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Bivariate topological complexity: a framework for coordinated motion planning

Jose Manuel Garcia Calcines, Jose Antonio Vilches Alarcon

TL;DR

A structural theory for $\mathrm{TC}(f,g)$ is developed, including symmetry, product inequalities, stability properties, and a collaboration principle showing that, when one of the maps is a fibration, the complexity of synchronization is controlled by the other.

Abstract

We introduce a bivariate version of topological complexity, $\mathrm{TC}(f,g)$, associated with two continuous maps $f\colon X\to Z$ and $g\colon Y\to Z$. This invariant measures the minimal number of continuous motion planning rules required to coordinate trajectories in $X$ and $Y$ through a shared target space $Z$. It recovers Farber's classical topological complexity when $f=g=\mathrm{id}_X$ and Pavešić's map-based invariant when one of the maps is the identity. We develop a structural theory for $\mathrm{TC}(f,g)$, including symmetry, product inequalities, stability properties, and a collaboration principle showing that, when one of the maps is a fibration, the complexity of synchronization is controlled by the other. We also introduce a homotopy-invariant bivariate complexity $\mathrm{TC}_H(f,g)$ of Scott type, defined via homotopic distance, and study its relationship with the strict invariant. Concrete examples reveal rigidity phenomena with no analogue in the classical case, including strict gaps between $\mathrm{TC}(f,g)$ and $\mathrm{TC}_H(f,g)$ and situations where synchronization becomes impossible. Cohomological estimates provide computable obstructions in both the strict and homotopy-invariant settings.

Bivariate topological complexity: a framework for coordinated motion planning

TL;DR

A structural theory for is developed, including symmetry, product inequalities, stability properties, and a collaboration principle showing that, when one of the maps is a fibration, the complexity of synchronization is controlled by the other.

Abstract

We introduce a bivariate version of topological complexity, , associated with two continuous maps and . This invariant measures the minimal number of continuous motion planning rules required to coordinate trajectories in and through a shared target space . It recovers Farber's classical topological complexity when and Pavešić's map-based invariant when one of the maps is the identity. We develop a structural theory for , including symmetry, product inequalities, stability properties, and a collaboration principle showing that, when one of the maps is a fibration, the complexity of synchronization is controlled by the other. We also introduce a homotopy-invariant bivariate complexity of Scott type, defined via homotopic distance, and study its relationship with the strict invariant. Concrete examples reveal rigidity phenomena with no analogue in the classical case, including strict gaps between and and situations where synchronization becomes impossible. Cohomological estimates provide computable obstructions in both the strict and homotopy-invariant settings.
Paper Structure (8 sections, 48 theorems, 105 equations)

This paper contains 8 sections, 48 theorems, 105 equations.

Key Result

Proposition 1.3

Consider the following diagram \xymatrix{ {X'} \ar[rr] \ar[dr]_{f'} & & {X} \ar[dl]^f \\ & Y & }

Theorems & Definitions (110)

  • Remark 1.1
  • Remark 1.2
  • Proposition 1.3
  • Proposition 1.4
  • Proposition 1.5
  • Definition 2.1
  • Proposition 2.2
  • proof
  • Definition 2.3
  • Remark 2.4
  • ...and 100 more