2019
DOI: 10.48550/arxiv.1904.10871
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Prediction bounds for higher order total variation regularized least squares

Abstract: We establish oracle inequalities for the least squares estimator f with penalty on the total variation of f or on its higher order differences. Our main tool is an interpolating vector that leads to upper bounds for the effective sparsity. This allows one to show that the penalty on the k th order differences leads to an estimator f that can adapt to the number of jumps in the (k − 1) th order differences. We present the details for k = 2, 3 and expose a framework for deriving the result for general k ∈ N.

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Cited by 5 publications
(14 citation statements)
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“…We can now use the existing bound given by Theorem 1.1 in Ortelli and van de Geer (2019) to bound SSE( θ (λ * ) , θ * ) for the usual Trend Filtering estimator by generalizing its proof to hold for general subgaussian errors. Therefore, the desired bound for min λ∈Λ SSE( θ (λ) , θ * ) again follows pretty much directly from the existing result Theorem 1.1 in Ortelli and van de Geer (2019).…”
Section: Sketch Of Trend Filtering Proofsmentioning
confidence: 73%
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“…We can now use the existing bound given by Theorem 1.1 in Ortelli and van de Geer (2019) to bound SSE( θ (λ * ) , θ * ) for the usual Trend Filtering estimator by generalizing its proof to hold for general subgaussian errors. Therefore, the desired bound for min λ∈Λ SSE( θ (λ) , θ * ) again follows pretty much directly from the existing result Theorem 1.1 in Ortelli and van de Geer (2019).…”
Section: Sketch Of Trend Filtering Proofsmentioning
confidence: 73%
“…4. We only state Theorem 4.2 for r ∈ {1, 2, 3, 4} and the assumptions on θ * in Theorem 4.2 are identical to the assumptions made in Theorem 1.1 of Ortelli and van de Geer (2019). This is because our proof is based on the proof technique employed by Ortelli and van de Geer ( 2019), as explained in Section 12.1.…”
Section: Main Results For the Cvtf Estimatormentioning
confidence: 99%
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