Dear sir i just subscribe to ur channel after this videos will u plz teach us the how to design circuit how to choose what calculation formulae require... to trace the whole circuit .
Thank you for your amazing video as always. I had a short-circuit in my brain here 4:48, though. What were you doing? I really have no clue what's happening there.
Ok sorry im not very talentet in Curcuit stuff but... Is the Condensator not pulling the Drain under the Gate Voltage in stead of adding up the Supply and the Condensator? I realy tryed to Rap my head around it. But i cant see how it schould pull the Voltage over its supply. Bevause 2x 12 Volte parallel are still 12V just in Series they get 24V. So i think the Condensator is "Chargin Negativ" and "Pulling Charge" away from the drain to make the Voltage differenz. Caus it cant charge over its supply.
Good video, was using it to refresh my knowledge, one point, thermal runaway can be eliminated using a source resistor, so as 'I.s' increase, the voltage across the resistor increases reducing Vgs - just a form of negative feedback, can also be used on bipolars.
I am so glad so many people like yourself are out there, getting on youtube, and expanding their futures, while teaching. I'm an old fart, I've been working in this field more than fifty years, but you've taught me more than a thing or two, "surface mount, liquid solder, oven soldering", what's this world coming to? Very nice demonstration, thank you.
If you made a full blown course of how to get started in constructing technology I’d pay for it. I love these videos would love to learn the basics so I could do projects like this.
Another reason to use MOSFET driver: cross-conduction prevention that could prevent your Metal Oxide Silicon Field Effect Transistor into becoming Magically Obliterated, Smoke n' Fire Emitting Transistor in a bridge configuration.
Most H-Bridge already have driver and cross-detection or so-called dead-time, if you need the power by using 4 (or 6 for brushless) stand-alone MOSFET's, you should not just use mcu-gpio to drive them that is for sure.
@@greatscottlab can you help me in the 'buck boost circiut' code. in my area attiny is not available ım limited to nano and registers in code not compatible
@@alexandersolon6548 I assembled a three phase inverter to test different digital control schemes, and evaluate how it affects the output harmonics. So this video summarize the all chapter where i explanied the mosfet's response and why you need the driver
I started viewing your video nearly 4 years ago when I didnt knew anything about electronics and now I know things about electronics still I am enjoying how you explain
Genuinely the best explanation of MOSFETs and how to drive them I've ever seen. The only thing missing, which can trip people up, is depletion vs enhancement mode for both P and N channel
That moment when you find out what to do with mosfet...i remember it very well That was a moment i started to prepare myself for real electronic jobs, old yugoslavian repair equipment, mostly chinese parts and basic knowlege. Today i still work with those tools and equipment but i smoke weed
While Iam watching your video, a music video came where two teenage boy and girl singing rum pum pum song please give the name of artist or link if you can or any one.
we have a youtube channel that deals with Arduino,ATmega328P,Java,Serial programming ,robotics. So if you like these stuff do Subscribe. Sorry for annoying
For some of those applications, you can use a MOSFET driver directly to drive the LED Load. The ones for example in my inverter are rated for 9 Amps and actively drive high and low, which is useful if you want to encode data on a fiber or laser diode.
I’d love to see you discuss the consequences of using a 3.3v PWM output as provided by an ESP controller. Currently I have some designs where I’m providing a 15vdc gate driver voltage to facilitate good MOSFET switching, but that’s now a second power supply on the pcb (in addition to the 5vdc one to drive the ESP). The MOSFETs are driving 24vdc LEDs.
I've built various circuits based on MOSFETs but all the time Optocoupler based circuits works best for me and also would love to share that it's the only cheap, hassle-free and efficient way to drive the MOSFETs 😄
Miller capacitance, the one you are talking at 6:30, is why we can't have nice things in the world. It really makes interesting engineering challenge, and is unavoidable. I once was designing high efficiency inverter, and instead of just using 4 MOSFETs, I ended up with 4 MOSFETS plus extra 48 transistors (FETs and BJTs), plus a 16 channel DSP driving scheme. Crazy, but it worked beautiful. Required a lot of simulations, including parasitics. Using driver ICs is probably better tho, both from complexity perspective, isolation, and performance (ICs can bring loop area smaller, and and reduce inductance). Also 4-pin FETs are getting popular, especially the SiC and GaN ones, where there is a separate source pin, just for driving. The pin has own path to the package for source, so there is no voltage drop when there is current flowing, and it has lower inductance, all helping with turnoff time and voltage clamping.
I work in a start-up environment where new engineers think I over complicate stuff, without properly looking into specifications. Your video will be useful for me to pass them to get educated
Your ability to deMystify some aspects of electronic engineering is of great credit to you, You have helped me so very much as a "Mature" student (I am 62 and still learning.) Many thanks and keep up the good work !!
Very well done videos. You have a natural talent for teaching. You lay out the concepts in a logical way which makes them easy to understand. I have a formal education in electronics, but informal instruction like this through RUclips is really amazing for the hobbyist without a formal education. You have earned a new subscriber. I've used plenty of MOSFETs in a variety of circuits in the past, but even professionals seldom just know how to do these things from memory. Unless you build the same circuits all the time it is often helpful to study some references before designing anything. I think videos like this are even useful for professional EEs who want to brush up on the concepts before diving into a design. I just bought a broken plasma cutter. It works just like a big off-line SMPS by rectifying the 240 VAC in to 350 VDC, then switching the 350 VDC with a variable current limit and rectifying the resulting AC to develop the 10-60A needed for cutting up to 3/4" (19 mm) steel like the proverbial hot knife through butter. On the switching board are 16 FETs arranged in four groups of four in an H-bridge. I can see two rather large torodial gate drive transformers on the board. I am looking forward to the next video to make sure the technical details of using gate drive transformers are fresh in my mind.
Great video. I have been using MOSFET drivers in my designs for quite some time now, without really knowing (or caring, tbh) about their inner working. Thanks to you, I can now make better component selections and designs. :)
Gosh, I've blown up a lot of components learning about FETs. There's a lot to get your head around. It gets even more exciting when you have inductive loads. Gate drivers and bridges definitely are very useful.
Great breakdown of one of the world's most popular devices and circuitry. This is used in practically every switch mode power supply out there, including laptop power supplies and desktop PC power supplies, just to name a few. Power electronics including switch mode power circuits will become even more popular with electrification of vehicles. Let's all get ready for dangerous high voltage digital circuits! Yes!
Huge thanks for including your workings in the videos ... so often folk try to cover such topics and just hand-wave the selection of component values. Big takeaway... if in doubt, add more MOSFETs!
This thing about driving MOSFETs gave me a lot of headaches to undertand when I was developing my first voltage inverter 1 year ago. I wish I could have watched this video back then, it would be a great help. Anyway, great video as always, even not not being a good english speaker, I learn a lot with your videos, it's also a good way to train my listening.
Really like your in-depth videos on subjects like this one. Saves me lots of time wondering why the magic smoke escaped from my MOSFETs ;-). Looking forward to part 2!
My HVAC electrical teacher's favorite line; "once the smoke comes out, you can't put the smoke back in" (usually referring to transformers, as several dudes hooked them up backwards 😂)
Bootstrapping with a diode and capacitor is a great hack. Just make sure your duty cycle doesn't stay at 100% long enough to discharge the capacitor to a voltage that will no longer turn on the MOSFET. For some applications (AC to DC inverter, buck converter with undervoltage protection, etc.) this is a perfectly suitable option.
@@mohammedyasarshaikh4090 Maybe you have connected the MOSFET backwards? If the drain and source are swapped, it will act like a diode instead. If you've checked that, use a multimeter to measure the gate voltage of the MOSFET and make sure your microcontroller is actually commanding the motor to turn off.
Such a good explanation with the worked example showing the charge times and average current draw. Correct me if I'm wrong, but my main alarm bells take home from this is that, if using a microcontroller to occasionally switch a mosfet, the resistor on the gate input probably isn't necessary, as the amount of time in a significant over current state is so miniscule, nothing will ever have time to get hot enough to melty melty. However if I'm fast switching a mosfet from microcontroller and the frequency is starting to interfere with the amount of time it takes to actually turn the thing on, I'm essentially spending all of my time *averaging* an over current situation... so in this case I really should be using a resistor (or indeed a dedicated driver).
noting of course that average isn't continuous, so it isn't even as bad as suggested but, if the over current is significant, then this makes things worse. I guess a reasonable analogy would be that no one ever died from a static electricity shock... but if we received them at high frequency over a sustained period... we'd be pretty unhappy bunnys.
At 8:37, your resistor setup could be improved. With your current setup you’re creating a voltage divider. You should put the shunt before the series resistor instead to get the same benefits with no voltage division.
4:40 Thermal runaway is always fun. I remember one time in lab I accidentally hooked up a BJT wrong and it exploded in my face. We were wearing PPE, so my eye was saved, but a large chunk pinged right off my safety glasses. I probably would have been injured if not for the safety glasses. Remember kids wear your PPE :).
This video Could have helped me a lot in my university project. I remember i faced issues just because i wasn't using a gate driver. That time electronoobs video on boost convertor helped me to figure out the issue
In your intro, you imply that Vth is enough to fully turn on a MOSFET, which is a misconception that far too many people seem to get. Vth is only enough to barely start conducting, and you need to go a few volts beyond Vth in order to reach the minimum Rdson.
Great video, so to summarize, the simplest and safe way for driving a fet from an arduino is to NOT connect the gate directly to the pin, correct? A resistor will be required, notwithstanding the increase of switching event time?
Great explanation! I knew a bit about MOSFET drivers, but still, I've learned something new from this video :) I'm currently experimenting with gate drive transformers, and I think it is an excellent topic for a video because many people don't know how and why to use them. If there is one thing that would fit here, that is a video about snubber networks :) Thanks for the awesome video and explanation.
One thing is the resistor configuration to discharge the mosfet might depending on which type of mosfet ; P type or N type, and whether its enhanced mode( normally off) or depletion (Normally on)
@@tinygriffy I've tried brother. After 32 KHz with heavy load, waveform of Vgs looks like capacitor charging and discharging. When in low load, it looks like square wave. I am using 12V 10A battery to drive gate.
@Harsh Desai The reason that your vgs looks like a cap charging is because a mosfet gate is a capacitor. As nico nico said you can choose one with less gate capacitance (would be specced in coulomb on the datasheet) or to drive the gate in a more aggressive manner. Is there any reason you need to switch above 1 MHz?
I remember reading about the very first commercial Mosfets (often called IgFETs then) being announced and doubting they would become very popular (it's not like the were cheap!) and boy, was I wrong!
Very Nice and informative video greatscott! These are an absolute gem for engineering students! And they help tremendously in making projects. Thank you for sharing your knowledge with us!
Part 2: ruclips.net/video/B7Eqrf2M-Iw/видео.html
Dear sir i just subscribe to ur channel after this videos will u plz teach us the how to design circuit how to choose what calculation formulae require... to trace the whole circuit .
Thank you for your amazing video as always. I had a short-circuit in my brain here 4:48, though. What were you doing? I really have no clue what's happening there.
Ok sorry im not very talentet in Curcuit stuff but...
Is the Condensator not pulling the Drain under the Gate Voltage in stead of adding up the Supply and the Condensator?
I realy tryed to Rap my head around it. But i cant see how it schould pull the Voltage over its supply. Bevause 2x 12 Volte parallel are still 12V just in Series they get 24V.
So i think the Condensator is "Chargin Negativ" and "Pulling Charge" away from the drain to make the Voltage differenz. Caus it cant charge over its supply.
Good video, was using it to refresh my knowledge, one point, thermal runaway can be eliminated using a source resistor, so as 'I.s' increase, the voltage across the resistor increases reducing Vgs - just a form of negative feedback, can also be used on bipolars.
PS: another way, is to generate a seperate power rail above the drain voltage-for those thinking of doing this.
I am so glad so many people like yourself are out there, getting on youtube, and expanding their futures, while teaching. I'm an old fart, I've been working in this field more than fifty years, but you've taught me more than a thing or two, "surface mount, liquid solder, oven soldering", what's this world coming to? Very nice demonstration, thank you.
If you made a full blown course of how to get started in constructing technology I’d pay for it. I love these videos would love to learn the basics so I could do projects like this.
Another reason to use MOSFET driver: cross-conduction prevention that could prevent your Metal Oxide Silicon Field Effect Transistor into becoming Magically Obliterated, Smoke n' Fire Emitting Transistor in a bridge configuration.
b-bridge? As in...
FULL BRIDGE RECTIFIER?
Yep. True
Exactly! H-bridge drivers have dead time for that...
@@greatscottlab Hi mate... When is it coming the part 2? 👍
Most H-Bridge already have driver and cross-detection or so-called dead-time,
if you need the power by using 4 (or 6 for brushless) stand-alone MOSFET's, you should not just use mcu-gpio to drive them that is for sure.
It bothers me that you always scrub the highlighter until it smears. Sorry, I couldn't hold it back any longer.
..... I CAN'T EITHER! Finally somebody said it. That and underlining things until that pen is definitely bleeding through the page..
I thought it is only me. it's soooo annoying to see that and writing on the same letter twice.
my daughter does the same thing, she is 3y old.
Yea like wait the to dry first before highlighting them!! omg!
@@gene_Code sorry but your sentence is.....let's say, out of order. Kinda the same annoyance.....lol.
What can I say except give him an award.
Thanks mate :-)
@@greatscottlab You are most welcome
Make a fm transmitter
Salt bae isn't a good cook and only a butcher
@@greatscottlab can you help me in the 'buck boost circiut' code. in my area attiny is not available ım limited to nano and registers in code not compatible
Dude you just resumed my B.S. Electrical Engineerging thesis on like 13 minutes.
WTF
Just awesome.
Bullshit electrical engineering? I'm also good at it.
what was your thesis about?
@@iNezerroth Basically feels like it
@@alexandersolon6548 I assembled a three phase inverter to test different digital control schemes, and evaluate how it affects the output harmonics.
So this video summarize the all chapter where i explanied the mosfet's response and why you need the driver
@@anl2468 can i have a link to the paper? i would like to read it.
If you had 100 videos about driving MOSFET gates, I would probably binge what all of them today. This is great, thank you.
You know what, there is something therapeutic and calming about the way you speak. I've been subscribed for years and just had a moment.
I started viewing your video nearly 4 years ago when I didnt knew anything about electronics and now I know things about electronics still I am enjoying how you explain
BYE THE WAY I AM ALSO MAKING ARDUINO PROJECTS PLEASE TAKE A LOOK :)
I have an exam on mosfets in two days. You have no idea how much this helped me
"The *field* of power electronics"
IC what you did there Scott :)
Edit: Damn, thread ended. Was hoping we'd see more electronics puns.
;-)
uhh, that was a pun? nah
I Gauss yer trying to be funny.Try to resist the urge to use puns or be inducted into the hall of lame.
@@tinygriffy Really? I'm genuinely Schottk'd!
Damn, made me lol
The slowly blackening tip of the yellow highlighter gives me flashbacks to college.
This is exactly what I was looking for. Really Great scott!!
Great to hear!
@@greatscottlab Hi mate... When is it coming the part 2? 👍
Genuinely the best explanation of MOSFETs and how to drive them I've ever seen. The only thing missing, which can trip people up, is depletion vs enhancement mode for both P and N channel
13:15
"But, of cousre, you don't know everything yet"
It's me, in every aspect of my life. Especially when I think I know what I'm doing.
I have no idea what you're talking about, but I do like your videos. Job well done...
Wonderful Video! I didn't know about mosfet drivers before this video but now I know what to do with them, Thanks!
Glad to help!
That moment when you find out what to do with mosfet...i remember it very well
That was a moment i started to prepare myself for real electronic jobs, old yugoslavian repair equipment, mostly chinese parts and basic knowlege.
Today i still work with those tools and equipment but i smoke weed
While Iam watching your video, a music video came where two teenage boy and girl singing rum pum pum song please give the name of artist or link if you can or any one.
@@greatscottlab make a fm transmitter
we have a youtube channel that deals with Arduino,ATmega328P,Java,Serial programming ,robotics. So if you like these stuff do Subscribe. Sorry for annoying
For some of those applications, you can use a MOSFET driver directly to drive the LED Load. The ones for example in my inverter are rated for 9 Amps and actively drive high and low, which is useful if you want to encode data on a fiber or laser diode.
I’d love to see you discuss the consequences of using a 3.3v PWM output as provided by an ESP controller. Currently I have some designs where I’m providing a 15vdc gate driver voltage to facilitate good MOSFET switching, but that’s now a second power supply on the pcb (in addition to the 5vdc one to drive the ESP). The MOSFETs are driving 24vdc LEDs.
I've built various circuits based on MOSFETs but all the time Optocoupler based circuits works best for me and also would love to share that it's the only cheap, hassle-free and efficient way to drive the MOSFETs 😄
Miller capacitance, the one you are talking at 6:30, is why we can't have nice things in the world. It really makes interesting engineering challenge, and is unavoidable. I once was designing high efficiency inverter, and instead of just using 4 MOSFETs, I ended up with 4 MOSFETS plus extra 48 transistors (FETs and BJTs), plus a 16 channel DSP driving scheme. Crazy, but it worked beautiful. Required a lot of simulations, including parasitics. Using driver ICs is probably better tho, both from complexity perspective, isolation, and performance (ICs can bring loop area smaller, and and reduce inductance). Also 4-pin FETs are getting popular, especially the SiC and GaN ones, where there is a separate source pin, just for driving. The pin has own path to the package for source, so there is no voltage drop when there is current flowing, and it has lower inductance, all helping with turnoff time and voltage clamping.
I work in a start-up environment where new engineers think I over complicate stuff, without properly looking into specifications. Your video will be useful for me to pass them to get educated
Engineering is all in the details.
Your ability to deMystify some aspects of electronic engineering is of great credit to you, You have helped me so very much as a "Mature" student (I am 62 and still learning.) Many thanks and keep up the good work !!
Glad to help
I am blown away of how professional this is...
This video helped me solve a problem on a product design that came from an outsourced electronics engineer.
Very well done videos. You have a natural talent for teaching. You lay out the concepts in a logical way which makes them easy to understand. I have a formal education in electronics, but informal instruction like this through RUclips is really amazing for the hobbyist without a formal education. You have earned a new subscriber.
I've used plenty of MOSFETs in a variety of circuits in the past, but even professionals seldom just know how to do these things from memory. Unless you build the same circuits all the time it is often helpful to study some references before designing anything. I think videos like this are even useful for professional EEs who want to brush up on the concepts before diving into a design.
I just bought a broken plasma cutter. It works just like a big off-line SMPS by rectifying the 240 VAC in to 350 VDC, then switching the 350 VDC with a variable current limit and rectifying the resulting AC to develop the 10-60A needed for cutting up to 3/4" (19 mm) steel like the proverbial hot knife through butter. On the switching board are 16 FETs arranged in four groups of four in an H-bridge. I can see two rather large torodial gate drive transformers on the board. I am looking forward to the next video to make sure the technical details of using gate drive transformers are fresh in my mind.
Great video. I have been using MOSFET drivers in my designs for quite some time now, without really knowing (or caring, tbh) about their inner working.
Thanks to you, I can now make better component selections and designs. :)
help me to control a DC motor please, I am using IRF3205, and the 12V geared DC motor is not turning off...
I love the detail you provide - I do not understand on the first viewing, but that is the strength of online, view it more than once
Please tell me I'm not the only one who lmao at needing the breakout board. "It only comes in smd." 10:20
PogChamp on getting it down to 70 ns.
Gosh, I've blown up a lot of components learning about FETs. There's a lot to get your head around. It gets even more exciting when you have inductive loads. Gate drivers and bridges definitely are very useful.
help me to control a DC motor please, I am using IRF3205, and the 12V geared DC motor is not turning off...Thanks
I couldn't understand half of it ... but got the gist. Can't wait for Part II to hit that Like again!
This is the best video you've made for months! I'm very excited about part 2.
Great breakdown of one of the world's most popular devices and circuitry. This is used in practically every switch mode power supply out there, including laptop power supplies and desktop PC power supplies, just to name a few. Power electronics including switch mode power circuits will become even more popular with electrification of vehicles. Let's all get ready for dangerous high voltage digital circuits! Yes!
Huge thanks for including your workings in the videos ... so often folk try to cover such topics and just hand-wave the selection of component values. Big takeaway... if in doubt, add more MOSFETs!
I never understand your vdos (except a few), but I appreciate your knowledge!! Hats off!!
Electroboom is uploading frequently and great Scott too
Germany is in hard lockdown again, so not much to do besides making videos, I guess
I try ;-) One more episode next week and then I will take a longer break.
Check 2 another smart guys youtube channels, 'DIY Perks' and 'Sorin - DIY Electrical Nerd'
u are right brp
@@greatscottlab please cover all MOSFET topic. And Thank you for your efforts.
Great timing on this subject. I was planning to look into the usage of gate drivers tomorrow.
I wish I could do more of practical, you really set good example with calculation it also helping me with theory and calculation
Amazing work GreatScott!, this is yet another example of a series of your invaluable electronics learning resources.
Enjoy the detail you put into your videos...even if I don't always understand what is going on. Thank you!
This thing about driving MOSFETs gave me a lot of headaches to undertand when I was developing my first voltage inverter 1 year ago. I wish I could have watched this video back then, it would be a great help. Anyway, great video as always, even not not being a good english speaker, I learn a lot with your videos, it's also a good way to train my listening.
BYE THE WAY I AM ALSO MAKING ARDUINO PROJECTS PLEASE TAKE A LOOK :)
So glad I came back and watched this again. Was defo worth the 2nd viewing.
i've been always confused with the term bootstrapping, now you explained it clearly with the floating ground. great video as always sir!
Glad it helped!
Wieviel Arbeit in dem Video steckt. Krass. Mega, dass du das machst! Bin von Anfang an dabei ;)
Really like your in-depth videos on subjects like this one. Saves me lots of time wondering why the magic smoke escaped from my MOSFETs ;-). Looking forward to part 2!
My HVAC electrical teacher's favorite line; "once the smoke comes out, you can't put the smoke back in"
(usually referring to transformers, as several dudes hooked them up backwards 😂)
Happy new years, greatscott. Thanks for bringing us all along! I appreciate you!
He explain way better then my lecture in school a thousand thumb up for u Scott.
A short summary at the end of such highly information dense video would be great!
Keep up the awesome work!
BYE THE WAY I AM ALSO MAKING ARDUINO PROJECTS PLEASE TAKE A LOOK :)
Bootstrapping with a diode and capacitor is a great hack. Just make sure your duty cycle doesn't stay at 100% long enough to discharge the capacitor to a voltage that will no longer turn on the MOSFET. For some applications (AC to DC inverter, buck converter with undervoltage protection, etc.) this is a perfectly suitable option.
Help me to control a DC motor please, I am using IRF3205, and the 12V geared DC motor is not turning off...Thanks
@@mohammedyasarshaikh4090 Maybe you have connected the MOSFET backwards? If the drain and source are swapped, it will act like a diode instead. If you've checked that, use a multimeter to measure the gate voltage of the MOSFET and make sure your microcontroller is actually commanding the motor to turn off.
Genau dieses Video hat uns am Samstag in unserer Miltenbecher-AG gefehlt😅 da wussten wir nicht, wie wir unseren Motor steuern sollen...👌
this is very informative Mr. Scott. Really appreciate you taking the time to explain the various pros and cons.
Glad it was helpful!
@@greatscottlab which high side low side mosfet driver would you recommend for a DIY inverter circuit?
THANK YOU!!! I've been wondering this for years but always forgot to look into it!
Such a good explanation with the worked example showing the charge times and average current draw. Correct me if I'm wrong, but my main alarm bells take home from this is that, if using a microcontroller to occasionally switch a mosfet, the resistor on the gate input probably isn't necessary, as the amount of time in a significant over current state is so miniscule, nothing will ever have time to get hot enough to melty melty. However if I'm fast switching a mosfet from microcontroller and the frequency is starting to interfere with the amount of time it takes to actually turn the thing on, I'm essentially spending all of my time *averaging* an over current situation... so in this case I really should be using a resistor (or indeed a dedicated driver).
noting of course that average isn't continuous, so it isn't even as bad as suggested but, if the over current is significant, then this makes things worse. I guess a reasonable analogy would be that no one ever died from a static electricity shock... but if we received them at high frequency over a sustained period... we'd be pretty unhappy bunnys.
At 8:37, your resistor setup could be improved. With your current setup you’re creating a voltage divider. You should put the shunt before the series resistor instead to get the same benefits with no voltage division.
How can it make a difference if they are in parallel?
The world's best teacher
4:40 Thermal runaway is always fun. I remember one time in lab I accidentally hooked up a BJT wrong and it exploded in my face. We were wearing PPE, so my eye was saved, but a large chunk pinged right off my safety glasses. I probably would have been injured if not for the safety glasses. Remember kids wear your PPE :).
Help me to control a DC motor please, I am using IRF3205, and the 12V geared DC motor is not turning off...Thanks
This video Could have helped me a lot in my university project. I remember i faced issues just because i wasn't using a gate driver. That time electronoobs video on boost convertor helped me to figure out the issue
Hey you got Würth as a sponsor, that is a good call from them! I certainly will check their products out!
Thanks for this video now I gained a lot knowledge from your videos 👍
Glad to hear it!
@@tinygriffy yupp 😁
Yey! Another great video!
Watching from state below yours! (Czech Republic)
Awesome! Thank you!
why is it that i enjoy the pictures you draw as much as the content?
I love it and I'm going to attempt to use the simple switching system with a little bit of tank circuit and see how it works
Thanks so much for your videos. I am a fan. Working my way towards PWM treadmill motor driver and this might help. Waiting for Part 2!
I'm really looking forward to part two in the serious :)
Has nobody told him yet?
Have a wonderfull chrismas and a happy newyear Great Scout🎉
Same to you!
Very clear content. Informative for the beginners. Keep going.
Thank you so much for this video, I understand better now 😉
BYE THE WAY I AM ALSO MAKING ARDUINO PROJECTS PLEASE TAKE A LOOK :)
@@HoXDipannew Please don't use so much flame emoji in your title 😫
There is a uge mistake
@@millomakerOo I got a point I must change
@@millomaker thank you for a good suggestion
You deliver the right video at right time......
Professor, will this be on the midterm?
This triggered my PTSD from college
😂
dude awesome! also ur handwriting is a gem!
Finally some different sponser!!😂
You truly are great Scott, cause this video was great!
Thank you :-)
Comme "Gadget Reboot" des vidéos super claires jusqu'au fond du détail 👍
Getting a real Marco Reps vibe here! Great stuff, thank you!!!
In your intro, you imply that Vth is enough to fully turn on a MOSFET, which is a misconception that far too many people seem to get. Vth is only enough to barely start conducting, and you need to go a few volts beyond Vth in order to reach the minimum Rdson.
great explanation video
best I've seen, and you've surveyed all the major issues one is confronted with using MOSFET's
Great walkthrough 👍
Of the adventure of the MOSFET.
Thanks for sharing your knowledge 👍🙂
BYE THE WAY I AM ALSO MAKING ARDUINO PROJECTS PLEASE TAKE A LOOK :)
Great video, so to summarize, the simplest and safe way for driving a fet from an arduino is to NOT connect the gate directly to the pin, correct? A resistor will be required, notwithstanding the increase of switching event time?
Thank you, I was just about to start working on a Tesla coil project and now I know why some designs use mosfet drives and some don’t.
DUDE!!! how did you cultivte such neat handwriting
Really a electronics lover want this.nice👍.I learner something ❤️😘.love from India😘
Very nice , I now understand why I keep blowing up stuff every time I use a MOSFET
Great explanation! I knew a bit about MOSFET drivers, but still, I've learned something new from this video :) I'm currently experimenting with gate drive transformers, and I think it is an excellent topic for a video because many people don't know how and why to use them. If there is one thing that would fit here, that is a video about snubber networks :)
Thanks for the awesome video and explanation.
Thanks for the feedback👍
I would also appreciate a Video about snubber networks
Why 1 week ago?
@@BenjaminAster it is part of his name
@@BenjaminAster patreons and members have early access to videos
One thing is the resistor configuration to discharge the mosfet might depending on which type of mosfet ; P type or N type, and whether its enhanced mode( normally off) or depletion (Normally on)
As always best video👍👍👍👍👍🔥🔥🔥❤️❤️ love from india
BYE THE WAY I AM ALSO MAKING ARDUINO PROJECTS PLEASE TAKE A LOOK :)
what are the odds.. i was just looking up how to control DC motors with a mosfet last night! thanks for the vid !
BYE THE WAY I AM ALSO MAKING ARDUINO PROJECTS PLEASE TAKE A LOOK :)
2:27 min mark: P= 6 ohms times 0.32 amps. I think you meant P= 1.88V times 0.32A= 0.62 W.
Excellent video, I watched it 3x!
Please make video about switching MOSFETs in range of MHz.
@@tinygriffy I've tried brother. After 32 KHz with heavy load, waveform of Vgs looks like capacitor charging and discharging. When in low load, it looks like square wave. I am using 12V 10A battery to drive gate.
@@tinygriffy Give me your contact details. I will send you everything.
@Harsh Desai The reason that your vgs looks like a cap charging is because a mosfet gate is a capacitor. As nico nico said you can choose one with less gate capacitance (would be specced in coulomb on the datasheet) or to drive the gate in a more aggressive manner. Is there any reason you need to switch above 1 MHz?
@@gummy1204 To make the buck converter. I have been trying for months, and still I can't trigger gate properly at heavy load.
Great video! There were a few things I was missing apparently when I drive MOSFETS. Thanks for the information!
Excellent video and great explanations. Thank you really much for sharing all of these.
BYE THE WAY I AM ALSO MAKING ARDUINO PROJECTS PLEASE TAKE A LOOK :)
Great video!! Love the new music. I appreciate the consistency and quality of your videos too. Keep em coming!!!
If electroboom deserve 10 million greatscott deserve 100 million views🤣
great explanation sir. now i can uderstand mosfet more
Thanks for sharing good electronic knowledge with us.. GreatScott👍👍
I remember reading about the very first commercial Mosfets (often called IgFETs then) being announced and doubting they would become very popular (it's not like the were cheap!) and boy, was I wrong!
Very Nice and informative video greatscott! These are an absolute gem for engineering students! And they help tremendously in making projects. Thank you for sharing your knowledge with us!
Wow awesome. So concise and understandable.
You are really Great,mr.Scott! thank you for the video.
Very helpful video. I liked it