The development of a new theory is typically associated with the greats of physics. You might think of Isaac Newton or Albert Einstein, for example. Many Nobel Prizes have already been awarded for new theories. Researchers at Forschungszentrum Jülich have now programmed an artificial intelligence that has also mastered this feat.
Their AI is able to recognize patterns in complex data sets and to formulate them in a physical theory. The development of a new theory is typically associated with the greats of physics. You might think of Isaac Newton or Albert Einstein, for example. Many Nobel Prizes have already been awarded for new theories. Researchers at Forschungszentrum Jülich have now programmed an artificial intelligence that has also mastered this feat. Their AI is able to recognize patterns in complex data sets and to formulate them in a physical theory.
In the following interview, Prof. Moritz Helias from Forschungszentrum Jülich’s Institute for Advanced Simulation (IAS-6) explains what the “Physics of AI” is all about and to what extent it differs from conventional approaches.
How do physicists come up with a new theory?
You usually start with observations of the system before attempting to propose how the different system components interact with each other in order to explain the observed behavior. New predictions are then derived from this and put to the test. A well-known example is Isaac Newton’s law of gravitation. It not only describes the gravitational force on Earth, but it can also be used to predict the movements of planets, moons, and comets – as well as the orbits of modern satellites – fairly accurately.
However, the way in which such hypotheses are reached always differs. You can start with general principles and basic equations of physics and derive the hypothesis from them, or you can choose a phenomenological approach, limiting yourself to describing observations as accurately as possible without explaining their causes. The difficulty lies in selecting a good approach from the numerous approaches possible, adapting it if necessary, and simplifying it.
What approach are you taking with AI?
In general, it involves an approach known as “physics for machine learning”. In our working group, we use methods of physics to analyze and understand the complex function of an AI.
The crucial new idea developed by Claudia Merger from our research group was to first use a neural network that learns to accurately map the observed complex behavior to a simpler system. In other words, the AI aims to simplify all the complex interactions we observe between system components. We then use the simplified system and create an inverse mapping with the trained AI. Returning from the simplified system to the complex one, we then develop the new theory. On the way back, the complex interactions are built up piece by piece from the simplified ones. Ultimately, the approach is therefore not so different from that of a physicist, with the difference being that the way in which the interactions are assembled is now read from the parameters of the AI. This perspective on the world – explaining it from interactions between its various parts that follow certain laws – is the basis of physics, hence the term “physics of AI”.
In which applications was AI used?
We used a data set of black and white images with handwritten numbers, for example, which is often used in research when working with neural networks. As part of her doctoral thesis, Claudia Merger investigated how small substructures in the images, such as the edges of the numbers, are made up of interactions between pixels. Groups of pixels are found that tend to be brighter together and thus contribute to the shape of the edge of the number.
How high is the computational effort?
The use of AI is a trick that makes the calculations possible in the first place. You very quickly reach a very large number of possible interactions. Without using this trick, you could only look at very small systems. Nevertheless, the computational effort involved is still high, which is due to the fact that there are many possible interactions even in systems with many components. However, we can efficiently parameterize these interactions so that we can now view systems with around 1,000 interacting components, i.e. image areas with up to 1,000 pixels. In the future, much larger systems should also be possible through further optimization.
How does this approach differ from other AIs such as ChatGPT?
Many AIs aim to learn a theory of the data used to train the AI. However, the theories that the AIs learn usually cannot be interpreted. Instead, they are implicitly hidden in the parameters of the trained AI. In contrast, our approach extracts the learned theory and formulates it in the language of interactions between system components, which underlies physics. It thus belongs to the field of explainable AI, specifically the “physics of AI”, as we use the language of physics to explain what the AI has learned. We can use the language of interactions to build a bridge between the complex inner workings of AI and theories that humans can understand.
Reference: “Learning Interacting Theories from Data” by Claudia Merger, Alexandre René, Kirsten Fischer, Peter Bouss, Sandra Nestler, David Dahmen, Carsten Honerkamp and Moritz Helias, 20 November 2023, Physical Review X.
DOI: 10.1103/PhysRevX.13.041033
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6 Comments
Millenials c2010: OH ZOWEE! smartphones will replace all desktop computers!
Reality: Good luck on your commercial jet designed on an iPhone.
Millenials c2024: OH ZOWEE! AI is gonna replace physicists and probably humans!
Reality: Re-read what you just said…. slowwwwwly….
Whether it is humans or artificial intelligence, mathematics and mathematical models are the foundation for their understanding and interpretation of nature.
Why are opposed and hated the following statements by some people and so-called academic journals?
The universe does not do algebra, formula or fraction, the universe is geometry.
Today, we have already entered the era of the internet. With the help of artificial intelligence and big data, discussions on scientific knowledge have become open and transparent. However, a group of editors of so-called academic journals (such as Physical Review Letters, Nature, Science, etc.) are self-righteous and mystifying themselves. They only care about their own so-called sufficiently high priority rating, general significance, discipline, novelty, etc., and do not care about what science and pseudoscience are.
Science and pseudoscience are not determined by a publication, an organization or a person, nor by you or me, but by mathematics the final say. Physical models must be based on mathematics or mathematical models in order to be scientific, convincing, and in accordance with natural laws.
The branch of geometry (mathematics) known as topology has become a cornerstone of modern physics. Topological vortex and antivortex are two bidirectional coupled continuous chaotic systems. They exhibit parity conservation, charge conjugation, and time reversal symmetry. The synchronization effect is extremely important in their interactions. The synchronization effect of the superposition, deflection, and twisting of multiple or countless topological vortices will make spacetime motion more complex. To understand this complex world, physics should respect the authenticity of topological vortex in low dimensional spacetime, rather than simply relying on a few formulas, numbers, or imagined particles.
Spin is a natural property of topological vortices. Spin is synchronized with energy, spin is synchronized with gravitation, spin is synchronized with time, spin is synchronized with evolution. The perpetually swirling topological vortices defy traditional physics’ expectations. One physical properties of topological vortices is them to spontaneously begin to change periodically in time, even though the system does not experience corresponding periodic interference. Therefore, in the interaction of topological vortices, time is both absolute and relative,and physics often requires treating space and time at the same level.
Low-dimensional spacetime matter is the foundation of high-dimensional spacetime matter. Low-dimensional spacetime matter (such as topological vortex) can form new material structures and derive more complex physical properties via interactions and self-organization. It is extremely wrong and irresponsible to imagine low dimensional spacetime matter using high-dimensional spacetime matter.
Please answer:
What is the difference between topological vortices and perpetual motion machines?
Science must follow mathematical rules. For example, the Standard Model (SM) is considered to be one of the most significant achievements of physics in the 20th century. However, the magnetic moment of μ particle is larger than expected, revealed by a g-2 experiment at Fermilab, suggests that the established theory (such as SM) of fundamental particles is incomplete. Furthermore, the SM omitting gravitation, it not involved the time problem and when the particle movement starts. Mathematics is the foundation of science. Physics must respect the scientific nature of mathematics and mathematical models. The SM must be based on mathematical models in order to be scientific, convincing, and in line with natural laws.
I hope researchers are not fooled by the pseudoscientific theories of the Physical Review Letters (PRL), and hope more people dare to stand up and fight against rampant pseudoscience.
The so-called academic journals (such as Physical Review Letters, Nature, Science, etc.) firmly believe that two high-dimensional spacetime objects (such as two sets of cobalt-60) rotating in opposite directions can be transformed into two objects that mirror each other, is a typical case of pseudoscience rampant.
If researchers are really interested in Science and Physics, you can browse https://zhuanlan.zhihu.com/p/643404671 and https://zhuanlan.zhihu.com/p/595280873.
Excellent! Get it working on demionsal theory for dimensions greater than 4 and interstellar travel at FTL speeds.
Both examples are of scientists that were frauds, so no doubt but that AI would give more of same.
Sounds like the assembly adaptation of physics, no opinion just fact, calculation,geometry,chemistry ect.
Yes, it can, but will they be any good?