Wednesday, November 03, 2004
The boundaries between animal and machine become more blurred
In his 1999 novel Starfish, science fiction writer Peter Watts wrote about "cultured brains on a slab" - a "smart gel - that could pilot a plane as well as a person. Now, (and I am not making this up) University of Florida biomedical engineer Dr. Thomas DeMarse has created a "brain in a dish" that can interact with a computer flight simulation.
The "brain" is a small puddle of 25,000 living neurons taken from a rat's brain and cultured in a glass dish. "It's essentially a dish with 60 electrodes arranged in a grid at the bottom," DeMarse said. "Over that we put the living cortical neurons from rats, which rapidly begin to reconnect themselves, forming a living neural network – a brain."
The multi-electrode grill is connected to a personal computer running a flight simulation program. The individual neurons are distributed randomly at the beginning of the experiment, and are not connected. The aircraft simulation of an F-22 fighter jet feeds data into the grid about flight conditions; whether the plane is flying straight and level or not. The neurons begin to organize themselves, forming connections to each other. The neurons analyze the data and respond by sending signals to the plane's controls.
At first, the simulated plane drifts randomly. But the neural network slowly learns; currently, the brain can control the pitch and roll of the simulated craft in most weather conditions, including storms and hurricane-force winds.
DeMarse calls his soupy creation — which could one day be used to pilot unmanned aircraft — a “live computation device”.
In his 1999 novel Starfish, science fiction writer Peter Watts wrote about "cultured brains on a slab" - a "smart gel - that could pilot a plane as well as a person. Now, (and I am not making this up) University of Florida biomedical engineer Dr. Thomas DeMarse has created a "brain in a dish" that can interact with a computer flight simulation.
The "brain" is a small puddle of 25,000 living neurons taken from a rat's brain and cultured in a glass dish. "It's essentially a dish with 60 electrodes arranged in a grid at the bottom," DeMarse said. "Over that we put the living cortical neurons from rats, which rapidly begin to reconnect themselves, forming a living neural network – a brain."
The multi-electrode grill is connected to a personal computer running a flight simulation program. The individual neurons are distributed randomly at the beginning of the experiment, and are not connected. The aircraft simulation of an F-22 fighter jet feeds data into the grid about flight conditions; whether the plane is flying straight and level or not. The neurons begin to organize themselves, forming connections to each other. The neurons analyze the data and respond by sending signals to the plane's controls.
At first, the simulated plane drifts randomly. But the neural network slowly learns; currently, the brain can control the pitch and roll of the simulated craft in most weather conditions, including storms and hurricane-force winds.
DeMarse calls his soupy creation — which could one day be used to pilot unmanned aircraft — a “live computation device”.
