active-sensing-subserves-task-control

name: active-sensing-subserves-task-control description: "Proposes that active sensing (energy expenditure for information) is not driven by sensory goals but is necessary for task-level control. Integrates empirical data and control theory to explain explore-exploit mode switching in biological sensorimotor systems. Use when researching active sensing, sensorimotor control, control theory in neuroscience, explore-exploit tradeoffs, or bio-inspired robotics." arxiv_id: "2605.22988" published: "2026-05-21" authors: ["Andrew Lamperski", "Debojyoti Biswas", "Eric S. Fortune", "John Guckenheimer", "Kathleen Hoffman", "Noah J. Cowan"] tags: [active sensing, sensorimotor control, control theory, explore-exploit, bio-inspired robotics, feedback control, adaptive sensors]

Active Sensing Subserves Task-Level Control

arXiv:2605.22988 | Submitted 21 May 2026 | q-bio.NC, cs.LG, cs.RO, eess.SY

Overview

Traditional definitions treat active sensing as energy expenditure for information acquisition. This paper inverts that view: active sensing is not driven by sensory goals but is a necessary consequence of task-level control in systems with adaptive sensors and sensorimotor coupling.

Key Contributions

1. Active sensing as a control necessity

• Reliance on adaptive sensors + linkage between movement and sensing + task-level control → active sensing movements emerge inevitably
• Active sensing is not about minimizing uncertainty — it's required for control

2. Explore-exploit mode switching

• Animals switch between two behavioral modes with distinct control policies:
  • Explore mode: dynamic movements to shape sensory feedback
  • Exploit mode: slower compensatory movements directly related to task goals
• These discrete epochs of active sensing are interspersed with goal-oriented behavior

3. Biological vs. engineered systems

• Engineered systems outperform animals on cost functions (force, precision, speed)
• Yet animals achieve robust, graceful behaviors unmatched by engineering
• Current engineered control systems are insufficient — bio-inspired approach may be critical

Mathematical Formulation

• Control-theoretic framework expressed in terms of observability, controllability
• Adaptive sensor models with state-dependent measurement properties
• Mode-switching control policies (explore/exploit)

Interdisciplinary Relevance

• Neuroscience: explains why active sensing movements occur in biological systems
• Robotics (cs.RO): implications for robotic sensing and control architecture design
• Machine Learning (cs.LG): explore-exploit framework for reinforcement learning
• Control Systems (eess.SY): challenges conventional assumptions about sensor design

Activation

• Keywords: active sensing, sensorimotor control, control theory, explore-exploit, bio-inspired robotics, feedback control, adaptive sensors