Quantum chip connected to internet is yours to command
Quantum computing is in the cloud, and you don't need
a degree in advanced physics to run your own programs. For the first
time, anyone with a web browser will soon be able to log in and run
basic algorithms on a quantum chip hooked up to the internet.
A quantum chip processes information in
qubits, or quantum bits, which, unlike the digital bits in a regular
computer, can be both 0 and 1 at the same time. In theory, this ability
should allow quantum computers to offer far speedier computation than
current PCs – although devices that can definitely outperform standard
machines don't yet exist.
Until now only a few labs around the world have had access to even basic quantum computers.
Google recently purchased a D-Wave quantum computer and shares access
with NASA and other select researchers, but not with the general public.
Questions also remain over just how quantum D-Wave's machine really is, because it operates using a non-mainstream technique called adiabatic quantum computing.
Scientists at the University of Bristol,
UK, were concerned that limited availability to any type of quantum
computer would mean a dearth of skilled coders when the expected quantum
revolution finally arrives.
"A quantum computer can do things faster
for you, but someone has to program it, and at the moment there are only
a handful of people around the world who would be qualified," says
Bristol's Jeremy O'Brien, who led the development of the quantum chip being used in the cloud project.
Quantum sim
The more traditionally quantum chip made at the University of Bristol
works by guiding two photons through a series of optical channels. As
the photons pass through the chip they become entangled, meaning that a
measurement on one influences the outcome when measuring the other.
Programming the computer involves tweaking the extent of this
entanglement to produce different computations.
Would-be quantum coders will first use an online simulator
that lets them practise programming. A tutorial explains the key
quantum-mechanical ideas that are central to the device, then guides
users through the steps required to adjust the chip and change its
output. Once experienced enough, users can ask for permission to connect
to the real chip, which is sitting in a lab in Bristol. It will run
programs and return results via the internet.
"You can sit on the bus with your mobile
phone and do a quantum optics experiment which might never have been
seen before," says team member Peter Shadbolt. The simulator is already online, but the ability to directly access the chip won't launch until 20 September.
Cloudy future
Exactly what a member of the public might
want to use the quantum chip for is unclear. And the version being used
online only has two qubits, so its processing power is a very limited.
"It's not going to calculate something
that your PC couldn't calculate, because it's not at that scale by a
long way," says O'Brien. His team has made 6-qubit and 8-qubit
computers, but those projects are still in development. In the meantime,
they are happy to let others use their older technology for free as a
way to encourage engagement.
The beginnings of a quantum cloud should
be a fun way to demonstrate the technology for the public, says Scott
Aaronson at the Massachusetts Institute of Technology, who is not part
of the project. And while a 2-qubit device won't be more useful than
your regular PC, putting it online might foreshadow how we will access
large-scale quantum computers in future, he says.
"If quantum computing does become a
practical technology, there will be a relatively small number of quantum
computers, which people will access remotely."
Quantum computing is in the cloud, and you don't need
a degree in advanced physics to run your own programs. For the first
time, anyone with a web browser will soon be able to log in and run
basic algorithms on a quantum chip hooked up to the internet.
A quantum chip processes information in
qubits, or quantum bits, which, unlike the digital bits in a regular
computer, can be both 0 and 1 at the same time. In theory, this ability
should allow quantum computers to offer far speedier computation than
current PCs – although devices that can definitely outperform standard
machines don't yet exist.
Until now only a few labs around the world have had access to even basic quantum computers.
Google recently purchased a D-Wave quantum computer and shares access
with NASA and other select researchers, but not with the general public.
Questions also remain over just how quantum D-Wave's machine really is, because it operates using a non-mainstream technique called adiabatic quantum computing.
Scientists at the University of Bristol,
UK, were concerned that limited availability to any type of quantum
computer would mean a dearth of skilled coders when the expected quantum
revolution finally arrives.
"A quantum computer can do things faster
for you, but someone has to program it, and at the moment there are only
a handful of people around the world who would be qualified," says
Bristol's Jeremy O'Brien, who led the development of the quantum chip being used in the cloud project.
Quantum sim
The more traditionally quantum chip made at the University of Bristol
works by guiding two photons through a series of optical channels. As
the photons pass through the chip they become entangled, meaning that a
measurement on one influences the outcome when measuring the other.
Programming the computer involves tweaking the extent of this
entanglement to produce different computations.
Would-be quantum coders will first use an online simulator
that lets them practise programming. A tutorial explains the key
quantum-mechanical ideas that are central to the device, then guides
users through the steps required to adjust the chip and change its
output. Once experienced enough, users can ask for permission to connect
to the real chip, which is sitting in a lab in Bristol. It will run
programs and return results via the internet.
"You can sit on the bus with your mobile
phone and do a quantum optics experiment which might never have been
seen before," says team member Peter Shadbolt. The simulator is already online, but the ability to directly access the chip won't launch until 20 September.
Cloudy future
Exactly what a member of the public might
want to use the quantum chip for is unclear. And the version being used
online only has two qubits, so its processing power is a very limited.
"It's not going to calculate something
that your PC couldn't calculate, because it's not at that scale by a
long way," says O'Brien. His team has made 6-qubit and 8-qubit
computers, but those projects are still in development. In the meantime,
they are happy to let others use their older technology for free as a
way to encourage engagement.
The beginnings of a quantum cloud should
be a fun way to demonstrate the technology for the public, says Scott
Aaronson at the Massachusetts Institute of Technology, who is not part
of the project. And while a 2-qubit device won't be more useful than
your regular PC, putting it online might foreshadow how we will access
large-scale quantum computers in future, he says.
"If quantum computing does become a
practical technology, there will be a relatively small number of quantum
computers, which people will access remotely."

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