New theory of how the brain transforms sensations into mental objects

Numenta publishes a new theory of how the brain transforms sensations into mental objects
Credit: Numenta

Inputs to the brain from the eyes, ears, and skin are continually changing as we move. Yet our brain perceives objects in the world as stable. How the brain learns the structure of the world from rapidly changing inputs is a mystery.

In a new paper titled "A Theory of How Columns in the Neocortex Enable Learning the Structure of the World," published in the journal Frontiers in Neural Circuits, researchers at Numenta propose a new theory for how the learns models of objects through movement. "The basic idea is simple," says Numenta Co-Founder Jeff Hawkins. "Existing ideas about how sensory input is processed in the brain are still valid. We are proposing that an important ingredient was missed, and with this missing ingredient, a large number of mysteries about the brain can be resolved." The paper proposes that to the brain is paired with a signal. The location is relative to the being sensed. For example, an edge becomes an edge at a particular location on a cup. As we move our eyes and move our fingers, the brain learns the structure of objects as a set of features at locations on the object.

"Scientists have suspected something like this had to be happening in the brain somewhere," explained VP of Research Subutai Ahmad. "We deduced it is happening throughout the neocortex, in each cortical column. The theory predicts that even the very first levels of processing in the brain are learning and recognizing complete objects. This is surprising; no one imagined it. But once you know what to look for, there is evidence supporting this prediction."

Another surprising outcome of the theory is the brain doesn't learn just one model of an object, but many parallel models, as each column in the cortex learns complete models. The theory shows that movement of the eyes and skin are necessary for learning, but after learning, objects can be recognized with one glance or one grasp of the hands. Although each column can only sense one part of an object, together they can reach a consensus.

The paper includes detailed simulations, anatomical and physiological evidence related to the theory, and testable predictions.

Among key findings presented in the paper:

  • The brain calculates an 'allocentric' location for features of any given object. It is allocentric because the locations are relative to the object as opposed to relative to you.
  • Specific layers in every cortical region receive sensory features and allocentric locations as input, and compute feature-location pairs. Those pairs are fed up to an output layer, which forms stable representations of objects.
  • Lateral connections between cortical columns allow them to share partial information to recognize objects more rapidly.

Although the theory was deduced by studying touch, the neural structures that determine the location signal exist in every part of the neocortex, even in cortical regions that process language and high-level thoughts. This provocatively suggests that all ideas are associated with locations, even if those locations do not correspond to physical locations in the world. It suggests that our brains manipulate abstract concepts using the same mechanisms we use to manipulate physical objects.

"The theory introduced in this paper is refreshing and will influence how neuroscientists think about the neocortex. The study offers an elegant approach for integrating the motor and sensory modalities, and opens new possibilities," said Prof. Dr. Mehmet Fatih Yanik, ETH Zurich Chair of Neurotechnology Laboratories.

The new theory is an important piece of Numenta's overall goal to reverse-engineer the neocortex. Previous papers from Numenta have proposed how neurons make predictions and detect anomalies, how layers of neurons learn sequences of patterns, and why activity in the brain is sparse. Part of Numenta's mission is to bridge the worlds of neuroscience and AI. Hawkins noted, "We believe the principles used by the brain, including the sensorimotor in the new , will be essential to create general artificial intelligence and sophisticated robotics."

More information: Jeff Hawkins et al, A Theory of How Columns in the Neocortex Enable Learning the Structure of the World, Frontiers in Neural Circuits (2017). DOI: 10.3389/FNCIR.2017.00081

To allow other researchers to reproduce these results, Numenta has created a repository with the source code, data, and scripts used in the paper. Numenta researchers hope this information will encourage more scientists to experiment with Numenta's theories and to provide feedback.

Journal information: Frontiers in Neural Circuits
Provided by Numenta
Citation: New theory of how the brain transforms sensations into mental objects (2017, November 15) retrieved 29 March 2024 from https://medicalxpress.com/news/2017-11-theory-brain-sensations-mental.html
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