symbolica-mcp

A scientific computing Model Context Protocol (MCP) server allows AI, such as Claude, to perform symbolic computing, conduct calculations, analyze data, and generate visualizations. This is particularly useful for scientific and engineering applications, including quantum computing, all within a containerized environment.

Features

Run scientific computing operations with NumPy, SciPy, SymPy, Pandas
Perform symbolic mathematics and solve differential equations
Support for linear algebra operations and matrix manipulations
Quantum computing analysis
Create data visualizations with Matplotlib and Seaborn
Perform machine learning operations with scikit-learn
Execute tensor operations and complex matrix calculations
Analyze data sets with statistical tools
Cross-platform support (automatically detects Windows, macOS, and Linux), especially for users with Mac M series chips
Works on both Intel/AMD (x86_64) and ARM processors

Quick Start

Using the Docker image

# Pull the image from Docker Hub
docker pull ychen94/computing-mcp:latest

# Run the container (automatically detects host OS)
docker run -i --rm -v /tmp:/app/shared ychen94/computing-mcp:latest

For Windows users:

docker run -i --rm -v $env:TEMP:/app/shared ychen94/computing-mcp:latest

Integrating with Claude for Desktop

Open Claude for Desktop
Open Settings ➝ Developer ➝ Edit Config
Add the following configuration:

For MacOS/Linux:

{
  "mcpServers": {
    "computing-mcp": {
      "command": "docker",
      "args": [
        "run",
        "-i",
        "--rm",
        "-v",
        "/tmp:/app/shared",
        "ychen94/computing-mcp:latest"
      ]
    }
  }
}

For Windows:

{
  "mcpServers": {
    "computing-mcp": {
      "command": "docker",
      "args": [
        "run",
        "-i",
        "--rm",
        "-v",
        "%TEMP%:/app/shared",
        "ychen94/computing-mcp:latest"
      ]
    }
  }
}

Examples

Tensor Products

Can you calculate and visualize the tensor product of two matrices? Please run:

import numpy as np
import matplotlib.pyplot as plt

# Define two matrices
A = np.array([[1, 2], 
              [3, 4]])
B = np.array([[5, 6],
              [7, 8]])

# Calculate tensor product using np.kron (Kronecker product)
tensor_product = np.kron(A, B)

# Display the result
print("Matrix A:")
print(A)
print("\nMatrix B:")
print(B)
print("\nTensor Product A ⊗ B:")
print(tensor_product)

# Create a visualization of the tensor product
plt.figure(figsize=(8, 6))
plt.imshow(tensor_product, cmap='viridis')
plt.colorbar(label='Value')
plt.title('Visualization of Tensor Product A ⊗ B')

Symbolic Mathematics

Can you solve this differential equation? Please run:
import sympy as sp
import matplotlib.pyplot as plt
import numpy as np

# Define symbolic variable
x = sp.Symbol('x')
y = sp.Function('y')(x)

# Define the differential equation: y''(x) + 2*y'(x) + y(x) = 0
diff_eq = sp.Eq(sp.diff(y, x, 2) + 2*sp.diff(y, x) + y, 0)

# Solve the equation
solution = sp.dsolve(diff_eq)
print("Solution:")
print(solution)

# Plot a particular solution (C1=1, C2=0)
solution_func = solution.rhs.subs({sp.symbols('C1'): 1, sp.symbols('C2'): 0})
print("Particular solution:")
print(solution_func)

# Create a numerical function we can evaluate
solution_lambda = sp.lambdify(x, solution_func)

# Plot the solution
x_vals = np.linspace(0, 5, 100)
y_vals = [float(solution_lambda(x_val)) for x_val in x_vals]

plt.figure(figsize=(10, 6))
plt.plot(x_vals, y_vals)
plt.grid(True)
plt.title("Solution to y''(x) + 2*y'(x) + y(x) = 0")
plt.xlabel('x')
plt.ylabel('y(x)')
plt.show()

Data Analysis

Can you perform a clustering analysis on this dataset? Please run:

import numpy as np
import pandas as pd
import matplotlib.pyplot as plt
from sklearn.cluster import KMeans
from sklearn.preprocessing import StandardScaler

# Create a sample dataset
np.random.seed(42)
n_samples = 300

# Create three clusters
cluster1 = np.random.normal(loc=[2, 2], scale=0.5, size=(n_samples//3, 2))
cluster2 = np.random.normal(loc=[7, 7], scale=0.5, size=(n_samples//3, 2))
cluster3 = np.random.normal(loc=[2, 7], scale=0.5, size=(n_samples//3, 2))

# Combine clusters
X = np.vstack([cluster1, cluster2, cluster3])

# Create DataFrame
df = pd.DataFrame(X, columns=['Feature1', 'Feature2'])
print(df.head())

# Standardize data
scaler = StandardScaler()
X_scaled = scaler.fit_transform(X)

# Apply KMeans clustering
kmeans = KMeans(n_clusters=3, random_state=42)
df['Cluster'] = kmeans.fit_predict(X_scaled)

# Plot the clusters
plt.figure(figsize=(10, 6))
for cluster_id in range(3):
    cluster_data = df[df['Cluster'] == cluster_id]
    plt.scatter(cluster_data['Feature1'], cluster_data['Feature2'], 
                label=f'Cluster {cluster_id}', alpha=0.7)

# Plot cluster centers
centers = scaler.inverse_transform(kmeans.cluster_centers_)
plt.scatter(centers[:, 0], centers[:, 1], s=200, c='red', marker='X', label='Centers')

plt.title('K-Means Clustering Results')
plt.xlabel('Feature 1')
plt.ylabel('Feature 2')
plt.legend()
plt.grid(True)

Quantum Computing

quantum example

Gallery

laser physics:

laser

elliptic integral:

elliptic integral

elliptic integral pic

Troubleshooting

Common Issues

Permission errors with volume mounts
- Ensure the mount directory exists and has appropriate permissions
Plot pciture files not appearing
- Check the path in your host system: /tmp for macOS/Linux or your temp folder for Windows
- Verify Docker has permissions to write to the mount location
- check the mcp tool's output content
  find the pic
  then open it in the terminal or your picture viewer.
  
  ⭐️ ⭐️ I use the iterm-mcp-server or other terminals' mcp servers to open the file without interrupting your workflow. ⭐️ ⭐️

Support

If you encounter issues, please open a GitHub issue with:

Error messages
Your operating system and Docker version
Steps to reproduce the problem

License

This project is licensed under the MIT License.
For more details, please see the LICENSE file in this project repository.