This article explores the evolution and performance of IBM's quantum computing hardware, tracing the progression from early 5-qubit Canary processors to the latest 1,121-qubit Condor chip.
The Canary family marked the initial steps, with the r1 design featuring 5 qubits and the r1.1 expanding to 16 qubits. The Falcon family then introduced medium-scale circuits with a quantum volume of 128, serving as a testbed for performance enhancements.
Subsequent generations saw the introduction of the Egret (33 qubits, QV 512), Hummingbird (65 qubits, QV 128), and Eagle (127 qubits, QV 128) processors, each pushing the boundaries of qubit count and coherence. The Osprey processor then set a new benchmark with 433 qubits.
The latest breakthrough is the Condor processor, featuring an unprecedented 1,121 superconducting qubits. This represents a 50% increase in qubit density compared to previous designs, enabled by advancements in chip fabrication and packaging. Alongside Condor, IBM also introduced the Heron processor, which delivers a 3-5x improvement in device performance over the Eagle series.
The article provides detailed performance metrics for 15 of IBM's current quantum systems, including coherence times, qubit frequencies, readout errors, and gate fidelities. This data serves as a valuable historical record of the NISQ era in quantum computing.
The progression of IBM's quantum hardware, from the early Canary to the record-breaking Condor, demonstrates the company's relentless pursuit of scaling and improving quantum computing capabilities. These advancements pave the way for practical quantum applications in fields such as computational chemistry, optimization, cryptography, and machine learning.
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