R

rag-architect

by @jeffallanv
4.4(22)

Specializes in designing and implementing production-grade Retrieval-Augmented Generation (RAG) systems, improving AI model accuracy and relevance through efficient data chunking and retrieval.

rag-(retrieval-augmented-generation)llm-architecturevector-databasesinformation-retrievalai-engineeringGitHub
Installation
npx skills add https://github.com/jeffallan/claude-skills --skill rag-architect
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Before / After Comparison

1
Before

Traditional AI Q&A systems lack external knowledge, often leading to hallucinations or inaccurate answers. This limits AI's application in specialized fields, making it difficult for users to obtain reliable information.

After

Design and implement a production-grade RAG system through document chunking and vectorization. Significantly improve the accuracy and reliability of AI Q&A, providing users with high-quality, well-substantiated answers.

SKILL.md

RAG Architect

Core Workflow

  1. Requirements Analysis — Identify retrieval needs, latency constraints, accuracy requirements, and scale
  2. Vector Store Design — Select database, schema design, indexing strategy, sharding approach
  3. Chunking Strategy — Document splitting, overlap, semantic boundaries, metadata enrichment
  4. Retrieval Pipeline — Embedding selection, query transformation, hybrid search, reranking
  5. Evaluation & Iteration — Metrics tracking, retrieval debugging, continuous optimization

For each step, validate before moving on (see checkpoints below).

Reference Guide

Load detailed guidance based on context:

TopicReferenceLoad When
Vector Databasesreferences/vector-databases.mdComparing Pinecone, Weaviate, Chroma, pgvector, Qdrant
Embedding Modelsreferences/embedding-models.mdSelecting embeddings, fine-tuning, dimension trade-offs
Chunking Strategiesreferences/chunking-strategies.mdDocument splitting, overlap, semantic chunking
Retrieval Optimizationreferences/retrieval-optimization.mdHybrid search, reranking, query expansion, filtering
RAG Evaluationreferences/rag-evaluation.mdMetrics, evaluation frameworks, debugging retrieval

Implementation Examples

1. Chunking Documents

from langchain.text_splitter import RecursiveCharacterTextSplitter

# Evaluate chunk_size on your domain data — never use 512 blindly
splitter = RecursiveCharacterTextSplitter(
    chunk_size=800,
    chunk_overlap=100,
    separators=["\n\n", "\n", ". ", " "],
)

chunks = splitter.create_documents(
    texts=[doc.page_content for doc in raw_docs],
    metadatas=[{"source": doc.metadata["source"], "timestamp": doc.metadata.get("timestamp")} for doc in raw_docs],
)

Checkpoint: assert all(c.metadata.get("source") for c in chunks), "Missing source metadata"

2. Generating Embeddings & Indexing

from openai import OpenAI
import qdrant_client
from qdrant_client.models import VectorParams, Distance, PointStruct

client = OpenAI()
qdrant = qdrant_client.QdrantClient("localhost", port=6333)

# Create collection
qdrant.recreate_collection(
    collection_name="knowledge_base",
    vectors_config=VectorParams(size=1536, distance=Distance.COSINE),
)

def embed_chunks(chunks: list[str], model: str = "text-embedding-3-small") -> list[list[float]]:
    response = client.embeddings.create(input=chunks, model=model)
    return [r.embedding for r in response.data]

# Idempotent upsert with deduplication via deterministic IDs
import hashlib, uuid

points = []
for i, chunk in enumerate(chunks):
    doc_id = str(uuid.UUID(hashlib.md5(chunk.page_content.encode()).hexdigest()))
    embedding = embed_chunks([chunk.page_content])[0]
    points.append(PointStruct(id=doc_id, vector=embedding, payload=chunk.metadata))

qdrant.upsert(collection_name="knowledge_base", points=points)

Checkpoint: assert qdrant.count("knowledge_base").count == len(set(p.id for p in points)), "Deduplication failed"

3. Hybrid Search (Vector + BM25)

from qdrant_client.models import Filter, FieldCondition, MatchValue, SparseVector
from rank_bm25 import BM25Okapi

def hybrid_search(query: str, tenant_id: str, top_k: int = 20) -> list:
    # Dense retrieval
    query_embedding = embed_chunks([query])[0]
    tenant_filter = Filter(must=[FieldCondition(key="tenant_id", match=MatchValue(value=tenant_id))])
    dense_results = qdrant.search(
        collection_name="knowledge_base",
        query_vector=query_embedding,
        query_filter=tenant_filter,
        limit=top_k,
    )

    # Sparse retrieval (BM25)
    corpus = [r.payload.get("text", "") for r in dense_results]
    bm25 = BM25Okapi([doc.split() for doc in corpus])
    bm25_scores = bm25.get_scores(query.split())

    # Reciprocal Rank Fusion
    ranked = sorted(
        zip(dense_results, bm25_scores),
        key=lambda x: 0.6 * x[0].score + 0.4 * x[1],
        reverse=True,
    )
    return [r for r, _ in ranked[:top_k]]

Checkpoint: assert len(hybrid_search("test query", tenant_id="demo")) > 0, "Hybrid search returned no results"

4. Reranking Top-K Results

import cohere

co = cohere.Client("YOUR_API_KEY")

def rerank(query: str, results: list, top_n: int = 5) -> list:
    docs = [r.payload.get("text", "") for r in results]
    reranked = co.rerank(query=query, documents=docs, top_n=top_n, model="rerank-english-v3.0")
    return [results[r.index] for r in reranked.results]

5. Retrieval Evaluation

# Run precision@k and recall@k against a labeled evaluation set
# python evaluate.py --metrics precision@10 recall@10 mrr --collection knowledge_base

from ragas import evaluate
from ragas.metrics import context_precision, context_recall, faithfulness, answer_relevancy
from datasets import Dataset

eval_dataset = Dataset.from_dict({
    "question": questions,
    "contexts": retrieved_contexts,
    "answer": generated_answers,
    "ground_truth": ground_truth_answers,
})

results = evaluate(eval_dataset, metrics=[context_precision, context_recall, faithfulness, answer_relevancy])
print(results)

Checkpoint: Target context_precision >= 0.7 and context_recall >= 0.6 before moving to LLM integration.

Constraints

MUST DO

  • Evaluate multiple embedding models on your domain data before committing
  • Implement hybrid search (vector + keyword) for production systems
  • Add metadata filters for multi-tenant or domain-specific retrieval
  • Measure retrieval metrics (precision@k, recall@k, MRR, NDCG)
  • Use reranking for top-k results before passing context to LLM
  • Implement idempotent ingestion with deduplication (deterministic IDs)
  • Monitor retrieval latency and quality over time
  • Version embeddings and plan for model migration

MUST NOT DO

  • Use default chunk size (512) without evaluation on your domain data
  • Skip metadata enrichment (source, timestamp, section)
  • Ignore retrieval quality metrics in favor of only LLM output quality
  • Store raw documents without preprocessing/cleaning
  • Use cosine similarity alone for complex multi-domain retrieval
  • Deploy without testing on production-like data volumes
  • Forget to handle edge cases (empty results, malformed docs)
  • Couple the embedding model tightly to application code

Output Templates

When designing RAG architecture, deliver:

  1. System architecture diagram (ingestion + retrieval pipelines)
  2. Vector database selection with trade-off analysis
  3. Chunking strategy with examples and rationale
  4. Retrieval pipeline design (query → results flow)
  5. Evaluation plan with metrics, benchmarks, and pass/fail thresholds

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Updated2026年7月17日
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Compatible Platforms

🔧Claude Code
🔧OpenClaw
🔧OpenCode
🔧Codex
🔧Gemini CLI
🔧GitHub Copilot
🔧Amp
🔧Kimi CLI

Timeline

Created2026年3月16日
Last Updated2026年7月17日
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