For those who ponder, "Why study calculus?" this presentation gives a clear answer. Also, the EE concepts that seem obvious to today's diligent EE student (and which mystify those who lack either diligence or proper preparation) earlier mystified the best minds, even Faraday. A hint to those who "don't quite get" some aspect of the material here: Go back and learn the fundamentals. Somewhere you missed a step or learned an incorrect shortcut. "But what about inductance?" as some have noted. Yes, it had not yet been folded into the theory.

I was in a baseball card shop in the early 90's and they had a NY Times from 1858 for sale. It had a box score for a few games in the NY/NJ area, including Hoboken. I thought that was very cool and bought it. When I got home and read the whole paper it was obvious why it was saved. It was because it was from the day after the first cable was completed. The entire front page was dedicated to it. It's fascinating. Not mentioned in the video, but they actually found the damaged spot on the original, pulled it up and fixed it.

Lord Kelvin is not obscure, he's a legend. He pushed classical physics to its absolute limits. Transmission lines are one contribution but thermodynamics was his real forte leaving his name on the absolute temperature scale to this day. Yep, he's why it's d̶e̶g̶r̶e̶e̶s̶ Kelvin. Obscure?

Well researched, well written, and beautifully produced. Thank you for your labors !

Vastly more informative than other videos on transatlantic cables.

Geez, back in the 20th century I struggled with transmission line theory. Now nearly 24% into the 21st century watching how you illustrate the properties of cables, the equations, I get a better intuitive feeling for transmission lines.

Top notch production quality. Hugely underrated channel

Hidden gem of a channel

YT has come a long way thanks to high quality content like this one. Amazing work.

A lot of effort went into making these videos. Thank you sir for the joy that you put into making them.

Slick. I never went to school to be an Electrical Engineer. But I do have a little background in Math, so I could follow along a little. Thanks. Elegant. I remember reading what about the fuss that Ohm's Law raised.

Loved the video, this deserves a sequel with heaviside.

The distortion affected early telephone signals over wires. A lot of effort was put into developing filters to reduce this distortion. Eight words a minute is not so bad. It's really amazing when you consider the benefit of going from Zero to something that is useful.

That's a very well-made video. I had imagined his knighthood was for something related to temperature. This is quite a relevant problem for the time and a brillant approach.

02:27 What about the inductance of the transmission line? when did they start to consider the inductance of the transmission path?

Thank You for this Amazing Video! It explained everything so clearly! Ever since I watched the documentary "The Story Of Electricity" by Jim Al Khalili, I have been looking for an in-depth explanation of this event. After watching your video it felt like something just clicked inside of me, It's the same feeling you get after putting all the pieces of a puzzle together. I feel so happy now. Thank You for making me feel like this!

Watching this again, I think of diving back into those equations I struggled with in college. I also think while most of us struggle learning the math, but these guys like Faraday, Clark, Thompson, and others had to learn it from scratch! Though 16 hours to send a message across the Atlantic but it must have been totally awesome to pick up the pulses like seeing the first video transmission from the moon.

Very well done and informative. Remember me as one of your OG fans when this channel blows up

When ham operators (amateur radio) had to be able to morse, the minimum requirement was 5 words pr minute (wpm). The limit for the traditional morse key is 15 wpm. With machine or computer generated morse it is possible to understand up to 40-50 wpm.

When people try to tell me about how awesome lord Kevin was, it gets absolutely zero reaction out of me. I'm just like 0 K.

Very nice and informative video. Thank you!

Well told. It's amusing that the solution was to increase the voltage, a choice made by a man who did not understand theory. In my career as a EE in mill controls I would encounter frequently people who would argue or give orders to use setting that would fail or would damage the equipment. It happened way too often actually.

Excellent Video! This deserves way way more views

Wowww, what a content, wonderful 👏 , enjoyed the way you guys have presented complicated topics in a manner that we can relate, thank you 😀

Beautiful production in every way. Wow.

very very very nice video....thank you.

The genius of these men.

This channel is undermined. you have gained a new subscriber , sir.

Continue with your videos . They are very informative

Fabulous content! Well done! Greatly appreciated. Thank you!

Wow!! Great job at explaining ! Subscribed

Another path in science catalyzed by this work in transmission lines is as follows: the cable equation, along with the associated formalization of problems of cable shielding and specification and placement of amplifiers along the cable, are used directly in the development of the Hodgkin-Huxley model of the neuron’s electrical and functional properties as manifested in neural morphology and physiology. This insight, voltage spike train modulation and transmission in neuronal networks, in turn, led quickly to the McCulloch-Pitts mathematical model of a formal neuron. Which led to perceptrons, the X-OR problem, multi-layer neural nets, Hinton’s resolution of the X-OR problem, the first, second and third “waves” of interest in NN technologies, and here we are today. Many other things are involved here, graphs, networks, mathematical logic, statistical sciences, experimental psychology, lots of things. But - it starts with the cable equation.

When I first learned about transmission line theory during my EE undergrad, I thought it was a bit of a leap to model straight wire as an inductor. I feel validated now, since even Kelvin did not think to model things that way (he only considered R & C).

Kelvin read Fourier's treatise on heat when he was 14. He was adept in its use. Nice presentation of the technical issues.

Interesting story, I like how dividing the cable into tiny bits led to a solution similar to how the Numerical Electromagnetics Code in antenna & line modeling today does much the same.

11:15 Both cables had multiple strands forming the center conductor, which increase the surface area of the conductor and the distributed capacitance. It seems as though a single center conductor would be better, perhaps with an electrically isolated shield between the center and outer conductors as this would divide the capacitance into two in series and reduce the reactive current.

Outstanding production quality. May I ask what software was used for the animations?

This presentation is awesome!

Masterfully done! I have subscribed

Check out "The Forgotten Genius of Oliver Heaviside: A Maverick of Electrical Science" ~ Basil Mahon

My dad told me that, in his Cambridge degree exam in 1934 there was a question on heat transmission. He said that he wrote as his answer "Using the telegraph equation, well known to electrical engineers, we have as the solution xyz" and moved on to the next question.

Small correction. Thomson was raised to a peerage to become Lord Kelvin not 'knighted'.

And what was the carecterstic impedance "Zo" of the transatlantic telegraph cable?

Lord Kelvin was a genius.

I don’t understand all of this but I do understand the concept of carrying power across large distances with smaller wires by sending them at a high voltage and then you can step the voltage down and increase the current to get the same power. So essentially you can carry many loads with a small wire, but once the voltage is reduced, large wires are required to carry even a small portion of that load. This makes sense to me if voltage is a force like I was taught in college but if voltage is not a force then it doesn’t make sense at all.

thank you so much for this amazing video 😇🎓

This has me wondering if I could explain the need for thicker cables to the scientists and engineers of the time (prior to Thomson's revelations) in a way that would at least seem plausible. Is there a more conventional physical model I could use to demonstrate why the cable they had used was inadequate, aside from the mistaken use of higher voltage?

The video is 60fps, which can't play correctly on my Chromecast. It's a pity. Why don't you upload videos at 1080p x 30fps ? 😮

Superb content.

Beautiful video

4:07 : there should not be ' I = ..' in the first eqn. but " dI = ..'

Heaviside was a great scientist and mathematician -- read about him. He struggled through adversity and was largely self-taught. Lord Kelvin was of course a great man also. with some advantages Heaviside did not have.

A math problem; With the cost of the cable, divided by the expected lifetime or the wanted break even time, what should the price per minute for a telegram be?

Love this. A great following could be the story of the Great Eastern.

This are great videos! As a non english speaker i need the use of headphones to follow the script of the video. Funny to hear the balancing on the chair of the author! 😅

sir i have some doubts in adc control using fpga how could i contact u please reply .

Another two smaller details 1. "Ohm's law" is not a law despite of names, in fact we call Ohmic conductors those that obey Ohm's law (a law that is only valid to those that obey this law is not a law at all or we would have billions of edge case "laws"), and even those only obey it in very small ranges as as conductors heat their "resistance " (the quotes use is explained further ahead) gets higher. But if Ohm's law defines resistance this is a circular reasoning, just like using Newton's second law as a definition of force (it is not). It is an empirical law, not a fundamental law. 2. The approach using only capacitance is valid for very low frequencies, for higher frequencies the inductance is not negligible (like audio or radio frequencies). But the same idea of calculating it can be used. In fact this approach is not different to the propagation of light on a dispersive medium, as the speed of each frequency component depends on the frequency (not surprising as Fourier created this method hat involves series of sines and cosines to solve heat equation). That is why when we learn that at college we learn to use a series involving the L and C and taking the limit to infinitesimal parts (there are two different ways to approach the slicing of the line in parts but when you take the limit bot converge to the same solution), this way is the first step that is more intuitive to students before you attack the differential equation and even calculation the distribution of energy around the line using the Poynting vector (that should silence sterile false polemics created by Veritasium but no one seems to have made their homework even those that pointed it like ElectroBoom ignored this part).

What is the book referenced in the video?

leave it to old men w/ too much time on their hands to 'misunderstand' the concept and start buying super expensive 10ft speaker cables that don't smear the upper octaves of the audio fq spectrum :) jokes aside, this was a great production, thanks and wish you all the best!

GREAT! The problems of resistance and capacitance are very well explained. If you had included induction (L), you would have covered the Big Three. Question: I'm assuming that R, C and L are irrelevant in a fiber optic cable. Is this so?????

What's amazing to me is how Fourier solved the differential equation

Signal Source impedance has to equal Transmission Line impedance HAS TO EQUAL Terminating Resistor impedance. Failure to establish these conditions results in unwanted Signal Reflections.

One thing missing is the inductance that makes it even worse. The inductance is in series with the resistance and as this is worse for higher frequencies it smears out the signal. it rises and falls slower.

I’ve never seen voltage represented by V. It was always E when I was in school. But how can voltage be present without current? If current is zero then the other side of the equation must also equal zero and therefore voltage cannot exist but is does. And I recently learned that electromotive force is not a force at all and I really don’t understood that. Back in the 80s and 90s, voltage was the force that pushed the electron flow. A lot has changed about the way we think but electricity hasn’t changed. It makes me wonder how much we really understand it.

who's got the skinny on the western route across the Bering Strait during Field's Atlantic attempts?

How many people knew this but never thought about the transmission time per word...? Half way round the planet. Me. Good vid.

Give it up for Heaviside!

Anyone watching this would appreciate reading "the world is one" , a non fiction book by Arthur C Clarke about the history of the transatlantic cable.

is this a typo? Ri = -dv/dx, should be idR/dx = -dv/dx

It's interesting how the predicted problems in the first cable were ignore, and only corrected in the second cable after the wretched performance of the first one were clearly demonstrated. The same thing happened more than a hundred years later when AOL bought Time Warner, expecting that someone would quickly figure out how to send 10 MHz videos through T1 voice grade telephone lines... as if the laws of physics truly were as "elastic" as Star Trek episodes portrayed them. As for pulse dispersion, an acoustic example of this was exploited to make sound effects for Photon torpedoes in Star Trek, and blaster sounds in Star Wars. In both cases, those sounds were recorded by striking a steel guy wire for a radio tower, and recording the resulting audio pulse, reverberating through the cable... One can clearly hear the rapid decay of high frequency components, as predicted in the math, yielding the prolonged metallic "twang" sound that screams "DISPERSION !" to anyone who understands this stuff. An example is here : kzbin.info/www/bejne/nJ2TqHyafN2ZmLMsi=eGCJv8ikpXjRv1gk

Amazing how such huge capital projects were embarked upon apparently without any practical modelling to prove the theory.

well done!

Great Video

From an 85 year old electronic technician, WOW!

You can't call Lord Kelvin obscure! Not as long as we meansure in degrees Kelvin and use the first two laws of thermodynamics.

Nice job. Great video. Thanks. I look forward to checking out your channel. Subscribed ... Cheers ...

cmon everyone knows Lord Kelvin

Willium Tompson is still a Giant in physics.

Thank you!!!

I still find RxC=t stunning

So it shows one line is carried like that

Nice video

Heaviside is and looks like a chad

In your diagrams people could misunderstand the flow of electrons this is the flow of electric charges. Electrons do not flow from source to load. This is exactly what the transmission line demonstrates. Electron valence drift is so small that no electron from your power grid gets to your home. The Ohm's law is a lumped some model they are simplified explanations of what's going on underneath an object of abstraction. I can prove this to you. The common everyday product like a electric toothbrush pause the Wireless cell phone charger has no physical connection to your device. The power grid is the same, with capacitors and Transformers and isolators the basics of a transmission line there is no physical connection. The electromagnetic field is propelled around the wires through the air to your load which could be something at your house and it seems like magic. This is called electrodynamix which comes from the Maxwell-Havyside , which came later.

Fine content, but what's with the odd rhythm?

And the foundation for the network you are watching this on!

Good thing fiber optic cables don't suffer from the same problem... ...oh, right. They do after all, just not to a degree that's measurable over 14,000 miles.

It's not theory it's science.

@ 0:58 SCHEVENINGEN

Someday a video on this subject will made that all understand. Otherwise this made for insiders who already know the formulas and what they represent. Unless it is clear, this is as dry a bone in the desert.

We are still with cables

Being made a knight is not the same as being made a lord. They are distinct honours and he was awarded both (not simultaneously, though).

Doesn't electricity travel instantaneously? Why did the messages take long to arrive?

And now we have 'twisted Pair' cables ...

So they tried to overclock the first trans-Atlantic cable and blew it up....

Subbed.

Yes lord kelvin, another Thomas is knighted

I have a system with transmission lines and a sub! 😅

Kelvin was clever but he blew it when he attempted to compute the earth's age with heat flow theory. His answer was 200000 years.

💐💐💐