The ever-growing scale of high-performance computing systems, particularly with the transition to exascale computing, has underscored the critical need for robust fault tolerance. As these systems ...

Fault tolerance in reconfigurable and embedded systems is a critical area of research that addresses the resilience of complex electronic devices against hardware faults and transient errors. As ...

While computing systems are typically equipped to handle crashes, slow faults—situations when system components' performance degrades rather than failing outright—can cause severe disruptions for ...

In the context of deep learning model training, checkpoint-based error recovery techniques are a simple and effective form of fault tolerance. By regularly saving the ...

Without full fault tolerance in quantum computers we will never practically get past 100 qubits but full fault tolerance will eventually open up the possibility of billions of qubits and beyond. In a ...

Designers parallel their power supplies to increase system power output or to provide fault tolerance. In this column, Contributing Editor Tom Curatolo discusses various techniques for load sharing ...

IBM has just made a major announcement about its plans to achieve large-scale quantum fault tolerance before the end of this decade. Based on the company’s new quantum roadmap, by 2029 IBM expects to ...

A distributed power distribution architecture delivers benefits that extend well beyond fault tolerance. It offers ...

Seamless operations are essential for business success, making system reliability and resilience more than just technical concerns—they are strategic priorities. Even brief periods of downtime can ...

A distributed system is comprised of multiple computing devices interconnected with one another via a loosely-connected network. Almost all computing systems and applications today are distributed in ...