Gilbert was a genius. There are several books out there not written by Gilbert where every 10th citation is to a paper of Gilbert. To understand how the Gilbert multiplier cell can be generalized, there’s an excellent book by Evert Seevinck: Analysis and Synthesis of Translinear Integrated Circuits. That’s one of those “10% Gilbert citations” books. Gilbert cell is a basic example of a translinear loop formed by the BE junctions of all 4 transistors.
This channel is a gift to every freshman scratching their head after looking at a semi-complex circuit. And it helps all the way into the final year. I wish I could like and subscribe twice. It baffles me that you're still out here liking comments and explaining little doubts.
I designed a gilbert cell over the summer to learn a little more about mixers and diff pairs, and I am so impressed at how well you described the concepts here! Building up that entire circuit must have been a pain in the fingers, but it is so very much appreciated. Great work!
Excellent tutorial, again I learned a lot. What I like especially is that you only repeat key items, because they matter, not because you didn't remember you mentioned them earlier in the video. In other words: no time wasted. Concise. Clear. I wish I could hand out 2 thumbs up ;)
Thank you for the excellent explanation of the Gilbert cell (and diff pair video aswell). For my wireless class in university I got assigned to build a RF receiver for receiving SSB signals with the help of the NE602. This video has helped me to understand the inner workings of the IC!!!
Best ever explanation how it works. You have explained to me and I understood. Next: how to build frequency shifter using it and which transistor needs to be similar in characreristics (Ube, Hfe and thermically)? I always wanted to do design thermically stable freq. shifter using discrete transistors.
Thanks for the clear and simple explanation of the differential pair and the Gilbert Cell. I'm a self-taught tech, and when I first read about the differential pair at a young age I found myself in awe of its simple elegance, the same simple elegance I found when I first learned of LC resonance. It was so amazing that I found myself wanting to run and explain it to my mother and everyone I knew, as if I were some 12 year-old electronics evangelist. The Gilbert Cell expands on that simple elegance, and I find myself wanting to describe it too, to others. I'm pleased to see you doing just that. Thanks.
I'm working on an automated jig to stress test audio amplifiers and will be using the circuit to measure the delivered power to the speakers. Your content is helping a lot. TKS, from PP5IXD 73
Thank you. You have great way of explaining things. You make things intuitive. I talked with Barrie Gilbert in 2002 ISSCC conference, read many papers about this topology and I have designed mixer chip with this cell, which is in use in many cell phones up to this day. Even I learned new things from this lecture and saw it from different view point. This lecture inspired me to see other Gilbert Cells potential applications. You pointing out Vout= K.V1.V2 is great way of looking at this cell. Thanks again.
This is great. I been trying to learn how to build a multiplier for an analogue computer. (trying to emulate all the math operations) but got totally stuck trying to understand the working of the Gilbert cell. So this has helped me so much. Bizzare how out of all the operations the multiplier is the hardest to understand. And yet all the others no problem. Many thanks, I read a ton of papers on this and none of them explained it simply like this.
Pleased to see & understand this; didn' t have to pause at all once I reviewed the long tail pair as advised b4! Useful to me as i am just getting into RF and understanding its mysteries. Have my first VNA arriving soon, an 8753D and hope to start building basic Rx and TX, so modulating and AGC wil be key. Mixer IF outputs as well for frequency shifting!
Without your video, I would have definitely run away from a circuit with so many diff pairs! Great video (once again). May God give you the strength to continue the good work (and benefit people like me ;) ).
I understand now why we need to add DC off-set to the message signal for the AM modulation --to prevent phase inversion. I have an EE degree and I got all the courses regarding the signal processing along with the communication theory, but non of teachers did not mention this basic detail. Every engineering school should take these videos as the reference teaching materials...
The movie of yours is very interesting for me, I'm from Japan and I wanna watch more movies of yours on other famous analog circuits in chronological order. Thank you.
I've been searching for an analog multiplier and I found your video on the Gilbert Cell. Exactly what I was looking for. I have also watched some of your other videos and they have been equally helpful! Thanks for creating them.
Building the Gilbert Cell from discrete components was a real education for me. I would love to see an additional video on using the 602 mixer. I haven't had much luck with that chip yet. Any practical tips would be a great help. Thanks again!
The trick is usually in getting the biasing and signal levels right. Some resources online: www.lb3hc.net/wp-content/uploads/2019/12/UsingTheNe602.pdf docs.rs-online.com/3cf1/0900766b80027aa2.pdf
I love the fundamentals of push comes to shove or push comes to pull...? Or is it 'quit pushing me around!!!'? Oh well, love the lesson. Thanks, Brought back memories. Videos make learning this so much quicker.
Fantastic. They say "If you are bad at something, teach it", and I think that is too often true. You however are an extraordinary teacher. I'm glad you have a Paypal, but I'm sure you could build more engagement to the channel with a Patreon if you wanted to.
Thank you Stephan, and thank you for your PayPal donation. I have considered Patreon, but the main reason that I haven't gone that route is because I feel like I would be "obligated" to produce content on a more regular basis, which is difficult for me to do.
@@w2aew Yes it usually means regular videos. Which I very much understand if you don't want to do. For all I know you are well off as it is, which is probable on account of your skill and knowledge.
@@stefflus08 The extra money would always be nice, but my work/life commitments would make it difficult to provide the content that I'd feel obligated to produce.
Thank you for your great video's! Your channel is a "must watch" for everyone who's into electronics! I Was looking around the web for a mixer to be part of a circuit that can shift frequencies from 80 - 86 MHz "up the dial" where a standard FM receiver can handle them (there's a lot of pirate radio activity just below the standard 3 meter "FM" band here in the Netherlands and I don't want to modify and mess up good receivers). I Discovered the double balanced diode mixer, other diode mixers and solid state mixers, but this one seems to be great to use in the circuit I want to build. Thank you!
LIGHT BULB!!! Thumbs-up, and subscribed! Thanks so much... I was familiar with balanced amps, but the double-reversed with balanced gain mixing topology here is really cool. Here's my problem... I'm working on an IQ digital modulator in a piece of avionics test equipment that uses a pair of the UPA101's as Gilbert Cell modulators. They are fed L.O. (120-170MHz) through lead/lag L/C circuits (main balanced inputs), the tails are commoned and static (shunt 5.1V zener regulator, each via its own NPN common-emitter buffer), the differential gain inputs are driven by the I and Q gain circuits (the Q channel has a slightly adjustable gain control circuit to balance them... all via sampled feedback). Then the outputs from each Gilbert Cell IC are summed to create the TX IF. The problem I'm having is that the carrier is not being eliminated, but only reduced by about -10dB, where it should be reduced about -50+dB from the main offset frequency (either upper or lower). It does the same thing regardless of whether the IQ inputs are creating USB or LSB... the carrier leakage is still horribly high. From what you said, it seems the carrier reduction should be happening in this modulator circuit... I kept thinking maybe it was in a TX IF gain-reduction circuit... Thoughts? Each IC has active outputs, but I did notice a DC imbalance on one of them when I was trying to troubleshoot it... and from what you said, they should not have any DC imbalance... right? I have full schematics, but the mfr gives no detailed circuit operational theory... at least not enough to help. Your video gave me FAAAARRR more info than the mfr did!
Looking at this I think of both the Ne-602 (now Sa-612) and the Ne-599... Both using Gilbert cell configure all except the Ne-602 had an LO implemented of 200 mHz. So cool to remember these things some 25 to 30 years later. I now have closure!
Thanks for showing how an Gilbert cell works. I finally made an mixer (for mixing 2 square wave oscillators) based on this cell, and it works much better then an OR based one.
Great video, i was curious in this single ended example, could you explain why there is no bypass to ground on base of q6 vs the bypass to ground on the bases of q2 and q3 please. Maybe the biasing is stiff enough, maybe it doesn’t matter, just curious.
Very interesting explanation and clear demonstration. Very well done. My one want is to see the inputs and outputs in the frequency domain. I suspect that there would be quite a bit of distortion due to the usage of discrete devices, but it would definitely be worth doing if your scope can FFT things fast enough or if you have access to a 4 port SA.
Well that stuck in my head!! I was going over the circuit for an Hitachi V-1050 CRO with no triggering and the Gilbert Cell pattern popped out at me. The IC CA3102E. 2 X differential amplifier with associated constant current transistor.
@@w2aew Well I had to go down the line to the sweep generator trig input and solved the issue. The thing is 34 years old, extremely precise and runs like a swiss watch. Very happy.
Brilliant. I’ve studied this cross coupled system for years. I wish I’d seen someone demo the phase inversion. Why didn’t I breadboard the thing? I was convinced I couldn’t match the BJTs. That was a mistake.
Nice video ! Could you go more in depth how the gilbert cell could be used as a phase detector (minimum mesured dt, benefits over xor phase detectors)?
The last 6 transistors circuit seems to forget a 0.1uF at base of Q6. This made outputs (yellow & cyan trace) have lower amplitude at the negative side of the modulation input signal (purple trace) as seen in scope.
Great video, I understood the working really well and so did my friends. We have to implement the same circuit for our term project this semester. We tried it already but we only got noise as the output. I think the problem might be that our input signal gets too noisy at lower amplitudes. We would be very grateful if you could tell us the maximum amplitudes that we could use and also tips to reduce noise in input and output.
You may want to review my video on the basics of the emitter coupled pair to get a solid understanding of the differential input voltage levels that are needed.
@@nidhilrs15 Noise reduction is generally all about bandwidth limiting in most cases. Employ lowpass, bandpass or highpass filtering on your signals and gain stages to allow your signals of interest to pass, but reject the frequency ranges that are not part of your signals.
@@w2aew Thank you very much. We implemented your circuit as our term project this semester and prof was very impressed with it. We couldn't have done it without your videos and help. Keep them coming.
@@w2aew I think you meant #224, which I watched; and again, it was nothing short of a pleasure and learning experience! I wondered if you are a professor or an experienced engineer.
@@LL-ue3ek Yes, thank you. I edited my reply so others don't get thrown off. I am not a professor. I've had my BSEE since 1985 and have done design, test, validation and test engineering - and for the last 16 years have been a field applications engineer for Tektronix.
A very helpful demonstration. Thank you. I'd be interested to see you demonstrate the DSB generation using the same test circuit. Assume it's necessary to apply a positive bias to the lower pair, correct? It would be cool to watch as you raise the bias offset voltage while observing the phase shift changes on the output. Hmmm.. might one produce a phase modulated carrier by modulating the bias voltage?
Gilbert, Early and Widlar all should have received Nobel prizes. Great video, tyvm for posting.
Gilbert was a genius. There are several books out there not written by Gilbert where every 10th citation is to a paper of Gilbert.
To understand how the Gilbert multiplier cell can be generalized, there’s an excellent book by Evert Seevinck: Analysis and Synthesis of Translinear Integrated Circuits. That’s one of those “10% Gilbert citations” books.
Gilbert cell is a basic example of a translinear loop formed by the BE junctions of all 4 transistors.
This channel is a gift to every freshman scratching their head after looking at a semi-complex circuit. And it helps all the way into the final year. I wish I could like and subscribe twice. It baffles me that you're still out here liking comments and explaining little doubts.
It’s always nice to hear that my videos are helping people.
Thank you for posting the operation of the "Gilbert Cell" ! Very helpful indeed. 73's / Gary Grove
Bless you man. 8 years ago, yet still so good!
I designed a gilbert cell over the summer to learn a little more about mixers and diff pairs, and I am so impressed at how well you described the concepts here! Building up that entire circuit must have been a pain in the fingers, but it is so very much appreciated. Great work!
Such an incredible teacher. Up there with AppliedScience as the best in RUclips.
Wow - that is quite a complement! Thank you!
Excellent tutorial, again I learned a lot. What I like especially is that you only repeat key items, because they matter, not because you didn't remember you mentioned them earlier in the video. In other words: no time wasted. Concise. Clear. I wish I could hand out 2 thumbs up ;)
Pure Gold ❤
Thank you for the excellent explanation of the Gilbert cell (and diff pair video aswell). For my wireless class in university I got assigned to build a RF receiver for receiving SSB signals with the help of the NE602. This video has helped me to understand the inner workings of the IC!!!
Best ever explanation how it works. You have explained to me and I understood. Next: how to build frequency shifter using it and which transistor needs to be similar in characreristics (Ube, Hfe and thermically)? I always wanted to do design thermically stable freq. shifter using discrete transistors.
Very nice explanation thanks very much! I didn't need to read a book to understand it and I love videos showing in practice how circuits perform.
Your lecture is incredible! I wish you put more time on phase difference.
Thanks for the clear and simple explanation of the differential pair and the Gilbert Cell. I'm a self-taught tech, and when I first read about the differential pair at a young age I found myself in awe of its simple elegance, the same simple elegance I found when I first learned of LC resonance. It was so amazing that I found myself wanting to run and explain it to my mother and everyone I knew, as if I were some 12 year-old electronics evangelist.
The Gilbert Cell expands on that simple elegance, and I find myself wanting to describe it too, to others. I'm pleased to see you doing just that. Thanks.
I'm working on an automated jig to stress test audio amplifiers and will be using the circuit to measure the delivered power to the speakers. Your content is helping a lot. TKS, from PP5IXD
73
Thank you. You have great way of explaining things. You make things intuitive.
I talked with Barrie Gilbert in 2002 ISSCC conference, read many papers about this topology and I have designed mixer chip with this cell, which is in use in many cell phones up to this day.
Even I learned new things from this lecture and saw it from different view point. This lecture inspired me to see other Gilbert Cells potential applications. You pointing out Vout= K.V1.V2 is great way of looking at this cell.
Thanks again.
This is great. I been trying to learn how to build a multiplier for an analogue computer. (trying to emulate all the math operations) but got totally stuck trying to understand the working of the Gilbert cell. So this has helped me so much. Bizzare how out of all the operations the multiplier is the hardest to understand. And yet all the others no problem. Many thanks, I read a ton of papers on this and none of them explained it simply like this.
Pleased to see & understand this; didn' t have to pause at all once I reviewed the long tail pair as advised b4! Useful to me as i am just getting into RF and understanding its mysteries. Have my first VNA arriving soon, an 8753D and hope to start building basic Rx and TX, so modulating and AGC wil be key. Mixer IF outputs as well for frequency shifting!
Without your video, I would have definitely run away from a circuit with so many diff pairs! Great video (once again). May God give you the strength to continue the good work (and benefit people like me ;) ).
A good example of how complicated things can be explained in a simple way! Thanks a lot!
It is not so complicated two diff amplifiers in parallel.
This is interesting, the basis of all active RF mixers. Still learning a lot from this video.
This is amazing. I always get more intuition and inspiration when I open your channel. Thanks a lot, Alan!
Beautiful explanation and demonstration!
I can't thank you enough for taking the time to do all this ! You have certainly inspired me to share knowledge and help others.
As always , fluent and clear crystal. Most appreciated
This is such an excellent explanation of such a very clever circuit! Mm, mm, mm. Makes me think "wow," every time I rewatch it.
Very useful. Thank you for your video!
Clear, brief and coherent explanation, I commend your hard work on sharing this video sir!
I understand now why we need to add DC off-set to the message signal for the AM modulation --to prevent phase inversion. I have an EE degree and I got all the courses regarding the signal processing along with the communication theory, but non of teachers did not mention this basic detail. Every engineering school should take these videos as the reference teaching materials...
Thank you Sr. it really helped me a lot! I love RF circuits!
The movie of yours is very interesting for me, I'm from Japan and I wanna watch more movies of yours on other famous analog circuits in chronological order. Thank you.
very well made and easy to understand! thanks!🙏
Great great explanation. Thank you
Excellent explanation!
thank you so much for this video
Really a great explanation and you made the understanding of such thing in proper way. Please keep up the good work that helps a lot. A big thumbs up.
thats the most simple and usefull circuit analysis i have ever heard
+Pradeep Chandran Thank you, I'm glad you enjoyed it.
Your circuit analysis videos are fantastic! Merry Christmas and Happy New Year!
+RF Burns Thank you! Merry Christmas and Happy New Year to you too!
I have spent months researching into electronics and discovered an awesome resource at Gregs Electro Blog (google it if you are interested)
Again Kudos, very clear explanation of a not so easy topic. Inspiring to go and build / experiment with Gilbert Cell circuits.
Fabulous detail and fabulous presentation skills
Really enjoyed this one, Alan! I'm gonna have a play with one on the bench here!
This is awesome and so simple explanation, to the point of it being obvious. Nice.
Excellent explanation of the Gilbert cell function.
Thanks very much for your efforts to enlighten the rest of us.
simply fantastic !!!!! You do have the power to make things easier than they really are !
I've been searching for an analog multiplier and I found your video on the Gilbert Cell. Exactly what I was looking for. I have also watched some of your other videos and they have been equally helpful! Thanks for creating them.
Simple , simplified and understandable explanation. Thank you
Simple, easy to understand. Masterful explanation.
You really talking about the real things that matter. As usuall you are unique!
Wow this could not have come at a better time for me. Thanks for your work doing these videos.
Building the Gilbert Cell from discrete components was a real education for me. I would love to see an additional video on using the 602 mixer. I haven't had much luck with that chip yet. Any practical tips would be a great help. Thanks again!
The trick is usually in getting the biasing and signal levels right. Some resources online:
www.lb3hc.net/wp-content/uploads/2019/12/UsingTheNe602.pdf
docs.rs-online.com/3cf1/0900766b80027aa2.pdf
I love the fundamentals of push comes to shove or push comes to pull...? Or is it 'quit pushing me around!!!'? Oh well, love the lesson. Thanks, Brought back memories. Videos make learning this so much quicker.
Fantastic. They say "If you are bad at something, teach it", and I think that is too often true. You however are an extraordinary teacher. I'm glad you have a Paypal, but I'm sure you could build more engagement to the channel with a Patreon if you wanted to.
Thank you Stephan, and thank you for your PayPal donation. I have considered Patreon, but the main reason that I haven't gone that route is because I feel like I would be "obligated" to produce content on a more regular basis, which is difficult for me to do.
@@w2aew Yes it usually means regular videos. Which I very much understand if you don't want to do. For all I know you are well off as it is, which is probable on account of your skill and knowledge.
@@stefflus08 The extra money would always be nice, but my work/life commitments would make it difficult to provide the content that I'd feel obligated to produce.
Thank you for your great video's! Your channel is a "must watch" for everyone who's into electronics! I Was looking around the web for a mixer to be part of a circuit that can shift frequencies from 80 - 86 MHz "up the dial" where a standard FM receiver can handle them (there's a lot of pirate radio activity just below the standard 3 meter "FM" band here in the Netherlands and I don't want to modify and mess up good receivers). I Discovered the double balanced diode mixer, other diode mixers and solid state mixers, but this one seems to be great to use in the circuit I want to build. Thank you!
I hope it works out well for you. This mixer is part of the NE602/NE612 - which may make your implementation easier.
Very Nicely done ! I quickly prototyped this circuit on a simulator and was able to verify it in phase detection mode !
excellent! Thank you so much!
Excellent explanation. Helping me understand a four quadrant multiplier module I am building for my modular synth.
Nice explanation of the Gilbert cell.
Many thanks for preparing & posting this presentation.
Never heard of these Gilbert Cell's before at school in the eighties. Great explanation. Thanks for this video. Merry Christmas and Happy New year.
LIGHT BULB!!! Thumbs-up, and subscribed!
Thanks so much... I was familiar with balanced amps, but the double-reversed with balanced gain mixing topology here is really cool. Here's my problem...
I'm working on an IQ digital modulator in a piece of avionics test equipment that uses a pair of the UPA101's as Gilbert Cell modulators. They are fed L.O. (120-170MHz) through lead/lag L/C circuits (main balanced inputs), the tails are commoned and static (shunt 5.1V zener regulator, each via its own NPN common-emitter buffer), the differential gain inputs are driven by the I and Q gain circuits (the Q channel has a slightly adjustable gain control circuit to balance them... all via sampled feedback).
Then the outputs from each Gilbert Cell IC are summed to create the TX IF.
The problem I'm having is that the carrier is not being eliminated, but only reduced by about -10dB, where it should be reduced about -50+dB from the main offset frequency (either upper or lower). It does the same thing regardless of whether the IQ inputs are creating USB or LSB... the carrier leakage is still horribly high.
From what you said, it seems the carrier reduction should be happening in this modulator circuit... I kept thinking maybe it was in a TX IF gain-reduction circuit...
Thoughts? Each IC has active outputs, but I did notice a DC imbalance on one of them when I was trying to troubleshoot it... and from what you said, they should not have any DC imbalance... right?
I have full schematics, but the mfr gives no detailed circuit operational theory... at least not enough to help. Your video gave me FAAAARRR more info than the mfr did!
DC imbalance will definitely lead to poor carrier suppression. You may also want to view this video:
ruclips.net/video/RHFZUqUM8DY/видео.html
ruclips.net/video/RHFZUqUM8DY/видео.html
Looking at this I think of both the Ne-602 (now Sa-612) and the Ne-599... Both using Gilbert cell configure all except the Ne-602 had an LO implemented of 200 mHz. So cool to remember these things some 25 to 30 years later. I now have closure!
Dear w2aew, thank you so much for this and next video. I wanted to play with mixers and You were the best source of information. Thank you!
Be sure to check out my other videos on mixers (diode ring mixers, etc.).
Alan, very good circuit explanation, takes some mystery out of the analog circuit design. 73, Bob WB2SRF
Brilliant and very informative video.
A very big thumbs up!
If I viewed this video a few weeks earlier, I could have put a reference of it in my paper on stereo multiplexing! Great video!
Thanks for showing how an Gilbert cell works. I finally made an mixer (for mixing 2 square wave oscillators) based on this cell, and it works much better then an OR based one.
Those videos are really awesome. My transistor background is really far away (like 10 years away...) yet everything seems intuitive again. Thanks!
Wow, best description I have ever heard of a Gilbert Cell Mixer! You hit it out of the park on this one! 73s de KA2ZOH and happy new year!
+Herbert Susmann Thank you!
Again a more than perfect explanation...i liked it ..clear ..technical and again a working example to show ..thanks
Excellent description of the Gibert cell function ..well executed ..Cheers !
Great video, i was curious in this single ended example, could you explain why there is no bypass to ground on base of q6 vs the bypass to ground on the bases of q2 and q3 please. Maybe the biasing is stiff enough, maybe it doesn’t matter, just curious.
Very interesting explanation and clear demonstration. Very well done. My one want is to see the inputs and outputs in the frequency domain. I suspect that there would be quite a bit of distortion due to the usage of discrete devices, but it would definitely be worth doing if your scope can FFT things fast enough or if you have access to a 4 port SA.
Great explanation!
Awesome video. Would love more about Gilbert Cell, maybe about bandwidth and noise.
Will add this to my long list of future topics
Thanks for another good video. Like others, I too have never heard of this GILBERT CELL. I always learn something from your videos. Thumbs up. Thanks
Best explanation ever...Thank you. Please what regions of operation are the transistors in, forward or saturation?
This video tops, very clear explanation. Please keep making such videos.
Excellent high level description.
Well that stuck in my head!!
I was going over the circuit for an Hitachi V-1050 CRO with no triggering and the Gilbert Cell pattern popped out at me. The IC CA3102E. 2 X differential amplifier with associated constant current transistor.
Yes, you can build a Gilbert Cell with that!
@@w2aew Well I had to go down the line to the sweep generator trig input and solved the issue. The thing is 34 years old, extremely precise and runs like a swiss watch. Very happy.
Brilliant. I’ve studied this cross coupled system for years. I wish I’d seen someone demo the phase inversion. Why didn’t I breadboard the thing? I was convinced I couldn’t match the BJTs. That was a mistake.
once again nice video.
Thanks Alan for another superb lesson! Merry Christmas and Happy New Year!
Very neat!
Outstanding explanation on this Alan.Have a safe and Merry Christmas.
I really appreciate the work you do to provide such education. Thanks very much and Merry Christmas/Happy New Year
Nice video ! Could you go more in depth how the gilbert cell could be used as a phase detector (minimum mesured dt, benefits over xor phase detectors)?
Is there a way i can make a million likes at once? Frankly, W2AEW is the best electronics teacher in RUclips hands down.
Excellent video, as usual.
Beautiful circuit analysis. Marry Christmas Alan 73.
Thank you, Levent! Nice to hear from you!
The last 6 transistors circuit seems to forget a 0.1uF at base of Q6. This made outputs (yellow & cyan trace) have lower amplitude at the negative side of the modulation input signal (purple trace) as seen in scope.
Oh man. I've been thinking about voltage controlled filters lately, and this video is so right on time for me :D Well explained as always. Thank you.
Thank You Sir, it is very informative, helpful and easy to comprehend.
Thanks Alan. A big thumbs up👍
Outstanding video (again). Merry Christmas to you and yours Alan
And again a great video from a great teacher! Thanks a lot and wish you a merry christmas!
Thank you very much for your fantastic explanation.
Thank You very much for Your videos! You are able to explain a lot of complicated issues. Merry Christmas and Happy New Year! :)
This is gold. Keep it up. Thank you!
Great video, I understood the working really well and so did my friends. We have to implement the same circuit for our term project this semester. We tried it already but we only got noise as the output. I think the problem might be that our input signal gets too noisy at lower amplitudes. We would be very grateful if you could tell us the maximum amplitudes that we could use and also tips to reduce noise in input and output.
You may want to review my video on the basics of the emitter coupled pair to get a solid understanding of the differential input voltage levels that are needed.
@@w2aew Okay, i go that. Do you have any tips to reduce noise in practical application? Thanks in advance
@@nidhilrs15 Noise reduction is generally all about bandwidth limiting in most cases. Employ lowpass, bandpass or highpass filtering on your signals and gain stages to allow your signals of interest to pass, but reject the frequency ranges that are not part of your signals.
@@w2aew Thank you, will try it out.
@@w2aew Thank you very much. We implemented your circuit as our term project this semester and prof was very impressed with it. We couldn't have done it without your videos and help. Keep them coming.
Great video with amazing insight. Could you explain a bit more on how to eliminate the carrier and keep the signal? Thanks!
Check out video #224...
@@w2aew I think you meant #224, which I watched; and again, it was nothing short of a pleasure and learning experience! I wondered if you are a professor or an experienced engineer.
@@LL-ue3ek Yes, thank you. I edited my reply so others don't get thrown off. I am not a professor. I've had my BSEE since 1985 and have done design, test, validation and test engineering - and for the last 16 years have been a field applications engineer for Tektronix.
A very helpful demonstration. Thank you. I'd be interested to see you demonstrate the DSB generation using the same test circuit. Assume it's necessary to apply a positive bias to the lower pair, correct? It would be cool to watch as you raise the bias offset voltage while observing the phase shift changes on the output. Hmmm.. might one produce a phase modulated carrier by modulating the bias voltage?
+k1mgy I am planning a video to show AM and DSB(SC) signal generation, and how the DC bias affects the modulation and spectrum of the emission.