Towards deep learning with segregated dendrites (1610.00161v3)

Abstract: Deep learning has led to significant advances in artificial intelligence, in part, by adopting strategies motivated by neurophysiology. However, it is unclear whether deep learning could occur in the real brain. Here, we show that a deep learning algorithm that utilizes multi-compartment neurons might help us to understand how the brain optimizes cost functions. Like neocortical pyramidal neurons, neurons in our model receive sensory information and higher-order feedback in electrotonically segregated compartments. Thanks to this segregation, the neurons in different layers of the network can coordinate synaptic weight updates. As a result, the network can learn to categorize images better than a single layer network. Furthermore, we show that our algorithm takes advantage of multilayer architectures to identify useful representations---the haLLMark of deep learning. This work demonstrates that deep learning can be achieved using segregated dendritic compartments, which may help to explain the dendritic morphology of neocortical pyramidal neurons.

• The paper proposes a novel model where neurons use segregated dendritic compartments to independently integrate feedforward and feedback signals for effective credit assignment.
• It employs a two-phase learning protocol that computes local error signals via plateau potentials, enhancing hierarchical representations and accuracy.
• Empirical results on MNIST demonstrate that multi-layer architectures with this biologically plausible strategy achieve lower error rates than traditional methods.

Essay: Towards Deep Learning with Segregated Dendrites

Summary

The paper "Towards deep learning with segregated dendrites" introduces a novel approach to deep learning inspired by the architecture and dynamics of biological neural networks, particularly pyramidal neurons in the mammalian neocortex. The authors propose a model where neurons possess electrotonically segregated compartments, allowing them to integrate feedforward and feedback information separately. This architecture offers a biologically plausible framework to solve the credit assignment problem, a long-standing challenge in both neuroscience and AI.

The core idea is to utilize segregated dendritic compartments to implement a deep learning strategy without resorting to biologically unrealistic mechanisms like weight transport used in traditional backpropagation algorithms. The model achieves this by using distinct "basal" and "apical" dendritic compartments in neurons to separate feedforward sensory inputs and feedback signals, respectively. The segregation enables the network to compute local error signals that guide synaptic updates, facilitating coordinated learning across layers.

Model and Methodology

The authors construct a neural network model with multi-compartment neurons, mimicking the morphologies found in biological neurons. They introduce a two-phase learning protocol, the "forward" and "target" phases, during which the network receives sensory input and, subsequently, feedback signals influenced by a teaching signal. The separation of these phases allows for the computation of plateau potentials, which are employed to guide synaptic updates based on the differences between feedforward and feedback-driven activities.

This model is tested on the MNIST dataset, a benchmark for image classification tasks, demonstrating that segregated dendritic compartments can significantly enhance the learning ability of neural networks, compared to traditional single-layer models. The results indicate that the proposed network is capable of effectively categorizing images and developing hierarchical representations—haLLMarks of deep learning.

Results and Implications

The paper presents empirical evidence that the model can indeed leverage the benefits of multi-layer architectures, showcasing improved performance in classification tasks. Notably, the network with two hidden layers achieved a lower error rate on the MNIST dataset than networks with fewer layers, indicating an ability to engage in deep learning.

The results have significant implications for both AI and neuroscience. On a practical level, the model suggests a path towards developing neural networks that utilize biologically plausible learning mechanisms, potentially leading to more robust and generalizable AI systems. Theoretically, it offers insights into how the mammalian brain might solve the credit assignment problem, potentially guiding future research into the neurobiological basis of learning and memory.

Future Directions

The insights gained from this paper open several avenues for future research. The mechanism of using segregated dendrites for credit assignment may inspire more biologically accurate models of neural learning. Future studies might explore the role of neuromodulatory systems in enhancing or inhibiting learning phases, as well as the potential for developing deeper architectures utilizing this framework.

The encouragement of sparse and symmetric feedback weights, as explored in variations of the model, suggests an interesting parallel with biological neural systems, where feedback pathways are inherently sparse. Further exploration into optimizing these conditions could enhance the efficacy and efficiency of learning in artificial systems.

Conclusion

The paper "Towards deep learning with segregated dendrites" contributes a significant step towards understanding and implementing deep learning in a biologically plausible manner. By leveraging the natural architecture of segregated dendritic compartments in neurons, it bridges a critical gap between AI and neuroscience in terms of solving the credit assignment problem. This work provides a foundation for future explorations into more advanced and biologically accurate models of learning, with the potential to influence both technological advancements and our understanding of brain function.