Analyze Magnetic Levitation
技能 已验证 活跃Analyze magnetic levitation systems by applying Earnshaw's theorem to determine whether passive static levitation is possible, then identifying the appropriate circumvention mechanism (diamagnetic, superconducting, active feedback, or spin-stabilized). Use when evaluating maglev transport, magnetic bearings, superconducting levitation, diamagnetic suspension, or Levitron-type devices. Covers force balance calculations, stability analysis in all spatial and tilting modes, and Meissner effect versus flux pinning distinctions.
To provide a rigorous, step-by-step analysis for determining the feasibility and stability of magnetic levitation systems.
功能
- Applies Earnshaw's theorem to static levitation possibility
- Identifies circumvention mechanisms (diamagnetic, superconducting, active, spin-stabilized)
- Performs force balance calculations and determines equilibrium height
- Analyzes translational and rotational stability across all degrees of freedom
- Documents common pitfalls and recovery steps for levitation failures
使用场景
- Evaluating the viability of new magnetic levitation designs
- Troubleshooting why a magnetic system fails to levitate statically
- Analyzing superconducting levitation phenomena like Meissner effect and flux pinning
- Assessing the stability requirements for active feedback levitation systems
非目标
- Designing the specific hardware components for a levitation system
- Implementing or simulating active feedback control loops
- Performing detailed finite element analysis of magnetic fields
Practical Utility
- info:Usage examplesThe SKILL.md provides detailed input requirements and expected outputs, but lacks explicit, ready-to-run examples for each capability. The 'Common Pitfalls' section offers some illustrative scenarios.
安装
/plugin install agent-almanac@pjt222-agent-almanac质量评分
已验证类似扩展
Design Acoustic Levitation
95Design an acoustic levitation system that uses standing waves to trap and suspend small objects at pressure nodes. Covers ultrasonic transducer selection, standing wave formation between a transducer and reflector, node spacing and trapping position calculation, acoustic radiation pressure analysis, and phased array configurations for multi-axis manipulation. Use when designing contactless sample handling for chemistry, biology, materials science, or demonstration purposes.
Qutip
99Quantum physics simulation library for open quantum systems. Use when studying master equations, Lindblad dynamics, decoherence, quantum optics, or cavity QED. Best for physics research, open system dynamics, and educational simulations. NOT for circuit-based quantum computing—use qiskit, cirq, or pennylane for quantum algorithms and hardware execution.
Evaluate Levitation Mechanism
98Evaluate and compare levitation mechanisms for a given application through a structured trade study. Covers magnetic (passive diamagnetic, active feedback, superconducting), acoustic (standing wave, phased array), aerodynamic (hovercraft, air bearings, Coanda effect), and electrostatic (Coulomb suspension, ion traps) mechanisms. Use when selecting the most appropriate levitation approach for transport, sample handling, display, bearings, or precision measurement applications.
Design Electromagnetic Device
96Design practical electromagnetic devices including electromagnets, DC and brushless motors, generators, and transformers by bridging theory to application. Use when sizing a solenoid or toroidal electromagnet for a target field or force, selecting motor topology and computing torque and efficiency, designing a transformer for a given voltage ratio and power rating, or analyzing losses from copper resistance, core hysteresis, and eddy currents.
Performance Analysis
100Comprehensive performance analysis, bottleneck detection, and optimization recommendations for Claude Flow swarms
Oraclaw Decide
100为 AI 代理提供决策智能。分析选项、使用 PageRank 映射决策依赖关系、检测信息源冲突,并找出最重要的选择。