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Manual built environment inspection suffers from multiple issues such as shortage of manpower, human error and miscommunication. To overcome these issues, there is a need for an automated and centralized inspection system capable of detecting multiple defects of interest and presenting the inspection results in an easy to access format. The technology presented uses data acquired from LiDAR and Cameras mounted on an autonomous robot to inspect building interiors and external facades. The system utilizes an AI engine and can accurately detect defects such as cracks, holes, and other built imperfections stated in building quality guidelines such as CONQUAS. Defect reports can be autonomously generated after the acquired image and LiDAR data has been processed by the AI analytics engine. 

According to Food and Agriculture Organization (FAO), invasive insects cost the global economy around US$ 70 billion each year. Rising temperatures, longer seasons, and changing weather patterns are creating more favourable conditions for insects to thrive in many areas, leading to increased infestations in crops. Traditional pest management methods in food crops, such as frequent spraying of insecticides and repeated inspection, are labour intensive and can have negative environmental impacts. This technology offers a promising solution to these challenges. It simultaneously reduces the particle size of insecticides and modifies their surface properties, which increases foliar uptake by several folds. Once absorbed by leaves, the insecticides are no longer prone to wash off or environmental degradation, resulting in a substantially longer residual treatment effect and a reduction in usage volumes and reapplication frequencies of the insecticides. This technology is designed as a ready-to-use adjuvant that works with commercialised insecticides. Growers can independently and safely nano encapsulate the insecticides with basic mixing equipment and a simple, one-step mixing process.

Root rot diseases in food crops are devastating diseases currently without solution. Examples of such diseases are the Basal Stem Rot in oil palms, Fusarium Wilt in bananas, and Phytophthora Root Rot in citrus.  While fungicides have in vitro efficacy, most do not possess phloem mobility and therefore cannot reach the roots to effect treatment. Thus, despite widespread usage of fungicides, root rot diseases are still inadequately treated or are not treated at all. This Nano Delivery Technology imparts phloem mobility to fungicides, allowing them to reach the roots from the application site to treat and protect the crops. The technology is designed as a ready-to-use adjuvant that works with commercialised fungicides. Growers can independently and safely nano encapsulate the fungicides with basic mixing equipment and a simple, one-step mixing process. This technology is patent-pending and ready to market.

Developed a cutting-edge IoT-based Irrigation System, uses proprietary algorithms and a suite of integrated hardware to intelligently optimize watering schedules based on various inputs like soil moisture levels, raining status, weather forecasts, plant species, and soil moisture needs. This smart irrigation system has been built to address the common issue of water waste and poor irrigation management in agriculture, horticulture, and landscaping sectors. Potential users for this technology are large-scale farmers, landscapers, gardening centres, municipalities managing public parks, and property management company seeking smart community solutions. This innovation aims to revolutionize irrigation management by providing an efficient, data-driven irrigation system that not only optimizes watering for different plant species but also significantly reduces water consumption and system maintenance needs.

In precision manufacturing, the ability to maintain optimum efficiency and accuracy is of critical importance. This AI Platform addresses these challenges by utilizing proprietary self-improving AI models for Automatic Defect Classification (ADC). This innovative solution incorporates AI Equipment Automation and Root Cause Mapping and provides a comprehensive system that significantly enhances production efficiency. The system seamlessly integrates Equipment Risk Analysis into existing alert mechanisms thus reducing downtime and increasing yield. At its core, it operates as a robust AI platform, featuring a user-centric interface for Machine Learning Operations (MLOps). This promotes recipe-free inspection while maintaining compatibility with a broad range of third-party software. The technology is modular and provides smooth productization of multiple AI solutions thereby increasing the effectiveness of defect inspection and analysis, assisting in equipment error recovery, and providing insights for process optimization. The technology offers an attractive solution for manufacturers across different industries interested in increasing their production efficiency and improving product quality.

Amidst the imposition of compulsory climate reporting by regulatory bodies in some nations including Singapore, a powerful carbon accounting software solution has been devised. This aims to aid and fortify companies in their readiness to adhere to this necessity and embark on their sustainability journey. The software suite consists of the following solutions: GHG Emissions Management: Efficiently manage and reduce your organisation's greenhouse gas (GHG) emissions. ESG Reporting: Streamline and simplify your Environmental, Social, and Governance (ESG) reporting process. Environmental Compliance: Propel your organisation towards comprehensive ISO 14001 environmental stewardship. 24/7 Electricity Emissions Traceability: Navigate your decarbonisation journey with real-time, precise and transparent electricity emissions tracking.

With the recent surge in the risk of pathogens and viruses, there has been a strong demand for hygiene-focused products globally. In public health, there is an increasing need to obtain more sterilised water and to create a hygienic environment with sterilised water. Ozone dissolved in water, commonly known as ozonated water, has been used to produce safe drinking water at water purification plants because of ozone's sanitising properties. However, conventional gas dissolution methods have limited their applications because it is difficult to incorporate both safe ozone production and ozone dissolution into water in the same small product. This technology is a modular sanitary device that is able to electro-produce ozonated water for sanitisation. This device can, on-demand, instantly generate ozonated water via electrolysis. The ability for on-demand generation circumvents the problem where ozonated water loses its sanitising properties over time. Furthermore, this modular device can be easily designed to have variable performance depending on the number of devices connected and the control of current and flow rate. Therefore, the device can be easily designed to be integrated into existing products (e.g., household water purifiers, etc.). Lastly, this compact device that can efficiently generate sterilising ozone water is expected to address dissolution problems in various systems such as public health, medical treatment, etc.

Singapore has a high consumption of fruits and vegetables, both locally produced and imported, and a significant portion of the total waste generated is derived from fruits and vegetables. These fruits and vegetables contain untapped nutritional and functional properties that can be upcycled into higher value products. This institute of higher learning has developed a technology with the know-how to cultivate microorganisms and a series of zero-waste extraction and purification methods to maximize the value of fruit peels into functional food ingredients.  This technology is designed for three types of industry players: i) fruit vending/processing industry with abundance of good quality fruit by-products; ii) waste management industry with technologies to value add to the by-products; and iii) start-ups with keen interest to upcycle by-products into novel food ingredients.

Population aging is a global phenomenon as most industrialized countries are experiencing growth in the size and proportion of elderly citizens in their population. The percentage of older adults is estimated to be double by 2050 than that in 2019, which will place new challenges on the social economy and healthcare. The increasing population of elderly people requires great attention to be paid to age-related problems. Especially, the decreased physical capacities cause elderly people to rely on others to perform daily activities such as showering, dressing, and eating. The lack of independence in activities of daily living (ADL) decreases their quality of life and exaggerate financial burden for family healthcare.   According to studies on affected daily activities of older adults, the showering activity needs more frequent assistance than any other ADL. Existing commercial products, such as Tutti Assisted Bath Tub and Sit & Shower, can provide automated bathing assistance for the elderly people. However, the available products are usually time-based passive cleaning that lacks active physical interactions with users, and thus they do not have some basic functionalities during showering such as scrubbing and wiping. Alternatively, robotic arms can provide active support in showering activity. Recent soft robotics technologies ensure safe and comfortable human-robot interactions. With different types of actuation (e.g. pneumatic, cable-driven), soft robotic manipulators can have dexterous motions and adaptable stiffness to achieve desired tasks.