Cross-Domain Causal Preference Learning for Out-of-Distribution Recommendation
- URL: http://arxiv.org/abs/2404.14856v1
- Date: Tue, 23 Apr 2024 09:21:15 GMT
- Title: Cross-Domain Causal Preference Learning for Out-of-Distribution Recommendation
- Authors: Zhuhang Li, Ning Yang,
- Abstract summary: Current recommender systems rely on the assumption that the training and testing datasets have identical distributions.
This study proposes a novel model called Cross-Domain Causal Preference Learning for Out-of-Distribution Recommendation (CDCOR)
- Score: 0.8315707564931466
- License:
- Abstract: Recommender systems use users' historical interactions to learn their preferences and deliver personalized recommendations from a vast array of candidate items. Current recommender systems primarily rely on the assumption that the training and testing datasets have identical distributions, which may not hold true in reality. In fact, the distribution shift between training and testing datasets often occurs as a result of the evolution of user attributes, which degrades the performance of the conventional recommender systems because they fail in Out-of-Distribution (OOD) generalization, particularly in situations of data sparsity. This study delves deeply into the challenge of OOD generalization and proposes a novel model called Cross-Domain Causal Preference Learning for Out-of-Distribution Recommendation (CDCOR), which involves employing a domain adversarial network to uncover users' domain-shared preferences and utilizing a causal structure learner to capture causal invariance to deal with the OOD problem. Through extensive experiments on two real-world datasets, we validate the remarkable performance of our model in handling diverse scenarios of data sparsity and out-of-distribution environments. Furthermore, our approach surpasses the benchmark models, showcasing outstanding capabilities in out-of-distribution generalization.
Related papers
- Debiased Recommendation with Noisy Feedback [41.38490962524047]
We study intersectional threats to the unbiased learning of the prediction model from data MNAR and OME in the collected data.
First, we design OME-EIB, OME-IPS, and OME-DR estimators, which largely extend the existing estimators to combat OME in real-world recommendation scenarios.
arXiv Detail & Related papers (2024-06-24T23:42:18Z) - Exploring Popularity Bias in Session-based Recommendation [0.6798775532273751]
We extend the analysis to session-based setup and adapted propensity calculation to the unique characteristics of session-based recommendation tasks.
We study the distributions of propensity and different stratification techniques on different datasets and find that propensity-related traits are actually dataset-specific.
arXiv Detail & Related papers (2023-12-13T02:48:35Z) - Causal Structure Representation Learning of Confounders in Latent Space
for Recommendation [6.839357057621987]
Inferring user preferences from the historical feedback of users is a valuable problem in recommender systems.
We consider the influence of confounders, disentangle them from user preferences in the latent space, and employ causal graphs to model their interdependencies.
arXiv Detail & Related papers (2023-11-02T08:46:07Z) - Pre-trained Recommender Systems: A Causal Debiasing Perspective [19.712997823535066]
We develop a generic recommender that captures universal interaction patterns by training on generic user-item interaction data extracted from different domains.
Our empirical studies show that the proposed model could significantly improve the recommendation performance in zero- and few-shot learning settings.
arXiv Detail & Related papers (2023-10-30T03:37:32Z) - Causality and Independence Enhancement for Biased Node Classification [56.38828085943763]
We propose a novel Causality and Independence Enhancement (CIE) framework, applicable to various graph neural networks (GNNs)
Our approach estimates causal and spurious features at the node representation level and mitigates the influence of spurious correlations.
Our approach CIE not only significantly enhances the performance of GNNs but outperforms state-of-the-art debiased node classification methods.
arXiv Detail & Related papers (2023-10-14T13:56:24Z) - Causal Disentangled Variational Auto-Encoder for Preference
Understanding in Recommendation [50.93536377097659]
This paper introduces the Causal Disentangled Variational Auto-Encoder (CaD-VAE), a novel approach for learning causal disentangled representations from interaction data in recommender systems.
The approach utilizes structural causal models to generate causal representations that describe the causal relationship between latent factors.
arXiv Detail & Related papers (2023-04-17T00:10:56Z) - Domain Adaptation with Adversarial Training on Penultimate Activations [82.9977759320565]
Enhancing model prediction confidence on unlabeled target data is an important objective in Unsupervised Domain Adaptation (UDA)
We show that this strategy is more efficient and better correlated with the objective of boosting prediction confidence than adversarial training on input images or intermediate features.
arXiv Detail & Related papers (2022-08-26T19:50:46Z) - Cross Pairwise Ranking for Unbiased Item Recommendation [57.71258289870123]
We develop a new learning paradigm named Cross Pairwise Ranking (CPR)
CPR achieves unbiased recommendation without knowing the exposure mechanism.
We prove in theory that this way offsets the influence of user/item propensity on the learning.
arXiv Detail & Related papers (2022-04-26T09:20:27Z) - CausPref: Causal Preference Learning for Out-of-Distribution
Recommendation [36.22965012642248]
The current recommender system is still vulnerable to the distribution shift of users and items in realistic scenarios.
We propose to incorporate the recommendation-specific DAG learner into a novel causal preference-based recommendation framework named CausPref.
Our approach surpasses the benchmark models significantly under types of out-of-distribution settings.
arXiv Detail & Related papers (2022-02-08T16:42:03Z) - General Greedy De-bias Learning [163.65789778416172]
We propose a General Greedy De-bias learning framework (GGD), which greedily trains the biased models and the base model like gradient descent in functional space.
GGD can learn a more robust base model under the settings of both task-specific biased models with prior knowledge and self-ensemble biased model without prior knowledge.
arXiv Detail & Related papers (2021-12-20T14:47:32Z) - Learning Bias-Invariant Representation by Cross-Sample Mutual
Information Minimization [77.8735802150511]
We propose a cross-sample adversarial debiasing (CSAD) method to remove the bias information misused by the target task.
The correlation measurement plays a critical role in adversarial debiasing and is conducted by a cross-sample neural mutual information estimator.
We conduct thorough experiments on publicly available datasets to validate the advantages of the proposed method over state-of-the-art approaches.
arXiv Detail & Related papers (2021-08-11T21:17:02Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.