The Quantum Leap: Uniting Industry 4.0 and Quantum Computing

By Fawaz Aslam-Pervez, Partner, Business Development, Kyndryl.

  • Tuesday, 20th June 2023 Posted 1 year ago in by Phil Alsop

AI is reigning supreme, with generative AI tools like ChatGPT, Bard, and numerous other AI-driven chatbots and image generators capturing the spotlight. 2023 has been hailed as the 'year of AI,' witnessing the rapid development of countless AI tools in the past six months alone. However, amidst the AI frenzy, there's another technology quietly proving its prowess as a driving force behind automation, data analytics, Internet of Things (IoT) and even AI: quantum computing. With its immense potential, quantum technologies are poised to seize the next big opportunity, ushering in a new era of possibilities.

The growth of quantum technologies

Quantum computing harnesses extraordinary computational power, surpassing the capabilities of traditional supercomputers. At its core are quantum bits, or qubits, which possess the unique ability to exist as both zero and one simultaneously in an entangled state. This extraordinary property empowers quantum computers to simultaneously explore multiple possibilities and uncover optimal solutions.

The potential impact of quantum computing is profound. It holds the key to revolutionizing every sector, unlocking breakthroughs in materials and drug development, providing novel approaches to address environmental crises, enhancing communication security, and advancing fields such as food production and weather forecasting.]

Quantum computing has the potential to profoundly impact artificial intelligence (AI) and machine learning (ML) with transformative possibilities. As the demand for advanced AI and ML applications continues to rise, traditional computers are limited in their ability to meet the complexities of these tasks. Quantum computing offers exponential growth and the capability to address these challenges head-on, presenting an opportunity for groundbreaking advancements in AI and ML. By harnessing the power of quantum mechanics, quantum computing unlocks new possibilities, propelling these fields into a new era of innovation.

Government spending on quantum technology reflects the buzz around it, with the US committing $1.8bn to research and development in 2022 and the UK launching a 10-year programme to invest £2.5bn in March 2023. However, the technology is far from being fully developed or as accessible as AI tools have become. Most computer scientists predict it will take around 1 million qubits to realise the technology’s potential.

Industry 4.0 and its potential

Industry 4.0, also known as the Fourth Industrial Revolution, signifies the digital transformation of the manufacturing and industrial sectors. This revolution involves the convergence of IT, engineering technology (ET), and operational technology (OT), as well as the integration of emerging technologies across physical and digital environments. By

modernizing OT and fostering collaboration between IT, ET and OT teams through Industry 4.0 methodologies, manufacturers are revolutionizing the potential of the industrial sector.

Industry 4.0 is supported by nine fundamental pillars:

1. Autonomous systems

2. Internet of Things (IoT)

3. Augmented Reality (AR)

4. Simulation

5. Cloud computing

6. Big data

7. Systems integration

8. Additive manufacturing

9. Cybersecurity

Outlined by the Boston Consulting Group, these nine technologies are the drivers of Industry 4.0, enabling factories, warehouses, plants, and other industrial environments to become “smart” through the capture, optimisation, and deployment of data.

Where quantum computing meets Industry 4.0

Quantum computing has a number of applications within the manufacturing industry, with unmatched data capabilities able to help find new correlations in data, enhance pattern recognition, and advance classification beyond classical computing, enabling optimised data analytics and performance.

In production, quantum computing can be used with machine learning to analyse factors and processes to increase yield of products like semiconductor chips. Quantum computing also allows optimisations to be applied more dynamically to production flows and highly complex robotics, which would be very intensive for standard computing. This enables predictive analytics and more comprehensive quality control, using simulation technology to continually test components as they are being manufactured. As a result, future errors are minimised, security incidents are reduced, and unnecessary downtime is avoided.

Quantum computing also has the potential to optimise supply chain management by accelerating decision-making through things like route automation, as well as improving risk management with secure communication and cryptography. With supply chains evolving from a linear model into a more responsive, continuously shifting form, quantum computing can use real-time decision-making to meet these changing needs, adjusting supply chains based on industry demands.

A key example of quantum computing within the manufacturing industry today is Bosch. With over 120,000 connected machines and more than 250,000 devices used across their 240 plants, Bosch is using the vast amounts of sensor data taken from the machinery in just one plant to understand the ways in which they can improve operations as a whole. Using quantum computing and machine learning tools, Bosch is developing its own algorithms, based on existing data, to boost performance, productivity, and maintenance schedules.

Secure, educate, collaborate

As with most emerging technologies, quantum computing must be monitored carefully for security risks. The sheer power of quantum computing means it can unlock most encryption technology, making stored personal data or company IP vulnerable. Improved security measures are vital in protecting its use and future accessibility, and action from governing bodies is needed to ensure compliant behaviour before quantum computing becomes broadly commercialised.

To accelerate quantum computing’s adoption in Industry 4.0, academia, industry players, and policymakers need to collaborate and work towards building the relevant skills within their organisations. With the right specialist skills and robust quantum architecture, as well as collaborating with the right solution partners, organisations can unlock new frontiers of innovation that give them a competitive edge.

Quantum computing has the potential to revolutionize Industry 4.0, transforming not only manufacturing but also reshaping the landscape of AI and ML. By unlocking unprecedented data resources, quantum computing enhances manufacturing processes, supply chain management, and various technological domains, including AI, VR, and IoT. Embracing the convergence of quantum computing and Industry 4.0 empowers businesses to enhance agility, expedite decision-making, and mitigate risks, placing them at the forefront of manufacturing's evolutionary journey. Moreover, quantum technologies redefine the boundaries of AI and ML applications.

While quantum computing may not have experienced the meteoric rise in popularity that AI or Industry 4.0 has, its transformative power holds the potential to shape the future of all industries. It is poised to redefine the boundaries of what is possible and revolutionize the way we approach challenges in fields beyond AI or Industry 4.0, making a profound impact on the entire spectrum of industries.