But as common as the MetroCard is to us, and as familiar the anecdotes, few of us have any idea how the thing actually works. Because I didn't know either when a friend asked me a few weeks ago, I began researching it. And because I had so much fun learning about it, I'm going to devote a few blog entries to the workings of the MetroCard, our key to the city...
The technology on the card itself—the magnetic stripe—is actually fairly uncomplicated. Magnetic stripes are made out of thousands of tiny particles of iron oxide, each about 20 millionths of an inch long. Because iron oxide is a magnetic material, all of these little particles are oriented in one of two directions-- you can think of them like arrows pointing north or south. When the card is blank, all of these little magnetic particles are oriented in the same direction, and by switching some of the particles around, the stripe becomes “encoded.” Just like binary code (0’s and 1’s) can be interpreted as characters and words and whole computer applications, the magnetic orientation of these particles can be read as information regarding your card’s serial number, balance, expiration, and so on.
The magnetic stripe on a MetroCard contains information in exactly the same format as virtually all other cards with magnetic stripes. Though you can’t see it, the stripe carries three different “tracks,” each with a different type of data. Track one on a driver’s license holds information about your name and address, along with the location the card was issued. On a MetroCard, tracks one and two hold information about the card type, expiration date, times used and remaining card value, while track three is encoded with a unique serial number. One inch of one of these tracks holds 210 bits of data, which translates to about 70 characters. Each time you swipe, your card is both read and rewritten to reflect your new balance. And how does that work? I'll tell you later this week.
(I created the handy drawing above using Microsoft Paint, an application that I don't believe has been updated with a new version since I was in elementary school. Speaking of simple technology...)
6 comments:
It sounds like most 'plastic' has the same magnetic strip technology. So can you explain why my ATM cards stop swiping properly after a couple of months? I swear that I have to order at least two new cards each year... Is it the number of swipes? The fact that the card is pressed next to a bunch of other magnetic strips in my wallet all day?
The most frequent destruction of magnetic stripe technology occurs by exposure to magnets...even little ones like fridge magnets, security tag de-activators, or magnetic nametags. How much time do you spend around magnets? More importantly, how much time does your debit card spend around magnets?
Another possibility could be your wallet situation. While keeping cards stripe-to-stripe in your wallet is not generally advisable, it's not super likely that your card will become demagnetized that way. If you keep your wallet in your back pocket and sit on it all day, however, you could be destroying your debit card by cracking the lamination on the magnetic stripe.
Is your ATM card the only one in your wallet that consistently gets ruined?
wow. had no idea i was carrying around such a neat little piece of technology in my pocket every day. i'm gonna miss this little yellow card. on to the red white and blue of the cta. i assume it works the same way?
your cta card will work the same way. in fact, the mta and cta use the same company (cubic transportation systems) for most of their technology.
i have a huge place in my heart for chicago, ryan, but the only thing i like about the cta is it's reference on that wilco song off of being there.
I'm currently doing a clas project on the metrocard and I was wondering if you wouldn't mind sharing where you got your information.
Dude I have to say I'm so glad to find your blog, even though I did it by a fluke. The information posted here is interesting and entertaining. In short, a really nice blog.
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