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Flexible Machine Learning Models are made possible by Resolving Brain Dynamics

Machine learning methods enable researchers to find statistical patterns in large datasets to solve a wide range of problems, including those in neuroscience. Recent advancements have resulted in an explosion in the scope and complexity of problems to which machine learning can be applied, with accuracy that rivals or exceeds that of humans in some domains.

Last year, MIT researchers announced the development of “liquid” neural networks inspired by the brains of small species: a class of flexible, robust machine learning models that learn on the job and can adapt to changing conditions for real-world safety-critical tasks such as driving and flying. The flexibility of these “liquid” neural nets meant boosting the bloodline to our connected world, resulting in better decision-making for many tasks involving time-series data, such as brain and heart monitoring, weather forecasting, and stock pricing.

But these models become computationally expensive as their number of neurons and synapses increase and require clunky computer programs to solve their underlying, complicated math. And all of this math, similar to many physical phenomena, becomes harder to solve with size, meaning computing lots of small steps to arrive at a solution.

The same group of scientists has now discovered a way to alleviate this bottleneck by solving the differential equation underlying the interaction of two neurons via synapses in order to unlock a new class of fast and efficient artificial intelligence algorithms. These modes share the same properties as liquid neural nets (flexibility, causality, robustness, and explainability), but are orders of magnitude faster and scalable. Because they’re compact and adaptable even after training—unlike many traditional models—this type of neural net could be used for any task that requires gaining insight into data over time.

Neural network systems based on differential equations are tough to solve and scale to, say, millions and billions of parameters. Getting that description of how neurons interact with each other, not just the threshold, but solving the physical dynamics between cells enables us to build up larger-scale neural networks.

Daniela Rus

The models, dubbed a “closed-form continuous-time” (CfC) neural network, outperformed state-of-the-art counterparts on a slew of tasks, with considerably higher speedups and performance in recognizing human activities from motion sensors, modeling physical dynamics of a simulated walker robot, and event-based sequential image processing. On a medical prediction task, for example, the new models were 220 times faster on a sampling of 8,000 patients.

A new paper on the work is published in Nature Machine Intelligence.

“The new machine-learning models we call ‘CfC’s’ replace the differential equation defining the computation of the neuron with a closed form approximation, preserving the beautiful properties of liquid networks without the need for numerical integration,” says MIT Professor Daniela Rus, director of the Computer Science and Artificial Intelligence Laboratory (CSAIL) and senior author on the new paper. “CfC models are causal, compact, explainable, and efficient to train and predict. They open the way to trustworthy machine learning for safety-critical applications.”

Solving brain dynamics gives rise to flexible machine-learning models

Keeping things liquid

Differential equations enable us to compute the state of the world or a phenomenon as it evolves, but not all the way through time—just step-by-step. To model natural phenomena through time and understand previous and future behavior, like human activity recognition or a robot’s path, for example, the team reached into a bag of mathematical tricks to find just the ticket: a “closed form'” solution that models the entire description of a whole system, in a single compute step.

With their models, one can compute this equation at any time in the future, and at any time in the past. Not only that, but the speed of computation is much faster because you don’t need to solve the differential equation step-by-step.

Imagine an end-to-end neural network that receives driving input from a camera mounted on a car. The network is trained to generate outputs, like the car’s steering angle. In 2020, the team solved this by using liquid neural networks with 19 nodes, so 19 neurons plus a small perception module could drive a car. A differential equation describes each node of that system. With the closed-form solution, if you replace it inside this network, it would give you the exact behavior, as it’s a good approximation of the actual dynamics of the system. They can thus solve the problem with an even lower number of neurons, which means it would be faster and less computationally expensive.

These models can receive inputs as time series (events that happened in time), which could be used for classification, controlling a car, moving a humanoid robot, or forecasting financial and medical events. With all of these various modes, it can also increase accuracy, robustness, performance, and, importantly, computation speed—which sometimes comes as a trade-off.

Solving this equation has far-reaching implications for advancing research in both natural and artificial intelligence systems. “When we have a closed-form description of neurons and synapses’ communication, we can build computational models of brains with billions of cells, a capability that is not possible today due to the high computational complexity of neuroscience models. The closed-form equation could facilitate such grand-level simulations and therefore opens new avenues of research for us to understand intelligence,” says MIT CSAIL Research Affiliate Ramin Hasani, first author on the new paper.

Portable learning

Moreover, there is early evidence of Liquid CfC models in learning tasks in one environment from visual inputs, and transferring their learned skills to an entirely new environment without additional training. This is called out-of-distribution generalization, which is one of the most fundamental open challenges of artificial intelligence research.

“Neural network systems based on differential equations are tough to solve and scale to, say, millions and billions of parameters. Getting that description of how neurons interact with each other, not just the threshold, but solving the physical dynamics between cells enables us to build up larger-scale neural networks,” says Hasani. “This framework can help solve more complex machine learning tasks—enabling better representation learning—and should be the basic building blocks of any future embedded intelligence system.”

“Recent neural network architectures, such as neural ODEs and liquid neural networks, have hidden layers composed of specific dynamical systems representing infinite latent states instead of explicit stacks of layers,” says Sildomar Monteiro, AI and Machine Learning Group lead at Aurora Flight Sciences, a Boeing company, who was not involved in this paper.

“These implicitly-defined models have shown state-of-the-art performance while requiring far fewer parameters than conventional architectures. However, their practical adoption has been limited due to the high computational cost required for training and inference.” He adds that this paper “shows a significant improvement in the computation efficiency for this class of neural networks … [and] has the potential to enable a broader range of practical applications relevant to safety-critical commercial and defense systems.”

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