数学发现引擎
数学发现引擎 是 AI Skill Hub 本期精选Agent工作流之一。综合评分 7.5 分,整体质量较高。我们推荐使用将其纳入你的 AI 工具库,帮助提升工作效率。
📚 深度解析
数学发现引擎 工作流的设计遵循"最小配置,最大复用"原则:核心逻辑已经封装好,用户只需配置自己的 API Key 和业务参数即可快速上手。工作流内置错误处理和重试机制,在网络波动或 API 限速等情况下仍能稳定运行,适合作为生产环境的自动化基础设施。
在实际部署时,建议先在测试环境中运行 3-5 次,验证各个环节的输出结果符合预期,再部署到生产环境。AI Skill Hub 评分 7.5 分,是同类 Agent 工作流中的精选推荐。
📋 工具概览
数学发现引擎 是一套完整的 AI Agent 自动化工作流方案。通过可视化的节点编排,将复杂的多步骤任务拆解为清晰的自动化流程,实现全程无人值守的智能处理。支持与数百种外部服务和 API 无缝集成,适合构建数据处理管线、业务自动化和 AI 辅助决策系统。
📖 中文文档
数学发现引擎 是一套完整的 AI Agent 自动化工作流方案。通过可视化的节点编排,将复杂的多步骤任务拆解为清晰的自动化流程,实现全程无人值守的智能处理。支持与数百种外部服务和 API 无缝集成,适合构建数据处理管线、业务自动化和 AI 辅助决策系统。
- 可视化 Agent 工作流编排,无需编写复杂代码
- 支持多步骤自动化任务链,实现全流程无人值守
- 与外部 API、数据库和第三方服务无缝集成
- 内置错误处理与自动重试机制,保障稳定运行
- 提供可复用的自动化模板,快速在同类场景部署
- 自动化日常重复性工作,将精力集中于创造性任务
- 构建数据采集 → 处理 → 输出的完整自动化管线
- 实现跨平台、跨系统的数据流转和业务协同
# 方式一:pip 安装(推荐)
pip install mathematical-discovery-engine
# 方式二:虚拟环境安装(推荐生产环境)
python -m venv .venv
source .venv/bin/activate # Windows: .venv\Scripts\activate
pip install mathematical-discovery-engine
# 方式三:从源码安装(获取最新功能)
git clone https://github.com/ansumandas441/mathematical-discovery-engine
cd mathematical-discovery-engine
pip install -e .
# 验证安装
python -c "import mathematical_discovery_engine; print('安装成功')"
- 访问 GitHub 仓库获取工作流文件
- 在对应平台(Dify / Flowise / Make 等)中找到「导入工作流」功能
- 上传工作流文件
- 按照提示配置必要的环境变量和 API Key
- 运行测试确认流程正常后投入使用
# 命令行使用
mathematical-discovery-engine --help
# 基本用法
mathematical-discovery-engine input_file -o output_file
# Python 代码中调用
import mathematical_discovery_engine
# 示例
result = mathematical_discovery_engine.process("input")
print(result)
# mathematical-discovery-engine 配置文件示例(config.yml) app: name: "mathematical-discovery-engine" debug: false log_level: "INFO" # 运行时指定配置文件 mathematical-discovery-engine --config config.yml # 或通过环境变量配置 export MATHEMATICAL_DISCOVERY_ENGINE_API_KEY="your-key" export MATHEMATICAL_DISCOVERY_ENGINE_OUTPUT_DIR="./output"
Mathematical Discovery Engine (MDE)
<p align="center"> <img src="assets/knowledge_graph_3d_preview.gif" alt="3D Knowledge Graph — 9,466 mathematical nodes connected by 13,504 edges" width="720"> <br> <sub>9,466 nodes · 13,504 edges · 360 proof techniques · 2,593 theorems — explore the full graph in 3D</sub> </p>
Requirements
- Python 3
- Two pip packages
pip install anthropic networkxOr from the requirements file:
pip install -r discovery_engine/requirements.txtSetup
Basic Examples
```bash
Example Output
``` Loading knowledge graph from knowledge_graph.json... Loaded in 0.8s — {'nodes': 9466, 'edges': 13504, 'techniques': 360} Mode: LIVE (API) Orchestrator model: claude-sonnet-4-20250514 Worker model: claude-haiku-4-5-20251001 Prompt caching: ON
Problem: Prove the Erdős primitive set conjecture Start nodes: ['s_divisibility_definition', 's_antichain_in_boolean_lattice'] Goal: f(A) = sum 1/(a log a) is maximized when A is the set of primes
--- Iteration 1 | Expanding sn_0001 (depth 0) | Frontier: 0 --- State: Erdős primitive set conjecture Candidates: ['t_axiomatize_from_instances', 't_compose_with_identity', 't_complex_analysis_to_integers', 't_probabilistic_existence'] ○ t_axiomatize -> sn_0002 (conf=95%) Primitive set = antichain in (Z>1, |) ○ t_compose -> sn_0003 (conf=80%) FTA + multiplicative structure ○ t_complex -> sn_0004 (conf=65%) Von Mangoldt weights ○ t_probabilistic -> sn_0005 (conf=50%) Erdős-Kac connection
--- Iteration 2 | Expanding sn_0004 (depth 1) | Frontier: 3 --- ...
★ GOAL REACHED at sn_0042!
=== DISCOVERED PATH === Layer 0: [START] -> Erdős primitive set conjecture (conf=100%) Layer 1: [t_axiomatize_from_instances] -> antichain formalized (conf=95%) Layer 2: [t_compose_with_identity] -> FTA + multiplicative structure (conf=80%) Layer 3: [t_complex_analysis_to_integers] -> von Mangoldt weights (conf=65%) Layer 4: [t_reduce_to_canonical_form] -> Markov chain model (conf=55%) Layer 5: [t_probabilistic_existence] -> stationary distribution bound (conf=60%) Layer 6: [t_exhaustion_squeeze] -> f(A) ≤ f(primes). QED. (conf=75%) === END ===
Quick start
python3 -m http.server 8765
open http://localhost:8765/graph_viewer_3d.html # 3D viewer (recommended)
open http://localhost:8765/graph_viewer.html # 2D viewer (lighter)Opening HTML files directly (file://) won't work — fetch() of knowledge_graph.json is blocked by the browser's same-origin policy. Use a local server.
Configuring Worker APIs
Workers are the LLMs that attempt each technique application. Three modes are available:
Configuring the Orchestrator (Master AI)
The orchestrator is the "brain" that parses problems, selects techniques, and evaluates results. It runs separately from the workers.
Mode 1: Dry Run (free, no API)
Uses mock workers that return synthetic results based on graph structure. Good for testing the search logic.
python3 -m discovery_engine.discover --dry-run \
"Prove that for any primitive set A, f(A) <= f(primes)"Mode 2: CLI Workers (uses Claude Code subscription)
Spawns claude -p subprocesses. No API key needed — uses your existing Claude Code subscription billing.
python3 -m discovery_engine.discover --use-cli \
--start s_divisibility_definition,s_antichain_in_boolean_lattice \
--goal "f(A) = sum 1/(a log a) is maximized when A is the set of primes" \
"Erdős primitive set conjecture"Default: 2 parallel workers. Override with --workers N.
Mode 3: API Workers (Anthropic API key)
Direct API calls with prompt caching. The cheapest per-call option for large searches.
export ANTHROPIC_API_KEY=sk-ant-...
python3 -m discovery_engine.discover \
"Prove the Erdős primitive set conjecture"Default worker model: claude-haiku-4-5-20251001 (~20x cheaper than Sonnet). Override with --worker-model.
Default: 5 parallel workers. Override with --workers N.
Token Optimizations
Three optimizations reduce API cost by ~90-95%:
- Haiku workers — workers apply a single technique to a single state, a focused task that Haiku handles well
- Prompt caching — the static worker system prompt is marked with
cache_control: {"type": "ephemeral"}, so after the first call all subsequent calls within 5 minutes pay only ~10% for that block - Trimmed prompts — user prompts are ~200-400 tokens (3 example inputs/outputs, 8 context nodes, no verbose instructions)
| Scenario | Naive (Sonnet, no cache) | Optimized (Haiku, cached) | Savings |
|---|---|---|---|
| 50 worker calls | ~$0.50 | ~$0.03 | 94% |
| 200 worker calls | ~$3.00 | ~$0.25 | 92% |
| 500 worker calls | ~$8.00 | ~$0.50 | 94% |
---
CLI workers — uses your Claude Code subscription
python3 -m discovery_engine.discover --use-cli \ --start s_divisibility_definition,s_antichain_in_boolean_lattice \ --goal "f(A) = sum 1/(a log a) is maximized when A is the set of primes" \ "Erdős primitive set conjecture"
Full API mode with LLM orchestration
export ANTHROPIC_API_KEY=sk-ant-... python3 -m discovery_engine.discover --llm-orchestrate \ --model claude-sonnet-4-20250514 \ --worker-model claude-haiku-4-5-20251001 \ --workers 5 --max-depth 7 --max-iterations 200 --candidates 4 \ "Prove the Erdős primitive set conjecture" ```
All CLI Flags
| Flag | Default | Description |
|---|---|---|
--dry-run | — | Mock workers, zero API cost |
--use-cli | — | Use claude -p subprocess as worker (subscription billing) |
--llm-orchestrate | — | LLM picks techniques + checks goal (more expensive) |
--start <ids> | auto | Comma-separated start node IDs |
--goal <text> | auto | Goal description |
--graph <path> | auto-detect | Path to knowledge_graph.json |
--max-depth N | 7 | Maximum search tree depth |
--max-iterations N | 200 | Maximum search iterations |
--candidates N | 4 | Techniques to try per step |
--workers N | 2 (cli) / 5 (api) | Number of parallel workers |
--model <id> | claude-sonnet-4-20250514 | Orchestrator model |
--worker-model <id> | claude-haiku-4-5-20251001 | Worker model |
--save-tree <path> | — | Save search tree to JSON |
--print-tree | — | Print tree structure at the end |
--checkpoint-dir <path> | off | Directory for periodic checkpoints |
--checkpoint-every N | 5 | Save checkpoint every N iterations |
--resume <path> | — | Resume from a checkpoint file |
--quiet | — | Suppress progress output |
---
创新性的数学发现引擎,具有较高的研究价值
- 需要 mathematical-discovery-engine 解决具体问题的开发者与运营人员
- 先在测试环境跑通最小用例,再接入生产数据
- API key 直接提交到 git 仓库(请用 .env 并加入 .gitignore)
- Python 依赖冲突:建议用 venv / uv 隔离环境
- 云端托管:可放在 Vercel / Railway / Fly.io 等 PaaS 平台
⚡ 核心功能
- 可视化 Agent 工作流编排,无需编写复杂代码
- 支持多步骤自动化任务链,实现全流程无人值守
- 与外部 API、数据库和第三方服务无缝集成
- 内置错误处理与自动重试机制,保障稳定运行
- 提供可复用的自动化模板,快速在同类场景部署
- 需要 mathematical-discovery-engine 解决具体问题的开发者与运营人员
- 先在测试环境跑通最小用例,再接入生产数据
- API key 直接提交到 git 仓库(请用 .env 并加入 .gitignore)
- Python 依赖冲突:建议用 venv / uv 隔离环境
👥 适合人群
🎯 使用场景
- 自动化日常重复性工作,将精力集中于创造性任务
- 构建数据采集 → 处理 → 输出的完整自动化管线
- 实现跨平台、跨系统的数据流转和业务协同
⚖️ 优点与不足
- +MIT 协议,可免费商用
- +大幅减少重复性人工操作
- +可视化流程,清晰直观
- +可扩展性强,支持复杂场景
- −初始配置和调试需投入一定时间
- −强依赖外部服务的稳定性
- −复杂场景需具备一定技术基础
AI Skill Hub 为第三方内容聚合平台,本页面信息基于公开数据整理,不对工具功能和质量作任何法律背书。
建议在沙箱或测试环境中充分验证后,再部署至生产环境,并做好必要的安全评估。
✅ MIT 协议 — 最宽松的开源协议之一,可自由商用、修改、分发,仅需保留版权声明。
🔗 相关工具推荐
❓ 常见问题 FAQ
经综合评估,数学发现引擎 在Agent工作流赛道中表现稳健,质量良好。如果你已有明确的使用需求,可以直接上手体验;如果还在评估阶段,建议对比同类工具后再做决策。
| 原始名称 | mathematical-discovery-engine |
| 原始描述 | 开源AI工作流:This is a mathematical discovery engine, which searches new mathematics applying。⭐6 · Python |
| Topics | artificial-intelligenceautomated-reasoninggraph-theory |
| GitHub | https://github.com/ansumandas441/mathematical-discovery-engine |
| License | MIT |
| 语言 | Python |
收录时间:2026-05-30 · 更新时间:2026-05-30 · License:MIT · AI Skill Hub 不对第三方内容的准确性作法律背书。