Towards neoRL networks; the emergence of purposive graphs
This work addresses the challenge of creating more autonomous and goal-directed AI systems, though it appears incremental by building on existing neoRL frameworks.
The paper tackles the problem of enabling AI agents to exhibit purposive behavior by introducing neoRL networks, which use autonomous desire and cognitive maps to guide learning, resulting in real-time navigation in Euclidean spaces.
The neoRL framework for purposive AI implements latent learning by emulated cognitive maps, with general value functions (GVF) expressing operant desires toward separate states. The agent's expectancy of reward, expressed as learned projections in the considered space, allows the neoRL agent to extract purposive behavior from the learned map according to the reward hypothesis. We explore this allegory further, considering neoRL modules as nodes in a network with desire as input and state-action Q-value as output; we see that action sets with Euclidean significance imply an interpretation of state-action vectors as Euclidean projections of desire. Autonomous desire from neoRL nodes within the agent allows for deeper neoRL behavioral graphs. Experiments confirm the effect of neoRL networks governed by autonomous desire, verifying the four principles for purposive networks. A neoRL agent governed by purposive networks can navigate Euclidean spaces in real-time while learning, exemplifying how modern AI still can profit from inspiration from early psychology.