wifi-densepose/v2/crates/wifi-densepose-sensing-server
ruv 0c311a202b feat(adr-110): SyncPacket::mesh_aligned_us_for_sequence (interpolation) + NodeState hook
Iter 17 — closes the per-frame mesh-time loop for ADR-018 CSI frames
that carry no per-frame local_us field (the v1 wire format reserves no
slot — see WITNESS-LOG-110 §A0.11).

Math: pair the frame's sequence number against the sync packet's
sequence high-water + an assumed CSI frame rate. Δframes × 1/fps
estimates the node-local delta from the sync, then apply_to_local
recovers the mesh epoch.

  SyncPacket::mesh_aligned_us_for_sequence(frame_seq: u32, fps_hz: f64) -> u64

3 new unit tests (13 total in sync_packet::tests, all green):
  * mesh_aligned_for_sequence_identity_at_sync_point — at sync.sequence
    returns sync.epoch_us exactly
  * mesh_aligned_for_sequence_extrapolates_forward — 20 frames @ 20 fps
    extrapolates by exactly 1 s
  * mesh_aligned_for_sequence_handles_seq_wraparound — u32 sequence
    wrap doesn't jump backward by 2^32 (wrapping_sub guards it)

NodeState hook:
  NodeState::mesh_aligned_us_for_csi_frame(frame_sequence: u32) -> Option<u64>
    Wraps the SyncPacket method, defaults fps_hz=20.0 (matches the
    firmware's CSI_MIN_SEND_INTERVAL_US-implied ceiling), enforces the
    same 9 s staleness gate as mesh_aligned_us.

cargo check -p wifi-densepose-sensing-server --no-default-features → green.
cargo test -p wifi-densepose-hardware sync_packet → 13/13, 122 filtered.

Downstream ADR-029/030 multistatic fusion code can now do:
  if frame.adr018_flags.ieee802154_sync_valid {
      if let Some(mesh_us) = ns.mesh_aligned_us_for_csi_frame(frame.sequence) {
          // pair this frame with frames from sibling nodes by mesh_us
      }
  }

Co-Authored-By: claude-flow <ruv@ruv.net>
2026-05-23 13:19:06 -04:00
..
src feat(adr-110): SyncPacket::mesh_aligned_us_for_sequence (interpolation) + NodeState hook 2026-05-23 13:19:06 -04:00
tests feat(introspection): I6 — regime-changed signal + per-frame analyze + honest ADR-099 D8 amendment 2026-05-13 23:29:37 -04:00
Cargo.toml feat(sensing-server): consume ADR-110 §A0.12 sync packets, store per-node 2026-05-23 13:11:35 -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-sensing-server

Crates.io Documentation License

Lightweight Axum server for real-time WiFi sensing with RuVector signal processing.

Overview

wifi-densepose-sensing-server is the operational backend for WiFi-DensePose. It receives raw CSI frames from ESP32 hardware over UDP, runs them through the RuVector-powered signal processing pipeline, and broadcasts processed sensing updates to browser clients via WebSocket. A built-in static file server hosts the sensing UI on the same port.

The crate ships both a library (wifi_densepose_sensing_server) exposing the training and inference modules, and a binary (sensing-server) that starts the full server stack.

Integrates wifi-densepose-wifiscan for multi-BSSID WiFi scanning per ADR-022 Phase 3.

Features

  • UDP CSI ingestion -- Receives ESP32 CSI frames on port 5005 and parses them into the internal CsiFrame representation.
  • Vital sign detection -- Pure-Rust FFT-based breathing rate (0.1--0.5 Hz) and heart rate (0.67--2.0 Hz) estimation from CSI amplitude time series (ADR-021).
  • RVF container -- Standalone binary container format for packaging model weights, metadata, and configuration into a single .rvf file with 64-byte aligned segments.
  • RVF pipeline -- Progressive model loading with streaming segment decoding.
  • Graph Transformer -- Cross-attention bottleneck between antenna-space CSI features and the COCO 17-keypoint body graph, followed by GCN message passing (ADR-023 Phase 2). Pure std, no ML dependencies.
  • SONA adaptation -- LoRA + EWC++ online adaptation for environment drift without catastrophic forgetting (ADR-023 Phase 5).
  • Contrastive CSI embeddings -- Self-supervised SimCLR-style pretraining with InfoNCE loss, projection head, fingerprint indexing, and cross-modal pose alignment (ADR-024).
  • Sparse inference -- Activation profiling, sparse matrix-vector multiply, INT8/FP16 quantization, and a full sparse inference engine for edge deployment (ADR-023 Phase 6).
  • Dataset pipeline -- Training dataset loading and batching.
  • Multi-BSSID scanning -- Windows netsh integration for BSSID discovery via wifi-densepose-wifiscan (ADR-022).
  • WebSocket broadcast -- Real-time sensing updates pushed to all connected clients at ws://localhost:8765/ws/sensing.
  • Static file serving -- Hosts the sensing UI on port 8080 with CORS headers.

Modules

Module Description
vital_signs Breathing and heart rate extraction via FFT spectral analysis
rvf_container RVF binary format builder and reader
rvf_pipeline Progressive model loading from RVF containers
graph_transformer Graph Transformer + GCN for CSI-to-pose estimation
trainer Training loop orchestration
dataset Training data loading and batching
sona LoRA adapters and EWC++ continual learning
sparse_inference Neuron profiling, sparse matmul, INT8/FP16 quantization
embedding Contrastive CSI embedding model and fingerprint index

Quick Start

# Build the server
cargo build -p wifi-densepose-sensing-server

# Run with default settings (HTTP :8080, UDP :5005, WS :8765)
cargo run -p wifi-densepose-sensing-server

# Run with custom ports
cargo run -p wifi-densepose-sensing-server -- \
    --http-port 9000 \
    --udp-port 5005 \
    --static-dir ./ui

Using as a library

use wifi_densepose_sensing_server::vital_signs::VitalSignDetector;

// Create a detector with 20 Hz sample rate
let mut detector = VitalSignDetector::new(20.0);

// Feed CSI amplitude samples
for amplitude in csi_amplitudes.iter() {
    detector.push_sample(*amplitude);
}

// Extract vital signs
if let Some(vitals) = detector.detect() {
    println!("Breathing: {:.1} BPM", vitals.breathing_rate_bpm);
    println!("Heart rate: {:.0} BPM", vitals.heart_rate_bpm);
}

Architecture

ESP32 ──UDP:5005──> [ CSI Receiver ]
                          |
                    [ Signal Pipeline ]
                    (vital_signs, graph_transformer, sona)
                          |
                    [ WebSocket Broadcast ]
                          |
Browser <──WS:8765── [ Axum Server :8080 ] ──> Static UI files
Crate Role
wifi-densepose-wifiscan Multi-BSSID WiFi scanning (ADR-022)
wifi-densepose-core Shared types and traits
wifi-densepose-signal CSI signal processing algorithms
wifi-densepose-hardware ESP32 hardware interfaces
wifi-densepose-wasm Browser WASM bindings for the sensing UI
wifi-densepose-train Full training pipeline with ruvector
wifi-densepose-mat Disaster detection module

License

MIT OR Apache-2.0