Cypher Robotics takes the stage at Hannover Messe 2025

Cypher Robotics takes the stage at Hannover Messe 2025

Apr 16, 2025 | Captis, cycle counting, Cypher Robotics, Scott Simmie

By Scott Simmie

 

We feel a bit like proud parents.

That’s because a company we have incubated, Cypher Robotics, recently took to the world stage at the big Hannover Messe 2025 show in Germany. It’s one of the largest automation and technology shows in the world. More than 125,000 people attended and Cypher’s Founder and CEO Peter King (seen on the left in the panel above) was one of them.

King was there to showcase the Captis cycle counting solution – a three-in-one robot that can autonomously scan inventory, capture RFID tags, and carry out precision scans on missions that last up to five hours. A single shift with Captis can capture all inventory in a large warehouse while transferring that data in realtime to a client’s Warehouse Management System or Warehouse Execution System software.

What differentiates Captis from other solutions is a ROS2-based tethered drone. In the back of a warehouse, that drone ascends from the Autonomous Mobile Robot (AMR) base. As the base moves down the aisles, the drone optically scans product codes. This eliminates human error, and saves people from the repetitive – and potentially risky – task of working from heights.

Below: The Captis system with its ROS2 tethered drone. InDro Robotics is the incubator for Cypher Robotics

 

Cypher Robotics Captis

ERICSSON AND 5G

 

Captis was on display at the Ericsson booth. That company is the world leader in telecommunications hardware and software. It’s very likely that your local cellular provider is running on a network built by Ericsson.

And now, as companies globally transition toward an Industry 4.0 (IR4) world of automation and connected devices, those networks are more important than ever. Secure, high-speed data throughput in the form of private 5G networks is the foundation of IR4.

“As manufacturers modernize their operations, the need for the right connectivity has never been more critical,” explains Ericsson. “Data transformation in manufacturing starts with a unified connectivity platform that seamlessly integrates your existing digital assets to enable new technologies. At the heart of this transformation is 5G connectivity, delivering scalable, flexible solutions that harness massive amounts of data generated by Industrial IoT devices.”

At big shows like Hannover Messe, Ericsson wants a tangible way to demonstrate what these private 5G networks mean in the real world. That’s why Cypher Robotics, along with several other innovators, was invited to display at the Ericsson booth.

“There was a lot of interest in Captis at Hannover Messe,” says King. “People immediately understand the value proposition.”

Below: Cypher Robotics Founder and CEO Peter King, left, along with partners Ericsson and Slolam Consulting

Cypher Robotics Peter King Hannover Messe Captis

INDRO’S TAKE

 

InDro was pleased to see Captis and Peter King once again take to the global stage. As the incubator for Cypher Robotics, we are particularly proud.

“The Captis solution is truly at the forefront of cycle-counting technology, and it’s been very satisfying to assist the Cypher Robotics team overcome some of the demanding technical hurdles,” says InDro Robotics Founder and CEO Philip Reece. “In addition to what it can do for clients, Captis is also a great way for Ericsson to demonstrate the undeniable efficiencies that private 5G networks enable in an Industry 4.0 setting.”

Bonus: If you’d like to see highlights from the big show – along with a glimpse of a robotic goaltender built by Ontario high school students that was on display – check out the video below.

Industry 4.0 and InDro – the evolution continues

Industry 4.0 and InDro – the evolution continues

Mar 11, 2025 | 4IR, Autonomy, Industry 4.0, Industry News, Scott Simmie

By Scott Simmie

 

Many of you will remember the days before smart phones. Same goes for automated tellers, online banking, self check-outs, personal computers, 3D printers – even the internet itself. Technology hasn’t merely marched along; it’s been sprinting at an ever-accelerating pace. What’s more, it’s been doing so pretty much everywhere. From the smart devices that now populate our pockets and homes and vehicles through to autonomous mobile robots in factories, hospitals, warehouses, airports – we are in the midst of an inflection point.

If you’re in the technology industry, this era is known as Industry 4.0. And there’s no question that it is – and will continue to be – utterly transformative.

Let’s take a brief look at how we got here…and where it’s going.

Below: An InDro Robotics Sentinel inspection robot. It carries out complex autonomous inspections before returning to its base to wirelessly recharge

Sentinel enclosure Ottawa Hydro

THE PATH TO 4.0

 

Industry 4.0 is also known by some as 4IR, meaning the Fourth Industrial Revolution. So it’s worth briefly reviewing the other three.

The initial Industrial Revolution began in the UK in the mid-1700s. The development of steam power, water power, and mechanisation paved the path for production of certain commodities at scale. They may seem primitive now, but these were huge innovations at the time. These efficiencies helped vault the UK to a leading economic position and the technology began rapidly spreading elsewhere in the world.

That was followed by three other industrial epochs:

  • The late 1800s, where mass production lines using electrical power marked the outset of the Second Industrial Revolution
  • The late 1960s saw the introduction of computers and other early IT systems, as well as significant advances in automation including simple robotic devices
  • The mid-2010s ushered in Industry 4.0, often described as the integration of cyber and physical systems (more on this in a moment)

To help visualise this, we’ve tapped on Wikimedia Commons, and this graphic from Christoph Roser at AllAboutLean.com

Industry 4.0 Wikimedia Commons Christoph Roser at AllAboutLean.com

THE FOURTH WAVE

 

As we saw, what’s thought of as the Third Industrial Revolution brought computers and early robotics/manufacturing advances onto the scene. Industry 4.0 can be thought of as the logical extension of the third – but with massive technological and data integration advances. As this Forbes article puts it, “The fourth industrial revolution will take what was started in the third with the adoption of computers and automation and enhance it with smart and autonomous systems fueled by data and machine learning…As a result of the support of smart machines that keep getting smarter as they get access to more data, our factories will become more efficient and productive and less wasteful.”

We asked an AI engine for its take, and it came back with a very concise definition: “Industry 4.0 is a term that describes the ongoing technological revolution that is transforming how companies operate, design, produce, and deliver goods and services.”

It also offered, helpfully, the key enabling technologies including: 

  • Artificial Intelligence 
  • The Internet of Things 
  • Big Data Analytics 
  • Augmented Reality 
  • Precision Scanning and digital twins
  • Robotics
  • Advanced manufacturing techniques, including 3D printing

COVID-19, with its extensive isolation and social distancing, played a significant role in companies embracing Industry 4.0. A basic example many can relate to was the growth of UberEats and other food delivery services. The coding and technology – the integration of the cyber and physical words – utterly transformed much of the restaurant industry.

It would be hard to think of a sector that has not been touched by 4IR: Manufacturing, mining, agriculture, pharmaceuticals, aerospace – you name it.

 

INDRO 4.0

 

Industry 4.0 is a massive topic – with implications not only for companies seeking a competitive edge but also for workers. Many companies, according to this excellent McKinsey and Company overview (complete with compelling data and examples of ‘Lighthouses’ – companies at the pinnacle of 4.0), are re-skilling employees hand-in-hand with adopting new 4IR technologies. Europe here has taken the lead over North America.

As for InDro? The company was officially formed in 2014. That happens to be the year generally accepted as the year Industry 4.0 began. And from the beginning, this has been the realm where our R&D has taken place. As a leader in the autonomous robotic space, many of our own inventions and custom builds operate in the Industry 4.0 space. We’re particularly proud of our Sentinel inspection robot (several of which are now working autonomously for a major US energy client), and also Captis – the leading solution in inventory cycle counting and precision scanning for large warehouses and other supply chain assets. InDro Robotics was the technology incubator for Captis, produced by Cypher Robotics. It’s already on the job in Canada, and will soon be deployed in New Zealand.

Below: The Captis cycle-counting and precision scanning system

Sentinel

INDRO’S TAKE

 

Industry 4.0 isn’t just a buzzword. It is a full-fledged transformation leveraging multiple complex technologies working in synergy for greater efficiency. Most of our clients have fully embraced IR4 or are in the midst of that transformation. And we, as always, continue to develop new robots, drones and other products for this new and exciting era.

“Industry 4.0 certainly draws on the framework laid by 3.0, but the technological advances of the past decade have been truly transformative,” says InDro Robotics Founder and CEO Philip Reece. “We are definitely in the midst of a new and exciting era, and InDro will continue to develop intelligent and innovative products for Industry 4.0. And yes, when 5IR eventually comes along…we’ll be ready.”

Want to learn more about how an InDro solution can help your company in IR4? Interested in learning how a private 5G network can offer smart factories a competitive and security edge? Head of R&D Sales Luke Corbeth is always up for a thoughtful conversation.

Dual manipulator Rosie the robot used for Industry 4.0 research

Dual manipulator Rosie the robot used for Industry 4.0 research

Oct 8, 2024 | Case Studies, InDro News, Innovation, Scott Simmie

By Scott Simmie

 

At least some of you will remember The Jetsons.

The television series, created by Hanna-Barbera Cartoons Inc., was a space-age version of The Flintstones (another Hanna-Barbera production). It originally aired in 1962-1963 with later episodes created in a reboot from 1985 to 1987.

But while Fred Flintstone drove a stone-age car (complete with stone wheels) that he powered by pushing his feet along the ground, George Jetson and his family lived in Orbit City, where Jetson commuted to his two-hour per week job via a flying car with a bubble top. And instead of having dinosaurs (including pterodactyls) help carry out tasks, The Jetsons live in a future where they’re surrounded by automated devices. You could think of their surroundings as the 1960s vision of the Smart Home.

And an integral part of that home? Well, that would be Rosey (later changed to ‘Rosie’) the robot.

Rosey was the family’s robotic maid. She carried out tasks that weren’t performed by the many other automatic conveniences that filled the Jetson’s home. She had two manipulator arms and an internally stored vacuum that be deployed on demand.

She was very useful around the house, carrying out tasks to save the family time.

And this story? Well, it’s about our own Rosie – which is also very space-age.

Below: A Rosie the robot publicity cel, signed by show creators William Hanna and Joseph Barbera. The cel was auctioned in 2018; image by Heritage Auctions

Rosie the Robot from The Jetsons Heritage Auctions image

THE ROSIE STORY

 

So. What is Rosie? We asked Head of R&D Sales Luke Corbeth for a snapshot.

“Rosie is a dual arm mobile manipulation robot designed for pick and place in an industry 4.0 setting,” he says. In other words, it has two arms and manoeuvres on a wheeled platform, and is capable of moving objects from one location to another or even manipulating a single object with both end effectors.

And Rosie has a few tricks up her sleeve. Or, more accurately, sleeves.

“The actual robot is very unique because it has six mounting points for the arms. So you can mount the arms on top, high on the side or low on the side to access shelving of different heights. In fact, you could actually mount one arm directly on the top right, for example, and then mount the second one on the bottom left. So you could grab something from the top of the shelf and from the floor at the same time, which is kind of cool, right?”

Yes, indeed.

Rosie’s home is not with the Jetsons (she has no vacuum cleaner) but in a new lab that hasn’t yet been officially launched at Polytechnique Montréal. It’s called the Intelligent-Cyber Physical System Lab, or I-CPS. So we contacted Lionel Birglen, a professor with the Department of Mechanical Engineering. We wanted to learn more about what the lab does, what he does – and what plans he has for Rosie (which InDro built and shipped in 2023).

Dr. Birglen is a PhD Mechanical Engineer, with a specialisation in robotics. He’s particularly interested in – and an expert on – manipulators and end effectors and has designed and built them. He’s written two books, holds three patents, and is the author or contributing author of at least 94 research papers. He’s also – get this – been listed among the top two per cent most-cited scientists in the world in his area of specialisation.

So it kinda goes without saying, but he’s a pretty big deal in this field.

Dr. Birglen has a deep interest in the role robotics will play in the future of industry. And, within that realm, he’s intensely interested in ensuring that robots, particularly those that will be sharing space with human beings on a factory or warehouse floor, will be safe.

And – he emphasises – he doesn’t trust simulations for important work like this.

“Because simulations lie. They lie all the time,” he says. “You have to understand that reality is infinitely more complex than anything you can have in simulation – so actual experiments are absolutely essential to me. They are essential to my work, to my understanding of what robotic manipulation is.”

“I believe in math, but I know that reality is different. It’s more complex, more complicated, and includes so many un-modelled phenomena.”

 

ROSIE’S JOURNEY

 

Dr. Birglen knew he wanted a new robot for use in the new lab (which we’ll get to shortly). And he knew he wanted a robot with two manipulator arms.

“Dual-arm robots are, in my opinion, the future for industry applications,” he says.

And while humanoid bipeds grab a lot of attention, they’re far more complex (and expensive) than wheeled robots. Plus, he says, most factory applications take place on a single level and don’t require climbing stairs.

“From a factory perspective, a wheeled platform makes a lot of sense because typically in factories you don’t have, say, five levels connected by stairs.”

So he knew he wanted an autonomous, wheeled, dual-arm robot. And he started, initially, to think of a company other than InDro for the build.

“I came across InDro almost by accident,” he explains. “Giovanni Beltrame told me about you because he has purchased many, many robots from you. He said: ‘Those guys can build and assemble the robot for you. They’re close and they do a great job.’ So that’s how I came in contact with you.” (We’ve written previously about the amazing work Dr. Beltrame is working on involving robots and space. You can find that here.)

And so, after a number of calls with Luke Corbeth and the engineering team to settle on design and performance parameters, work on Rosie began.

Below: Technologist Tirth Gajera (‘T’) puts the finishing touches on Rosie in 2023

Rosie and Tirth T

THE LAB

 

Polytechnique Montréal’s Intelligent-Cyber Physical System Lab (I-CPS) is set up as a highly connected Industry 4.0 factory. Faculty from four different departments – computer engineering, electrical engineering, industrial engineering and mechanical engineering (Dr. Birglen) – are involved with the lab. Interns and students, under supervision, also work in the facility.

“So we have four departments involved in this lab and the idea is to build a small scale factory of the future, meaning that everything is connected. We are building a mini-factory inside this lab,” he says.

So think of cameras that can track objects on shelves – and people and robots within the environment. Think of smart tools like a CNC machine, which will eventually be operated by Rosie. And, perhaps just as important as the connectivity within the lab, is connectivity to other research institutes in Quebec, including Université Laval, Université de Sherbrooke and École de Technologié Supérieure (ÉTS). All of those institutes are working with similar mini-factories, and they’re all connected. There’s even a relationship (and connectivity) with manipulator manufacturer Kinova. Funding came via a significant grant from the Canada Foundation for Innovation, or CFI.

“So think of our lab as like one node of this network of mini-factories around Quebec,” explains Dr. Birglen. That connectivity of all components is still a work-in-progress, but “ultimately the goal is that there is a cyber-connection between these different mini-factories, these different laboratories around Quebec, so that one part of one node can work in collaboration with another node in realtime.”

Plus, of course, a lot of learnings will take place within the individual labs themselves.

“We want to bring collaborative robots to work in tandem with humans,” he says. “We want our robots to safely move around people, we want robots to help people. And we also want robots to learn how to work from people.”

 

SAFETY, SAFETY, SAFETY

 

As mentioned earlier, there’s a huge emphasis on safety. And while there are international safety standards for collaborative robots, even a ‘safe’ cobot can pose a threat.

“All the collaborative robots that you have currently on the market more or less follow this technical standard and they are more or less safe, but they’re still dangerous,” explains Dr. Birglen. “And the classical example that we’ve all heard, and which is true, is that if a safe cobot has a knife in its hand and is moving around – it is very dangerous.”

So safety in the lab(s) is paramount – and that means safety at multiple levels. There must be safety:

  • At the task level; you must not have tasks that could endanger people
  • Safety at the control level
  • Safety in terms of collision detection, mitigation, obstacle avoidance
  • Safety at the data security level

Plus – and this really interests Dr. Birglen – you must ensure safety with any additional mechanical innovations that are introduced.

“What you develop, any mechanical system you develop, must be as much as possible intrinsically safe. And actually that’s one of the topics I’m currently working on is to develop end effectors and tooling that is intrinsically safe.”

Below: A LinkedIn post from Luke Corbeth shows Rosie, using both arms, inside the I-CPS lab

THE FUTURE

 

And why is research like this so important? What difference will it make to have robots and humans working safely together, with safe manipulators and end effectors that might even be able to, for example, lift an object in concert with a human being? And why the focus on interconnectedness between all of these facilities?

Well, there’s obviously the value of the research itself – which will lead to greater efficiencies, improved manipulators, gripping technologies, new algorithms and AI enhancements – as well as enhanced safety down the road. But there’s a much bigger picture, says Dr. Birglen, especially if you can get your head around thinking about the future from a global perspective.

China, he says, is no longer a developing nation. The days when the words “Made in China” meant poor quality are – with rare exceptions – gone. The country is, in fact, highly developed – and working at breakneck speed when it comes to innovation and adoption of robotics at scale. A revolution is underway that has massive implications for competitive advantage that simply cannot be ignored. So the research at  I-CPS is not merely important from an academic perspective, it’s strategic when viewed through a global economic lens.

“We as a country – meaning Canada – are in competition with other countries for manufacturing, for producing goods and services. China is a developed country and it is very, very, very good in robotics,” he states. “You know how in the past we saw China as producing low quality goods, low quality robots? That’s over, man. That’s finished.”

And?

“If they are investing in robotics like mad and we are not, we’re going to be a leftover – Canada is going to sink as a rich country. If you want to produce wealth in the 21st Century, you need robots, you need automation, you need integration. In short, you need to be the leader of the pack or you’re going to be eaten.”

It’s a stark warning – and it’s true.

I step outside as author and state this having lived in China back when it was still a developing country in the late 1980s – and having returned several times since then. The transformation has been nothing short of astonishing. How, you might ask, did it achieve all this?

The answer has its genesis with former Chinese leader Deng Xiaoping. who led the country from 1978 to 1989. He didn’t merely open the door to reform; he created policies that began sending waves of students from what had been a xenophobic country abroad to study. There was an emphasis on careers that could help modernise the nation, including all aspects of engineering, aerospace, construction, transportation, architecture, etc. That’s where all this began.

Thankfully (and with credit to federal funding agencies like CFI), there are projects like I-CPS underway – and academics like Dr. Lionel Birglen with the vision to push the needle safely forward.

Below: “Baxter” – the original dual-arm robot. Baxter is still at Polytechnique Montréal, but Rosie is the mobile future. Photo by Luke Corbeth

Baxter
Rosie

INDRO’S TAKE

 

We’re obviously pleased Polytechnique Montréal selected InDro to build Rosie. And we’re particularly pleased to see that she’s being deployed at I-CPS, as part of an integrated and networked research project that has such potentially profound implications for the future.

“I believe Dr. Birglen is correct in his assessment of the importance of robotics and automation in the future,” says InDro Robotics Founder and CEO Philip Reece. “And when you throw innovations with drones and even autonomous Uncrewed Aerial Vehicles capable of carrying large cargo loads and passengers into the mix, we are actually heading into a Jetsons-like future,” he adds.

“I think there’s a growing understanding of the implications of this kind of future from not only the private sector, but also federal regulators and funding agencies. At InDro our mission will always focus on continued innovation. Sometimes those innovations are our own inventions, but a key piece of the puzzle is R&D work carried out by academics like Lionel Birglen. We’re confident that Rosie’s arms are in the right hands.”

Interested in learning more about a custom robotics solution? Feel free to contact us here.