Thanks for your wonderful comment and sharing. I'll look into creating a video highlighting the differences between BJTs and MOSFETs.

The same here, I have ton of videos but didn’t grasp what is the point capacitor, but this video really helped me to understand the need of capacitor

You're welcome! Thanks for the comment.

Thank you for the comment. Very glad it was helpful.

Thank you for your comment. I do plan to produce more such videos.

I really appreciate your comment. Thank you for creating this and other wonderful teaching tools.

sovereign power Glad you found the video useful. Thanks for commenting and sharing. I'll be getting back into video production mode soon so please consider subscribing for future videos.

I would agree IF he did not use the term current because according to the person it can be ambiguous. Next, he should have shown how to use a capacitor to value an inductor with a multimeter. Let me try to make this a myte easier. Take an air plate adjustable capacitor larger in value than the inductor. (How can you tell? When the two are hooked up the capacitor will still have a value reading the multimeter.) Hook up your multimeter to the capacitor let it charge the capacitor and write down its value. Now hook up the inductor and the multimeter in parellel and also in parallel with the Air Capcitor. Let it charge until the multimeter (set to Ohms) stabilizes. Deduct the second capacitance reading from the first capacitance reading and that is the value of the inductor. By adjusting the Air Capacitor you can find different values in the inductor's tap points.

Funny, because my issue was the fact that they seemed so similar to one another.

+Hossam Zayed You're very welcome. My goal is to get students to see things in new ways that help them make sense of the world . Glad you found this useful and thanks for watching.

I have spent months studying circuits and discovered a great resource at Gregs Electro Blog (check it out on google)

+Chris Harvey I really appreciate your comment. Thank you for watching, commenting and subscribing. :-)

You have bragging rights if your a second semester Electrical Engineering student. It's not an easy degree to obtain. Glad the video was useful and wish I had access to a resource like KZbin when I was working on my EE degree. :-)

+Migueldeservantes Thanks. I believe strongly in compare/contrast to help students understand a concept better. Most books compartmentalize this information and don't make an effort to show how these concepts are related. I hope to produce more video's in the future to do a better job of this.

+Dorian McIntire I beg please make subtitles

Great! Thanks for watching and commenting.

With AC, you get a circulating current flowing between the inductor and capacitor that is not draw from the supply. Thus a correctly-sized capacitor across the supply can improve power factor and reduce current drawn from the supply in an inductive circuit.

+Enigma758 This is true. I've tried to keep the math to a minimum to keep from intimidating viewers I but would like to create a series connecting math to the real world. Thanks for your comment.

Too late...... I'm already intimidated, LOL !!! Great Video. I only wish KZbin had been around when I was a kid, I would have done so much better academically, with so much information available at my fingertips.

I've included a link to a circuit that I created to answer your question. Please go to the following link: www.circuitlab.com/circuit/q9262adx4sy5/lc-circuit-comparisons/ Let me know if this helped.

Thank you for your wonderful comment.

I agree there can be confusion due to the heavy damping in the circuit. My main goal was to demonstrate the phase relationship between the two components in a transient situation. It might be a good idea to create a video with three such circuits with: high damping, low damping and no damping. Thanks for watching and commenting.

Thanks for replying so quickly. Not a problem as long as the situation is pointed out by a tutor. May cause some issues for self learners. Having said that, it isn't always possible to cover all bases and keep it simple... Great vid.

+michael swipes Thank you very much. Did you find the graphics useful? I'm thinking about using this simulation software more often if others find it beneficial. Thanks for watching and commenting.

That information is available in the video description information.

It did discharge. The inductor electron current flowed into the positively charged top plate of the capacitor and removed the charge on the capacitor. If you watch the video carefully you can see the bulb in series with the capacitor get very bright for an instant while the capacitor was discharged due to the inductor current.

Yes it was,but i was thinking about the LC circuit, which produce oscillation I mean capacitor discharge and charge the inductor then inductor discharge and charge the capacitor, over-all produce undamped oscillation. Will this circuit not behave like that after switch get off? And thanks for replying my query sir👍

If you look at 2:09 the correct formula was shown. A typo correction was made at 2:14 after I transposed L and R. You may not have noticed the overlay of the correct information.

Capacitors are used in many ways. They are commonly used for coupling circuits and to handle transients in power supplies. the capacitor in the video is being used in a 'damped' LC Tank circuit to show how the two components are complimentary.

Gabe, I do have another video about the two devices together. Check out the following link and let me know if you find it useful: kzbin.info/www/bejne/invIYayblLSjndU Thanks for the nice feedback.

The answer to your question is located in the video description information.

You're welcome, very glad you found this useful. I really appreciate your comment.

I'm not sure how this would work. UPS's must be specially designed to provide instant on capability and unfortunately there is no easy fix for this problem.

Simulation glitch.

*sorry discharging when switch is closed.pls confirm when it getting charged.

Things are complicated. When the switch is first closed the capacitor is charged almost instantly since the resistance between the power supply and the battery is very low and current leads voltage in a capacitor. The inductor currents lags the voltage so it takes time to build up current. Once the capacitor is charged it can only discharge through the inductor and since the bulbs have resistance the electrons move back and forth between the capacitor and inductor but the energy quickly decays since it is lost through he bulbs.

What we call "Electricity" is usually due to electrical current which is the flow of charge (electrons in wires). A concentration of more electrons than protons in an object or part of an object (or vice versa) produces an electric field. The flow of charge produces what we call a magnetic field which is really another form of an electric field produced by relativistic effects (Einstein's theory of relativity). It can be complicated so usually simple analogies are used to explain it.

Look in the video description for the link to the simulation tool.

The light bulbs are turning the stored energy of the capacitor into heat and the circuit is highly damped so it can only oscillate for essential a single cycle.

Capacitors simply store charge and as a result store voltage (V=Q/C). More charge creates a higher voltage for a given capacitance. Capacitors store voltage exactly because they have infinite resistance between both terminals. Current flows into a capacitor because the electrons can "feel" the positive charge on the other side of the thin dielectric inside the capacitor. An AC voltage applied to a capacitor causes it to constantly charge, discharge, and reverses polarity. The continual charging and discharging is caused by current flowing one way and then the other way. Once you understand that process everything else makes sense.

Look in the description and comments of the video for links to the software.

+Prathamesh Vichare This particular circuit is DC, to help simply the demonstration, although inductors and capacitors are used extensively in AC circuits also.

Thx a lot Dorian .... I have 2 more question ,1) where we use AC capacitor and inductor circuit in normal life? 2) Where we use DC capacitor and inductor in normal life?

+Prathamesh Vichare In AC applications inductors and capacitors are used to build transmitters, couple ac signals from one part of a circuit to another, filter signals, create phase delays in motor circuits and many other things. In DC application these devices store energy, create delays for timing circuits, smooth out DC in power supplies and more.

Thx a lot....this info is very useful for me...

Not really since the capacitor would create a current spike when you closed the relay. Capacitors are typically used across relays to absorb inductive spikes however.

Dan Mart You're welcome! Thanks for your feedback.

You're welcome. Thanks.

+Bob “bobdabiulder” dabiuld The program is called the Circuit Construction Kit and its free from PhET. Google PhET and you'll find it.

Yes, it was a typo but I crossed it out and superimposed the correct formula in the video long ago. You should see this correction in the video.

strange, you're saying i should not be able to see the incorrect formula?

You should see a strikeout over the original formula and the correct formula underneath. I can see when I watch the video.

With just a capacitor the energy in the capacitor would remain stored when the switch is open. With just an inductor the magnetic energy due to electron movement in the inductor would create a spark across the switch dissipating most of the inductor energy in the form of heat and light in the spark.

So, when the current flows freely through the inductor, the inductor's magnetic field is gone?

No. Anytime current flows through an inductor a magnetic field is created. Anytime a magnetic field is present it will attempt to maintain the current.

Dorian McIntire so.... When current is flowing thru inductor, then inductor is charged, and cap is discharged? 7:22

Inductors are fully "charged" when current is maximum and voltage across inductor is zero. Capacitors are charged when voltage across the capacitor is maximum and current is zero.

Dorian McIntire isn't that a description of the state of each, with switch closed, after settling?

Yes

Thanks. Nice video.

Thank You!

Your comment is greatly appreciated.

Thanks!

Vũ Đức Thiện Thank you. The software used is from PHET and is available at the following link: phet.colorado.edu/en/simulation/circuit-construction-kit-ac-virtual-lab Enjoy.

Reactance would come into play. If the frequency matched the resonance frequency of the two components the current would circulate back and forth and very little current would be drawn from the AC source.

Mechanical movement, such as a flywheel. The energy due to electron movement can be stored in devices such as superconducting magnets.

Thank You.

This is actually a bad question. The most correct answer for the creator of the question, I suspect, would be a resistor. Inductors and capacitors are actually reactive devices that provide reactance, not resistance. Reactance is an active opposition to current flow versus a passive opposition to current flow.

@geniusgirl fari : it behaves as... an inductor! 😁

Thanks!

Voltage, across a capacitor, is created when charge flows (current) and accumulates across the capacitor plates. The general way of referring to this phenomena is that current leads voltage for capacitors. The reverse is true for an inductor since inductors resist changes in charge flow and a voltage must be present to create the charge flow so this phenomena is described as voltage leading current.

@@DorianMcIntire Thank you for your time to reply! You made it more clear. However i still don't get what actualy makes this difference.. is this a property of their nature? (electromagnetic buildup vs electric buildup) or is it something imposed by humans, by design to make them so "complementary"? Thank you, and don't bother answering if you find my inquiry tedious...

Their complementary nature is due to the complimentary nature of electric and magnetic fields. Electric fields are the result of charge position and magnetic fields are the result of charge motion. Changes in position imply motion and motion implies a change in position and this results in a complimentary behavior of the two components.

@@DorianMcIntire I get it! Thank you!

Titas Bhattacharya You're welcome. Thanks for commenting!

You're very welcome. I'm glad you found the video useful. Thank you for watching, sharing and commenting.

My approach is that all circuits involve time constants since resistance is a part of all circuits except perfect circuits. All power supplies have current limits, all conductors contain resistance and all loads (light bulbs) contain resistance. I always start using practical circuits and discuss ideal (non-existent circuits) later. Whether capacitors are charged or uncharged makes no different. In fact an uncharged capacitor, creating a transient condition, is a better example of this property. When applying a voltage to such a capacitor the voltage across the capacitor will not instantaneously follow the applied voltage since a time constant in one form or another is always involved. The same conditions are true for inductors except that an infinite rate of change is not possible for inductors so these devices are subject to the same constraints demonstrated in a capacitor circuits. All instruction should begin with practical circuits and we can discuss perfect circuits with infinite current capabilities and zero resistance at a later time.

A slip of the tongue in the heat of the presentation. 😊

Using amperage instead of current is like naming speed MilesPerHourAge. We typically do not name things after a unit used to measure an attribute for that thing. If a student knows nothing about what an Amp is (actually an attribute for something they need to know about) they are not necessarily aware that the process involves MOVEMENT in working electrical circuits. Additionally, current suggests flow which helps students visualize and gain an intuitive grasp of what is really happening in a wire that carries moving electrons. I typically tell my students, to help them understand electrical systems, that Cause and Effect exist in most energy transfer systems, including electrical systems. CAUSE is voltage and EFFECT is the resulting movement of electrons (current).

@@DorianMcIntire The problem's reference is the misuse of the term current. However you used it correctly and Never used amperage which also causes vague understandings. I have even found the misuse or vague use of "current" in books! A novice can get quite confused when they attempt using volts, amps, watts & then current. It was one of my pet peeves as news letter editor while writing about wave propagation and electronics for an amateur radio organization (FARA and several nearby organizations who copied my work) in the mid 90's. I re-read what I had written and should not have been abrasive but been more concise. My apologies. I did enjoy your work! Newly Subscribed.

I can understand how things can get very confusing for novices with the many different ways books and articles can get loose with the terminology. 'Voltage' has fortunately replaced 'EMF' in many older textbooks but I still see it a few new textbooks. The current trend seems lean toward 'voltage' which seems much more natural since we don't call a voltmeter an EMF meter. BTW no offense taken and thanks for the sub.