Loading…
Sunday July 12, 2026 11:10am - 11:30am ADT

Li Ji-An1,2,3Marcus K. Benna*3

Neurosciences Graduate Program, University of California San Diego, La Jolla, CA, USA
Department of Psychology, New York University, New York, NY, USA
Department of Neurobiology, University of California San Diego, La Jolla, CA, USA

*Email: [email protected]

Introduction
Backpropagation has been highly successful for training artificial neural networks. However, whether the biological brain implements any variant of backpropagation remains unknown. A key challenge concerns the capability of a single biological neuron to simultaneously encode and transmit feedforward predictions and feedback errors with minimal interference. Here, we propose a neuronal frequency multiplexing framework to address this challenge.

Methods
Each model neuron has multiple compartments that multiplex signals in the frequency domain. One dendrite acts as a low-pass filter, and extracts feedforward prediction signals from the low-frequency, direct-current components of the inputs. Another dendrite acts as a high-pass filter, and extracts feedback error signals from high-frequency, oscillatory components of the inputs. The soma integrates both signals, transmitting them to other neurons through its firing rate, which consists of a slowly varying prediction component and an oscillatory error component.

Results
We demonstrate that this frequency multiplexing algorithm using a simple, local learning rule closely approximates backpropagation in fully connected networks trained on the MNIST dataset and in convolutional networks trained on the CIFAR-10 dataset, achieving comparable performance and similar learning speed as a function of the number of training epochs.

Discussion
Our framework implements backpropagation-like training of functionally feedforward neural networks using continuously running, recurrently connected neuronal populations that simultaneously encode and propagate both prediction and error signals with minimal interference. This represents a new solution to the long-standing problem of biologically plausible credit assignment, suggesting a potential computational role for oscillatory signals in coordinating synaptic plasticity.

Speakers
MK

Marcus K Benna

UC San Diego
Sunday July 12, 2026 11:10am - 11:30am ADT
Ballroom B1

Sign up or log in to save this to your schedule, view media, leave feedback and see who's attending!

Share Modal

Share this link via

Or copy link