Navigating the New Frontier: AI and Testing in Space and Telecom
June 14, 2025, 10:09 am
Location: France, Ile-de-France, Paris
Employees: 1001-5000
Founded date: 1975
Total raised: $198.67K
In the vast expanse of space and the intricate web of telecommunications, two sectors are converging. They are driven by innovation, propelled by technology, and fueled by the need for reliability. As we stand on the brink of a new era, the importance of artificial intelligence (AI) and rigorous testing cannot be overstated. These elements are the unsung heroes, quietly ensuring that our devices and spacecraft operate seamlessly.
Glasgow's Craft Prospect Ltd (CPL) is making waves in the space sector. The company recently secured a contract with the European Space Agency (ESA) to develop machine learning algorithms for spacecraft navigation. This project, dubbed Robust real-time constrained optimal control using machine learning (ROC-ML), aims to tackle the complexities of motion planning in space. Imagine navigating a spacecraft through a minefield of debris, where every decision counts. That’s the challenge at hand.
CPL’s collaboration with the University of Glasgow is a marriage of expertise. The project will explore how AI can enhance guidance, navigation, and control systems. The stakes are high. Space missions are fraught with uncertainty. Targets can spin wildly, and debris can lurk in unexpected places. AI acts as a guiding star, helping spacecraft make real-time decisions in chaotic environments.
The ROC-ML project is not just theoretical. It’s grounded in practical application. The team is developing a hardware-in-the-loop simulator to train and demonstrate the AI-augmented guidance navigation and control (GNC) system. This agile approach to product development allows for rapid prototyping and iterative testing. The goal is clear: validate the AI-optimized motion planning capabilities by 2026.
Meanwhile, in the realm of telecommunications, Tatyana Krasik is a beacon of reliability. Her work in high-frequency compliance and satellite validation underscores the critical nature of testing in modern telecom. Behind every smooth video call or seamless app update lies a complex web of testing protocols. These protocols ensure that networks perform as expected, even under pressure.
The global 5G device testing market is booming, projected to exceed $2.5 billion in 2025. This surge is driven by the demand for automated solutions capable of handling the complexities of new radio frequency (RF) systems. As telecom equipment evolves, the reliability of testing systems becomes paramount. It’s not just about flashy marketing; it’s about the engineering that keeps everything running smoothly.
Krasik’s journey is a testament to the importance of precision. With a background in radio electronics and test automation, she has navigated the intricate world of 5G and satellite communications. Her work at Ceragon Networks exemplifies this. There, she developed a calibration solution that reduced testing time and enhanced operational performance. This innovation was crucial for the successful launch of Ceragon’s IP-50EX platform, reinforcing its reputation in high-reliability 5G transport solutions.
The challenges in testing are not just technical; they are regulatory. In the U.S., the Federal Communications Commission (FCC) and the European Telecommunications Standards Institute (ETSI) impose stringent regulations. These regulations ensure that devices do not interfere with critical systems, such as emergency services or air traffic control. One careless device can have catastrophic consequences, as illustrated by a case where a truck driver’s jammer disrupted GPS at an airport.
Krasik’s role at Hermon Laboratories involved preparing test setups and ensuring compliance with these regulations. Her expertise helped manufacturers navigate complex approval processes, facilitating faster market entry and reducing rework costs. This behind-the-scenes work is essential for making advanced communication systems safe and globally deployable.
As the space sector pushes for mobile broadband in remote areas, the demand for RF testing intensifies. The increasing density of satellites in low Earth orbit raises the stakes. Signal interference and orbital congestion are real threats. Rigorous RF testing is vital to ensure that satellite communications remain reliable and do not contribute to space debris.
Krasik’s contributions to AST SpaceMobile highlight the intersection of space and telecom. She helped define RF testing strategies for satellite communication modules, developing custom testing tools that simulate satellite conditions. This work is crucial for ensuring that systems perform reliably in the harsh environment of space.
The future of 5G and space connectivity hinges on the invisible infrastructure that supports them. Test engineering is evolving from a mere operational role to a strategic one. As networks become more complex, the need for robust testing systems grows. The reliability of these systems shapes the very fabric of connectivity.
In this landscape, AI and testing are not just buzzwords; they are the backbone of innovation. They ensure that our devices work as intended, whether in the depths of space or the heart of urban environments. As we venture into this new frontier, the importance of these elements will only increase.
In conclusion, the convergence of AI in space navigation and rigorous testing in telecommunications paints a picture of a future where connectivity knows no bounds. The work being done by companies like Craft Prospect and engineers like Tatyana Krasik is paving the way for a world where technology seamlessly integrates into our lives. As we look to the stars and beyond, we must remember the silent guardians of our digital age—the engineers and innovators who make it all possible.
Glasgow's Craft Prospect Ltd (CPL) is making waves in the space sector. The company recently secured a contract with the European Space Agency (ESA) to develop machine learning algorithms for spacecraft navigation. This project, dubbed Robust real-time constrained optimal control using machine learning (ROC-ML), aims to tackle the complexities of motion planning in space. Imagine navigating a spacecraft through a minefield of debris, where every decision counts. That’s the challenge at hand.
CPL’s collaboration with the University of Glasgow is a marriage of expertise. The project will explore how AI can enhance guidance, navigation, and control systems. The stakes are high. Space missions are fraught with uncertainty. Targets can spin wildly, and debris can lurk in unexpected places. AI acts as a guiding star, helping spacecraft make real-time decisions in chaotic environments.
The ROC-ML project is not just theoretical. It’s grounded in practical application. The team is developing a hardware-in-the-loop simulator to train and demonstrate the AI-augmented guidance navigation and control (GNC) system. This agile approach to product development allows for rapid prototyping and iterative testing. The goal is clear: validate the AI-optimized motion planning capabilities by 2026.
Meanwhile, in the realm of telecommunications, Tatyana Krasik is a beacon of reliability. Her work in high-frequency compliance and satellite validation underscores the critical nature of testing in modern telecom. Behind every smooth video call or seamless app update lies a complex web of testing protocols. These protocols ensure that networks perform as expected, even under pressure.
The global 5G device testing market is booming, projected to exceed $2.5 billion in 2025. This surge is driven by the demand for automated solutions capable of handling the complexities of new radio frequency (RF) systems. As telecom equipment evolves, the reliability of testing systems becomes paramount. It’s not just about flashy marketing; it’s about the engineering that keeps everything running smoothly.
Krasik’s journey is a testament to the importance of precision. With a background in radio electronics and test automation, she has navigated the intricate world of 5G and satellite communications. Her work at Ceragon Networks exemplifies this. There, she developed a calibration solution that reduced testing time and enhanced operational performance. This innovation was crucial for the successful launch of Ceragon’s IP-50EX platform, reinforcing its reputation in high-reliability 5G transport solutions.
The challenges in testing are not just technical; they are regulatory. In the U.S., the Federal Communications Commission (FCC) and the European Telecommunications Standards Institute (ETSI) impose stringent regulations. These regulations ensure that devices do not interfere with critical systems, such as emergency services or air traffic control. One careless device can have catastrophic consequences, as illustrated by a case where a truck driver’s jammer disrupted GPS at an airport.
Krasik’s role at Hermon Laboratories involved preparing test setups and ensuring compliance with these regulations. Her expertise helped manufacturers navigate complex approval processes, facilitating faster market entry and reducing rework costs. This behind-the-scenes work is essential for making advanced communication systems safe and globally deployable.
As the space sector pushes for mobile broadband in remote areas, the demand for RF testing intensifies. The increasing density of satellites in low Earth orbit raises the stakes. Signal interference and orbital congestion are real threats. Rigorous RF testing is vital to ensure that satellite communications remain reliable and do not contribute to space debris.
Krasik’s contributions to AST SpaceMobile highlight the intersection of space and telecom. She helped define RF testing strategies for satellite communication modules, developing custom testing tools that simulate satellite conditions. This work is crucial for ensuring that systems perform reliably in the harsh environment of space.
The future of 5G and space connectivity hinges on the invisible infrastructure that supports them. Test engineering is evolving from a mere operational role to a strategic one. As networks become more complex, the need for robust testing systems grows. The reliability of these systems shapes the very fabric of connectivity.
In this landscape, AI and testing are not just buzzwords; they are the backbone of innovation. They ensure that our devices work as intended, whether in the depths of space or the heart of urban environments. As we venture into this new frontier, the importance of these elements will only increase.
In conclusion, the convergence of AI in space navigation and rigorous testing in telecommunications paints a picture of a future where connectivity knows no bounds. The work being done by companies like Craft Prospect and engineers like Tatyana Krasik is paving the way for a world where technology seamlessly integrates into our lives. As we look to the stars and beyond, we must remember the silent guardians of our digital age—the engineers and innovators who make it all possible.