Quantum Computers
| The promise of quantum computers has a big obstacle to overcome—the environments of the devices easily introduce error to the system. Now researchers have created a small quantum computing array that for the first time performs with a Sudoku-like error correction method that might pave the way toward practical devices. The team behind the breakthrough have also just joined Google, to further their research. |
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esearchers in the UC Santa Barbara’s physics professor John Martinis’ lab have developed quantum circuitry that self-checks for errors and suppresses them, preserving a qubits’ state(s) and imbuing the system with the highly sought-after reliability that may be the long sought after foundation for the building large-scale superconducting quantum computers.
Keeping qubits error-free, or stable enough to reproduce the same result time and time again, is one of the major hurdles scientists on the forefront of quantum computing face.
“One of the biggest challenges in quantum computing is that qubits are inherently faulty,” said Julian Kelly, graduate student researcher and co-lead author of a research paper that was published in the journal Nature. “So if you store some information in them, they’ll forget it.”
Unlike classical computing, in which the computer bits exist on one of two binary (“yes/no”, or “true/false”) positions, qubits can exist at any and all positions simultaneously, in various dimensions. It is this property, called “superpositioning,” that gives quantum computers their phenomenal computational power, but it is also this characteristic which makes qubits prone to “flipping,” especially when in unstable environments, and thus difficult to work with.
“It’s hard to process information if it disappears,” said Kelly.
However, that obstacle may just have been cleared by Kelly, postdoctoral researcher Rami Barends, staff scientist Austin Fowler and others in the Martinis Group.
The error process involves creating a scheme in which several qubits work together to preserve the information, said Kelly. To do this, information is stored across several qubits.
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“This is the first time a quantum device has been built that is capable of correcting its own errors,” said Fowler. For the kind of complex calculations the researchers envision for an actual quantum computer, something up to a hundred million qubits would be needed, but before that a robust self-check and error prevention system is necessary.
Key to this quantum error detection and correction system is a scheme developed by Fowler, called the surface code. It uses parity information — the measurement of change from the original data (if any) — as opposed to the duplication of the original information that is part of the process of error detection in classical computing. That way, the actual original information that is being preserved in the qubits remains unobserved as follows quantum physics.
"This is the first time a quantum device has been built that is capable of correcting its own errors." |
, the parity values of data qubits in a qubit array are taken by adjacent measurement qubits, which essentially assess the information in the data qubits by measuring around them.“So you pull out just enough information to detect errors, but not enough to peek under the hood and destroy the quantum-ness,” said Kelly.
This development represents a meeting of the best in the science behind the physical and the theoretical in quantum computing — the latest in qubit stabilization and advances in the algorithms behind the logic of quantum computing.
“It’s a major milestone,” said Barends. “Because it means that the ideas people have had for decades are actually doable in a real system.”
The Martinis Group continues to refine its research to develop this important new tool. This particular quantum error correction has been proved to protect against the “bit-flip” error, however the researchers have their eye on correcting the complimentary error called a “phase-flip,” as well as running the error correction cycles for longer periods to see what behaviors might emerge.
Martinis and the senior members of his research group have, since this research was performed, entered into a partnership with Google.
The recruitment of the Martinis group signals Google's intent to recruit or tap into talent with wide-ranging expertise at the Google Quantum Artificial Intelligence Lab which also involves NASA. The move also inaugurates a new era of cooperation between academic researchers and D-Wave (under the Google umbrella). The scenario would have seemed unbelievable just several years ago because of the skepticism and heated debates surrounding D-Wave's machines.
SOURCE UCSB
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