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Exploring Multi-Agent Foundation Models in Zero-Shot Visual Question Answering


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Exploring the zero-shot capabilities of foundation models in Visual Question Answering tasks through an adaptive multi-agent system.
Samenvatting
  • Introduction to Multi-Agent VQA and its significance in zero-shot VQA tasks.
  • Proposal of an adaptive multi-agent system to address limitations in object detection and counting.
  • Description of the pipeline for the Multi-Agent VQA system.
  • Experiments conducted on VQA-v2 and GQA datasets, showcasing results and benchmark comparisons.
  • Ablation study highlighting the impact of different components on performance.
  • Limitations, failure examples, and future work directions discussed.
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Statistieken
Almost all pre-trained large vision-language models require fine-tuning on specified VQA datasets with a limited vocabulary for optimal performance. BEiT3-large-indomain achieves almost zero accuracies on VQA-v2 without fine-tuning on the dataset. Multi-Agent VQA achieved an accuracy of 78.02% on VQA-v2 rest-val dataset.
Citaten
"Almost all pre-trained large vision-language models in the VQA literature require fine-tuning on specified datasets." "Our study focuses on the system’s performance without fine-tuning it on specific VQA datasets." "The generalization ability of foundation models suggests exploring their zero-shot VQA performance."

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by Bowen Jiang,... om arxiv.org 03-25-2024

https://arxiv.org/pdf/2403.14783.pdf
Multi-Agent VQA

Diepere vragen

How can the concept of zero-shot learning be applied beyond Visual Question Answering tasks?

Zero-shot learning, as demonstrated in the context of Visual Question Answering (VQA), can be extended to various other domains and tasks. One prominent application is in natural language processing (NLP), where models can leverage zero-shot capabilities to understand and generate text without specific training on every possible scenario. For instance, in machine translation, a model could potentially translate between languages it has never seen before by understanding underlying linguistic structures. In image recognition, zero-shot learning can enable models to recognize new objects or scenes without explicit training on those classes. This would be particularly useful in scenarios where collecting labeled data for every possible object or situation is impractical or time-consuming. Moreover, zero-shot learning can revolutionize personalized recommendation systems by predicting user preferences for items that were not part of the training dataset. By understanding user behavior and preferences from existing interactions, these systems could recommend novel products or services effectively. Overall, applying zero-shot learning beyond VQA tasks opens up possibilities for more adaptive and versatile AI systems across a wide range of applications.

What are potential drawbacks or criticisms of relying heavily on specialized agents within a multi-agent system?

While utilizing specialized agents within a multi-agent system offers several advantages like enhanced performance and flexibility, there are also potential drawbacks and criticisms associated with this approach: Complexity: Introducing multiple specialized agents increases the complexity of the system architecture. Coordinating communication between different agents may lead to challenges in maintaining consistency and efficiency during inference. Dependency: The reliance on specialized agents means that any failure or suboptimal performance by one agent could impact the overall system's effectiveness. Ensuring robustness across all components becomes crucial but challenging. Scalability: As the number of specialized agents grows, scalability issues may arise concerning computational resources and maintenance costs. Integrating new agents into an existing system might require significant effort due to dependencies among components. Interpretability: Understanding decision-making processes within a multi-agent framework becomes more intricate compared to single-model approaches. Interpreting results generated by different agents collectively might pose challenges for users seeking transparency. Training Data Bias: Each specialized agent operates based on its training data, potentially introducing biases specific to that domain into the overall decision-making process if not carefully managed.

How can prompt engineering and chain-of-thought reasoning enhance the capabilities of foundation models in diverse tasks?

Prompt engineering plays a vital role in guiding foundation models towards desired outputs while ensuring coherent responses across various tasks: 1- Contextual Guidance: Well-crafted prompts provide contextual information essential for foundation models' understanding complex queries accurately. 2-Avoiding Overconfidence: Prompts help prevent overconfident predictions by steering models towards acknowledging uncertainties when necessary. 3-Specialized Instructions: Tailoring prompts according to task requirements enables foundation models to focus on relevant aspects leading to improved performance. Chain-of-thought reasoning enhances model reasoning abilities through sequential steps: 1-Structured Reasoning: Breaking down complex problems into smaller logical steps allows foundation models to tackle them systematically. 2-Incremental Learning: By building upon previous insights at each step, chain-of-thought reasoning facilitates incremental knowledge accumulation leading to more informed decisions. 3-Error Correction: Detecting errors early in reasoning chains helps rectify mistakes before propagating further downstream improving overall accuracy. By combining effective prompt engineering with chain-of-thought reasoning strategies, foundation models exhibit enhanced problem-solving skills adaptable across diverse tasks yielding more reliable outcomes efficiently
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