All public circuits

Now showing circuits 21301-21320 of 53077. Sort by

	Idea for Bench Test Speaker 1 PUBLIC by fas11030 \| updated October 23, 2021
	ideal PUBLIC by nbpadilha \| updated April 19, 2013
	ideal ammeter with input impedance PUBLIC by Kivugo \| updated May 19, 2015
	Ideal charger by npn for thartley PUBLIC by cje26 \| updated March 25, 2014
	Ideal Current Source DC Sweep PUBLIC An ideal current source does not change in current as its terminal voltage difference is changed. by UltimateElectronics \| updated December 23, 2020
	ideal diode PUBLIC by bytemanP \| updated June 07, 2012
	ideal diode circuit_1 PUBLIC by shaohsi \| updated May 06, 2015
	ideal diode circuit_2 PUBLIC by shaohsi \| updated May 06, 2015
	ideal diode circuit_3 PUBLIC by shaohsi \| updated May 06, 2015
	ideal diode circuit_4 PUBLIC by shaohsi \| updated May 06, 2015
	Ideal Diode Full-Wave Rectifier PUBLIC by mrobbins \| updated August 08, 2020
	Ideal Diode vs PN Junction Diode Comparison PUBLIC by mrobbins \| updated August 08, 2020
	Ideal Gyrator 01 PUBLIC An Ideal Gyrator model. This example shows a capacitor being gyrated into an inductor. A real inductor is shown for reference and the effect of varying the gyrator ratio is illustrated by the sweep.... by signality \| updated May 16, 2012 behavioural-inductor gyrator
	Ideal Gyrator 02 PUBLIC An Ideal Gyrator model. This example shows an inductor being gyrated into a capacitor. A real capacitor is shown for reference and the effect of varying the gyrator ratio is illustrated by the sweep.... by signality \| updated May 16, 2012 behavioural-capacitor gyrator
	Ideal Op-Amp as VCVS PUBLIC The ideal op-amp works like a Voltage Controlled Voltage Source (VCVS), where the output voltage is equal to the difference in input voltages multiplied by a large open-loop gain. by UltimateElectronics \| updated December 23, 2020
	Ideal Op-Amp Subtraction and Multiplication PUBLIC The ideal op-amp essentially produces its output voltage by subtracting the voltage difference between its inputs, and multiplying this difference by a large open-loop gain. by UltimateElectronics \| updated December 23, 2020
	Ideal Op-Amp Symbol PUBLIC The ideal op-amp has three terminals: non-inverting (+) input, inverting (-) input, and output. by UltimateElectronics \| updated December 23, 2020
	Ideal Op-Amp with Finite Gain and Gain-Bandwidth Product: Laplace Block Model PUBLIC The frequency response of a real op-amp is well modeled with two parameters: an open-loop DC gain, and a gain-bandwidth product. These two parameters can be modeled in a single Laplace Block. by UltimateElectronics \| updated December 23, 2020
	Ideal Op-Amp with Finite Gain: Laplace Block Model PUBLIC An ideal op-amp with finite gain can be modeled using a Laplace Block to represent the open-loop gain. by UltimateElectronics \| updated December 23, 2020
	Ideal Op-Amp with Voltage Rails Symbol PUBLIC Op-amps have positive and negative voltage rails which limit the ability of the output to swing too high or too low. This can result in clipping. by UltimateElectronics \| updated December 23, 2020

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555 7805 ac-to-dc active-filter amplifier analog and anode attenuator atx audio automotive band-reject bandgap behavioral bias-point bjt bode bridge-rectifier button calculator cascaded-filters cascode cathode cmos colpitts compensation constant-current-source current-limiting current-mirror current-monitor current-regulator dac dc-to-ac device-modeling differential differentiator digital diode divider emitter-follower feedback filter flyback flyback-diode frequency-domain full-wave guitar ham-radio high-pass high-speed high-voltage hv hysteresis ic ignition-coil induction inductive inductive-load initial-conditions instrumentation-amplifier integrator inverting jfet laplace led led-array level-shift lighting lipo lm317 load-cell logic-gate low-pass mechanical microcontroller microphone mosfet motor multivibrator non-inverting nonlinear nor notch ohms-law op-amp optical or oscillator parallel passive passive-filter pcb-design phase-shift photodiode photoresistor phototransistor piezo plants potentiometer power power-supply power-supply-unit preamp pull-down pull-up pwm rc relaxation-oscillator relay resistor-ladder resonance rf rlc rom saturation schmitt-trigger sensor series servo-motor signal spark-plug stability stepper summing superposition switching time-constant transformer transistor translinear twin-t voltage-divider voltage-regulator waveform-arithmetic wiring xnor xor zener-diode zero-voltage-switching

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	Idea for Bench Test Speaker 1 PUBLIC by fas11030 \| updated October 23, 2021
	ideal PUBLIC by nbpadilha \| updated April 19, 2013
	ideal ammeter with input impedance PUBLIC by Kivugo \| updated May 19, 2015
	Ideal charger by npn for thartley PUBLIC by cje26 \| updated March 25, 2014
	Ideal Current Source DC Sweep PUBLIC An ideal current source does not change in current as its terminal voltage difference is changed. by UltimateElectronics \| updated December 23, 2020
	ideal diode PUBLIC by bytemanP \| updated June 07, 2012
	ideal diode circuit_1 PUBLIC by shaohsi \| updated May 06, 2015
	ideal diode circuit_2 PUBLIC by shaohsi \| updated May 06, 2015
	ideal diode circuit_3 PUBLIC by shaohsi \| updated May 06, 2015
	ideal diode circuit_4 PUBLIC by shaohsi \| updated May 06, 2015
	Ideal Diode Full-Wave Rectifier PUBLIC by mrobbins \| updated August 08, 2020
	Ideal Diode vs PN Junction Diode Comparison PUBLIC by mrobbins \| updated August 08, 2020
	Ideal Gyrator 01 PUBLIC An Ideal Gyrator model. This example shows a capacitor being gyrated into an inductor. A real inductor is shown for reference and the effect of varying the gyrator ratio is illustrated by the sweep.... by signality \| updated May 16, 2012 behavioural-inductor gyrator
	Ideal Gyrator 02 PUBLIC An Ideal Gyrator model. This example shows an inductor being gyrated into a capacitor. A real capacitor is shown for reference and the effect of varying the gyrator ratio is illustrated by the sweep.... by signality \| updated May 16, 2012 behavioural-capacitor gyrator
	Ideal Op-Amp as VCVS PUBLIC The ideal op-amp works like a Voltage Controlled Voltage Source (VCVS), where the output voltage is equal to the difference in input voltages multiplied by a large open-loop gain. by UltimateElectronics \| updated December 23, 2020
	Ideal Op-Amp Subtraction and Multiplication PUBLIC The ideal op-amp essentially produces its output voltage by subtracting the voltage difference between its inputs, and multiplying this difference by a large open-loop gain. by UltimateElectronics \| updated December 23, 2020
	Ideal Op-Amp Symbol PUBLIC The ideal op-amp has three terminals: non-inverting (+) input, inverting (-) input, and output. by UltimateElectronics \| updated December 23, 2020
	Ideal Op-Amp with Finite Gain and Gain-Bandwidth Product: Laplace Block Model PUBLIC The frequency response of a real op-amp is well modeled with two parameters: an open-loop DC gain, and a gain-bandwidth product. These two parameters can be modeled in a single Laplace Block. by UltimateElectronics \| updated December 23, 2020
	Ideal Op-Amp with Finite Gain: Laplace Block Model PUBLIC An ideal op-amp with finite gain can be modeled using a Laplace Block to represent the open-loop gain. by UltimateElectronics \| updated December 23, 2020
	Ideal Op-Amp with Voltage Rails Symbol PUBLIC Op-amps have positive and negative voltage rails which limit the ability of the output to swing too high or too low. This can result in clipping. by UltimateElectronics \| updated December 23, 2020

Idea for Bench Test Speaker 1 PUBLIC

ideal PUBLIC

ideal ammeter with input impedance PUBLIC

Ideal charger by npn for thartley PUBLIC

Ideal Current Source DC Sweep PUBLIC

ideal diode PUBLIC

ideal diode circuit_1 PUBLIC

ideal diode circuit_2 PUBLIC

ideal diode circuit_3 PUBLIC

ideal diode circuit_4 PUBLIC

Ideal Diode Full-Wave Rectifier PUBLIC

Ideal Diode vs PN Junction Diode Comparison PUBLIC

Ideal Gyrator 01 PUBLIC

Ideal Gyrator 02 PUBLIC

Ideal Op-Amp as VCVS PUBLIC

Ideal Op-Amp Subtraction and Multiplication PUBLIC

Ideal Op-Amp Symbol PUBLIC

Ideal Op-Amp with Finite Gain and Gain-Bandwidth Product: Laplace Block Model PUBLIC

Ideal Op-Amp with Finite Gain: Laplace Block Model PUBLIC

Ideal Op-Amp with Voltage Rails Symbol PUBLIC

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