When Computers Were Human

stern writes "In the not-so-distant past, engineers, scientists and mathematicians routinely consulted tables of numbers for the answers to questions that they could not solve analytically. Sin(.4)? No problem: look it up in the Sine table. These tables were prepared by teams of people called computers (no, really -- that's where the term comes from) who typically had only rudimentary math skills. The computers were overseen by more knowledgeable mathematicians, who designed the algorithms and supervised their work." Read below for Stern's review of David Alan Grier's book When Computers Were Human. When Computers Were Human author David Alan Grier pages 424 (with index and table of names) publisher Princeton University Press rating worth reading reviewer Stern ISBN 0691091579 summary A history of the first "computers", semi-literates who did math by hand

The most important of these teams was the Mathematical Tables Project, organized by the Work Projects Administration in the United States during the Great Depression. WPA rules required the hiring of people with virtually no skills, so much of the definitive work of the Mathematical Tables Project was computed by people who had mastered only addition. They were not authorized to subtract, let alone delve into the mysteries of multiplication or division. The algorithmic steps assigned to them sometimes produced negative numbers, and it goes almost without saying that these computers had no idea what these were or how to handle them. Gertrude Blanch, the mathematician who oversaw their work, had devised a scheme whereby positive numbers would be written in black, negative numbers in red. On the wall in front of her human computers hung a poster that encapsulates much of the era of human computing. It read:

Black plus black is black
Red plus red is red
Black plus red or red plus black, hand the sheets to team 2

Grier has written a history of human computing. It begins in the 1760s and continues through the two hundred years until digital computers ended the industry.

From the start, computers were dedicated to projects in astronomy, cartography, and navigation. Grier describes the nature of these problems and why they required numerical solutions. He touches on the alternating competition and cooperation between teams of computers in different countries, and the different organizational models they employed. Perhaps the most memorable fact from the early years of human computing is that the very first team of French computers, assembled by Gaspard Clair Francois Marie Riche de Prony in the early 1790s, was composed entirely of wig-makers left unemployed by the French Revolution. They created trigonometric tables required by France's experiments with the decimalization of trigonometry (an abandoned effort to do for angle measure what the metric system was doing for the measurement of mass, length, and so forth).

Their work, though of little ultimate relevance to the modern world, illustrates aspects of human computing that would not change. Major computing efforts were always sponsored by governments. A small number of planners oversaw work by people who themselves knew little math. And the bulk of the work was done by people who were marginalized, perhaps otherwise unemployable, and who would do the repetitive calculations. This work conferred no prestige, and many were skeptical even of the conclusions drawn from it. If an equation could not be properly solved, how could one take confidence from any numerical approximation? Even Henry David Thoreau worked a dig at human computers into the manuscript for Walden, dismissing the mathematics that might allow an astronomer "to discover new satellites of Neptune but not detect the motes in his eyes, or to what vagabond he is a satellite himself."

Women emerged as the most important computers. Demand for computing spiked in wartime, when young men were off fighting and therefore unavailable, and the economics of hiring women was compelling even in peacetime. They would work for half of what similarly skilled men would. By World War II, in the United States, computing power was measured not in megahertz or teraflops, but in kilogirls.

By the 20th century, the work of human computers was augmented by mechanical or even electrical calculators that automated certain steps of their work, but these were expensive and prone to breakdown, and did not significantly change the nature of the work.

Grier devotes special attention to the Mathematical Tables Project run by the WPA, later taken over by the National Bureau of Standards, and to the mathematician Gertrude Blanch who ran that team. She is fascinating, a woman who arrived in the United States at the age of 11, who had worked to support her family and not been able to get her Ph.D until she was 39 years old. It was then 1936, the middle of the Great Depression, and the job prospects for female, Jewish mathematicians were bleak. Through luck and hard work she found her way to the Mathematical Tables Project, where she assumed a role that combined mathematician, schoolteacher, and coach. Her fanatical attention to error-checking resulted in tables good enough to win the support of those who were skeptical of work by a government relief organization. She also led by example, and solved certain problems personally when she thought that would be easier than breaking down the algorithms for her computers. Grier says that Blanch in this way personally did work that backed Hans Bethe's Nobel prize-winning model of solar evolution, though it is unclear if Bethe ever knew that the math had been done by one mathematician, rather than her computers. After the war, Blanch was hampered by FBI suspicions that she was secretly a communist. Their evidence for this was nearly nonexistent, and in what must have been a remarkable showdown, this diminutive fifty-year-old mathematician demanded, and won, a hearing to clear her name. She worked productively in numerical mathematics and algorithms for the rest of her life, but remained forever suspicious of digital computers and never adopted them herself.

Grier does excellent research, tracking down surviving computers and sorting through family letters to tell the stories of an entire industry that is being forgotten. He even finds evidence for the working environment for the women computers at Harvard Observatory in the late 1870s in the lyrics to a satire of Gilbert & Sullivan's HMS Pinafore, written by a junior astronomer there at the time.

The book is beautifully printed and has a comprehensive index. Kudos to the Princeton University Press for taking such pride in their work.

When Computers Were Human is weak in several areas. First, Grier glosses over technical aspects of human computing. What were the algorithms that these people used? How was error-checking implemented? He never tells us. Clearly, Grier's goal was to write a work of history, not math, but the people likely to read it are people who care about the math, or about computers, and he omits material that such readers would expect. Second, this is a bureaucratic story. The best human computing was done by large teams sponsored by government in wartime, and the story of these teams revolves around the politicians or bureaucrats who arranged for their funding, and the various acronym-labeled groups that gave them work or provided their employees. At times, it reads as much like a history of agricultural policies as a text about the prehistory of computers.

Grier's story follows his sources: he devotes space to the groups where he has the most material, even if others may have been larger or done more important work. Finally, his discussion of digital computers, where they play a role in the story, is cursory, and may not give credit to those who deserve it.

Is it worth reading? Yes. Consider the reviews of the final tables published by the Bureau of Standards at Amazon.com: In comments as recent as 2004, people who are still using these 50-year-old volumes comment in several languages on which chapters of the books are most useful, where to beware of errors or outdated methods, and on the special emotional role that these volumes play for those who use them, or who needed them in the past. "I probably would never have gotten my Ph.D without this book, and it is a stupendous classic." "Nearly every time you need a mathematical relation or information you will find it on this book." "If you work with mathematical research or numerical computing, you must have this book," and so forth. This praise, and Grier's book, are fine testaments to the world's first computers.

You can purchase When Computers Were Human from bn.com. Slashdot welcomes readers' book reviews -- to see your own review here, read the book review guidelines, then visit the submission page.

Slide rules...

[Fjornir]

You can have my circular slide-rule when you pry it from my cold dead fingers.

Re:Slide rules...

According to my actuarial table, if you are still using a circular slide rule, I may not have have very long to wait.

Re:Slide rules...

[Fjornir]

But you're missing out on the real wins of a slide-rule (especially the circular ones). First: arbitrary precision. Second: better grasp of the relationships between two numbers (consider the difference in feeling between a quarter-twist and four twists)....

Re:Slide rules...

[dasunt]

You can keep your slide rule, and I'll keep my TI. Which can calculate sin,cos,tan as well as e and pi to 10 digits.

Lets let wikipedia rebutt this:

Advantages: A slide rule tends to moderate the fallacy of "false precision" and significance. The typical precision available to a user of a slide rule is about three places of accuracy. This is in good correspondence with most data available for input to engineering formulas (such as the strength of materials, accurate to two or three places of precision, with a great amount--typically 1.5 or greater--of safety factor as an additional multiplier for error, variations in construction skill, and variability of materials). When a modern pocket calculator is used, the precision may be displayed to seven to ten places of accuracy while in reality, the results can never be of greater precision than the input data available."

Re:Slide rules...

[bcrowell]

I use a slide rule rather than a calculator or computer in situations where it's appropriate. I have a cute little one I carry in my pants pocket, comes in very handy. Here is some discussion of the advantages of slide rules. Actually there's quite a big community of people who like slide rules, and nice ones tend to go for quite a bit of money on e-bay. When's the last time you actually needed to calculate something to eight decimal places?

David Alan Grier?

[aftk2]

Did he write this book before or after his seminal work on "In Living Color": When Television Was Funny.

Re:David Alan Grier?

[Qzukk]

One would think that with a naming convention that allows two or more alphabetic names plus a possibility of a trailing number that parents would manage to name the people they create in a non-colliding fashion. Obviously we need to create namespaces to further subdivide the population of names to help disambiguate such conflicts.

I propose that we begin using a word to identify said namespaces. Let's call it a "title". When we then refer to a specific person, we then refer to them by title. For example, and I'm just making this up here, we may want to have several committee meetings before we settle on these namespace titles, we could refer to this person as "Comedian David Alan Grier". This would disambiguate references to that person from another person... lets call him "Professor David Alan Grier".

Of course this is just an idea in formation stages. We'll need to hold off on any action until we have an RFC with approvals from the appropriate naming organizations and an ISO standard to help ensure worldwide compatibility.

Truly amazing...

[Gopal.V]

It is very very humbling to think about all those teams sitting around calculating the sine and log for the damned tables. I hated to even use a slide-rule or the log tables - the only thing I could do in my head was approximate square roots. These are the real pioneers who made most of modern engineering math possible.

The more interesting part is the title rather than the blurb though. It sounded almost like when men were men, women were women and small furry creatures from Alpha Centauri were small furry creatures. Sadly this seems to be a story about the people who bothered the so called computers rather than a story of grit and glory - a story of buearacracy and communist witch hunts ?.

My God!

[ShaniaTwain]

The Sandiego Supercomputer is made of people! You've got to tell them! Sandiego Supercomputer is people!

Re:My God!

[EMH_Mark3]

That would have worked soo much better with 'Soylent Cray'

Dear Old Mum

[Stanistani]

My mother was one of those computers - she worked in England during WWII, using a 'comptometer' and had no idea what she was computing, despite hearing random roaring noises from elsewhere in the facility, until one fine day she was introduced to a Mr. Whittle, who had designed one of the first jet engines for Great Britain.

And You Guys Thought Working The Help Desk Sucked

[DanielMarkham]

This sounds like a demeaning, brutal job. Almost like a factory for addition. Can you imagine what these folks talked about when they went home at night?
"Had a bunch of sevens at the plant today. Thought we never add them all up."
There's a slide-rule connection here. Oddly enough, numbers that couldn't be computed on a slide rule were deemed irrational. For those interested in slide rules, Here's a short history of the slide rule and here's a guy's collection of slide rules

Microsoft Taken To Task On Hiring Practices

progress?

[colmore]

So instead of asking a hunk of plastic and metal for answers to math problems, I would have been asking a room full of educated unmarried women?

This is progress!?!?!

Re:Obligatory Question

[Rosco+P.+Coltrane]

Other important questions:

- what happened to them when they were told to calculate the following problem: "Add one to a positive number and do it again until the result is null, then come tell me the result"

- did you have to put thermal grease under their butt to sit them on a socket-7 chair? and did they need a fan on their forehead?

- if you asked them to divide 20 by 4, would they sometime answer 4.99999999?

- Did they use their fingers to write on a certain sheet (address) and their feet to switch sheets (segments)?

etc...

Parallelism: Feynman's "Los Alamos From Below"

[LouisvilleDebugger]

Feynman is credited with an early application of parallel processing in the way he divided up his "girls" to do the yield calculations for the first atomic bomb, while they were waiting for IBM machines to be set up at Los Alamos during the Manhattan Project. Instead of each girl doing one whole equation herself, he divided the work so that one girl would only do a single kind of operation (such as cube roots.) In his memoir, "Surely You're Joking, Mr. Feynman," he writes that with this scheme he was able to get the predicted speed of the IBM machines out of his human computers. "The difference was that the machine didn't get tired and could work three shifts. But the girls got tired after awhile."

Asimov Short Story

[CrazyWingman]

There is a great short story by Asimov, in which many years in the future, man has forgotten how to do math without an electronic computer. It then happens one day that a young man figures out a process for doing addition and multiplication on paper, and shows off his new methods to a bunch of government big wigs. The military planners are overjoyed, and they begin to redesign their rockets so they can fit a man, who will then be able to calculate his trajectory and pilot the missile to its target by using pencil and paper. This is a huge win for all involved, because humans are much cheaper than computers, of course. :)

Full speed to the past

[Mac+Scientist]

Reminds me of an Asimov story "The Feeling of Power" written by Asimov in 1958. People of the future, who are totally reliant on personal computers, experience the wonder at being able to do arithmetic by hand.

Are we there yet?

Build your own slide rule

[slapout]

If anyone's interested, there are several sites with instructions on creating your own slide rule.

http://www.sphere.bc.ca/test/build.html

http://solar.physics.montana.edu/kankel/math/csr.h tml

etc.

I learned calculation with log tables

[Qbertino]

The last few years of school I went to waldorf school. We actually learned to use log tables (still got my table book here) and calculators were forbidden.
We'd draw roots using them and all.
The reasoning was that anyone can keypunch but understanding what log actually mean is a differn't thing and requires getting your hands dirty. It was at that time when I started programming on my first computer - a PC 1402 Sharp Pocket Computer. Amongst my friends I was the only one that actually understood what these symbols really meant.

I'm gratefull for our teachers taking us that way. I'd actually do the same. Once you've really understood what logs are all about (and when you do your A levels with log tables you have understood what they're about) tackeling larger math problems is a piece of cake.

Take this advice: If you have kids, don't let them near/use an electronic calculator to early. Give them log tables or a slide ruler. It's the best was to learn higher math.

Most important question of them all...

[TiggertheMad]

If you run more electricity through them, do they work faster?