Estimating peer effects in noisy, low-rank networks via network smoothing
TLDR
This paper proposes a network smoothing method to estimate peer effects in noisy, low-rank networks, addressing measurement error.
Key contributions
- Introduces a network smoothing method to estimate peer effects in noisy networks with low-rank expected adjacency matrices.
- Proves that peer effects over true unobserved networks are asymptotically equivalent to those over the expected adjacency matrix.
- Reduces peer effect estimation in noisy networks to low-rank matrix estimation of the expected adjacency matrix.
- Demonstrates broad applicability to egocentric samples, aggregated data, and networks with missing edges.
Why it matters
Accurate peer effect estimation is vital, yet real-world network data is often noisy. This paper offers a robust framework to overcome measurement error by leveraging low-rank network structures. It makes peer effect estimation feasible and consistent even with imperfect data, advancing social science and economic modeling.
Original Abstract
Peer effect estimation requires precise network measurement, yet most empirical networks are noisy, rendering standard estimators inconsistent. To address measurement error in networks, we propose a method to estimate peer effects in networks whose expected adjacency matrix is low-rank. Our key result shows that peer effects over a true unobserved network are asymptotically equivalent to peer effects over the expected adjacency matrix. This result reduces peer effect estimation in noisy networks to low-rank matrix estimation targeting the expected adjacency matrix. We develop our theory for weighted networks observed with additive noise, but simulations suggest approach can be applied more generally when there is a low-rank estimation method suited to a particular noise structure. We demonstrate via simulations that our approach applies to egocentric samples, aggregated relational data, and networks with missing edges, each requiring a different low-rank estimation method.
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