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* feat(ADR-262 P3): live RuField surface — RuView sensing speaks RuField on /api/field + /ws/field Wire the P1 `wifi-densepose-rufield` bridge into the live `wifi-densepose-sensing-server` so the governed sensing cycle emits real signed RuField `FieldEvent`s on two additive endpoints. - Cargo: add the `wifi-densepose-rufield` path dep (the single coupling point, ADR-262 §5.4 — no new RuView-internal coupling). - New `src/rufield_surface.rs` (kept out of the 8k-line main.rs): `FieldSurface` holds a dedicated ed25519 `Signer` + a bounded ring of recent events + the `/ws/field` broadcast topic; `GET /api/field` and `GET /ws/field` handlers; a standalone `router()` for isolated testing. - Signer (defers the P2 key decision, ADR-262 §8 Q1): a STANDALONE dev/sensing key from `WDP_RUFIELD_SIGNING_SEED`, else a deterministic dev default with a logged WARN. Reusing the `cog-ha-matter` Ed25519 key is the deferred P2 call — P3 does not pre-empt it. - Tap: at the ESP32 governed-trust cycle (`main.rs` ~5886 observe_cycle / ~5938 SensingUpdate build), `emit_rufield_event` joins the cycle's features/classification/signal_field with the engine's effective_class/demoted trust state into a `SensingSnapshot` and surfaces it via the bridge. Existing endpoints (`/ws/sensing` etc.) are unchanged — purely additive. - Privacy egress: `network_egress_allowed` is fail-closed for an unattended live surface — only P1/P2 leave the box; P0 raw and P3/P4/P5 (identity/biometric/aggregate) are held edge-local. A `Derived` cycle maps to P4/P5 and never surfaces. - No-phantom: `emit` drops no-presence cycles (no fabricated events). Gates (tests/rufield_surface_test.rs, tower::oneshot, 4/0): well-formed signed event (WifiCsi, P2 not P1, is_fusable, real timestamp); empty cycle → no phantom; Derived trust never surfaces; mixed stream surfaces only egress-safe events. Honesty (ADR-262 §0/§6): real plumbing on a live endpoint, NOT accuracy. Single-link CSI with its existing caveats (no validated room-coordinate accuracy); dedicated dev signing key pending the P2 ownership decision; no accuracy claim. Co-Authored-By: claude-flow <ruv@ruv.net> * docs(ADR-262 P3): mark P1+P3 implemented; document /api/field + /ws/field; CHANGELOG - ADR-262 Status → "P1 + P3 implemented"; add a P3 implementation-status block (tap site, endpoints, dedicated dev signer deferring the §8 Q1 key decision, fail-closed egress, gates). Keep the honesty framing: real plumbing on a live endpoint, not accuracy. - CHANGELOG [Unreleased]: add the ADR-262 P3 entry. - user-guide: add `/api/field` to the REST table + a "RuField surface (ADR-262 P3)" section covering `/api/field` + `/ws/field`, the fail-closed P1/P2-only egress, the WDP_RUFIELD_SIGNING_SEED dev key, and the no-accuracy honesty note. Co-Authored-By: claude-flow <ruv@ruv.net> * ci: checkout submodules everywhere + Dockerfile copies vendor/rufield Making wifi-densepose-rufield (ADR-262 bridge) a v2 workspace member means EVERY cargo-on-workspace context must have the vendor/rufield submodule present (cargo loads all member manifests). P1 only fixed the rust-tests job; this adds `submodules: recursive` to all workflow checkouts that run cargo (mqtt-integration was failing on the missing submodule manifest), and makes Dockerfile.rust COPY vendor/rufield/ to /vendor/rufield (matches the bridge's ../../../vendor/rufield path-dep under the collapsed Docker layout). update-submodules.yml left alone (it manages submodules itself). Co-Authored-By: claude-flow <ruv@ruv.net> --------- Co-authored-by: ruv <ruvnet@gmail.com>
WiFi-DensePose Rust Crates
See through walls with WiFi. No cameras. No wearables. Just radio waves.
A modular Rust workspace for WiFi-based human pose estimation, vital sign monitoring, and disaster response using Channel State Information (CSI). Built on RuVector graph algorithms and the WiFi-DensePose research platform by rUv.
Performance
| Operation | Python v1 | Rust v2 | Speedup |
|---|---|---|---|
| CSI Preprocessing | ~5 ms | 5.19 us | ~1000x |
| Phase Sanitization | ~3 ms | 3.84 us | ~780x |
| Feature Extraction | ~8 ms | 9.03 us | ~890x |
| Motion Detection | ~1 ms | 186 ns | ~5400x |
| Full Pipeline | ~15 ms | 18.47 us | ~810x |
| Vital Signs | N/A | 86 us (11,665 fps) | -- |
Crate Overview
Core Foundation
| Crate | Description | crates.io |
|---|---|---|
wifi-densepose-core |
Types, traits, and utilities (CsiFrame, PoseEstimate, SignalProcessor) |
|
wifi-densepose-config |
Configuration management (env, TOML, YAML) | |
wifi-densepose-db |
Database persistence (PostgreSQL, SQLite, Redis) |
Signal Processing & Sensing
| Crate | Description | RuVector Integration | crates.io |
|---|---|---|---|
wifi-densepose-signal |
SOTA CSI signal processing (6 algorithms from SpotFi, FarSense, Widar 3.0) | ruvector-mincut, ruvector-attn-mincut, ruvector-attention, ruvector-solver |
|
wifi-densepose-vitals |
Vital sign extraction: breathing (6-30 BPM) and heart rate (40-120 BPM) | -- | |
wifi-densepose-wifiscan |
Multi-BSSID WiFi scanning for Windows-enhanced sensing | -- |
Neural Network & Training
| Crate | Description | RuVector Integration | crates.io |
|---|---|---|---|
wifi-densepose-nn |
Multi-backend inference (ONNX, PyTorch, Candle) with DensePose head (24 body parts) | -- | |
wifi-densepose-train |
Training pipeline with MM-Fi dataset, 114->56 subcarrier interpolation | All 5 crates |
Disaster Response
| Crate | Description | RuVector Integration | crates.io |
|---|---|---|---|
wifi-densepose-mat |
Mass Casualty Assessment Tool -- survivor detection, triage, multi-AP localization | ruvector-solver, ruvector-temporal-tensor |
Hardware & Deployment
| Crate | Description | crates.io |
|---|---|---|
wifi-densepose-hardware |
ESP32, Intel 5300, Atheros CSI sensor interfaces (pure Rust, no FFI) | |
wifi-densepose-wasm |
WebAssembly bindings for browser-based disaster dashboard | |
wifi-densepose-sensing-server |
Axum server: ESP32 UDP ingestion, WebSocket broadcast, sensing UI |
Applications
| Crate | Description | crates.io |
|---|---|---|
wifi-densepose-api |
REST + WebSocket API layer | |
wifi-densepose-cli |
Command-line tool for MAT disaster scanning |
Architecture
wifi-densepose-core
(types, traits, errors)
|
+-------------------+-------------------+
| | |
wifi-densepose-signal wifi-densepose-nn wifi-densepose-hardware
(CSI processing) (inference) (ESP32, Intel 5300)
+ ruvector-mincut + ONNX Runtime |
+ ruvector-attn-mincut + PyTorch (tch) wifi-densepose-vitals
+ ruvector-attention + Candle (breathing, heart rate)
+ ruvector-solver |
| | wifi-densepose-wifiscan
+--------+---------+ (BSSID scanning)
|
+------------+------------+
| |
wifi-densepose-train wifi-densepose-mat
(training pipeline) (disaster response)
+ ALL 5 ruvector + ruvector-solver
+ ruvector-temporal-tensor
|
+-----------------+-----------------+
| | |
wifi-densepose-api wifi-densepose-wasm wifi-densepose-cli
(REST/WS) (browser WASM) (CLI tool)
|
wifi-densepose-sensing-server
(Axum + WebSocket)
RuVector Integration
All RuVector crates at v2.0.4 from crates.io:
| RuVector Crate | Used In | Purpose |
|---|---|---|
ruvector-mincut |
signal, train | Dynamic min-cut for subcarrier selection & person matching |
ruvector-attn-mincut |
signal, train | Attention-weighted min-cut for antenna gating & spectrograms |
ruvector-temporal-tensor |
train, mat | Tiered temporal compression (4-10x memory reduction) |
ruvector-solver |
signal, train, mat | Sparse Neumann solver for interpolation & triangulation |
ruvector-attention |
signal, train | Scaled dot-product attention for spatial features & BVP |
Signal Processing Algorithms
Six state-of-the-art algorithms implemented in wifi-densepose-signal:
| Algorithm | Paper | Year | Module |
|---|---|---|---|
| Conjugate Multiplication | SpotFi (SIGCOMM) | 2015 | csi_ratio.rs |
| Hampel Filter | WiGest | 2015 | hampel.rs |
| Fresnel Zone Model | FarSense (MobiCom) | 2019 | fresnel.rs |
| CSI Spectrogram | Standard STFT | 2018+ | spectrogram.rs |
| Subcarrier Selection | WiDance (MobiCom) | 2017 | subcarrier_selection.rs |
| Body Velocity Profile | Widar 3.0 (MobiSys) | 2019 | bvp.rs |
Quick Start
As a Library
use wifi_densepose_core::{CsiFrame, CsiMetadata, SignalProcessor};
use wifi_densepose_signal::{CsiProcessor, CsiProcessorConfig};
// Configure the CSI processor
let config = CsiProcessorConfig::default();
let processor = CsiProcessor::new(config);
// Process a CSI frame
let frame = CsiFrame { /* ... */ };
let processed = processor.process(&frame)?;
Vital Sign Monitoring
use wifi_densepose_vitals::{
CsiVitalPreprocessor, BreathingExtractor, HeartRateExtractor,
VitalAnomalyDetector,
};
let mut preprocessor = CsiVitalPreprocessor::new(56); // 56 subcarriers
let mut breathing = BreathingExtractor::new(100.0); // 100 Hz sample rate
let mut heartrate = HeartRateExtractor::new(100.0);
// Feed CSI frames and extract vitals
for frame in csi_stream {
let residuals = preprocessor.update(&frame.amplitudes);
if let Some(bpm) = breathing.push_residuals(&residuals) {
println!("Breathing: {:.1} BPM", bpm);
}
}
Disaster Response (MAT)
use wifi_densepose_mat::{DisasterResponse, DisasterConfig, DisasterType};
let config = DisasterConfig {
disaster_type: DisasterType::Earthquake,
max_scan_zones: 16,
..Default::default()
};
let mut responder = DisasterResponse::new(config);
responder.add_scan_zone(zone)?;
responder.start_continuous_scan().await?;
Hardware (ESP32)
use wifi_densepose_hardware::{Esp32CsiParser, CsiFrame};
let parser = Esp32CsiParser::new();
let raw_bytes: &[u8] = /* UDP packet from ESP32 */;
let frame: CsiFrame = parser.parse(raw_bytes)?;
println!("RSSI: {} dBm, {} subcarriers", frame.metadata.rssi, frame.subcarriers.len());
Training
# Check training crate (no GPU needed)
cargo check -p wifi-densepose-train --no-default-features
# Run training with GPU (requires tch/libtorch)
cargo run -p wifi-densepose-train --features tch-backend --bin train -- \
--config training.toml --dataset /path/to/mmfi
# Verify deterministic training proof
cargo run -p wifi-densepose-train --features tch-backend --bin verify-training
Building
# Clone the repository
git clone https://github.com/ruvnet/wifi-densepose.git
cd wifi-densepose/v2
# Check workspace (no GPU dependencies)
cargo check --workspace --no-default-features
# Run all tests
cargo test --workspace --no-default-features
# Build release
cargo build --release --workspace
Feature Flags
| Crate | Feature | Description |
|---|---|---|
wifi-densepose-nn |
onnx (default) |
ONNX Runtime backend |
wifi-densepose-nn |
tch-backend |
PyTorch (libtorch) backend |
wifi-densepose-nn |
candle-backend |
Candle (pure Rust) backend |
wifi-densepose-nn |
cuda |
CUDA GPU acceleration |
wifi-densepose-train |
tch-backend |
Enable GPU training modules |
wifi-densepose-mat |
ruvector (default) |
RuVector graph algorithms |
wifi-densepose-mat |
api (default) |
REST + WebSocket API |
wifi-densepose-mat |
distributed |
Multi-node coordination |
wifi-densepose-mat |
drone |
Drone-mounted scanning |
wifi-densepose-hardware |
esp32 |
ESP32 protocol support |
wifi-densepose-hardware |
intel5300 |
Intel 5300 CSI Tool |
wifi-densepose-hardware |
linux-wifi |
Linux commodity WiFi |
wifi-densepose-wifiscan |
wlanapi |
Windows WLAN API async scanning |
wifi-densepose-core |
serde |
Serialization support |
wifi-densepose-core |
async |
Async trait support |
Testing
# Unit tests (all crates)
cargo test --workspace --no-default-features
# Signal processing benchmarks
cargo bench -p wifi-densepose-signal
# Training benchmarks
cargo bench -p wifi-densepose-train --no-default-features
# Detection benchmarks
cargo bench -p wifi-densepose-mat
Supported Hardware
| Hardware | Crate Feature | CSI Subcarriers | Cost |
|---|---|---|---|
| ESP32-S3 Mesh (3-6 nodes) | hardware/esp32 |
52-56 | ~$54 |
| Intel 5300 NIC | hardware/intel5300 |
30 | ~$50 |
| Atheros AR9580 | hardware/linux-wifi |
56 | ~$100 |
| Any WiFi (Windows/Linux) | wifiscan |
RSSI-only | $0 |
Architecture Decision Records
Key design decisions documented in docs/adr/:
| ADR | Title | Status |
|---|---|---|
| ADR-014 | SOTA Signal Processing | Accepted |
| ADR-015 | MM-Fi + Wi-Pose Training Datasets | Accepted |
| ADR-016 | RuVector Training Pipeline | Accepted (Complete) |
| ADR-017 | RuVector Signal + MAT Integration | Accepted |
| ADR-021 | Vital Sign Detection Pipeline | Accepted |
| ADR-022 | Windows WiFi Enhanced Sensing | Accepted |
| ADR-024 | Contrastive CSI Embedding Model | Accepted |
Related Projects
- WiFi-DensePose -- Main repository (Python v1 + Rust v2)
- RuVector -- Graph algorithms for neural networks (5 crates, v2.0.4)
- rUv -- Creator and maintainer
License
All crates are dual-licensed under MIT OR Apache-2.0.
Copyright (c) 2024 rUv