quantum supremacy

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The race to building a fully functional quantum stack

David Cowan
Contributor

David Cowan is a partner at Bessemer Venture Partners and one of the world’s leading investors across cloud infrastructure, cybersecurity, consumer and space technology.

Tomer Diari
Contributor

Tomer Diari is a vice president at Bessemer Venture Partners, where he focuses primarily on cybersecurity, big data and deep tech opportunities.

Quantum computers exploit the seemingly bizarre yet proven nature of the universe that until a particle interacts with another, its position, speed, color, spin and other quantum properties coexist simultaneously as a probability distribution over all possibilities in a state known as superposition. Quantum computers use isolated particles as their most basic building blocks, relying on any one of these quantum properties to represent the state of a quantum bit (or “qubit”). So while classical computer bits always exist in a mutually exclusive state of either 0 (low energy) or 1 (high energy), qubits in superposition coexist simultaneously in both states as 0 and 1.

Things get interesting at a larger scale, as QC systems are capable of isolating a group of entangled particles, which all share a single state of superposition. While a single qubit coexists in two states, a set of eight entangled qubits (or “8Q”), for example, simultaneously occupies all 2^8 (or 256) possible states, effectively processing all these states in parallel. It would take 57Q (representing 2^57 parallel states) for a QC to outperform even the world’s strongest classical supercomputer. A 64Q computer would surpass it by 100x (clearly achieving quantum advantage) and a 128Q computer would surpass it a quintillion times.

In the race to develop these computers, nature has inserted two major speed bumps. First, isolated quantum particles are highly unstable, and so quantum circuits must execute within extremely short periods of coherence. Second, measuring the output energy level of subatomic qubits requires extreme levels of accuracy that tiny deviations commonly thwart. Informed by university research, leading QC companies like IBM, Google, Honeywell and Rigetti develop quantum engineering and error-correction methods to overcome these challenges as they scale the number of qubits they can process.

Following the challenge to create working hardware, software must be developed to harvest the benefits of parallelism even though we cannot see what is happening inside a quantum circuit without losing superposition. When we measure the output value of a quantum circuit’s entangled qubits, the superposition collapses into just one of the many possible outcomes. Sometimes, though, the output yields clues that qubits weirdly interfered with themselves (that is, with their probabilistic counterparts) inside the circuit.

QC scientists at UC Berkeley, University of Toronto, University of Waterloo, UT Sydney and elsewhere are now developing a fundamentally new class of algorithms that detect the absence or presence of interference patterns in QC output to cleverly glean information about what happened inside.

The QC stack

A fully functional QC must, therefore, incorporate several layers of a novel technology stack, incorporating both hardware and software components. At the top of the stack sits the application software for solving problems in chemistry, logistics, etc. The application typically makes API calls to a software layer beneath it (loosely referred to as a “compiler”) that translates function calls into circuits to implement them. Beneath the compiler sits a classical computer that feeds circuit changes and inputs to the Quantum Processing Unit (QPU) beneath it. The QPU typically has an error-correction layer, an analog processing unit to transmit analog inputs to the quantum circuit and measure its analog outputs, and the quantum processor itself, which houses the isolated, entangled particles.

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QC Ware Forge will give developers access to quantum hardware and simulators across vendors

Quantum computing is almost ready for prime time, and, according to most experts, now is the time to start learning how to best develop for this new and less than intuitive technology. With multiple vendors like D-Wave, Google, IBM, Microsoft and Rigetti offering commercial and open-source hardware solutions, simulators and other tools, there’s already a lot of fragmentation in this business. QC Ware, which is launching its Forge cloud platform into beta today, wants to become the go-to middleman for accessing the quantum computing hardware and simulators of these vendors.

Forge, which like the rest of QC Ware’s efforts is aimed at enterprise users, will give developers the ability to run their algorithms on a variety of hardware platforms and simulators. The company argues that developers won’t need to have any previous expertise in quantum computing, though having a bit of background surely isn’t going to hurt. From Forge’s user interface, developers will be able to run algorithms for binary optimization, chemistry simulation and machine learning.

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“Practical quantum advantage will occur. Most experts agree that it’s a matter of ‘when’ not ‘if.’ The way to pull that horizon closer is by having the user community fully engaged in quantum computing application discovery. The objective of Forge is to allow those users to access the full range of quantum computing resources through a single platform,” said Matt Johnson, CEO, QC Ware. “To assist our customers in that exploration, we are spending all of our cycles working on ways to squeeze as much power as possible out of near-term quantum computers, and to bake those methods into Forge.”

Currently, QC Ware Forge offers access to hardware from D-Wave, as well as open-source simulators running on Google’s and IBM’s clouds, with plans to support a wider variety of platforms in the near future.

Initially, QC Ware also told me that it offered direct access to IBM’s hardware, but that’s not yet the case. “We currently have the integration complete and actively utilized by QC Ware developers and quantum experts,”  QC Ware’s head of business development Yianni Gamvros told me. “However, we are still working with IBM to put an agreement in place in order for our end-users to directly access IBM hardware. We expect that to be available in our next major release. For users, this makes it easier for them to deal with the churn. We expect different hardware vendors will lead at different times and that will keep changing every six months. And for our quantum computing hardware vendors, they have a channel partner they can sell through.”

Users who sign up for the beta will receive 30 days of access to the platform and one minute of actual Quantum Computing Time to evaluate the platform.

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