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CHIP WAR: Notes and Things I Learned

Posted by Omer

08 Jul 2023 — No Comments

Posted in Notes

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This February I read CHIP WAR by Chris Miller. The book follows the semiconductor industry form the invention of the transistor, to the trade war between the USA and China. The book is mainly about the economics of electronics manufacturing and geopolitics, but has some technological insight nuggets. I highly recommend it.

Below some notes and things I learned.

There’s also a discussion on Twitter.

The Formula is Abundance

“Cores Lose Price War to New Chip” – Intel 1103 DRAM (1971) Ad showing the main allure of their DRAM chip: It’s cheaper than core memory.

Aggressive price-cutting of ICs was a deliberate Fairchild strategy to bootstrap a consumer market. This was a deliberate choice, and not an obvious one to make, given the abundance of demand in DoD funding. It definitely wasn’t Bill Shockley‘s choice in his own company.

1969 Commemoration brochure showing Fairchild’s Shiprock (in color, no less), NM facility. Courtesy of the Computer History Museum

Although accepting DoD contracts, Fairchild Semiconductor was keeping defense-related development at an arm’s length. Had they leaned into being a military contractor, development would not be incentivized to happen fast or cheap. Instead, they kept looking for consumer applications and opened factories wherever was cheapest. Fairchild opened a plant in Shiprock, NM in 1969 (employing primarily Navajo Women) for DoD business and a plant in Hong Kong for TV & Radio parts.

In both cases, factories brought rural communities into tech work (still low-wage manual labor). Later in Southeast Asia, this formula repeated, as semiconductor factories seeking lower margins increased subsistence farmer intake, and in turn promoting urbanization.

Fairchild Hong Kong Plant. Courtesy of the Computer History Museum

Comparing the US market (in which Fairchild was the only profitable player in the 60s) to other semiconductor efforts, the obvious takeaway is cost-cutting and a large market enabled faster technological growth.

Japan’s Success: The Best Outcome for the US

Screenshot from the Best Ad Ever

Japan becoming a consumer electronics empire was an insanely successful US foreign policy move that survived multiple governments and regime changes; Taiwan’s strategy to fill the same role has been its’ biggest growth engine too.

Corrugated Capacitor Cell, discovered 1982 by Hideo Sumami et al, Courtesy of Semiconductor History of Japan

Side note: with Israel’s current state (gestures vaguely at everything going on in 2023), one might forget that it also tried to have the same geopolitical moat in the early 90s with Tower Semiconductor (ex-National Semi, later Jazz Semi) and later Intel’s fabs. It only worked because of a massive Soviet Jew influx; The only hi-tech manufacturing to exist substantially before that was military – a big change came after the 1987 axing of the Lavi jet fighter, which coincided with the Soviet Jew immigration, and flooded the market with skilled engineers. Although there are fabs in Israel, it currently concentrates foundry-model design centers more than a manufacturing center. There are fabs (3 Intel fabs, currently), but Tower-Jazz (2 fabs in Israel) now makes high-precision CMOS sensors and other high-end products more robust against supply chain disruptions.

Morris Chang‘s prediction that supply chain conditions are unique in the East is still undefeated.

Core Knowledge: Word of Mouth

Photoresist exposure illustration from Introduction to VLSI Systems by Carver Mead and Lynn Conway, 1978

The main driver of US wafer industry was practical experience passed by word of mouth:

  • Know-how was colocated, often undocumented.
  • Majority of know-how was not theory, but engineering: melting temperatures, photoresist exposure times.
  • No noncompetes preventing spread of knowledge.

In the 1980s, this knowledge leaked to Japan quickly (legitimately through academic exchange and some notorious industrial espionage cases). Japan’s strategy wasn’t word of mouth: all semiconductor manufacturers were part of a consortium, working together to deepen Japanese dominance in semiconductor manufacturing.

The Semiconductor Industry, as we know it, is a Supply Chain

Primary production of raw materials by country/region (2019) – from Georgetown’s Center of Security and Emerging Technologies’ report (2021)

A robust supply chain has always been a success enabler – not just today, even when things were smaller: it’s hard to imagine that there was a lot less stuff in the world. The USSR could source machinery and components, but hit a wall as soon as its’ process wasn’t good enough: a single supplier won’t improve their yield or cost without real competition. For comparison, when TI needed purer chemicals or sharper lithography masks than the market had, they made them in-house, as a competitive move. In a planned economy, that was harder to do.

This also emphasizes the lack of “miracle” in the evolution of the semiconductor market: The USSR was “constantly 5 years behind” by artificial efforts to catch up – but it never had a scale market.

Morris Chang in the past warned multiple times that the supply chain Southeast Asia has (due to globalization) is unbeatable. Recently he changed his tune, coincidentally speaking at a fab groundbreaking in Arizona:

“Twenty-seven years have passed and [the semiconductor industry] witnessed a big change in the world, a big geopolitical situation change in the world.
Globalization is almost dead and free trade is almost dead. A lot of people still wish they would come back, but I don’t think they will be back.”

Morris Chang

This is also ruffling feathers in Southeast Asia, where TSMC’s efficient supply chain can’t all move elsewhere, definitely not to Europe and US.

Do We Have to Move to the US?

The US is obsessed with tracking and analyzing the semiconductor supply chain. Detaching countries that the US views as threats from the supply chain is really difficult – but so is keeping tabs on every chemical process at risk due to shortage. The discourse forces players in the market to address this publicly. TSMC releases some press material (for public opinion management? not sure) and does publish some reports on their critical sources (I have less than zero expertise on this, mind you).

Some dude showing off his Eurorack Extreme Ultraviolet Lithography Tool, one of the core technologies ASML leans on, Wikimedia Commons

A Western[-ized] fab ecosystem may happen now that a full-on semiconductor war is on with China. CHIP WAR says ASML’s supply chain is the real cause: it’s got thousands of ad-hoc parts sourced from single suppliers. If ASML machines (hella expensive, require ASML technician onsite) are blocked from entering countries the US views as rivals, those countries won’t have access to Extreme UV Lithography for a while (it took the US around 2 decades and multiple nations from research to production).

On the other hand: in the US, unit economics will be pricier, meaning fab margins may suffer – which can lead to many side effects. As I’m writing this, Apple is reportedly lowering the expected production quota of Vision Pro due to Micro OLED panel yield – a technology that’s so far been a challenge to produce consistently. The US hasn’t shown any manufacturing edge yet (Noah Smith has a nice piece on this), and constraining supply channels may be a short-term challenge.

The CDMA/UMTS/5G lineage is the same story of Western strategic importance that x86 and ARM are. Foreign SIGINT code running inside western infra isn’t the only issue, efforts to harm channel capacity happen on simple crappy wifi routers. RF and network safety is an unfortunate frontier – it’s wholly unsexy, but unlikely to go away from defense requirements.

DEALERS OF LIGHTNING: Notes and Things I Learned

Posted by Omer

02 Jul 2023 — No Comments

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In an attempt to move my writings to a place I can keep them, I’m posting my notes about DEALERS OF LIGHTNING: Xerox Parc and the Dawn of the Computer Age (1999) by Michael Hiltzik here.

There’s also a Twitter discussion. Enjoy it while it lasts* (written July 2 2023).

Alvy Ray Smith and Alan Kay

After running into issues bringing Alvy Ray Smith into PARC to as an “Artist In Residence”, “Temp” or “Contractor” to work on Superpaint, Alan Kay succeeded in bringing him over as “Furniture”.
Alvy Ray Smith was looked down upon by every senior at PARC outside Kay’s group, who didn’t get why color mattered (memory is expensive!). KCET TV featured Superpaint, Xerox heard and wasn’t having it. Smith, who was at PARC as “Furniture”, had his purchase order cancelled.

Side note: here’s an IEEE History of Computing Article about Superpaint.

The Alto

The Alto 1 was a prototype built in a handful of units to experiment. v2 was an experiment in productization: it was built in the SDS plant in LA, focusing on assembly. There was an Alto 3 as well, which was meant for mass production. It failed to clear bureaucracy. Many times.
In both cases, the Alto was better, further reaching, and deliverable faster than anything Xerox had been making anywhere else. Departments scaled quickly with unfitting org structures to deliver mass market products, and they all preferred their own stuff over Alto 3.

(Suffice to say I’ve seen this behavior happen multiple times since)

The first round of Alto 3 was canned for the Xerox 8xx “Word Processor” system, which had a proprietary OS just for word processing. This series later included the Xerox 820, which ran CP/M.

Xerox 850 Catalog Photo, Courtesy of The Computer History Museum

The second round of Alto 3, with a plan to manufacture entirely from commercial components, was canned in favor of the Xerox Star – a scope-crept project which included an OS and hardware, later only the OS with matching hardware.

PARC as the Progenitor of VLSI

Jim Clark learned about VLSI from Lynn Conway who was at PARC at the time, working on VLSI for enabling the Dorado (here’s a fascinating technical report Jim Clark wrote about it). Jim Clark built the “geometry engine” with VLSI principles, as the first vertex processor.

(Jim Clark later founded SGI, which at the time of the book’s writing, was a multibillion dollar company lol)

Figure 1 from the Dorado Technical Report
Figure 3 from the Dorado technical report: How to make a CPU

The first issue of INTRODUCTION TO VLSI SYSTEMS is still up on Conway’s UMich website. It’s an incredible book with fundamentals.

The Notetaker

Alan Kay tried to do the opposite of the Dorado and made a computer called Notetaker – a PC for schoolchildren (ok king). To put ethernet inside it, they studied Bob Metcalfe’s ethernet board and made it software-based, shrinking from 80 to 24 chips.

The Notetaker, courtesy of the Computer History Museum

Alan Kay was so burned out from the project that he said he was “going to LA to take Organ lessons” and never came back. Unrelated: Among Kay’s contributions, he appears to also have invented the soyjak meme:

Alan Kay with a working Alto, Cookie Monster displayed on it. Source unknown 🙁

Apple

The demo Apple saw at PARC was a Xerox corporate decision that made no sense to anybody in the center. They came back 2 days later for more demo (likely at the behest of Jobs), then another time for the confidential stuff. Apple Lisa engineers read every PARC paper beforehand.

Side note: the book epilogue mentions “today [1999] even Apple’s existence is in doubt”. lol

The Xerox Business Model: Clicks

This is something I only vaguely knew but shocks me to my core even now: Xerox didn’t sell copy machines. It leased them and charged for photocopies. The counter clicked with each page, and salespeople would nickname their commission size “clicks”. HP ink biz model.

Doing Backflips to Avoid Selling Computers

The printers initially sold by Xerox were essentially teletype machines with a larger buffer. This is at a time where Xerox PARC had a working bitmap laser printer (more similar to Xerograhic copiers!), but Xerox wouldn’t put it to market due to internal politics.

The perception at the time among corporates was hardware needed to be part of a software product. This is a result of software being unpatentable (USPTO wouldn’t accept an application on software).

But We Totally Want to Sell Ethernet. Cables.

Xerox wanted to control all Ethernet products, a worse ROI than licensing photocopiers. IBM had token ring networks, patented and deployed by IBM. A really obvious thing to do was to give ethernet to the world and not worry about mfg, but “OEM” was a vague concept at the time.

How Research Departments Work Today

All in all: It took Xerox 12 years from buying a computer company (SDS, 1969) to selling a first personal computer (Star, 1981). Along the way, PARC developed almost every component of a minicomputer, without successfully productizing any. Star was a financial failure.

PARC drew prestige at first by having an ARPA association. ARPA drew prestige because of a charismatic leader who understood academics and sought their eccentricities.

At the time of the book’s writing (1999), Microsoft Research was the closest thing to PARC, what with connections to academia, and in spite of a lot of “practical” research, still a publishing cycle. Several companies have the same impetus today (2023), where I work included.

Sometime in Oculus Research’s expansion (now Facebook Reality Labs…Research? or Meta? idk) Michael Abrash told employees that the intention was to become PARC. I wonder which part though.

Notes

Update 06/07/2023: Someone pointed out that Alan Kay gave an AMA on HN in 2016 regarding it.