Using stigmergy as a computational memory in the design of recurrent neural networks
This work addresses the challenge of improving recurrent neural network memory mechanisms for temporal data processing, though it appears incremental as it builds on existing RNN concepts with a new memory type.
The authors tackled the problem of designing recurrent neural networks with a novel computational memory based on stigmergy, resulting in a framework that encodes temporal input for classification tasks, as demonstrated on MNIST variants.
In this paper, a novel architecture of Recurrent Neural Network (RNN) is designed and experimented. The proposed RNN adopts a computational memory based on the concept of stigmergy. The basic principle of a Stigmergic Memory (SM) is that the activity of deposit/removal of a quantity in the SM stimulates the next activities of deposit/removal. Accordingly, subsequent SM activities tend to reinforce/weaken each other, generating a coherent coordination between the SM activities and the input temporal stimulus. We show that, in a problem of supervised classification, the SM encodes the temporal input in an emergent representational model, by coordinating the deposit, removal and classification activities. This study lays down a basic framework for the derivation of a SM-RNN. A formal ontology of SM is discussed, and the SM-RNN architecture is detailed. To appreciate the computational power of an SM-RNN, comparative NNs have been selected and trained to solve the MNIST handwritten digits recognition benchmark in its two variants: spatial (sequences of bitmap rows) and temporal (sequences of pen strokes).