Leela AI Skill
Manufacturing Intelligence -- from theory to industrial application.
Overview
This skill describes Leela AI's relationship to MOOLLM. Leela develops MOOLLM with an eye toward manufacturing intelligence, using it daily for practical devops, edgebox management, coding, debugging, and design work. The team is exploring how the theoretical foundations of Minsky, Papert, and Drescher might eventually deploy on factory floors.
Leela and Gary Drescher
Leela's foundations lie in Gary Drescher's work at MIT under Marvin Minsky and Seymour Papert. Drescher brought Jean Piaget's developmental psychology into computing: infants learn through sensorimotor experience and build schemas (context → action → result). Henry Minsky was exposed to this as a student; years later he reimplemented Drescher's algorithms and, with Cyrus Shaoul and Milan Minsky, founded Leela AI. The name Leela is Sanskrit for divine play — the play of creation, destruction, and re-creation.
Key points:
- Schema mechanism: Leela builds models of the world using schemas that reason about which actions are possible and what changes when an action is performed. Goals are achieved by chaining schemas (planner finds actions whose results match the goal).
- Self-supervised learning: Leela learns from exploratory actions without labeled examples or explicit reward; it forms and tests hypotheses. In multi-goal grid-world experiments (Kommrusch et al., IWSSL 2020), Leela reached training targets in ~160N² steps vs DQN ~360N^2.7, and does not suffer catastrophic forgetting.
- Neurosymbolic extension: Later work (Symbolic Guidance for Constructivist Learning, Neurosymbolic Learning on Video Data, Society of LLMs) combines the symbolic schema system with neural perception (object/pose detection, cortical columns, multi-LLM instances). Society of LLMs (Kommrusch & Minsky, IWSSL 2024) maps Drescher's schema mechanism onto multi-agent LLMs: curiosity-driven goals, multiple plans, training samples when plans differ and one succeeds, contextual sub-activation (one agent "thinking subconsciously"), and incremental LoRA updates; evaluation target ARC-AGI. Leela Core uses the hybrid for manufacturing video intelligence — causal reasoning and explainability on top of ConvNets.
See: schema-mechanism/, reference/drescher-lineage.yml, reference/publications.yml, reference/society-of-llms.yml.
Core Technology
Neural-Symbolic Vision
Traditional computer vision is pattern matching. Leela's neural-symbolic system is causal reasoning.
neural_symbolic:
layer_1: neural
- object detection (what is there?)
- pose estimation (how is it positioned?)
- motion tracking (where is it going?)
layer_2: symbolic
- context inference (what situation is this?)
- causal reasoning (why is this happening?)
- SQL queries over temporal event database
- prediction (what will happen next?)
- explanation (human-readable "why")
layer_3: pda # LLM interface layer
- generate: natural language → SQL
- perform: execute queries
- interpret: results → meaning
- explain: causation in plain language
- visualize: charts, timelines, maps
- remember: query history, preferences
The neural layer provides perception. The symbolic layer provides reasoning. The PDA layer provides natural language interface -- neural at the surface, symbolic in the protocol.
Schema Mechanism (Drescher)
Every inference follows Drescher's schema pattern:
schema:
context: [observable conditions]
action: [event that occurred]
result: [observed outcome]
learning:
marginal_attribution:
- which context features predict result?
synthetic_items:
- inferred entities not directly observed
generalization:
- when does this schema apply elsewhere?
Edge Computing Architecture
Intelligence at the edge, not in the cloud:
edge_architecture:
edgebox:
location: factory floor
latency: <50ms
capabilities: [inference, alerting, logging]
cloud:
purpose: training, aggregation, analytics
latency: acceptable for non-real-time
principle: |
Real-time decisions happen at the edge.
Learning and optimization happen in the cloud.
Data sovereignty stays with the customer.
Applications
1. Safety Monitoring
safety_monitoring:
purpose: Prevent accidents through predictive awareness
examples:
- pedestrian_in_vehicle_zone
- ppe_compliance (hard hats, vests, glasses)
- ergonomic_risk (repetitive motion, lifting posture)
- near_miss_detection (close calls before accidents)
output:
alert: real-time notification
explanation: why this is a safety concern
recommendation: suggested action
audit: logged for compliance
2. Process Optimization
process_optimization:
purpose: Improve efficiency through observation and inference
examples:
- cycle_time_analysis
- bottleneck_detection
- idle_time_measurement
- workflow_optimization
output:
insight: what is happening
causation: why it is happening
recommendation: how to improve
simulation: what-if scenarios
3. Predictive Maintenance
predictive_maintenance:
purpose: Fix equipment before it fails
signals:
visual: vibration patterns, wear indicators, alignment
thermal: heat signatures indicating friction or failure
acoustic: sound patterns indicating mechanical issues
schema:
context: [equipment state, operational history]
action: [detected anomaly]
result: [predicted failure mode]
output:
prediction: what will fail, when
explanation: why we predict this
recommendation: maintenance action
confidence: certainty level
4. DevOps Automation
devops:
purpose: Apply MOOLLM patterns to infrastructure
patterns:
files_as_state:
- infrastructure as code
- git as audit trail
- YAML as configuration
coherence_engine:
- detect configuration drift
- propose remediation
- explain changes
speed_of_light:
- batch operations
- parallel deployment
- minimal round-trips
MOOLLM Integration
Rooms as Zones
# Factory zone as MOOLLM room
zone:
id: assembly_line_3
type: [production, monitored, indoor]
contains:
- equipment: [robot_arm_1, conveyor_2, station_7]
- personnel: [operator_badge_1234]
- cameras: [cam_3a, cam_3b, cam_3c]
exits:
- to: staging_area
- to: quality_check
atmosphere:
safety_status: green
production_status: active
alert_level: none
Characters as Entities
# Forklift as MOOLLM character
entity:
id: forklift_07
type: [vehicle, autonomous, tracked]
location: loading_dock_2
state: stationary
current_task: awaiting_clearance
relationships:
operator: badge_5678
cargo: pallet_1234
needs:
fuel: 0.73
maintenance: 0.15 # due soon
Skills as Inference Rules
# Safety protocol as MOOLLM skill
skill:
id: pedestrian-safety
activation:
context: pedestrian detected in vehicle zone
action:
- alert vehicle operators
- log safety event
- track pedestrian until zone-clear
advertisement:
provides: pedestrian-zone-monitoring
satisfies: [safety, compliance, awareness]
The Team
| Team Member | Role | Background |
|---|---|---|
| Henry Minsky | CTO | MIT AI Lab, NTT DoCoMo, Google Nest. Marvin Minsky's son. |
| Dr. Cyrus Shaoul | Chief Evangelist | Computational neuroscientist, Digital Garage co-founder/CTO |
| Dr. Milan Singh Minsky | VP Product | Venture-backed startups, RayVio co-founder |
| Sheung Li | VP Applications | Machine vision in manufacturing |
| Dr. Steve Kommrusch | Senior AI Research Scientist | Deep learning, AMD/HP/National Semiconductor |
| Don Hopkins | AI Architect | The Sims, NeWS, pie menus, MOOLLM |
The theory meets the practice. Minsky's ideas, refined through Hopkins's implementation experience and Kommrusch's deep learning expertise, deployed on factory floors.
Ethical Framework
Transparency
transparency:
principle: Every inference is explainable
implementation:
- causal_chains: visible in audit log
- confidence_levels: always reported
- uncertainty: acknowledged, not hidden
- limitations: documented
Privacy
privacy:
principle: Data sovereignty and minimal collection
implementation:
- edge_processing: data stays local when possible
- anonymization: faces pixelated by default
- retention: minimal, configurable
- consent: clear signage, worker awareness
Human Agency
human_agency:
principle: AI advises, humans decide
implementation:
- critical_decisions: require human approval
- recommendations: clearly labeled as suggestions
- override: always possible
- accountability: human remains responsible
Integration Points
| System | Integration |
|---|---|
| SCADA | Sensor data ingestion |
| MES | Production event correlation |
| ERP | Business context enrichment |
| CMMS | Maintenance recommendation routing |
| Safety Systems | Alert escalation |
Deployment Model
deployment:
edge:
edgeboxes: industrial compute at the source
latency: <50ms for real-time inference
resilience: operates offline if cloud disconnected
cloud:
platform: customer choice (AWS, GCP, Azure, on-prem)
purpose: training, aggregation, dashboard
sovereignty: customer owns their data
hybrid:
edge_to_cloud: telemetry, events, learning data
cloud_to_edge: model updates, configuration
References
- Drescher, G. (1991). Made-Up Minds. MIT Press.
- Minsky, M. (1985). Society of Mind. Simon & Schuster.
- Kommrusch et al. (2020). Self-Supervised Learning for Multi-Goal Grid World: Comparing Leela and Deep Q Network. IWSSL, PMLR 131.
- MOOLLM Skills
- Schema Mechanism
- reference/publications.yml — papers and case study
- leela.ai