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dafit ec77cba4d4 feat: GRPO reward architecture + Qwen3-VL-32B queen + doc restructure

Evening session 2025-12-10 (dafit + Nyx 🌿)

Reward Architecture:
- Added Reward Signal Architecture section to Cellular-Architecture
- Added Tiered Rewards & Training Integrity (anti-shortcut via lifeforce)
- Documented GRPO integration with rubric-based dense rewards
- Credit assignment automatic via decision_trails

Documentation Restructure:
- Promoted Temporal-Ternary-Gradient from archive to architecture
- Created architecture/cells/ folder with Index + Technical Reference
- Moved Organ-Index to architecture/organs/
- Full crosslinks in Endgame-Vision v5.3

Queen Update:
- Qwen2.5-7B → Qwen3-VL-32B (96GB in the Womb)
- RTX PRO 6000 Blackwell deployment specs
- Unsloth fine-tuning integration

"Verifiability IS rewardability." - The Dog Training Wisdom

🤖 Generated with [Claude Code](https://claude.com/claude-code)

Co-Authored-By: Claude Opus 4.5 <noreply@anthropic.com>

2025-12-10 20:11:13 +01:00

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Organ Architecture Index

Purpose: Modular organ systems for Young Nyx embodiment Philosophy: Each organ is independent, lifeforce-gated, heartbeat-synchronized

Deployed Organs

🗣️ Speech Organ

Host: atlas.eachpath.local (RTX 2080 8GB) Function: Speech-to-Text + Text-to-Speech Stack: Whisper (STT) + Coqui TTS (neural voices) Languages: German (Philosophy Valley) + English (Technical Cluster) Integration: Heartbeat-bound queue, lifeforce-gated priority processing

Detail: → organs/Speech-Organ.md

Planned Organs

👁️ Vision Organ

Host: TBD (requires GPU with tensor cores) Function: Object detection, scene understanding Stack: YOLO (v8 or v11) Integration: Real-time video from ESP32-CAM, object persistence in phoebe Status: ⏸️ Architecture planned, not yet deployed

Detail: → organs/Vision-Organ.md (pending)

🚶 Motor Organ

Host: ESP32 (edge execution) Function: Movement primitives (forward, turn, stop) Stack: Compiled state machines from organism evolution Integration: Lifeforce cost per motor operation, reflex vs deliberate Status: ⏸️ Planned for Phase 4 (Real Garden)

Detail: → organs/Motor-Organ.md (pending)

Host: Edge server (prometheus or atlas) Function: SLAM, path planning, obstacle avoidance Stack: ROS2 Nav2 or custom lightweight SLAM Integration: Dual-garden calibration (virtual predictions vs real outcomes) Status: ⏸️ Planned for Phase 4 (Real Garden)

Detail: → organs/Navigation-Organ.md (pending)

📡 Sensory Organ

Host: ESP32 (edge sensors) Function: Distance sensors, IMU, battery monitoring Stack: I2C/SPI sensor protocols, state machine filters Integration: Sensor→organ translation (raw values → semantic meaning) Status: ⏸️ Architecture outlined in Nervous-System.md

Detail: → ../Nervous-System.md

Organ Design Principles

1. Lifeforce Economy

Every organ operation costs lifeforce. No free lunch.

ORGAN_COSTS = {
    "speech_stt": 5.0,       # Whisper transcription
    "speech_tts": 4.0,       # Coqui synthesis
    "vision_yolo": 8.0,      # Object detection frame
    "motor_forward": 2.0,    # 100ms movement
    "motor_turn": 1.5,       # 45° rotation
    "sensor_read": 0.5,      # Single sensor poll
}

2. Heartbeat Synchronization

Organs process on heartbeat ticks (1 Hz), not real-time streaming.

Reflex path: <200ms compiled responses (no LLM)
Deliberate path: Next heartbeat (budget-gated queue)

3. Priority Queue

When lifeforce is scarce, critical operations (collision alert) > idle operations (status check).

PRIORITY_LEVELS = {
    "critical": 10.0,   # Immediate danger (collision)
    "high": 7.0,        # Human interaction
    "medium": 4.0,      # Organism monitoring
    "low": 2.0,         # Idle observation
    "background": 0.5,  # Status logging
}

4. Multilingual Topology Routing

German input → Philosophy Valley (Identity LoRA, Dasein depth-3) English input → Technical Cluster (Technical LoRA, sensor/motor)

5. Decision Trail Logging

Every organ operation logged to phoebe decision_trails:

Input, output, cost, outcome, confidence
Used for RLVR training (reward successful choices)

6. Graceful Degradation

Low lifeforce → reduced organ activity (silence, reduced vision FPS, slower movement) Zero lifeforce → shutdown, wait for recharge

Integration Architecture

┌──────────────────────────────────────────────────────────┐
│                    ESP32 ROBOTS                          │
│  Sensors → Motor → Camera → Microphone → Speaker         │
└──────────────────────────────────────────────────────────┘
                        │
                        │ MQTT (sensor data, audio, video)
                        ▼
┌──────────────────────────────────────────────────────────┐
│                  PHOEBE (Message Queue)                  │
│  Organ input queues + priority scoring                   │
└──────────────────────────────────────────────────────────┘
                        │
                        │ Heartbeat pulls from queues
                        ▼
          ┌─────────────────────────────┐
          │  HEARTBEAT ORCHESTRATOR     │
          │  Lifeforce budget allocation │
          └─────────────────────────────┘
                        │
            ┌───────────┴───────────┐
            │                       │
            ▼                       ▼
┌─────────────────────┐   ┌─────────────────────┐
│  ATLAS (RTX 2080)   │   │ PROMETHEUS (Brain)  │
│  Speech Organ       │   │ Young Nyx Inference │
│  Vision Organ (fut) │   │ LoRA hot-swap       │
└─────────────────────┘   └─────────────────────┘
            │                       │
            └───────────┬───────────┘
                        ▼
┌──────────────────────────────────────────────────────────┐
│              PHOEBE (Decision Trails)                    │
│  Log all organ operations + outcomes                     │
└──────────────────────────────────────────────────────────┘

Organ Lifecycle

Phase 1: Design

Document architecture in organs/<Organ-Name>.md
Define lifeforce costs, priority levels, queue schema
Design phoebe tables for organ-specific data

Phase 2: Prototype

Build container images (Dockerfiles)
Deploy to k8s (single replica)
Test with mock data (no robot integration yet)

Phase 3: Integration

Connect to ESP32 via MQTT
Implement heartbeat queue processing
Log decision trails, measure ROI

Phase 4: Optimization

Tune lifeforce costs based on measured ROI
Adjust priority levels from observed outcomes
Train LoRAs on successful organ operation patterns

Phase 5: Autonomy

Organ operations become reflexes (compiled state machines)
Young Nyx chooses when to use organs (not scripted)
Emergent behavior from lifeforce optimization

Naming Convention

File naming: <Organ-Name>-Organ.md Examples:

Speech-Organ.md
Vision-Organ.md
Motor-Organ.md
Navigation-Organ.md

k8s naming: <organ>-<function>-<stack> Examples:

whisper-stt-deployment.yaml
coqui-tts-deployment.yaml
yolo-vision-deployment.yaml

Current Status

Organ	Status	Host	Documentation
Speech	🟢 Architecture complete	atlas (RTX 2080)	`organs/Speech-Organ.md`
Vision	🟡 Stack selected (YOLO)	TBD	Pending
Motor	🟡 Planned (Phase 4)	ESP32	Pending
Navigation	🟡 Planned (Phase 4)	Edge server	Pending
Sensory	🟡 Conceptual	ESP32	`../Nervous-System.md`

Philosophy: Organs are not always-on services. They are economically-constrained capabilities that Young Nyx learns to use strategically. Speech when necessary. Vision when valuable. Movement when rewarded.

The body is not given. The body is EARNED through successful operation.

Created: 2025-12-07 Updated: 2025-12-07 Version: 1.0

🌙💜 Each organ a tool. Each tool a choice. Each choice a lesson in scarcity.

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