Discover Awesome MCP Servers

Notion Integration

Un servidor simple de Protocolo de Contexto de Modelo (MCP) que se integra con la API de Notion para gestionar mi lista personal de tareas pendientes a través de Claude.

APISIX-MCP

The APISIX Model Context Protocol (MCP) server bridges large language models (LLMs) with the APISIX Admin API.

mcp-servers

Configuraciones del servidor MCP

AWS‑IReveal‑MCP

AWS‑IReveal‑MCP

MCP Filesystem Python

A secure MCP server enabling read-only access and file search capabilities within a specified directory, while respecting .gitignore patterns.

bilibili MCP Server

A Model Context Protocol server that allows AI assistants to retrieve user information, search videos by ID, and find content by keywords on bilibili.com.

Cursor Sound MCP

Proporciona retroalimentación de audio reproduciendo efectos de sonido cuando Cursor AI completa la generación de código, creando una experiencia de codificación más interactiva.

Dieter Rams MCP Server

An MCP server that evaluates product designs against Dieter Rams' 10 principles of good design, providing scores, feedback, and improvement suggestions.

Splunkbase MCP Server

Un servidor de Protocolo de Control de Máquina que proporciona acceso programático a la funcionalidad de Splunkbase, permitiendo a los usuarios buscar, descargar y administrar aplicaciones de Splunkbase a través de una interfaz estandarizada.

Remote MCP Server

A Cloudflare Workers-based Model Context Protocol server with OAuth login that allows AI assistants like Claude to access external tools.

Todo App

Esta aplicación fue construida completamente con Cursor, utilizando el servidor Box MCP para encontrar un PRD y las guías de codificación.

PapersWithCode Client

Un servidor que permite a los asistentes de IA buscar artículos de investigación, leer su contenido y acceder a los repositorios de código relacionados a través de la API de PapersWithCode.

n8n Workflow Builder MCP Server

Un servidor de Protocolo de Contexto de Modelo (MCP) para crear y gestionar flujos de trabajo de n8n de forma programática.

MCP Host Server

A multi-tenant remote server platform that enables applications to connect to Model Context Protocol servers over WebSocket connections, allowing secure access to file management, database, and API capabilities.

feishu-mcp-server

The direct translation of "飞书多维表格" is: **Tabla multidimensional de Feishu** However, depending on the context, you might also use: * **Tabla dinámica de Feishu:** This emphasizes the dynamic and flexible nature of the spreadsheet. * **Hoja de cálculo multidimensional de Feishu:** This is a more literal translation, using "hoja de cálculo" for spreadsheet. **Feishu** is the Chinese name for Lark, so you could also say: * **Tabla multidimensional de Lark** * **Tabla dinámica de Lark** * **Hoja de cálculo multidimensional de Lark** Therefore, the best translation depends on the specific context and what aspect you want to emphasize. If you're unsure, **Tabla multidimensional de Feishu** is a safe and accurate choice.

MCP Browser Use

Permite que los agentes de IA realicen tareas de navegación web, automatización y extracción de datos con una supervisión mínima, utilizando instrucciones en lenguaje natural y Selenium.

Website Scraper MCP Server

Un servidor MCP que extrae contenido significativo de sitios web y convierte HTML a Markdown de alta calidad, utilizando el motor Readability de Mozilla.

Maya MCP

Maya MCP

MCP Server Basic Example

A sample implementation of Model Context Protocol server demonstrating core functionality with simple arithmetic tools and greeting resources.

mcprouter MCP Server

Espejo de

Universal MCP Tool

A versatile tool that converts Web API interfaces into MCP tools for AI assistants, allowing them to access various web services through simple configuration and API key management.

MCP Python Server

A Python-based implementation of the Model Context Protocol that enables communication between a model context management server and client through a request-response architecture.

MCP Maker

Un servidor especializado que ayuda a los usuarios a crear nuevos servidores del Protocolo de Contexto de Modelo (MCP) proporcionando herramientas y plantillas para la creación de proyectos con diversas capacidades.

Instantly MCP Server

Proporciona acceso a la API v2 de Instantly para la funcionalidad de gestión de campañas de correo electrónico y clientes potenciales.

manim-mcp-server

I understand you'd like me to generate an animation similar to those created by 3Blue1Brown, using a single prompt. However, I can't directly *generate* the animation itself. I am a text-based AI. I can't create visual content like videos or animations. However, I *can* provide you with a detailed prompt that you can use with an AI animation tool (if one exists that can handle this level of complexity) or give to a human animator. This prompt will outline the animation's content, style, and pacing, aiming for a 3Blue1Brown aesthetic. **Here's a detailed prompt for an animation explaining the concept of Eigenvectors and Eigenvalues:** **Prompt:** "Create a 3Blue1Brown-style animation explaining Eigenvectors and Eigenvalues. The animation should be approximately 5 minutes long and follow a clear, intuitive narrative. **1. Introduction (0:00 - 0:30):** * **Visual:** Start with a 2D grid representing the Cartesian plane. Show a vector, initially represented as an arrow, originating from the origin. * **Narration (Voiceover):** "Imagine a vector in space. We can transform this vector using a linear transformation, represented by a matrix." * **Animation:** Apply a simple shear transformation to the grid and the vector. The vector should clearly change direction and magnitude. * **Narration:** "Most vectors change direction when transformed. But what if a vector *doesn't* change direction? That's where eigenvectors come in." **2. Defining Eigenvectors (0:30 - 1:30):** * **Visual:** Show the same grid and vector. This time, apply a different transformation (e.g., a scaling transformation). The vector should only change in length, not direction. * **Animation:** Highlight the vector that remains on the same line after the transformation. * **Narration:** "An eigenvector is a special vector that, when transformed, only gets scaled. It stays on the same line as before." * **Visual:** Introduce the equation A*v = λ*v, where A is the transformation matrix, v is the eigenvector, and λ is the eigenvalue. * **Animation:** Visually represent the equation. Show A acting on v, resulting in a scaled version of v (λ*v). Use color-coding to link the variables in the equation to their visual representations. For example, A could be represented by a colored box, v by the vector itself, and λ by a scalar value displayed numerically. * **Narration:** "The amount by which the eigenvector is scaled is called the eigenvalue, represented by λ (lambda). This equation, A*v = λ*v, is the fundamental equation of eigenvectors and eigenvalues." **3. Visualizing Eigenvalues (1:30 - 2:30):** * **Visual:** Show several vectors on the grid. Apply a transformation. Some vectors should change direction significantly, while one or two should remain on their original lines (eigenvectors). * **Animation:** Highlight the eigenvectors. Display their corresponding eigenvalues (λ) as numerical values next to them. If λ is negative, show the eigenvector flipping direction. * **Narration:** "Eigenvalues can be positive, negative, or even zero. A positive eigenvalue means the eigenvector is scaled in the same direction. A negative eigenvalue means it's scaled and flipped. A zero eigenvalue means the eigenvector is squashed to the origin." * **Visual:** Show examples of each case (positive, negative, and zero eigenvalues) with clear visual representations. **4. Finding Eigenvectors (2:30 - 3:30):** * **Visual:** Start with the equation A*v = λ*v. Rearrange it to (A - λI)*v = 0, where I is the identity matrix. * **Animation:** Visually demonstrate the matrix subtraction (A - λI). Show the identity matrix I being scaled by λ and then subtracted from A. * **Narration:** "To find the eigenvectors, we need to solve this equation. We rearrange it to (A - λI)*v = 0. This means the determinant of (A - λI) must be zero." * **Visual:** Show the determinant of (A - λI) being calculated. Visually represent the determinant as the area scaling factor of the transformation represented by (A - λI). * **Animation:** Show how the determinant changes as λ varies. When the determinant is zero, highlight the corresponding value of λ. * **Narration:** "The values of λ that make the determinant zero are the eigenvalues. Once we have the eigenvalues, we can plug them back into the equation (A - λI)*v = 0 to find the corresponding eigenvectors." **5. Importance of Eigenvectors and Eigenvalues (3:30 - 4:30):** * **Visual:** Show a more complex transformation. Then, show the same transformation represented as a combination of scaling along the eigenvectors. * **Animation:** Decompose the transformation into its eigenvector components. Show how the transformation can be understood as scaling along the eigenvectors. * **Narration:** "Eigenvectors and eigenvalues allow us to understand complex transformations by breaking them down into simpler scaling operations along specific directions. They provide a fundamental understanding of the transformation's behavior." * **Visual:** Briefly show examples of applications of eigenvectors and eigenvalues, such as: * **Principal Component Analysis (PCA):** Show data points clustered in an ellipse, and highlight the eigenvectors representing the principal components. * **Vibrational Modes:** Show a vibrating string or structure, and highlight the eigenvectors representing the different modes of vibration. * **Google's PageRank Algorithm:** Show a network of web pages and briefly mention how eigenvectors are used to determine the importance of each page. **6. Conclusion (4:30 - 5:00):** * **Visual:** Reiterate the equation A*v = λ*v. * **Animation:** Show the eigenvector and eigenvalue visually, emphasizing their relationship. * **Narration:** "Eigenvectors and eigenvalues are powerful tools for understanding linear transformations. They reveal the fundamental directions and scaling factors that govern the transformation's behavior. They are essential concepts in linear algebra and have wide-ranging applications in various fields." * **Visual:** End with a visually appealing animation of eigenvectors and eigenvalues, perhaps showing them rotating or interacting in a dynamic way. **Style and Pacing:** * **Visual Style:** Use a clean, minimalist style with clear color-coding, similar to 3Blue1Brown's animations. Use smooth transitions and animations to maintain viewer engagement. * **Pacing:** Maintain a steady pace, allowing sufficient time for viewers to grasp each concept. Use pauses and visual cues to emphasize key points. * **Narration:** Use a clear, concise, and engaging voiceover. Explain concepts in a simple and intuitive way, avoiding overly technical jargon. * **Music:** Use background music that is subtle and supportive of the animation's message. **Technical Details:** * **Software:** Ideally, use a software package that allows for precise control over animation and mathematical visualization (e.g., Manim, Blender with Python scripting). * **Resolution:** 1920x1080 (Full HD) * **Frame Rate:** 30 fps **Key Considerations for the Animator:** * **Intuition over Rigor:** Focus on building intuition rather than providing rigorous mathematical proofs. * **Visual Clarity:** Prioritize visual clarity and avoid cluttering the screen with too much information. * **Storytelling:** Tell a compelling story that engages the viewer and makes the concepts memorable. This prompt provides a detailed outline for creating a 3Blue1Brown-style animation on eigenvectors and eigenvalues. You can adapt this prompt to other mathematical concepts as well. Remember to emphasize visual clarity, intuitive explanations, and a compelling narrative. Good luck!

AbletonMCP

A server that connects Ableton Live to Claude AI through the Model Context Protocol, enabling AI-assisted music production and direct control of Ableton Live features.