We live in a silent century. Though no less powerful than their pre-millennial ancestors, our post-millennial innovations are mostly intangible; even when they do occupy physical space, they but wobble neighboring air particles and scarcely make a sound.
Compiling the "Sounds of the 21st Century" is a steep challenge, therefore, but one that legendary beatboxer Beardyman didn't shy from.
"There's an absence of sound rather than a defining sound," he tells Wired.co.uk. Pay attention to the objects around you—the ones that are truly 21st century make next to no noise when we interact with them. The clatter of keyboards? 20th century. The din of car engines? 20th century. The cacophony of the city? Choose whichever century BC you like.
To create a track that begins to "encapsulate the mood of living in the future," as Beardyman puts it, you have to amplify the silent touches we make to interact with modern society. First and foremost, the tapping of fingers on smartphones. "That's all everyone does these days. That's [partly] the point of the video," he says.
In the song, Beardyman meshes beatboxing, phone-tapping, key-bashing, and other sounds in a glitchy track, which will be performed live on September 2 at the O2 Campus Party Europe opening party.
Beardyman presents "the sounds of the 21st century"
- Africa
- Alon Keinan
- Andrew Clark
- Anthropology
- Bangor
- Biology
- Brooklyn
- California
- Cornell University
- David Altshuler
- Deborah A. Nickerson
- Evolution
- Evolutionary biology
- Genetic variation
- Genetics
- Genomics
- Henry Harpending
- Human evolution
- Human genetics
- Human genome
- Human Genome
- Hyun Min Kang
- Jay Shendure
- John Hawks
- John Novembre
- Joshua Akey
- Joshua M. Akey
- Maine
- Mark Shriver
- Matt Nelson
- Michael J. Bamshad
- Natural selection
- New York
- New York
- Penn State University
- Pennsylvania
- Philosophy of biology
- Population genetics
- reproductive technologies
- Robert Moyzis
- Sarah Tishkoff
- Stacey Gabriel
- Suzanne M. Leal
- the University of Pennsylvania
- University of California, Irvine
- University of Utah
- University of Washington
- University of Wisconsin
- Utah
- Wisconsin
How can we begin to understand the way the brain works? The same way we begin to understand a city: by making a map. In this visually stunning talk, Allan Jones shows how his team is mapping which genes are turned on in each tiny region, and how it all connects up.
- Allan Jones
- Allen Institute for Brain Science
- auditory processing
- basic technology
- basic technology
- Brain
- Brazil
- Central nervous system
- Creative Commons
- diffusion tensor imaging
- DNA Chip
- drug discovery
- Flash
- GPS
- Health
- Higher Education
- higher language processing centers
- Human Genome
- JavaScript
- Jill Bolte Taylor
- laser
- Lincoln cent
- Magnetic Resonance Imaging
- magnetic resonance imaging
- mobile device
- MRI
- Neuroanatomy
- Organs
- Peter Jodogne
- Prozac
- Ron Burnett
- satellite view
- Seattle
- Structure
- StumbleUpon
- TED Conferences LLC
- Wellbutrin
In 2005, a team of researchers at the Brain and Mind Institute of the École Polytechnique in Lausanne, Switzerland set out to do some truly wonderful things. Led by neuroscientist Henry Markram, the team, known as the Blue Brain Project, spent two years tearing down rat brains to the molecular level and using what they learned to reverse-engineer a highly detailed, functioning computer model of a rat's cortical column—a basic building block of brain structure.
You know that brains start with neurons, cells that can transmit electrochemical signals. A single neuron is like one person, standing around by themselves and playing an instrument. A cortical column is like an orchestra, with thousands of neurons communicating and working together to accomplish a single task. There are 10,000 neurons in a single rat cortical column. Ten thousand neurons, an amazing amount of complexity—just to do something simple, like twitch a single whisker. To make a whole functional rat brain, you need 100,000 cortical columns. The larger, more complex human brain is even more astounding, with some 100,000 neurons to a single cortical column and perhaps as many as 2 million columns.
Recreating that on a computer requires a frightening amount of processing capability. Each neuron, alone, needs the equivalent of a standard laptop. The computer that the Swiss team used to model a single rat cortical column is a massive beast, one of the fastest supercomputers in the world. But it's still not enough to do what Markram and his team want to accomplish next. Their new goal: Model the form and function of the entire human brain, cortical column-by-cortical column—a task that's likely to take more than a decade.
The Blue Brain Project is currently in the running for a European Commission research grant that would bring in 100 million euros a year for 10 years. The final decision won't happen until next Spring, but if Blue Brain gets the nod, it'll become the Human Brain Project—and could be a major step toward creating a man-built mind. (Or death by Skynet, depending on whether you're a glass-is-half-empty kind of person.)
On May 9, Rueters photographer Denis Bailbouse went inside the Blue Brain Project and took some beautiful photos of the people and computers that could shape the future of the human race. Take a look, be awed. (All image captions written by Reuters, not me.)
Top image: Pipettes are placed near a rat brain sample for an experiment in a lab of the Blue Brain Project at the Brain Mind Institute of the Swiss Federal Institute of Technology (EPFL) in Ecublens, near Lausanne May 9, 2011. If selected from amongst six other candidates by the Future and Emerging Technologies (FET) Flagship Program launched by the European Commission, the Blue Brain Project will upgrade to become the Human Brain Project and will receive funding up to 100 million euros a year for 10 years. The final decision will take place in April 2012. The goal of the Blue Brain Project is to reconstruct the brain piece by piece and build a virtual brain in a supercomputer. (REUTERS/Denis Balibouse)
Cables are pictured on the Internet server at the Swiss Federal Institute of Technology (EPFL) in Ecublens, near Lausanne May 9, 2011. (REUTERS/Denis Balibouse)
Lab assistant prepares pipettes for an experiment in a lab of the Blue Brain Project at the Brain Mind Institute of the EPFL in Ecublens. (REUTERS/Denis Balibouse)
Shi works on the 3D modelling of a neuron in a lab of the Blue Brain Project at the Brain Mind Institute of the EPFL in Ecublens (REUTERS/Denis Balibouse)
Lab assistant Delattre prepares for an experiment in a lab of the Blue Brain Project at the Brain Mind Institute of the EPFL in Ecublens. (REUTERS/Denis Balibouse)
Professor Henry Markram head of the Blue Brain Project poses in a lab of the Brain Mind Institute at the Swiss Federal Institute of Technology (EPFL) in Ecublens (REUTERS/Denis Balibouse)
A rat brain sample is placed into liquid for an experiment in a lab of the Blue Brain Project .
(REUTERS/Denis Balibouse)
A technician poses near a Blue Gene/P deep computer of the Blue Brain Project at the Brain Mind Institute.
(REUTERS/Denis Balibouse)
For more on the Blue Brain Project, check out these stories:
• Henry Markram's detailed and fascinating description of the project, written for Nature Reviews Neuroscience in 2006, before the team had finished modeling the rat cortical column.
• Jonah Lehrer's story for Seed Magazine, written in 2008, that tells the story of the project, and how it met its first modeling goal.
• The well-written Blue Brain Project website itself.
• Henry Markram's 2009 TEDTalk
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