Where in the world?

I'm not sure whether this would be a fun problem or not. I definitely think it falls into the "doing math" category when it comes to that math task categorization taxonomy.

Lots of famous cities have those signs with lots of arrows pointing in different directions with distances to famous cities. My math problem idea: show a picture and ask "Where in the world is this?" I'd want kids to figure out what to do from there, and to use the power of the internet and Google maps to go crazy.

I also found this sign that gives times instead of distances. Definitely an added level of challenge.

To me, this is a problem about loci and intersections of loci, so I can imagine asking a follow up question about how much information from the sign is actually needed to figure out where you are. In theory, this could get pretty interesting because you're working on a sphere instead of a cartesian plane.

Here's why I have questions about this activity:
-How do you find a picture of a sign that's not too easy to google?
-Just by typing in "___ kilometers from Moscow" how quickly will kids find their answer?
-Does a sign with obscure cities (like a road sign on the freeway) make the task more interesting or less interesting? More challenging or less challenging?
-Which is really all to say: how much math is in this task? What math is it?

Also: in searching for a good picture to add to this post, I found a 3D Signpost App. This feels like it has more potential. I especially like this screen:

It feels like there's lots of potential for kids to make their own versions of the screens from this app. And if there's some crossover with a geography or world history class or something, even better. 

Headlines from a Mathematically Illiterate World

http://mathwithbaddrawings.com/2013/12/02/headlines-from-a-mathematically-literate-world/

The longer I teach, the more I think that the math that feels most important for students to take away from my class is about learning to read, interpret, and critically evaluate the logical/illogical statements that float around every day. I do actively enjoy pure math kinds of things, but if it came down to a choice of residue, I'd give up a robust understanding of derivatives for my kids leave being able to read a graph in the newspaper and evaluate the reasonableness of the latest study's claim.

I think it would be really fun for kids to find ridiculous statements in news articles and correct them like this. It would be interesting to develop that critical eye for poorly worded statements, both from a language and a mathematical perspective.

Steep Streets of San Francisco

I kind of wish I taught in San Francisco because I feel like this could somehow turn into a fun field trip:
http://www.7x7.com/arts-culture/real-top-10-list-steepest-streets-san-francisco

Maybe the math problem isn't that interesting, at least not at high school, but talk about a real-life application of slope. I think it's interesting to think about slope as a percentage--you never see a 30% line in math class, but you might see things like 30% grade on street signs. I wonder if kids notice those signs (especially if they don't drive yet and especially if they don't live in a hilly area), and I wonder what they think that grade means. It might be interesting to connect trig to this somehow and think about the angle that the street is tilted at. There always seem to be trig problems about wheelchair ramps--are road grades another piece of this? Is it even interesting?

Sort of related, I have to say I'm always kind of amazing at how steep a road or hill actually feels when I think of the grade mathematically. In my math class mind, a slope of 3/10 is definitely not steep (really, anything below a slope of 1 doesn't seem that steep. I wonder if this is because I often think about slopes in terms of pile patterns, so a slope <1 means that you're not even adding one block per pile...). But driving on a 30% grade is terrifying and just walking up it is painful. Would a kinesthetic experience with slope actually support students' understanding?

Update: 

I finally decided to turn this into a student activity, but the article above doesn't really give enough information to make something interesting. With a little more research into Stephen Van Woorley (the guy who did the calculations the article was based on), I found some much more interesting stuff:

• The story of how he came up with these measurements. I think this will be my basis for the student activity. 
• More steepness calculations, including some good history. An interdisciplinary opportunity??
• A sweet map! I mean, really, who doesn't love a good map-based data visualization?