UltimateElectronics's Profile

UltimateElectronics's Public Circuits:

Now showing circuits 21-40 of 52. Sort by recently modified name

	DC Sweep of First-Order Non-Ideal Current Source PUBLIC This simulation shows how a finite (not infinite) parallel internal resistance makes a current source behave in a non-ideal way. by UltimateElectronics | updated December 23, 2020
	First-Order Non-Ideal Current Source PUBLIC A non-ideal current source has an finite internal resistance in parallel with the current source. by UltimateElectronics | updated December 23, 2020
	DC Sweep of First-Order Non-Ideal Voltage Source PUBLIC This simulation shows a how a nonzero internal resistance makes a voltage source be non-ideal. by UltimateElectronics | updated December 23, 2020
	First-Order Non-Ideal Voltage Source PUBLIC A non-ideal voltage source has a nonzero internal resistance. by UltimateElectronics | updated December 23, 2020
	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 Voltage Source DC Sweep PUBLIC An ideal voltage source does not change voltage under a variable current load. by UltimateElectronics | updated December 23, 2020
	Ideal Voltage and Current Source Symbols PUBLIC The schematic symbols for the ideal voltage source and ideal current source are shown and labeled. 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
	Op-Amp with Voltage Rails as Analog Comparator PUBLIC The op-amp with voltage rails can be used as an analog voltage comparator by connecting the two voltages to be compared to the op-amp's two inputs. by UltimateElectronics | updated December 23, 2020
	Op-Amp With and Without Voltage Rails DC Sweep Comparison PUBLIC This simulation compares the open-loop DC Sweep behavior of an op-amp with and without voltage rails. 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
	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
	Signal, Earth, Chassis Ground PUBLIC Signal ground, earth ground, and chassis ground are the three most common types of grounding connections you'll see on a schematic. by UltimateElectronics | updated December 23, 2020
	Parallel Plate Capacitor with Interstital Plate PUBLIC When a third plate is inserted between the two plates of a parallel plate capacitor, charges separate in the third plate to cancel the field within itself, and consequently the electric field gets... by UltimateElectronics | updated December 23, 2020
	Parallel Plate Capacitor PUBLIC A parallel plate capacitor has equal and opposite surface charges on the inner surfaces of the two plates, leading to parallel electric field lines in the small gap between the plates. by UltimateElectronics | updated December 23, 2020
	Induced Electrostatic Charge PUBLIC Charges are free to move within conductive materials. This can be taken advantage of by bringing a charged object near a conductive object to create induced charge separation. by UltimateElectronics | updated December 23, 2020
	Voltage Controlled Voltage Source (VCVS) Example PUBLIC In a Voltage Controlled Voltage Source (VCVS), the voltage difference across this element depends on a voltage difference elsewhere in the circuit, multiplied by some gain. by UltimateElectronics | updated December 23, 2020
	Voltage Controlled Current Source (VCCS) Example PUBLIC A Voltage Controlled Current Source (VCCS) has a current equal to some voltage difference elsewhere in the circuit multiplied by a gain. by UltimateElectronics | updated December 23, 2020