Bootstrap of the project (M0). Sets up the monorepo, design docs, hardware BOM, the open API contract, component skeletons, licensing and CI, following the Default Workflow SOP. What changed: - CLAUDE.md + docs/: copied the Default Workflow so sessions load the SOP. - state/: PROJECT, ARCHITECTURE, DECISIONS, TODO, NOTES filled in for OpenScribe. ARCHITECTURE captures the four-part design (firmware, server, app, case) and the three sync paths; DECISIONS records the hardware, AI-stack, storage, app and licensing choices; TODO lays out milestones M1-M9. - hardware/BOM.md: two build options (compact XIAO ESP32-S3 Sense; dev ESP32-S3 + I2S mic + SD), wiring/pinout, indicative cost. - api/openapi.yaml: the completely open API (device + server surfaces), including recording list/download/delete and exports (wav/ogg/txt/srt/vtt/md/json). - firmware/: PlatformIO ESP32-S3 project, two board profiles, pin map, boot scaffold with module seams for M1-M4. - server/: FastAPI skeleton mirroring the OpenAPI, config for self-hosted MinIO, faster-whisper and Ollama; stub routes browsable at /docs. - app/, case/: Flutter app plan; parametric OpenSCAD enclosure. - Licensing: GPL-3.0 (code), CERN-OHL-S-2.0 (hardware), CC-BY-SA-4.0 (case/docs), REUSE-style LICENSES/ with SPDX headers; LICENSING.md explains the split. - CI: Forgejo Actions workflow builds firmware (both profiles) and lints/imports server. Why: - Everything self-hosted and openly licensed per the user's requirements: an open API, three sync paths (BLE control, WiFi transfer, independent WiFi upload on charge to generic cloud storage), and a full self-hosted transcription+summary stack. Notes: - No custom PCB in v1; off-the-shelf modules. Physical verification waits on parts. - Component code is stubs at M0; features land milestone by milestone, each as its own branch/PR per the workflow. Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
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Decisions
A dated, append only log of decisions and their rationale. Newest at the top. Never rewrite past entries; if a decision is reversed, add a new entry that says so.
2026-07-03 - Licensing: copyleft, multi-part (REUSE-style)
- Decision: Code (firmware, server, app) under GPL-3.0-only; hardware design under
CERN-OHL-S-2.0; case models and documentation under CC-BY-SA-4.0. Licence texts live in
LICENSES/; top-levelLICENSEis GPL-3.0 for forge detection;LICENSING.mdexplains the split. Apache-2.0 text kept for a possible future permissive client SDK. - Context: User asked for "as open source as possible".
- Rationale: Strong copyleft keeps derivatives open (the point of the project); CERN and CC-BY-SA are the standard reciprocal licences for hardware and creative/docs.
- Consequences: Derivatives must stay open. If we later want wide third-party adoption of a client library, that specific component can be relicensed permissive (Apache-2.0).
2026-07-03 - Self-hosted tools throughout
- Decision: Forge = Forgejo (git.discworld.casa); CI = Forgejo Actions; STT = faster-whisper; summaries = Ollama (local LLM); object storage = MinIO (S3-compatible) or local FS / WebDAV. No required proprietary SaaS anywhere.
- Context: User: "using selfhosted tools where possible".
- Rationale: Matches the own-your-data goal and keeps running costs at zero beyond the user's own hardware.
- Consequences: User must run a server (NAS / mini-PC) for AI features; the device and app work without it for plain recording + transfer.
2026-07-03 - Self-hosted AI stack in scope for v1
- Decision: Build the full pipeline: record -> transcribe (faster-whisper) -> summarise (Ollama) -> export. AI runs on the server, not the device.
- Context: User chose "Full self-hosted AI stack" at the scope checkpoint.
- Rationale: Transcription + summary is Plaud's headline feature; server-side keeps the device cheap and low-power while staying fully self-hosted.
- Consequences: Larger build; server is required for AI features. Device stays simple.
2026-07-03 - Independent upload target: generic cloud storage
- Decision: When on charge / hard-powered, the device uploads to configurable generic storage: S3-compatible (default: self-hosted MinIO), with WebDAV/NAS as alternatives.
- Context: User chose "Generic cloud storage" for the independent WiFi path.
- Rationale: Decouples device from any bespoke always-on server; standard protocol; self-hostable.
- Consequences: Server ingests from the store (watch/notify/poll). Object-store credentials live in device NVS and must be scoped/rotatable.
2026-07-03 - Mobile app: Flutter (Android + iOS)
- Decision: One Flutter codebase targeting both platforms.
- Context: User chose Flutter (Android + iOS).
- Rationale: Single codebase, both stores.
- Consequences: iOS background BLE is restricted, so BLE = control/provisioning only; WiFi handles bulk transfer (already the design).
2026-07-03 - Hardware: ESP32-S3 + I2S MEMS mic + microSD (off-the-shelf, no PCB)
- Decision: Target ESP32-S3 (PSRAM, WiFi + BLE 5, USB). Mic: I2S MEMS (INMP441
default, ICS-43434 upgrade). Storage: microSD. Power: LiPo + charge IC with charge/VBUS
detect. v1 uses modules on a carrier/protoboard; no custom PCB. Full list in
hardware/BOM.md. - Context: User asked me to spec a BOM to buy; has ESP32 / Pico W / other boards.
- Rationale: ESP32-S3 does all three radios + audio buffering on one cheap chip; I2S MEMS gives clean digital audio; microSD removes length limits. Pico W and classic ESP32 are viable fallbacks but weaker for audio/PSRAM.
- Consequences: Bigger enclosure than a commercial Plaud; a custom PCB is a later step.
2026-07-03 - Firmware toolchain: PlatformIO + Arduino-ESP32
- Decision: Build the firmware with PlatformIO using the Arduino-ESP32 framework.
- Context: Need approachable, reproducible builds and CI.
- Rationale: Lower barrier for contributors than raw ESP-IDF; good library support for I2S, SD, BLE, HTTP; PlatformIO gives pinned, CI-friendly builds.
- Consequences: If we hit Arduino limits (fine-grained power, advanced BLE), we can drop to ESP-IDF per-module or migrate; noted as a possible future change.
2026-07-03 - Project name and default audio format
- Decision: Name = "OpenScribe" (record + transcribe, open). Default recording format = WAV PCM 16 kHz mono 16-bit; compressed codecs (ADPCM/Opus) are a later optimisation.
- Context: Project bootstrap.
- Rationale: Clear, descriptive, unencumbered name; WAV is simple and high quality for speech and trivial to decode everywhere.
- Consequences: Larger files (~115 MB/hour) make WiFi the primary transfer path; revisit with Opus for battery-mode transfer and storage.