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Abstract
Classical mechanics offers us reliable means to predict various physical quantities, but it is difficult to derive the precise dynamic equations underlying most phenomena and obtain physical quantities in real-world situations. Intuitive physics, the ability to intuitively understand and predict physical phenomena, prevents this complication. However, its applications are confined to the inertial frame of reference. Here, we explored the potentials of neural network-based intuitive physics for solving non-inertial reference frames. We designed three experiments, each of which represents different types of real-world challenges. The task required predicting the speed of an object while the observer accelerates. We demonstrated that multilayer perceptron, invariant methods, and long-term memory networks successfully learn underlying dynamics from observations. This implies that neural network-based intuitive physics provides alternative means to predict various quantities in real-world applications that are unsolvable by classical physics methods.
Highlights
Newton's laws, Hamiltonian, and Lagrangian mechanics are used to explain physical phenomena in classical mechanics [1]
This paper explores the possibility that artificial neural networks can learn intuitive physics in non-inertial systems and solve physical phenomena in cases where it is difficult to apply physics
The third experiment was conducted to find the effect of buildings in non-inertial reference. This is the first study to directly examine the possibility that artificial neural networks can solve the non-inertial reference frames and show performance that is superior to classical physics
Summary
Newton's laws, Hamiltonian, and Lagrangian mechanics are used to explain physical phenomena in classical mechanics [1]. This paper explores the possibility that artificial neural networks can learn intuitive physics in non-inertial systems and solve physical phenomena in cases where it is difficult to apply physics. Note that there is no visual cue to indicate the gravitational effect In both experiments, we successfully demonstrated that neural network-based intuitive physics models revealed a significantly more accurate estimation of actual movements—measured by the mean square error (MSE) value [11]—as compared to the conventional physics approach. The third experiment was conducted to find the effect of buildings in non-inertial reference This is the first study to directly examine the possibility that artificial neural networks can solve the non-inertial reference frames and show performance that is superior to classical physics
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