Load line (electronics): Difference between revisions

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			{{Short description\|Graphical analysis tool for electronic circuit engineering}}
	The '''load line''' of a ] circuit shows the voltage-current characteristic (V-I Graph) of that particular circuit or configuration, over a range of Base currents. As the Collector-Emitter Voltage (V<sub>CE</sub>) varies from zero to its maximum value, the current at the Collector varies accordingly. It must be noted that this is the '']'' load line for the circuit for a fixed load. The saturation current and cutoff voltage determine the intersections of the graph on the Y and X axes respectively. Intersections of the base voltage curves with the I<sub>C</sub>-V<sub>CE</sub> graph indicate realistic operating conditions for those base currents.
			]In graphical analysis of ] ]s, a '''load line''' is a line drawn on the ] graph for a ] like a ] or ]. It represents the constraint put on the ] and ] in the nonlinear device by the external circuit. The load line, usually a straight line, represents the response of the ] part of the circuit, connected to the nonlinear device in question. The points where the characteristic curve and the load line ] are the possible ](s) (]s) of the circuit; 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 ] circuit. The diode, a nonlinear device, is in series with a linear circuit consisting of a ], R and a ] source, V<sub>DD</sub>. The characteristic curve ''(curved line)'', representing the current ''I'' through the diode for any given voltage across the diode ''V''<sub>D</sub>, is an exponential curve. The load line ''(diagonal line)'', representing the relationship between current and voltage due to ] applied to the resistor and voltage source, is
			:<math>V_D = V_{DD} - I R \,</math>
			Since the same current flows through each of the three elements in series, and the voltage produced by the voltage source and resistor is the voltage across the terminals of the diode, the operating point of the circuit will be at the intersection of the curve with the load line.

			In a circuit with a three terminal device, such as a ], the current–voltage curve of the collector-emitter current depends on the base current. This is depicted on graphs by a series of (I<sub>C</sub>–V<sub>CE</sub>) curves at different base currents. A load line drawn on this graph shows how the base current will affect the operating point of the circuit.

	== Load lines for common configurations ==		== Load lines for common configurations ==

	=== ~~Common-Emitter~~ ===		=== Transistor load line ===
			]
	The given load line diagram is for the ] configuration. ]The load line diagram illustrates all possible values of collector current (I<sub>C</sub>) and the collector voltage (V<sub>CE</sub> in this case) for a given load resistor (R<sub>C</sub>).

			The load line diagram at right is for a resistive load in a ] circuit. The load line shows how the collector load resistor (R<sub>L</sub>) constrains the circuit voltage and current. The diagram also plots the transistor's collector current ''I''<sub>C</sub> versus collector voltage ''V''<sub>CE</sub> for different values of base current ''I''<sub>base</sub>. The intersections of the load line with the transistor characteristic curves represent the circuit-constrained values of ''I''<sub>C</sub> and ''V''<sub>CE</sub> at different base currents.<ref name=MY73> Maurice Yunik, ''Design of Modern Transistor Circuits'', Prentice-Hall Inc., 1973 {{ISBN\|0-13-201285-5}} section 4.6 "Load Line Analysis" pp. 68-73 </ref>
	The point on the load line where it intersects the collector current axis is referred to as ''saturation point''. 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>.

			If the transistor could pass all the current available, with no voltage dropped across it, the collector current would be the supply voltage V<sub>CC </sub>over R<sub>L</sub>. This is the point where the load line crosses the vertical axis. Even at saturation, however, there will always be some voltage from collector to emitter.
	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>.

			Where the load line crosses the horizontal axis, the transistor current is minimum (approximately zero). The transistor is said to be cut off, passing only a very small leakage current, and so very nearly the entire supply voltage appears as V<sub>CE</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 ] applications.

			The ''operating point'' of the circuit in this configuration (labelled Q) is generally designed to be in the ''active region'', approximately in the middle of the load line's active region for ] applications. Adjusting the base current so that the circuit is at this operating point with no signal applied is called ]. Several techniques are used to stabilize the operating point against minor changes in temperature or transistor operating characteristics. When a signal is applied, the base current varies, and the collector-emitter voltage in turn varies, following the load line - the result is an amplifier stage with gain.

			A load line is normally drawn on I<sub>c</sub>-V<sub>ce</sub> characteristics curves for the transistor used in an amplifier circuit. The same technique is applied to other types of non-linear elements such as ]s or ]s.

			==DC and AC load lines==
			] circuits typically have both ] and ] currents in them, with a source of DC current to ] 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 ], defined by reducing the reactive components to zero (replacing capacitors by open circuits and inductors by short circuits). It is used to determine the correct DC operating point, often called the ].

			Once a DC operating point is defined by the DC load line, an AC load line can be drawn through the Q point. The AC load line is a straight line with a slope equal to the AC ] facing the nonlinear device, which is in general different from the DC resistance. The ratio of AC voltage to current in the device is defined by this line. 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.

	==References==		==References==
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			<references/>
	{{electronics-stub}}

			]

Latest revision as of 20:37, 26 April 2023

Graphical analysis tool for electronic circuit engineering

In graphical analysis of nonlinear electronic circuits, a load line is a line drawn on the current–voltage characteristic graph for a nonlinear device like a diode or transistor. It represents the constraint put on the voltage and current in the nonlinear device by the external circuit. The load line, usually a straight line, represents the response of the linear part of the circuit, connected to the nonlinear device in question. The points where the characteristic curve and the load line intersect are the possible operating point(s) (Q points) of the circuit; at these points the current and voltage parameters of both parts of the circuit match.

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_DD. The characteristic curve (curved line), representing the current I through the diode for any given voltage across the diode V_D, is an exponential curve. The load line (diagonal line), representing the relationship between current and voltage due to Kirchhoff's voltage law applied to the resistor and voltage source, is

V_{D}=V_{DD}-IR\,

Since the same current flows through each of the three elements in series, and the voltage produced by the voltage source and resistor is the voltage across the terminals of the diode, the operating point of the circuit will be at the intersection of the curve with the load line.

In a circuit with a three terminal device, such as a transistor, the current–voltage curve of the collector-emitter current depends on the base current. This is depicted on graphs by a series of (I_C–V_CE) curves at different base currents. A load line drawn on this graph shows how the base current will affect the operating point of the circuit.

Load lines for common configurations

Transistor load line

The load line diagram at right is for a resistive load in a common emitter circuit. The load line shows how the collector load resistor (R_L) constrains the circuit voltage and current. The diagram also plots the transistor's collector current I_C versus collector voltage V_CE for different values of base current I_base. The intersections of the load line with the transistor characteristic curves represent the circuit-constrained values of I_C and V_CE at different base currents.

If the transistor could pass all the current available, with no voltage dropped across it, the collector current would be the supply voltage V_CCover R_L. This is the point where the load line crosses the vertical axis. Even at saturation, however, there will always be some voltage from collector to emitter.

Where the load line crosses the horizontal axis, the transistor current is minimum (approximately zero). The transistor is said to be cut off, passing only a very small leakage current, and so very nearly the entire supply voltage appears as V_CE.

The operating point of the circuit in this configuration (labelled Q) is generally designed to be in the active region, approximately in the middle of the load line's active region for amplifier applications. Adjusting the base current so that the circuit is at this operating point with no signal applied is called biasing the transistor. Several techniques are used to stabilize the operating point against minor changes in temperature or transistor operating characteristics. When a signal is applied, the base current varies, and the collector-emitter voltage in turn varies, following the load line - the result is an amplifier stage with gain.

A load line is normally drawn on I_c-V_ce characteristics curves for the transistor used in an amplifier circuit. The same technique is applied to other types of non-linear elements such as vacuum tubes or field effect transistors.

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 short 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 can be drawn through the Q point. The AC load line is a straight line with a slope equal to the AC impedance facing the nonlinear device, which is in general different from the DC resistance. The ratio of AC voltage to current in the device is defined by this line. 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.

References

Adel Sedra, Kenneth Smith. Microelectronic Circuits, 5th ed.
Maurice Yunik, Design of Modern Transistor Circuits, Prentice-Hall Inc., 1973 ISBN 0-13-201285-5 section 4.6 "Load Line Analysis" pp. 68-73

Category:

Electrical engineering