CircuitBread

100K SUBSCRIBERS 🎉 We’re proud of the milestones we’ve been hitting here at CircuitBread and grateful for the support of our viewers! It has not always been smooth sailing (as you can see in the video!) but we are glad for the things we’re learning to make our resources better every day. 🙌

Wishing you all a wonderful Thanksgiving! 🦃⚡

With Thanksgiving upon us, we want to extend our heartfelt gratitude to the Friends of CircuitBread. Your dedication to supporting both current and aspiring engineers is truly inspiring. We appreciate your friendship in our mission and the incredible resources and perks you offer to the engineering community. Visit our Friends of CircuitBread page to explore the wonderful offerings from our generous partners. Happy Thanksgiving! https://lnkd.in/dHaiCxUi Search Engine/Aggregator Friend: Octopart - Search And Compare Parts From Hundreds Of Distributors Distributor Friends: Rochester Electronics, LLC (Distributor/Supplier) - Free Technical Articles Sager Electronics - Power resources and value-add OnlineComponents.com - Bill of Materials Manager Supplier Friends: Same Sky Devices - Free Electronics Tutorials & Resources ebm-papst - Free Technical Articles PUI Audio, Inc. - Product Samples Digilent Inc - Partner Store With Academic Discount Pricing Triad Magnetics - Free eBook & Resource Library APEM, Inc - Product Samples Neutrik Group - Americas - Free Product Samples Omron Electronic Components- Americas - Relays, Switches & Connectors Knowledge Series Ohmite Manufacturing - Ohm's Law Calculator Orion Fans - Free Product Training Guides

Inrush current occurs when a system powers on and experiences a spike in current. Devices such as motors, motor drives, amplifiers, and power supplies typically have low impedance and high inductance or high capacitance, causing them to draw significantly more current than usual during startup. Capacitors in these systems can act like a short circuit until they are charged, leading to a current spike that can be many times higher than the normal operating current. Limiting this inrush current is crucial for device reliability. How do I protect my circuit from inrush current? https://lnkd.in/gdZe_GVu

Happy 0, 1, 1, 2, 3, 5… day! Fibonacci, a mathematician from Pisa, introduced the Fibonacci sequence in his 1202 book "Liber Abaci" to highlight the advantages of Arabic numerals over Roman numerals. This sequence, where each number is the sum of the two preceding ones, has significantly influenced electrical engineering. It improves various applications, including signal processing, antenna design, filter design, algorithm efficiency, chaos theory, and electrical resonance, demonstrating its broad and impactful utility in modern technology.

Get your priorities straight!

Lasers with a knot? 🪢 Caltech’s creation of "knots" in mode-locked laser pulses boosts laser stability, enhancing reliability in telecommunications, medical diagnostics, and sensing. This advancement supports more precise and dependable communication systems and sensors, helping engineers create better-performing electronics.

Excessive ripple current generates heat in a capacitor, and if this heat surpasses its maximum temperature limit, it causes damage or shortens its lifespan. A capacitor's ripple current capacity depends on its size, ability to dissipate heat, and thermal interaction with its environment. Larger capacitors handle heat better due to more mass and surface area, while smaller ones may fail sooner. Learn more about the ripple current specification in capacitors: https://lnkd.in/gH4ypDZD

The pitch of a connector is the distance between the centers of two adjacent pins. When designing circuits or buying connectors, it’s crucial to ensure both sides have matching pitches, otherwise they won’t fit together. This can be tricky due to varying standards and nomenclature. So, what is the 'pitch' of a connector and why does it matter? Learn more about the answer here: https://lnkd.in/gaRfnJ-3

Safeguarding Tomorrow! 🧯 The Shibaura Institute of Technology's new method for detecting arc faults in low-voltage AC systems is noteworthy because it directly addresses the significant risk of electrical fires, enhancing safety in homes and businesses. This innovation highlights the importance of improving electrical system reliability in our technology-driven world and has the potential for broader applications beyond just low-voltage systems. For more of this, connect with CircuitBread: Facebook: https://lnkd.in/gNf6Sfk7 Youtube: https://lnkd.in/gYWj_aBF Instagram: https://lnkd.in/g6c_5rmx Tiktok: https://lnkd.in/giPDq-pm