Personal blog of Yzmir Ramirez

“The best-kept secret in quantum computing.” That’s what Cambridge Quantum Computing (CQC) CEO Ilyas Khan called Honeywell‘s efforts in building the world’s most powerful quantum computer. In a race where most of the major players are vying for attention, Honeywell has quietly worked on its efforts for the last few years (and under strict NDA’s, it seems). But today, the company announced a major breakthrough that it claims will allow it to launch the world’s most powerful quantum computer within the next three months.

In addition, Honeywell also today announced that it has made strategic investments in CQC and Zapata Computing, both of which focus on the software side of quantum computing. The company has also partnered with JPMorgan Chase to develop quantum algorithms using Honeywell’s quantum computer. The company also recently announced a partnership with Microsoft.

Honeywell has long built the kind of complex control systems that power many of the world’s largest industrial sites. It’s that kind of experience that has now allowed it to build an advanced ion trap that is at the core of its efforts.

This ion trap, the company claims in a paper that accompanies today’s announcement, has allowed the team to achieve decoherence times that are significantly longer than those of its competitors.

“It starts really with the heritage that Honeywell had to work from,” Tony Uttley, the president of Honeywell Quantum Solutions, told me. “And we, because of our businesses within aerospace and defense and our business in oil and gas — with solutions that have to do with the integration of complex control systems because of our chemicals and materials businesses — we had all of the underlying pieces for quantum computing, which are just fabulously different from classical computing. You need to have ultra-high vacuum system capabilities. You need to have cryogenic capabilities. You need to have precision control. You need to have lasers and photonic capabilities. You have to have magnetic and vibrational stability capabilities. And for us, we had our own foundry and so we are able to literally design our architecture from the trap up.”

The result of this is a quantum computer that promises to achieve a quantum Volume of 64. Quantum Volume (QV), it’s worth mentioning, is a metric that takes into account both the number of qubits in a system as well as decoherence times. IBM and others have championed this metric as a way to, at least for now, compare the power of various quantum computers.

So far, IBM’s own machines have achieved QV 32, which would make Honeywell’s machine significantly more powerful.

Khan, whose company provides software tools for quantum computing and was one of the first to work with Honeywell on this project, also noted that the focus on the ion trap is giving Honeywell a bit of an advantage. “I think that the choice of the ion trap approach by Honeywell is a reflection of a very deliberate focus on the quality of qubit rather than the number of qubits, which I think is fairly sophisticated,” he said. “Until recently, the headline was always growth, the number of qubits running.”

The Honeywell team noted that many of its current customers are also likely users of its quantum solutions. These customers, after all, are working on exactly the kind of problems in chemistry or material science that quantum computing, at least in its earliest forms, is uniquely suited for.

Currently, Honeywell has about 100 scientists, engineers and developers dedicated to its quantum project.

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.

“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.

Here at TechCrunch, we like to think about what’s next, and there are few technologies quite as exotic and futuristic as quantum computing. After what felt like decades of being “almost there,” we now have working quantum computers that are able to run basic algorithms, even if only for a very short time. As those times increase, we’ll slowly but surely get to the point where we can realize the full potential of quantum computing.

For our TechCrunch Sessions: Enterprise event in San Francisco on September 5, we’re bringing together some of the sharpest minds from some of the leading companies in quantum computing to talk about what this technology will mean for enterprises (p.s. early-bird ticket sales end this Friday). This could, after all, be one of those technologies where early movers will gain a massive advantage over their competitors. But how do you prepare yourself for this future today, while many aspects of quantum computing are still in development?

IBM’s quantum computer demonstrated at Disrupt SF 2018

Joining us onstage will be Microsoft’s Krysta Svore, who leads the company’s Quantum efforts; IBM’s Jay Gambetta, the principal theoretical scientist behind IBM’s quantum computing effort; and Jim Clark, the director of quantum hardware at Intel Labs.

That’s pretty much a Who’s Who of the current state of quantum computing, even though all of these companies are at different stages of their quantum journey. IBM already has working quantum computers, Intel has built a quantum processor and is investing heavily into the technology and Microsoft is trying a very different approach to the technology that may lead to a breakthrough in the long run but that is currently keeping it from having a working machine. In return, though, Microsoft has invested heavily into building the software tools for building quantum applications.

During the panel, we’ll discuss the current state of the industry, where quantum computing can already help enterprises today and what they can do to prepare for the future. The implications of this new technology also go well beyond faster computing (for some use cases); there are also the security issues that will arise once quantum computers become widely available and current encryption methodologies become easily breakable.

The early-bird ticket discount ends this Friday, August 9. Be sure to grab your tickets to get the max $100 savings before prices go up. If you’re a startup in the enterprise space, we still have some startup demo tables available! Each demo table comes with four tickets to the show and a high-visibility exhibit space to showcase your company to attendees — learn more here.

 Universal quantum computers don’t exist, but that hasn’t stopped D-Wave from carving out its own place in the quantum computing market. Today, the 17-year-old company is announcing its forth quantum chip, the 2000Q, doubling the number of qubits on its exiting 1000Q chip. The Burnaby, British Columbia based company’s chips fall under a specific class of quantum… Read More