RobotMem
Enables robots to store, retrieve, and consolidate episodic experiences including physical parameters, trajectories, and outcomes. It supports hybrid vector search with structured filtering and spatial sorting to help robotic agents learn from past successes and failures.
README
robotmem — Let Robots Learn from Experience
Your robot ran 1000 experiments, starting from scratch every time. robotmem stores episode experiences — parameters, trajectories, outcomes — and retrieves the most relevant ones to guide future decisions.
FetchPush experiment: +25% success rate improvement (42% → 67%), CPU-only, reproducible in 5 minutes.
<p align="center"> <img src="examples/demo.gif" alt="robotmem 30s demo: save → restart → recall" width="600"> </p>
Quick Start
pip install robotmem
from robotmem import learn, recall, save_perception, start_session, end_session
# Start an episode
session = start_session(context='{"robot_id": "arm-01", "task": "push"}')
# Record experience
learn(
insight="grip_force=12.5N yields highest grasp success rate",
context='{"params": {"grip_force": {"value": 12.5, "unit": "N"}}, "task": {"success": true}}'
)
# Retrieve experiences (structured filtering + spatial nearest-neighbor)
memories = recall(
query="grip force parameters",
context_filter='{"task.success": true}',
spatial_sort='{"field": "spatial.position", "target": [1.3, 0.7, 0.42]}'
)
# Store perception data
save_perception(
description="Grasp trajectory: 30 steps, success",
perception_type="procedural",
data='{"sampled_actions": [[0.1, -0.3, 0.05, 0.8], ...]}'
)
# End episode (auto-consolidation + proactive recall)
end_session(session_id=session["session_id"])
7 APIs
| API | Purpose |
|---|---|
learn |
Record physical experiences (parameters / strategies / lessons) |
recall |
Retrieve experiences — BM25 + vector hybrid search with context_filter and spatial_sort |
save_perception |
Store perception / trajectory / force data (visual / tactile / proprioceptive / auditory / procedural) |
forget |
Delete incorrect memories |
update |
Correct memory content |
start_session |
Begin an episode |
end_session |
End an episode (auto-consolidation + proactive recall) |
Key Features
Structured Experience Retrieval
Not just vector search — robotmem understands the structure of robot experiences:
# Retrieve only successful experiences
recall(query="push to target", context_filter='{"task.success": true}')
# Find spatially nearest scenarios
recall(query="grasp object", spatial_sort='{"field": "spatial.object_position", "target": [1.3, 0.7, 0.42]}')
# Combine: success + distance < 0.05m
recall(
query="push",
context_filter='{"task.success": true, "params.final_distance.value": {"$lt": 0.05}}'
)
Context JSON — 4 Sections
{
"params": {"grip_force": {"value": 12.5, "unit": "N", "type": "scalar"}},
"spatial": {"object_position": [1.3, 0.7, 0.42], "target_position": [1.25, 0.6, 0.42]},
"robot": {"id": "fetch-001", "type": "Fetch", "dof": 7},
"task": {"name": "push_to_target", "success": true, "steps": 38}
}
Each recalled memory automatically extracts params / spatial / robot / task as top-level fields.
Memory Consolidation + Proactive Recall
end_session automatically triggers:
- Consolidation: Merges similar memories with Jaccard similarity > 0.50 (protects constraint / postmortem / high-confidence entries)
- Proactive Recall: Returns historically relevant memories for the next episode
FetchPush Demo
cd examples/fetch_push
pip install gymnasium-robotics
PYTHONPATH=../../src python demo.py # 90 episodes, ~2 min
Three-phase experiment: baseline → memory writing → memory utilization. Expected Phase C success rate 10-20% higher than Phase A.
Architecture
SQLite + FTS5 + vec0
├── BM25 full-text search (jieba CJK tokenizer)
├── Vector search (FastEmbed ONNX, CPU-only)
├── RRF fusion ranking
├── Structured filtering (context_filter)
└── Spatial nearest-neighbor sorting (spatial_sort)
- CPU-only, no GPU required
- Single-file database
~/.robotmem/memory.db - MCP Server (7 tools) or direct Python import
- Web management UI:
robotmem web
Comparison
| Feature | MemoryVLA (Academic) | Mem0 (Product) | robotmem |
|---|---|---|---|
| Target users | Specific VLA models | Text AI | Robotic AI |
| Memory format | Vectors (opaque) | Text | Natural language + perception + parameters |
| Structured filtering | No | No | Yes (context_filter) |
| Spatial retrieval | No | No | Yes (spatial_sort) |
| Physical parameters | No | No | Yes (params section) |
| Installation | Compile from paper code | pip install | pip install |
| Database | Embedded | Cloud | Local SQLite |
License
Apache-2.0
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