + R_E)</math> <math>// </math> <math>(r_{ \pi} +R_E) </math>
| |
| |<math></math>
| |
| | |
| |-valign="center"
| |
| |<math> R_{22} = \begin{matrix} \frac{V_{2}}{I_{2}}\end{matrix} \Big|_{I_{1}=0} </math> | |
| |<math> \ ( </math><math> 1 + \beta </math> <math> \begin{matrix} \frac {R_E} {r_{ \pi} +r_E+2R_E } \end{matrix} ) </math> <math> r_O </math> <math>+ \begin{matrix} \frac { r_{ \pi}+r_E +R_E }{r_{ \pi}+r_E +2R_E } \end{matrix} </math><math>R_E</math>
| |
| |<math> \ ( </math><math>1 + \beta </math><math> \begin{matrix} \frac {R_E} {r_{ \pi}+2R_E } \end{matrix} ) </math> <math>r_O </math>
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|
| |
|
| |-valign="center"
| | :::<math>\ g_m = \begin{matrix}\frac {2I_\mathrm{D}}{ V_{\mathrm{GS}}-V_\mathrm{th} }\end{matrix}</math>, |
| |<math> R_{12} = \begin{matrix} {V_\mathrm{1} \over I_\mathrm{2} }\end{matrix} \Big|_{I_{1}=0} </math>
| | |
| |<math>R_E </math> <math>\begin{matrix} \frac {r_E+R_E} {r_{ \pi} +r_E +2R_E} \end{matrix}</math>
| | :where: |
| |<math>R_E</math> <math> \begin{matrix} \frac {r_E+R_E} {r_{ \pi} +2R_E} \end{matrix}</math>
| | ::<math>I_\mathrm{D} </math> is the [[quiescent]] drain current (also called the drain bias or DC drain current) |
| |}
| | ::<math>V_{th}</math> = [[threshold voltage]] and <math>V_{GS}</math> = gate-to-source voltage. |
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| The negative feedback introduced by resistors ''R<sub>E</sub>'' can be seen in these parameters. For example, when used as an active load in a differential amplifier, ''I<sub>1</sub> ≈ -I<sub>2</sub>'', making the output impedance of the mirror approximately ''R<sub>22</sub> -R<sub>21</sub>'' ≈ 2 β ''r<sub>O</sub>R<sub>E</sub>'' /( ''r<sub>π</sub>+2R<sub>E</sub>'' ) compared to only ''r<sub>O</sub>'' without feedback (that is with ''R<sub>E</sub>'' = 0 Ω) . At the same time, the impedance on the reference side of the mirror is approximately ''R<sub>11</sub> -R<sub>12</sub>'' ≈ <math> \begin{matrix} \frac {r_{\pi}} {r_{\pi}+2R_E} \end{matrix} </math> <math> (r_E+R_E)</math>, only a moderate value, but still larger than ''r<sub>E</sub>'' with no feedback. In the differential amplifier application, a large output resistance increases the difference-mode gain, a good thing, and a small mirror input resistance is desirable to avoid [[Miller effect]]. | | The combination: |
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| ==Admittance parameters (y-parameters) == | | :: <math>\ V_{ov}=( V_{GS}-V_{th})</math> |
| {{Image|Y-equivalent two-port.PNG|right|350px| Y-equivalent two port showing independent variables ''V<sub>1</sub>'' and ''V<sub>2</sub>''.}} | |
| The figure shows the two-port driven by two external voltage sources, making the input voltages ''V<sub>1</sub>'' and ''V<sub>2</sub>'' the independent variables controlled from outside the two-port. The port currents are determined in terms of these input voltages by the ''y''-parameters defined by:
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| :<math> \left[ \begin{array}{c} I_1 \\ I_2 \end{array} \right] = \left[ \begin{array}{cc} y_{11} & y_{12} \\ y_{21} & y_{22} \end{array} \right] \left[ \begin{array}{c}V_1 \\ V_2 \end{array} \right] </math>.
| | often is called the ''overdrive voltage''. |
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| |
|
| where
| | *<math> r_O = \frac{v_{ds}}{i_{d}}\Bigg |_{v_{gs}=0}</math> is the output resistance due to [[channel length modulation]], calculated using the Shichman-Hodges model as |
| | | |
| :<math>y_{11} = {I_1 \over V_1 } \bigg|_{V_2 = 0} \qquad y_{12} = {I_1 \over V_2 } \bigg|_{V_1 = 0}</math>
| | :::<math>r_O = \begin{matrix}\frac {1/\lambda+V_{DS}}{I_D}\end{matrix} \approx \begin{matrix} \frac {V_E L}{I_D}\end{matrix} </math>, |
| | | using the approximation for the '''channel length modulation''' parameter λ<ref name=Sansen> |
| :<math>y_{21} = {I_2 \over V_1 } \bigg|_{V_2 = 0} \qquad y_{22} = {I_2 \over V_2 } \bigg|_{V_1 = 0}</math>
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| | |
| The network is said to be reciprocal if <math> y_{12} = y_{21}</math>. Notice that all the shunt-connected elements are represented by y-parameters with dimensions of siemens, as are the dependent source parameters.
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| | |
| ==Hybrid parameters (h-parameters) ==
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| {{Image|H-equivalent two-port.PNG|right|350px|H-equivalent two-port showing independent variables ''I<sub>1</sub>'' and ''V<sub>2</sub>''.}}
| |
| The figure shows the two-port driven by two external sources, a current source at port 1 and a voltage source at port 2, making the input current ''I<sub>1</sub>'' and input voltage ''V<sub>2</sub>'' the independent variables controlled from outside the two-port. The voltage at port 1, ''V<sub>1</sub>'', and the current at port 2, ''I<sub>2</sub>'', are determined in terms of these inputs by the ''h''-parameters defined by:
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| :<math> {V_1 \choose I_2} = \begin{pmatrix} h_{11} & h_{12} \\ h_{21} & h_{22} \end{pmatrix}{I_1 \choose V_2} </math>.
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| where
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| :<math>h_{11} = {V_1 \over I_1 } \bigg|_{V_2 = 0} \qquad h_{12} = {V_1 \over V_2 } \bigg|_{I_1 = 0}</math>
| |
| | |
| :<math>h_{21} = {I_2 \over I_1 } \bigg|_{V_2 = 0} \qquad h_{22} = {I_2 \over V_2 } \bigg|_{I_1 = 0}</math>
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| | |
| Often this circuit is selected when a current amplifier is described, because the port 1 input is the independent input current and port 2 output is the dependent current.
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| Notice that off-diagonal h-parameters are dimensionless, while the series-connected diagonal element has dimensions of ohms, while the shunt-connected diagonal element has dimensions of siemens.
| |
| | |
| ===Example: common base amplifier===
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| {{Image|Common base with current drive.PNG|left|200px|Common base circuit with active load and current drive.}}
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| {{Image|Common base with current driver.PNG|right|300px|Common-base amplifier with AC current source ''I<sub>1</sub>'' as signal input and unspecified load supporting voltage ''V<sub>2</sub>'' and a dependent current ''I<sub>2</sub>''.}}
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| The common base amplifier is shown at left. The current source in the collector lead is an ideal DC source, and as such will not allow passage of any varying signal through itself. Its purpose in the circuit is to proved a DC bias current that sets the operating point (the quiescent transistor state about which the transistor varies in processing the signal). A signal ''current'' is applied to the emitter, and an output ''voltage'' is required at the collector. The output node is shown as an open circuit (no load) at the left, but to make use of the amplifier, a load can be attached, which then will draw a signal current from the collector node.
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| The small-signal circuit at the right assumes the voltage at the collector is a specified variable, and the output current is to be determined. The input current at the emitter also is a specified variable, and the signal voltage developed at the emitter is a dependent variable.
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| | |
| Tabulated formulas in Table 2 make the h-equivalent circuit of the transistor agree with the small-signal low-frequency circuit found using the transistor [[hybrid-pi model]] at the right. Notation: ''r<sub>π</sub>'' = base resistance of transistor, ''r<sub>O</sub>'' = output resistance, and ''g<sub>m</sub>'' = transconductance. The negative sign for ''h<sub>21</sub>'' reflects the convention that ''I<sub>1</sub>'', ''I<sub>2</sub>'' are positive when directed ''into'' the two-port. A non-zero value for ''h<sub>12</sub>'' means the output voltage affects the input voltage, that is, this amplifier is '''bilateral'''. If ''h<sub>12</sub>'' = 0, the amplifier is '''unilateral'''.
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| {| class="wikitable" style="background:white;text-align:center;margin: 1em auto 1em auto"
| |
| !Table 2 !! Expression !! Approximation
| |
| | |
| |-valign="center"
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| |<math>h_{21} = \begin{matrix} {I_\mathrm{2} \over I_\mathrm{1} }\end{matrix} \Big|_{V_{2}=0} </math>
| |
| |<math> \begin{matrix} - \frac {\frac {\beta }{\beta+1}r_O +r_E} {r_O+r_E} \end{matrix} </math>
| |
| |<math>\begin{matrix} - \frac {\beta }{\beta+1}\end{matrix} </math>
| |
| | |
| |-valign="center"
| |
| |<math>h_{11}= \begin{matrix} \frac{V_{1}}{I_{1}}\end{matrix} \Big|_{V_{2}=0} </math>
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| |<math> r_E//r_O </math>
| |
| |<math>r_E</math>
| |
| | |
| |-valign="center"
| |
| |<math> h_{22} = \begin{matrix} \frac{I_{2}}{V_{2}}\end{matrix} \Big|_{I_{1}=0} </math>
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| |<math> \begin{matrix} \frac {1} {( \beta +1) ( r_O +r_E)} \end{matrix} </math>
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| |<math> \begin{matrix} \frac {1} {( \beta +1) r_O } \end{matrix} </math>
| |
| | |
| |-valign="center"
| |
| |<math> h_{12} = \begin{matrix} {V_\mathrm{1} \over V_\mathrm{2} }\end{matrix} \Big|_{I_{1}=0} </math>
| |
| |<math>\ \begin{matrix} \frac {r_E} {r_E+r_O} \end{matrix} \ </math>
| |
| |<math>\ \begin{matrix} \frac {r_E} {r_O} \end{matrix} \ </math> << 1
| |
| |}
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| | |
| ==Inverse hybrid parameters (g-parameters)==
| |
| {{Image|G-equivalent two-port.PNG|right|350px| G-equivalent two-port showing independent variables ''V<sub>1</sub>'' and ''I<sub>2</sub>''.}}
| |
| The figure shows the two-port driven by two external sources, a voltage source at port 1 and a current source at port 2, making the input voltage ''V<sub>1</sub>'' and input current ''I<sub>2</sub>'' the independent variables controlled from outside the two-port. The current at port 1, ''I<sub>1</sub>'', and the voltage at port 2, ''V<sub>2</sub>'', are determined in terms of these inputs by the ''g''-parameters defined by:
| |
| | |
| :<math> {I_1 \choose V_2} = \begin{pmatrix} g_{11} & g_{12} \\ g_{21} & g_{22} \end{pmatrix}{V_1 \choose I_2} </math>.
| |
| | |
| where
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| :<math>g_{11} = {I_1 \over V_1 } \bigg|_{I_2 = 0} \qquad g_{12} = {I_1 \over I_2 } \bigg|_{V_1 = 0}</math>
| |
| | |
| :<math>g_{21} = {V_2 \over V_1 } \bigg|_{I_2 = 0} \qquad g_{22} = {V_2 \over I_2 } \bigg|_{V_1 = 0}</math>
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| | |
| Often this circuit is selected to describe a voltage amplifier, as the port 1 input is an independent voltage, and the port 2 output is a dependent voltage. Notice that off-diagonal g-parameters are dimensionless, while the series-connected diagonal element has dimensions of ohms, while the shunt-connected diagonal element has dimensions of siemens.
| |
| | |
| ===Example: [[common base]] amplifier===
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| {{Image|Common base with voltage drive.PNG|left|200px|Bipolar transistor with base grounded and signal applied to emitter.}}
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| {{Image|Small-signal common base circuit.PNG|right|300px|Common-base amplifier with AC voltage source ''V<sub>1</sub>'' as signal input and unspecified load delivering current ''I<sub>2</sub>'' at a dependent voltage ''V<sub>2</sub>''.}}
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| The common base amplifier is shown again at the left. This time, a signal ''voltage'' is applied to the emitter, and an output ''current'' is taken from the collector.
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| The small-signal circuit at the right assumes the current at the collector is a specified variable, and the output voltage is to be determined. The input voltage at the emitter also is a specified variable, and the signal current driven into the emitter is a dependent variable.
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| The tabulated formulas in Table 3 make the g-equivalent two-port for the amplifier agree with the small-signal circuit found using the small-signal low-frequency [[hybrid-pi model]] for the transistor. Notation: ''r<sub>π</sub>'' = base resistance of transistor, ''r<sub>O</sub>'' = output resistance, and ''g<sub>m</sub>'' = transconductance. The negative sign for ''g<sub>12</sub>'' reflects the convention that ''I<sub>1</sub>'', ''I<sub>2</sub>'' are positive when directed ''into'' the two-port. A non-zero value for ''g<sub>12</sub>'' means the output current affects the input current, that is, this amplifier is '''bilateral'''. If ''g<sub>12</sub>'' = 0, the amplifier is '''unilateral'''.
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| {| class="wikitable" style="background:white;text-align:center;margin: 1em auto 1em auto"
| |
| !Table 3 !! Expression
| |
| | |
| |-valign="center"
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| |<math>g_{21} = \begin{matrix} {V_\mathrm{2} \over V_\mathrm{1} }\end{matrix} \Big|_{I_{2}=0} </math>
| |
| |<math> g_m r_O +1 </math>
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| | |
| |-valign="center"
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| |<math>g_{11}= \begin{matrix} \frac{I_{1}}{V_{1}}\end{matrix} \Big|_{I_{2}=0} </math>
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| |<math> \begin{matrix} \frac {1} {r_{\pi}} \end{matrix} </math>
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| | |
| |-valign="center"
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| |<math> g_{22} = \begin{matrix} \frac{V_{2}}{I_{2}} \Big|_{V_{1}=0} \end{matrix}</math>
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| |<math> r_O </math>
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| | |
| |-valign="center"
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| |<math> g_{12} = \begin{matrix} {I_\mathrm{1} \over I_\mathrm{2} }\end{matrix} \Big|_{V_{1}=0} </math>
| |
| |<math> -1 </math>
| |
| |}
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| ==References==
| |
| {{reflist|refs=
| |
| | |
| <ref name=Gray> | |
| {{cite book | | {{cite book |
| |author=P.R. Gray, P.J. Hurst, S.H. Lewis, and R.G. Meyer | | |author=W. M. C. Sansen |
| |title=Analysis and Design of Analog Integrated Circuits | | |title=Analog Design Essentials |
| |year= 2001 | | |year= 2006 |
| |edition=Fourth Edition
| | |page=§0124, p. 13 |
| |publisher=Wiley
| | |publisher=Springer |
| |location=New York
| | |location=Dordrechtμ |
| |isbn=0471321680
| | |isbn=0-387-25746-2 |
| |pages=§3.2, p. 172 | | |url=http://worldcat.org/isbn/0387257462}} |
| |url=http://worldcat.org/isbn/0471321680}}
| |
| </ref>
| |
| | |
| <ref name=Jaeger>
| |
| {{cite book
| |
| |author=R. C. Jaeger and T. N. Blalock
| |
| |title=Microelectronic Circuit Design
| |
| |year= 2006
| |
| |edition=Third Edition
| |
| |publisher=McGraw-Hill | |
| |location=Boston | |
| |isbn=9780073191638 | |
| |pages=§10.5 §13.5 §13.8
| |
| |url=http://worldcat.org/isbn/9780073191638}} | |
| </ref>
| |
| | |
| <ref name=Jasper>
| |
| See review by {{cite web |url=http://www.ieee.org/organizations/pubs/newsletters/emcs/summer03/jasper.pdf |author= Jasper J. Goedbloed |title=Reciprocity and EMC measurements |work=Presentation at 2003 EMC Zurich Symposium ''and as'' IEEE EMC EMCS Newsletter |year=2003 |pages=pp.93-104 }}</ref>
| |
| </ref>
| |
| | |
| <ref name=feedback>
| |
| | |
| The emitter-leg resistors counteract any current increase by decreasing the transistor ''V<sub>BE</sub>''. That is, the resistors ''R<sub>E</sub>'' cause negative feedback that opposes change in current. In particular, any change in output voltage results in less change in current than without this feedback, which means the output resistance of the mirror has increased.
| |
| | |
| </ref> | | </ref> |
| | :::<math> \lambda =\begin{matrix} \frac {1}{V_E L} \end{matrix} </math>. |
| | Here ''V<sub>E</sub>'' is a technology related parameter (about 4 V / μm for the [[65 nanometer|65 nm]] technology node<ref name = Sansen/>) and ''L'' is the length of the source-to-drain separation. |
|
| |
|
| <ref name=Pozar>{{cite book | | The reciprocal of the output resistance is named the '''drain conductance''' |
| | author = David M. Pozar
| | *<math>g_{ds} = \frac {1} {r_O} </math>. |
| | title = Microwave Engineering
| |
| |edition = 3rd Edition
| |
| | publisher = John Wiley & Sons
| |
| | year = 2005
| |
| | chapter=Chapter 4: Microwave network analysis
| |
| | pages = pp. 161-221
| |
| | isbn = 047164451X (Softcover)
| |
| |url=http://www.amazon.com/gp/reader/047164451X/ref=sib_dp_pt/104-7406128-1988732#reader-link}}
| |
| </ref> | |
|
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|
| | ==References and notes== |
|
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|
| }} | | {{reflist}} |