7c1351fd5d
* feat: dual-modal WASM browser pose estimation demo (ADR-058) Live webcam video + WiFi CSI fusion for real-time pose estimation. Two parallel CNN pipelines (ruvector-cnn-wasm) with attention-weighted fusion and dynamic confidence gating. Three modes: Dual, Video-only, CSI-only. Includes pre-built WASM package (~52KB) for browser deployment. - ADR-058: Dual-modal architecture design - ui/pose-fusion.html: Main demo page with dark theme UI - 7 JS modules: video-capture, csi-simulator, cnn-embedder, fusion-engine, pose-decoder, canvas-renderer, main orchestrator - Pre-built ruvector-cnn-wasm WASM package for browser - CSI heatmap, embedding space visualization, latency metrics - WebSocket support for live ESP32 CSI data - Navigation link added to main dashboard Co-Authored-By: claude-flow <ruv@ruv.net> * fix: motion-responsive skeleton + through-wall CSI tracking - Pose decoder now uses per-cell motion grid to track actual arm/head positions — raising arms moves the skeleton's arms, head follows lateral movement - Motion grid (10x8 cells) tracks intensity per body zone: head, left/right arm upper/mid, legs - Through-wall mode: when person exits frame, CSI maintains presence with slow decay (~10s) and skeleton drifts in exit direction - CSI simulator persists sensing after video loss, ghost pose renders with decreasing confidence - Reduced temporal smoothing (0.45) for faster response to movement Co-Authored-By: claude-flow <ruv@ruv.net> * fix: video fills available space + correct WASM path resolution - Remove fixed aspect-ratio and max-height from video panel so it fills the available viewport space without scrolling - Grid uses 1fr row for content area, overflow:hidden on main grid - Fix WASM path: resolve relative to JS module file using import.meta.url instead of hardcoded ./pkg/ which resolved incorrectly on gh-pages - Responsive: mobile still gets aspect-ratio constraint Co-Authored-By: claude-flow <ruv@ruv.net> * feat: live ESP32 CSI pipeline + auto-connect WebSocket - Add auto-connect to local sensing server WebSocket (ws://localhost:8765) - Demo shows "Live ESP32" when connected to real CSI data - Add build_firmware.ps1 for native Windows ESP-IDF builds (no Docker) - Add read_serial.ps1 for ESP32 serial monitor Pipeline: ESP32 → UDP:5005 → sensing-server → WS:8765 → browser demo Co-Authored-By: claude-flow <ruv@ruv.net> * docs: add ADR-059 live ESP32 CSI pipeline + update README with demo links - ADR-059: Documents end-to-end ESP32 → sensing server → browser pipeline - README: Add dual-modal pose fusion demo link, update ADR count to 49 - References issue #245 Co-Authored-By: claude-flow <ruv@ruv.net> * feat: RSSI visualization, RuVector attention WASM, cache-bust fixes - Add animated RSSI Signal Strength panel with sparkline history - Fix RuVector WasmMultiHeadAttention retptr calling convention - Wire up RuVector Multi-Head + Flash Attention in CNN embedder - Add ambient temporal drift to CSI simulator for visible heatmap animation - Fix embedding space projection (sparse projection replaces cancelling sum) - Add auto-scaling to embedding space renderer - Add cache busters (?v=4) to all ES module imports to prevent stale caches - Add diagnostic logging for module version verification - Add RSSI tracking with quality labels and color-coded dBm display - Includes ruvector-attention-wasm v2.0.5 browser ESM wrapper Co-Authored-By: claude-flow <ruv@ruv.net> * feat: 26-keypoint dexterous pose + full RuVector attention pipeline Pose Decoder (17 → 26 keypoints): - Add finger approximations: thumb, index, pinky per hand (6 new) - Add toe tips: left/right foot index (2 new) - Add neck keypoint (1 new) - Hand openness driven by arm motion intensity - Finger positions computed from wrist-elbow axis angles CNN Embedder (full RuVector WASM pipeline): - Stage 1: Multi-Head Attention (global spatial reasoning) - Stage 2: Hyperbolic Attention (hierarchical body-part tree) - Stage 3: MoE Attention (3 experts: upper/lower/extremities, top-2) - Blended 40/30/30 weighting → final embedding projection Canvas Renderer: - Magenta finger joints with distinct glow - Cyan toe tips - White neck keypoint - Thinner limb lines for hand/foot connections - Joint count shown in overlay label CSI Simulator: - Skip synthetic person state when live ESP32 connected - Only simulate CSI data in demo mode (was already correct) Embedding Space: - Fixed projection: sparse 8-dim projection replaces cancelling sum - Auto-scaling normalizes point spread to fill canvas Cache busters bumped to v=5 on all imports. Co-Authored-By: claude-flow <ruv@ruv.net> * fix: centroid-based pose tracking for responsive limb movement Rewrites pose decoder from intensity-based to position-based tracking: - Arms now track toward motion centroid in each body zone - Elbow/wrist positions computed along shoulder→centroid vector - Legs track toward lower-body zone centroids - Smoothing reduced from 0.45 to 0.25 for responsiveness - Zone centroids blend 30% old / 70% new each frame 6 body zones with overlapping coverage: - Head (top 20%, center cols) - Left/Right Arm (rows 10-60%, outer cols) - Torso (rows 15-55%, center cols) - Left/Right Leg (rows 50-100%, half cols each) Hand openness now driven by arm spread distance + raise amount. Cache busters v=6. Co-Authored-By: claude-flow <ruv@ruv.net> * fix: remove duplicate lAnkleX/rAnkleX declarations in pose-decoder Stale code block from old intensity-based tracking was left behind, re-declaring variables already defined by centroid-based tracking. Co-Authored-By: claude-flow <ruv@ruv.net> * feat(demo): wire all 6 RuVector WASM attention mechanisms into pose fusion - Add WasmLinearAttention and WasmLocalGlobalAttention to browser ESM wrapper - Add 6 WASM utility functions (batch_normalize, pairwise_distances, etc.) - Extend CnnEmbedder to 6-stage pipeline: Flash → MHA → Hyperbolic → Linear → MoE → L+G - Use log-energy softmax blending across all 6 stages - Wire WASM cosine_similarity and normalize into FusionEngine - Add RuVector pipeline stats panel to UI (energy, refinement, pose impact) - Compute embedding-to-joint mapping stats without modifying joint positions - Center camera prompt with flexbox layout - Add cache busters v=12 Co-Authored-By: claude-flow <ruv@ruv.net> |
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|---|---|---|
| .. | ||
| components | ||
| config | ||
| mobile | ||
| observatory | ||
| pose-fusion | ||
| services | ||
| tests | ||
| utils | ||
| README.md | ||
| TEST_REPORT.md | ||
| app.js | ||
| index.html | ||
| observatory.html | ||
| pose-fusion.html | ||
| start-ui.sh | ||
| style.css | ||
| viz.html | ||
README.md
WiFi DensePose UI
A modular, modern web interface for the WiFi DensePose human tracking system. Provides real-time monitoring, WiFi sensing visualization, and pose estimation from CSI (Channel State Information).
Architecture
The UI follows a modular architecture with clear separation of concerns:
ui/
├── app.js # Main application entry point
├── index.html # HTML shell with tab structure
├── style.css # Complete CSS design system
├── config/
│ └── api.config.js # API endpoints and configuration
├── services/
│ ├── api.service.js # HTTP API client
│ ├── websocket.service.js # WebSocket connection manager
│ ├── websocket-client.js # Low-level WebSocket client
│ ├── pose.service.js # Pose estimation API wrapper
│ ├── sensing.service.js # WiFi sensing data service (live + simulation fallback)
│ ├── health.service.js # Health monitoring API wrapper
│ ├── stream.service.js # Streaming API wrapper
│ └── data-processor.js # Signal data processing utilities
├── components/
│ ├── TabManager.js # Tab navigation component
│ ├── DashboardTab.js # Dashboard with live system metrics
│ ├── SensingTab.js # WiFi sensing visualization (3D signal field, metrics)
│ ├── LiveDemoTab.js # Live pose detection with setup guide
│ ├── HardwareTab.js # Hardware configuration
│ ├── SettingsPanel.js # Settings panel
│ ├── PoseDetectionCanvas.js # Canvas-based pose skeleton renderer
│ ├── gaussian-splats.js # 3D Gaussian splat signal field renderer (Three.js)
│ ├── body-model.js # 3D body model
│ ├── scene.js # Three.js scene management
│ ├── signal-viz.js # Signal visualization utilities
│ ├── environment.js # Environment/room visualization
│ └── dashboard-hud.js # Dashboard heads-up display
├── utils/
│ ├── backend-detector.js # Auto-detect backend availability
│ ├── mock-server.js # Mock server for testing
│ └── pose-renderer.js # Pose rendering utilities
└── tests/
├── test-runner.html # Test runner UI
├── test-runner.js # Test framework and cases
└── integration-test.html # Integration testing page
Features
WiFi Sensing Tab
- 3D Gaussian-splat signal field visualization (Three.js)
- Real-time RSSI, variance, motion band, breathing band metrics
- Presence/motion classification with confidence scores
- Data source banner: green "LIVE - ESP32", yellow "RECONNECTING...", or red "SIMULATED DATA"
- Sparkline RSSI history graph
- "About This Data" card explaining CSI capabilities per sensor count
Live Demo Tab
- WebSocket-based real-time pose skeleton rendering
- Estimation Mode badge: green "Signal-Derived" or blue "Model Inference"
- Setup Guide panel showing what each ESP32 count provides:
- 1 ESP32: presence, breathing, gross motion
- 2-3 ESP32s: body localization, motion direction
- 4+ ESP32s + trained model: individual limb tracking, full pose
- Debug mode with log export
- Zone selection and force-reconnect controls
- Performance metrics sidebar (frames, uptime, errors)
Dashboard
- Live system health monitoring
- Real-time pose detection statistics
- Zone occupancy tracking
- System metrics (CPU, memory, disk)
- API status indicators
Hardware Configuration
- Interactive antenna array visualization
- Real-time CSI data display
- Configuration panels
- Hardware status monitoring
Data Sources
The sensing service (sensing.service.js) supports three connection states:
| State | Banner Color | Description |
|---|---|---|
| LIVE - ESP32 | Green | Connected to the Rust sensing server receiving real CSI data |
| RECONNECTING | Yellow (pulsing) | WebSocket disconnected, retrying (up to 20 attempts) |
| SIMULATED DATA | Red | Fallback to client-side simulation after 5+ failed reconnects |
Simulated frames include a _simulated: true marker so code can detect synthetic data.
Backends
Rust Sensing Server (primary)
The Rust-based wifi-densepose-sensing-server serves the UI and provides:
GET /health— server healthGET /api/v1/sensing/latest— latest sensing featuresGET /api/v1/vital-signs— vital sign estimates (HR/RR)GET /api/v1/model/info— RVF model container infoWS /ws/sensing— real-time sensing data streamWS /api/v1/stream/pose— real-time pose keypoint stream
Python FastAPI (legacy)
The original Python backend on port 8000 is still supported. The UI auto-detects which backend is available via backend-detector.js.
Quick Start
With Docker (recommended)
cd docker/
# Default: auto-detects ESP32 on UDP 5005, falls back to simulation
docker-compose up
# Force real ESP32 data
CSI_SOURCE=esp32 docker-compose up
# Force simulation (no hardware needed)
CSI_SOURCE=simulated docker-compose up
Open http://localhost:3000/ui/index.html
With local Rust binary
cd rust-port/wifi-densepose-rs
cargo build -p wifi-densepose-sensing-server --no-default-features
# Run with simulated data
../../target/debug/sensing-server --source simulated --tick-ms 100 --ui-path ../../ui --http-port 3000
# Run with real ESP32
../../target/debug/sensing-server --source esp32 --tick-ms 100 --ui-path ../../ui --http-port 3000
Open http://localhost:3000/ui/index.html
With Python HTTP server (legacy)
# Start FastAPI backend on port 8000
wifi-densepose start
# Serve the UI on port 3000
cd ui/
python -m http.server 3000
Pose Estimation Modes
| Mode | Badge | Requirements | Accuracy |
|---|---|---|---|
| Signal-Derived | Green | 1+ ESP32, no model needed | Presence, breathing, gross motion |
| Model Inference | Blue | 4+ ESP32s + trained .rvf model |
Full 17-keypoint COCO pose |
To use model inference, start the server with a trained model:
sensing-server --source esp32 --model path/to/model.rvf --ui-path ./ui
Configuration
API Configuration
Edit config/api.config.js:
export const API_CONFIG = {
BASE_URL: window.location.origin,
API_VERSION: '/api/v1',
WS_CONFIG: {
RECONNECT_DELAY: 5000,
MAX_RECONNECT_ATTEMPTS: 20,
PING_INTERVAL: 30000
}
};
Testing
Open tests/test-runner.html to run the test suite:
cd ui/
python -m http.server 3000
# Open http://localhost:3000/tests/test-runner.html
Test categories: API configuration, API service, WebSocket, pose service, health service, UI components, integration.
Styling
Uses a CSS design system with custom properties, dark/light mode, responsive layout, and component-based styling. Key variables in :root of style.css.
License
Part of the WiFi-DensePose system. See the main project LICENSE file.