How the Königsberg bridge problem changed mathematics - Dan Van der Vieren
-
0:09 - 0:14You'd have a hard time finding
Königsberg on any modern maps, -
0:14 - 0:17but one particular quirk in its geography
-
0:17 - 0:22has made it one of the most famous cities
in mathematics. -
0:22 - 0:26The medieval German city lay on both sides
of the Pregel River. -
0:26 - 0:29At the center were two large islands.
-
0:29 - 0:33The two islands were connected
to each other and to the river banks -
0:33 - 0:36by seven bridges.
-
0:36 - 0:41Carl Gottlieb Ehler, a mathematician who
later became the mayor of a nearby town, -
0:41 - 0:44grew obsessed with these islands
and bridges. -
0:44 - 0:47He kept coming back to a single question:
-
0:47 - 0:51Which route would allow someone
to cross all seven bridges -
0:51 - 0:55without crossing any of them
more than once? -
0:55 - 0:57Think about it for a moment.
-
0:57 - 0:587
-
0:58 - 0:596
-
0:59 - 1:005
-
1:00 - 1:014
-
1:01 - 1:023
-
1:02 - 1:032
-
1:03 - 1:041
-
1:04 - 1:05Give up?
-
1:05 - 1:06You should.
-
1:06 - 1:08It's not possible.
-
1:08 - 1:13But attempting to explain why
led famous mathematician Leonhard Euler -
1:13 - 1:16to invent a new field of mathematics.
-
1:16 - 1:19Carl wrote to Euler for help
with the problem. -
1:19 - 1:23Euler first dismissed the question as
having nothing to do with math. -
1:23 - 1:25But the more he wrestled with it,
-
1:25 - 1:29the more it seemed there might
be something there after all. -
1:29 - 1:33The answer he came up with
had to do with a type of geometry -
1:33 - 1:38that did not quite exist yet,
what he called the Geometry of Position, -
1:38 - 1:42now known as Graph Theory.
-
1:42 - 1:43Euler's first insight
-
1:43 - 1:49was that the route taken between entering
an island or a riverbank and leaving it -
1:49 - 1:51didn't actually matter.
-
1:51 - 1:54Thus, the map could be simplified with
each of the four landmasses -
1:54 - 1:57represented as a single point,
-
1:57 - 1:59what we now call a node,
-
1:59 - 2:04with lines, or edges, between them
to represent the bridges. -
2:04 - 2:10And this simplified graph allows us
to easily count the degrees of each node. -
2:10 - 2:13That's the number of bridges
each land mass touches. -
2:13 - 2:15Why do the degrees matter?
-
2:15 - 2:17Well, according to the rules
of the challenge, -
2:17 - 2:21once travelers arrive onto a landmass
by one bridge, -
2:21 - 2:24they would have to leave it
via a different bridge. -
2:24 - 2:28In other words, the bridges leading
to and from each node on any route -
2:28 - 2:31must occur in distinct pairs,
-
2:31 - 2:34meaning that the number of bridges
touching each landmass visited -
2:34 - 2:36must be even.
-
2:36 - 2:40The only possible exceptions would be
the locations of the beginning -
2:40 - 2:42and end of the walk.
-
2:42 - 2:47Looking at the graph, it becomes apparent
that all four nodes have an odd degree. -
2:47 - 2:49So no matter which path is chosen,
-
2:49 - 2:53at some point,
a bridge will have to be crossed twice. -
2:53 - 2:58Euler used this proof to formulate
a general theory -
2:58 - 3:02that applies to all graphs with two
or more nodes. -
3:02 - 3:06A Eulerian path
that visits each edge only once -
3:06 - 3:09is only possible in one of two scenarios.
-
3:09 - 3:14The first is when there are exactly
two nodes of odd degree, -
3:14 - 3:16meaning all the rest are even.
-
3:16 - 3:20There, the starting point is one
of the odd nodes, -
3:20 - 3:22and the end point is the other.
-
3:22 - 3:26The second is when all the nodes
are of even degree. -
3:26 - 3:31Then, the Eulerian path will start
and stop in the same location, -
3:31 - 3:35which also makes it something called
a Eulerian circuit. -
3:35 - 3:38So how might you create a Eulerian path
in Königsberg? -
3:38 - 3:39It's simple.
-
3:39 - 3:41Just remove any one bridge.
-
3:41 - 3:46And it turns out, history created
a Eulerian path of its own. -
3:46 - 3:50During World War II, the Soviet Air Force
destroyed two of the city's bridges, -
3:50 - 3:54making a Eulerian path easily possible.
-
3:54 - 3:57Though, to be fair, that probably
wasn't their intention. -
3:57 - 4:01These bombings pretty much wiped
Königsberg off the map, -
4:01 - 4:05and it was later rebuilt
as the Russian city of Kaliningrad. -
4:05 - 4:09So while Königsberg and her seven bridges
may not be around anymore, -
4:09 - 4:13they will be remembered throughout
history by the seemingly trivial riddle -
4:13 - 4:18which led to the emergence of
a whole new field of mathematics.
- Title:
- How the Königsberg bridge problem changed mathematics - Dan Van der Vieren
- Description:
-
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View full lesson: http://ed.ted.com/lessons/how-the-konigsberg-bridge-problem-changed-mathematics-dan-van-der-vieren
You’d have a hard time finding the medieval city Königsberg on any modern maps, but one particular quirk in its geography has made it one of the most famous cities in mathematics. Dan Van der Vieren explains how grappling with Königsberg’s puzzling seven bridges led famous mathematician Leonhard Euler to invent a new field of mathematics.
Lesson by Dan Van der Vieren, animation by Artrake Studio.
- Video Language:
- English
- Team:
closed TED
- Project:
- TED-Ed
- Duration:
- 04:39
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