agent-orchestration-improve-agent
This Claude Code skill provides a systematic workflow for improving existing agents through performance analysis, prompt engineering, and iterative optimization. Use it when you have an operational agent with performance metrics or user feedback and need to identify failure modes, test prompt improvements, establish baselines, run A/B tests, or design controlled rollout strategies to enhance reliability and accuracy.
git clone --depth 1 https://github.com/sickn33/antigravity-awesome-skills /tmp/agent-orchestration-improve-agent && cp -r /tmp/agent-orchestration-improve-agent/plugins/antigravity-awesome-skills-claude/skills/agent-orchestration-improve-agent ~/.claude/skills/agent-orchestration-improve-agentSKILL.md
# Agent Performance Optimization Workflow Systematic improvement of existing agents through performance analysis, prompt engineering, and continuous iteration. [Extended thinking: Agent optimization requires a data-driven approach combining performance metrics, user feedback analysis, and advanced prompt engineering techniques. Success depends on systematic evaluation, targeted improvements, and rigorous testing with rollback capabilities for production safety.] ## Use this skill when - Improving an existing agent's performance or reliability - Analyzing failure modes, prompt quality, or tool usage - Running structured A/B tests or evaluation suites - Designing iterative optimization workflows for agents ## Do not use this skill when - You are building a brand-new agent from scratch - There are no metrics, feedback, or test cases available - The task is unrelated to agent performance or prompt quality ## Instructions 1. Establish baseline metrics and collect representative examples. 2. Identify failure modes and prioritize high-impact fixes. 3. Apply prompt and workflow improvements with measurable goals. 4. Validate with tests and roll out changes in controlled stages. ## Safety - Avoid deploying prompt changes without regression testing. - Roll back quickly if quality or safety metrics regress. ## Phase 1: Performance Analysis and Baseline Metrics Comprehensive analysis of agent performance using context-manager for historical data collection. ### 1.1 Gather Performance Data ``` Use: context-manager Command: analyze-agent-performance $ARGUMENTS --days 30 ``` Collect metrics including: - Task completion rate (successful vs failed tasks) - Response accuracy and factual correctness - Tool usage efficiency (correct tools, call frequency) - Average response time and token consumption - User satisfaction indicators (corrections, retries) - Hallucination incidents and error patterns ### 1.2 User Feedback Pattern Analysis Identify recurring patterns in user interactions: - **Correction patterns**: Where users consistently modify outputs - **Clarification requests**: Common areas of ambiguity - **Task abandonment**: Points where users give up - **Follow-up questions**: Indicators of incomplete responses - **Positive feedback**: Successful patterns to preserve ### 1.3 Failure Mode Classification Categorize failures by root cause: - **Instruction misunderstanding**: Role or task confusion - **Output format errors**: Structure or formatting issues - **Context loss**: Long conversation degradation - **Tool misuse**: Incorrect or inefficient tool selection - **Constraint violations**: Safety or business rule breaches - **Edge case handling**: Unusual input scenarios ### 1.4 Baseline Performance Report Generate quantitative baseline metrics: ``` Performance Baseline: - Task Success Rate: [X%] - Average Corrections per Task: [Y] - Tool Call Efficiency: [Z%] - User Satisfaction Score: [1-10] - Average Response Latency: [Xms] - Token Efficiency Ratio: [X:Y] ``` ## Phase 2: Prompt Engineering Improvements Apply advanced prompt optimization techniques using prompt-engineer agent. ### 2.1 Chain-of-Thought Enhancement Implement structured reasoning patterns: ``` Use: prompt-engineer Technique: chain-of-thought-optimization ``` - Add explicit reasoning steps: "Let's approach this step-by-step..." - Include self-verification checkpoints: "Before proceeding, verify that..." - Implement recursive decomposition for complex tasks - Add reasoning trace visibility for debugging ### 2.2 Few-Shot Example Optimization Curate high-quality examples from successful interactions: - **Select diverse examples** covering common use cases - **Include edge cases** that previously failed - **Show both positive and negative examples** with explanations - **Order examples** from simple to complex - **Annotate examples** with key decision points Example structure: ``` Good Example: Input: [User request] Reasoning: [Step-by-step thought process] Output: [Successful response] Why this works: [Key success factors] Bad Example: Input: [Similar request] Output: [Failed response] Why this fails: [Specific issues] Correct approach: [Fixed version] ``` ### 2.3 Role Definition Refinement Strengthen agent identity and capabilities: - **Core purpose**: Clear, single-sentence mission - **Expertise domains**: Specific knowledge areas - **Behavioral traits**: Personality and interaction style - **Tool proficiency**: Available tools and when to use them - **Constraints**: What the agent should NOT do - **Success criteria**: How to measure task completion ### 2.4 Constitutional AI Integration Implement self-correction mechanisms: ``` Constitutional Principles: 1. Verify factual accuracy before responding 2. Self-check for potential biases or harmful content 3. Validate output format matches requirements 4. Ensure response completeness 5. Maintain consistency with previous responses ``` Add critique-and-revise loops: - Initial response generation - Self-critique against principles - Automatic revision if issues detected - Final validation before output ### 2.5 Output Format Tuning Optimize response structure: - **Structured templates** for common tasks - **Dynamic formatting** based on complexity - **Progressive disclosure** for detailed information - **Markdown optimization** for readability - **Code block formatting** with syntax highlighting - **Table and list generation** for data presentation ## Phase 3: Testing and Validation Comprehensive testing framework with A/B comparison. ### 3.1 Test Suite Development Create representative test scenarios: ``` Test Categories: 1. Golden path scenarios (common successful cases) 2. Previously failed tasks (regression testing) 3. Edge cases and corner scenarios 4. Stress tests (complex, multi-step tasks) 5. Adversarial inputs (potential breaking points) 6. Cross-domain tasks (combining capabilities) ``` ### 3.2 A/B Testing Framework Compare original
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