The field of modeling brain circuits as intelligent systems has garnered significant attention in recent years, driven by the need to understand the brain's complex dynamics and learning capabilities. Despite notable advancements, there remain substantial gaps in our comprehension of how brain circuits function as intelligent systems. Pioneering work by researchers such as Karl Lashley, Walter Freeman, and Karl Pribram has laid the groundwork, yet the integration of these principles into a cohesive framework remains incomplete. Recent studies have made strides in Cognitive Optimization and Prediction (COPN), as highlighted in the NSF solicitation on Emerging Frontiers Research Initiation of 2007. However, the field still requires a more unified mathematical framework to bridge biological data with machine learning and collective intelligence. Addressing these gaps is crucial for advancing our understanding of cognition and its applications in various domains.
This Research Topic aims to explore and highlight how brain circuits can be modeled as intelligent systems, building on the fundamental principles and methodologies outlined by notable proponents. We seek to foster cross-disciplinary dialogue and extend our understanding of cognition beyond the mere biological interpretation of data to a more integrated perspective. Our primary focus is to encourage empirical and theoretical submissions that contribute to a better understanding of the brain's complex dynamics and its broad learning capabilities. We particularly welcome contributions presenting novel mathematical models and algorithmic tools that can link biological data with machine learning and other intelligence-boosting strategies.
To gather further insights into the modeling of brain circuits as intelligent systems, we welcome articles addressing, but not limited to, the following themes:
- Novel mathematical models for brain circuit dynamics
- Algorithmic tools linking biological data with machine learning
- Empirical studies on brain's reinforcement maximization
- Theoretical perspectives on cognitive optimization and prediction
- Reviews of advancements in collective intelligence
- Interdisciplinary approaches to understanding brain function
- Applications of brain circuit models in machine learning and AI
- Investigations into the brain's interaction with varied environments
Keywords: Brain Circuits, brain dynamics, Collective Intelligence, machine learning, systems neuroscience
Important note: All contributions to this Research Topic must be within the scope of the section and journal to which they are submitted, as defined in their mission statements. Frontiers reserves the right to guide an out-of-scope manuscript to a more suitable section or journal at any stage of peer review.
