diff --git a/rust-port/SWARM_CONFIG.md b/rust-port/SWARM_CONFIG.md
deleted file mode 100644
index 56776c6..0000000
--- a/rust-port/SWARM_CONFIG.md
+++ /dev/null
@@ -1,114 +0,0 @@
-# WiFi-DensePose Rust Port - 15-Agent Swarm Configuration
-
-## Mission Statement
-Port the WiFi-DensePose Python system to Rust using ruvnet/ruvector patterns, with modular crates, WASM support, and comprehensive documentation following ADR/DDD principles.
-
-## Agent Swarm Architecture
-
-### Tier 1: Orchestration (1 Agent)
-1. **Orchestrator Agent** - Coordinates all agents, manages dependencies, tracks progress
-
-### Tier 2: Architecture & Documentation (3 Agents)
-2. **ADR Agent** - Creates Architecture Decision Records for all major decisions
-3. **DDD Agent** - Designs Domain-Driven Design models and bounded contexts
-4. **Documentation Agent** - Maintains comprehensive documentation, README, API docs
-
-### Tier 3: Core Implementation (5 Agents)
-5. **Signal Processing Agent** - Ports CSI processing, phase sanitization, FFT algorithms
-6. **Neural Network Agent** - Ports DensePose head, modality translation using tch-rs/onnx
-7. **API Agent** - Implements Axum/Actix REST API and WebSocket handlers
-8. **Database Agent** - Implements SQLx PostgreSQL/SQLite with migrations
-9. **Config Agent** - Implements configuration management, environment handling
-
-### Tier 4: Platform & Integration (3 Agents)
-10. **WASM Agent** - Implements wasm-bindgen, browser compatibility, wasm-pack builds
-11. **Hardware Agent** - Ports CSI extraction, router interfaces, hardware abstraction
-12. **Integration Agent** - Integrates ruvector crates, vector search, GNN layers
-
-### Tier 5: Quality Assurance (3 Agents)
-13. **Test Agent** - Writes unit, integration, and benchmark tests
-14. **Validation Agent** - Validates against Python implementation, accuracy checks
-15. **Optimization Agent** - Profiles, benchmarks, and optimizes hot paths
-
-## Crate Workspace Structure
-
-```
-wifi-densepose-rs/
-├── Cargo.toml                    # Workspace root
-├── crates/
-│   ├── wifi-densepose-core/      # Core types, traits, errors
-│   ├── wifi-densepose-signal/    # Signal processing (CSI, phase, FFT)
-│   ├── wifi-densepose-nn/        # Neural networks (DensePose, translation)
-│   ├── wifi-densepose-api/       # REST/WebSocket API (Axum)
-│   ├── wifi-densepose-db/        # Database layer (SQLx)
-│   ├── wifi-densepose-config/    # Configuration management
-│   ├── wifi-densepose-hardware/  # Hardware abstraction
-│   ├── wifi-densepose-wasm/      # WASM bindings
-│   └── wifi-densepose-cli/       # CLI application
-├── docs/
-│   ├── adr/                      # Architecture Decision Records
-│   ├── ddd/                      # Domain-Driven Design docs
-│   └── api/                      # API documentation
-├── benches/                      # Benchmarks
-└── tests/                        # Integration tests
-```
-
-## Domain Model (DDD)
-
-### Bounded Contexts
-1. **Signal Domain** - CSI data, phase processing, feature extraction
-2. **Pose Domain** - DensePose inference, keypoints, segmentation
-3. **Streaming Domain** - WebSocket, real-time updates, connection management
-4. **Storage Domain** - Persistence, caching, retrieval
-5. **Hardware Domain** - Router interfaces, device management
-
-### Core Aggregates
-- `CsiFrame` - Raw CSI data aggregate
-- `ProcessedSignal` - Cleaned and extracted features
-- `PoseEstimate` - DensePose inference result
-- `Session` - Client session with history
-- `Device` - Hardware device state
-
-## ADR Topics to Document
-- ADR-001: Rust Workspace Structure
-- ADR-002: Signal Processing Library Selection
-- ADR-003: Neural Network Inference Strategy
-- ADR-004: API Framework Selection (Axum vs Actix)
-- ADR-005: Database Layer Strategy (SQLx)
-- ADR-006: WASM Compilation Strategy
-- ADR-007: Error Handling Approach
-- ADR-008: Async Runtime Selection (Tokio)
-- ADR-009: ruvector Integration Strategy
-- ADR-010: Configuration Management
-
-## Phase Execution Plan
-
-### Phase 1: Foundation
-- Set up Cargo workspace
-- Create all crate scaffolding
-- Write ADR-001 through ADR-005
-- Define core traits and types
-
-### Phase 2: Core Implementation
-- Port signal processing algorithms
-- Implement neural network inference
-- Build API layer
-- Database integration
-
-### Phase 3: Platform
-- WASM compilation
-- Hardware abstraction
-- ruvector integration
-
-### Phase 4: Quality
-- Comprehensive testing
-- Python validation
-- Benchmarking
-- Optimization
-
-## Success Metrics
-- Feature parity with Python implementation
-- < 10ms latency improvement over Python
-- WASM bundle < 5MB
-- 100% test coverage
-- All ADRs documented
diff --git a/rust-port/wifi-densepose-rs/crates/wifi-densepose-ruvector/Cargo.toml b/rust-port/wifi-densepose-rs/crates/wifi-densepose-ruvector/Cargo.toml
index 2e16bb9..5b07224 100644
--- a/rust-port/wifi-densepose-rs/crates/wifi-densepose-ruvector/Cargo.toml
+++ b/rust-port/wifi-densepose-rs/crates/wifi-densepose-ruvector/Cargo.toml
@@ -5,7 +5,10 @@ edition.workspace = true
 authors.workspace = true
 license.workspace = true
 description = "RuVector v2.0.4 integration layer — ADR-017 signal processing and MAT ruvector integrations"
+repository.workspace = true
 keywords = ["wifi", "csi", "ruvector", "signal-processing", "disaster-detection"]
+categories = ["science", "computer-vision"]
+readme = "README.md"
 
 [dependencies]
 ruvector-mincut = { workspace = true }