Combine Large Context Window Models and Graph RAG for State-of-the-art AI Integrations

Ali Arsanjani
7 min readSep 28, 2024

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As artificial intelligence evolves, researchers and practitioners face increasingly complex challenges in handling large datasets and interconnected knowledge. In this blog, we explore how to combine large context window models like Gemini 1.5 Pro or Flash with Graph Retrieval-Augmented Generation (RAG) and context caching to produce AI systems that offer a balance between performance, latency, cost, and accuracy.

As AI systems grow in complexity and need to handle increasingly large datasets and interconnected knowledge, models like Gemini 1.5 Pro offer an opportunity to balance performance, latency, cost, and accuracy in novel ways. This article is aimed at applied AI researchers and practitioners, explaining how large context window models, combined with RAG and context caching, can enhance the capabilities of AI systems. It outlines the key patterns, best practices, trade-offs, and real-world applications of this approach.

1. Introduction: The Challenge of Complex AI Systems

Modern AI systems, especially those working in domains requiring deep reasoning, need to retrieve and operate over large volumes of interconnected information. For instance, fields such as legal document analysis, pharmaceutical research, or real-time financial analytics involve multiple relationships between entities, which must be understood in context. Traditionally, knowledge graphs are employed to model these relationships, with retrieval techniques like text embeddings-based RAG or Graph RAG used to query relevant data.

However, both real-time graph construction and static pre-constructed graphs come with limitations, including latency, token costs, and the difficulty of dynamically updating relationships in real time. This article proposes leveraging large context window models like Gemini 1.5 Pro, alongside context caching, to mitigate these limitations and enhance system performance.

2. Large Context Windows: What Are They and Why Are They Important?

Large context window models, such as Gemini 1.5 Pro, offer a solution by holding significantly more information within their context window during inference. This capability addresses the need to store more knowledge, relationships, and query context directly in memory, reducing the need for repeated external calls or graph constructions.

The benefits of large context windows are multifaceted. First, they significantly improve latency by allowing more information to be processed in a single pass. This reduces the need for frequent external queries or real-time graph rebuilding, resulting in faster response times for complex queries. Second, large context windows contribute to reduced token costs. Cache the graph and pass it through the large context window to minimize repeated querying and tokenization costs, leading to more cost-effective operations. Lastly, these models enhance contextual reasoning. Retain relationships and connections between data points to enable more coherent and accurate reasoning in complex domains, improving the overall quality of AI-generated responses and insights.

Gemini 1.5 Pro can hold up to 2M tokens in its context window during inference. This capability addresses the need to store more knowledge, relationships, and query context directly in memory, reducing the need for repeated external calls or graph constructions.

Combine Google Gemini Large Context window with GraphRAG

Key Benefits:

  • Improved Latency: With more information available within a single pass of the model, systems no longer need to frequently query external databases or re-build graphs in real-time, thereby reducing the overall response time.
  • Reduced Token Costs: Token usage can be a significant cost driver when interacting with LLMs. By caching the graph and passing it through the large context window, repeated querying and tokenization costs are avoided.
  • Better Contextual Reasoning: Large context windows enable the model to retain relationships and connections between data points, leading to more coherent and accurate reasoning in complex domains.

3. Combining Graph RAG with Large Context Windows

Graph RAG enhances traditional RAG by using knowledge graphs to represent interconnected relationships between data points. While powerful, Graph RAG typically incurs higher token usage and latency because it consumes more input tokens, particularly in cases involving multi-hop reasoning.

Here, Gemini 1.5 Pro’s large context windows can serve to mitigate these costs by allowing the pre-constructed graph to be cached and passed into the model’s context. This not only reduces the number of external queries but also speeds up the system by holding more of the graph in memory for complex reasoning tasks.

Patterns for Combining Graph RAG and Large Context Windows:

  1. Pre-Construction of Knowledge Graphs

For scenarios where the relationships between entities remain relatively static (e.g., internal knowledge bases, product catalogs), a pre-constructed graph can be built and passed into the context window.

Best Practice: Regularly update the graph at fixed intervals or during off-peak hours to minimize the impact of real-time data changes.

2. Context Caching for Frequently Accessed Data

By caching the graph after its initial query or construction, systems can re-use this cached context across multiple user queries. This is particularly useful for domains like customer support or e-commerce search, where the graph doesn’t change frequently.

Best Practice: Use context caching for static or semi-dynamic data sources to improve query efficiency.

3. Handling Real-Time Data Updates

In domains that require real-time data integration (e.g., financial markets, social media trends), the graph can be dynamically updated in smaller batches, with only the most recent data passed into the context window. This prevents the need to constantly recompute the entire graph.

Best Practice: Use a hybrid approach by pre-constructing the bulk of the graph and updating only relevant sections dynamically in real-time.

4. Trade-offs and Considerations

Performance vs. Cost:

  • Pre-constructed graphs offer lower latency and more predictable costs but can become outdated quickly in fast-evolving domains.
  • Real-time graph construction offers up-to-date insights but incurs higher computational and token costs due to the dynamic nature of query processing.
  • Large context windows can mitigate both issues, but they come with an upfront cost related to the increased memory and model size.

Accuracy vs. Scalability:

  • Large context window models improve accuracy by holding more relevant data in memory, reducing fragmentation and improving multi-hop reasoning.
  • However, scaling these models across many users or applications may be costly due to the high compute requirements.

Latency vs. Flexibility:

  • Context caching improves latency for static or semi-dynamic systems, but systems that require real-time updates may sacrifice some flexibility if the cached graph becomes outdated.
  • Real-time graphs provide flexibility and adaptability but may result in increased latency due to graph re-computation.

5. Best Practices for Implementing Large Context Windows with Graph RAG

1. Optimize for Static vs. Dynamic Data

For static knowledge sources (e.g., documentation, FAQs), use pre-constructed graphs that can be cached and passed into the model’s context. This drastically reduces the cost of handling recurring queries and eliminates latency.

2. Hybrid Graph Construction

In dynamic domains, consider a hybrid approach where a base graph (covering stable knowledge) is pre-constructed and cached, while dynamic updates are applied in real time. Use the large context window to retain both parts of the graph.

3. Leverage Context Caching for Repeated Queries

If your system handles repeated queries over similar datasets (e.g., customer support, document retrieval), implement context caching to store and reuse graph structures, cutting down token and processing costs significantly.

4. Prioritize Multi-Hop Reasoning Scenarios

Use Graph RAG for queries that require multi-hop reasoning — such as in legal research or scientific literature review — where complex relationships between data points are crucial for accuracy. The large context window can store these relationships to maintain coherence across multi-step queries.

6. Real-World Use Cases and Outcomes

Here we will examine some real world use cases.

1. Customer Support Systems

In customer support, a pre-constructed knowledge graph representing the company’s products, policies, and FAQs can be passed through Gemini 1.5 Pro’s context window, reducing the need to query external data repeatedly.

Outcome: Reduced latency, quicker resolutions, and lower token usage as frequently asked questions and responses are cached.

2. E-Commerce Recommendations

E-commerce platforms can leverage a hybrid graph that combines pre-constructed product catalogs with real-time updates based on user behavior (e.g., recent searches or purchases).

Outcome: More personalized recommendations with faster response times, while minimizing the costs associated with dynamic querying.

3. Scientific Research

Researchers analyzing large volumes of interconnected papers and datasets can use Graph RAG with context caching to hold relationships between studies in memory. This allows the model to make connections between related findings without constant re-querying.

Outcome: Faster retrieval of relevant papers, more accurate multi-hop reasoning, and reduced computational costs.

Achieving Better Outcomes with Gemini 1.5 Pro and Graph RAG

By combining large context windows, Graph RAG, and context caching, AI systems can achieve significant improvements in performance, scalability, and cost-efficiency. This approach not only reduces latency and token costs but also enhances the ability of AI systems to reason over complex, interconnected data.

Ultimately, the key to success lies in understanding the trade-offs and fine-tuning the approach to your specific use case. Whether you are building customer support systems, real-time recommendation engines, or scientific research tools, leveraging large context windows and Graph RAG can unlock new levels of performance and insight.

By combining Graph RAG, Text2Emb, and Gemma with large context window models like Gemini 1.5 Pro, AI systems can achieve powerful, dynamic retrieval capabilities while minimizing latency and token costs. This unified approach allows for:

  • Deeper reasoning and multi-hop exploration of knowledge through Graph RAG.
  • Fast, semantic retrieval for simpler queries using Text2Emb.
  • Real-time dynamic retrieval of data through DataGemma, ensuring that the system adapts to evolving data and query contexts.
  • Efficient memory usage and reduced latency through large context windows, with Google Gemini 1.5 Pro, allowing for more data to be processed in a single pass.

Use this to manage trade-offs between cost, complexity, latency, and accuracy, AI researchers and practitioners can build more intelligent and responsive systems, capable of handling both static and dynamic data environments with ease.

This combined approach enables better outcomes in fields like legal research, healthcare, e-commerce, and real-time analytics, ensuring that AI systems can handle the increasing complexity of modern data-driven tasks.

Call for Feedback: If any part of this process seems unclear or could benefit from deeper reflection, I welcome your input to refine and improve this practical guide for applied AI researchers.

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Ali Arsanjani
Ali Arsanjani

Written by Ali Arsanjani

Director Google, AI | EX: WW Tech Leader, Chief Principal AI/ML Solution Architect, AWS | IBM Distinguished Engineer and CTO Analytics & ML

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