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06 Aug 16:35

Card Catalogs: “Paper Machines”

by jrochkind

A book I just became aware of that I am very excited about (thanks to Jessamyn West for posting a screenshot of her ‘summer reading’ on facebook, bringing it to my attention!)

Paper Machines: About Cards & Catalogs, 1548-1929
by Krajewski PhD, Markus (Author), Peter Krapp (Translator)

Why the card catalog―a “paper machine” with rearrangeable elements―can be regarded as a precursor of the computer.

Today on almost every desk in every office sits a computer. Eighty years ago, desktops were equipped with a nonelectronic data processing machine: a card file. In Paper Machines, Markus Krajewski traces the evolution of this proto-computer of rearrangeable parts (file cards) that became ubiquitous in offices between the world wars.

The story begins with Konrad Gessner, a sixteenth-century Swiss polymath who described a new method of processing data: to cut up a sheet of handwritten notes into slips of paper, with one fact or topic per slip, and arrange as desired. In the late eighteenth century, the card catalog became the librarian’s answer to the threat of information overload. Then, at the turn of the twentieth century, business adopted the technology of the card catalog as a bookkeeping tool. Krajewski explores this conceptual development and casts the card file as a “universal paper machine” that accomplishes the basic operations of Turing’s universal discrete machine: storing, processing, and transferring data. In telling his story, Krajewski takes the reader on a number of illuminating detours, telling us, for example, that the card catalog and the numbered street address emerged at the same time in the same city (Vienna), and that Harvard University’s home-grown cataloging system grew out of a librarian’s laziness; and that Melvil Dewey (originator of the Dewey Decimal System) helped bring about the technology transfer of card files to business.

I haven’t read it yet myself.

But I’ve thought for a while about how card catalogs were pre-computer information processing systems (with some nostalgia-for-a-time-i-didn’t-experience-myself of when library science was at the forefront of practically-focused information processing system theory and practice).

And I’ve realized for a while that most of our legacy data was designed for these pre-computer information processing systems. And by “legacy” data, I mean the bulk of data we have :) MARC, AACR2, LCSH, even call number systems like DDC or LCC.

If you want to understand this data, you have to understand the systems it was designed for — their affordances and constraints, how they evolved over time — and thinking of them as information processing machines is the best way to understand it, and understand how to make use of it in the present digital environment, or how to change it to get the most benefit from the different constraints and affordances of a computerized environment.

So I can’t quite recommend the book, cause I haven’t read it myself yet — but I recommend it anyway. :)

15 Jul 18:04

An Apple for a Dollar

I'd like 0.4608 apples, please.
18 Jan 15:55

Comic for January 18, 2018

Dilbert readers - Please visit Dilbert.com to read this feature. Due to changes with our feeds, we are now making this RSS feed a link to Dilbert.com.
12 Mar 21:27

Fire From Moonlight

by xkcd

Fire From Moonlight

Can you use a magnifying glass and moonlight to light a fire?

—Rogier Spoor

At first, this sounds like a pretty easy question.

A magnifying glass concentrates light on a small spot. As many mischevious kids can tell you, a magnifying glass as small as a square inch in size can collect enough light to start a fire. A little Googling will tell you that the Sun is 400,000 times brighter than the Moon, so all we need is a 400,000-square-inch magnifying glass. Right?

Wrong. Here's the real answer: You can't start a fire with moonlight[1]Pretty sure this is a Bon Jovi song. no matter how big your magnifying glass is. The reason is kind of subtle. It involves a lot of arguments that sound wrong but aren't, and generally takes you down a rabbit hole of optics.

First, here's a general rule of thumb: You can't use lenses and mirrors to make something hotter than the surface of the light source itself. In other words, you can't use sunlight to make something hotter than the surface of the Sun.

There are lots of ways to show why this is true using optics, but a simpler—if perhaps less satisfying—argument comes from thermodynamics:

Lenses and mirrors work for free; they don't take any energy to operate.[2]And, more specifically, everything they do is fully reversible—which means you can add them in without increasing the entropy of the system. If you could use lenses and mirrors to make heat flow from the Sun to a spot on the ground that's hotter than the Sun, you'd be making heat flow from a colder place to a hotter place without expending energy. The second law of thermodynamics says you can't do that. If you could, you could make a perpetual motion machine.

The Sun is about 5,000°C, so our rule says you can't focus sunlight with lenses and mirrors to get something any hotter than 5,000°C. The Moon's sunlit surface is a little over 100°C, so you can't focus moonlight to make something hotter than about 100°C. That's too cold to set most things on fire.

"But wait," you might say. "The Moon's light isn't like the Sun's! The Sun is a blackbody—its light output is related to its high temperature. The Moon shines with reflected sunlight, which has a "temperature" of thousands of degrees—that argument doesn't work!"

It turns out it does work, for reasons we'll get to later. But first, hang on—is that rule even correct for the Sun? Sure, the thermodynamics argument seems hard to argue with,[3]Because it's correct. but to someone with a physics background who's used to thinking of energy flow, it may seem hard to swallow. Why can't you concentrate lots of sunlight onto a point to make it hot? Lenses can concentrate light down to a tiny point, right? Why can't you just concentrate more and more of the Sun's energy down onto the same point? With over 1026 watts available, you should be able to get a point as hot as you want, right?

Except lenses don't concentrate light down onto a point—not unless the light source is also a point. They concentrate light down onto an area—a tiny image of the Sun.[4]Or a big one! This difference turns out to be important. To see why, let's look at an example:

This lens directs all the light from point A to point C. If the lens were to concentrate light from the Sun down to a point, it would need to direct all the light from point B to point C, too:

But now we have a problem. What happens if light goes back from point C toward the lens? Optical systems are reversible, so the light should be able to go back to where it came from—but how does the lens know whether the light came from B or to A?

In general, there's no way to "overlay" light beams on each other, because the whole system has to be reversible. This keeps you from squeezing more light in from a given direction, which puts a limit on how much light you can direct from a source to a target.

Maybe you can't overlay light rays, but can't you, you know, sort of smoosh them closer together, so you can fit more of them side-by-side? Then you could gather lots of smooshed beams and aim them at a target from slightly different angles.

Nope, you can't do this.[5]We already know this, of course, since earlier we said that it would let you violate the second law of thermodynamics.

It turns out that any optical system follows a law called conservation of étendue. This law says that if you have light coming into a system from a bunch of different angles and over a large "input" area, then the input area times the input angle[6]Note to nitpickers: In 3D systems, this is technically the solid angle, the 2D equivalent of the regular angle, but whatever. equals the output area times the output angle. If your light is concentrated to a smaller output area, then it must be "spread out" over a larger output angle.

In other words, you can't smoosh light beams together without also making them less parallel, which means you can't aim them at a faraway spot.

There's another way to think about this property of lenses: They only make light sources take up more of the sky; they can't make the light from any single spot brighter,[7]A popular demonstration of this: Try holding up a magnifying glass to a wall. The magnifying glass collects light from many parts of the wall and sends them to your eye, but it doesn't make the wall look brighter. because it can be shown[8]This is left as an exercise for the reader. that making the light from a given direction brighter would violate the rules of étendue.[9]My résumé says étendue is my forté. In other words, all a lens system can do is make every line of sight end on the surface of a light source, which is equivalent to making the light source surround the target.

If you're "surrounded" by the Sun's surface material, then you're effectively floating within the Sun, and will quickly reach the temperature of your surroundings.[10](Very hot)

If you're surrounded by the bright surface of the Moon, what temperature will you reach? Well, rocks on the Moon's surface are nearly surrounded by the surface of the Moon, and they reach the temperature of the surface of the Moon (since they are the surface of the Moon.) So a lens system focusing moonlight can't really make something hotter than a well-placed rock sitting on the Moon's surface.

Which gives us one last way to prove that you can't start a fire with moonlight: Buzz Aldrin is still alive.

11 Mar 11:20

New Feature: Include Book Details in Book Display Widgets!

by KJ

We are pleased to have added a new feature to our wildly popular LibraryThing for Libraries product, Book Display Widgets: Book Details. Book Display Widgets let you create virtual book displays to show off collections on your library’s website, Facebook page, LibGuides, and more. Clicking a cover image brings you directly into the catalog to that item’s record.

Our new feature lets you include a bit more information about each title, before the jump into the catalog. In addition to the title and author of an item, you can now choose to include publication date, summaries, and more! The Book Detail box will pop up when a patron clicks on an item in the Book Display Widget, and they can choose to go onto the catalog page from there, or continue browsing in the widget.

bdw summaries screenshot

Check it out: Click on a book cover in our Showcase page to view Book Details. You can see it there in a few different types of displays.

Set it up: If you’re already using Book Display Widgets, you can turn this on easily in the LTFL admin pages. On each of your widgets under “Options,” you can choose to “Show Items Details upon clicking.” Simple toggle to “on” and you should be set!

Learn More: Interested in using Book Display Widgets for your library? Email me (abby@librarything.com) with any questions about this or any of the LibraryThing for Libraries products.