Common Inductance Terminology – SolveForce Fiber Internet, Cloud Computing & Telecommunications

Air-core Inductor: An inductor that does not have a core, typically made of wire that is wound around a form.
Air-core inductor: An inductor that does not have a magnetic core and instead uses the surrounding air as the medium for the magnetic field.
Air-Core Inductor: An inductor that does not have a magnetic core and relies on the winding of the wire to generate a magnetic field. Air-core inductors have a very high inductance but also have a high resistance to AC current.
Air-core inductor: An inductor that does not use a ferromagnetic core, but instead uses a coil of wire to create a magnetic field.
Air-Core Inductor: An inductor that doesn’t have a core made of a ferromagnetic material. Air-core inductors are used in applications where a high-frequency signal needs to be passed through the coil.
Air-Core Inductor: An inductor that uses air as the core material. Air-core inductors are used in high frequency applications where the core material would introduce significant losses.
Air-cored Inductor: An inductor that does not have a core, typically made of wire that is wound around a form. Air-cored inductors are commonly used in high-frequency applications where the core material would introduce losses.
Auto-transformer: A type of transformer that has one winding that is used as both the primary and secondary winding. It is a special case of a transformer where the primary and secondary windings have a shared part of the coil, so mutual inductance is present between them.
Bullet Point List Inductance Terminology and Related Definitions.
Choke Inductor: An inductor that is used to block high-frequency AC signals while allowing DC signals to pass through. Choke inductors are commonly used in power supplies to filter out high-frequency noise.
Coil: A conductor that is wound in the form of a spiral to create an electromagnetic field. In the context of inductors, it refers to the winding of wire around a core material that creates the inductive effect.
Common-mode Choke: An inductor that is used to suppress common-mode noise in a circuit. Common-mode noise is the noise that is present on both the positive and negative lines of a circuit.
Core Loss: The energy loss that occurs in an inductor due to the properties of the core material.
Current Transformer: A type of transformer that uses the principle of electromagnetic induction to measure the current flowing through a conductor. It consists of a primary coil that surrounds the conductor and a secondary coil that generates a voltage proportional to the current flowing through the primary coil.
Current-mode control: A method of controlling the output of a power electronic circuit by regulating the current flowing through the circuit. Inductors are often used in current-mode control circuits to store energy and release it as needed.
Differential-mode Choke: An inductor that is used to suppress differential-mode noise in a circuit. Differential-mode noise is the noise that is present on one line of a circuit but not the other.
Eddy Current Loss: The energy loss that occurs in an inductor due to circulating currents (eddy currents) induced in the core material by the alternating magnetic field.
Ferrite Core Inductor: An inductor that has a core made of ferrite, a type of ceramic material that has a high permeability and low losses at high frequencies. Ferrite core inductors are commonly used in high-frequency applications such as radio frequency circuits.
Ferrite-core inductor: An inductor that has a magnetic core made of ferrite, a type of ceramic material with magnetic properties.
Ferrite-Core Inductor: An inductor that uses a ferrite material as the core. Ferrite-core inductors are used in a wide range of applications, including radio frequency (RF) and power electronics, due to their high inductance and low losses at high frequency.
Ferrite-Core Inductor: An inductor that uses a magnetic core made of ferrite material to enhance the magnetic field generated by the winding of the wire. Ferrite-core inductors have a lower inductance than iron-core inductors but also have a lower resistance to AC current.
Hybrid Inductive-inductive-capacitive-resistive-resistive (L-L-C-R-R) circuit: An electrical circuit that contains both inductors, more than one inductor, capacitors, resistors and more than one resistor, and can be used to create more complex filter or tune signals, and dampen oscillations.
Hybrid Inductive-inductive-inductive-capacitive-resistive (L-L-L-C-R) circuit: An electrical circuit that contains more than two inductors, capacitors, resistors and can be used to couple energy between different circuits or to create more complex time-delays and dampen oscillations.
Hybrid Inductive-inductive-inductive-resistive-capacitive (L-L-L-R-C) circuit: An electrical circuit that contains more than two inductors, resistors and capacitors, and can be used to couple energy between different circuits or to create more complex time-delays and dampen oscillations.
Hybrid Inductive-inductive-resistive-capacitive-resistive (L-L-R-C-R) circuit: An electrical circuit that contains both inductors, more than one inductor, resistors, capacitors and more than one resistor, and can be used to create more complex filter or tune signals, and dampen oscillations.
Hybrid Inductive-resistive-capacitive-inductive-resistive (L-R-C-L-R) circuit: An electrical circuit that contains both inductors, resistors, capacitors, more than one inductor and more than one resistor, and can be used to create more complex filter or tune signals, and dampen oscillations.
Hybrid Inductive-resistive-inductive-capacitive-resistive (L-R-L-C-R) circuit: An electrical circuit that contains both inductors, resistors, more than one inductor, capacitors and more than one resistor, and can be used to create more complex filter or tune signals, and dampen oscillations.
Hysteresis Loss: The energy loss that occurs in an inductor due to the hysteresis of the magnetic material used in the inductor’s core.
Impedance: The total opposition to the current flow in a circuit, including both resistance and reactance. Inductive reactance is one component of the impedance in an inductive circuit.
Inductance Bridge: A type of bridge circuit that is used to measure the inductance of an unknown inductor. The bridge circuit consists of four arms, one of which contains the unknown inductor and the other three arms contain known inductors or resistance. By adjusting the values of the known components, the value of the unknown inductor can be determined.
Inductance Meter: A type of electronic test instrument that is used to measure the inductance of an unknown inductor. Inductance meters typically use a bridge circuit or an oscillator circuit to make the measurement.
Inductance: The property of an electrical circuit that opposes changes in current. It is measured in units of henrys (H).
Inductive AC Motor Controller: A device used to regulate the speed, torque and other parameters of an inductive AC motor.
Inductive AC Motor Drive with Feedback: A power electronic converter that provides a controlled voltage and frequency to an inductive AC motor and also uses feedback to control the speed, torque and other parameters of the motor.
Inductive AC Motor Drive with Field-oriented Control: A power electronic converter that provides a controlled voltage and frequency to an inductive AC motor and also uses feedback to control the position, speed and torque of the motor with advanced control algorithm which is Field-oriented control.
Inductive AC Motor Drive with Position Control: A power electronic converter that provides a controlled voltage and frequency to an inductive AC motor and also uses feedback to control the position of the motor.
Inductive AC Motor Drive with Speed and Position Control: A power electronic converter that provides a controlled voltage and frequency to an inductive AC motor and also uses feedback to control both the speed and position of the motor.
Inductive AC Motor Drive with Speed Control: A power electronic converter that provides a controlled voltage and frequency to an inductive AC motor and also uses feedback to control the speed of the motor.
Inductive AC Motor Drive with Speed, Position and Torque Control: A power electronic converter that provides a controlled voltage and frequency to an inductive AC motor and also uses feedback to control the speed, position and torque of the motor.
Inductive AC Motor Drive with Torque Control: A power electronic converter that provides a controlled voltage and frequency to an inductive AC motor and also uses feedback to control the torque of the motor.
Inductive AC Motor Drive with Vector Control: A power electronic converter that provides a controlled voltage and frequency to an inductive AC motor and also uses feedback to control the speed, position and torque of the motor with advanced control algorithm which is Vector control.
Inductive AC Motor Drive: A power electronic converter that provides a controlled voltage and frequency to an inductive AC motor.
Inductive AC Motor Soft Starter: A device used to start and stop an inductive AC motor in a smooth and controlled manner to reduce the mechanical stress on the motor and the power system.
Inductive AC Motor Starter: A device used to start and stop an inductive AC motor. Inductive AC motor starters are commonly used in industrial and commercial applications, such as conveyors, pumps, and fans.
Inductive Admittance (YL): The ratio of current to voltage in an inductor. It is measured in siemens (S).
Inductive Amplifier: A type of electronic circuit that uses an inductor to increase the amplitude of a signal. Inductive amplifiers are used in applications such as radio communications and audio equipment.
Inductive Amplifier: An electronic circuit that uses the principle of electromagnetic induction to amplify a signal. Inductive amplifiers are used in many applications such as audio, instrumentation, and RF communication systems.
Inductive amplifier: An electronic device that uses the principle of electromagnetic induction to amplify a weak signal.
Inductive angle encoder: A sensor that uses the principle of inductance to measure the angle of rotation of a shaft or other mechanical component.
Inductive bridge: A bridge circuit that uses a combination of inductors and resistors to measure unknown inductance.
Inductive bridge: A circuit consisting of four or more inductors that can be used to measure the unknown inductance of one of the inductors.
Inductive charging: A method of charging an electronic device, such as a smartphone or electric vehicle, by inductively transferring energy from a charging pad to the device’s battery.
Inductive charging: A method of charging batteries by using an electromagnetic field to induce a current in the battery.
Inductive charging: A method of wireless power transfer that uses the principle of electromagnetic induction to charge a device.
Inductive Charging: A method of wirelessly charging a device by using an inductive coupling between a transmitter coil in the charging base and a receiver coil in the device. The transmitter coil generates a magnetic field that induces a current in the receiver coil, which is then used to charge the device’s battery.
Inductive Charging: A method of wirelessly charging batteries by passing an alternating current through a coil to create an electromagnetic field that induces a current in another coil. This technology is commonly used to charge devices such as mobile phones, laptops, and electric vehicles.
Inductive charging: A method of wirelessly transferring energy to a device by means of an electromagnetic field created by an inductive coil.
Inductive charging: A method of wirelessly transferring energy to a device using electromagnetic induction.
Inductive Coupler: A device that uses electromagnetic induction to transfer power or data between two circuits that are not in direct electrical contact. Inductive couplers are used in applications such as wireless charging and data transfer.
Inductive Coupling (k): The degree to which two inductors are coupled, measured as a ratio of the induced voltage in one inductor to the current in the other inductor.
Inductive coupling coefficient (k): A measure of the degree of mutual inductance between two coils, typically ranging from 0 to 1.
Inductive coupling coefficient: A measure of the degree of mutual inductance between two or more inductors.
Inductive coupling interference (EMI): The unwanted transfer of energy between two electrical circuits due to electromagnetic induction.
Inductive coupling interference: Interference caused by the inductive coupling between two or more circuits, often seen in electronic devices that are placed close to each other.
Inductive coupling: The transfer of energy between two circuits through a mutual inductance.
Inductive coupling: The transfer of energy between two circuits through a shared inductive element, such as a transformer.
Inductive Coupling: The transfer of energy between two circuits through an electromagnetic field. It can occur between two coils that are close to each other or between a coil and a nearby conductor.
Inductive coupling: The transfer of energy between two circuits through an inductive link.
Inductive Coupling: The transfer of energy between two circuits through electromagnetic fields. Inductive coupling is commonly used in wireless charging and data transfer applications.
Inductive Coupling: The transfer of energy between two coils through an electromagnetic field. It is a measure of the mutual inductance between the two coils and is used in applications such as wireless charging, power transfer and inductive communication.
Inductive coupling: The transfer of energy between two electrical circuits through electromagnetic induction.
Inductive Coupling: The transfer of energy between two inductors that are close to each other. This can occur when the two inductors are in the same circuit or when they are in separate circuits but are close enough to each other for the magnetic field of one inductor to induce a current in the other inductor.
Inductive Coupling: The transfer of energy between two inductors that are in close proximity to each other. Inductive coupling is a key principle in the operation of transformers, which use the phenomenon to transfer electrical energy between two or more coils.
Inductive coupling: The transfer of energy from one circuit to another through a mutual inductance.
Inductive Coupling: The transfer of energy from one circuit to another through a shared electromagnetic field. Inductive coupling is used in a variety of applications, such as transformer-based power supplies, wireless power transfer, and in communication systems to transfer data between devices.
Inductive Coupling: The transfer of energy through electromagnetic induction between two circuits that are not in direct contact. Inductive coupling is used in many applications such as wireless charging, data transfer, and power transmission.
Inductive current divider: A circuit consisting of two or more inductors connected in parallel, where the current through each inductor is inversely proportional to its inductance.
Inductive current sensor: A sensor that uses the principle of inductance to measure the current flowing through a conductor.
Inductive Current Sensor: A type of sensor that uses the principle of electromagnetic induction to measure the current flowing through a conductor. The sensor consists of a coil that surrounds the conductor and generates a magnetic field. When current flows through the conductor, it induces a voltage in the coil, which is used to measure the current.
Inductive Current Transformer: A type of current transformer that uses electromagnetic induction to measure the current in a circuit. Inductive current transformers are commonly used in power metering and protection applications.
Inductive Current Transformer: A type of current transformer that uses the principle of electromagnetic induction to measure the current flowing in a conductor. Inductive current transformers are commonly used in power systems to measure the current in high-voltage power lines.
Inductive Current Transformer: A type of transformer that is used to measure current in a high-voltage circuit. Inductive current transformers are commonly used in power distribution and transmission systems to measure the current flowing in high voltage lines.
Inductive current: The current that flows through an inductor due to the changing magnetic field produced by the current flowing through it.
Inductive discharge welding: A welding process that uses the principle of inductive heating to melt the metal at the point of contact between the workpiece and the electrode.
Inductive Discharge: A method of rapidly discharging an inductor by breaking the current path through the coil using a switch or semiconductor. This creates a large voltage spike across the inductor, which can be used in applications such as welding and ignition systems.
Inductive Displacement Sensor: A sensor that uses the principle of electromagnetic induction to detect the displacement of a moving object. Inductive displacement sensors are commonly used in industrial automation, robotics, and other applications where the precise displacement of a moving object needs to be determined.
Inductive Displacement Sensor: A sensor that uses the principle of electromagnetic induction to measure the position or displacement of an object. Inductive displacement sensors are commonly used in industrial automation and process control applications, such as measuring the position of a machine component or monitoring the movement of a shaft.
Inductive Displacement Sensor: A sensor that uses the principle of electromagnetic induction to measure the position or movement of an object. Inductive displacement sensors are commonly used in industrial automation and process control applications.
Inductive displacement sensor: A sensor that uses the principle of inductance to measure the displacement of a mechanical component.
Inductive Displacement Sensor: A type of sensor that uses an inductive transducer to measure the displacement of a moving object. It generates a magnetic field and when a metallic object enters the field, it induces a current in the object. This current is used to determine the displacement of the object.
Inductive divider: A circuit that uses a series of inductors to divide a voltage into multiple outputs.
Inductive divider: An electronic circuit that uses the principle of mutual inductance to divide a current into two or more parts.
Inductive effect: The phenomenon of an electric current producing a magnetic field around it, and a changing magnetic field producing an electric current in a conductor.
Inductive Energy Storage: A method of storing energy in an inductor by passing a current through the coil, this creates a magnetic field which can be used to generate an emf when the current is turned off.
Inductive energy storage: The ability of an inductor to store energy in its magnetic field when a current flows through it.
Inductive energy storage: The energy stored in an inductor due to the current flowing through it, which can be released back into the circuit as electrical energy.
Inductive energy storage: The storing of energy in the magnetic field of an inductor.
Inductive Filter: A circuit that uses inductors to filter out unwanted frequency components from an AC signal. Inductive filters are used in applications such as audio and power supply to filter out noise and harmonics.
Inductive filter: A circuit that uses inductors to selectively pass or block certain frequencies of AC, while attenuating others.
Inductive filter: A filter that uses an inductor to block or pass certain frequencies of AC current.
Inductive Filter: An electronic circuit that uses one or more inductors to filter out unwanted frequency components from a signal. Inductive filters are commonly used in audio and radio frequency (RF) applications.
Inductive Flow Sensor: A sensor that uses the principle of electromagnetic induction to measure the flow rate of a conductive liquid or gas. Inductive flow sensors are commonly used in industrial and commercial applications, such as monitoring the flow of water in a pipe or measuring the flow of fuel in an engine.
Inductive heating: A method of heating a material by passing an alternating current through it, causing it to heat up due to eddy currents and hysteresis losses.
Inductive impedance (Z_L): The total opposition to the flow of AC in an inductive circuit, including both resistance and reactance.
Inductive Impedance (ZL): The total opposition to the flow of alternating current in an inductor, including both resistance and inductive reactance. It is measured in ohms (Ω).
Inductive impedance: The opposition to current flow in an inductive circuit, caused by the self-inductance of the circuit elements.
Inductive impedance: The total opposition to the flow of AC current in an inductor, including both its resistance and reactance.
Inductive impedance: The total opposition to the flow of alternating current in an inductor, considering both its self-inductance and resistance.
Inductive kickback: A phenomenon in which a high voltage spike is generated when the current flowing through an inductor is suddenly interrupted.
Inductive Kickback: A sudden voltage spike that occurs when an inductor’s current is suddenly interrupted. This spike can be dangerous and cause damage to electronic components if not properly protected against.
Inductive kickback: A voltage spike caused by the sudden interruption of current in an inductive circuit.
Inductive Kickback: Also known as flyback voltage, it is the voltage spike that occurs when the current through an inductor is suddenly interrupted. This voltage spike can cause damage to electronic components if not properly protected.
Inductive kickback: The sudden voltage spike that occurs when an inductor is rapidly disconnected from a circuit.
Inductive kickback: The voltage spike that can occur when a switch is opened in an inductive circuit, due to the sudden interruption of the current flowing through the inductor.
Inductive Kickback: The voltage spike that can occur when an inductive load is suddenly disconnected from a power source. Inductive kickback can damage electronic devices and cause safety hazards, so it is important to properly design circuits to mitigate its effects.
Inductive Kickback: The voltage spike that occurs across an inductor when the current path through the coil is abruptly interrupted. Inductive kickback can be dangerous and can damage electronic devices if not properly handled.
Inductive kickback: The voltage spike that occurs when an inductive load is suddenly disconnected from a power source, caused by the collapse of the magnetic field in the inductor.
Inductive kickback: The voltage spike that occurs when an inductive load is suddenly disconnected from a power source.
Inductive Kickback: The voltage spike that occurs when the current flowing through an inductor is suddenly interrupted. Inductive kickback can cause damage to electronic devices and it’s important to use protective measures such as snubbers to suppress the voltage spike.
Inductive Latch: An electronic circuit that uses the principle of electromagnetic induction to maintain a state of energy storage in a circuit, even after the input signal is removed. Inductive latches are commonly used in digital circuits, such as flip-flops, and memory devices.
Inductive Load Balancing: A method of balancing the current flowing through multiple parallel inductors to ensure that the current is distributed evenly. It helps to reduce the overall resistance of the circuit and increase the efficiency of the circuit.
Inductive load balancing: A method of distributing the load among multiple inductive loads to prevent overloading and prolong their life.
Inductive load balancing: A technique used to balance the current flowing through multiple parallel inductors in order to prevent one from overheating.
Inductive Load Balancing: A technique used to balance the load in an AC system with inductive loads. Inductive load balancing is used to ensure that the system operates efficiently and to prevent damage to the equipment.
Inductive Load Bank: A device that simulates an inductive load on a power system to test the performance of generators, UPS and other power sources.
Inductive Load Bank: A device used to simulate an inductive load, typically used to test and evaluate the performance of an AC power source, such as a generator or an inverter.
Inductive load bank: A device used to simulate the effects of inductive loads, such as electric motors, on power systems during testing and commissioning.
Inductive load bank: A load bank that uses inductors to simulate the load on an electrical power system.
Inductive Load Bank: A type of load bank that uses inductive loads to simulate the load on an electrical system. Inductive load banks are commonly used in testing and commissioning of power systems, as well as in the testing of generators and other electrical equipment.
Inductive Load Bank: A type of load bank that uses inductors to simulate the load on a power supply or generator. Inductive load banks are commonly used in testing and commissioning of power systems.
Inductive Load Calculator: A tool that calculates the current, power, and voltage in an inductive load based on the inductance, resistance and frequency of the applied AC current.
Inductive Load Modeling: The process of mathematically modeling the behavior of an inductive load in a circuit. This can be used to simulate the performance of a circuit before it is built and to optimize the design of a circuit.
Inductive Load Power Factor: The ratio of real power to apparent power in an inductive load. It is a measure of the efficiency of an inductive load and is typically less than 1.
Inductive Load Tester: A device that measures the inductive load of a circuit, typically used to test the performance of motors, generators and other devices that use rotating machinery.
Inductive Load Testing: A test method used to measure the inductive load of a circuit, typically used to test the performance of motors, generators, and other devices that use rotating machinery.
Inductive load: A load that consumes energy in the form of an induced current.
Inductive Load: A load that is composed of an inductor and a resistor. Inductive loads are commonly used in applications such as motor drives, power factor correction, and filtering.
Inductive load: A load that is made up of one or more inductors, such as a motor or transformer.
Inductive load: A load, such as an inductor, that consumes power primarily due to its inductive reactance.
Inductive Load: A type of electrical load that consumes power in the form of an inductive reactance. Inductive loads are commonly found in electric motors, transformers and other devices that use electromagnetic fields.
Inductive Load: A type of electrical load that is characterized by its inductive reactance. Inductive loads include motors, transformers and other devices that use inductors to store energy in a magnetic field.
Inductive Load: A type of load on a power system that is primarily resistive, with a small inductive component. Inductive loads are commonly found in motors, generators, and other devices that use rotating machinery.
Inductive load: An electrical load that exhibits a significant inductive reactance, such as an electric motor or transformer.
Inductive load: An electrical load that is mostly inductive in nature, such as an inductor or an electric motor.
Inductive load: An electrical load, such as an electric motor, that generates a back emf when the current flowing through it is changed, due to the self-inductance of the load.
Inductive Loop Antenna: A type of antenna that uses an inductive loop to transmit and receive electromagnetic waves. It is commonly used in applications such as radio frequency identification (RFID) and near-field communication (NFC).
Inductive Loop Antenna: A type of antenna that uses an inductor to transmit and receive electromagnetic waves. Inductive loop antennas are commonly used in radio frequency identification (RFID) and near-field communication (NFC) applications.
Inductive loop antenna: An antenna that uses a loop of wire to pick up electromagnetic waves in the radio frequency range.
Inductive Loop Antenna: An antenna that uses the principle of electromagnetic induction to transmit and receive signals. Inductive loop antennas are commonly used in radio communication systems, such as AM and shortwave radio, and in metal detection applications.
Inductive loop detector: A device that uses a loop of wire embedded in the pavement to detect the presence of metal objects, such as vehicles, passing over it.
Inductive Loop Detector: A device that uses the principle of electromagnetic induction to detect vehicles in a traffic control system. Inductive loop detectors are commonly used in traffic lights, parking garages, and toll booths.
Inductive Loop Detector: A type of detector used to detect the presence of metal objects such as vehicles and bicycles. Inductive loop detectors are commonly used in traffic control systems, parking garages, and other applications where the detection of metal objects is required.
Inductive Loop Detector: A type of sensor that uses the principle of electromagnetic induction to detect the presence of metal objects, such as vehicles, in a specific area. Inductive loop detectors are commonly used in applications such as traffic control, parking lots and garages, and access control systems.
Inductive Loop System: An electronic circuit that uses the principle of electromagnetic induction to detect the presence of metal objects in its proximity. Inductive loop systems are commonly used in industrial automation, robotics, and process control applications.
Inductive loop: A loop of wire that is used to create a magnetic field, often used in inductive sensors or charging applications.
Inductive loop: A loop of wire that is used to detect vehicles or other metal objects passing through it.
Inductive loop: A loop of wire used in inductive sensing applications such as vehicle detection, underground pipe location, and metal detection.
Inductive Loop: A type of antenna that uses an inductor to transmit and receive electromagnetic waves. Inductive loops are commonly used in radio frequency identification (RFID) and near-field communication (NFC) applications.
Inductive Loop: A type of sensor that uses an inductor to detect the presence of a metallic object. The inductor is connected in a loop and when a metallic object is brought into the loop, it disrupts the magnetic field and induces a current in the loop. This current can be measured to detect the presence of the object.
Inductive Motor: A type of electric motor that uses electromagnetic induction to generate torque. Inductive motors are commonly used in industrial and commercial applications, including fans, pumps, and conveyors.
Inductive pick-up: A device used to sense the passing of a metal object, such as a gear tooth or a rotor, in rotating machinery.
Inductive Position Sensor: A sensor that uses the principle of electromagnetic induction to detect the position of a moving object. Inductive position sensors are commonly used in industrial automation, robotics, and other applications where the precise position of a moving object needs to be determined.
Inductive Position Sensor: A sensor that uses the principle of electromagnetic induction to measure the position or movement of an object. Inductive position sensors are commonly used in industrial automation and process control applications.
Inductive Position Sensor: A type of sensor that uses an inductive transducer to measure the position of a moving object. The sensor generates a magnetic field and when a metallic object enters the field, it induces a current in the object. This current is used to determine the position of the object.
Inductive Position Sensor: A type of sensor that uses the principle of electromagnetic induction to determine the position of an object. They are commonly used in industrial automation, robotics and other applications.
Inductive Power Supply: A type of power supply that uses electromagnetic induction to convert AC power to DC power. Inductive power supplies are commonly used in a variety of applications, such as charging batteries, powering electronic devices, and providing power to industrial machines.
Inductive Power Supply: A type of power supply that uses inductive coupling to transfer power. Inductive power supplies are used in applications such as charging electric vehicles and powering wireless sensors.
Inductive Power Transfer (IPT): A method of wirelessly transmitting electrical power using an electromagnetic field. Inductive power transfer is used in applications such as electric vehicle charging, wireless power tools, and charging of medical implants.
Inductive Power Transfer (IPT): A technology that uses the principle of electromagnetic induction to transfer power wirelessly. IPT is used in a variety of applications, such as charging electric vehicles, powering medical implants, and providing power to remote locations.
Inductive Power Transfer (IPT): A wireless charging technology that uses electromagnetic induction to transfer power between a transmitter and a receiver. IPT is used in a wide range of applications, including electric vehicles, industrial equipment, and consumer electronics.
Inductive Power Transfer Calculator: A tool that calculates the power transfer efficiency and the distance between the transmitter and receiver coils in an inductive power transfer system.
Inductive Power Transfer: A method of transferring electrical energy wirelessly using electromagnetic induction. Inductive power transfer is used in a wide range of applications, including electric vehicles, wireless charging pads, and other applications where a wire-free power transfer is required.
Inductive Power Transfer: A method of transferring electrical power wirelessly using the principle of electromagnetic induction. It consists of a primary coil that generates a magnetic field and a secondary coil that induces a current in the secondary coil, which is used to transfer power.
Inductive power transfer: A method of wireless power transfer that uses the principle of electromagnetic induction to transfer power from a primary coil to a secondary coil.
Inductive Power Transfer: A method of wirelessly transferring power using electromagnetic fields. This technology is used in applications such as charging electric vehicles and powering wireless sensors.
Inductive power transfer: The transfer of electrical energy from one point to another using electromagnetic induction.
Inductive Power Transmitter: A device that uses electromagnetic induction to transfer power wirelessly from a power source to a receiver. Inductive power transmitters are commonly used in wireless charging applications.
Inductive proximity sensor: A sensor that detects the presence or absence of a metallic object by measuring the change in inductance caused by its proximity.
Inductive Proximity Sensor: A sensor that uses the principle of electromagnetic induction to detect the presence of a metal object. Inductive proximity sensors are commonly used in industrial automation and process control applications, such as detecting the presence of a metal part on a conveyor belt or detecting the position of a metal cam in a machine.
Inductive Proximity Sensor: A sensor that uses the principle of electromagnetic induction to detect the presence of metal objects in its proximity. Inductive proximity sensors are commonly used in industrial automation, robotics and process control applications.
Inductive proximity sensor: A sensor that uses the principle of inductance to detect the presence of a metallic object without physical contact.
Inductive proximity sensor: A sensor that uses the principle of inductance to detect the presence of metal objects.
Inductive proximity sensor: A sensor that uses the principle of inductance to detect the presence or absence of an object in a specific area.
Inductive proximity sensor: A sensor that uses the principle of inductive coupling to detect the presence or proximity of metal objects.
Inductive Proximity Sensor: A type of sensor that uses an inductor to detect the presence of a metallic object. The inductor generates a magnetic field and when a metallic object is brought into the field, it induces a current in the object. This current can be measured to detect the presence of the object.
Inductive Proximity Sensor: A type of sensor that uses the principle of electromagnetic induction to detect the presence of metal objects in a specific area. Inductive proximity sensors are commonly used in industrial automation, robotics, and other applications where the presence or absence of metal objects needs to be detected.
Inductive Proximity Sensor: A type of sensor that uses the principle of electromagnetic induction to detect the presence of metal objects. It consists of a coil that generates a magnetic field and a metal object entering the field induces a current in the object, which is used to detect the presence of the object.
Inductive Proximity Sensor: A type of sensor that uses the principle of electromagnetic induction to detect the presence or position of an object. They are commonly used in industrial automation, robotics, and other applications.
Inductive proximity switch: An electronic switch that uses the principle of inductance to detect the presence of a metallic object without physical contact.
Inductive reactance (X_L): The opposition to the flow of alternating current (AC) in an inductive circuit, measured in ohms.
Inductive Reactance (XL): The opposition to the flow of alternating current in an inductor, caused by the inductor’s property of inductance. It is measured in ohms (Ω).
Inductive Reactance Bridge: An electronic circuit used to measure the inductive reactance of a circuit. Inductive reactance bridges use a combination of resistors and capacitors to generate an alternating current that passes through the circuit being tested, and then measure the voltage and current to calculate the inductive reactance.
Inductive Reactance Calculator: A tool that calculates the inductive reactance of an inductor based on the inductance and frequency of the applied AC current.
Inductive Reactance Calculator: A tool that can be used to calculate the inductive reactance of a coil. It can be used in the design of circuits, and to determine the performance of inductors.
Inductive reactance calculator: A tool used to calculate the inductive reactance of an inductor based on its inductance and the frequency of the applied current.
Inductive Reactance Filter: An electronic circuit that uses the principle of inductive reactance to filter out unwanted frequencies from a signal. Inductive reactance filters are commonly used in audio and radio frequency applications.
Inductive Reactance Formula: A mathematical formula used to calculate the inductive reactance of a circuit. The formula is typically Xl = 2πfL, where Xl is the inductive reactance, f is the frequency, and L is the inductance.
Inductive Reactance Frequency: The opposition that an inductor presents to the flow of alternating current, it is dependent on the frequency of the applied voltage and the inductance of the coil.
Inductive Reactance: A measure of the opposition to AC current flow in an inductor, caused by the magnetic field it generates. Inductive reactance is measured in ohms (Ω) and is dependent on the frequency of the AC current and the inductance of the inductor.
Inductive Reactance: The opposition that an inductor presents to the flow of alternating current. It is measured in ohms (Ω) and is dependent on the frequency of the applied voltage and the inductance of the coil.
Inductive reactance: The opposition to AC current flow in an inductive circuit, caused by the self-inductance of the circuit elements. It is measured in ohms and is represented by the symbol XL.
Inductive reactance: The opposition to an AC current in an inductive circuit, measured in ohms (Ω).
Inductive Reactance: The opposition to current flow in an AC circuit caused by the inductance of the circuit. Inductive reactance is measured in ohms and is dependent on the frequency of the applied voltage and the inductance of the circuit.
Inductive Reactance: The opposition to the AC current flow in an inductor, caused by the inductor’s inductance. It is measured in ohms and is dependent on the frequency of the applied AC current and the inductance of the inductor.
Inductive reactance: The opposition to the flow of AC current in an inductor, caused by the coil’s self-inductance.
Inductive reactance: The opposition to the flow of AC current in an inductor, measured in ohms and represented by the symbol XL.
Inductive reactance: The opposition to the flow of alternating current in an inductor, caused by its self-inductance.
Inductive Reactance: The opposition to the flow of alternating current in an inductor, caused by the inductor’s self-induced electromotive force. Inductive reactance is measured in ohms (Ω) and is dependent on the frequency of the alternating current and the inductance of the inductor.
Inductive Response: The response of an inductor to an applied alternating current. Inductive response can be characterized by the phase angle between the applied current and the induced electromotive force, as well as the magnitude of the induced electromotive force.
Inductive Sensor: A device that uses the principle of electromagnetic induction to detect the presence, position or motion of an object. Inductive sensors are used in a wide range of applications, including industrial automation, robotics, and process control.
Inductive sensor: A sensor that uses the principle of inductance to detect changes in position, motion, or other parameters.
Inductive sensor: A sensor that uses the principle of inductance to detect or measure a physical quantity, such as position, velocity, or current.
Inductive sensor: A sensor that uses the principle of inductance to detect the presence or position of an object.
Inductive sensor: A sensor that uses the principle of inductance to measure a physical quantity, such as position, speed, or displacement.
Inductive Sensor: A type of sensor that uses the principle of electromagnetic induction to detect the presence or position of an object. They are commonly used in industrial automation, robotics and other applications.
Inductive susceptance (B_L): The inverse of inductive reactance, measured in siemens (S).
Inductive Susceptance (BL): The imaginary component of the admittance of an inductor. It is measured in siemens (S).
Inductive Synthesizer: An electronic circuit that uses inductors to generate a stable high-frequency signal. Inductive synthesizers are used in applications such as radio communications and test equipment.
Inductive Temperature sensor: A sensor that uses the principle of Inductance to measure the temperature of an object.
Inductive time constant (τ): The time it takes for the current in an inductive circuit to reach 63.2% of its final value after a step change in voltage.
Inductive time constant: The time it takes for an inductor to reach 63.2% of its final value when a current is applied or removed.
Inductive time constant: The time it takes for the current flowing through an inductor to reach 63.2% of its final steady-state value after a change in current. It is represented by the symbol τ (tau) and is equal to the product of the inductance value and the circuit’s total resistance.
Inductive time constant: The time it takes for the current in an inductor to reach 63.2% of its final value after a step change in voltage.
Inductive Timing Sensor: A sensor that uses the principle of electromagnetic induction to measure the position or movement of an object with high precision. Inductive timing sensors are commonly used in industrial automation and process control applications.
Inductive Timing Sensor: A sensor that uses the principle of electromagnetic induction to measure the position or rotation of an object. It is commonly used in automotive and industrial applications such as engine control, camshaft position, and crankshaft position.
Inductive transducer: A device that converts a mechanical or other non-electrical input into an electrical output through the use of an inductor.
Inductive transducer: A device that converts a physical quantity, such as position or displacement, into an electrical signal by using the principle of inductance.
Inductive Transducer: A type of transducer that uses the principle of electromagnetic induction to convert physical quantities such as position, displacement, or angular motion into an electrical signal.
Inductive voltage divider: A circuit consisting of two or more inductors connected in series, where the voltage across each inductor is inversely proportional to its inductance.
Inductive Voltage Divider: A circuit that uses the principle of electromagnetic induction to divide the voltage level of a signal. Inductive voltage dividers are commonly used in power distribution, high voltage testing and measurement, and other applications where a high voltage signal needs to be divided for further processing.
Inductive voltage divider: A circuit that uses the principle of electromagnetic induction to divide voltage in a circuit.
Inductive Voltage Divider: A circuit that uses two or more inductors in series to divide an input voltage into several output voltages. Inductive voltage dividers are commonly used in power distribution systems, as well as in high-voltage electrical testing equipment.
Inductive Voltage Divider: A circuit that uses two or more inductors in series to divide the voltage applied to the circuit. It is commonly used in applications such as voltage stabilization and power factor correction.
Inductive Voltage Divider: An electronic circuit that uses the principle of electromagnetic induction to divide a high voltage into lower voltage levels. It is commonly used in applications such as power distribution, high voltage testing and measurement.
Inductive Voltage Divider: An electronic circuit that uses the principle of electromagnetic induction to reduce the voltage level of a signal. Inductive voltage dividers are commonly used in high voltage applications, such as power distribution, high voltage testing and measurement.
Inductive Voltage Drop: The voltage difference caused by the inductive reactance of a circuit. Inductive voltage drop occurs in AC circuits and can affect the performance of the circuit if not properly accounted for in the design.
Inductive Voltage Drop: The voltage drop across an inductor due to its inductive reactance. It can cause a reduction in the voltage available to the load and should be taken into account when designing inductive circuits.
Inductive Voltage Multiplier: A circuit that uses inductors to multiply the voltage applied to the circuit. Inductive voltage multipliers are used in applications such as high voltage power supplies and X-ray generators.
Inductive Voltage Multiplier: An electronic circuit that uses the principle of electromagnetic induction to increase the voltage level of a signal. Inductive voltage multipliers are commonly used in high voltage applications, such as power distribution and high voltage testing and measurement.
Inductive Voltage Multiplier: An electronic circuit that uses the principle of electromagnetic induction to increase the voltage level of a signal. They are commonly used in high voltage applications such as power distribution, high voltage testing and measurement.
Inductive Voltage Regulator: A type of voltage regulator that uses electromagnetic induction to control the voltage level of a circuit. Inductive voltage regulators are used in applications such as power supplies, UPS, and renewable energy systems.
Inductive Voltage Transformer (IVT): A type of voltage transformer that uses electromagnetic induction to measure the voltage in a circuit. Inductive voltage transformers are commonly used in power metering and protection applications.
Inductive voltage transformer: A transformer that uses the principle of mutual inductance to step up or step down voltage levels.
Inductive Voltage Transformer: A type of transformer that is used to measure voltage in a high-voltage circuit. Inductive voltage transformers are commonly used in power distribution and transmission systems to measure the voltage on high voltage lines.
Inductive Voltage Transformer: An electronic circuit that uses the principle of electromagnetic induction to transfer voltage level from one circuit to another. It is commonly used in applications such as power distribution, high voltage testing and measurement.
Inductive-capacitive (L-C) circuit: An electrical circuit that contains both inductors and capacitors, and can be used to filter or tune signals.
Inductive-capacitive-inductive (L-C-L) circuit: An electrical circuit that contains both inductors, capacitors and more than one inductor, and can be used to create more complex filter or tune signals.
Inductive-capacitive-resistive (L-C-R) circuit: An electrical circuit that contains both inductors, capacitors, and resistors, and can be used to create more complex filter or tune signals, and dampen oscillations.
Inductive-inductive (L-L) circuit: An electrical circuit that contains multiple inductors and can be used to couple energy between different circuits.
Inductive-inductive-capacitive-resistive (L-L-C-R) circuit: An electrical circuit that contains both inductors, more than one inductor, capacitors and resistors, and can be used to create more complex filter or tune signals, and dampen oscillations.
Inductive-inductive-capacitive-resistive-inductive-capacitive (L-L-C-R-L-C) circuit: An electrical circuit that contains both inductors, more than one inductor, capacitors, resistors, more than one inductor and more than one capacitor
Inductive-inductive-inductive (L-L-L) circuit: An electrical circuit that contains more than two inductors and can be used to couple energy between different circuits or to create more complex time-delays.
Inductive-inductive-inductive-capacitive-resistive-inductive (L-L-L-C-R-L) circuit: An electrical circuit that contains more than two inductors, capacitors, resistors, more than one inductor. It can be used to couple energy between different circuits or to create more complex time-delays and dampen oscillations.
Inductive-inductive-inductive-inductive-capacitive-resistive (L-L-L-L-C-R) circuit: An electrical circuit that contains more than three inductors, capacitors, resistors. It can be used to couple energy between different circuits or to create more complex time-delays and dampen oscillations.
Inductive-inductive-inductive-inductive-resistive-capacitive (L-L-L-L-R-C) circuit: An electrical circuit that contains more than three inductors, resistors, capacitors. It can be used to couple energy between different circuits or to create more complex time-delays and dampen oscillations.
Inductive-inductive-inductive-resistive-capacitive-inductive (L-L-L-R-C-L) circuit: An electrical circuit that contains more than two inductors, resistors, capacitors and more than one inductor. It can be used to couple energy between different circuits or to create more complex time-delays and dampen oscillations.
Inductive-inductive-resistive-capacitive (L-L-R-C) circuit: An electrical circuit that contains both inductors, more than one inductor, resistors and capacitors, and can be used to create more complex filter or tune signals, and dampen oscillations.
Inductive-inductive-resistive-capacitive-inductive-resistive (L-L-R-C-L-R) circuit: An electrical circuit that contains both inductors, more than one inductor, resistors, capacitors, more than one inductor and more than one resistor. It can be used to create more complex filter or tune signals, and dampen oscillations.
Inductive-resistive (L-R) circuit: An electrical circuit that contains both inductors and resistors, and can be used to create time-delays or dampen oscillations.
Inductive-resistive-capacitive (L-R-C) circuit: An electrical circuit that contains both inductors, resistors and capacitors, and can be used to filter or tune signals, and dampen oscillations.
Inductive-resistive-capacitive-inductive (L-R-C-L) circuit: An electrical circuit that contains both inductors, resistors, capacitors and more than one inductor, and can be used to create more complex filter or tune signals, and dampen oscillations.
Inductive-resistive-capacitive-inductive-resistive-capacitive (L-R-C-L-R-C) circuit: An electrical circuit that contains both inductors, resistors, capacitors, more than one inductor, more than one resistor, and more than one capacitor. It can be used to create more complex filter or tune signals, and dampen oscillations.
Inductive-resistive-inductive (L-R-L) circuit: An electrical circuit that contains both inductors, resistors and more than one inductor, and can be used to create more complex time-delays or dampen oscillations.
Inductive-resistive-inductive-capacitive (L-R-L-C) circuit: An electrical circuit that contains both inductors, resistors, more than one inductor and capacitors, and can be used to create more complex filter or tune signals, and dampen oscillations.
Inductive-resistive-inductive-capacitive-resistive-inductive (L-R-L-C-R-L) circuit: An electrical circuit that contains both inductors, resistors, more than one inductor, capacitors, more than one resistor and more than one inductor. It can be used to create more complex filter or tune signals, and dampen oscillations.
Inductor: A passive component that stores energy in a magnetic field when electric current flows through it.
Inductor-Capacitor (LC) filter: An electronic filter that passes certain frequencies while rejecting others. It is made up of one or more inductors (L) and one or more capacitors (C) connected in a specific configuration. LC filters are commonly used in electronic circuits to filter out unwanted frequencies or to isolate different frequency bands.
Inductor-Resistor-Capacitor (LRC) filter: An electronic filter that is similar to an LC filter, but also includes one or more resistors (R) in the circuit. The resistors are used to control the amount of energy loss in the circuit and to fine-tune the filter’s performance.
Inductor-Transistor Logic (LTL): A type of digital logic circuit that uses inductors in combination with transistors to perform logic operations. LTL is a high-power alternative to traditional transistor-transistor logic (TTL) and is used in high-power applications such as motor control and power management.
Inductor-Transistor-Capacitor (LTC) filter: An electronic filter that uses a transistor to control the flow of current through an LC circuit. This type of filter is useful for applications where the filter needs to be turned on and off quickly.
Inductor-Transistor-Diode Logic (ITDL): A type of digital logic circuit that uses inductors in combination with transistors and diodes to perform logic operations. ITDL is similar to LTL but uses a different circuit configuration.
Inductor-Transistor-Resistor-Capacitor (LTRC) filter: An electronic filter that uses a transistor, resistor, and capacitor in addition to an inductor to control the flow of current through the circuit. This type of filter is useful for applications where the filter needs to be turned on and off quickly and fine-tune the filter’s performance.
Inductor-Transistor-Transistor Logic (ITL): A type of digital logic circuit that uses inductors in combination with transistors to perform logic operations. ITL is similar to LTL but uses a different circuit configuration.
Iron-Core Inductor: An inductor that has a core made of a ferromagnetic material. Iron-core inductors are used in applications where a large amount of inductance is required and the frequency of the signal is relatively low.
Iron-core Inductor: An inductor that has a core made of iron or other ferromagnetic material.
Iron-core inductor: An inductor that has a magnetic core made of iron or other ferromagnetic material to increase its inductance.
Iron-core inductor: An inductor that uses a ferromagnetic core to increase the inductance of the coil.
Iron-Core Inductor: An inductor that uses a magnetic core made of iron to enhance the magnetic field generated by the winding of the wire. Iron-core inductors have a lower inductance than air-core inductors but also have a lower resistance to AC current.
Iron-Core Inductor: An inductor that uses iron as the core material. Iron-core inductors are used in applications such as power supplies and audio equipment, due to their high inductance and low cost.
Laminated Core Inductor: An inductor that has a core made of thin layers of a magnetic material, typically used to reduce core loss.
Leakage Inductance (Lm): The inductance that is not used for the intended purpose of the circuit and is instead “leaking” to other parts of the circuit.
Leakage inductance: The inductance that is not part of the intended magnetic circuit and causes energy loss.
Linear inductor: An inductor whose inductance does not change significantly with changes in current.
Linear Inductor: An inductor whose inductance remains constant over a wide range of current and frequency. Linear inductors are used in applications such as power supplies and audio equipment where the inductance needs to remain constant.
Magnetic Amplifier: A type of amplifier that uses a magnetic core to control the flow of current through the circuit. Inductors are the key component of magnetic amplifier.
Magnetic Core: A material placed inside an inductor to increase the inductance of the coil. Magnetic cores are commonly made of materials such as iron, ferrite, and powders.
Magnetic Resonance Imaging (MRI): A medical imaging technique that uses a powerful magnetic field and radio waves to create detailed images of the inside of the body. The images are created by exciting the hydrogen atoms in the body, which then emit radio waves that are detected and used to create the images. Inductors are used in the radio frequency coils of the MRI machine to generate the radio waves.
measure the performance of inductors in various applications.
Mutual Inductance (M): The phenomenon in which a change in current in one coil induces an electromotive force in a second coil, even if the two coils are not in direct electrical contact.
Mutual Inductance Calculator: A tool that can be used to calculate the mutual inductance between two coils. It can be used in the design of circuits, and to determine the performance of inductors in systems where multiple coils are used.
Mutual inductance: The inductance between two or more circuit elements caused by the current in one element affecting the voltage in another element.
Mutual Inductance: The inductance that exists between two coils that are near each other, which is caused by the magnetic field of one coil inducing an electromotive force in the other coil. Mutual inductance is a key concept in transformer design.
Mutual Inductance: The measure of the degree of inductive coupling between two or more inductors.
Mutual inductance: The phenomenon in which the current flowing through one coil induces a current in a neighboring coil.
Mutual inductance: The phenomenon where a changing current in one coil induces an EMF in a second coil.
Mutual inductance: The phenomenon where the changing current in one coil induces an electromotive force (EMF) in another coil that is coupled to it.
Mutual Inductance: The phenomenon where the changing current in one coil induces an electromotive force in another coil that is placed nearby. Mutual inductance is a measure of the amount of coupling between two coils and is expressed in henries (H).
Mutual Inductance: The property of two or more inductors by which a change in current flowing through one coil induces an emf in the other coils. Mutual inductance is measured in henrys (H) and it is a key concept in the operation of transformers.
Mutual inductance: The property of two or more inductors by which a change in current flowing through one of the inductors induces an EMF in the other(s)
Mutual Inductance: The property of two or more inductors by which an emf is induced in one coil due to a change in current flowing through another coil. It is a measure of the inductive coupling between two or more coils and is measured in henrys (H).
Mutual inductance: The property of two or more inductors that causes a change in current flowing through one inductor to induce an electromotive force in the other inductor(s).
Nonlinear inductor: An inductor whose inductance changes significantly with changes in current.
Non-Linear Inductor: An inductor whose inductance varies with the current and/or frequency of the applied voltage. Non-linear inductors are used in applications such as saturable reactors and current transformers where the inductance needs to vary.
Parallel Inductance (Lp): The total inductance of a parallel of inductors.
Pot Core Inductor: An inductor that has a pot-shaped core with the coil of wire wound around the core.
Power Inductor: An inductor that is used in power electronic circuits to store energy in a magnetic field and release it as needed. Power inductors are commonly used in switching power supplies, DC-DC converters, and other power electronic applications.
Proximity Effect: The phenomenon where the alternating current flowing in a conductor causes a magnetic field that induces currents in nearby conductors. This effect increases the resistance of the inductor and can cause energy loss.
Proximity effect: The phenomenon where the current in a multi-conductor AC circuit is concentrated in the closest conductors, due to the increasing inductive coupling with increasing distance.
Quality factor (Q): A dimensionless measure of the “quality” of an inductor, typically defined as the ratio of energy stored to energy lost per cycle.
Quality Factor (Q): A dimensionless parameter that describes the damping of energy in an inductor or resonant circuit. It is equal to the ratio of the energy stored in the circuit to the energy lost per cycle.
Quality Factor (Q): The measure of the efficiency of an inductor, also known as “Q-factor” which is the ratio of the energy stored in the magnetic field of the inductor to the energy loss in the inductor. A higher Q-factor indicates a more efficient inductor.
Quality Factor (Q-factor): A measure of the efficiency of an inductor. A higher Q-factor indicates a higher efficiency and a lower loss.
Saturable Core Inductor: An inductor that uses a core material that can be saturated by a magnetic field, which changes the inductance of the coil. Saturable core inductors are used in applications such as power supplies and audio equipment.
Saturable Reactor: A type of inductor that uses a magnetic core made of a material that can be saturated by an applied magnetic field. Saturable reactors can be used to control the current flow in AC circuits, and to generate high-frequency pulses.
Saturable reactor: A type of inductor that uses a saturable core, which allows the inductance to change based on the current flowing through the coil.
Saturable reactor: A type of saturable inductor that is used to control the flow of current in a circuit. A saturable reactor consists of a core made of a magnetic material that can be magnetized and demagnetized. When the core is magnetized, it increases the inductance of the reactor and reduces the current flowing through the circuit. When the core is demagnetized, it decreases the inductance of the reactor and increases the current flowing through the circuit.
Saturated inductor: An inductor that has reached its maximum inductance due to the presence of a magnetic core that is magnetically saturated.
Saturation: The point at which an inductor can no longer increase its magnetic field, regardless of the current flowing through it.
Self-Inductance (L): The property of an inductor by which a change in current flowing through it induces an electromotive force in the coil.
Self-inductance: The inductance of a circuit element caused by its own current.
Self-inductance: The phenomenon in which a changing current in a coil induces an electromotive force in the same coil.
Self-inductance: The phenomenon where a changing current in a coil induces an electromotive force (EMF) in the same coil.
Self-inductance: The phenomenon where a changing current in a coil induces an EMF in the same coil.
Self-inductance: The property of an inductor by which a change in current flowing through it induces an electromotive force (EMF) in the same circuit.
Self-Inductance: The property of an inductor by which an emf is induced in it due to a change in the current flowing through it. It is a measure of the inductance of an individual inductor and is measured in henrys (H).
Self-Inductance: The property of an inductor by which an emf is induced in the coil due to a change in current flowing through the coil. It is a measure of the inductance of a single coil and is measured in henrys (H).
Self-inductance: The property of an inductor that causes it to oppose a change in current flowing through it.
Series Inductance (Ls): The total inductance of a series of inductors.
Shielded Inductor: An inductor that has a metal shield around the coil to reduce electromagnetic interference (EMI) or RFI. Shielded inductors are commonly used in high-frequency and RF applications to reduce unwanted interference.
Skin Effect: The phenomenon where the alternating current flows mainly on the surface of a conductor, rather than throughout the entire cross-section of the conductor. This effect increases the resistance of the inductor and can cause energy loss.
Skin effect: The phenomenon where the current in an AC circuit is concentrated near the surface of a conductor, due to the increasing resistance of the conductor with increasing depth.
Sure, here are a few more terms related to inductance and its applications:
Toroidal Inductor: An inductor that has a toroidal (doughnut-shaped) core. Toroidal inductors are often used in circuits where space is limited and a compact size is needed. They are also used in circuits where low leakage inductance is required.
Toroidal Inductor: An inductor that is shaped like a torus (doughnut) with the coil of wire wound around the center of the torus.
Transformer: A device that uses the principle of mutual inductance to transfer electrical energy between two or more circuits, often used to step up or step down voltage levels.
Transformer: An electrical device that uses the principle of electromagnetic induction to transfer electrical energy between separate coils. It can step up or step down the voltage and current between the primary and secondary windings.
Variable inductor: An inductor that has a mechanism to adjust its inductance, such as a movable coil or core.
Voltage Transformer: A type of transformer that uses the principle of electromagnetic induction to step up or step down the voltage applied to the circuit. It consists of a primary coil and a secondary coil, the ratio of the number of turns of the primary coil to the number of turns of the secondary coil determines the voltage transformation ratio.
Voltage-mode control: A method of controlling the output of a power electronic circuit by regulating the voltage across the circuit. Inductors are often used in voltage-mode control circuits to filter out high-frequency noise.

Common Circuit Terminology

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