In quantum computing, fault tolerance isn’t a single threshold—it depends on which errors you’re dealing with. The physics of your qubits determines the dominant errors—and that shapes which error correction codes will work. Learn more in this carousel.

You’ve probably heard the magic number—99% fidelity—for fault-tolerant quantum computing. But where does it come from? What does it actually mean? And is it really the whole story? In this carousel, we break it all down.

Learn how to read a surface code diagram, including the difference between data qubits vs. measurement qubits, how to denote bit flip and phase flip errors, and how these diagrams shape quantum hardware design.

Quantum hardware doesn’t need to be perfect, but it needs to be below the fault-tolerance threshold. Staying below the threshold for all imperfections is not easy, but QC Design’s Plaquette™ makes it easier. Learn more in our carousel.

Why are quantum teams racing to build LOGICAL qubits? Learn how logical qubits protect quantum information by encoding it across many physical qubits, how this paves the way for big quantum applications, and how QC Design’s Plaquette™ optimizes hardware for success.

Learn to decode quantum fault tolerance threshold plots—key to scalable quantum computing! Discover how hardware imperfections, logical qubit errors, and qubit size impact thresholds, ensuring error correction surpasses error rates. Explore how Plaquette helps hardware teams tackle these challenges

Discover why logical qubits are vital for fault-tolerant quantum computing! Learn how encoding quantum information can protect against errors, the role of the fault-tolerance threshold, and how QC Design’s Plaquette™ optimizes hardware for success.