10 KiB
10 KiB
Phase 4: Completion and Documentation
Phase to record final results and commit code.
Time Required: 30 minutes - 1 hour
📋 Related Documents: Overall Workflow | Practical Examples
Phase 4: Completion and Documentation
Step 12: Create Final Evaluation Report
Report Template:
# LangGraph Application Fine-Tuning Completion Report
Project: [Project Name]
Implementation Period: 2024-11-24 10:00 - 2024-11-24 15:00 (5 hours)
Implementer: Claude Code with fine-tune skill
## Executive Summary
This fine-tuning project executed prompt optimization for a LangGraph chatbot application and achieved the following results:
- ✅ **Accuracy**: 75.0% → 92.0% (+17.0%, achieved 90% target)
- ✅ **Latency**: 2.5s → 1.9s (-24.0%, achieved 2.0s target)
- ⚠️ **Cost**: $0.015 → $0.011 (-26.7%, target $0.010 not met)
A total of 3 iterations were executed, achieving 2 out of 3 metric targets.
## Implementation Summary
### Iteration Count and Execution Time
- **Total Iterations**: 3
- **Optimized Nodes**: 2 (analyze_intent, generate_response)
- **Evaluation Run Count**: 20 times (baseline 5 times + 5 times × 3 post-iteration)
- **Total Execution Time**: Approximately 5 hours
### Final Results
| Metric | Initial | Final | Improvement | % Change | Target | Achievement |
|--------|---------|-------|-------------|----------|--------|-------------|
| Accuracy | 75.0% | 92.0% | +17.0% | +22.7% | 90.0% | ✅ 102.2% achieved |
| Latency | 2.5s | 1.9s | -0.6s | -24.0% | 2.0s | ✅ 95.0% achieved |
| Cost/req | $0.015 | $0.011 | -$0.004 | -26.7% | $0.010 | ⚠️ 90.9% achieved |
## Iteration Details
### Iteration 1: Optimization of analyze_intent node
**Date/Time**: 2024-11-24 11:00
**Target Node**: src/nodes/analyzer.py:25-45
**Changes**:
1. temperature: 1.0 → 0.3
2. Added 5 few-shot examples
3. Structured JSON output format
4. Defined clear classification categories (4)
**Results**:
- Accuracy: 75.0% → 86.0% (+11.0%)
- Latency: 2.5s → 2.4s (-0.1s)
- Cost: $0.015 → $0.014 (-$0.001)
**Learning**: Few-shot examples and clear output format most effective for accuracy improvement
---
### Iteration 2: Optimization of generate_response node
**Date/Time**: 2024-11-24 13:00
**Target Node**: src/nodes/generator.py:45-68
**Changes**:
1. Added conciseness instructions ("answer in 2-3 sentences")
2. max_tokens: unlimited → 500
3. temperature: 0.7 → 0.5
4. Clarified response style
**Results**:
- Accuracy: 86.0% → 88.0% (+2.0%)
- Latency: 2.4s → 2.0s (-0.4s)
- Cost: $0.014 → $0.011 (-$0.003)
**Learning**: max_tokens limit contributed significantly to latency and cost reduction
---
### Iteration 3: Additional improvement of analyze_intent
**Date/Time**: 2024-11-24 14:30
**Target Node**: src/nodes/analyzer.py:25-45
**Changes**:
1. Increased few-shot examples from 5 → 10
2. Added edge case handling
3. Re-classification logic with confidence threshold
**Results**:
- Accuracy: 88.0% → 92.0% (+4.0%)
- Latency: 2.0s → 1.9s (-0.1s)
- Cost: $0.011 → $0.011 (±0)
**Learning**: Additional few-shot examples broke through final accuracy barrier
## Final Changes
### src/nodes/analyzer.py (analyze_intent node)
#### Before
```python
def analyze_intent(state: GraphState) -> GraphState:
llm = ChatAnthropic(model="claude-3-5-sonnet-20241022", temperature=1.0)
messages = [
SystemMessage(content="You are an intent analyzer. Analyze user input."),
HumanMessage(content=f"Analyze: {state['user_input']}")
]
response = llm.invoke(messages)
state["intent"] = response.content
return state
After
def analyze_intent(state: GraphState) -> GraphState:
llm = ChatAnthropic(model="claude-3-5-sonnet-20241022", temperature=0.3)
system_prompt = """You are an intent classifier for a customer support chatbot.
Classify user input into: product_inquiry, technical_support, billing, or general.
Output JSON: {"intent": "<category>", "confidence": <0.0-1.0>, "reasoning": "<explanation>"}
[10 few-shot examples...]
"""
messages = [
SystemMessage(content=system_prompt),
HumanMessage(content=f"Input: {state['user_input']}\nOutput:")
]
response = llm.invoke(messages)
intent_data = json.loads(response.content)
# Low confidence → re-classify as general
if intent_data["confidence"] < 0.7:
intent_data["intent"] = "general"
state["intent"] = intent_data["intent"]
state["confidence"] = intent_data["confidence"]
return state
Key Changes:
- temperature: 1.0 → 0.3
- Few-shot examples: 0 → 10
- Output: free text → JSON
- Added confidence threshold fallback
src/nodes/generator.py (generate_response node)
Before
def generate_response(state: GraphState) -> GraphState:
llm = ChatAnthropic(model="claude-3-5-sonnet-20241022", temperature=0.7)
prompt = ChatPromptTemplate.from_messages([
("system", "Generate helpful response based on context."),
("human", "{context}\n\nQuestion: {question}")
])
chain = prompt | llm
response = chain.invoke({"context": state["context"], "question": state["user_input"]})
state["response"] = response.content
return state
After
def generate_response(state: GraphState) -> GraphState:
llm = ChatAnthropic(
model="claude-3-5-sonnet-20241022",
temperature=0.5,
max_tokens=500 # Output length limit
)
system_prompt = """You are a helpful customer support assistant.
Guidelines:
- Be concise: Answer in 2-3 sentences
- Be friendly: Use a warm, professional tone
- Be accurate: Base your answer on the provided context
- If uncertain: Acknowledge and offer to escalate
Format: Direct answer followed by one optional clarifying sentence.
"""
prompt = ChatPromptTemplate.from_messages([
("system", system_prompt),
("human", "Context: {context}\n\nQuestion: {question}\n\nAnswer:")
])
chain = prompt | llm
response = chain.invoke({"context": state["context"], "question": state["user_input"]})
state["response"] = response.content
return state
Key Changes:
- temperature: 0.7 → 0.5
- max_tokens: unlimited → 500
- Clear conciseness instruction ("2-3 sentences")
- Added response style guidelines
Detailed Evaluation Results
Improvement Status by Test Case
| Case ID | Category | Before | After | Improved |
|---|---|---|---|---|
| TC001 | Product | ❌ Wrong | ✅ Correct | ✅ |
| TC002 | Technical | ❌ Wrong | ✅ Correct | ✅ |
| TC003 | Billing | ✅ Correct | ✅ Correct | - |
| TC004 | General | ✅ Correct | ✅ Correct | - |
| TC005 | Product | ❌ Wrong | ✅ Correct | ✅ |
| ... | ... | ... | ... | ... |
| TC020 | Technical | ✅ Correct | ✅ Correct | - |
Improved Cases: 15/20 (75%) Maintained Cases: 5/20 (25%) Degraded Cases: 0/20 (0%)
Latency Breakdown
| Node | Before | After | Change | % Change |
|---|---|---|---|---|
| analyze_intent | 0.5s | 0.4s | -0.1s | -20% |
| retrieve_context | 0.2s | 0.2s | ±0s | 0% |
| generate_response | 1.8s | 1.3s | -0.5s | -28% |
| Total | 2.5s | 1.9s | -0.6s | -24% |
Cost Breakdown
| Node | Before | After | Change | % Change |
|---|---|---|---|---|
| analyze_intent | $0.003 | $0.003 | ±$0 | 0% |
| retrieve_context | $0.001 | $0.001 | ±$0 | 0% |
| generate_response | $0.011 | $0.007 | -$0.004 | -36% |
| Total | $0.015 | $0.011 | -$0.004 | -27% |
Future Recommendations
Short-term (1-2 weeks)
-
Achieve cost target: $0.011 → $0.010
- Approach: Consider partial migration to Claude 3.5 Haiku
- Estimated effect: -$0.002-0.003/req
-
Further accuracy improvement: 92.0% → 95.0%
- Approach: Analyze error cases and add few-shot examples
- Estimated effect: +3.0%
Mid-term (1-2 months)
-
Model optimization
- Use Haiku for simple intent classification
- Use Sonnet only for complex response generation
- Estimated effect: -30-40% cost, minimal latency impact
-
Leverage prompt caching
- Cache system prompts and few-shot examples
- Estimated effect: -50% cost (when cache hits)
Long-term (3-6 months)
- Consider fine-tuned models
- Model fine-tuning with proprietary data
- No need for few-shot examples, more concise prompts
- Estimated effect: -60% cost, +5% accuracy
Conclusion
This project achieved the following through fine-tuning of the LangGraph application:
✅ Successes:
- Significant accuracy improvement (+22.7%) - exceeded target by 2.2%
- Notable latency improvement (-24.0%) - exceeded target by 5%
- Cost reduction (-26.7%) - 9.1% away from target
⚠️ Challenges:
- Cost target not met ($0.011 vs $0.010 target) - addressable through migration to lighter models
📈 Business Impact:
- Improved user satisfaction (through accuracy improvement)
- Reduced operational costs (through latency and cost reduction)
- Improved scalability (through efficient resource usage)
🎯 Next Steps:
- Validate migration to lighter models for cost reduction
- Continuous monitoring and evaluation
- Expansion to new use cases
Created: 2024-11-24 15:00:00 Creator: Claude Code (fine-tune skill)
### Step 13: Commit Code and Update Documentation
**Git Commit Example**:
```bash
# Commit changes
git add src/nodes/analyzer.py src/nodes/generator.py
git commit -m "feat: optimize LangGraph prompts for accuracy and latency
Iteration 1-3 of fine-tuning process:
- analyze_intent: added few-shot examples, JSON output, lower temperature
- generate_response: added conciseness guidelines, max_tokens limit
Results:
- Accuracy: 75.0% → 92.0% (+17.0%, goal 90% ✅)
- Latency: 2.5s → 1.9s (-0.6s, goal 2.0s ✅)
- Cost: $0.015 → $0.011 (-$0.004, goal $0.010 ⚠️)
Full report: evaluation_results/final_report.md"
# Commit evaluation results
git add evaluation_results/
git commit -m "docs: add fine-tuning evaluation results and final report"
# Add tag
git tag -a fine-tune-v1.0 -m "Fine-tuning completed: 92% accuracy achieved"
Summary
Following this workflow enables:
- ✅ Systematic fine-tuning process execution
- ✅ Data-driven decision making
- ✅ Continuous improvement and verification
- ✅ Complete documentation and traceability