LQP02TQ0N8B02D

Fixed inductors, identified with a part number LQP02TQ0N8B02D, are electronic components used to store energy in the form of a magnetic field. The inductance of the component is measured in units of Henries (H), and its current rating will be specified in its datasheet. As a passive component, the inductor relies on the conservation of energy in order to function. It can be used in a variety of fields due to its ability to change the properties of an electric current.

Fixed inductors are most commonly used to filter, store and release energy within an electrical circuit. Being a passive component, their use is most suitable in low frequency applications, and have applications as diverse as telecommunications, power electronics, antennas and radar systems. The unique properties of the inductor allow it to be used in the design of filters, amplifiers and oscillators, providing the necessary components for the design of electrical circuits of all kinds.

Inductors are also used in power electronics to reduce the ripple voltage of the current, as well as in motor drive circuits to ensure the current is continuously supplied to the motor. They largely work to convert the changing of electric current into magnetic field energy, assisting in voltage regulation and waveform shaping. They can also be used to increase current flow in audio amplifiers.

Due to the nature of their construction, particular inductors may also be used as antennas. This is due to the inductive property of the coil being able to act as a tuned frequency, and can be used to transmit or receive electrical signals.

Inductors work on the principles of electromagnetic induction. It works by converting electrical energy into magnetic energy, and when the electric current going through the inductor is varied, a voltage is generated across the device which is opposed to the changing electric current. This is known as Lenz’s Law, which states when the electric current flowing through the inductor experiences a change, a back EMF (electromotive force) is induced in the device. This back EMF opposes the change in electric current.

The rate at which the electric current changes will determine the magnitude of the induced EMF. This property is kept constant in fixed inductors, meaning the rate at which the electric current changes determines the current in the device. If the electric current increases, it will also increase, and vice versa.

The strength of the magnetic field created by the inductor will depend upon its ability to store energy in the form of a magnetic field. This is called the ‘self-inductance’ of an inductor. The larger the current running through the inductor, the larger its self-inductance. The inductor will also be affected by its core material, as this determines the amount of energy stored.

Inductors can also be used in conjunction with capacitors to form filters. This works as the capacitor reacts to the changing electric current, and this is greatly enhanced by the inductor. The combination of an inductor and capacitor can create a low-pass filter, high-pass filter, band-pass filter, or band-stop filter.

For LQP02TQ0N8B02D fixed inductors, the current rating will be specified in its datasheet. The inductance in units of H will also be listed, and this is the overall measure of their effect on the electric current. Typically, the operating temperatures of these inductors will range from -40 to +125°C, with a rated dissipation factor of 0.2 - 0.4W at rated temperature.