Your search keyword '"Li Xiaoling"' showing total 3 results

1. Multi-Treatment Multi-Task Uplift Modeling for Enhancing User Growth

Author

Wei, Yuxiang, Qiu, Zhaoxin, Li, Yingjie, Sun, Yuke, and Li, Xiaoling

Subjects

Computer Science - Machine Learning, Computer Science - Artificial Intelligence, Computer Science - Information Retrieval

Abstract

As a key component in boosting online user growth, uplift modeling aims to measure individual user responses (e.g., whether to play the game) to various treatments, such as gaming bonuses, thereby enhancing business outcomes. However, previous research typically considers a single-task, single-treatment setting, where only one treatment exists and the overall treatment effect is measured by a single type of user response. In this paper, we propose a Multi-Treatment Multi-Task (MTMT) uplift network to estimate treatment effects in a multi-task scenario. We identify the multi-treatment problem as a causal inference problem with a tiered response, comprising a base effect (from offering a treatment) and an incremental effect (from offering a specific type of treatment), where the base effect can be numerically much larger than the incremental effect. Specifically, MTMT separately encodes user features and treatments. The user feature encoder uses a multi-gate mixture of experts (MMOE) network to encode relevant user features, explicitly learning inter-task relations. The resultant embeddings are used to measure natural responses per task. Furthermore, we introduce a treatment-user feature interaction module to model correlations between each treatment and user feature. Consequently, we separately measure the base and incremental treatment effect for each task based on the produced treatment-aware representations. Experimental results based on an offline public dataset and an online proprietary dataset demonstrate the effectiveness of MTMT in single/multi-treatment and single/multi-task settings. Additionally, MTMT has been deployed in our gaming platform to improve user experience.

Published

2024

2. AgentFL: Scaling LLM-based Fault Localization to Project-Level Context

Author

Qin, Yihao, Wang, Shangwen, Lou, Yiling, Dong, Jinhao, Wang, Kaixin, Li, Xiaoling, and Mao, Xiaoguang

Subjects

Computer Science - Software Engineering

Abstract

Fault Localization (FL) is an essential step during the debugging process. With the strong capabilities of code comprehension, the recent Large Language Models (LLMs) have demonstrated promising performance in diagnosing bugs in the code. Nevertheless, due to LLMs' limited performance in handling long contexts, existing LLM-based fault localization remains on localizing bugs within a small code scope (i.e., a method or a class), which struggles to diagnose bugs for a large code scope (i.e., an entire software system). To address the limitation, this paper presents AgentFL, a multi-agent system based on ChatGPT for automated fault localization. By simulating the behavior of a human developer, AgentFL models the FL task as a three-step process, which involves comprehension, navigation, and confirmation. Within each step, AgentFL hires agents with diversified expertise, each of which utilizes different tools to handle specific tasks. Particularly, we adopt a series of auxiliary strategies such as Test Behavior Tracking, Document-Guided Search, and Multi-Round Dialogue to overcome the challenges in each step. The evaluation on the widely used Defects4J-V1.2.0 benchmark shows that AgentFL can localize 157 out of 395 bugs within Top-1, which outperforms the other LLM-based approaches and exhibits complementarity to the state-of-the-art learning-based techniques. Additionally, we confirm the indispensability of the components in AgentFL with the ablation study and demonstrate the usability of AgentFL through a user study. Finally, the cost analysis shows that AgentFL spends an average of only 0.074 dollars and 97 seconds for a single bug.

Published

2024

3. A Data-driven dE/dx Simulation with Normalizing Flow

Author

Fang, Wenxing, Li, Weidong, Ji, Xiaobin, Sun, Shengsen, Chen, Tong, Liu, Fang, Li, Xiaoling, Zhu, Kai, Lin, Tao, and Qiu, Jinfa

Subjects

High Energy Physics - Experiment, Physics - Instrumentation and Detectors

Abstract

In high-energy physics, precise measurements rely on highly reliable detector simulations. Traditionally, these simulations involve incorporating experiment data to model detector responses and fine-tuning them. However, due to the complexity of the experiment data, tuning the simulation can be challenging. One crucial aspect for charged particle identification is the measurement of energy deposition per unit length (referred to as dE/dx). This paper proposes a data-driven dE/dx simulation method using the Normalizing Flow technique, which can learn the dE/dx distribution directly from experiment data. By employing this method, not only can the need for manual tuning of the dE/dx simulation be eliminated, but also high-precision simulation can be achieved.

Published

2024