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[[Image:Load line diode.png|thumb|300px|Diode load line. The curve shows the diode response (I vs V<sub>D</sub>) while the straight line shows the behaviour of the linear part of the circuit: I=(V<sub>DD</sub>-V<sub>D</sub>)/R. The point of intersection gives the actual current and voltage.]] | |||
A '''load line''' is used in graphical analysis of [[linear circuit|nonlinear]] [[electronic circuit]]s, representing the constraint other parts of the circuit place on a [[Nonlinear device|non-linear]] device, like a [[diode]] or [[transistor]]. It is usually drawn on a graph of the [[electric current|current]] vs the [[voltage]] in the nonlinear device, called the device's [[Electronics|characteristic curve]]. A load line, usually a straight line, represents the response of the [[linear circuit|linear]] part of the circuit, connected to the nonlinear device in question. The operating point(s) of the circuit are the points where the characteristic curve and the load line intersect; at these points the current and voltage parameters of both parts of the circuit match.<ref>Adel Sedra, Kenneth Smith. Microelectronic Circuits, 5th ed.</ref> | |||
The example at right shows how a load line is used to determine the current and voltage in a simple [[diode]] circuit. The diode, a nonlinear device, is in series with a linear circuit consisting of a [[resistor]], R and a [[voltage]] source, V<sub>DD</sub>. The characteristic curve ''(curved line)'', representing current ''I'' through the diode versus voltage across the diode ''V''<sub>D</sub>, is an exponential curve. The load line ''(diagonal line)'' represents the relationship between current and voltage due to [[Kirchhoff's voltage law]] applied to the resistor and voltage source, is | |||
:<math>V_D = V_{DD} - I R \,</math> | |||
Since the current going through the three elements in series must be the same, and the voltage at the terminals of the diode must be the same, the operating point of the circuit will be at the intersection of the curve with the load line. | |||
In a [[Bipolar junction transistor|BJT]] circuit, the BJT has a different current-voltage (I<sub>C</sub>-V<sub>CE</sub>) characteristic depending on the base current. Placing a series of these curves on the graph shows how the base current will affect the operating point of the circuit. | |||
==DC and AC load lines== | |||
[[Semiconductor]] circuits typically have both [[direct current|DC]] and [[alternating current|AC]] currents in them, with a source of DC current to [[biasing|bias]] the nonlinear semiconductor to the correct operating point, and the AC signal superimposed on the DC. Load lines can be used separately for both DC and AC analysis. The DC load line is the load line of the DC [[equivalent circuit]], defined by reducing the reactive components to zero (replacing capacitors by open circuits and inductors by closed circuits). It is used to determine the correct DC operating point, often called the [[biasing|Q point]]. | |||
Once a DC operating point is defined by the DC load line, an AC load line with, in general, a different slope can be drawn, through the DC operating point, to calculate the AC output. Because the impedance of the reactive components will vary with frequency, the slope of the AC load line depends on the frequency of the applied signal. So there are many AC load lines, that vary from the DC load line (at low frequency) to a limiting AC load line, all having a common intersection at the dc operating point. This limiting load line, generally referred to as the ''AC load line'', is the load line of the circuit at "infinite frequency", and can be found by replacing capacitors with short circuits, and inductors with open circuits. | |||
== Load lines for common configurations == | |||
=== Transistor load line === | |||
[[Image:common emitter load line.PNG|thumb|400px|Common emitter transistor load line.]] | |||
The load line diagram at right is for a transistor connected in a [[common emitter]] circuit. It shows the collector current in the transistor ''I''<sub>C</sub> versus collector voltage ''V''<sub>CE</sub> for different values of base current ''I''<sub>base</sub>. The load line represents a particular value of collector load resistor (R<sub>C</sub>). The intersections of the load line with the transistor characteristic curve represent the different values of ''I''<sub>C</sub> and ''V''<sub>CE</sub> at different base currents. | |||
The point on the load line where it intersects the collector current axis is referred to as ''saturation point''.<ref>Assuming an ideal transistor.</ref> At this point, the transistor current is maximum and voltage across collector is minimum, for a given load. For this circuit, I<sub>C-SAT</sub>= V<sub>CC</sub>/R<sub>C</sub>.<ref>Assuming Vce = 0 for an ideal transistor, so for the ideal transistor the voltage over R<sub>C</sub> equals V<sub>CC</sub> at this point on the load line.</ref> | |||
The ''cutoff point '' is the point where the load line intersects with the collector voltage axis. Here the transistor current is minimum (approximately zero) and emitter is grounded. Hence V<sub>CE-CUTOFF</sub>=V<sub>cc</sub>. | |||
The ''operating point'' of the circuit in this configuration is generally designed to be in the ''active region'', approximately between middle of the load line and close to saturation point. In this region, the collector current is proportional to the base current, and hence useful for [[amplifier]] applications. | |||
a load line is normally drawn on ic-vce characteristics curves for the transistor used in amplifier circuit. | |||
==References== | |||
*[http://www.vias.org/feee/bjt_09.html Vias.org] | |||
<references/> | |||
[[Category:Electrical engineering]] |
Latest revision as of 01:29, 7 November 2013
A load line is used in graphical analysis of nonlinear electronic circuits, representing the constraint other parts of the circuit place on a non-linear device, like a diode or transistor. It is usually drawn on a graph of the current vs the voltage in the nonlinear device, called the device's characteristic curve. A load line, usually a straight line, represents the response of the linear part of the circuit, connected to the nonlinear device in question. The operating point(s) of the circuit are the points where the characteristic curve and the load line intersect; at these points the current and voltage parameters of both parts of the circuit match.[1]
The example at right shows how a load line is used to determine the current and voltage in a simple diode circuit. The diode, a nonlinear device, is in series with a linear circuit consisting of a resistor, R and a voltage source, VDD. The characteristic curve (curved line), representing current I through the diode versus voltage across the diode VD, is an exponential curve. The load line (diagonal line) represents the relationship between current and voltage due to Kirchhoff's voltage law applied to the resistor and voltage source, is
Since the current going through the three elements in series must be the same, and the voltage at the terminals of the diode must be the same, the operating point of the circuit will be at the intersection of the curve with the load line.
In a BJT circuit, the BJT has a different current-voltage (IC-VCE) characteristic depending on the base current. Placing a series of these curves on the graph shows how the base current will affect the operating point of the circuit.
DC and AC load lines
Semiconductor circuits typically have both DC and AC currents in them, with a source of DC current to bias the nonlinear semiconductor to the correct operating point, and the AC signal superimposed on the DC. Load lines can be used separately for both DC and AC analysis. The DC load line is the load line of the DC equivalent circuit, defined by reducing the reactive components to zero (replacing capacitors by open circuits and inductors by closed circuits). It is used to determine the correct DC operating point, often called the Q point.
Once a DC operating point is defined by the DC load line, an AC load line with, in general, a different slope can be drawn, through the DC operating point, to calculate the AC output. Because the impedance of the reactive components will vary with frequency, the slope of the AC load line depends on the frequency of the applied signal. So there are many AC load lines, that vary from the DC load line (at low frequency) to a limiting AC load line, all having a common intersection at the dc operating point. This limiting load line, generally referred to as the AC load line, is the load line of the circuit at "infinite frequency", and can be found by replacing capacitors with short circuits, and inductors with open circuits.
Load lines for common configurations
Transistor load line
The load line diagram at right is for a transistor connected in a common emitter circuit. It shows the collector current in the transistor IC versus collector voltage VCE for different values of base current Ibase. The load line represents a particular value of collector load resistor (RC). The intersections of the load line with the transistor characteristic curve represent the different values of IC and VCE at different base currents.
The point on the load line where it intersects the collector current axis is referred to as saturation point.[2] At this point, the transistor current is maximum and voltage across collector is minimum, for a given load. For this circuit, IC-SAT= VCC/RC.[3]
The cutoff point is the point where the load line intersects with the collector voltage axis. Here the transistor current is minimum (approximately zero) and emitter is grounded. Hence VCE-CUTOFF=Vcc.
The operating point of the circuit in this configuration is generally designed to be in the active region, approximately between middle of the load line and close to saturation point. In this region, the collector current is proportional to the base current, and hence useful for amplifier applications. a load line is normally drawn on ic-vce characteristics curves for the transistor used in amplifier circuit.