User:John R. Brews/Circuits

Widlar current source using bipolar transistors

Small-signal circuit for finding output resistance of the Widlar source

Design trade-off between output resistance and output current in Widlar source

A current mirror implemented with npn bipolar transistors using a resistor to set the reference current I_REF; V_CC = supply voltage.

An n-channel MOSFET current mirror with a resistor to set the reference current

Gain-boosted current mirror with op amp feedback to increase output resistance.

MOSFET version of wide-swing current mirror; M₁ and M₂ are in active mode

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.

A digital inverter circuit using a bipolar transistor.

Transfer characteristic of bipolar inverter showing modes.

Collector current vs. input voltage for a bipolar inverter with V_CC=5V and R_C=1kΩ.

Input and output signals for bipolar inverter used as an amplifier.

Two-port network with symbol definitions.

Z-equivalent two port showing independent variables I₁ and I₂.

Y-equivalent two port showing independent variables

H-equivalent two-port showing independent variables

G-equivalent two-port showing independent variables

Block diagram for asymptotic gain model

Possible signal-flow graph for the asymptotic gain model

MOSFET transresistance feedback amplifier.

Collector-to-base biased bipolar amplifier.

Two-transistor feedback amplifier; any source impedance R_S is lumped in with the base resistor R_B.

Small-signal circuit for pn-diode driven by a current signal represented as a Norton source.

Bipolar current mirror with emitter resistors

Small-signal circuit for bipolar current mirror

Common base circuit with active load and current drive.

Common-base amplifier with AC current source I₁ as signal input

Bipolar transistor with base grounded and signal applied to emitter.

Common-base amplifier with AC voltage source V₁ as signal input

The result of applying Norton's theorem.

Bipolar current buffer.

Small-signal circuit to find output current.

Small-signal circuit with test current i_X to find Norton resistance.

The result of applying Thévenin's theorem.

Bipolar buffer.

Small-signal circuit for voltage follower.

Determination of the small-signal output resistance.

Simplified, low-frequency hybrid-pi BJT model.

Bipolar hybrid-pi model with parasitic capacitances.

Simplified, low-frequency hybrid-pi BJT model.

Bipolar hybrid-pi model with parasitic capacitances.

Simplified, three-terminal MOSFET hybrid-pi model.

Four-terminal small-signal MOSFET circuit.

Miller effect: These two circuits are equivalent.

Small-signal circuit for transresistance amplifier

Small-signal circuit with return path broken and test current i_t driving amplifier at the break.

Three small-signal schematics used to discuss the asymptotic gain model

Left - small-signal circuit corresponding to bipolar amplifier; Center - inserting independent source and marking leads to be cut; Right - cutting the dependent source free and short-circuiting broken leads.

Some terms used to describe step response in time domain.

Ideal negative feedback model; open loop gain is A_OL and feedback factor is β.

Conjugate pole locations for step response of two-pole feedback amplifier.

Step-response of a linear two-pole feedback amplifier.

Step response for three values of time constant ratio.

Bode gain plot to find phase margin of two-pole amplifier.

The Bode plot for a first-order (one-pole) highpass filter

The Bode plot for a first-order (one-pole) lowpass filter

Bode magnitude plot for zero and for low-pass pole

Bode phase plot for zero and for low-pass pole

Bode magnitude plot for pole-zero combination; the location of the zero is ten times higher than in above figures

Bode phase plot for pole-zero combination; the location of the zero is ten times higher than in above figures

Gain of feedback amplifier A_FB in dB and corresponding open-loop amplifier A_OL.

Phase of feedback amplifier °A_FB in degrees and corresponding open-loop amplifier °A_OL.

Gain of feedback amplifier A_FB in dB and corresponding open-loop amplifier A_OL.

Phase of feedback amplifier A_FB in degrees and corresponding open-loop amplifier A_OL.

Operational amplifier with compensation capacitor C_C between input and output to cause pole splitting.

Operational amplifier with compensation capacitor transformed using Miller's theorem to replace the compensation capacitor with a Miller capacitor at the input and a frequency-dependent current source at the output.

Idealized Bode plot for a two pole amplifier design.

Miller capacitance at low frequencies C_M (top) and compensation capacitor C_C (bottom) as a function of gain