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Tessellation Localized Transfer learning for nonparametric regression

Hélène Halconruy, Benjamin Bobbia, Paul Lejamtel

Abstract

Transfer learning aims to improve performance on a target task by leveraging information from related source tasks. We propose a nonparametric regression transfer learning framework that explicitly models heterogeneity in the source-target relationship. Our approach relies on a local transfer assumption: the covariate space is partitioned into finitely many cells such that, within each cell, the target regression function can be expressed as a low-complexity transformation of the source regression function. This localized structure enables effective transfer where similarity is present while limiting negative transfer elsewhere. We introduce estimators that jointly learn the local transfer functions and the target regression, together with fully data-driven procedures that adapt to unknown partition structure and transfer strength. We establish sharp minimax rates for target regression estimation, showing that local transfer can mitigate the curse of dimensionality by exploiting reduced functional complexity. Our theoretical guarantees take the form of oracle inequalities that decompose excess risk into estimation and approximation terms, ensuring robustness to model misspecification. Numerical experiments illustrate the benefits of the proposed approach.

Tessellation Localized Transfer learning for nonparametric regression

Abstract

Transfer learning aims to improve performance on a target task by leveraging information from related source tasks. We propose a nonparametric regression transfer learning framework that explicitly models heterogeneity in the source-target relationship. Our approach relies on a local transfer assumption: the covariate space is partitioned into finitely many cells such that, within each cell, the target regression function can be expressed as a low-complexity transformation of the source regression function. This localized structure enables effective transfer where similarity is present while limiting negative transfer elsewhere. We introduce estimators that jointly learn the local transfer functions and the target regression, together with fully data-driven procedures that adapt to unknown partition structure and transfer strength. We establish sharp minimax rates for target regression estimation, showing that local transfer can mitigate the curse of dimensionality by exploiting reduced functional complexity. Our theoretical guarantees take the form of oracle inequalities that decompose excess risk into estimation and approximation terms, ensuring robustness to model misspecification. Numerical experiments illustrate the benefits of the proposed approach.
Paper Structure (37 sections, 27 theorems, 363 equations, 2 figures, 2 tables)

This paper contains 37 sections, 27 theorems, 363 equations, 2 figures, 2 tables.

Key Result

Theorem 1

Assume that Assumption Ass:transfer_function holds on the oracle tessellation $H^\star$, and that Assumptions Ass:design, Ass:regularity_source, Ass:noise, Ass:kernels, Ass:local-design, Ass:quasi_uniform, and Ass:regularity_transfer hold, together with the plug-in condition eq:plug-in_condition. Th

Figures (2)

  • Figure 1: Error reduction \ref{['eq:error_reduction']} for the estimation of $f_1$ and $f_2$ as a function of the regressor dimension $d$.
  • Figure 2: Error reduction for the estimation of female abalone age as a function of the target sample size.

Theorems & Definitions (53)

  • Remark 1: Interpretation and comparison of the transfer assumptions
  • Definition 1: Admissible tessellation class
  • Remark 2: $({\mathrm{T}}{\mathrm{L}})^2$
  • Remark 3: On Assumption \ref{['Ass:star_local-design']}
  • Theorem 1: Oracle rate under a \ref{['subsec:well-specified']}
  • Theorem 2: Fixed tessellation rate in \ref{['subsec:well-specified_local']}
  • Remark 4: Interpretation of the error decomposition
  • Corollary 1: Expectation bound for a fixed tessellation
  • proof
  • Corollary 2: Effective sample size regime
  • ...and 43 more