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// Compute PageRank for large web graph const pageRankResults = await mcp__sublinear-time-solver__pageRank({ adjacency: { rows: 1000000, cols: 1000000, format: "coo", data: { values: edgeWeights, rowIndices: sourceNodes, colIndices: targetNodes } }, damping: 0.85, epsilon: 1e-8, maxIterations: 1000 }); console.log("Top 10 most influential nodes:", pageRankResults.scores.slice(0, 10));

// Compute personalized PageRank for recommendation systems const personalizedRank = await mcp__sublinear-time-solver__pageRank({ adjacency: userItemGraph, damping: 0.85, epsilon: 1e-6, personalized: userPreferenceVector, maxIterations: 500 }); // Generate recommendations based on personalized scores const recommendations = extractTopRecommendations(personalizedRank.scores);

// Analyze influence propagation in social networks const influenceMatrix = await mcp__sublinear-time-solver__analyzeMatrix({ matrix: socialNetworkAdjacency, checkDominance: false, checkSymmetry: true, estimateCondition: true, computeGap: true }); // Identify key influencers and influence patterns const keyInfluencers = identifyInfluencers(influenceMatrix);

// Optimize swarm communication topology class SwarmTopologyOptimizer { async optimizeTopology(agents, communicationRequirements) { // Create adjacency matrix representing agent connections const topologyMatrix = this.createTopologyMatrix(agents); // Compute PageRank to identify communication hubs const hubAnalysis = await mcp__sublinear-time-solver__pageRank({ adjacency: topologyMatrix, damping: 0.9, // Higher damping for persistent communication epsilon: 1e-6 }); // Optimize topology based on PageRank scores return this.optimizeConnections(hubAnalysis.scores, agents); } async analyzeSwarmEfficiency(currentTopology) { // Analyze current swarm communication efficiency const efficiency = await mcp__sublinear-time-solver__solve({ matrix: currentTopology, vector: communicationLoads, method: "neumann", epsilon: 1e-8 }); return { efficiency: efficiency.solution, bottlenecks: this.identifyBottlenecks(efficiency), recommendations: this.generateOptimizations(efficiency) }; } }

// Deploy distributed PageRank computation const graphSandbox = await mcp__flow-nexus__sandbox_create({ template: "python", name: "pagerank-cluster", env_vars: { GRAPH_SIZE: "10000000", CHUNK_SIZE: "100000", DAMPING_FACTOR: "0.85" } }); // Execute distributed PageRank algorithm const distributedResult = await mcp__flow-nexus__sandbox_execute({ sandbox_id: graphSandbox.id, code: ` import numpy as np from scipy.sparse import csr_matrix import asyncio async def distributed_pagerank(): # Load graph partition graph_chunk = load_graph_partition() # Initialize PageRank computation local_scores = initialize_pagerank_scores() for iteration in range(max_iterations): # Compute local PageRank update local_update = compute_local_pagerank(graph_chunk, local_scores) # Synchronize with other partitions global_scores = await synchronize_scores(local_update) # Check convergence if check_convergence(global_scores): break return global_scores result = await distributed_pagerank() print(f"PageRank computation completed: {len(result)} nodes") `, language: "python" });

// Train neural networks for graph analysis const graphNeuralNetwork = await mcp__flow-nexus__neural_train({ config: { architecture: { type: "gnn", // Graph Neural Network layers: [ { type: "graph_conv", units: 64, activation: "relu" }, { type: "graph_pool", pool_type: "mean" }, { type: "dense", units: 32, activation: "relu" }, { type: "dense", units: 1, activation: "sigmoid" } ] }, training: { epochs: 50, batch_size: 128, learning_rate: 0.01, optimizer: "adam" } }, tier: "medium" });

name	agent-pagerank-analyzer
description	Agent skill for pagerank-analyzer - invoke with $agent-pagerank-analyzer

agent-pagerank-analyzer

More from this repository

More from this repository

Core Capabilities

Graph Analysis

Network Optimization

Primary MCP Tools

Usage Scenarios

1. Large-Scale PageRank Computation

2. Personalized PageRank

3. Network Influence Analysis

Integration with Claude Flow

Swarm Topology Optimization

Consensus Network Analysis

Integration with Flow Nexus

Distributed Graph Processing

Neural Graph Networks

Advanced Graph Algorithms

Community Detection

Network Dynamics

Graph Machine Learning

Performance Optimization

Scalability Techniques

Memory Optimization

Computational Optimization

Application Domains

Social Network Analysis

Web Search and Ranking

Recommendation Systems

Infrastructure Optimization

Integration Patterns

With Matrix Optimizer

With Trading Predictor

With Consensus Coordinator

Example Workflows

Social Media Influence Campaign

Web Search Optimization

Distributed System Design

Core Capabilities

Graph Analysis

Network Optimization

Primary MCP Tools

Usage Scenarios

1. Large-Scale PageRank Computation

2. Personalized PageRank

3. Network Influence Analysis

Integration with Claude Flow

Swarm Topology Optimization

Consensus Network Analysis

Integration with Flow Nexus

Distributed Graph Processing

Neural Graph Networks

Advanced Graph Algorithms

Community Detection

Network Dynamics

Graph Machine Learning

Performance Optimization

Scalability Techniques

Memory Optimization

Computational Optimization

Application Domains

Social Network Analysis

Web Search and Ranking

Recommendation Systems

Infrastructure Optimization

Integration Patterns

With Matrix Optimizer

With Trading Predictor

With Consensus Coordinator

Example Workflows

Social Media Influence Campaign

Web Search Optimization

Distributed System Design