How Joule Thief Circuit Works? Working of Joule Thief Circuit Explained with 3D Animation...
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LearningTranscript
00:00Today, we're exploring the fascinating world of the Jewel Thief, a simple yet
00:04ingenious circuit that can breathe new life into seemingly dead batteries by
00:09amplifying their remaining power.
00:11Despite its seemingly magical abilities, the Jewel Thief is nothing more than a
00:15voltage amplifier, consisting of just five electronic components, a 1.5 volt
00:21battery, a resistor, a bifilar toroidal coil, an NPN bipolar junction transistor,
00:28and an LED.
00:29But before we delve into how the Jewel Thief works its magic, let's quickly
00:33review how batteries function.
00:35Batteries rely on chemical reactions to generate a consistent voltage over time.
00:40As these reactions become less efficient with use, the battery's voltage
00:44gradually decreases, eventually rendering it unable to power devices
00:49effectively.
00:50However, there's often residual energy left in the battery, waiting to be
00:54tapped into.
00:55Enter the Jewel Thief.
00:57This circuit exploits the remaining energy in depleted batteries, effectively
01:01stealing jewels to power low-voltage devices.
01:05At its core, the Jewel Thief operates on the principle of positive feedback,
01:10continuously amplifying the voltage until it's sufficient to illuminate an
01:14LED.
01:15Here's how it works.
01:16When the circuit is initially powered on, current flows through the resistor
01:20and the base-emitter junction of the transistor, causing the transistor to
01:24conduct current between its collector and emitter terminals.
01:28This in turn allows current to flow through the bifilar toroidal coil,
01:32inducing a magnetic field.
01:34As the magnetic field grows, a voltage is induced in both windings of the
01:39coil, boosting the current flowing into the transistor's base.
01:43This positive feedback loop rapidly switches the transistor into a fully
01:47conducting state, allowing current to flow through the LED.
01:51However, the LED only lights up when the collapsing magnetic field induces a
01:56voltage of sufficient magnitude to overcome its forward voltage drop.
02:00This process repeats in a continuous cycle, with the LED appearing to remain
02:04constantly illuminated to the observer.
02:06The speed of this cycle can be adjusted by varying the inductance of the
02:10toroidal coil.
02:11In essence, the Jewel Thief breathes new life into seemingly spent batteries,
02:17demonstrating the ingenious ways in which simple electronic components can
02:21be harnessed to solve complex problems.
02:23Like, comment, share, and follow for more informative 3D videos.