TECH OFFERS

Conventionally, the design consideration of bearings is very much driven by the mechanical loading condition. With the advancement of wide bandgap (WBG) power electronic devices and pulse-wide modulation (PWM) control techniques, the electrification of motor drive system has found wide applications due to its compact size and high-power conversion efficiency, such as electric vehicles and more-electric aircrafts. However, motor drive systems incorporating high-speed switching devices produce time-varying high-amplitude common-mode (CM) voltage, which results in undesirable CM current in the motor drive system that also flows through the bearings. This phenomenon causes frosting, fluting, and pitting on the bearing and leads to premature bearing failures, which results in unexpected downtime of critical systems. Existing bearing test systems focus on the impact of mechanical load on bearing degradation, but no comprehensive bearing test system is available to evaluate the bearing degradation due to both mechanical and electrical loads. A comprehensive test system with the ability to include the electrical load has been invented. The test system allows the life-span prediction of the bearing under varying electrical load conditions (pulsed current amplitude and repetition rate) at realistic operating conditions with adjustable axial force, rotational speed, and thermal conditions. The measurement data collected can be used to quantity the effectiveness of different bearing designs on extending the lifespan of the bearing under the influence of electrical load. The team is seeking a commercial partner to further develop and bring this technology into commercialization. The bearing test system consists of: (1) Bearing-holder on a rotating shaft; (2) Subsystem to emulate mechanical load; (3) Subsystem to emulate electrical load; (4) Data acquisition subsystem to monitor the vibration as an indicator of health degradation of the bearing-under-test; (5) Software algorithm to estimate the lifespan of the bearing-under-test. The test system has the following adjustable test conditions: (1) Rotational speed up to 2500 rpm; (2) Axial force up to 10 kN; (3) Pulsed circulating current in the bearing up to 3A peak; (4) Pulsed current frequency up to 10 kHz. The potential collaboration partners are test and certification laboratories and bearing manufacturers. The measurement data collected from the bearing test system help evaluate the quality and reliability of any motor-driven products consist of bearings. Therefore, it can be deployed in various industries where bearings are used, such as the automotive, aerospace industry, marine, and energy industries. The bearing test system generates valuable data and insights of the bearing health condition under varying electrical load conditions that can emulate different power ratings of the motor drive systems without building the full systems. It can assist to design and develop high-performance bearings that are immune to electrical loads. The potential customers of the test system are manufacturers of bearings, machinery and equipment manufacturers, electric vehicle manufacturers, and industries that use high-power motor drive systems. Bearings are virtually used in every kind of equipment or machinery, ranging from automobile parts, farm equipment, and household appliances to defence and aerospace equipment. The global bearing market size was valued at USD 111.59 billion in 2022 and is expected to grow at a compound annual growth rate (CAGR) of 10.6% from 2023 to 2030. As one of the major causes of machinery downtime and productivity loss, the issue of bearing failure has become increasingly important in various industries. Therefore, a comprehensive and cost-effective bearing test system becomes a valuable tool in the market. The current bearing test systems primarily concentrate on assessing the influence of mechanical load on bearing degradation. However, there have been no reported bearing test systems that incorporate both mechanical and electrical loads. To address this gap and evaluate the bearing degradation mechanism caused by advanced power electronic devices (i.e., the electrical load), a novel test system has been invented with the ability to include both the electrical and mechanical loads during testing.  Bearing Degradation, Bearing Performance Evaluation, Bearing lifespan prediction, Electrical Load Electronics, Power Management, Manufacturing, Assembly, Automation & Robotics

In a world where resources are diminishing and demands are rising, the value of land has significantly increased for clean energy and food production. Agrivoltaic farming represents a potential game-changing solution that can bring substantial benefits to both the energy and food sectors. The patented technology is a tubular solar photovoltaic (PV) module designed for agrivoltaic farming. The unique tubular nature of the system allows sunlight, water, and wind to reach the plants below while simultaneously harnessing solar power. Moreover, the tubular modules can provide consistent partial shading to protect the plants and reduce ambient temperature and ground moisture loss. This technology enables the dual use of land by integrating agricultural activities such as farming and gardening with solar power generation, maximising the value derived from the limited land. The combination of energy harvesting and agriculture has significant potential to improve farming productivity, increase land-use efficiency, reduce carbon emissions, and promote environmental sustainability. The technology owner is keen to collaborate with partners interested in agrivoltaic farming like farmers, gardeners, agritech companies, research centres, and ministries to test-bed and adopt their tubular solar PV technology. The technology owner is also seeking industrial partners (e.g., manufacturers, system integrators, architects, designers, etc) to co-develop a complete solar energy solution or integrate the tubular solar PV modules into specific use cases. The technology owner has developed an innovative tubular solar PV module that integrates flexible thin-film solar PV stripes into glass tubes arranged in parallel. The unique design allows for the permeation of sunlight, rain, and wind through the module. The key features of this technology are: Efficient sunlight utilisation: unique design allows it to capture more direct sunlight for electricity conversion Sunlight and rainwater permeability: increase productivity and crop yields Wind permeability: enable the usage of structures with lower load bearing, reducing the system cost Partial cooling shading: reduce moisture loss and protects the plants from excessive solar radiation Consistent protection: protect the plants below from heavy rain and hail damage Long-term reliability: monolithic PV cells continue work when partially damaged or shaded Self-cleaning capability due to cylindrical shape: reduce maintenance cost compared to conventional panels Modular design with various sizes: allow customisation for specific requirements and facility scalability Horizontal solar PV elevation: enable simple and fast installation (seamless array over large area) The potential applications include but are not limited to: Farms (agriculture, aquaculture, viticulture, horticulture, etc.) Gardens (open gardens, green roofs, etc.) Building façade and rooftop Greenhouses Natural parks, reservoirs, and lakes Other applications (EV charging stations, outdoor canopies, cabanas, pergolas, etc.) The patented technology offers the following unique features: Maximised land-use efficiency: dual use of the land High energy efficiency: constant direct sun exposure Optimised plant growth: light, water, and wind permeability High reliability and good long-term performance Low operating expense (OPEX): negligible maintenance Agrivoltaic Farming, Agrophotovoltaics, Agrisolar, Dual-Use Solar, Ultra Low Light Sensitive PV, Agrivoltaics Energy, Solar, Sustainability, Low Carbon Economy

Rising energy consumption and electricity costs pose significant challenges for all businesses, from light commercial to heavy industrial sectors. Moreover, sustainability has become a crucial component of corporate strategies, particularly within the framework of environmental, social, and governance (ESG). Electrical energy optimisation is not just about cost savings, but also an approach towards resource conservation, power stability, equipment protection, as well as sustainable development. The technology owner has developed a transformer-based voltage optimisation system to reduce energy consumption, optimise electrical power supply, extend equipment lifespan, and lower carbon emissions. This patented technology can control the voltage to an acceptable minimum level and keep the current within the optimum range for best efficiency, providing an immediate and practical way for energy savings. The technology owner is keen to collaborate with industrial partners such as building management, property owners, industrial facility management in manufacturing sectors, etc. The technology owner is also seeking OEM partners to integrate this technology into building management systems (BMS) or co-develop a complete energy saving solution. The core of this technology has the electronic controller regulating the direction of the current in the coil, balancing the phase voltage, and filtering the harmonics from reactive loads, to sustain the highest performance while minimising power loss. The features of this technology are: 8 – 12% reduction in power consumption and electricity bill Improve the quality of overall electrical power supply Over-voltage protection to prolong equipment lifespan Real-time remote monitoring and analysis by app Compact and modular design (easy installation and fast repair) Compatible for both indoor and outdoor installation Enable scalable and customisable adoption for property portfolios Completely self-sufficient solution with virtually unlimited lifespan The voltage optimisation system is applicable for both commercial and industrial applications, especially industrial sectors with energy intensive equipment like motors and cooling devices. The potential applications include but are not limited to: Commercial buildings (shopping malls, office buildings, markets, restaurants, hotels, etc.) Industrial facilities (factories, warehouses, chemical plants, fabrication plants, etc.) Other infrastructures (airports, hospitals, train stations, sports complexes, institutes, etc.) The patented technology offers the following unique features: 8-12% immediate energy savings High efficiency of 99.7% with low system losses Reduce maintenance cost by increasing equipment lifespan Remote monitoring for smart energy management Return on Investment (ROI) in 12-24 months Voltage Optimisation, Energy Saving, Cost Reduction Energy, Sensor, Network, Power Conversion, Power Quality & Energy Management, Electronics, Power Management, Sustainability, Low Carbon Economy

There is an increasing requirement for systems that can detect people in built up space. The requirements come from diverse fields such as safety, security and sustainability. In the field of safety, video cameras or wearables have conventionally been used and both come with significant downsides. Video cameras are highly dependent on the line of sight and are privacy invasive while wearables introduce a burden on the end user. Microwave radar-based solutions are a field of research which can overcome the downsides by being accurate, not burdening the end user and by removing the requirement of line-of-sight. The company provides algorithmic solution in this space based on microwave radar in a Multi Input Multi Output (MIMO) configuration. The solution utilizes biological activity including respiration and heartbeat and consequently does not require measurement of the static environment in advance. The technology consists of an algorithmic solution to allow detection of live bodies using microwave radar. The proof of concept was done using wireless routers with custom antennas. The solution provides a resolution of under 1m for localization. The solution is not dependent on ‘line of sight’. The solution does not require any additional setup process for measurement of static environment and only a simple installation step needs to be performed. Human position is detected based on ‘Angle of Arrival’ calculations. The solution allows shared use of Wi-Fi hardware making it cost competitive versus millimeter wave based solutions. The applications include but are not limited to: Child Safety Monitoring Presence Detection Living Body Localization Security and Intrusion Detection The technology offers a non-invasive and a convenient method of tracking live bodies in a built-up environment. The competing technologies in the space are either inconvenient requiring the person to carry an instrument on them or are invasive because of the use of video cameras. Other non-invasive solutions such as those based on infrared suffer from performance issues as they are adversely affected by environmental factors while the ones using radar and AI require a setup step to recognize the static environment. AI based solutions also lack the capability of localization. An additional advantage of the technology is that it uses standard Wi-Fi allowing routers to compliment or replace additional sensor installation requirements in some cases. Electronics, Sensors & Instrumentation, Radio Frequency, Healthcare, Medical Devices, Infocomm, Internet of Things, Wireless Technology

Blowflies are insects often used for scientific research in fields such as forensics, veterinary science, ecology, and biology. Scientists study them at different stages of their lives, including maggots and adult blowflies.This technology relates to a fully operational and scalable multi-species insectary (Arthropod Containment Level 2) which focuses on harnessing the potential of non-medical blowflies for agricultural and waste management sectors. Firstly, blowfly maggots can be produced at scale to act as biodigesters to break down and convert agri-food waste or side streams to valuable blowfly insect protein. With additional processing, bioactive compounds can be extracted from these insect proteins with diverse applications in medicine and industry. When maggots mature into blowflies, they can be deployed for all-year-round insect pollination instead of bees. This can be conducted in controlled environments, including Indoor Vertical Farms, Greenhouses, and Polytunnels. This application has been validated with state-of-the-art UV lighting technology where blowflies are adept at locating flowers and conducting crucial pollination activities. The technology provider is actively seeking collaborative partnerships with stakeholders from the agriculture sector to enhance crop yields for farmers, while also aiming to collaborate with the waste management industry in order to minimize waste generation and transform it into valuable products through recycling. The insectary is designed with modularity and scalability, allowing for easy expansion or modification of the facility to accommodate various insect populations. It provides a fully contained environment that caters to all stages of the blowfly's life cycle, as well as other insects, ensuring proper housing and management. The insectary maintains a highly controlled environment that complies with Arthropod Containment Level 2 standards, operating as a no-odor facility with negative pressure, approved by National Environment Agency (Singapore). To optimize space utilization within the insectary and maintain separation between different insect populations, insects are carefully housed within netted cages stacked vertically. A specialized diet consisting of homogenized, strictly heterogeneous protein waste is provided to convert waste into valuable insect protein for diverse purposes. The insectary produces a substantial quantity of eggs necessary to sustain a closed-loop protein biodigester system, ensuring a continuous supply of insects for the biodigester. The insectary facilitates the emergence of newly developed blowflies, which can serve as alternative pollinators in Controlled Environment Agriculture (CEA), diversifying and enhancing pollination strategies for improved agricultural productivity. When complemented with a patented UV lighting technology, the insectary creates optimal environmental conditions for flower pollination, stimulating blowflies' active participation in the pollination process. Biodigesters: Blowfly maggots play a crucial role as biodigesters, efficiently converting waste protein into valuable insect protein. This sustainable process not only effectively manages waste but also yields a valuable protein source with diverse applications. Insect Pollinators: Blowflies can serve as effective insect pollinators, detecting flowers that are ready for pollination and being selectively recaptured and removed from indoor farming arenas after completing the pollination process. This innovative approach offers an alternative method of pollination, ensuring optimal crop production and enhancing agricultural sustainability. By harnessing the potential of blowfly maggots in these areas, there is an opportunity to explore innovative and sustainable solutions for both pollination and waste management. This exploration can lead to significant improvements in agricultural practices and resource utilization, contributing to enhanced sustainability in the agricultural sector. This technology also aims to revolutionize the aquaculture industry by eliminating disposables cost associated with waste management in a cost-effective and environmentally friendly manner. Waste Management Capability: The blowfly system is adept at handling high-protein waste, including offal and by-products generated from animal processing facilities like aquaculture. Unlike black soldier flies, blowflies excel specifically in breaking down protein waste. Their effectiveness in degrading protein-rich by-products makes them highly valuable for waste management in industries dealing with such materials. Continuous Supply and Expansion: The continuous supply of blowfly eggs ensures the expansion of current capabilities and guarantees long-term sustainability in waste management practices. This steady availability enables efficient and scalable operations. Ecological Compatibility: The insectary is designed to utilize native blowfly species in any country where it is established, ensuring ecological compatibility. By using local blowfly species, the system maintains harmony with the local ecosystem, promoting biodiversity and ecological balance. Versatile Applications of Insect Protein: Insect protein derived from blowflies serves as a sustainable source of fertilizers and can be further processed to extract bioactive compounds and enzymes. These valuable components meet the demands of medicinal and industrial sectors, expanding the potential uses and commercial value of insect protein beyond waste management. Year-round Pollination: Introducing blowflies as alternative pollinators enables year-round pollination activities, supporting agricultural production regardless of seasonal limitations. This consistent pollination fosters continuous crop growth and yield, contributing to agricultural sustainability. Enhanced Crop Quality and Value: Blowflies, as pollinators, contribute to the generation of better-quality crops, particularly fruiting crops, which command higher value in the market. This enhances the profitability of agricultural producers while meeting the growing demands for high-quality produce, resulting in improved economic outcomes for farmers.         Insectary, Pollination, Waste Valorisation, Agriculture, Biodigestor Life Sciences, Agriculture & Aquaculture, Waste Management & Recycling, Food & Agriculture Waste Management, Sustainability, Circular Economy

Lignocellulosic biomass side streams derived from the agri-food value chain such as agricultural residues, have the potential to be converted into high-value products, including biofuel, bio-composite construction materials, and sustainable packaging. Among the various conversion processes, pre-treatment plays a crucial role in maximizing the value of lignocellulosic biomass. The primary objective of pre-treatment is to address the complex and heterogeneous structure of the biomass by removing lignin, reducing biomass size, and increasing the surface area for hydrolysis. Unfortunately, current pre-treatment methods for lignocellulosic biomass are energy-intensive, costly, and produce inhibitory compounds that impact subsequent production stages. To overcome these challenges, this technology offers a catalytic oxidation pre-treatment process. This innovative approach operates under ambient or mild conditions, with a short reaction time, resulting in reduced energy consumption and treatment costs. The technology provider is seeking interested parties from the agricultural, biofuels, or biogas industry to license this catalytic oxidation pre-treatment process to enhance their operations and achieve a more sustainable and cost-effective production of valuable products from lignocellulosic biomass. The pre-treatment technology incorporates alkaline solutions, oxidizing agents, and synthetic catalysts to break down the recalcitrant structure of biomass and release soluble lignin. Mild operating conditions @ 1 atm pressure and 40-50oC Requires lower concentration & smaller volume of chemicals @ < 1% (w/v) Short reaction time (2-3 hours) Inhibitory compounds such as furfural and 5-HMF (Hydroxymethylfurfural) are removed in the process through oxidation This technology is mainly applied to pre-treat residual biomass but can be extended to the following applications: Lignin extraction Municipal sludge Palm Oil Mill Effluent (POME) treatment Recalcitrant wastewater treatment The biofuel industry is expected to grow at a CAGR of 7.9% by 2033. As companies look for more sustainable fuels for vehicles that cannot be easily electrised, biofuels will be the most suitable alternative to fossil fuels to cut down on carbon emissions. Valorization of agricultural waste that is rich in lignocellulosic cells as second-generation biofuels is also gaining prominence. Hence, this pre-treatment technology will be highly relevant in the coming years. Up to 90% energy savings @ ambient working conditions No inhibitory products produced High selectivity on aromatic compounds such as lignin increases the delignification effectiveness Lignocellulose, biomass, agrifood, Residual biomass pre-treatment, agriculture waste valorization, side stream Waste Management & Recycling, Waste-to-Energy, Food & Agriculture Waste Management, Sustainability, Circular Economy

Three-dimensional (3D) coil winding technology is a significant development in the field of coil manufacturing, enabling the creation of smaller, more efficient, and more complex coil structures. The need for 3D coil winding arises from the increasing demand for compact, high-performance electronic devices in various applications such as medical devices, automotive, aerospace, and communication equipment. These devices require coils that can fit into tighter spaces and operate at higher frequencies. Additionally, there is a growing need for coils with more complex shapes and designs to improve their performance and reduce manufacturing costs. This technology offer is a 3D coil winding method to produce complex coil structures. The method allows for precise control of the winding process, which enables the creation of coils with a wide range of shapes, sizes, and configurations. The technology can also incorporate multiple wires, producing multi-layered and multi-phase coils within the same structure. The technology owner is keen to do R&D collaboration and license the 3D coil winding technology to application developers from various industries.  This technology offer consists of a coil winding method that has the following features: Stable magnetic field distribution: The coil winding produced by this technology provides a stable magnetic field distribution, ensuring optimal performance of the electronic device. Space-saving: This technology allows for the production of smaller and more compact coils, which is critical in modern electronic devices where space is at a premium. Customization: 3D winding technology allows for the production of coils with a wide range of shapes, sizes, and configurations, making them ideal for various applications. Greater Flexibility: The ability to produce complex coil structures with 3D winding technology opens up new possibilities for the design of electronic devices, leading to new innovations and advances in technology. This technology offer can be customised for various applications, such as: Medical Devices: 3D coil winding technology can be used to manufacture coils for medical devices such as MRI machines and pacemakers, where performance and compact design are critical. Automotive: Coils produced using 3D winding technology can be used in various automotive applications such as sensors, actuators, and motors. Aerospace: 3D coil winding technology can be used in aerospace applications such as satellite systems, radar, and avionics. Communication Equipment: The technology can be used to manufacture coils for communication equipment such as antennas, receivers, and transmitters. Industrial Automation: Coils produced using 3D winding technology can be used in industrial automation applications such as robotics, servo motors, and machine tools. Power delivery: 3D coil winding technology can be used in high-power delivery, such as wireless charging for higher power density, improved thermal management, efficient and reliable designs. The unique value proposition of 3D coil winding technology is its ability to produce compact and efficient coils with complex shapes, sizes, and configurations, leading to improved performance, space-saving, and cost-effectiveness. This technology offer is a more advanced and precise method of coil winding, resulting in stable magnetic field distribution, thinner overall coil structure, and the ability to combine multiple structures into the same plane. These features make it an attractive option for a wide range of applications, including medical devices, automotive, aerospace, communication equipment, industrial automation, and renewable energy systems. The technology owner is keen to do R&D collaboration and licensing the 3D coil winding technology to application developers from various industries.  Electronics, Interconnects

Diabetes is a prevalent and growing health problem worldwide, affecting 1 in 10 people, with 90% of cases being type 2 diabetes. Congenital diabetes also affects 1 in 6 live births. In the next 20 years, diabetes is projected to increase by 46%. More than half a billion people are affected globally, 400,000 of them are in Singapore and if nothing is done by 2050, there will be one million diabetics patients in Singapore.   The company offers two technical solutions in form of a blended powder format: 1) Low Glycaemic Index (GI) and 2) Low Glycaemic Index (GI) with added protein.   The blend is plant-based, a source of protein, high in dietary fibre and replaces sugar from 20% to 100% in recipes across various food and beverage applications, it is versatile, high solubility, no alternation to original taste.   The solution is primarily targeted at Food Service sectors operators and manufacturers who seeks to penetrate the reduced sugar food & beverage market.  The technology consists of a proprietary blend (formulated by a renowned research institute based in Singapore) and consist of ingredients and composition that has clinically proven results of lowered GI. Affordable and cost effective compared to functional sugars No alteration to original taste of recipe Versatility of application due to its high solubility The applications include but are not limited to: Beverage Products (Bubble Tea, Ready-To-Drink, Pre-Packaged, Hot & Cold Beverages) Bakery Products (Cookies, Muffins, Pies, Tarts, Cakes, Brownies) Dairy (Milkshakes, Ice Creams, Gelato, Frozen Yogurt) Desserts (Asian & Western) The global reduced sugar food & beverage market size is at US$46.1bil, growing at CAGR of 9.53% in next 5 years, APAC is the fastest growing region, valued at US$12.9bil. It is a global movement to fight against diabetes through educational campaigns and government intervention. The Singapore Government decided to introduce mandatory nutrition labels and advertising prohibitions for Nutri-Grade beverages across all formats. The innovative solution offers immense versatility, catering to a broad spectrum of food items. Unlike the current state-of-the-art, which primarily focuses on baked goods and rice, the technology is not restricted to the same spectrum offered by competitors. The potential applications of the technology are limitless, offering a significant advantage over existing solutions. Furthermore, clinical trials have been conducted to validate the efficacy of the technology in food product sets them apart from the current state-of-the-art. In addition, the company possess the technological capabilities to demonstrate the effectiveness and efficacy of their solution across a broad range of food items. This ability to provide concrete evidence of their technology's efficacy offers a compelling advantage to customers looking to adopt innovative, effective, and reliable solutions to meet the demands of the growing diabetic and obese market. Low GI, Low Glycaemic Index, Low Glycaemic Load, Diabetics friendly, Low Glycemic Index, Obesity, Reduced sugar, Better for you, Keto friendly, Plant based, vegan, Healthier choice, HCS, Nutri grade, Halal certified Foods, Ingredients

Terahertz (THz) radiation is a form of electromagnetic radiation that lies in the frequency spectrum ranging between microwaves and infrared light. In the field of Non-Destructive Testing (NDT), THz radiation is utilised to inspect materials for imperfections or anomalies. THz radiation can penetrate numerous non-metallic materials and can reveal internal structures that are not visible in natural light or x-ray imaging. THz-based NDT finds applications in a variety of applicatins, including aerospace, electronics, and medical imaging. Each material possesses a unique fingerprint that enables its identification, differentiation, condition, quantification, and quality of materials through spectroscopy. This technology offer is a spectral sensing technique that utilises accessible terahertz technology. It includes a portable device equipped with industrial-grade sensors and cloud-based data analytics. The technology owner is keen to engage in R&D collaboration with industrial partners in various industries, including pharmaceuticals, food packaging quality inspection and public safety inspection.     The technology offer is a reliable solution for non-disruptive inspection and measurement of materials:  It boasts high accuracy and multi-layer penetration capabilities. The accuracy rate of 95% in laboratory conditions provides users with confidence in the results produced. The wide measurement range of 30μm to 100μm and beyond with an accuracy of approximately ±4μm makes it suitable for various applications. The multi-layer penetration capability of up to four layers of material allows for the inspection of layered materials or detection of defects within multiple layers. Designed to increase productivity and efficiency, the technology provides accurate measurements and multi-layer penetration capabilities for faster decision-making and efficient use of resources. The technology offer is versatile, suitable for quality control and inspection in the manufacturing, electronics, medical, and aerospace industries.   This technology offer can be expanded and deployed in various industry such as: Package inspection Security and screening Spectroscopy, medical imaging Material science, chemical analysis Food quality control Terahertz (THz) technology offers numerous advantages over other radiation-based technologies. One key benefit is its ability to penetrate non-conductive materials, making it useful for imaging and inspecting plastic, paper, wood, cloth, ceramics, and other materials. THz technology is also safe and non-radioactive, making it a preferred choice for imaging and analysis. THz technology is non-contact and non-destructive, making it an ideal tool for Non-Destructive Testing (NDT) applications. It can detect defects and flaws within materials without requiring physical contact and provides high-resolution images with sub-millimeter accuracy. THz technology is valuable for composition identification by analyzing the spectral fingerprints of materials, allowing for non-invasive identification and characterization of materials. This feature is useful for security, pharmaceuticals, and food analysis applications. The technology owner is keen to engage in R&D collaboration with industrial partners in various industries, including pharmaceuticals, food packaging quality inspection and public safety inspection. mmwave, terahertz Electronics, Sensors & Instrumentation, Radio Frequency