Vertical Federated Learning (VFL) has gained increasing attention as a novel training paradigm that integrates sample alignment and feature union. However, existing VFL methods face challenges when dealing with heterogeneous local models among participants, which affects optimization convergence and generalization. To address this issue, this paper proposes a novel approach called Vertical Federated learning for training Multi-parties Heterogeneous models (VFedMH). VFedMH focuses on aggregating the embeddings of each participant's knowledge instead of intermediate results during forward propagation. The active party, who possesses labels and features of the sample, in VFedMH securely aggregates local embeddings to obtain global knowledge embeddings, and sends them to passive parties. The passive parties, who own only features of the sample, then utilize the global embeddings to propagate forward on their local heterogeneous networks. However, the passive party does not own the labels, so the local model gradient cannot be calculated locally. To overcome this limitation, the active party assists the passive party in computing its local heterogeneous model gradients. Then, each participant trains their local model using the heterogeneous model gradients. The objective is to minimize the loss value of their respective local heterogeneous models. Additionally, the paper provides a theoretical analysis of VFedMH's convergence performance. Extensive experiments are conducted to demonstrate that VFedMH can simultaneously train multiple heterogeneous models with heterogeneous optimization and outperform some recent methods in model performance.
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