Nullor

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In electronics, a nullor is a theoretical two-port network composed of a nullator at its input and a norator at its output.^[1] Nullors represent an ideal amplifier, having infinite current, voltage, transconductance and transimpedance gain.^[2] Its transmission parameters are all zero, that is, its input-output behavior is summarized with the matrix:

${\displaystyle {\begin{pmatrix}v_{i}\\i_{i}\end{pmatrix}}={\begin{pmatrix}0&0\\0&0\end{pmatrix}}{\begin{pmatrix}v_{o}\\i_{o}\end{pmatrix}}\ .}$

That is, any non-zero input v_i, i_i leads to infinite output v_o, i_o. Consequently the nullor makes sense only in a feedback network. In negative feedback circuits, the circuit surrounding the nullor determines the nullor output in such a way as to force the nullor input to zero.

Inserting a nullor in a circuit schematic imposes mathematical constraints on how that circuit must behave, forcing the circuit itself to adopt whatever arrangements are needed to meet the conditions. For example, an ideal op amp can be modeled using a nullor,^[3] and the textbook analysis of a feedback circuit using an ideal op amp uses the mathematical conditions imposed by the nullor to analyze the circuit surrounding the op amp.

Example: voltage-controlled current sink

(PD) Image: John R. Brews
Operational-amplifier based current sink. Because the op amp is modeled as a nullor, op amp input variables are zero regardless of the values for its output variables.

The figure shows a voltage-controlled current sink.^[4] The sink is intended to draw the same current i_OUT regardless of the applied voltage V_CC at the output. The value of current drawn is to be set by the input voltage v_IN. Here the sink is to be analyzed by idealizing the op amp as a nullor.

Using properties of the input nullator portion of the nullor, the input voltage across the op amp input terminals is zero. Consequently, the voltage across reference resistor R_R is the applied voltage v_IN, making the current in R_R simply v_IN / R_R. Again using the nullator properties, the input current to the nullor is zero. Consequently, Kirchhoff's current law at the emitter provides an emitter current of v_IN / R_R. Using properties of the norator output portion of the nullor, the nullor provides whatever current is demanded of it, regardless of the voltage at its output. In this case, it provides the transistor base current i_B. Thus, Kirchhoff's current law applied to the transistor as a whole provides the output current drawn through resistor R_C as:

${\displaystyle i_{OUT}={\frac {v_{IN}}{R_{R}}}-i_{B}\ ,}$

where the base current of the bipolar transistor i_B is normally negligible provided the transistor remains in active mode. That is, based upon the idealization of a nullor, the output current is controlled by the user-applied input voltage v_IN and the designer's choice for the reference resistor R_R.

Without the transistor, the current through R_C would be:

${\displaystyle i_{OUT}=(V_{CC}-v_{IN})/R_{C}\ ,}$

which interferes with the design goal of independence of i_OUT from V_CC. With the transistor in place, the output current is given as indicated earlier, and the collector-emitter voltage adjusts to force agreement with the Ohm's law result, that is:

${\displaystyle i_{OUT}={\frac {v_{IN}}{R_{R}}}-i_{B}\ ={\frac {V_{CC}-v_{CE}-v_{IN}}{R_{C}}}\ .}$

This equation indicates a limitation of the circuit: as i_OUT is increased, the collector-emitter voltage of the transistor is reduced, and at some point the transistor will leave its active mode and enter saturation (the collector-base junction becomes forward biased). That is, for proper operation of the circuit, the current output is limited. Likewise, as R_C is increased, keeping i_OUT fixed, at some point the transistor will leave its active mode and enter saturation. In other words, the maximum output resistance of this circuit is limited. Ideally, the output resistance of this circuit viewed as a current sink would be infinite, as that would make it an ideal Norton current sink.

Another practical advantage of the transistor is that the op amp must deliver only the small transistor base current, which is unlikely to tax the op amp's current delivery capability. Of course, only real op amps are current-limited, not nullors.

The remaining variation of the current with the voltage V_CC is due to the Early effect in the transistor, which causes the β of the transistor to change with its collector-to-base voltage V_CB according to the relation β = β₀ ( 1 + V_CB / V_A ), where V_A is the so-called Early voltage. Analysis based upon a nullor leads to the output resistance of this current sink as R_out = r_O ( β + 1 ) + R_C , where r_O is the small-signal transistor output resistance given by r_O = ( V_A + V_CB ) / i_out. See current mirror for the analysis.

Use of the nullor idealization allows design of the circuitry around the op amp. The practical problem remains of designing an op amp that behaves like a nullor.

References