Reward Tampering Problems and Solutions in Reinforcement Learning: A Causal Influence Diagram Perspective

August 13, 2019 · Declared Dead · 🏛 arXiv.org

"No code URL or promise found in abstract"

Evidence collected by the PWNC Scanner

Authors Tom Everitt, Marcus Hutter, Ramana Kumar, Victoria Krakovna arXiv ID 1908.04734 Category cs.AI: Artificial Intelligence Cross-listed cs.LG Citations 128 Venue arXiv.org Last Checked 3 months ago

Abstract

Can humans get arbitrarily capable reinforcement learning (RL) agents to do their bidding? Or will sufficiently capable RL agents always find ways to bypass their intended objectives by shortcutting their reward signal? This question impacts how far RL can be scaled, and whether alternative paradigms must be developed in order to build safe artificial general intelligence. In this paper, we study when an RL agent has an instrumental goal to tamper with its reward process, and describe design principles that prevent instrumental goals for two different types of reward tampering (reward function tampering and RF-input tampering). Combined, the design principles can prevent both types of reward tampering from being instrumental goals. The analysis benefits from causal influence diagrams to provide intuitive yet precise formalizations.

📄 View on arXiv 🌐 View on ar5iv 📑 PDF 🎉 Report Code Found

Community Contributions

Found the code? Know the venue? Think something is wrong? Let us know!

📜 Similar Papers

In the same crypt — Artificial Intelligence

📚 📚 The Cartographer

Explainable Artificial Intelligence (XAI): Concepts, Taxonomies, Opportunities and Challenges toward Responsible AI

Alejandro Barredo Arrieta, Natalia Díaz-Rodríguez, ... (+10 more)

cs.AI 🏛 Inf. Fusion 📚 7.8K cites 6 years ago

R.I.P. 👻 Ghosted

Explanation in Artificial Intelligence: Insights from the Social Sciences

Tim Miller

cs.AI 🏛 AI 📚 4.9K cites 8 years ago

R.I.P. 👻 Ghosted

Federated Machine Learning: Concept and Applications

Qiang Yang, Yang Liu, ... (+2 more)

cs.AI 🏛 ACM TIST 📚 2.8K cites 7 years ago

R.I.P. 👻 Ghosted

Counterfactual Explanations without Opening the Black Box: Automated Decisions and the GDPR

Sandra Wachter, Brent Mittelstadt, Chris Russell

cs.AI 🏛 arXiv 📚 2.8K cites 8 years ago

R.I.P. 👻 Ghosted

DeepAR: Probabilistic Forecasting with Autoregressive Recurrent Networks

David Salinas, Valentin Flunkert, Jan Gasthaus

cs.AI 🏛 International Journal of Forecasting 📚 2.7K cites 9 years ago

R.I.P. 👻 Ghosted

Rainbow: Combining Improvements in Deep Reinforcement Learning

Matteo Hessel, Joseph Modayil, ... (+8 more)

cs.AI 🏛 AAAI 📚 2.5K cites 8 years ago

Died the same way — 👻 Ghosted

R.I.P. 👻 Ghosted

Federated Learning: Strategies for Improving Communication Efficiency

Jakub Konečný, H. Brendan McMahan, ... (+4 more)

cs.LG 🏛 arXiv 📚 5.2K cites 9 years ago

R.I.P. 👻 Ghosted

In-Datacenter Performance Analysis of a Tensor Processing Unit

Norman P. Jouppi, Cliff Young, ... (+73 more)

cs.AR 🏛 ISCA 📚 5.1K cites 9 years ago

R.I.P. 👻 Ghosted

Deep Convolutional Neural Networks for Computer-Aided Detection: CNN Architectures, Dataset Characteristics and Transfer Learning

Hoo-Chang Shin, Holger R. Roth, ... (+7 more)

cs.CV 🏛 IEEE TMI 📚 4.9K cites 10 years ago

R.I.P. 👻 Ghosted

Equality of Opportunity in Supervised Learning

Moritz Hardt, Eric Price, Nathan Srebro

cs.LG 🏛 NeurIPS 📚 4.9K cites 9 years ago