History

arsen 3393c1e839 fix(rssi): correct parse_esp32_frame offsets + carry RSSI through feature_state Two server-side parsers (csi.rs::parse_esp32_frame and the duplicate in main.rs) read every field after `n_antennas` from offsets shifted by 2 bytes — n_subcarriers as u8 instead of u16, sequence at 10..14 instead of 12..16, rssi at 14 instead of 16. The saturating_neg() workaround hid the bug by always forcing a negative dBm value, so the trace looked plausible but was actually a slice of mid-sequence number. ADR-100 D3 documented this as an open item; this commit closes it. Adds two regression tests in csi.rs (header-offset round-trip with distinctive values per field, plus 20-byte boundary case) so the layout contract can't drift again without CI catching it. Even with both parsers correct, RSSI never reached the UI because the firmware now ships only rv_feature_state_t (0xC5110006) — raw CSI (0xC5110001) is no longer hot. rv_feature_state had no RSSI field; both parsers fell back to rssi: -50 hardcode. To fix without a protocol bump: repurpose the first byte of the trailing `reserved` field (offset 54) as `int8_t rssi_dbm`. Firmware fills it from radio_ops::get_health()::rssi_median_dbm in emit_feature_state. Server reads buf[54] as i8; 0 means "not measured yet" → keeps the historical -50 fallback for backward compat with pre-update nodes. Verified live on TP-Link WISP (192.168.0.100/101): node 1: -54 dBm node 2: -63 dBm (was plateau -50.0 fallback) Co-Authored-By: claude-flow <ruv@ruv.net>		2026-05-17 02:20:25 +07:00
..
nvsim	feat(nvsim): full simulator stack — Rust crate, dashboard, server, App Store, Ghost Murmur [ADR-089/090/091/092/093]	2026-04-27 12:41:01 -04:00
nvsim-server	fix(ci): wasm-pack PATH + Dockerfile workspace stub (#440 )	2026-04-27 12:49:03 -04:00
ruv-neural	chore(repo): rename rust-port/wifi-densepose-rs → v2/ (flatten to one level) (#427 )	2026-04-25 21:28:13 -04:00
wifi-densepose-api	chore(repo): rename rust-port/wifi-densepose-rs → v2/ (flatten to one level) (#427 )	2026-04-25 21:28:13 -04:00
wifi-densepose-cli	chore(repo): rename rust-port/wifi-densepose-rs → v2/ (flatten to one level) (#427 )	2026-04-25 21:28:13 -04:00
wifi-densepose-config	chore(repo): rename rust-port/wifi-densepose-rs → v2/ (flatten to one level) (#427 )	2026-04-25 21:28:13 -04:00
wifi-densepose-core	chore(repo): rename rust-port/wifi-densepose-rs → v2/ (flatten to one level) (#427 )	2026-04-25 21:28:13 -04:00
wifi-densepose-db	chore(repo): rename rust-port/wifi-densepose-rs → v2/ (flatten to one level) (#427 )	2026-04-25 21:28:13 -04:00
wifi-densepose-desktop	deploy: tp-link wisp ap + rssi-Δ presence detector + live calibration ui	2026-05-15 11:26:07 +07:00
wifi-densepose-geo	chore(repo): rename rust-port/wifi-densepose-rs → v2/ (flatten to one level) (#427 )	2026-04-25 21:28:13 -04:00
wifi-densepose-hardware	fix(hardware): aggregator tolerates sibling RuView UDP packet magics (#517 )	2026-05-11 10:48:00 -04:00
wifi-densepose-mat	chore(repo): rename rust-port/wifi-densepose-rs → v2/ (flatten to one level) (#427 )	2026-04-25 21:28:13 -04:00
wifi-densepose-nn	chore(repo): rename rust-port/wifi-densepose-rs → v2/ (flatten to one level) (#427 )	2026-04-25 21:28:13 -04:00
wifi-densepose-pointcloud	fix(pointcloud): exponential backoff on unreachable backend + status banner	2026-04-29 23:03:05 -04:00
wifi-densepose-ruvector	feat(ruvector,signal,sensing-server): ADR-084 Passes 1/1.5/2/3 — RaBitQ similarity sensor implementation (#435 )	2026-04-26 02:21:35 -04:00
wifi-densepose-sensing-server	fix(rssi): correct parse_esp32_frame offsets + carry RSSI through feature_state	2026-05-17 02:20:25 +07:00
wifi-densepose-signal	feat(ruvector,signal,sensing-server): ADR-084 Passes 1/1.5/2/3 — RaBitQ similarity sensor implementation (#435 )	2026-04-26 02:21:35 -04:00
wifi-densepose-train	chore(release): wifi-densepose-train 0.3.0 -> 0.3.1	2026-05-11 23:59:50 -04:00
wifi-densepose-vitals	chore(repo): rename rust-port/wifi-densepose-rs → v2/ (flatten to one level) (#427 )	2026-04-25 21:28:13 -04:00
wifi-densepose-wasm	chore(repo): rename rust-port/wifi-densepose-rs → v2/ (flatten to one level) (#427 )	2026-04-25 21:28:13 -04:00
wifi-densepose-wasm-edge	feat(nvsim): full simulator stack — Rust crate, dashboard, server, App Store, Ghost Murmur [ADR-089/090/091/092/093]	2026-04-27 12:41:01 -04:00
wifi-densepose-wifiscan	chore(repo): move v1/ → archive/v1/ + add archive/README.md (#430 )	2026-04-25 23:07:52 -04:00
README.md	chore(repo): rename rust-port/wifi-densepose-rs → v2/ (flatten to one level) (#427 )	2026-04-25 21:28:13 -04:00

README.md

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
`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

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.