Paper Announcement: Leveraging Multimodal LLMs for Large-Scale Product Retrieval Evaluation

We are excited to share our latest research paper Retrieve, Annotate, Evaluate, Repeat — Leveraging Multimodal LLMs for Large-Scale Product Retrieval Evaluation. We introduce a novel approach to large-scale product retrieval evaluation using Multimodal Large Language Models (MLLMs). Evaluated on 20,000 examples, our method shows how MLLMs can help automate the relevance assessment of retrieved products, achieving levels of accuracy comparable to human annotators and enabling scalable evaluation for high-traffic e-commerce platforms.

In summary, our contributions are as follows:

  • We introduce a multimodal LLM-based evaluation framework for large-scale product retrieval systems. This framework utilizes LLMs (i) to generate context-specific annotation guidelines and (ii) to conduct relevance assessments.
  • We evaluate the performance of our framework against human annotations on real-world production search queries in a multilingual setting and analyse the different types of errors that humans and LLMs tend to make.
  • We demonstrate the cost-effectiveness and efficiency of our approach for conducting large-scale evaluations. We also compare the performance of different types of LLMs for relevance assessment, including GPT-4o, GPT-4 Turbo and GPT-3.5 Turbo.

We assess the performance of different types of LLMs in relevance assessment, including GPT-4o, GPT-4 Turbo and GPT-3.5 Turbo. By leveraging Multimodal LLMs (MLLMs) that analyze both text and images, our framework enables a high level of semantic accuracy in evaluating query-product relevance at scale, minimizing the need for extensive human input. We compare agreements based on (i) matching either A1 or A2 and (ii) inter annotator agreement between human annotators (A1 vs. A2) and between LLMs and the human majority vote. Results are reported separately for English and German. For human annotations, we report the total time and cost.

agreements between LLM and the human annotator groups

Table 1: Agreements between our LLM-based evaluation framework and the human annotator groups (A1 and A2).

Why Evaluate Product Retrieval at Scale?

Search functionality is a fundamental component of e-commerce platforms, with the objective of finding the most relevant products in a dynamic product database. Customers using search often exhibit a higher intent to find specific products, leading to greater engagement and conversion rates. However, they may struggle to articulate their needs in a search query. Even if they do express their intent clearly, information retrieval systems and search engines might fail to interpret it correctly, resulting in irrelevant search results.

Evaluating product retrieval systems on a large scale in a multilingual setting and for a diverse set of customer queries is an intricate but essential task for maintaining a high-quality user experience and driving business success. Traditionally, the quality of these results is measured through human relevance assessments, which require substantial time and resources.

Our paper proposes a scalable solution: a framework that integrates Multimodal LLMs (i) to generate context-specific annotation guidelines and (ii) to conduct relevance assessments. By using MLLMs that analyze both text and images, we enable a high level of semantic accuracy in evaluating query-product relevance without the need for extensive human input.

Retrieve, Annotate, Evaluate, Repeat

Our framework, built for efficiency and scalability, is structured as follows:

  • Query extraction: query-product pairs are extracted from search logs for evaluation.
  • Guideline generation: for each query, an LLM generates custom annotation guidelines, setting detailed criteria for relevance.
  • Multimodal annotation: MLLMs assign relevancy scores to the search results based on both textual and visual descriptions, classifying each result as "highly relevant", "acceptable substitute", or "irrelevant".
  • Evaluation and storage: each labeled pair is stored for continuous retrieval system evaluation and comparison across different configurations.

The framework's modular design allows for caching and parallel processing, enabling evaluations to scale efficiently to support multiple search engines and to accommodate updates to retrieval algorithms.

Our proposed approach works by extracting a query-product pair from our search query-click logs (1). The query (e.g. black sneakers) is then passed on to the "LLM generator" (2). The LLM generator creates specific annotation instructions for the given query. The query-specific annotation guidelines and the query-product pair (e.g. black sneakers and the retrieved product) are provided as input to the "LLM annotator" (3). Lastly, the annotated query-product pair is forwarded to the search engine evaluation module (4).

proposed framework

Fig. 1: Design of the LLM-based annotation framework.

Multimodal LLM-powered relevance assessment: evaluation steps for an example query

Fig. 2 demonstrates the structured process of our evaluation framework with the example query "women's long sleeve t-shirt with green stripes" in panel (a). The LLM identifies and prioritizes four query requirements: "assortment category"; "sleeve length"; "product type" and "pattern", with assigned importance levels, as shown in panel (b). Using this information, query-specific annotation guidelines are generated in panel (c) to provide tailored descriptions for three relevance labels: "irrelevant", "acceptable substitute" and "highly relevant". Panel (d) illustrates an example product and its attributes, with the relevance label "highly relevant" assigned in panel (e) based on LLM-guided reasoning. The entire content displayed in this figure is generated by Multimodal LLMs, except for panel (a), the packshot in panel (d), and the black dashed rectangle also in panel (d). However, within the attributes shown in panel (d), the "visual description of packshot", highlighted by a red rectangle, is generated by a vision model (here: GPT-4o).

Evaluation steps for an example query

Fig. 2: Evaluation steps for the example query "women's long sleeve t-shirt with green stripes".

Key Findings and Benefits

Our method, validated through deployment on Zalando's large e-commerce platform, demonstrates comparable quality to human annotations. This approach offers several advantages:

  • Cost efficiency: MLLM-based assessments are up to 1,000 times cheaper than human labor, resulting in substantial resource savings.
  • Speed: The pipeline can assess 20,000 query-product pairs in around 20 minutes, compared to the weeks needed for human annotators.
  • Multilingual adaptability: The framework supports multiple languages, essential for e-commerce platforms operating in diverse markets.
  • Error analysis: MLLMs demonstrated lower rates of common human errors, such as brand mismatches, which are often caused by annotation fatigue, making MLLMs a reliable solution for repetitive assessment tasks. See the next section "Human vs. LLM Error Analysis" for more details.

Human versus LLM Error Analysis

We compare the LLM-based annotations to human annotations on a dataset collected from live traffic and find that while humans and LLMs approximately make the same amount of errors, the respective error distributions are very different.

For example, the majority of human errors are on (i) brands (e.g. query asks for an Adidas sneaker, retrieved product is from another brand, yet humans would annotate it as relevant), (ii) products and (iii) categories.

On the other hand, LLMs barely made these errors but were often too strict in their judgement (e.g. query asks for black Levi's jeans, retrieved product is a dark grey pair of Levi's jeans, yet the LLM would judge it as irrelevant) or suffer from an "understanding" error (e.g. query asks for the brand "On Vacation", the LLM interprets it in its literal sense, i.e. going on holiday, instead of the brand).

Given these observations we found that LLMs are a very good choice for handling the annotation bulk work for our use-case (most bread-and-butter queries), freeing up human expertise to focus on the tricky cases (e.g. asking for styles and trends)

Fig. 3 shows the distribution of errors between LLMs and humans on hard disagreements (50% were due to human errors, 31% LLM errors and in 19% both made an error). The upper part ("Both errors") focuses on errors that either the LLM or humans could make. It highlights that LLMs and humans make very different types of errors. In addition, the lower part ("LLM errors") shows the distribution of errors that only an LLM would make. Predominantly these are misunderstandings of a part of the search query.

Error analysis, Human vs LLM

Fig. 3: Distribution of errors between LLMs and humans on hard disagreements

Real-World Impact at Zalando

This framework has been deployed in production at Zalando, enabling regular monitoring of high-frequency search queries and identifying low-performing queries for targeted improvements. This continual assessment allows us to quickly pinpoint areas where the retrieval system needs adjustments, helping to ensure a high-quality customer experience.

We note that high relevance is a necessary, but not a sufficient condition, for high customer engagement, as it is also determined by other factors, such as, personal preferences, product availability, and price expectations. In this paper, we focus on semantic relevance, but in production we rank the retrieved documents based on various features to take into account both relevance to the query and customers' personal preferences.

This approach enables us to significantly reduce costs and to enhance customer experience faster by prioritising the queries that need the most attention and optimising our resources accordingly.

Future Directions

While the MLLM-powered framework has shown considerable promise, we are exploring several enhancements to extend its capabilities and broaden its impact:

  • Deeper Human-LLM collaboration: Integrating human expertise for ambiguous or complex cases could optimize relevance assessments, with humans addressing nuanced judgments where domain knowledge is essential.

  • Broadening relevance dimensions: In this paper, we focused on semantic relevance, excluding factors like personal preferences, seasonal trends, or emerging product categories. A future direction could involve adapting the framework to assess multiple relevance dimensions, providing a more holistic view of query relevance in response to shifting customer interests.

  • Adaptability across market segments: To further enhance the robustness of our framework, we aim to test its adaptability across various market segments and product categories, refining its ability to interpret domain-specific language and visual cues that vary between, for example, fashion and beauty products.

  • Automated detection of new trends: By leveraging real-time data and LLMs' growing ability to capture new terminology and styles, we hope to improve the framework's responsiveness to evolving trends, allowing for quick adjustments in annotation criteria to align with emerging patterns.

By advancing these areas, we're setting new standards for automated evaluation in large-scale e-commerce, providing practical solutions for scalable, accurate, and context-aware relevance assessments.

Want to Know More?

For a detailed exploration of our framework, experimental results, and insights on the use of Multimodal LLMs in product retrieval evaluation, refer to our full paper Retrieve, Annotate, Evaluate, Repeat — Leveraging Multimodal LLMs for Large-Scale Product Retrieval Evaluation on arXiv. The paper includes comprehensive discussions on our methodology, error analysis, and a comparison of human and LLM annotations. We invite you to dive into the technical details and explore how this approach is shaping the future of scalable, automated relevance assessment in e-commerce.

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