NTU Singapore Launches Three New Space Projects Under National Space Technology Development Programme

Singapore's Ambitious Push into Space Technology

Nanyang Technological University (NTU), Singapore—one of Asia's leading research-intensive universities—has taken a significant step forward in the nation's burgeoning space sector. On February 2, 2026, NTU announced the launch of three innovative space projects under the government-backed Space Technology Development Programme (STDP). These initiatives, part of the Space Access Programme (SAP), aim to validate cutting-edge technologies in orbit, accelerating their commercialization and positioning Singapore as a key player in the global space economy. 49 48

The STDP, administered by the Office for Space Technology and Industry (OSTIn), has invested over S$200 million since 2022 to nurture local space capabilities. With an additional S$60 million secured in 2024, the programme supports everything from technology development to in-orbit testing. For universities like NTU, this represents not just research funding but a gateway to hands-on space missions that train the next generation of engineers and scientists. 45

These projects underscore NTU's pivotal role in Singapore's higher education landscape, where interdisciplinary collaboration between academia, startups, and industry drives national priorities. As Singapore prepares to establish the National Space Agency (NSAS) on April 1, 2026, under the Ministry of Trade and Industry, such university-led efforts highlight how higher education institutions are fueling economic growth in high-tech fields.

NTU's Legacy as Singapore's Space Pioneer

NTU Singapore has been at the forefront of the country's space endeavors since the early 2000s. The university's Satellite Research Centre (SaRC), established in 2011, has spearheaded the VELOX (Versatile, Efficient, Lightweight, and eXpendable) satellite series—the backbone of Singapore's space programme. VELOX-C1, launched in 2014 via India's PSLV rocket, marked Singapore's first locally built satellite, demonstrating technology demonstration and technology in space. 49

Subsequent missions like VELOX-II in 2015 and VELOX-AM in 2019 expanded capabilities in laser communications, propulsion, and Earth observation. Today, SaRC boasts over two decades of experience, having deployed more than a dozen satellites and payloads. This track record made NTU a natural choice for the latest SAP projects, which build on proven expertise while pushing boundaries in artificial intelligence (AI), propulsion, and optics.

Professor Warren Chan, Dean of NTU's College of Engineering, emphasized, “With over two decades of experience, NTU has built a strong track record in co-developing and deploying satellite technologies rapidly and cost-effectively.” This legacy not only elevates NTU's global standing but also creates opportunities for students and faculty in aerospace engineering, electrical engineering, and materials science—fields central to Singapore's universities. 49

The First Project: AI-Enabled Nanosatellite for Edge Computing

The flagship of the trio is Singapore's first AI-powered nanosatellite, a 3U CubeSat measuring 30cm x 10cm x 10cm and weighing under 5kg. Scheduled for launch in 2026 into a sun-synchronous orbit at approximately 500km altitude, this mission will test edge-computing AI capabilities that process data onboard. 48

Traditional satellites downlink massive raw image data—hundreds of megabytes to gigabytes daily—straining bandwidth and delaying analysis. NTU's satellite uses compact AI models to analyze images in real-time: identifying cloud cover, detecting anomalies like forest fires or oil spills, and transmitting only prioritized insights (kilobytes to megabytes). This reduces latency from hours to minutes, enabling rapid responses for disaster management or environmental monitoring. 49

The satellite also validates next-generation perovskite solar cells, lightweight and printable panels developed collaboratively by NTU's Schools of Electrical and Electronic Engineering, Materials Science and Engineering, and startup Singfilm. These cells promise higher efficiency in space's harsh radiation environment compared to silicon-based alternatives.

Led by SaRC scientists and integrated into a platform built by Singapore firm Satoro Space, the one-year mission demonstrates how university research translates to practical, agile space systems. SaRC Executive Director Lim Wee Seng noted, “Intelligent satellites can decide what matters onboard, ensuring precious space bandwidth is used to deliver answers, not noise.” 48

🚀 Second Project: Propulsion Innovation with the MUSIC Engine

Building momentum, the second project deploys a larger 16U nanosatellite (40cm x 30cm x 30cm, up to 30kg) in 2027 to test advanced propulsion and environmental sensors. At its core is the MUlti-Stage Ignition Compact (MUSIC) engine, developed by NTU spin-off Aliena.

The MUSIC engine ionizes a gas propellant using electric and magnetic fields, generating efficient thrust for precise orbit maneuvers—essential for maintaining satellite constellations in crowded low Earth orbit (LEO). This addresses challenges like orbit raising, deorbiting for sustainability, and collision avoidance amid the projected 100,000+ satellites by 2030.

Complementing the engine is an Atomic Oxygen Detector from NTU's Temasek Laboratories, measuring corrosion from atomic oxygen in Very Low Earth Orbit (VLEO, below 300km). VLEO offers drag-based propulsion savings but accelerates material degradation; this data will inform durable designs for future missions. 47

Aliena CEO Dr. Lim Jian Wei, Mark, highlighted, “With the growing number of satellites in low Earth orbit, advanced in-orbit mobility is no longer optional.” The 1.5-year mission underscores NTU's role in spinning out commercial ventures from university labs. 49

Third Project: LEOCAM – Revolutionizing Earth Observation

Rounding out the projects, LEOCAM—a locally developed electro-optical imaging payload—will be validated on the International Space Station (ISS) in 2028 for six months. Unlike conventional lens-based cameras, LEOCAM's triple-mirror setup delivers sub-meter resolution, capturing details like one-meter-wide objects for urban planning, agriculture, and defense applications.

Developed by LightHaus Photonics, this payload marks Singapore's first space-qualified optical system. CTO Dr. Phua Poh Boon stated, “We are excited to test our optical imaging payload on the ISS, a key milestone for LightHaus as the first Singaporean company to build a space-based optical system.” 49

ISS deployment provides a stable, high-altitude platform (around 400km) for rigorous testing, accelerating technology readiness levels (TRL) from lab prototypes to operational heritage.

Strategic Partnerships Driving Innovation

NTU's projects thrive on collaborations. Satoro Space provides the reliable CubeSat bus for the AI satellite, while Aliena's propulsion tech stems from NTU research. LightHaus Photonics and Singfilm exemplify how startups leverage university IP.

Satoro Chairman Maverick Shih praised, “The cooperation between NTU’s SaRC and SATORO allows us to implement projects locally, helping research institutes develop cutting-edge space technology rapidly.” These ties extend STDP's archetype 3 (space access) to foster a vibrant ecosystem. 49

For higher education, such partnerships offer students internships and co-op programs. Aspiring researchers can explore roles via platforms like higher-ed-jobs or university-jobs, where space tech demands skilled graduates.

Impacts on Singapore's Higher Education Landscape

These NTU space technology projects ripple through Singapore's universities, enhancing STEM curricula and research output. NTU's involvement elevates its ranking among global peers, attracting top talent amid competition from NUS and overseas institutions.

Students gain from hands-on projects: from designing AI algorithms to fabricating solar cells. Faculty secure grants, publish in top journals, and mentor PhDs—key for career progression. The STDP's focus on IHLs (Institutions of Higher Learning) ensures equitable access, with calls open to all Singapore universities. 45

• Boosts employability in aerospace, with Singapore's space sector projected to contribute S$5.7 billion to GDP by 2030.
• Fosters interdisciplinary skills: AI + engineering + materials science.
• Encourages spin-offs like Aliena, creating postdoc and lecturer opportunities.

Professionals seeking transitions can consult higher-ed-career-advice for tips on academic CVs and research roles.

Challenges and Solutions in Nano-Satellite Development

Despite promise, nano-satellites face hurdles: radiation hardening, thermal management, and regulatory compliance for spectrum allocation. NTU addresses these through iterative VELOX testing and SAP's streamlined access.

Global trends favor smallsats—SpaceX's rideshares reduce costs to under S$1 million per launch—enabling non-spacefaring nations like Singapore. STDP 2.0 from 2025 pivots strengths in AI and robotics to space manufacturing and life sciences.

Risks include launch delays and tech failures, mitigated by redundant designs and ISS backups for LEOCAM.

Future Horizons: NSAS and Beyond

With NSAS launching in April 2026, Singapore eyes policy frameworks for sustainable space activities. NTU's projects pave the way for constellations in remote sensing and comms, aligning with national imperatives like climate monitoring.

By 2030, experts predict a robust ecosystem with 100+ local firms. Universities will lead, training 1,000+ space professionals annually. Explore opportunities at Singapore higher ed jobs.

Conclusion: Elevating Singapore's Academic Excellence

NTU Singapore's three new space projects exemplify how universities propel national innovation. From AI smarts to propulsion prowess, they promise transformative impacts. For educators, researchers, and students, this is a call to engage—check rate-my-professor, pursue higher-ed-jobs, or seek career advice. Singapore's stars are rising, powered by its higher education institutions.