කෘත්රිම බුද්ධිය
මේ නිව් සයන්ටිස්ට් සඟරාවේ දැනුමේ සීමා පිළිබඳ වූ ලිපි පහෙන් අවසාන ලිපියයි. ඒ කෘත්රිම බුද්ධිය පිළිබඳ ව. කෘත්රිම බුද්ධිය පරිගණක ඇසුරෙන් සිදුවන්නක්. ලංකාවේ නම් කොහොමටත් ඉන්නේ කෘත්රිම බුද්ධිමතුන්. ඒ කොහොම වෙතත් මෙහි කතා කරන්නේ දැනුම අභිසංස්කරණය ගැන නො වෙයි. දැනුමේ සීමා වෙනස් කිරීම ගැන නො වෙයි.
How
AI is shifting the limits of knowledge imposed by complexity
From
weather to the structure of proteins, some things are predictable in theory,
but too complex to figure out in practice. But the rise of artificial
intelligence is changing that fast
PHYSICS 10 January 2023
By Anna Demming
Storms can still surprise forecasters
NASA
Everyone
knows it is impossible to predict the future, but not a lot of people pause to
wonder why. Even putting aside the issue of free choice, it isn’t
straightforward. After all, Isaac Newton’s laws of motion can be used to
calculate what any object will do if we know its starting trajectory and the
forces acting on it. French thinker Pierre-Simon Laplace once imagined a being armed
with these laws and a lot of information, writing that “for such an intellect,
nothing would be uncertain and the future, just like the past, would be present
before its eyes”.
The
reason the world still unfolds in a cascade of the unexpected is that there is
a gulf between what equations can predict in theory and what it is possible to
calculate in practice. The limits of our technology, the speed of our computers
and the incredible complexity of nature all mean that some things are
practically impossible to know.
of
knowledge, in which we explore:
How can we understand quantum
reality if it is impossible to measure?
Why maths, our best tool to
describe the universe, may be fallible
Why some aspects of physical
reality must be experienced to be known
Logic underpins knowledge – but
what if logic itself is flawed?
One
problem is that the things we want to study are sometimes composed of many
objects that mutually affect each other. So while we can predict the path of a
flying football just fine, we can’t do the same with particles because there are usually lots of them
flying around, all exerting forces on each other. It is beyond our current
computing abilities to simulate all those interactions at once – with any more
than about 10 particles, we don’t stand a chance.
Complexity
is a problem in many fields of science, not least medicine. Take proteins, the
long strings of amino acid molecules that fold themselves up into intricate
shapes inside our bodies to do all manner of jobs, from powering our metabolism to fending off bacteria.
We know what forces and considerations dictate the functional, folded shape
each protein will adopt. But there are so many atoms interacting with each
other that we can’t compute this perfectly. This is a frustrating limit to our
knowledge, because knowing the precise structure of a protein can help us
design new drugs.
Chaos
theory
There
is an even more fundamental issue at play. It turns out that the behaviour of
some systems are sensitive to even the tiniest difference in starting
conditions – they are subject to what we call chaos. The weather is a classic
example. Small changes in air temperatures or moisture levels on one day can
result in unpredictable storms the next. Chaos applies to apparently simpler
scenarios too. The roughly 27-day orbit of the moon around our planet varies
erratically by up to 15 hours from month to month due to the constantly
shifting pull the moon feels from Earth and the sun.
Chaos
and complexity certainly put limits on what we can know. But they are more
malleable than the iron-clad boundaries dictated by physical laws themselves
(see “How can we understand quantum reality if it is impossible to
measure?”). For example, by measuring atmospheric conditions in the
present more precisely and using faster computers, we can make better weather
forecasts, up to a point.
While
aspects of the world – from weather to financial markets to the patterns of
disease spread – will always be subject to chaos, there are tricks we can pull
to understand them better. One helpful strategy, says physicist Tim Palmer at the University of Oxford, is to run
a large series of simulations of the system you are studying with tiny
variations in your starting conditions. The sooner the outcomes of the
scenarios begin to diverge, the more unpredictable the system is. These
“ensemble simulations” are now a standard approach. This is why rain forecasts
now often come with a percentage chance attached – helpful for giving us an
appropriate level of confidence in leaving our umbrellas at home. “Enlightened
ignorance is often characterised as knowing what you don’t know,” says
philosopher James Ladyman at the University of Bristol, UK.
Read
more: AlphaFold: Why DeepMind’s protein-folding AI is transformational
But
it doesn’t necessarily have to be this way. A case in point is the way that
artificial intelligence (AI) has revolutionised our ability to calculate the structures that
proteins adopt. Deep-learning AIs don’t attempt to crack this by
modelling the physics. Instead, they are trained on thousands of known protein
structures and use this knowledge to predict new ones. In July 2022, AI firm
DeepMind said that its AlphaFold algorithm had calculated the structures of 200
million proteins, nearly all of those known to science. Sometimes, the limits
of what it is practically possible to fathom can change drastically in a blink.
Will
we ever build a warp drive?
Most
spacecraft use propulsion systems. But there might be another way to zip
around: by warping the space around you. Think of it like swimming
breaststroke, where you scoop up water in front of your body and push it
backwards. Could we ever build an engine that does this in space?
Everything with mass warps space-time to some extent. The appeal of a warp drive is that, in theory, it could effectively move faster than light. To do that, however, it would have to be so massive that it would form a black hole. There is a workaround, proposed by physicist Miguel Alcubierre: use something with negative mass. This would warp space-time without creating a black hole. There are good reasons to think objects with negative mass can’t exist, but the laws of nature don’t rule them out. The upshot is that a useful warp drive will probably – but not definitively – never be possible.
