Glad it was helpful! Thanks

Thanks for kind note

Thanks Mouli for nice words. The Egyptians built pyramids to be remembered. I am uploading videos😊😊And more seriously, I reached an age at which one realizes that it is more rewarding to give than to receive.

Yes i have also to say that your Videos are amazing in detail and accuracy, you cant and will not find any better things online. Maybe in a book and in a good lecture but even then this is just amazing! Imaging if more where doing such amazing work!

Great intuitive video.. I wish I could go back in time and see that before designing my first DAB converter

Thanks

Thanks

Thanks

Thanks

Thanks. Good points.

👍😊

Thanks

👍🤔

Thanks, Merry Christmas

תודה רענן. מה שלומך?

מצויין תודה. עוקב אחר מרבית ההרצאות שלך ומשתף עם המהנדסים בצוותים שלי. כולם נהנים!

👍

Thanks. Yes, I think this is the wave of the future. This and certainly future generations will not have the patient nor the motivation to go over pages and pages pf analytical derivations which are in fact superfluous today.

👍😊

Thanks Rob.

Thanks. Just had a peek at your channel. Repairing cars? Wow

@@sambenyaakov It is relaxing to kick and smash things with hammer and it will in fact repair them

Thanks

Thanks. There are many related videos in my KZbin channel. e.g. kzbin.info/www/bejne/p33SiYKip9aNebc

@@sambenyaakov So, after all, the mutual inductance and magnetization inductans are one and the same manifestation of reluctance of the core material. Lo and behold, I said to myself :D

See www.ee.bgu.ac.il/~pel/pdf-files/jour112.pdf

Thanks Angelo

The reflected leakage inductance to the primary.

Yes, different models are different visualization and can make perhaps easier the analysis (by hand) but you will end up with exactly mathematical expressions.

Thanks

This way of explanation is original. You can find relevant videos in my KZbin channel. Go to You tube and search "Ben Yaakov + a relevant keyword, such as leakage, transformer, coupled inductors..."

Please help me out by pointing to the slide number or minute in the video you are referring to.

@@sambenyaakov the slide number is 22, time is 20:05. On the left, upper model, you have divided LT2 by (k*k). Please let me know why is that and how it resembles an ideal transformer. Thank a lot

k (defined in PARAM) is the coupling coefficient between the original coupled inductors. You can check the validity of the division by k^2 by working out the inductance seen at the secondary with the primary open. Should be L22.

At 13:55 I say in recorded video that this is a mistake and it should be (1-k)L22, you probably did not listen😊 In all other points: you seem to be confused between inductors and reflected value of inductors. For example in 8:55 there is no L2*K .Rather, L1*k is seen from the secondary with a value L2*K . That is with a transformer you DO NOT put two inductors.

La=L11*k^2? left top side ? on slide 22?

@@sambenyaakov Thanks for your kind reply, professor. I have figured the derivation. WIsh you all the best in work and life.😀

The generic SPICE does not include a transformer only coupled inductors defined by L1, L2 and K (n= sqrt(L1/L2). You emulate an ideal transformer by making L1 and L2 large.

Primary 8uH gapped ? mH?

@@sambenyaakov 10mH gapped. Sorry not 8uH.

@@sujoybha The question is also, at which frequency are you measuring? Going too high will case the parasitic capacitances take over and your transformer becomes resonant, fooling many measurement devices. Try the lowest frequency that makes sense, 1-10kHz is very common, even if the frequency of application is much higher. Only very low inductance transformers in the micro henry regions are measured with 100kHz and above. If you want to be sure and see more, get a low end vector network analyzer. They measure over a very wide span of frequencies and show you all nasty resonances and other parasitic effects. They are available at reasonable prices as small bench top USB devices. Something like this. www.digikey.de/de/products/detail/trenz-electronic-gmbh/29069/9460077?RF%20Evaluation%20and%20Development%20Kits&Shopping_Product_RF%2FIF%20and%20RFID&productid=9460077&gclid=CjwKCAiAsNKQBhAPEiwAB-I5zSTMmW0dWNbqu4tWWGwLPSeyI8bDnKKtzDmLZSWZi6WteYdxaYRNChoCcWwQAvD_BwE www.sdr-kits.net/DG8SAQ-Vector-Network-Analyzer-3-Series?gclid=CjwKCAiAsNKQBhAPEiwAB-I5zXDY8vuXURT-gx1d0v1QT3CHqHqCY66yvBMGOAGOcwBKZ5LEDEmx4RoCaDoQAvD_BwE The E13/6/6.15 has no gap, you have to add it using a spacer. If you have 10mH with 256turns, this yields an AL of ~150nH/N^2. This is much lower than the ungapped 900-1300nH/N^2. And sure, a gapped transformer will have more stray inductance than an ungapped. How much, depends on the size of the gap and the position of the windungs (both windings on center leg inside one chamber, two chamers or even different legs of the core).

Hi, thanks. Please point to the minute in the video you are referring to.

@@sambenyaakov the time mark is 19:14, it's the definition of parameters in the pspice models listed on slide 22. I'm assuming all of the K's are the coupling coefficient, I don't understand what 1K means.

@@pbaemedan Thanks for pointer. Sorry for the confusion. K is indeed the coupling coefficient but...when you write in LTspice 1k (not 1*k) this is interpreted as 1000.

@@sambenyaakov thank you for the information. Your series on coupled inductors provides large amounts of information and understanding. Again, thank you.

Not sure I am following. Where is the turns ratio? What kind of filter, no rectification?

@@sambenyaakov a pwm filter for inverter. Np/Ns is 5.

Using leakage inductance for filtering may not be a good idea. For one thing you get a rather small inductance so you will need very large capacitance.

It's about 5mH primary leakage ( by shorting secondary). But I'm a bit confused about the value of L in the expression 1/(2pi sqrt(LC)). If I use 5mH, a C of 20uF would give about 600hz -3dB.

Professor I think I got it now. The value for L is ( Lp/N^2 + Ls). Ls is small (uH) so I ignore. So all leakage reflected to secondary is 5mH/25. If I use 40uH, the value for 1/2pi sqrt(LC) is 1.7kHz. Thanks for the good explanation of equivalent circuit reflected to secondary side.

👍🙏

Please indicate the minute in video you are referring to.

@@sambenyaakov 6:18

@@tanvimahajan1019 This is an independent source used to carry out the analysis. This definition of the test source simplifies the math.

@@sambenyaakov Still, this doesn't explain to me where this equation (I2=-jI2) comes from. Is there a typo here ? I understand that to get the output instantaneous power you would multiply v2 by i2.

@@RaedMohsen Long time since we communicated. I arbitrarily define a source jI2 (90 degrees with respect to I1) and the minus is due to the direction (positive is into the terminal)

Thanks Huseyin. No I am not using magnetic design packages. Have not found one that really saves me time. I will look into the software you indicated. Thanks for pointer. Sam

Did not see it. sby@bgu.ac.il or try sam.benyaakov@gmail.com

My email is wlee@cnu.ac.kr, and I think you received it. I wrote to gmail account. Thank you sir.

Hi Falk, I am afraid that the joke is on you. 1. The majority of people on the plant that write from right to left are Arabs, so how come you came to the conclusion that I am an Israeli? 2, You really do not need to play Sherlock Holmes, Look up my profile in LinkedIn or just google "sam ben-yaakov" 3.In the majority of my published work, papers, tutorials, videos, etc. I am usually drawing the inputs on the left. Which shows, again, that statistics that is based on one case is nonsense. 4. Drawing the input on the right or left has nothing to do with the language that a person speaks but on his educational path - what he saw when he was a student. 6. You wrote :"the input is on the right, the output on the left 😂 (your native language form your way of thinking)", so I understand that you think that I am a right thinker while you are probably a wrong thinker😀.