Full 1 Hour Video AC Circuits: www.patreon.com/MathScienceTutor Direct Link to The Full Video: bit.ly/3vEFYjI Physics PDF Worksheets: www.video-tutor.net/physics-basic-introduction.html Final Exams and Video Playlists: www.video-tutor.net/

Last minute cramming. Fell asleep right at the end. Woke up to a loud af chicken nugget commercial. This is my life now.

I always look for your videos, they are simple and easy to understand. Such teachers like you makes me love physics more.

This simplified what my teacher overcomplicated. I appreciate how concise and simple you made all of this

Got an Electrical engineering midterm in 24 hours. Thank You 🙏

Dude, you're a genius. I planned to skip these questions in my upcoming FE exams but then I decided to watch your video and lo and behold, you've made it so easy. and even explained what's not in the question. Thank you.

Many many summer's ago i stumbled upon this matter, keep up with those lectures bless you and your family and upbringing.

If not because of JG video, I don't know where I'll be today. Always teach from scratch until someone understand it. I always had A in school anytime I consult JG videos. You are not better than the rest but Best among the best.

I have learned more from the organic chemistry tutor than I have in any lecture hall.

Love this guy! he's far better than khan academy with explanations!

You saved my degree. I am forever grateful.

Problem at 4:30--the current cannot decrease exponentially as stated when the switch is opened because open switch = open circuit = zero current, leading one to conclude that current decreases to zero instantaneously. In practice, as current decreases at a very high rate when switch is opened, di/dt is very high, energy stored in coil's magnetic field is discharged into circuit at a very high rate, a very high voltage is developed in the coil opposing the drop in current, that voltage opposes the battery voltage and is many times higher, and the air between the opening switch contacts is ionized, allowing a spark of current to flow in the direction opposite to the original current to dissipate the power supplied by the inductor. You have here the basis of the battery-powered automotive ignition circuit.

i know it's an old vid but you have excellent talent! I'll crush the test thanks to you

he said LR rather than RL but still managed to understand what a guy

Things gets simplified here. Thank you very much

Thanks❤ May God bless you abundantly ❤❤❤

Thank you, oh my god. Also 10/10 accent

thank you so much for your informative tutorials

Yo I had no idea Mark Wahlberg was so good at Physics. All kidding aside, your videos are dope and have really helped me.

I have whole elcetro mechanics in back log and i have exam on this Friday today is tuesday. I gonna put my bet on you.

Exam in exactly 24 hours, I’d say I’m on the lower end of procrastination compared to some here, but I had to spend the last 5 days Nodal, Mesh, Linearity, Max Power, Thevenin’s, Norton’s, Source Transformation, Op-Amps, Capacitors, RC Circuits (still working on getting that down) because I took this entire semester for granted aaaand now I’m here. Wish me luck lmao

great thanks bro. its simple to understand.

You are amazing man! Thanks a lot!

Another great set of examples helping us to understand the intricacies of these calculations. I don't yet understand how capacitors and inductors differ in their purposes for a single circuit. When do you use one or the other for a single circuit and why?

Thanks for all you do 🤗

My exam is tomorrow. Wish me luck guys!

@"The Organic Chemistry Tutor" - Can you possibly explain me one thing that I find hard to understand. Lets say we have an inducting coil, but it is make of a super-conductor. We fill that super-conducting coil with current and store energy in magnetic field that is created. We unplug the coil from the current source and current flows forever, because there is no resistance. Now comes the difficult part I don't understand: since now energy is stored in a magnetic field, and stored energy is a state of higher potential, wouldn't be normal to expect magnetic field to want to collapse back to zero and in process coil current will fade away to zero, as well? Essentially, never mind that resistance in super-conductor is zero, the magnetic field would want to collapse, regardless of what resistance is, because it's on a higher potential?

Nice, which app does he use to make this videos?

For the second problem... Why do we use 0.174A as our current while we said it changes? Should we not use the max current driven by the battery?

3:34 how do you put that on a calculator and got 0.472 amps? I got syntax error.

For #1, we used the I equation which represents current increasing, the 1-e one, but we got a +EMF which tells us that the current in this circuit is decreasing?

16.31 So our final answer for part a should have had a negative even though there wasn't one in the equation?

Nicely Explaination

question: how does it work if im trying to figure the time for the current to reach its maximum value since you can't natural log 0?

How did we come up with the formula to find the current after so many seconds?

Can I calculate the energy stored in a coil without having the current?

Thank you 😊

the equation used at 3:20 is wrong when the circuit is open the is no 1-e the 1 is obsolete

the -ve signs in 7.28V 4.72V are totally wrong. If the L is replaced by R2 will u get -ve voltages as well?

we said that the inductor doesn't dissipate power so why can we find the value of the power here???

you are amazing!! thank you

Am I wrong or could you have solved the 99.4% by setting the 1-e^(-t/~) =.994 then do the natural log?

May be I will pay all the fee to this guy......

how can you get 0.472A and what is the value of e?

What happened to part d at the end?

I come up with a conclusion. 1. A teacher bad at teaching is not your fault. 2. If you failed to study ahead before your class is your fault. -------------------------------------- If you will have both conditions, it would be great. However, not everyone is lucky to get 1. but here is the organic chemistry tutor.

What does the "e" mean? Ln?

Sw-- sewage only -- ur descript -- sewage facility only! There be: "ON | OFF only!" Shared circuit then! Radar net -- Oriental Tribal - right now -- TTY static!

Man, I still don't understand this. I wish your vids had more complex and useful problems.

I think based on your orientation of + and - on the voltage drops of the passives that your sign was wrong. Just a thought I could be wrong as well.

at part d) is there another way how to calculate the voltage across the inductor?

Cramming is literally the fuel to energy boost.

Gud explanation but audio is low

Plz add videos for rl rc and rlc transients for dc excitation..

It seems that in exercise 2, your answer didn't answer the question (d)

you made a mistake in question d. it says that "at what rate" but you solved directly the power

my new best friend

RL circuit time domain When a magnetic field inside a solenoid varies with time, a curly non-coulomb electric field is observed both inside and outside the solenoid. A coulomb electric field results and we note that an attempt to change the current in the coil induces an emf in the same coil and makes the coil sluggish to respond to current changes. Electrostatics and circuits belong to one science not two. To learn the operation of circuits it is instructive to understand Current, the conduction process, resistors and Voltage at the fundamental level as in the following two videos: i. kzbin.info/www/bejne/ioXXpWVul5aXj9E and ii. kzbin.info/www/bejne/bnO0fpKurJeFnNE It is not possible in this post to discuss the production of induced emfs in inductors in detail. The last frame References in video #1 lists two textbooks 3 and 4 which discuss in detail with a series of sequential diagrams the physical processes to explain the operation of inductors and RL circuits. RL circuit frequency domain The existence of a sinusoidal current resulting from the application of a sinusoidal voltage to an inductor is a characteristic of the non-Coulomb electric field that is proportional to the rate of change in current causing a changing magnetic field. The current is a result of an opposing Coulomb electric field, which is a result of polarization by the non-Coulomb electric field associated with the changing magnetic field, and the current is a consequence of the resultant field of the applied field and the Coulomb electric field in the inductance coil. Inductors find applications as filters in power supplies and in resonant circuits in tuned amplifiers. If we increase the “frequency” of the input voltage to an inductor, the “rate of change” of the input voltage and the applied field is “greater than” the rates obtained with applied voltages at lower frequencies. At low frequencies, this causes a smaller induced opposing electric field and emf, therefore, large currents will flow within small intervals of time in the coils of the inductor. In the limit, if the input is a dc voltage, the current will become so large that the inductor will burn out. In an inductor, the opposition to the applied voltage which is changing the current is instantaneous and so, the current can only follow after the applied field has overcome the opposing emf. In an inductor for sinusoidal currents, the current lags the voltage by 90 degrees if the inductor is pure, and less if a resistance is in series with it; the inductor fights before current flows. If an inductor weren’t to fight, you will get energy for free! Faraday's Law and self-induced emf - video lectures by North Carolina State Univ faculty This is a link to a video lecture by NCSU faculty on Faraday's Law. Important 7. Faraday's Law Watch from 8.0 minute. Ch22L1a kzbin.info/www/bejne/oaWqfWiZeqdraKssi=u9vH33gaX1Wy5JvF 8. Non-coulomb electric field - curly-patterned fields Watch from the beginning. Ch22L1b kzbin.info/www/bejne/pIeZqZpjhNqrpbssi=UjJBG3wDjazfeQMM The second link is to a video lecture on self-induced emfs in solenoids (inductors). 9. Self-induced emf in a solenoid Ch22L2a Watch from 10.30 minute. kzbin.info/www/bejne/iHuTe5KKgZKqi7Msi=qPZ74uD-m6weyFlb Low pass filters are built using L-R circuits in simple applications. Therefore, we say the inductor “blocks high frequencies” and acts as a “short circuit” at low frequencies as if the inductor was not there but a wire. It is not possible in this post to discuss in more detail current in inductor circuits and inductive reactance with sequential diagrams (textbook 4, see below). The last frame References in video #1 lists textbooks 3 and 4 which discusses topics on inductance and inductors in more detail using a unified approach and provides an intuitive understanding of inductive reactance. It also describes with sequential diagrams how an inductor develops the induced emf. Textbook 4 is here techsarworld.com/product-detail/fundamentals-of-electric-theory-and-circuits-559 shows how the current lags the voltage across the inductor by 90 degrees for sinusoidal input voltages using sequential diagrams. PPTs and Videos with animations for all the ten chapters and a few applications Regulated DC Power Supply, Differential Amplifier and Transformer coupled audio power amplifier of the book Fundamentals of Electric Theory and Circuits are available for download and viewing here techsarworld.com/download-resource/fundamentals-of-electric-theory-and-circuits-559

thank you so much

And basics of transients

Thanks!

thank you

Thanks

God bless you

Awesome

It helllllps a lot thankyousosososomuch

Big day today

14:16

for the time constant i got 0.02

I watched it.

9:59 hahah feel you bro

It would be better if the text is removed

god

Thanks!