Wideband autonomous SDR analysis engine forked from sdr-visual-suite

Jan Svabenik d045bfaac0 Update web audio player (v3 patch)		1日前
cmd/sdrd	fix: eliminate live audio clicks (buffer bloat + decimation phase + resampler BW)	1日前
docs	Remove obsolete Windows build scripts	5日前
internal	fix: eliminate live audio clicks (buffer bloat + decimation phase + resampler BW)	1日前
tools	Attempt MinGW-host CUDA build path for Windows	5日前
web	Update web audio player (v3 patch)	1日前
.gitignore	Add structured logging with categories and rate limiting	1日前
PLAN.md	docs: capture Phase-4 monitor-window status	2日前
README.md	docs: capture Phase-4 monitor-window status	2日前
ROADMAP.md	fix: use stable signals for live audio streaming	2日前
STATE.md	docs: persist roadmap and current state	2日前
TODO.md	Expand todo list with band profiles plan	3日前
build-cuda-linux.sh	docs: split CUDA build paths by platform	5日前
build-cuda-windows.ps1	Add Windows gpudemod DLL build path	5日前
build-gpudemod-dll.ps1	Use hybrid CUDA runtime for gpudemod DLL	5日前
build-sdrplay.ps1	Checkpoint current working SDR pipeline state	4日前
config.yaml	Update web audio player (v3 patch)	1日前
go.mod	Add structured logging with categories and rate limiting	1日前
go.sum	Add structured logging with categories and rate limiting	1日前
start-sdr.ps1	Add start script	6日前

README.md

SDR Wideband Suite

Go-based SDR analysis engine and live spectrum/waterfall UI, evolved from the original sdr-visual-suite into a more scalable foundation for wideband monitoring, candidate-driven refinement, classification, and demod/recording.

Features

Live spectrum + waterfall web UI (WebSocket streaming)
Event timeline view (time vs frequency) + detail drawer
Live signal list + classifier insights
Runtime UI controls: center, span, sample rate, tuner bandwidth, analysis FFT size, gain, AGC, DC block, IQ balance, detector settings
Optional GPU FFT (cuFFT) + /api/gpu
IQ/audio recording + recordings list
Live demod endpoint + WebSocket live-listen audio
WFM stereo + RDS baseband
Mock mode for testing without hardware
Phase-1 architecture foundation complete: explicit pipeline/surveillance/refinement/resources config model plus candidate/refinement/admission scaffolding
Phase-2 milestone complete: multi-resolution surveillance levels, derived detection governance, support levels, and fused candidate evidence summaries
Phase-3 milestone complete: conservative runtime prioritization/admission/pressure/hold/displacement/rebalance behavior across refinement, record, and decode

Requirements

Core

Go 1.22 (see go.mod)

Optional (real device)

SDRplay API (sdrplay_api.h + library)

Optional (GPU)

CUDA toolkit (cuFFT)
nvcc for kernel build (Linux) or build-gpudemod-dll.ps1 (Windows)

Windows build prerequisites (real device + GPU)

MSYS2 MinGW64 (C:\msys64\mingw64\bin\gcc.exe / g++.exe) for CGO
SDRplay API installed (default path in scripts)
CUDA toolkit (default paths in scripts)

Quick Start (Mock Mode)

# From repo root

go run ./cmd/sdrd --mock

Open http://localhost:8080.

Configuration

Edit config.yaml (autosave goes to config.autosave.yaml).

Legacy-compatible core fields

center_hz, sample_rate, fft_size, gain_db, tuner_bw_khz
use_gpu_fft, agc, dc_block, iq_balance
detector.*
recorder.*
decoder.*

Phase-1 pipeline fields

pipeline.mode -- operating mode label (legacy, wideband-balanced, ...)
pipeline.profile -- last applied operating profile name (if any)
pipeline.goals.* -- declarative target/intent layer for future autonomous operation
- intent
- monitor_start_hz / monitor_end_hz / monitor_span_hz
- monitor_windows -- optional list of monitor windows (each window uses start_hz + end_hz or center_hz + span_hz, plus optional label, zone, priority, auto_record, auto_decode)
- signal_priorities
- auto_record_classes
- auto_decode_classes
surveillance.analysis_fft_size -- analysis FFT size used by the surveillance layer
surveillance.frame_rate -- surveillance cadence target
surveillance.strategy -- single-resolution or multi-resolution
surveillance.display_bins -- preferred presentation density for clients/UI
surveillance.display_fps -- preferred presentation cadence for clients/UI
surveillance.derived_detection -- auto, on, or off (governs derived detection vs support-only levels)
refinement.enabled -- enables explicit candidate refinement stage
refinement.max_concurrent -- refinement budget hint
refinement.detail_fft_size -- FFT size for refinement/detail path (defaults to surveillance analysis FFT)
refinement.min_candidate_snr_db -- floor for future scheduling decisions
refinement.min_span_hz / refinement.max_span_hz -- clamp refinement window span (0 = no clamp)
refinement.auto_span -- use mod-type heuristics when candidate bandwidth is missing/odd
resources.prefer_gpu -- GPU preference hint

Operating profiles (wideband)

wideband-balanced: multi-resolution, 4096 surveillance/detail FFT, refinement span 4000-200000 Hz
wideband-aggressive: multi-resolution, 8192 surveillance/detail FFT, refinement span 6000-250000 Hz
archive: record-forward bias, higher record/decode budgets, 4096 detail FFT
digital-hunting: digital-first priorities and decode bias
resources.max_refinement_jobs -- processing budget hint
resources.max_recording_streams -- recording/streaming budget hint
resources.max_decode_jobs -- decode budget hint
resources.decision_hold_ms -- baseline hold time for queue slots before churn (arbitration scales per profile/strategy and tags hold reasons in debug snapshots)
profiles[] -- named operating profiles/intent metadata

Phase 1 stays backward compatible, but the config model now reflects the intended separation between:

acquisition
surveillance analysis
local refinement
resource policy
presentation
operator goals / future autonomous intent

Refinement plans now rank candidates, while a shared arbitration step admits refinement/record/decode work based on budgets and hold policy. Arbitration reasons are normalized:

refinement:* for work item lifecycle (planned/admitted/running/completed/drop/skip)
admission:* for refinement admission outcomes
decision:* for record/decode decisions
queue:* when record/decode is deferred by budget Hold policy reasons are surfaced as profile:* / strategy:* tokens in hold_source.

Phase-1 scope stops at consistent policy surfaces, ranking/admission scaffolding, and debug visibility. Phase 2+ adds a true multi-resolution surveillance engine and scheduler/intent overrides that can re-balance budgets automatically.

Phase-2 status (Wave E):

derived detection policy now reports detection vs support-only vs disabled
fused candidate evidence summaries expose role/kind detail
surveillance level summaries include role intent for easier debug

Phase-3 status (Wave 3E):

scheduler/arbitration layer for refinement + record/decode admission
hold/displacement policy with normalized reason tags
budget pressure summaries and decision queue stats (including displaced-by-hold counters)
conservative cross-resource rebalance (refinement/record/decode) with profile/intent-aware protections
rebalance state and reasons surfaced in arbitration/debug snapshots

The long-term target is that you describe what the system should do (for example broad-span monitoring intent, preferred signal families, auto-record/decode priorities), while the engine decides how to allocate surveillance, refinement and decoding budgets.

Phase-4 status (monitor-window operating model): monitor_windows gates candidates inside a capture span, supports overlapping windows with priority/zone bias, and can auto-record/decode per window without retuning. Window stats + summaries now surface in /api/refinement, and decision/admission reasons include window tags/zone tags for traceability.

CFAR modes: OFF, CA, OS, GOSCA, CASO

Build & Run (Windows)

Mock / No SDRplay

go build ./cmd/sdrd
.\sdrd.exe --mock

SDRplay (Real Device)

$env:CGO_CFLAGS='-IC:\Program Files\SDRplay\API\inc'
$env:CGO_LDFLAGS='-LC:\Program Files\SDRplay\API\x64 -lsdrplay_api'

go build -tags sdrplay ./cmd/sdrd
.\sdrd.exe -config config.yaml

Windows (GPU + SDRplay) -- recommended path

powershell -ExecutionPolicy Bypass -File .\build-cuda-windows.ps1
powershell -ExecutionPolicy Bypass -File .\build-sdrplay.ps1

This path:

Builds gpudemod_kernels.dll (MSVC/nvcc)
Builds Go app with MinGW64 CGO + tags sdrplay,cufft
Copies CUDA runtime DLLs next to sdrd.exe

Notes:

build-sdrplay.ps1 expects MinGW at C:\msys64\mingw64\bin
CUDA DLLs are copied if found (see script for exact paths)
Override the GPU DLL path with GPUMOD_DLL=C:\path\to\gpudemod_kernels.dll

Build & Run (Linux)

SDRplay (Real Device)

export CGO_CFLAGS='-I/opt/sdrplay_api/include'
export CGO_LDFLAGS='-L/opt/sdrplay_api/lib -lsdrplay_api'

go build -tags sdrplay ./cmd/sdrd
./cmd/sdrd/sdrd -config config.yaml

CUDA kernel build (GPU demod)

./build-cuda-linux.sh

APIs

Config

GET /api/config
POST /api/config
POST /api/sdr/settings
GET /api/gpu
GET /api/pipeline/policy
GET /api/pipeline/recommendations
GET /api/refinement -> latest refinement plan/windows snapshot (includes window_stats, levels, request/context/work_items, plus arbitration with budgets/hold policy/refinement admission/queue/decision summary)

Signals / Events

GET /api/signals -> current live signals
GET /api/events?limit=&since= -> recent events

Recordings

GET /api/recordings
GET /api/recordings/:id (meta.json)
GET /api/recordings/:id/iq
GET /api/recordings/:id/audio
GET /api/recordings/:id/decode?mode=FT8|WSPR|DMR|D-STAR|FSK|PSK

Live Demod / Listen

GET /api/demod?freq=...&bw=...&mode=...&sec=... -> audio/wav
WS /ws/audio?freq=...&bw=...&mode=... -> live PCM audio stream

Decoder Tools

Put external decoder binaries/scripts under tools/ and configure decoder.* in config.yaml. Placeholders: {iq}, {audio}, {sr}. See tools/README.md for examples.

Tests

go test ./...

Troubleshooting

sdrplay support not built -> rebuild with -tags sdrplay.
SDRplay library not found -> check CGO_CFLAGS / CGO_LDFLAGS.
GPU demod not loading -> verify gpudemod_kernels.dll / cudart64_13.dll next to sdrd.exe (Windows).
Use --mock to run without hardware.