Acquired - TSMC (Remastered)
Episode Date: January 21, 2025We dive into the unbelievable and unlikely history behind the quietest technology giant of them all: the Taiwan Semiconductor Manufacturing Company. Founded in 1987 by the then-56 year old Mo...rris Chang, already a legend in the semiconductor industry by virtue of his meteoric rise and fall at Texas Instruments, TSMC today manufactures nearly all the leading-edge chips for Nvidia, Apple, Broadcom, Qualcomm, AMD, and yes — even Intel. Tune in for an incredible story of innovation, perseverance and lasers. Lots and lots of lasers!Note: this is a remastered version of our original 2021 episode. We don’t often re-release old episodes, but in this case we have a very timely reason for doing so. Stay tuned! :)Sponsors:Many thanks to our fantastic partners:VantaJ.P. Morgan PaymentsStatsigLinks:Episode SourcesCarve Outs:Ted Lasso (Season 1)GreekWho is Michael Ovitz?More Acquired:Get email updates with hints on next episode and follow-ups from recent episodesJoin the SlackSubscribe to ACQ2Check out the latest swag in the ACQ Merch Store!Note: Acquired hosts and guests may hold assets discussed in this episode. This podcast is not investment advice, and is intended for informational and entertainment purposes only. You should do your own research and make your own independent decisions when considering any financial transactions.
Transcript
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Hello, acquired listeners.
We regularly get feedback that this episode on TSMC, the Taiwan Semiconductor Manufacturing
Company, is one of the best acquired episodes ever.
And interestingly, it predates our NVIDIA episodes.
We did it way back in 2021 when the acquired audience was about 12% the size of what it
is today, which means that the vast majority of you have never heard it.
So we definitely wanted to fix that. Since then, semiconductors have become so much more important
in our world and TSMC has essentially become the only manufacturer of the leading edge chips.
They make the primary chip inside every MacBook and iPhone shipped today. They're powering the
AI wave, manufacturing
all of Nvidia's chips. They make the chips for a whole bunch of other fabless companies like Qualcomm,
AMD, Broadcom, and hyperscalers like AWS. And it turns out they even manufacture a lot of chips
for Intel too. Yes. Little known fact. Yeah, TSMC rode the smartphone era to crazy heights, as we all know.
And here now in the next AI era, here in 2025, it turns out that they are the manufacturing
superpower behind all of that too.
Yep.
Well, listeners, without doing too much foreshadowing, now is a very good time for anyone to listen
or re-listen to the TSMC episode.
So we decided we should go all the way back
to the raw audio tracks and remaster this whole thing
from scratch for your listening pleasure.
Ben, in fact, I looked it up since we were going back
to 2021 when we initially recorded this.
TSMC's market cap has doubled since then
from 550 billion to over a trillion dollars.
And in fact, you're the one that tipped me off to this
as we were re-researching here.
They and Saudi Aramco are the only trillion dollar companies
in the world that are not located on the West Coast
of the United States.
Wild.
This is such a crazy stat.
It's crazy that the rest are located on the West Coast
of the United States, but it really underscores
what an extreme outlier TSMC is
So without further ado the story is truly unbelievable and we hope you enjoy this presentation of TSMC remastered Welcome to Season 9, Episode 3 of Acquired, the podcast about great technology companies
and the stories and playbooks behind them.
I am Ben Gilbert.
And I'm David Rosenthal.
And we are your hosts.
Today's episode is on TSMC, or the Taiwan Semiconductor Company.
It is your classic, most people have never heard of it, but it's the ninth largest company
in the world episode.
This is wild.
Morris Chang founded TSMC at age 56, retired at 74, then came back at age 78, into the
deal to make all of Apple's chips.
And yeah, we're gonna tell the whole story here.
It's wild.
It's nuts.
They make literally every chip in every iPhone sold today
and soon to be in every Mac sold.
If you're excited at all about Nvidia, AMD, Qualcomm,
or even any of the chips that Amazon, Microsoft,
Facebook, Apple are making, all of those chips or even any of the chips that Amazon, Microsoft, Facebook, Apple are making, all
of those chips, or nearly all of them, are actually made by TSMC, along with all the
chips in your cars, in your smart home devices, in fighter jets, and everything.
Unbelievably, this company that the entire world relies on is on an island that some
countries feel is a sovereign nation, and the People's Republic of China feels is actually theirs.
So today's episode has it all ascending from startup to tech superpower, an underdog founder, and of course, a good dose of geopolitics.
Indeed.
All right, well, listeners, it finally felt like the right time to do this episode amidst this global chip shortage that we've got going on
that David, I think I've heard even Ford has paused
the production of F-150s because of this.
So it is like a massive impact on the world.
And we've had TSMC on the agenda to do for like
two and a half years now in our little Google doc.
Totally.
Well, I feel like we haven't called it a mini series,
but let's call it a mini series on semiconductors
and like Silicon.
The ARM episode.
Yup. Sequoia part one, PA Semi.
Yup. Okay, listeners, it is time to jump into the history and facts and David's
going to lead us in that. But as usual, even though we're going to be probably
very excited about some companies, less excited about other companies, the show
is not investment advice. We may have investments in the companies
we discuss. It's for entertainment and informational purposes only, and you should do all of your own research.
Okay, speaking of, we start in Ningbo, China in July 1931, just about one year after Warren Edward Buffett
was born in Omaha, Nebraska. And there are going to
be quite a few parallels here as we go through this episode. But in July 1931 in Ningbo,
China, our protagonist, Dr. Morris Chang, order of the propitious clouds with special
grand cordon, which is the highest civilian honor that anyone in Taiwan can hold.
Sweet.
So he's like a knight of Taiwan. It's the order of propitious clouds. And then I think which is the highest civilian honor that anyone in Taiwan can hold. Sweet.
So he's like a knight of Taiwan.
It's the order of propitious clouds.
And then I think there's like nine ranks of it and the highest is special grand cordon.
And he's special grand cordon?
He's special.
Yes, he's very special.
So he was born then.
For those who are unfamiliar with Chinese geography, Ningbo is a small city, just a bit
south of Shanghai. You know,
small. It's about 8 million people. It's casual. No big deal.
China scale is ridiculous. But certainly wasn't 8 million people when Morris was born in 1931.
No, but I bet it was still probably pretty big. But yeah, today 8 million people. Crazy.
So Morris's father was a county official and later became a bank manager. So the family
moved around a good bit within China as his father was transferring for work.
This is pre People's Republic of China. This is pre World War II. This is a very
different place. Right. The leadership is not communist. No. No, no. So his early
childhood years were like middle-class, not wealthy, but pretty well to do
relative to your average
Chinese citizen. Then when he was six, the second Sino-Japanese war breaks out and Morris
and his mom flee the main part of China to Hong Kong and they go to live in Hong Kong
for a few years to escape the air raids and the fighting. And then on December 8th, 1941, three hours after Pearl Harbor, the
Japanese attack and invade Hong Kong.
Morris talks about this.
He's like, yeah, everybody knows Pearl Harbor, December 7th, 1941.
What people don't often talk about is the same thing happened in Hong
Kong three hours later on the next day.
So they're in Hong Kong.
So they flee again back to China.
They end up in Shanghai this time and they stay there for a few years until 1948 after
World War II is over.
But that's when the Chinese Civil War breaks out that would lead to the Chinese Communist
Revolution.
And so they flee again
back to Hong Kong. So this is crazy. Morris, before he turns 18, he has lived through three
major wars, the Second Sino-Japanese War, World War II, and the Chinese Civil War. So the
next year in 1949, which is the same year as the establishment of the PRC, the People's Republic
of China, Morris turns 18 and with the help of an uncle that he has in Boston, his life completely
changes. He gets accepted to Harvard. So he goes to the US, he goes to college at Harvard. Wow.
Talk about a change of fate.
Talk about a change of fate, a change of scene,
everything. Morris says much later, my reaction entering Harvard was sheer ecstasy, almost
disbelief. What a country. The United States was at its peak in its moral leadership and its
political leadership in terms of democracy, and it was the richest country in the world.
Not to mention stable. I mean, you could say what you want, you could count on the fact that it's
likely that 10 years from now, whatever economic structure or political structures exist will
continue to exist. If what you want to do and what he ended up doing with his whole life is innovate,
having that stability around you and all those structures enable you to do that.
Yeah, like we just take this for granted, but this is a good reminder.
At the very least, he's probably not going to have to flee Boston to continue his studies.
But he does end up fleeing Harvard, as we'll get into.
So Morris loved it.
It was like that quote we read.
He was so overjoyed to be there, but he realizes he has a new problem in America and at Harvard.
His parents aren't coming over.
He's on his own.
He's got to support himself and make his own way.
At that time, his race is probably going to limit his opportunities.
As he says, quote, in the early 50s in the United States, there
were Chinese laundromen, Chinese restaurateurs, Chinese engineers and Chinese professors.
Those were the only respectable professions for Chinese, no lawyers, no accountants, no
politicians. And what does Harvard turn out? Lawyers, sort of accountants, maybe politicians.
Yes. Yeah. Not a lot of engineers. Certainly finance professionals.
Certainly finance professionals.
As we will see as we will go along,
Morris is much more than a finance professional,
but Harvard actually didn't have
an undergrad engineering program at the time.
Huh, that's crazy to think about.
If you're really, really focused,
you're probably gonna go down the street
in Cambridge from Harvard
to MIT, which Morris does. So he only spends his freshman year there. And then for his
sophomore year, he transfers to MIT so that he can study mechanical engineering. So Morris,
our man, has learned the ways of the world in the US. He's focused. He starts mechanical
engineering a year behind at MIT. He finishes both undergrad and his master's in the US, he's focused. He starts mechanical engineering a year behind at MIT.
He finishes both undergrad and his master's in the remaining three years.
And what year is this?
This would have been 1951 when he transferred fall of 1951.
Okay, so to contextualize what's going on in the tech world right now with quotes around
it, because it's not so much a world as a very small continent. I mean you have all of the post-World War
II defense spending that went in particularly on the West Coast with the
innovations from Stanford but has Fairchild Semiconductor been started yet?
Nope. So maybe Shockley Semiconductor. Shockley Semiconductor is
probably just getting going but we're probably still in vacuum too. Like Bell Labs land.
Yeah. To give you a sense,
silicon is years away.
Transistors are probably just getting going.
We're not in the integrated circuit yet,
and it's all being done in germanium, not silicon.
Wow.
So it's like this is OG.
Yeah.
So after he gets his masters in the three years,
Morris wants to stay and do a PhD,
fully complete his technical training,
but he ends up failing his qualifying exams twice.
They give you two chances to take and he fails twice.
By the way, this is a good time to say,
so David and I watched and listened to every footage
that Morris has ever spoken
that has been released publicly to prepare for this.
He is very funny.
Oh, he's great.
The way he talks about this, he says that, unfortunately, the biggest impediment to him
going forward was that he failed the qualifying exam. But fortunately for him, they were kind
enough to let him take it a second time, which he also failed. And he has this really dry,
clever sense of humor.
So in one of the interviews, he talks about one of the Stanford ones, he gets a question
from the audience about how did he kick his smoking habit?
Oh yeah.
That like the questioner is like,
I know you used to smoke, how did you finally stop?
And he's like, I never stopped, I still smoke.
Yeah.
He's like 94 years old.
And he goes on to make the case for why he's a pipe smoker.
Yep.
And actually, even though smoking is hurtful to his lungs,
it's actually beneficial for his mental life.
So he's pretty sure it's prolonged his life.
Well, he says he's delved into the data
and pipe smokers live longer than nonsmokers.
Which I'm sure you can find data to support that.
I'm also sure you can find plenty of data to refute that.
But yes, this gives you a sense of who Morris is.
Okay, so he's failed his qualifying exams.
He's gotta go out and get a job and you know, not as a PhD.
He's got to go get a job as a super entry level as an engineer.
I mean, he has a master's degree, but still.
Okay, so legend has it.
He has a couple job offers.
The one he really wants.
Remember, he's a mechanical engineer.
And this is like super early days of technology. It's not really
a thing.
There was electrical engineering at this time.
Right, right, right. Yes, he could, but he didn't study electrical engineering in terms
of where you would want to work. Like it's not really on anybody's radar screen, especially
Morris says that you're going to go enter the tech industry. So he gets his dream job
offer from the Ford Motor Company.
Oh, no way.
Yes. I didn't hear that. And I'm
sure this is apocryphal. But let's repeat the apocryphal story and broadcast it out
to hundreds of thousands of people here. Totally. So the legend has it that Ford offers him a salary
of $479 a month to go take an entry-level job. And then he has a competing offer from Sylvania's
new semiconductor division.
And Sylvania, I know of this company only because my vacuum growing up was made by Sylvania.
Oh, well, we're going to talk much more about Sylvania in one second. This is the competing
job offer he's considering. They offer him a salary of $480 a month, $1 more. And legend
has it that Morris asked Ford
to beat Sylvania's offer.
They didn't, and so he took the Sylvania job offer.
I'm sure that is a-
It was 100% a pocketful.
Yeah.
But you know, Morris, he's great.
So speaking of Sylvania, do you remember,
I'm sure some portion of our audience remembers,
but do you Ben remember who else started their
career in Sylvania's semiconductor division right around this exact same time? We have talked a lot
about this in this person on the show. No. Donald T. Valentine. No way. Yep. That's right.
So he started at Sylvania after Fordham or maybe it was after the military.
He ended up at Shockley. Well, no, then he was at Raytheon and then he joined Fairchild.
Fairchild, okay. Right after the trade race left Shockley and started Fairchild. You're
better at remembering these deep details of older episodes than I am. Well, I do a lot
of research for this show. And sometimes research includes past acquired episodes.
There you go.
So they didn't overlap, Don Valentine and-
They were never in the same place.
They were in different locations and different job functions,
very different job functions, but they were both,
I believe both at Sylvania.
Amazing.
At the same time, crazy.
So Don is out chilling in California,
like we were talking about and falling in love
with California.
He's playing water polo.
He's like, oh my gosh, I'm never going to leave this place.
Morris, he's on the grind.
He gets posted as a junior engineer at Sylvania's Ipswich, Massachusetts plant.
Not quite the same glamour as Don out in Southern California.
So remember, Morris is a mechanical
engineer. He doesn't know anything about electrical engineering but he's working
in this new semiconductor division. So after work, he's living in a hotel by the
way. He doesn't even get an apartment. It's like some company-sponsored hotel.
He goes home back to the hotel from work and he studies the best textbook that he
can find about electrical engineering which is entitled Electrons and Holes in Semiconductors
with Applications to Transistor Electronics,
written just recently, a couple of years before in 1950,
by William Shockley.
Oh, wow. Yeah.
Shockley and two other guys basically invented the,
I'm not sure it was the first transistor, but the
first transistor of the type that everything else would then be built upon when they were
at Bell Labs not too long before this.
Yeah, not too long at all. I mean, ENIAC was a vacuum tubes and then Shockley invented
the transistor. And then in a sec, we're going to talk about the integrated circuit that
Bob Noyce and Jack Kilby who are going to talk about invented, circuit that Bob Noyce and Jack Kilby, who are going
to talk about invented, co-invented. But anyway, okay, back to this moment in time. So Morris
is just studying the Shockley textbook in his hotel room, but like he's not a college
and he doesn't have any teachers. He just has the book.
Wow.
But he's very resourceful. So he figures out that one of the senior engineers at the
plant is kind of an alcoholic and hits
up the hotel bar almost every night. So what Morris does is he comes home from work in
the early evening, he studies in his room for a couple hours, and then later at night
when the older colleague shows up at the bar, Morris goes down to the bar not to drink,
but he brings the textbook and he asks the guy questions like, I don't understand this,
I don't understand that.
Like grill me.
And he's just like buying drinks for his buddy.
So great.
Incredible.
Here's the quote.
He says later, he being the older colleague didn't solve all my problems, but he solved
enough so that I could move ahead.
He was my main teacher about electrical engineering.
So great.
Wow.
So this goes on for three years.
Morris is like rolling hard.
He's burning the candle at both ends,
working and at the bar, but not drinking, learning.
But as he like is learning the industry, coming up speed,
it becomes pretty clear to him
that if he really wants to go places
in this new emerging industry,
Sylvania, not really the right bus to be on, so to speak.
And obviously, Don Valentine figures out the same thing and jumps to Raytheon and then
to Fairchild.
Morris says the moment when this crystallized for him was there was a talk that a senior
manager at Sylvania gave at the plant.
And the quote that the senior manager said that stuck with Morris for the rest of his life was, we at Sylvania cannot make what we can sell and we cannot sell what we can make.
Real great position to be in. So Morris was like, damn, I got to get the hell out of here.
Yeah. That's a signal to move on if you ever heard one.
Totally. So like Don, Morris leaves Sylvania for greener pastures. However, not to California.
Halfway in between.
Or to Silicon Valley, yep.
Halfway in between.
So we talk a lot about Fairchild and the Traders 8,
Silicon Valley, blah, blah, blah, the place to be.
Here's the secret, Silicon Valley is all marketing.
The biggest semiconductor company in all types,
digital, analog, everything at that time,
was not in California, it was in Dallas, Texas.
It was Texas Instruments.
Which of course, me, you, many people in our generation
know of as the people that made our graphing calculators
in high school and college.
But of course, at this time,
I don't even think they had a consumer division yet.
They were just making-
No, no, no, no, no, that's gonna come up later. No, TI was the juggernaut. Like
now Silicon Valley is Silicon Valley. But then it was, yeah, okay, California, I don't know,
West Coast, whatever. Like TI was the big incumbent. They were the juggernaut. TI actually
got its start. I had no idea before doing the research here. In the 30s, you're like, how did
a technology company and a semiconductor company end up in Dallas, Texas? They started making instruments, Texas instruments for measuring seismic activity
for oil exploration.
Whoa.
So all the oil companies-
Oh, that makes sense about Texas.
They were like the TSMC, like the technology provider to oil companies. And that's what
led them into computing and into digital to power that business.
Oh, wow.
They were huge.
Not just huge in terms of the company,
but they were the technology leader.
Bob Noyce, like I was saying a minute ago,
is credited when he was at Fairchild,
inventing the integrated circuit and all that.
Well, he was the co-inventor.
Simultaneously, it was co-invented by Jack Kilby,
who was at TI, and Jack was actually
the one who got the Nobel Prize for inventing the integrated circuit.
Gordon Moore, who was also at Fairchild and then founder of Intel along with Noyce, he
would coin Moore's law.
But Jack has a great quote, too, about the implications of the integrated circuit and
semiconductors.
He says, what we didn't realize then, this was a little later,
when they were inventing it,
was that the integrated circuit
would reduce the cost of electronic functions
by a factor of a million to one.
Nothing had ever done that for anything before.
Wow.
It's such a great way to frame it too,
like this had never happened in human history.
There was this thing that used to be X expensive in terms of resources, and then magically
one day it's a million times cheaper.
Yeah, that's crazy.
I didn't realize it was on that scale.
This is probably a good time to talk about some definitions because there are some things
that we've thrown around already.
I think everyone has a general understanding of what these things are, but it's worth understanding
more precisely before we move on. The first of which is a transistor. The best way to think about
a transistor is not the tiny little transistor that's on a silicon die today, but think about it as a
little encased piece of circuitry with three prongs coming out of it. And those three prongs
will save the technical names, basically
have an input and output and something that controls the input and the output. It's a
switch. It has two purposes. The first of which is being a switch where you can decide
that either stuff is going to go through it, stuff being voltage, current, or none, or
it rounds to none. And so that way you can decide, hey, this binary piece of equipment is either off, zero,
or on, one.
Okay, so that's a transistor.
Now a transistor can be made out of lots of different things.
It can take any implementation.
Why is everybody talking about silicon?
Well silicon as an element is a semiconductor.
It is a metalloid.
It has some properties that make it like a metal, like a semiconductor. It is a metalloid. It has some properties that make it like a
metal, like a conductor. It has some properties that make it non-conductive.
Imagine trying to move electrical signal through a piece of wood. It's not going
to work. But imagine moving it through copper. It's going to work really well
and you're never going to be able to interrupt it. Well geez, wouldn't it be
great if we had some material, a semiconductor, where we could modify whether current was flowing through it or not.
Make it a switch really easily. Exactly. Exactly.
Well, and lots of things are semiconductors. Germanium was the main material for a while,
but germanium is expensive and rare. Silicon is made of sand.
I think it's like the second most plentiful, mineable element on earth.
Yeah, I mean, it's sand, right?
Yeah.
There's one other major thing, though.
So we've been talking about transistors.
The IC.
Yeah, the IC.
The integrated circuit.
The integrated circuit.
A transistor, it's a switch.
Before the IC, people were making switches.
Like you make one switch at a time,
you wire it to another switch.
You know, if you've seen photos of ENIAC and vacuum tubes,
literally they're plugging one tube into another, you're still doing that with transistors.
When Noyce and Kilby invent the IC, now you can put a lot of switches on one thing.
And, you know, fast forward today, the latest processor, you know, the five nanometer processors
that TSMC and basically nobody else is churning out, I don't know, billions, trillions of
switches are in like a tiny little.
Integrated circuit.
Without the integrated circuit,
that never would have happened.
So this invention, this miraculous invention
of the integrated circuit, it happened in 1958.
When did Morris Chang join Texas Instruments?
1958.
Ooh, fascinating. Coincidence?
Yes, totally a coincidence.
Absolutely coincidence.
Absolutely a coincidence.
And again, to peg us in history here,
we're still, I think, 10 years before the founding of Intel.
Yes, exactly 10 years.
Yeah, Morris obviously wasn't working directly
with Jack on inventing the IC.
But this gives you a sense.
TI, this is the place.
This is like Google plus Facebook.
Without the world paying attention to them.
Yes, and in Texas. So Morris gets assigned as his first project to a sort of problem
child within TI. They have entered into a deal with IBM. IBM is working on their first
mainframe computer major project that's going to use transistor
logic instead of vacuum tubes, the IBM 7090.
And they anticipate so much demand for this product.
Usually IBM manufactures everything for all their products themselves, but they're like,
we need more chips than we're going to be able to make ourselves, so we need a second
source for our chips. They turn to TI and they're like, hey, we can give you all the designs for you know
how to do this, this chip that we want for our product. We want you to additionally manufacture
some of these in addition to our own line. You might even say almost like a contract manufacturer
of chips or like a foundry business almost, you know.
Hmm, interesting. But it's not going too well. So IBM's own plant is churning out transistors
with about a 10% yield, which means that of every 100 chips that they turn out of the
plant, 90% of them fail and only 10% of them work. Yikes. That's the first party line.
The TI line has about a 0% yield.
Really?
They're lucky if they're getting any that work.
Almost everything coming off the line fails at TI when Morris shows up.
So Morris would say about this later, quote, the supervisor was concerned, the operators
were concerned, everybody was concerned. So Morris, remember,
he's a mechanical engineer by training. So he starts tinkering. He's like, well, I know this
is a mechanical process, chemical and mechanical process creating this stuff. I'm just going to
use my training and optimize it like a good mechanical engineer. So he starts doing some
stuff. After about four months, he gets the yields at the TI plant up to 20%
So twice as good as the first party line at IBM and there's a great profile
There was one of the main sources for this episode in IEEE spectrum
Oh, yeah, great industry magazine that we'll quote from here. They write suddenly even TI President Pat Haggerty knew Morris's name
IBM thought Chang had just gotten lucky, but when the company IBM sent engineers down to
talk to him, Morris described the theories he'd been testing and explained why his experimental
process worked.
This achievement propelled him into his first managerial job, creating a Germanium transistor
development department with 20 plus engineers reporting to him.
So this is his first big win
here in the foundry business. So on the back of all this, TI is like, all right, we got a rising
star here. They offered to sponsor him to go finally get his PhD. They even offered to continue
paying his full salary while he's getting his PhD, which they're paying for. All right. So they think
like very highly of him. Very, very highly of Morris. I mean, this one probably made the millions doing this in 1958.
It's funny, I don't know anything about the commercial success of that particular IBM
mainframe, but if it's the first one that's transistor based instead of being vacuum tube
based, I have to imagine that it was far more efficient for customers.
Customers are probably lining up for it.
I bet there's a lot of demand.
And what's Morris making a year? Like $20,000? Maybe?
You know, how much does it cost to go to Stanford then? Not much. So they're like, sure.
So Morris goes to Stanford, but he's now like a pig in mud. He has found his calling. He can't
wait to get back to Texas, back to TI. So he finishes his PhD in two and a half years. Wild.
One of the Stanford interviews is with John Hennessey, the president of Stanford at the time.
John's like, Morris, tell the students,
how did you finish your PhD in two and a half years?
Morris is like, I don't know, I was focused.
I didn't do much else.
So by 1964, he's done, he's back at TI.
And this is right as people have discovered
the silicon is way more cost effective
and scales up way better.
And if I remember right, the initial attempts at using silicon were that
people didn't know how to work with it yet.
And so even though it was more abundant and cheaper, there's some particular
manufacturing process that you have to do to silicon in order to make it as
viable as it became.
Yes.
How to dope silicon to make it function and produce it at scale as a semiconductor.
And listeners, this is where you should start to get the idea that, especially today, manufacturing
these products involves the most advanced process in human history consisting of layers
of innovation in chemistry, physics, mathematics.
It's breakthrough after breakthrough after breakthrough,
all building on top of each other,
which need to all happen in the manufacturing process.
So even here in, what, 1964, we're
starting to get into the level of complexity
where it's some of the most advanced science ever done
being applied in an engineering
and manufacturing fashion to get even marginal results, you know, at 20% yields off the manufacturing
line.
And a little preview to fast forward to today.
TSMC, they're a contract manufacturer for silicon.
That is what they are.
TSMC has 40% operating margins as a contract manufacturer.
It's not like this is just, there's no technology or R&D.
They are one of the most advanced technology organizations in the whole world.
There is so much IP just in the manufacturing.
Take out the design, take out the functions, just making this stuff is so hard.
I mean, now it involves like lasers.
Like it's, we'll get to it later.
It's going to blow your mind how this stuff is done.
But anyway, so Morris, he's coming up, he's learning,
like literally as this whole industry is getting developed,
he's right there.
So a couple of years after he gets back from Stanford,
he's still rising through the ranks.
In 1967, TI makes him a general manager
of one of the divisions within the semiconductor business.
And that's
where he has his next big breakthrough. And this is on the business side. So
Morris notices what they're doing, setting up these new plants for all these
successive new methodologies and processes of manufacturing, you know, at
this point integrated circuits and silicon and pumping out these chips,
it's super expensive to do this,
super cost capital intensive.
So what TI and everybody else in the industry did,
when they would start a new product line
that would use a new fab for chips,
they charged a lot of money for it.
Cause like, man, they put a lot of money into these things.
So right off the gate,
you want the latest new hotness in the end products that TI is selling, they're gonna put a lot of money into these things. So right off the gate, you want the latest new hotness in the end products that TI
is selling, they're going to charge a lot of money for them.
Yep.
Morris realizes he's like, that's not actually optimal to do that because as
evidenced by his first big win at TI with the IBM line, there's a learning curve
until getting the yields right and learning how to manufacture a new process.
And in the beginning, you're going to have really low yield.
And so what you want, ideally from a fabrication perspective, is you want to have a ton of
volume from the get-go.
As soon as the plan is online, you want to be running at max capacity so that you can
A, learn as fast as possible, get yields up to
the profitable levels.
And then you want to still be running at max capacity as long as possible because you already
spent the fixed cost to make the plan.
Basically you always want max capacity.
So when you started out by pricing so high, you kept demand low and you weren't able to
get up to capacity fast enough.
It's almost like they didn't realize the benefit
of the potential operating leverage that they had
because they were just passing their exact economics
onto their customers and saying,
you basically have to pay us for us
to do all these fixed costs.
And then you'll get all the benefits of how cheap it is
to stamp it off the press every time.
Whereas what they really should have been doing is saying,
we will make an investment.
We'll eat the cost of having to spin all this up,
but boy are we going to be super profitable
on every chip that comes off the line.
Yep, totally.
So Morris is thinking about this.
He hires BCG and they come up with the idea
of actually pricing low to start,
to drive this volume and speed up the yield curve.
And then also the side benefit of that is,
if they're pricing low and everybody else is pricing high, they're going to grab a ton of market
share and probably keep that.
Paying consultants.
I know. Well, so here's Morris's quote about this. He says, this was in the late sixties
and Boston consulting group was a very small outfit when we did this. And we used loads
of data, a lot of theory and a lot of effort. The result was so-called learning curve pricing. So start low and then continually automatically reduce
the price every quarter,
even when the market did not demand it.
And this was a very successful effort,
even though it was somewhat controversial.
A lot of people thought we were being foolish.
Why would you reduce the price when you didn't have to?
But we did it because we believed in it.
And indeed our market share just kept expanding.
That combined with other strategies
made the TI integrated circuits business
the biggest IC business in the world
and also the most profitable.
This is right when Intel is getting founded.
So screw Fairchild, screw National, screw,
and like TI is kicking all of their butts
and it's thanks to Morris.
And interestingly enough, the reason I always thought that Fairchild was sort of so successful
in those days was out of all the defense spending and research that was being done at Stanford,
the government as a customer.
But is Texas Instruments playing in that ecosystem at all?
Good question, probably. I mean, I think this is a case of the in that ecosystem at all? Good question, probably.
I mean, I think this is a case of the rising tide
is floating all boats.
Yeah, Fairchild's killing it.
Intel's killing it.
National's killing it.
TI's just killing it bigger than anybody else.
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So on the back of this, Morris gets promoted to VP at TI, one level below the CEO, running
the entire semiconductor business. That happens
in 1972. And he becomes the obvious leading candidate to be the next CEO of TI, which
he's like, yeah, I want to do that. I'm focused. This is what I love. This is why I've been
going to the bar for three years reading a textbook.
Exactly. But might be fair to say history turns on a knife point.
Things don't entirely go as planned.
Three different viewpoints, as far as I could identify,
on what happens next to Morris at TI.
He does not become the next CEO, obviously.
Viewpoint number one is simply and probably fair
that he was just discriminated against
because he was ethnically Chinese. Although, at this point, I'm pretty sure already he was just discriminated against because he was ethnically
Chinese. Although at this point, I'm pretty sure already he was an American citizen, but
anyway, and he got passed over for, I have no evidence for it, but not be at all surprised
that that was part of what was going on. So that's one. Two, second point, which Morris
totally acknowledges, TI was a really big company, the semiconductor division.
He had made it probably the most successful
and the most fastest rising division within the company.
But you mentioned calculators.
They were starting to launch the consumer products
division at this time.
And so in 1978, so six years he's
running the semiconductor division as VP,
they move him over to VP of Consumer
Products in 1978 because this was a big new strategic initiative and it wasn't going super
well. And they're like, oh, Morris is a great manager. He can fix this and turn it around.
Different set of competencies though. I mean, you need like marketing.
Yeah. Here's Morris's quote on this. Mark Sheppard, then chairman and CEO of TI,
agreed with the prevailing wisdom at the time
that a good manager could manage anything.
In this case, I think he was wrong.
I found the consumer business to be very different,
like you were saying.
The customer set, completely different.
The market, completely different.
And what you need to get ahead in that business
is different too.
In the semiconductor business,
it's just technology and costs.
In consumer, technology helps, but it's just technology and costs. In consumer,
technology helps, but it's also the appeal to consumers, which is a nebulous thing.
Not Morris's strong suit, or at least not anything he's trained in.
Yeah, that makes total sense.
So in 1983, five years after he gets moved over to take over the consumer business,
he hasn't turned it around. It's still struggling. He gets demoted to, quote, head of quality and people effectiveness, which is pretty much a slap in
the face. Like this dude built your semiconductor business. Is this when he says he was put out to
pasture? Exactly. So that's number two. Here's number three. I found some evidence on this.
It's unclear to me how much of this is Morris's fault versus his successor. But while Morris was
definitely responsible for making TI Semiconductor a powerhouse, at some point towards either at the
end of his tenure running it or under his successor, they totally dropped the ball.
This is when Silicon Valley in California takes over. So in the mid 70s, the semiconductor industry transitioned over to the metal oxide process,
the MOS.
You ever hear about MOS, MOS semiconductors?
Yeah, the precursor to CMOS.
Exactly.
So that happened in the 70s.
And TI, again, was well, they had the best engineers, they were well positioned to lead
this transition. they didn't.
Actually, most of the talent within TI that were the ones that led
the industry transition to Moz left,
including probably most prominently a guy named LJ7,
who left and founded a company called Moztech,
and then he later became a semiconductor venture capitalist and founded Seven Rosen Ventures,
which was one of the early VC firms.
So he was a TI guy and he left.
And you know, the culture at TI, as shown by Morris's experience, was not like Trader
S8, Silicon Valley, you leave.
It was like, you're a company man, you know, you stay at the company.
Right.
So Motorola poached a whole bunch of Moz engineers from TI and it all
kind of fell apart. Culminating in the biggest huge loss, this is really history turning
on a knife point, in 1980, so Morris has already transitioned to consumer products, IBM puts
out a secret RFP bid proposal for a secret project that they're working on, this is 1980 1980 by a new group based out of Boca Raton, Florida.
Do you know what I'm talking about, Ben?
I have no idea.
Some listeners might know what I'm talking about.
This is the secret project.
This is the RFP to be the microprocessor,
the CPU for this secret project, the IBM PC.
Ah, okay.
That was out of Boca Raton? Yeah, it was a secret project, like a Skunk Works division of PC. Ah, okay. That was at a Boca Votone?
Yeah, it was a secret project, like a Skunk Works division of IBM.
Oh, wow.
To build the PC, which is a big, you know, IBM was the mainframe company.
Right.
We're going to build a personal computer.
So Skunk Works project and TI, you know, a couple of years earlier under Morris
would have been an obvious candidate.
Remember, he had the relationship with IBM going all the way back.
TI probably should have been the processor chosen.
Right.
Instead, of course, it was Intel.
I think it was the 8088 that was chosen for that first one.
Wow.
Boy, did that set things in motion.
Well, then the architecture standardizes on x86 and boom, there goes the whole next generation
of computing away from TI over to Intel. The sort of family of IBM with Intel processors
and eventually running Microsoft operating systems.
And then all the IBM clones all running Intel processors.
OK, so this is really where.
That is a major loss.
In the highway of history, TI accidentally
took the off ramp there.
They did.
Now, OK, is that Morris's fault?
Is that not Morris's?
I don't know.
Certainly the culture at TI was we rotate you around,
you're gonna fix consumer.
He didn't fix consumer, but couldn't.
And then this, like the semiconductor powerhouse
took an off ramp, as you say.
All that, like his career at TI is basically over.
So he was the rising star.
Everybody thought he was gonna be the next CEO.
And at age 52 in 1983, after he stays a couple of years being the head of whatever,
he was something staff. Yeah, yeah. He just resigns. And he's like, wow, well,
I guess this is it. My career at TI 30 years done. He still regarded super highly in the industry though,
in the semiconductor industry.
So people start calling him with opportunities.
And he wants to be a CEO.
I mean, that's what's on his mind.
Yeah, that's the, he wanted to be CEO of TI.
That didn't happen.
Like he wants to be CEO,
but he whittles it down to two opportunities
he's going to consider.
One is to go to a competitor called General Instrument,
which people may have heard of another one of these old chip companies. It was based in New York, in Manhattan, in New York City,
actually, to go be their COO, the number two there, with an understanding that like, hey,
if things go well in a couple of years, you'll replace the CEO, become the CEO there, or
to become a venture capitalist.
Really?
Yeah.
No way.
So he was weighing the two. I don't know where or how.
I couldn't find that out, but he was weighing these two opportunities.
The VC idea is going to come back up in a big way in a second, but obviously he goes
with General Instruments, GI.
A, his dream is to be CEO.
B, he's got this chip on his shoulder from the way TI ended.
So great.
So he goes off to New York, you know, he leaves Texas,
lives in Manhattan, things are gonna work out at GI.
Thing though is GI had a very different culture than TI.
TI was this research, build, develop technology,
push the ball forward.
GI is this New York based, they were almost like at the time
like a proto tech private equity firm.
Their strategy was they just acquired lots of different semiconductor businesses, either
independent companies or divisions from other companies.
Try and integrate them.
No, they would acquire them.
They would get these business units into good shape and then they'd sell them again.
Oh, really?
Yeah.
They were like, literally they were like a financial engineering firm, basically.
Definitely not Morris's cup of tea.
So he only stays there
a year. It's clear that's not a good fit. So he resigns again. So within less than 18
months, he's had two major setbacks. Basically, you know, his dream is over. Like here's the
quote from him. He says, after these two setbacks at T.I. and G.I., I did not think that my aspiration to be the CEO of a major U.S. company was in the cards. Well, turns out he was right.
He was not going to be the CEO of a major U.S. company. So how do we go from this dude
in his mid-50s, former rising star, now washed up from that to he's in Taiwan, he's CEO
of TMC? I don't think you could
ever script this out. I think this is probably the most unique, every founding story is unique,
but I think this might be the most unique founding story we've had on acquired so far.
So back when Morris was at TI, when he was running the semiconductor business there,
he went over to Taiwan a couple times to talk about building a manufacturing business there. He went over to Taiwan a couple times
to talk about building a manufacturing plant there.
TI would own and build the manufacturing plant
but outsourced to Taiwan.
Not like a TSMC style business like is a TI plant there.
Anyway, he had no connection to Taiwan.
Remember, he's Chinese.
He's not from Taiwan.
People are like, oh, Morris, you went back to Taiwan.
He didn't go back to Taiwan.
Yeah, he talks about how Taiwan was a strange land to him
when he first got there, that it's not going back. So, he talks about how Taiwan was a strange land to him when he first got there, that
it's not going back. So it's not the land is a strange place to him. But if he is going
to call someplace home and return there, is it the People's Republic of China?
Well, I think he would say at this point, it's America. He's been in America. He's
a US citizen. Well, I don't know what he would say. It's complicated. So anyway, so he had
met a bunch of government officials
in Taiwan when he was talking about building
this plant over there.
And that was back in the 70s.
Now we're in the 80s, mid 80s.
Taiwan at this point, it's a manufacturing nation.
You know, they have no IP, they have no technology.
Okay, the quote's great.
All right, so this is Morris.
We had no strength in research and development, or this is Morris. We had no strength in research
and development or very little anyway. We had no strength in circuit design, IC product design.
We had little strength in sales and marketing. And this is of course referring to Taiwan as a
nation. And we had almost no strength in intellectual property. The only possible
strength in Taiwan that we had, and even that was just a potential one, not an obvious one,
was semiconductor manufacturing,
wafer manufacturing. And so what kind of company would you create to fit that strength and avoid
all the other weaknesses? The answer was a pure play foundry. Yeah, I mean that was Taiwan at the
time. So to give you a sense, the average gross margin of a Taiwanese company at this point in
time in the mid 80s is four to five percent. Zero four to zero five percent gross margin.
Gross, before you even have overhead operating costs.
Yeah, I mean it was like, you know, if you were, grew up around when Ben and I did, you know,
sort of born in the 80s in the US, you see made in Taiwan on everything, like, you know, Barbie dolls, toys, clothes,
everything was made in Taiwan, you know, now it's made in China or made in Vietnam or elsewhere,
but made in Taiwan was super low end physical manufacturing stuff.
Yeah.
And a way pull forward the seven powers section, as Hamilton Helmer would sort of explain,
if your margins, particularly your gross margins are only four or 5%, you're in an industry
or a business where all the profits are arbitraged away and everyone's just raised to the bottom
on prices and no one's able to build any real enterprise value because everyone's just out
competing each other for pure commodity. I mean, four to five percent gross margins.
People used to hammer on Amazon, I guess, for being like a low gross margin business in the like 40%.
Anyways, I can't even imagine running a company with that level of gross margins.
The Taiwanese government, though, they wanted to come up in the world.
They were like, this is where we are now.
This is not where we want to be.
They knew that technology was the way.
They had decided back in the 70s that they would establish an initiative called the Industrial
Technology Research Institute, or ITRI.
And the goal was for it to become like the Bell Labs of Taiwan to do some tech transfers
from the US and elsewhere and home grow some real technology businesses in Taiwan so that
maybe they can lift businesses out of poverty there at least.
And so Morris wasn't going to Taiwan to start TSMC.
No.
He was being recruited to ITRI. So one of the ministers he had met, a guy named KT Lee, who because of this, he would also
become venerated in Taiwanese history. He's known as the father of Taiwan's economic miracle,
literally because of this. Wow. He recruits Morris to come over and run ITRI, be like the head of
Bell Labs Taiwan essentially. And this is like a ridiculous thing for Morris to do. He had been, you know,
captain of American semiconductor industry. He was put out to pasture at TI,
but at least he was still at TI. And then he was COO at General Instrument. He's gonna go
over to Taiwan and run like a research park there. Like, what?
And like every time someone starts something like this, it doesn't go well.
A government top-down innovation mandate from a country that's not a world power tends not
to turn into a gigantic economic success.
This is like all the countries and cities and the like that are like, oh, we're going
to build the next Silicon Valley in XYZ.
And we're going to recruit some former Silicon Valley person to come do that.
And it's going to work. Probably not going to work.
So everybody tells him not to do this.
All his former colleagues, his wife at the time, tell him not to do this.
His marriage was actually falling apart, maybe in part because of this.
And he's had all these experiences, like, you know what?
I just, I need to change the scene.
I got to get out of here.
So he takes the job and he figures,
you know, it's going to be cushy. This is like a soft landing.
Right. He thinks about this as like the pseudo retirement he's going into.
Totally. So here's his quote. By then I was financially pretty secure. I was not rich,
but you also have to realize that the standards of wealth were much lower back in 1985. And he's
going to live in Taiwan where, you know, corporate magnets have 5% gross margins,
but says, but still in absolute standards, I was financially secure, which meant that
I could live according to the way I desire, which was actually pretty modest for the rest
of my life without having to earn a living or a salary.
This is retirement.
He also makes a joke.
I remember after that about how, by the way, interest rates were higher back then.
So that was much more achievable on less principle.
So 1985, he goes over, he takes over as president of E-Tree. It's kind of a culture clash. So
this is retirement for Morris, but he's still coming from this hard charging industry. All
of the employees of E-Tree are people in government jobs in Taiwan. Government jobs, not even in a democracy
because Taiwan is like, it's under martial law. I think that it just ended. This is not
the same, this is like jobs for life. You're a government official in a non-democracy type
organization. Morris says, back then, they considered me a foreigner who suddenly became
their boss. They were scared of me and they were right to be scared of him.
So there was one thing though that the government had done right before Morris showed up, which
was they had successfully negotiated one technology transfer license in the semiconductor industry
from, did you find out what company this was?
This is probably what they were trying to negotiate with TI for.
I do.
It's a three-letter acronym.
Oh, yeah.
Yep, yep, yep.
We haven't talked much about it on this show, but this is another.
Yeah.
Talking about captains of American industry, RCA.
RCA, that's right.
Yeah.
So RCA had a semiconductor line and the government in the 70s, the Taiwanese government, had
negotiated a tech transfer from RCA.
But this is like 10-year-old semiconductor technology, right?
This is not like the latest generation.
No.
TI and Intel and everybody like, you know, and Fairchild, they're international, they're
leading the way.
They're at the bleeding edge of semiconductor manufacturing process.
RCA was already at least a generation behind.
By the time it actually gets onto the ground in Taiwan,
they're two and a half generations behind
the leading producers.
So it's like the only thing that you could do with that is
Super low end stuff.
Right. There are some category of goods
that don't need a fast or the latest processor and
Totally. Totally.
Even today when TSMC or Intel or Samsung or whoever builds fab, the leading edge fabs,
they produce the leading edge stuff for a while and then the new generations come on.
They don't shut down the old ones.
It's just chips that don't need the same bleeding edge performance.
They keep getting made on the old ones.
Often that's automotive,
or now what we think of as IOT,
but the stuff in your smartphone, obviously, is the-
The leading edge.
Yeah.
So the government, E3 does actually spin out a company
using this old RCA technology
that would be called UMC,
United Microelectronics Corporation,
not a technology leader. It actually does okay in
the long run. They would later spin out their own chip design business. So UMC was doing both
fabrication for third-party clients and designing some of their own chips with the fab that they
created. They spin out their chip design business later. That becomes MediaTek.
Oh, no way.
Yeah, which is a $50 billion company today.
So like, you know, the government did pretty good.
Like this is pretty good.
Yeah, totally.
And you know, when Morris arrives because of this,
he's not starting from a standing start.
Right.
Like it's not good, but there's some-
They acquired IP, they've created a company,
there's a paved path.
So he gets to work at E-Tree, he's working on all this,
he's transforming the organization
into a high performing organization.
And then all of a sudden out of nowhere,
KT Lee comes back to him and is like,
hey, great, you're running our Bell Labs,
you're running eTree.
Now I want you to start a company.
And Morris is like, uh.
And KT's like, yeah, yeah, yeah.
I don't want you to have somebody else in eTree do it.
I want you, Morris Chang,
to start a new semiconductor company here in Taiwan and I want you to
make it into a global leader."
Morris is like, um, okay.
He doesn't say this directly.
Well, he's got a great quote I'm going to say in a minute, but again, remember this
is not a democracy in Taiwan at this time.
Morris has also won his third job in three years.
Yeah, he doesn't need a salary to survive, but this is kind of the end of the rope for him. If he gets fired
here at E3, he's legit done. Done, done, done. So he kind of doesn't have a choice here.
The quote, this is so Morris, so great. He says, it was like in the movie, The Godfather,
it was an offer I couldn't refuse.
And I do think the implication was go start an Intel or go start an IBM. It wasn't go
start the very first pure play foundry.
Yeah. Lee had no, he was the government, he was a minister. He was like, go start a semiconductor
company and make it a world leader.
Right. Those semiconductor companies, they do really well. So go do that. And that's
of course, when Morris says, okay, I'm being told I should do this. I have some latitude I can take and some liberties
I can take on how I do it and the quote that I read earlier about evaluating
Exactly, what type of semiconductor company should I start? That's how he sort of informs the business plan
So Lee is like, alright good. We're Capiche. We're clear. Come back to me in a week with a business plan.
Tell me what you need and we're gonna make this happen, right?
Someone's like, oh, okay, a week, all right.
And then like a day later, Lee supposedly is like,
I'm gonna need you to come in on Friday.
So like you got like three days.
You know, they say necessity is the mother of invention
and yet these three days are
what creates the, you know, now ninth most valuable company in the world.
Morris comes up with this brilliant idea to create a pure play foundry company to be a
contract manufacturer.
Sounds genius today in hindsight, as Steve Jobs would say, you know, it's easy to connect
the dots looking backwards.
But at that time, was this a good idea, David?
Well, no. The answer is no. You know, like we've said all along, all the chip companies,
all the, you know, American and European and, you know, Japanese, all the leading
semiconductor companies, they made their own stuff. You know, and there was some sharing of production and some companies were emerging that were
borrowing production from the big guys.
There's a great quote right around this time from Jerry Sanders, who was the co-founder
and CEO of AMD.
And he famously said in the mid 1980s that, quote, real men have fabs.
That's right
So ironic because in the 2000s AMD would spin out its fabs and go fabulous global foundries
Yeah, I can do global foundries
But yeah, like this was not an obvious idea
like if you wanted to be a real semiconductor company you made your own chips and the idea was like
This isn't like manufacturing Barbie dolls here. Like this is real technology. Like you need to control it soup to nuts.
And already at this point in history, I mean, this is an important point to make because I
didn't realize this coming in where I thought, wow, Apple really outsources their manufacturing.
They outsource some of it to TSMC and some of it to Foxconn. And maybe some of those people will
start to do each other's
work. No, this is a completely different thing. Assembling an iPhone is completely, completely
different than taking a brand new design for a next generation ship and manufacturing that
ship. One is manufacturing and one is alchemy. The alchemy can only be done by alchemists.
I think even here in the late 80s, we're already
at the point where it's manufacturing broadly, but yeah, it's not like, well, I got a factory.
No, no, no, no, no, no, for the opposite of that. We said a minute ago, this is a bad idea. So
Morris says, now, however, there was one problem with the PurePlay Foundry model and it was a fatal problem.
It could be a fatal problem, which was, where's the market?
He sounds like Don Valentine here.
Where's the market?
Show me the market.
This whole idea, it was really a solution looking for a problem.
And of course the solution being that all we have is manufacturing capability here.
So let's start a company that just manufactures.
And it's like, you're looking around like, okay, who's definitely going to manufacture?
Real men have fabs. Yeah.
You know, they're not real startup. I mean, there are startups, but all these startups
are building their own fabs. Like nobody wants to do this. So nonetheless, you know, he has
to start a company who's literally got a gun to his head.
But he does have the core insight here. It's interesting.
These companies don't exist yet, but Morris has reason to believe that people will want
to start fabless chip companies and that they will need a foundry to fab those chips.
He says, when I was at TI in general instrument, I saw a lot of integrated circuit designers
wanting to leave and set up their own business.
But the one thing or the biggest thing that stopped them from leaving those companies
was they couldn't raise enough money to form their own company.
Because at the time, as we were just saying, real men, it was thought that every company
needed manufacturing, needed their wafer manufacturing, and that most capital intensive part of a
semiconductor company, of an IC company, does the manufacturing.
And so I saw those people wanting to leave,
but being stopped by the lack of ability
to raise a lot of money and build a wafer fab.
Totally, right?
But those companies, this like,
if you build it, they will come.
They haven't started yet.
They haven't come yet.
They haven't come yet.
So Morris, he knows what the long-term market is gonna be,
but he's gotta find the short-term market.
He needs some real politic here.
So what's that going to be?
So he says, well, maybe I can go around to the big guys.
They've been doing, just like my first thing back at TI,
they've been doing some line sharing
for either new products that they need excess capacity for,
or for older products that they need to transition some fabs, but they still need to make components.
Maybe I can take some of that off their hands.
And so he goes around and he talks to Intel, he talks to TI, he talks to everybody in the
industry and they're like, yeah, he talks to Motorola.
Like sure, fine.
And the government had told him, we know it's going to take a lot of money to set up a fab.
We're good for half of it,
but you gotta go raise the other half of it.
And we want you to raise it from like an Intel or a TI,
you know, somebody who's gonna be your first customer
and that they're gonna be bought in.
So he does the rounds, he goes and talks to everybody.
He gets meetings with Intel, he gets meetings with TI.
They're both like, you know, Morris, we like you, but no.
So he said the last ditch effort and he has a meeting with Phillips, the Dutch company. They have a semiconductor business. So Morris,
he has a great quote about this. He says he would describe Phillips as the first rung
of the second Raiders in semiconductors, but they were the only interested option. So they put up 28% of the capital.
Government puts up 50%.
It ends up being 220 million in total.
The 110 is probably a lot more than what the Taiwanese
government thought they were going to be buying here.
And then literally the premier of Taiwan,
like the head of the government, has to then go around
to all the other business leaders in Taiwan
and like strong arm them into investing the rest of it. The other, what is that? 22%, I guess.
Yeah. We also should say, remember that Philips was a Dutch company because that's going to
come into play later.
Ooh, I don't know how that's going to come into play.
Yeah, putting a pin in Dutch.
Oh, okay. We got a surprise coming. I'm going to be surprised here. We're doing a real time,
doing it live. This may be the craziest part about the whole TSMC founding story. I'm 99.9% sure, Ben, you do not know this.
Oh.
Do you know what the pre-money valuation was on TSMC?
No, I couldn't find that anywhere.
It was zero dollars. Morris Chang got no equity in the company.
No.
Zero. So 100% of the company was owned by?
The investors.
50% by the government.
The other 50% were owned by the investors.
Morris got nothing.
And just got to keep his salary.
He was a government employee.
Wow.
There by the grace of the government.
Oh my God.
Isn't that unbelievable? Like this is so the grace of the government. Oh my God.
Isn't that unbelievable?
This is so the opposite of Silicon Valley in every way.
How is he worth $3 billion today?
Well what he did as TSMC started to work, he basically put all of his money into buying.
He bought his own shares in the company.
I don't know if it was privately before they went public on the Taiwan Stock Exchange in
1994 and then the New York
Stock Exchange in 1997. But yeah, he put basically all of his excess cash flow into buying TSMC
shares.
Oh my God.
Isn't that wild?
So the government owned 50% of the whole business.
And you can see their perspective too. They're like, hey, we hired you to do this. And then
we told you to do this. You are our foot soldier. We are the mafia.
Wow. Yeah. Things had really not gone well in his career that he was willing to take that deal.
Yeah. Crazy, right? And okay, before we go on in the TSMC story, we need to have
two real quick sidebars. So it was 1987 when TSMC gets officially stood up, they raised the money at a zero dollar pre-money valuation. Do you know what other company, other big
thing happened in 1987? We have covered it on this show in the chip world. Is this the
founding of Arm? Yes, it is. Yes. Yes. Arm. JV between Apple, Acorn and VLSI Logic,
which was the sort of manufacturing partner.
They were an ASICS company.
That's a whole nother sidebar we're not gonna get into.
But yeah, 1987, what a year.
Brand new, unconventional, instruction set architecture.
It's totally different than the x86 stuff
that the whole industry and world
seems to have standardized on at this point.
The Anis Mirabilis for the semiconductor industry.
And useless, right?
It's in 1987, it's ham strong, it's very few instructions.
PCs are always plugged in.
So what do we need a low power chip for?
This thing's pathetic.
Real men have fabs and real men use power.
Okay, so that's sidebar number one.
Arm gets started.
Okay.
I was wondering, I don't actually know the relationship
because obviously today a huge
amount of volume of TSMC's manufacturing is making chips for iPhones, which since the
outset has used ARM.
Tips that are using all mobile devices, iPhones and Android, all of which are ARM and lots
of servers that are ARM.
So presumably there's some relationship coming between TSMC and ARM.
Well they're really close partners.
I mean the way now this stuff is so integrated.
Yeah.
All the companies have to like.
The architecture companies like ARM, the design, the EDA companies like Synopsys, these guys
are all deeply, like the engineering is all deeply in bed with one another.
Okay, so you mentioned EDA.
I'm going to take your sidebar and I'm going to.
You're going to raise me.
I'm going to raise you one more sidebar. So listeners were two clicks out here
So this is a pretty good point to talk about how the value chain went from
one company that
Created transistors and then they designed the chip they manufactured the chip they marketed the chip
Here's how the value chain looks today and I think you've already alluded to I think in the 80s it already started to look like this
First there's EDA. There's electronic design automation. This is the software that professional chip designers
Use to do their work. So synopsis I think cadence. Yeah cadence. There's another big one
Yep, there's two leaders. So that's like I don't know Excel or like figma for chip designers. Yeah, thatence, there's another big one. Yeah, they're the two leaders. So that's like, I don't know, Excel or like Figma for chip designers.
Yeah. That's what they use.
Proprietivity tools. Yeah.
So that's category one of four.
And of course, as you can imagine, the software to design the chips
probably has to be very aware of the manufacturing capability
of who's going to be manufacturing the chips.
But let's put a pause in that for a second.
So then, of course, there's the fabless chip design companies.
So today, think Apple, Nvidia, Qualcomm.
Broadcom.
Eventually AMD after they stopped being real men,
apparently.
Tons of innovative new startups now, like Cerberus.
PA Semi.
Tesla.
Before Apple acquired it.
Yeah, PA Semi is coming in a sec.
Okay, okay.
So you've got the EDA companies
that are making the software,
the Fabless companies that are designing the chips
using the software. Then third, there's one company that we have not talked about yet,
one component of the value chain. And these are the people that manufacture the machines
Oh yeah.
that go into the factories that the foundries operate.
There's actually one between, well, no, actually I think above EDA, there is one more part
of the value chain,
there's a fifth, which is IP.
So that's all like ARM.
Oh, right.
Yeah, like architecture, IP,
there's actually a ton of companies now
that do just straight up IP.
And I thought before this episode,
these were like, oh, just shell companies
that sue one another about IP.
It's not that, systems are on a chip now.
So like everything is on one chip basically.
You need a USB functionality in your chip.
You don't need to design it.
You just buy some IP off the shelf.
So there are companies that do that.
Yep. Okay.
So that's a good point.
So that's our fifth sort of like IP.
They own the instruction set architecture.
They kind of create the general rules
that you're playing by when you're designing a chip
such that whoever's writing the compilers
knows what assembly language they're targeting that can then operate on the chip that's going to be designed.
So we covered the EDA, we covered the IP, we covered the Fabless companies.
There's somebody before we get to the foundries, which is the equipment manufacturers that
sell to TSMC.
So more historically, you've got Lamb Research, you've got applied materials in the US, you've
got Tokyo Electron in Japan, but today, I just want to give everyone a taste of this
and then we'll get more to it later.
There's a company that is also Dutch based.
Ah, there it is.
There it is.
ASML, which was originally ASM Lithography, and Lithography is marginally in scope for this episode.
There's a whole thing we could do on the magical process
that is Lithography.
Take me back to my high school photo lab.
Right?
Yeah.
And the L is Lithography.
So the company was originally called ASM Lithography.
They make the most advanced chip manufacturing machines
in the world.
They're the only company that makes them.
They're located still in the Netherlands. Their biggest the only company that makes them. They're located still
in the Netherlands. Their biggest customer is TSMC. They, and this is where
I want to bring it all the way back around and we of course will talk about
the magic that is these machines later. It was founded in 1984 as a joint venture
between Advanced Semiconductor Materials International, ASM lithography, and Philips.
Oh, wow, I did not know that.
So that-
That's crazy.
Is the beginning of the relationship between
TSMC and their equipment provider.
Oh, wow.
And what a strategic point.
I mean, because, well, it's TSMC's insane capital
operating cashflow production that enables
them to spend capex above anybody else that allows them to buy more ASMR equipment than
anyone else.
But that relationship, wow.
I mean, these machines, we'll get into it later.
It's going to blow your mind what this stuff does.
All right, listeners.
This is a great time to thank our big partner here at Acquired, JP Morgan Payments.
When we told the team over at JPM that we were remastering our TSMC episode, they smiled and said, oh we have
the perfect thing for this episode that most listeners won't know about but is
super important to how international companies accomplish global trade. Which
of course that is like catnip for us so we're like well tell us more. Yes. JP
Morgan has a whole trade and working capital group
that helps companies manage risk and access
liquidity for global trade, in addition to, of course,
facilitating the actual payments to drive growth.
Yep.
Imagine this scenario.
You're a global auto parts manufacturer,
and you build up inventory of a key car engine component
because it requires a super complicated production process.
But then you have to wait for the final demand forecast from the actual car company, your customer,
before you can ship units to them. But in the meantime, you have to secure credit lines and manage your own supply chain.
Sounds complicated. Enter JP Morgan's Trade and Work and Capital Group.
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And as you all know, you can't time the market.
But if you intend to be in business for decades,
you know you're going to exist through all sorts
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So make sure you've got a great payments partner that's
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JP Morgan really is a behind-the-scenes powerhouse
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Our huge thanks to JPMorgan Payments.
You can learn more at jpmorgan.com slash acquired
or click the link in the show notes
and just tell them that Ben and David sent you.
Okay, back to my second sidebar.
Also gonna be worth it, PA Semi.
We did an episode, wave is like episode 20 something.
This is like when Acquired was a very different show
when it was actually about small acquisitions.
Totally. Yeah.
So I don't know that we actually covered this,
but I uncovered in the research for this episode,
do you know the origins of PA Semi?
No, I don't.
Okay, so ARM, my sidebar number one,
you know, 1987 also created, right?
They're just an IP design company,
like I was saying in your sidebar.
It's like inception over here.
So they just license out the Arm architecture
to other companies that then design
using the Arm architecture.
One of their original licensees was DEC,
Digital Equipment Corporation, like OG, way back in the day.
So they took the ARM architecture
and they tuned it for performance
and they called what they did at DEC,
their version of ARM that they created, StrongArm.
And that product line within DEC
would later be acquired by Intel of all places.
Okay.
Crazy way.
Intel acquired an ARM architecture.
Right.
Anyway.
They're the x86.
Yeah.
They remarketed it as X scale.
I think they ended up shutting it down.
Huh.
So a bunch of the core engineers on the team, like the DEC team that had been working with
ARM from back in the day and they're like, we just got acquired by Intel. What the hell? Like, you know, screw
this. We don't want to go work for Intel.
There's no interesting flourishing alternative architectures at Intel.
Yeah, we're Arm engineers. We're going to go start our own company.
That's PSMI?
That's PSMI.
Ah.
So the leg is-
And of course the underpinnings of all of Apple's chips today.
Totally. So the lineage of all of Apple Silicon,
probably the most valuable, defensible part of Apple today in terms of technology,
was Arm and Deck to Intel to PISMI to Apple.
Whoa. That's wild.
I don't think I ever knew that.
So you can trace Apple Silicon all the way back to Apple.
Yeah, because Arm was a JV with Apple.
Crazy.
With Intel and Deck in the middle.
Wow.
Okay, so back to TSMC.
The short-term market is,
Morris basically begs all of his old colleagues
in the US and European and Japanese semiconductor
industries to just give the dregs to TSMC and it really was the dregs so here's
Morris on what this was. The IDMs would let us manufacture their wafers only
when they didn't have capacity or when they didn't want to manufacture the
stuff themselves anymore. Now when they didn't have the capacity and asked us to do the manufacturing,
then as soon as they got the capacity,
they would stop giving us orders.
So it wasn't a stable market.
When they didn't-
So it wasn't actually a thing they wanted to outsource.
They were just using them for-
No, it was just like they didn't have the capacity,
so they needed some extra access space.
But then when they got the capacity online,
they took it away.
Right.
And then the tips that they gave us
that they didn't wanna make anymore, well, the reason they didn't wanna make they took it away. Right. And then the chips that they gave us that they didn't want to make anymore,
well, the reason they didn't want to make it
was it was losing money.
So they basically were just transferring their losses
on producing these chips to TSMC.
So how do they get out of this?
So Morris continues,
the conventional conclusion at the time
was that there was no market.
That's why the pure play foundry idea
was so poorly thought of.
What very few people saw,
and I can't tell you that I saw,
was the rise of the fabless industry.
I only hoped for it.
And then as you said, but I had better reasons
for hoping for it than the people at Intel,
at TI, and Motorola, because I was now standing outside.
When I was at TI in general instrument,
I saw a lot of these IC designers wanting to leave,
start their own businesses,
and the constraint was setting up their own fabs.
So like, yes, he saw that at TI, but remember he had been considering becoming a VC
instead of going over to E-Tree.
Yep.
So this is the ultimate end-around.
He becomes essentially like the world's best semiconductor VC.
He takes an index out on the whole future innovation
and entrepreneurship market in semiconductors by becoming the platform
that they're going to build on instead of like going and investing in them.
Like he enables all of it.
He's like the Y Combinator of semiconductors.
Right.
Or in many ways, the Tencent.
Tencent, of course, also does direct investing, but the idea that you could get distribution
through WeChat, it's kind of like, it's not distribution, but it is manufacturing.
There is a thing that you have to raise 10 to 20%
of the capital that you otherwise would have needed
to raise if TSMC exists.
Yep.
And just like Don Valentine, you know,
kind of when he left to go join VC a generation earlier,
and again, it was not VC, it's TSMC's building the platform,
but Morris is a hero.
So all these engineers, they all look up to him.
And he knows a lot of them personally, the ones he doesn't know, like who's not going
to take a meeting with Morris Chang, right?
He almost ran TI.
Totally.
Like he did all this amazing stuff.
It's interesting because it's like with the incumbents, of course, because they had it
in their DNA to be a manufacturer, of course they wanted to take the most profitable things
and manufacture them in-house.
But if you actually are betting on all these startups
that will never develop DNA to be their own manufacturer,
they never want to take that back.
Yeah, and so Morris is now going out and evangelizing
and he's like, all these great designers,
like, we're an option for you now.
You want to leave, you want to start your own company,
you don't need a fab, we be your fab you know it takes a
couple years for a couple years TSMC has to survive on the dregs from the IDM's
the big guys but after a couple years these startups get going you know
little companies like Qualcomm Broadcom Marvel Nvidia these are all started with
TSMC. NVIDIA was started in 1993, only ever raised $20 million.
$20 million.
And never opened their own fab.
I believe 100% with TSMC.
Wow.
Well, maybe they have other foundries too,
but the vast majority of their business,
Jensen talks about this, Jensen Huang.
It took him actually a little while
to get on Morris's radar.
But once he did, the vast majority of Nvidia's chips,
TSMC makes them.
And Nvidia is what, like a 350, $400 billion
market cap company now?
It's wild.
And only raised $20 million.
It's like the AWS for chip companies.
Never would have been possible before.
Nope.
So this is what's super cool.
I don't think Morris saw this.
This even exceeds his
wildest dreams. He was hoping for this Fabless market to take off, but this creates this insane
flywheel for TSMC. So the Fabless market starts to grow, which they're exceeding and enabling it.
As that happens, TSMC's revenue grows. And because they have 50% gross margins and 40%
operating margins, they can take that profit and buy more advanced machinery.
Plow it back into CapEx. Build more fabs. And advance the level of their technology. Remember,
they were starting from behind in technology. Within about 10 years, they catch up and then
they start to exceed everybody else. So as they push the manufacturing process technology forward,
they're manufacturing better chips
with smaller wave, you know, process lengths.
They're enabling their customers,
which are the Fabless companies,
to get better and better performance.
As they get better performance,
the Fabless companies can address more of the market
and more use cases.
So their existing customers get bigger
and new file
bliss customers start, which gives them more revenue,
which repeats the whole cycle.
And, you know, it goes slowly like any flywheel.
It takes a lot of effort and a lot of time to start
turning it, but fast forward to now.
So in the early two thousands, when TSMC finally caught up to the bleeding edge level of technology with other
semiconductor companies, there were 22 companies that were at the leading edge.
I think it was like, I don't know, let's call it 150 nanometer process or something like that at
that point in time. 22 and TSMC finally broke into the pack. They were one of the 22. By the
late 2000s, it had gone from 22 down to 14 that were at the leading edge.
By the mid 2010s, there are six.
It's basically Samsung and TSMC, right?
Today there are two. Five nanometer process is the current leading edge. Only TSMC and
Samsung. Intel has been trying to get there, but they haven't been able to. They've fallen
behind. And the next process is going to be three nanometers. TSMC is going
to launch that next year. By the way, just slipped six months.
Ah, interesting. Well, Samsung has already slipped to 2024. Whoa.
So very likely in the next process is just going to be TSMC.
Which means that you will see that on an Apple slide somewhere announcing the next iPhone,
talking about how it's a three nanometer process.
They'll take all the credit for it.
And TSMC is totally fine with that because their job is not to market.
It's to empower their customers.
This flywheel, it's just unreal what happens here.
They run the table on the whole industry.
It is interesting.
The industry went from vertical to horizontally integrated where the very best products in the market became horizontally integrated.
And it's interesting how i'm trying to figure out what drove that because at some point.
I guess there's a couple components to it one is the speed at which mores law happens.
makes it such that you can't be good at everything. You can't be good at everything from EDA
to making the manufacturing equipment,
to running the manufacturing process,
to designing the chips.
You're not gonna write your own instruction set architecture.
People did need to break into best of class.
Oh, Morris has got this great quote about this
that I have in here.
So he says, the semiconductor business is like a treadmill
that speeds up all the time.
If you can't keep up, you fall off, and that's Moore's law.
From 22 down to two down to one, even when their competitors are only doing the one thing
that TSMC has done, like if you fall behind by a step, you're toast.
Right. And it's because there's this big part of it that you're talking about that hasn't
come up on other episodes because we tend not to talk about companies that require a
lot of manufacturing prowess.
But in order to stay on that treadmill, the number of tens of billions of dollars that
you need to be spending into CapEx is going up.
So you need to be enormously profitable so you can build the factories for the next generation.
Yeah.
I mean, well, there's two things.
So yes, that is 100% true. And the scale of this now,
I mean, TSMC just announced they're going to spend $100 billion in CapEx over the next three
years. $30 billion this year, 60 over the next two, and I bet that keeps going up. So that's a lot of
billions. You might even say, like, this is so strategically important and people are talking
about this. Certainly China is talking about this. The US government's now talking about this. Governments might need to come in with a bazooka of money and create other
options because almost all their manufacturing is in Taiwan. It's in this strategically,
geopolitically challenged location. We need to re-onshore some of this in the US. China,
of course, wants their own. You can't just spend the money and do this. US government could come
in and say, we're going to spend a trillion dollars this year to do this. They can't just spend the money and do this. US government could come in and say, we're gonna spend a trillion dollars this year to do this.
They can't do it because we're gonna get to powers later.
But there's this marriage of scale economies
and process power, the TSMC, like in this industry.
There is no amount of money you could spend
to catch up next year.
You can't because the engineering is so hard
and the learning curve takes decades to get to this point.
I was listening to a podcast, Bloomberg AdLots podcast about this, where they
were talking about this and their reporter who covers TSMC is great.
China, they asked them a question like the, well, China could just spend a
billion dollars and do this, create their own fabs and they're doing this.
What's the company called?
SMIC.
SMIC.
Yep.
It's the Chinese.
Yep.
Cause basically TSMC seems to have picked a side in the US.
Yeah.
And so with a little bit of prodding, I'm sure, from various presidential administrations
over the last five years.
Yeah. The guy who covers TSMC was like, they can do that and they are doing that, but they
wouldn't know what to do with it. And it's not because they're dumb.
It's the hardest thing in the world.
It's the hardest thing in the world.
Yes.
To do this stuff, to make the equipment that ASML does and to manufacture the way that TSMC does,
it is the hardest thing to do in the world.
Yeah.
Anybody else could get all the same equipment from ASML.
Actually, that's not true.
Oh no, I'm saying even if you could,
you wouldn't know what to do with it.
Right.
And it's not cause you're dumb,
there are only like a small number of people in the world
that can operate this stuff.
All right, I'm jumping out of my seat here,
so I'm gonna do the ASML thing now.
So the reason that some people can't get their hands on the ASML equipment is because
the Netherlands did not renew their trade agreement with China. Also likely it has been
reported that probably that is because of US prodding to say, hey, these pieces of equipment
you're making seem pretty specialized. You're the only people in the world who can do it, and it makes the most cutting edge semiconductor manufacturing
technology, maybe let's not sell that to SMIC in China. And so they're not doing that. Now
you might say, oh, come on, how hard can this stuff be? Well, these machines-
Tell us Ben, what these machines do. Well, first of all, they cost $200 million for a machine that makes the chips, and that's
going to go up to like $300 million.
And by the way, on a lot of this, we have a lot of thank yous for John Bathgate and
Britton Johns from the episode of the Knowledge Project that they went on to talk about a
lot of this stuff.
It takes four 747s to ship one of these machines.
So you buy one, your TSMC, you buy one and it arrives.
And of course the 747s, then there's a crew
of ASML employees on site, not only to assemble it,
but then to help you run it.
So like you mentioned, these companies are deeply integrated
with each other to pull this off.
Okay, so what does running it mean?
What do these machines do?
Okay, so it becomes exponentially harder
to manufacture chips the more dense they are.
So David, you mentioned that 150 nanometers or so
from several years back, and we know now
that the M1s are made on this five nanometer process.
Well, the wavelength of white light,
of regular light is 193 nanometers.
Ooh, that seems like a problem.
Well, it's certainly wide, but you know, we're humans.
We come up with clever solutions, we can solve this.
And so you shoot it through a lens
and maybe you shoot it through some water.
Like a laser.
Well, not yet, but even that really only gets us to like 11 nanometers. So how the heck are we supposed to make these chips where the transistors are ostensibly only a 5 nanometers apart when what we've done to date, shooting through lenses and shooting through water gets us to 11 nanometers. Well, okay, so this is crazy. You have to create a plasma. So what they
do, and this is called extreme ultraviolet light or EUV, this is a process that is just
wild. On one side of the machine, you drop molten tin. On the other side of the machine,
you then hit it with a highly specialized laser. You perfectly pulse them, it explodes into a plasma
which creates extreme ultraviolet light.
Now, of course, this is hard enough to do
as you can imagine how that might work,
but you actually have to do that 50,000 times per second.
Yeah, and what I read is that the accuracy with which
that laser needs to hit the drop of molten tin
is more precise than the calculations
to send the Apollo missions to the moon.
And you got to do that 50,000 times a second.
Unbelievable.
Now, of course, think a little bit more about this.
Well, wait a minute. That wavelength is so small, we're going, you know, shy of 11 nanometers here.
We're going to have 5 nanometers, 3 nanometers, that actually it is absorbed by all known mirrors,
which we're used to reflecting light,
but they don't reflect this light
because the wavelength is so small.
So part of this process involves reflecting it
a bunch of times, like 20 or something,
before etching the silicon.
So what do we do?
Well, ASML actually needed to invent a new type of mirror
to do this, and they also needed a contract with a German company to make this special type of laser, which is the only known
company in the world capable of making it.
This is crazy hard stuff.
They only make 50 of these machines per year or so.
They used to have competitors, like Nikon used to compete with ASML on this, but it's
too hard.
They gave up.
That's how hard extreme ultraviolet lithography is.
And of course, we haven't talked a lot about this, and I think it's outside the scope of
the show, but just to overly simplify, lithography is kind of the process of taking that silicon
wafer and etching a design on it.
And if we want to do that in smaller and smaller ways, we got to do with more and more specialized
equipment. And at the end of the day, if you want to make the M2, the M3, you know, the A18X Bionic,
whatever it's going to be called.
There is no other way to make it than this extreme cutting edge alchemy.
It truly is alchemy.
So, you know, Ben.
So you're a government, you want to throw 100 billion?
I was gonna say, you know, like acquired is doing really well. Like we're on a tear here.
You know, we've got power. We got brand power. We got network, you know, economies. We got our
community. Like we're doing well. We should invest in it. We should do the opportunity. We should
compete with TSMC. Yeah, screw the governments. We'll do it. We've got a couple hundred million
dollars. We'll buy this stuff. You know, you have a CS degree. You know, you're the more technical
one of it. You can run this stuff, right? When we get the shipments from ASML, you can make this happen.
I wouldn't know the first thing to do.
Even if we could invest the cash, even if we could build the facility, even if we could
buy the machines, which by the way, that's going to be hard because there's 50 some on
back order.
So like I can't even get it for years.
TSMC has ordered out all of them for years.
It takes people who have done the most advanced manufacturing in the world ever in history
in order to know how to do the next version of it.
And this is why TSMC has 40% operating margins.
It's crazy.
Totally crazy.
I'm just like in awe of this.
Completely.
Okay.
So a little while back before we get totally geeked out on that, which was awesome,
you said something like, how do we get this flywheel effect, you know, it's great, but
like how do we really get from TSMC started taking the dregs from the IDMs, then the Fabless
companies came along.
How do we get from there to like now there's another really important chapter here.
And you're going to flash us forward from like 93, 95 to like 2010 ish?
Is that what's about to happen?
2008.
Well, first we'll stop in 2005.
So 2005, you know, things are going well, better than Morris ever imagined.
These fabulous companies are getting started.
Nvidia is killing it.
I mean, I was making gaming PCs at the time.
I wanted those Nvidia GPUs.
But Nvidia wasn't a top 20 stock in the world.
No.
I mean, Intel was like, Nvidia, come on.
Real men have fabs.
OK, maybe we're beyond that part, but they were making GPUs.
Nvidia's stock tracked whether they
won the next Sony contract for the next PlayStation
or the Xbox.
That was the market for GPUs.
That was the market.
Right.
Great market, but it's not what we're talking about here.
It's not about machine learning.
It's not about crypto.
It's like, is the next PlayStation
gonna include your chip or not?
Totally.
But still great for TSMC.
It's awesome.
2005, Morris is 74 years old.
He's like, all right, I did it.
I've been buying TSMC stock with my own money.
It's done well enough.
I didn't really need to work anyway.
I'm gonna call it. Ready to retire,
ready to ride off into the sunset. He hands the reins of TSMC over to his longtime lieutenant,
Rick Sy, and he retires. He spends a couple years, he's just chill. I don't know what he's doing.
He loves literature, he's like reading all sorts of stuff. He's on his second marriage,
which he credits his second wife for really reinvigorating him and inspiring him.
Then it's summer of 2009. By the way, that's right around the time that people were starting to speculate that EUV
might work. All this had been kind of an idea to this point.
Oh, interesting. They've been science projects before. Oh, cool. I didn't realize that. Oh,
well, this is going to make what happens even more sense. The financial crisis had happened
in 2008. And, you know, chaos everywhere.
We've talked about it a lot on this show.
Surprise press conference, TSMC summer 2009.
They announced that Morris is returning to lead TSMC as CEO.
Rick is out.
Morris is coming back for the third act of his career.
I don't even know what number he's wearing.
He's not 45 because that was, you know, the second what number he's wearing. He's not 45, because that was the second act.
He's like Jordan.
He's beyond Jordan at this point.
Coming back, he's going to be CEO again at age 78.
Rick would actually have a second act himself.
Do you know what Rick is doing now?
No.
Rick is CEO of MediaTek, which is a UMC.
So like he's doing fine.
Rick's doing great.
But Morris comes back.
Why does Morris come back?
But this is, Harold, it is like kind of a botched transition, right?
Well, there's a lot of stuff going on like from Morris to Rick people kind of viewed it as like you didn't really
Do a great job bringing in the next CEO of the company. Maybe I don't know enough to say okay
I think maybe but also like there's a lot going on at this moment in time. So the financial crisis. Yep
That's like a crisis that's affecting everybody.
So that's one thing.
But the other thing, so in the press release,
there's a quote from Morris and he says,
one, this move will not affect TSMC's fighting spirit
and is likely to spur greater intensity.
But two, he says that he sees, quote,
golden opportunities ahead.
What are these golden opportunities
that he's referring to?
It's 2009, mobile, the smartphone.
2007 in July, the iPhone comes out.
2008, the iPhone 3G comes out with the app store
for the first time, the SDK,
all these developers building for it.
But of course-
And Android comes out in 2008?
Yep.
Apple had to this point,
well, building this operating system,
the scaled down version of OS X, it's Unix,
but they weren't designing their own chips.
They just used an off the shelf Samsung chip.
They got it right with saying like,
hey, we gotta use ARM in these things
because we need a really low power device.
So they've done actual God's work and magic to be able to bring a PC x86
operating system, create a sub operating system from it. Totally that runs on ARM. Yep. Miracle.
But of course it's an off the shelf Samsung processor. Totally. Well, even that's great for
TSMC. Like, you know, Intel's not making that. Okay. So that's one. We're going to talk more
about that in a sec. But we should say, and Samsung also fabbed it because Samsung is both a chip designer
and a manufacturer.
But the point is on mobile, the previous whole paradigm of computing and silicon everything
was PC.
It was like stuff plugged into a wall.
It was Intel.
It was x86.
And like, yeah, TSMC could now access some of that because AMD went fabless, but come
on.
But now all of the leading companies that are going to make silicon for design
so are our arm companies, you know, Qualcomm, Broadcom, MediaTek, Apple,
who all are fabulous. All are fabulous.
OK, so that's a big opportunity.
And guess who knows all of those people, Morris.
And we should say to 2009 was an interesting tipping point,
because if you'll remember back to the 2007 introduction to the iPhone, Steve Jobs has a slide where he says their hope, their goal is to get 1% of the existing smartphone market.
Right.
So, Apple had no notion. I mean, Google had no notion of how big smartphones were about to become. In 2009, we're starting to see, I think the iPhone 4 came out, we're starting to see a ton of different OEMs making Android phones.
You're moving into this era where everyone's looking at each other going, oh, this might actually be the next computing paradigm.
Yeah, yeah, yeah. Well, that was half of the next computing paradigm. Remember back when this is when I started in BC, there were two waves that everybody was talking about.
Mobile and social?
Mobile and on the consumer side, everything shifting to mobile.
That was what happened.
Bring your own device?
Well, sort of.
You're on the right track.
What happened in the enterprise?
The cloud.
The cloud.
Right.
So you got mobile and you got cloud.
And it's so simplistic, but those are the two things that drove trillions of dollars
of market cap over the next decade.
Well, what's the cloud?
So at first, the cloud is good for Intel, right? X86, you're putting CPUs in the cloud, Amazon's buying lots of...
Dude, the cloud's the best thing that ever happened for Intel. Those are incredible server
architecture.
It was the best thing that ever happened to Intel. But as the cloud progressed and computing
workloads progressed, the CPU became a lot less important.
Like AI started becoming a thing,
CPU like, yeah, maybe you need some of that.
Maybe you'll use Intel, maybe you'll use ARM,
like whatever, but what really matters.
Well, the majority of cloud workloads are still on CPU.
Yeah, okay, fine, fine.
But you're right, the future looking.
Why is Nvidia now a $403 or $404 billion market cap company?
It's not because of the PlayStation.
And it's bigger than Intel, right?
And Nvidia's 2X Intel's market cap, something like that.
Yeah, to your point.
It's the cloud.
The notion of chips that are really good at parallelized processing, which is GPUs, and
matrix multiplication effectively, vector math, versus the CPU, which are sort of these general purpose
workhorses built for the operating system
that runs on your computer, super good for serial.
Of course, there's like multi-core, you know,
there's 64 cores on a CPU now,
so they're good at parallelization too,
but all this stuff, especially machine learning is GPU.
It's GPUs and it's specialized. Like the Tesla Dojo stuff.
That's not x86.
Oh yeah, we're in this.
I mean, the other thing that foundries enabled,
the Fabulous Era enabled is the custom chip.
Like everybody's building custom chips
for all sorts of things.
Yep.
So you got these two big golden opportunities
that are coming online.
And Morris is like, I got this.
And we should say, we should clarify too,
I think Tesla uses Samsung.
Oh, interesting.
Not TSMC or at least for part of it.
And I think they actually even fabbed their chips
in Austin in the US.
Really?
Yeah, so they can't imagine that's gonna last.
This is like the beginning of the like,
what everyone's sort of hoping for in the US
is this like return to American manufacturing of chips
They're gonna have to go to TSMC though in the next generation because you want three nanometer
It depends. I mean it depends what the workloads are. Yeah, I guess so what depends what you need. Well, anyway point is
Intel's dominance is over and
the index on all that's gonna take over is TSMC. Yep, and
Morris
Riding back in he comes in he gets these deals done. So like the Apple deal
2012
Morris Chang
78 80 years old and I think the Apple rep on that was Jeff Williams the classic Tim Cook's Tim Cook
That's right.
I think there was something where it was even like one went over to the other's house for dinner
or something and it was like a living room conversation to ink the deal for, hey, we bought
this company, PA Semi, we've been designing our own chip architecture in-house, we're gonna
launch, I think it was the A4. Yeah, I think that was the first one.
And it was Apple basically saying, we think a lot of people are going to buy a lot of
iPhones in the future.
And we are competing head to head with Samsung because they're a company that is not clear
on strategy.
They have a consumer angle here with the Galaxy phones.
They think they're also kind of a foundry.
And Jobs hated Samsung famously.
What did he call them?
He called them some derogatory term.
Well, there's been a few interesting things.
There was Steve Jobs saying he was going to wage thermonuclear war.
That was on Google, right?
I think that was Google.
But he had some like, oh, Samsung, they're just like, something that like really put
them in.
It was about the lawsuits.
It was like when they kept stealing Apple's designs.
Yeah.
And then there was something else where someone, this is later, but Tim Cook
read the quote on stage about it being a toxic hell stew.
Well, it doesn't get any better than that.
No, but Bloomberg reported that it was a really big risk for both companies, both Apple and
TSMC.
Apple was relying on a company that was then seen as an also ran.
And the quote is, I think this actually Jeff Williams, if we were to bet heavily on TSMC,
there would be no backup plan.
And for TSMC, it meant an initial investment of $9 billion, fabs are expensive to build,
and devoting 6,000 employees to building a dedicated plant
for Apple in just 11 months.
It took several years before it even began producing
the chips.
So that was in 2010.
And then I think 2012 was the launch of the A4,
designed by Apple, built on the PA semi acquisition.
And of course fabbed by TSMC.
And I think it wasn't until the iPhone 6, which was what 2014, 2013, something like
that.
That they were solely TSMC.
I think so.
And that was like the huge hit product.
Cause remember the 6 was when they first increased the screen size and those things flew off
the shelves.
I'm pretty sure some iPhones had Samsung fabbed A4s and 5s
in them, and some had DSMC fabbed ones.
But I think by the 6, all iPhones were huge winners,
but I think the 6 was like mega, mega winner.
And I think that was all DSMC.
Huh.
9 billion of manufacturing capacity
just for a deal with one company paid off.
That was a bet the farm deal.
And kind of like something only Morris could do.
Totally.
I mean, it really speaks to founder Gravitas.
Yeah.
Even if he had no equity as a founder, no equity that he didn't buy.
So after getting that deal done in 2013, Morris steps down as CEO again, but he stays on
his chairman.
And then finally, once it all plays out and TSMC is
on top in June of 2018, Morris retires, presumably for real.
He even stepped down from the chairman.
Yeah, fully retires from chairman at age 86. Oh my God.
Crazy.
Wow. So that was 2018. So I mean, let's talk about now. So 2020, TSMC, we all alluded to this,
operating profit of $20 billion
on $48 billion of revenue.
They took 17 of the $20 billion in operating profit
and plowed it all back into CapEx last year in 2020.
Beginning of this year, January 2021,
they give guidance that they will raise CapEx
from 17 last year in 2020
to 25 to 28 billion in 2021. In April of this year, 2021, they raised it again to 30 billion
forecast for the year and 100 billion over the next three years. That's like the real
shot across the ballot. Everybody wakes up, the financial markets wake up and they're
like, holy crap, TSMC has cornered the market.
Even Samsung's not going to be able to keep up with this.
It's wild.
All right, listeners, it is time to talk about one of our favorite companies, Statsig.
It's funny, David, Statsig has gone from this little startup when we first started working
with them a couple of years ago to this total powerhouse now.
I know it's wild. I was looking it up and they have added all these customers since
we started working together. OpenAI, Figma, Atlassian, Versel, Notion, tons more. At this
point if there's a growth stage tech company out there, there's pretty good chance they're
using StatSig.
Yep. So listeners, if you are unfamiliar with StatSig, they basically took what was the
standard product
infrastructure at every big tech company,
and they built it as a standalone company.
This includes advanced experimentation tools,
A-B testing, feature flags, product analytics,
session replays, and more.
So if you're building the next great software company,
this sort of infrastructure is essential
because it allows your product and engineering teams
to release things quickly, measure the impact of them, and track progress over time.
Totally.
So, I mean, as we've talked about on the show forever at companies like Facebook or Netflix,
data was just a part of how everything was built, which contributed to all the crazy
bottoms up organic growth that they had.
Now with StatSig, you can get that from day one at your startup.
And today, they're not only trusted by startups, but also by more mature enterprises like Bloomberg
and Microsoft and Electronic Arts.
Turns out that a single system for data-driven product decisions is useful at any scale.
Yeah, and by the way, the scale they're operating at is completely insane.
They process over two trillion events per day now.
By the way, David, this is updated.
The last I checked it was one trillion, and then this morning I pulled it up two trillion events per day now. By the way, David, this is updated. The last I checked it was one trillion and then this morning I pulled it up two trillion.
And they handle releases to billions of end users.
If you're listening to this podcast and you've used software in the last few years, there
is a very good chance you've been a part of many experiments orchestrated by StatSig.
Yeah, it's just awesome.
And as they've gone up market, they've also started to offer some interesting deployment
models like being able to run the whole thing natively inside your existing data warehouse It's just awesome. And as they've gone up market, they've also started to offer some interesting deployment models,
like being able to run the whole thing natively
inside your existing data warehouse,
or just using StatSig's fully hosted solution.
If you want to leverage StatSig to grow your business,
there are a bunch of great ways to get started.
StatSig has a very generous free tier for small companies,
a startup program with a billion free events that's
$50,000 in value and significant discounts
for enterprise customers.
To get started, go to statcig.com slash acquired
and just tell them that Ben and David sent you.
Thank you, Statcig.
So more on today, David, TSMC Today.
Well, okay, so speaking of data,
I think this is the data point
that really kind of says everything.
So since the first IPO
in Taiwan in 1994, TSMC has had compound annual revenue growth of 17.4% for 27 years. Revenue
growth. 17.4% compounded for 27 years. Now the IRR, the equivalent on valuation on market cap, so it was 4 billion market cap
at the Taiwan IPO in 1994.
Today it is 550 billion.
So that is a 19.9% IRR starting from a $4 billion base over the last 27 years.
So 20% IRR over 27 years, incredible by any means,
starting from a $4 billion base,
it is now currently as we record
the ninth most valuable company in the world.
And I think other than Saudi Aramco,
it is the only company in the top 10
that we haven't done on Acquired.
Ooh, interesting.
Yeah, the US oil companies are no longer correct in the top 10
But Berkshire foreshadowing some future episodes
I mean they're in hallowed grounds at this point
The other thing that just talking about financials today so crazy that they grew 31% in revenue from 2019 to 2020
They doubled their keger
From 2019 to 2020. Yeah, it's nuts.
Talk about accelerating growth.
Okay, so in 2020, their adjusted net income was $17 billion.
How are they going to go spend $100 billion over three years?
Is that going to be out of profits of each of those years?
Or do you think they're doing some kind of financing? I don't know. I don't actually don't know if they've done any financing. I'm quite confident
they'll make enough profit to fund it organically because big news just in the past week, they
started this a little earlier in the year, but now they're really doing it. They're getting
away from Morris's second big innovation of reducing prices.
In fact, I think they're going to raise prices this year by 20%.
So the first announcement a couple of months ago was they're not going to cut prices.
And then they just announced they're going to raise prices.
Nobody's ever done this since the pre-Morris days.
Pricing power in action.
Totally. I mean, what a clearer picture of how they have taken a commodity business
and turned it into, I mean, this has got to be one of the biggest moats of all time.
Totally. I mean, they've got 28 billion of cash and cash equivalents on the balance sheet,
and they're going to use that and all the cash that they generate from their operations to plow directly back in
to making sure that everybody else is five plus years behind.
Unbelievable. The other thing is that they already are the largest.
They have over 50% of the market for foundries
for all contract manufacturing of chips.
And like 95 plus percent of the profit.
Correct.
I thought where you were going with that,
it is also true that they have 90% market share
on the current generation, like the leading edge chips.
Yeah. In the five nanometer, Samsung has like five, 10% market share and TSMC has 90 plus percent.
In many ways-
Going to a hundred.
They're the Apple of semiconductors. They don't have all the market share,
but they have all the most profitable market share.
Yeah, exactly. They are the iPhone of semiconductors.
You can still buy previous generation, worse technology from other.
And for plenty of, on the Odleots podcast, this was actually, they talked about the bare
case going forward for TSMC.
One potential one is that, oh, well, the processing power is so good that you're not going to
need the leading edge anymore.
I find that a really weak argument. You always need the leading edge. You think Tesla going to need the leading edge anymore. I find that a really
weak argument. You always need the leading edge. You think Tesla doesn't want the leading
edge? Totally. You think Apple doesn't want the leading edge? Software will always match
the complexity on the most advanced hardware it can run on. Totally. Which is why I love
when people are like, Apple's slowing down my computer. I'm like, yes, I'm sure that's
what's happening. They wrote special code that they're putting on there to make the
consumer... No, it's because every piece of software just always assumes that it has the most advanced processor
on earth and it always gets to developers. Sure, they test on two and three year old equipment,
but no one's making sure that the six and seven year old laptops are as performant. Software
designed for the current generation is hard. I think they Google and Amazon are going to be like,
now we're good. Right.
Hell no.
It actually is worth touching on.
There's one other interesting bit about this five nanometer process, which first of all
is a marketing name at this point.
What it used to originally referred to was the length on the gate on the transistor.
At this point, it's not exactly five nanometers and the additional performance is not going to come from,
you know, making smaller gates.
Here's the interesting thing though,
you actually can't put these transistors
much closer to each other.
So if you think about silicon atoms
that are between the transistors,
you can only fit five of them in a nanometer.
So in a three nanometer process,
sure as marketing speak.
Right, like at some point, you cannot subdivide silicon anymore. So either we need to change
the substrate or the innovations are sort of going to come from elsewhere.
Which has always been the case. Moore's law was technically the doubling of the number of transistors
on an integrated circuit.
Now it comes from multi-core. It comes from all the other advancements of figuring out
how to make chips do more stuff faster.
Yep.
That I think is going to keep going and I think it's going to keep being expensive and
getting more expensive and I think TSMC is the only company that's going to be able to
keep up at the leading edge.
Yeah.
Do you know David about Moore's second law?
Ooh, no I don't.
So everyone knows about Moore's law, but there's this second one, which is also known as Rock's law, after Arthur Rock.
Arthur Rock, yeah.
Yeah, OG.
It states that the cost of a semiconductor chip fabrication plant doubles every four years.
So with fabs today costing 15, 20 billion dollars, I don't know that that's
proven exactly true, but it's certainly... Well, shoot, if we just look at TSMC's capex
forecasting, they're going from 17 to 30 to 60 over two years. So that's way faster than
four years.
So the interesting thing is when you combine these two things, the Moore's law and Moore's second law, it
implies that the leading company, that most profitable company will become a monopoly.
Winner take all.
There you go.
And it's fascinating that both of these things, these laws aren't actually in conflict because
Moore's law is about effectively when you really look at it from a financial perspective,
operating expenses when producing at scale.
And Rock's law is about the upfront capital expenditures
to enable all that production.
So it's everything we talk about on the show.
It's being able to pile investment into fixed costs
as much as possible at huge scale
in order to realize the benefits of making as many
of the thing as humanly possible at global scale.
And TSMC, interestingly, is the most perfect example of this. making as many of the thing as humanly possible at global scale.
And TSMC, interestingly, is the most perfect example of this.
And I say interestingly because we almost always talk about operating leverage and scale
in the context of software on the internet.
This is how venture capital started because actually manufacturing chips, the operating leverage that comes from huge amount of fixed costs into
foundries to make chips and then hopefully be very profitable,
50% gross margin on those chips.
Venture capital financing was built for that for semiconductors.
And it just so happened to work just as well or even better with
software on the internet.
Even better in the notion that gross margins of software can be 80 to 90 percent, not 50 percent.
But I would back that down because it doesn't have the sort of moat defensibility characteristics
that being able to plow your cop ex into manufacturing capability does.
Yeah. Should we do power?
Absolutely. Let's do it.
Let's do it. So for folks new to the show, this is one of the discussion topics we do
for every episode is we go through Hamilton Helmer's excellent Seven Powers.
The best business theory book.
Totally. We've had Hamilton on the show. He's amazing. Go read the book if you haven't.
He identifies seven powers, essentially sources of defensibility, which he defines as long-term
differential profit margins versus your competitors, as we've been talking about on the whole show.
Yep.
The seven that he identifies are counter positioning, scale economies, switching costs,
network economies, process power, branding, and cornered resources.
And we almost always talk about network economies. We talk about counter positioning on this show.
Sometimes we talk about branding.
Sometimes we talk about branding.
I think we're talking about none of those this time.
Yeah, we sometimes talk about scale economies,
which we're gonna definitely talk about here,
but I think we're gonna have our first process power
if I'm gonna forecast, but let's start.
Let's go down the list.
Counter positioning.
I mean, like maybe you could-
When they were starting, and in particular,
would the incumbents have started
with the exact business model?
No, because their profit center was the integration,
that all the margin you get of integrating design
and manufacturing, and by saying,
nope, we're gonna be a pure play manufacturer,
TSMC theoretically was saying, no, we're going to take less gross margin and we're just going
to make it up in volume. I'm actually not sure it played out that way. I think they have more.
Do you know what Intel's gross margins are? I actually don't know. I would suspect they're
higher, but I don't know. Right. Yeah, there was counter positioning here. I don't think I said
this when we were going through it, but before TSMC and the PurePlay Foundry model,
if you were either a Fabless company,
one of the very, very few,
or you were another IDM and you were trying
to get some excess capacity, you rent it from another IDM,
most of the IDMs, they'll be like,
okay, you strong-arm them,
you got a great strategic relationship,
they'll give you some capacity.
But they also demanded the right to market your products under their brand too. So like, which obviously TSMC wasn't
going to. So yeah, there was counter positioning, like the IDM was in no way they were going
to do what TSMC was going to do.
Right. Huh. Okay. Scale economies. Absolutely. That is the biggest, it's one of the top two
with process power, in my opinion.
Switching costs. Well, it's funny, now there are huge switching.
You can't switch off TSMC.
No, unless you're going to stop being on the leading edge.
If you're going to change from being a phone company to an automotive company, you can
switch off of them.
Well, I think it's even deeper than that.
Again, we haven't gone, listeners probably think we've gone deep technically on this
episode.
We haven't even scratched the surface.
Totally.
But yes, if you want the leading edge,
now you gotta be TSMC,
but you gotta be so integrated with TSMC to do this.
Say you wanna switch to Global Foundries
or one of the other competitors out there,
of which there are a few,
you can't just call up Global Foundries and be like,
hey, I'm porting over, expect my business on Monday.
It takes years because you're so deeply integrated
with the process.
So yeah, big switching costs.
Network economies, it's not really worth talking about.
Not in the traditional sense.
This is not Facebook here.
And certainly none of TSMC's customers
really benefit from other customers being on it.
No, I do think there actually is, I don't think Hamilton captures this in his seven
powers and I don't know if he would consider this one, but there is like an ecosystem aspect
here because the EDM companies and the IP companies are so deeply integrated with TSMC.
If you want to be using ARM, for instance, or you know, they're kind of the best integrated with TSMC. If you wanna be using Arm, for instance,
or they're kind of the best integrated with,
now I don't think that's network economies,
that is kind of like this ecosystem thing.
TSMC actually has a name for this,
they call it like the Open Innovation something or other.
It's some corporate name, but it means this.
I do wonder if it's actually worse for a lot of people
that Apple is a TSMC customer,
because who else has access to the five nanometer process right now?
They're going to take as much as they can.
Right.
Yeah.
Good point.
Process power.
Yes.
I think other than Pixar, this is the first time we've really, although we weren't doing
seven powers during.
Yeah.
To me, this is the clearest example I could ever imagine of process power. It takes all 40 years of TSMC's history to have arrived at where they are today.
And even if 10 people left and tried to start the next TSMC, to be able to create what they've
created at this point from scratch, virtually impossible.
All of their IP, all of their people, all of their know-how, all of their relationships
with ASML and the like. Yeah. No amount of money can replicate it.
I think the only thing that will unseat TSMC is a complete paradigm shift.
Yeah.
Something where, like what mobile did to desktop. If there's something where the compute required
in the future is unable to be provided
by anything that TSMC is good at today. If all the crazy laser molten tin asml stuff we were
talking about if all of a sudden there's discovered a new either different or way cheaper way quantum
computing yeah way to do this then that kind of could reset the playing field yeah yeah yeah
totally but even little shifts i bet they'd be fine.
If everyone figured out that like,
hey, silicon's not the best substrate
and we can figure out a better substrate.
If there were like an AWS moment,
of which is funny because TSMC is the AWS equivalent,
but where something happened
that just made it way cheaper than it used to be,
you could now get access to the technology
and the know-how.
Orders of magnitude cheaper than it is now, would take away a big part of yeah their power, but I don't see that happening
No
Absent a paradigm shift. This is TSM sees to lose. They're pretty much they're in the groove
So I think we should skip branding and corner resource for now. It's not really worth talking about literally
They're antithetical to branding like yeah, it corner resource for now. It's not really worth talking about. I mean, literally they're antithetical to branding.
Like it's Apple's brand.
It's not TSMC.
Right.
So this is, I think, a good time to enter our geopolitics discussion.
Because I was thinking about the other way that TSMC could fail would be that China decides
the moment is right to go and assert our force and take over Taiwan.
Depending on how you see it, either annex Taiwan or assert its, as always claimed
sovereignty in Taiwan.
Yes.
Actually start enforcing what has been right the whole time.
I think as they would sort of say, if they were speaking in my casual tone in
English from America, then doing all this business with the West, I have to imagine
that assuming that it didn't start a full war,
like an actual world war, which it may,
then of course they would start using
all the TSMC manufacturing capacity
for all the Chinese customers.
Huawei and...
And Huawei's been a TSMC customer
for a long time. Huawei's end is currently cut off.
Yeah.
So how do you capture that in power?
What is the power or maybe like, let's not-
I mean, that's a risk.
That's like a bear case.
Right.
Let's not get too specific on this, but maybe in a general sense, how do you capture the
power that a company has that comes from regulatory environment?
Where would that get classified under?
That like they have a lot of room to be operating safely.
Maybe cornered resource, I guess.
So you're saying this is like an anti-power for them.
This is a weakness.
Exactly, exactly.
I suppose that all that matters is things that you have
that your direct competitors don't.
So in this strange straw man that I'm putting together,
it would really be about what if you were located
in a country that none of your competitors were also domiciled in
and being there gave you some special ability to be more profitable than others.
Which they had in the beginning with the government in Taiwan.
Basically the mafia boss was like, this is happening.
We're going to strong arm all the business leaders in the country to investing in this.
We're going to make sure that this happens.
Yeah. Okay, well let's put a pin in that. because you're right. It turns out that it's actually not
a perfect power discussion, but the geopolitics thing is interesting.
Well, I think it's the bear case.
Right. That to me, absent an enormous computing paradigm shift is the way that TSMC has an
enormous risk in the business.
Yeah, totally. Which does make it kind of surprising that,
you know, they haven't diversified
their geographical operations very much.
So this is interesting.
So they're facing a lot of pressure for this.
They are spending, I think, $12 billion this year
to start a plant in Arizona,
which will not be the three nanometer,
I don't even think it will be the five nanometer. I don't even think it'll
be the five nanometer. It's not their most advanced manufacturing. I think the U.S. is
subsidizing in a big way. I think it's part of the Biden administration's most recent
bill to try and bring some semiconductor manufacturing here. But they're also starting a fab in Japan
that came out on their last earnings call. So they're doing some...
And they have operations in China, I believe too.
Yep. They're doing some diversification, but I don't think it's for this reason.
I think it's because they're basically getting free money to open fabs and other
places. And Morris has even made comments like,
I don't think it makes any business sense for us to have the leading edge in those
countries, even though those countries want us to have them there. I think it makes sense based on the ecosystem that
we've created in Taiwan to keep operating it here. So the question is if it directly
helps, let's take the U.S. for example, the U.S.'s prowess as a semiconductor manufacturing
force in the world to have TSMC's Arizona plant or if it's really just indirect
and the idea is like, let's try this as a first stab, we'll get more people in the US
familiar with doing this again in case we need to.
Restore this.
Yes.
Yeah.
I mean, this is a scary, scary future to contemplate and hope to God it doesn't happen.
But really the thought exercise here is what would happen if China annexes Taiwan tomorrow?
Which is scary for a number of reasons, the smallest of which is this corporate takeover.
It's scary for a lot of people, their lives.
Yeah, scary.
But I wouldn't say it's the smallest, like everything.
Imagine if we didn't have access to leading edge semiconductors.
That's everything. Imagine if we didn't have access to leading edge semiconductors. Yeah.
That's everything.
What part of our lives do not run on semiconductors?
Right, Ford can't make F-150s right now.
Basically all of our technological progress would stop.
Yeah, you're right.
So I think the question is,
and I don't know enough to answer this,
what would happen?
Would it be possible to airlift the process power
that TSMC has physically out of Taiwan to somewhere else?
You get all the people,
ASML now sends the stuff somewhere else,
you airlift everybody out, there's an evacuation.
Does the process power come with it or not?
I don't know.
That's a good question.
I mean, if the Toyota production system is an example
where Toyota tried to, there was that factory joint
venture with, was it GM?
Yeah, the Numi plant that's now the Tesla plant in Fremont.
With Toyota trying to replicate their process somewhere else, didn't work.
Now it wasn't under threat of war.
Right, this one would need to.
It's actually a good question.
If you think about the US's strategic defensive weaknesses, what's more important, having
onshore semiconductor capability to continue to advance technology in the nation or Boeing,
our ability to build, which we've always held up as this example of the US needs that to
stay US owned, to stay operating, stay profitable, to stay prosperous because it is a matter
of the US way of life
that we're able to protect.
Well, Boeing needs semiconductors.
That's a great point.
So we're now outside our depth,
but is it actually more important
to have cutting edge semiconductor capability here
than airplanes or any of the other
sort of defense supply chain?
And you know, maybe the answer here is like Korea.
Same situation exists in Korea with Samsung, right?
Like North Korea is right there.
I've been there.
I've been to North Korea.
Like I went to the DMZ like, yeah, it's so weird.
It's like an amusement park.
Weird.
It's super, super weird and bizarre.
But yeah, North Korea is right there.
You know, maybe it's the same like China's right there, but this isn't actually going
to happen.
But I don't know what it feels in the last year.
Like the risk of it actually happening
has ratcheted up quite a bit.
I think so.
I mean, it's like globalization as a whole.
It is in the best interest of everyone to continue to share resources, to continue to entangle everything until somebody decides that it's not, and
then we have a big problem.
And hopefully for lots of reasons, it just continues to be okay that
TSMC is located on an island that is of disputed claim.
Yeah. Maybe the best thing that could happen is, my carve out a while back was the book by the
Harvard Chair, the Harvard Astrophysics Department about Uumuamua that he postulates was an alien
spaceship. Maybe if we discovered that aliens are real, that's going to be the uniting force, you
know, like all these conflicts seem pretty petty. Yeah.
I wouldn't use that as an investment basis though.
No. Okay. Before we get into playbook and just hit some things that I think we missed during the
narrative, or at least didn't put a fine enough point on in the narrative, I have a, what would
have happened otherwise that I want to hit? We haven't done this in a while.
No, we haven't. And I'll just read this as a direct quote from Bloomberg.
And there were some awesome sources for this episode,
all of which are linked in the show notes.
In the mid 2000s, as Apple Inc was preparing
for the release of its new smartphone,
Steve Jobs approached then CEO of Intel,
Adelini, about providing the chips for the iPhone.
Intel already sold iPhone,
the processors that ran on its Macs.
But jobs made video to acquire it so that everybody can see the look on my face right now.
I'm just like literally I got like fists in the air. I'm so happy.
And remember, Adelini was the guy that jobs brought out on stage during the Intel transition.
Yes.
Burying the power PC to say this is the future. This is the partnership.
So, okay. But Jobs made what Adelini
considered a low ball offer
and Apple awarded the contract to Samsung.
It later began designing the chips itself,
eventually outsourced production at TSMC,
a contract manufacturer in Taiwan,
they'd been found, blah, blah, blah, blah, blah.
So what could have been?
Apple went to Intel and said, do you want this contract?
Cause they were partners on the back.
Totally. And apparently it was less about the fact that I'm sorry,
you want to use arm what no,
it was more about the money company and it was more about we felt it was a
low ball offer.
Biggest strategic error of all time. All right.
I'm going to postulate a playbook theme and put forward as a possible more than
a playbook theme that what's the, you know, like in geometry,
there's like laws that are approved, but then there's like postulates that
are like, you can't prove them, but our fundamental understanding of the universe doesn't work if they
don't work. Whatever that is, axioms, I don't know whatever it is. I'm going to put one of those out
there. Please never make strategic decisions based on economics. This is prime example. Like the
number of, and we talk about this all the
time on this show, VCs passing over valuation on something. Andreessen getting cold feet
about a $300 million valuation on Uber. This Intel move passing on being partnering with
Apple.
And maybe more specifically than economics, because you could imagine that you would want
to pass on this if Intel
didn't get to be the upside from the deal.
Assuming that the structure is right, then passing because a number is too low in the
structure.
Or Ford Motor Company not hiring Morris Chang over $1.
Whatever.
It's just, humans are so prone to cutting off their noses despite their faces.
We already have the Rosenthal Doct doctrine of never bet against the internet, but now
we have the Rosenthal postulate, which is never make strategic decisions based on pricing.
Based on pricing.
Based on not economics, but pricing.
Hmm.
I like it.
I need to add a new section of the acquired website.
All right.
All right.
Next on Playbook is another one on Intel fading.
So it takes a very long time to become irrelevant.
So despite Intel's stock price being, I think TSMC is like two and a half X Intel stock
price.
As a matter of fact, ASML is actually larger than Intel by market cap.
Now they are the sole source provider of one thing in the value chain to
mostly one company and they're bigger than Intel now.
I'd be fascinated. Okay, so public markets investors who are listening,
shoot us a DM in Slack or post in general.
acquiredfm at gmail.com
Or acquiredfm at whatever channel works for you or Twitter, whatever. Be super curious,
if you are along this thesis that we're sort of laying out on the show,
I'd be super curious if you are along this thesis that we're sort of laying out on the show, how are you playing it between TSMC and ASML?
Which is now Europe's most valuable company.
Right.
I mean, probably you just invest in both, but how do you think about that?
Right.
And what's the up and comer that's kind of speculative at this point, but could be another
puzzle piece here.
Yeah.
Are you also shorting Intel through all that?
Like, what do you do here?
All right.
So my point on Intel is it takes a long time to become irrelevant
They still control 80% of the computer processor market and they have an even bigger share in
Servers so despite everything we're saying it's still huge workloads running on CPUs that are in computers and on the cloud
Pretty big business. Yeah, the majority of workloads they're happening in the cloud is not Tesla Dojo.
It's, I don't know, some company that's not a tech company somewhere in the world
running their Outlook server on Office 365.
Yep, absolutely.
Doesn't need 5-nanometer process.
Two other Intel things. One is that indecision has been very tough on the company.
Bob Swan, who was the former CEO,
started to prepare to outsource manufacturing
of Intel designed ships to TSMC.
Whoa, wow.
I think even like two years ago, this was the plan.
They finally decided, throw it in the towel.
You know, Intel is the greatest ship manufacturing company
in the world, but.
Real men are sensitive.
They talk about their feelings.
Bob Swan is no longer the CEO of Intel.
And now in a complete reversal, their new CEO, Pat Gelsinger, wants to turn Intel into
a foundry themselves by which other fabless companies can contract with Intel to build.
Maybe that's right, but if so, they gotta figure out,
and I think they're thinking about this the right way
because they said it's gonna be a fully separate
autonomous division, they gotta run that
like a completely separate independent company
of the rest of Intel.
And if so, I don't actually know why Intel owns it.
Yeah, I mean, well, A, let's look at AMD here, right?
They did this, they spun out their manufacturing into Global Foundries.
Which has been good for Global Foundries and AMD.
Like, Global Foundries is getting ready to IPO.
Yep. Yeah, that's probably the right strategic decision,
but it's not going so well.
I mean, like it's going fucking.
It's not in TSMC.
Right. It's going better probably than if they had not done that,
but they're not a winner here.
Like, TSMC is the winner.
Yeah. I guess the playbook theme there is indecision is paralyzing. I mean, this company
has spun its wheels one direction or the other and all it's done is make itself deeper in
the mud.
Oh, I just looked up, I was trying to remember this. Gelsinger was the VMware CEO. He started
his career at Intel and then EMC and then EMC owned the majority of VMware.
They became the CEO of VMware. Yeah. And he was the outside candidate to replace Bomber
as Microsoft CEO.
Oh, no way.
Yeah. Yeah. Yeah.
Huh. You know, I hear he's really revered in the organization that people think he's
really going to make some good change there. We'll see.
The last thing on Intel, and it's funny this is not the Intel episode, but there's a thing
that happened here that is very similar to the fact that Kodak developed the digital
camera first in their lab.
They knew it.
They knew this was the future and they didn't commercialize it because it's impossible
to counter position yourself because of the innovator's dilemma. Intel actually saw
extreme UV lithography, EUV first. So Intel was the biggest early investor in EUV,
committing more than 4 billion to it in 2012. Whoa. It was slower than its main rivals,
and this is from the Wall Street street journal in adopting the technology and skeptical
about whether it would work.
Eventually Intel calculated that it was a sure bet to try and improve existing
ways of handling lithography. And of course,
where we are today,
EUV completely enabled the next generation of chips to be built that couldn't.
Argument an example for why you need startups.
Right?
Right?
Like, totally.
Like, yeah, Intel was there.
They invested in it.
They saw it and they were like, meh.
They put four billion in and I think even to this day, there is not a shipping Intel
chip that was manufactured by Intel using UV.
Wow.
That's crazy.
You're right. It is the most perfect, pure example
of the innovator's dilemma in action.
That's why you need startups.
Yep. All right. My next one is that if you're only looking
at the outcomes that happened, you cannot reverse engineer
what the probability that it would happen is.
And this is a very abstract way of me saying the strategy of if you build
it they will come that Morris implemented is a bad strategy and it also worked.
Right.
Like if something's low probability.
This is what Sequoia and Don Valentine hated. They would never invest in developing a market.
That was like rule number one. We invest when the market already exists, not when we need to develop it.
And this is like the classic problem.
This is the knock up here in Seattle.
There's a lot of people spinning out of Microsoft,
starting companies.
Classically, people coming out of Microsoft
would always want to build platforms
because Microsoft was the platform company
and they would always have a small,
too small of an understanding of the market,
of people that wanted that platform today
and they assumed if you build it, they would come.
Morris was that exact problem.
And yet if something is going to be true 10% of the time and fail 90% of the
time, one out of 10 times it's going to work.
And it may have been the case.
I guess what I'm saying here is if you're starting a startup, it's impossible to
know if this was actually a good strategy or if it was a bad strategy
that probabilistically just happened to work. I mean, this is the thing about startups, right?
There are all these rules, but they can all be broken. There is no formula.
Yep, totally. All right. Other playbook themes? I just have one more that, again, we talked about
a bunch in the episode, but I want to highlight, and actually add one spin on here, the Jeff Bezos
quote about AWS, as a startup, anything that doesn't make your beer
taste better, the analogy back to German beer factories
and outsourcing electricity generation.
Outsource things that aren't your core competency.
Right, focus on what makes the beer your beer,
whatever that is, proverbially, taste better.
And everything that is not that,
like finance and accounting, outsource, et cetera,
double underscore that. But you know, like this is accounting, outsource, et cetera, double underscore that.
But like this is obvious, so obvious,
but obviously Bezos didn't say it directly
and thus I think we don't highlight it enough.
The counterpoint to that is anytime you see something
that lots of people, lots of companies are doing
that is not making their beer taste better,
that is a massive opportunity to go build a platform company.
Yeah.
That is how you build a platform company.
Grading?
All right. So we were thinking for grading.
Look, we could grade like, I don't know, Taiwan's decision to do this.
To own 50% of the company at the outset.
Whatever, like, you know, A plus, you know, not interesting.
So we had thought, you know, experiment plus, you know, not interesting. So we had the thought, you know, experiment,
we'll try this for this episode,
rather than like letter grading this,
we'll ask a question,
where does TSMC belong in the pantheon
of great technology companies of all time?
Is it FANG level?
Is it like top five?
Is it top 10?
Is it like top 20? Is it top 10? Is it like top 20? Like where is this?
What is the right context in which we should be placing TSMC, this whole story, the company, the power, all of it?
So interesting because it really does raise this question of value chain.
We talked about the five-part value chain that exists today for making chips.
the five part value chain that exists today for making chips. And so it's interesting because you could say, well, it belongs wherever Intel belonged
circa 2000.
Or you could say, well, the set of products that TSMC manufacturers have a hundred X the
scale that Intel in 2000 had.
Like if you think about it, all this stuff that everyone's all excited about,
every time someone talks about the next wave of computing and they're like
machine learning or they're like crypto or they're like 5G and anything they
tell you is something TSMC makes that enables it all.
When Marc Andreessen says software is eating the world,
it's only eating the world because TSMC has made it so freaking cheap to
manufacture silicon.
And then you can run whatever you want on that silicon, and the cost of compute asymptotically
approaches zero because TSMC, TSMC, TSMC.
So how much do we ascribe to them versus ASML?
How much do we ascribe to them versus the entire landscape of talented chip designers out there, including the like 600
chip designers at Apple working on the Apple Silicon, is hard to disambiguate that.
So where does it belong?
I mean, it's probably the most successful and important B2B hardware company of all
time. I think we can safely say
At this point it surpasses Intel
I mean gosh right like that's a big statement to say really Intel silicon value the traders say like all of it Moore's law
But in compounding all the value shows up at the end
Yeah
It is true that the value that TSMC will create in the world over the next year, two years, three years, is probably more than the entire silicon industry leading
up to this point combined.
I mean, hell, they grew 30% last year at an already unimaginable scale. Intel's not doing
that. Okay, I think we can say it's above Intel.
I probably wouldn't say it is above Facebook, Amazon, Apple, Microsoft, Google in terms
of pure value creation in the world.
I mean, devil's advocate, you could argue that none of the innovative things those companies
are doing now happens without TSMC.
Yeah.
Unless the Foundry model and the Fabulous model was inevitable.
Yeah. Maybe somebody else would have done it. Yeah. Maybe. Yeah, unless the Foundry model and the Fabulous model was inevitable.
Yeah, maybe somebody else would have done it. Yeah, maybe.
But they didn't. They didn't.
They were arrested.
I mean, guys, the thing that's really just beaten me over the head in this episode,
we've probably beaten all of you over the head with, or at least I have,
is, you know, look, there's the geopolitical risk with being in Taiwan.
Other than that, I don't know that there is a stronger moat that any company has in the entire world than TSMC.
Compare it to all the FANG companies and Microsoft.
Those are very, very strong moats.
But we've seen all of those, you know, they've seen their new companies, they've emerged,
they've, you know, Microsoft fell and then now it came back with new strategy and Facebook's not that old and Google's not that old.
TSMC is impenetrable.
Yeah, their business model and the costs required to compete are such that they have.
It's like bulletproof.
It's everything but bulletproof.
Yeah, totally.
Sadly.
Sadly, yeah.
So, I don't know, maybe we're exaggerating because we're so deep in it.
We always go native on these episodes.
Right. The only way it could be more valuable is if the company had an army.
It's like if people talk about the US dollar is backed up by the full
faith of the US government, which implies guns.
Yep.
And so it's only because everybody's currently playing by the rules
that any business gets to stay in business.
And so this one just
happens to be a little bit more at risk than other ones. All right. So I think we can safely say
top 10. I think the question is, is it top five? Well, Defensibles is an interesting question. So
in 30 years, will TSMC be a huge company? Well, they've got this dynamic going right now with
this flywheel where like structurally
nobody can catch them.
Something unforeseen has to change.
But something unforeseen will change because it always changes.
Right, right, right.
Yes, yes, true.
Who's had the most similar dynamic in the past?
Standard oil?
Either been successful or unsuccessful.
Standard oil is a good one.
I mean, that's very different style, but same sort of dynamic with standard oil,
right? Was they crowded out structurally how they were set up.
Nobody else could compete. And the rich kept getting richer.
And they kind of still exist. That's the best.
That is the best part. They kind of still exist. Yeah.
All right. I'm with you. I'll go top 10, but probably not top five.
What I'm wrestling with is how much of it is just marketing.
And I don't mean marketing in a bad way, but intentionally TSMC rides under the radar.
They intentionally have no brand. The brand is the customers.
They want the customers to succeed.
So we don't hear all the time about them like we do the fan companies.
Yeah, we will start to. I think anybody who tunes into this episode probably saw the name of the episode and then thought,
hmm, I should tune into that because I've seen more about this thing recently that I previously didn't know about.
Kind of like we did when we were like, we should do this episode.
It's finally time.
Yeah.
Yeah. All right. Well, that's where I want to leave it.
All right. I'll put a stake in the ground. I'm going to say, I think I'm with you, top 10, not top 5 yet, but maybe we need to revisit
this.
I will definitely say it's the most successful B2B hardware company ever.
And the question is, is it the most successful B2B company ever?
And say it's probably just competing with Microsoft there.
Yeah.
I mean, and again, maybe even like across all industries, right?
Like look at, I mean, shoot, semiconductors run everything.
And they run semiconductors.
Semiconductors are the new oil, David.
Okay, okay, enough, enough, enough.
We gotta bring this one home.
Carbouts?
Carbouts, let's do it.
I've got two.
Jenny and I were just down in Santa Barbara
for a couple of weeks, rented an Airbnb down there.
It was so great, we did that last year.
Hopefully this becomes an annual thing in the summer.
Yeah.
Escape the freezing San Francisco summers.
So while we were down,
we don't watch a lot of TV usually,
but you know, it was like change of scene,
summertime in a new place.
We're like, all right,
we'll watch some TV together at night.
So this is like, for the percentage of you out there
who are living under a rock like me with TV,
we've watched now most of Ted Lasso season one. Cause we heard season two was terrible, but that made me think,
well, it was terrible. It is terrible. But season one's that made me think, oh, if people
are this upset about season two, that means season one was really good. It's so good.
If you haven't watched it, we're on episode eight now. So we're not going to club. So
good. Love it. And then the other TV show we watched, this was Jenny's suggestion, old school throwback, a show called Greek, which aired in the mid 2000s and is about
Greek sorority and fraternity life and a fictional university. And it's just so good. It's like
one of those heartwarming period pieces, but it was right from like when we were in college.
So yeah, it's fun.
Nice. All right. David watching TV, Who knows what could change in the world?
Right.
Maybe TSMC's mode isn't as deep as we thought.
All right.
Well, mine is a book that has been recommended to me
for two or three years now.
And I finally got around to reading and it was awesome.
It's called, Who Is Michael Ovitz?
And if you've read Shoe Dog
and you've read The Ride of the Lifetime
and you've read what's the Ford one've read The Ride of the Lifetime and you've read,
what's the Ford one?
An American icon, these iconoclastic CEO founder business.
Yeah, what's a Sam Walton one?
Built in America, I think?
Yes.
This one needs to be on your list, especially if you've enjoyed any movies or TV shows that
were put together in the last, well, let's be specific.
Or our two-part injuries and horrors series.
Totally.
From like 1975 to 2000, Michael Ovitz put everything together.
And it is this wonderfully written book about an unbelievable business story, the strategy
behind it, the way that with Creative Artists Agency, they just completely upended the entire
industry in Hollywood and did it really without
ever talking to the press and were very tight lipped about it.
For some Hollywood outsider, I found the book really wonderful, really compelling.
I also think I previously had only read The Ride of a Lifetime and watched the Disney
Plus special about sort of the history of Disney and Disneyland.
I had a one-sided view
of Michael based on just his short tenure at Disney. Yeah. I was going to say, yeah, what a
great connection with, you know, acquired and Disney and totally. And what kicked it off was
doing the Andreessen episodes and, you know, hearing about how they based it on CAA. So,
especially if you like those episodes or if you like the Disney episodes or if you're a movie fan or if you like these
Classic CEO business stories who is my globet's was just an awesome read. So cool
Well, I mean like all the media that we grew up on probably even more so because we were kids
But it was the adult movies and the kids movies too
But you know when you're a kid and like the adult movie that you really want to see
Totally too young to see and just all these such classics like goodfellas
Like that was just my previous carve-out or Jurassic Park or just everything that they packaged want to see, but we're too young to see. And just all these such classics like Goodfellas,
like that was just my previous carve out,
or Jurassic Park, or just everything that they packaged.
It's cool to hear how it came to be.
Super cool.
I don't think we told you at the beginning,
but you can join our Slack, acquired.fm slash Slack.
Come hang out with other talented,
smart, good looking people like yourselves.
And with that, listeners,
feel free to share the show with a friend.
Shout it from the social media hilltops.
Yeah.
You always, sometimes you say, but I'll chime in here too.
Like seriously, you know, it's funny,
podcasting is this weird thing, right?
There's no viral loop.
It's not like, you know, you can share,
please share from social media.
We love that.
That's great.
If you love this episode, you think it's interesting.
You think what we do is cool here. But really the way this goes is word of mouth. That is it. You can share, please share from social media. We love that, that's great if you love this episode, you think it's interesting,
you think what we do is cool here.
But really the way this goes is word of mouth.
That is it.
People tell their friends, they listen to this episode,
they thought it was cool.
They think that their friends would really enjoy,
learn from listening to this too, so.
Share a thing you liked,
share a thing you disagree with us on, whatever it is.
If you feel that way, please do that.
If you don't feel that way,
get in touch with us and tell us why. All right, listeners, we will see you next time. We'll see you next time.