Qatar-Singapore Joint Innovation Challenge

Fostering innovation and collaboration between Singapore-based startups and Qatari entities across critical sectors such as energy, environmental sustainability, insurance, and information technology.

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CHALLENGE AREAS

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CHALLENGE STATEMENTS

Click on each of the challenge statements below to view the details.
Complete your submission by March 1st, 2024 at 23:59pm (SGT/GMT +8).

Sustainable Infrastructure/System

How can we enhance the process, installations, or longevity of sea-floating solar energy farming?

Up to S$130,000 funding from QRDI Council to support solution development and piloting

Up to S$20,000 grant support from EnterpriseSG

Access to datasets and facilities

Smart Transport Optimisation

How might we build an optimised allocation system to enable the planning and optimisation of high value and limited asset resources for transportation in airports?

Up to S$130,000 funding from QRDI Council to support solution development and piloting

Up to S$20,000 grant support from EnterpriseSG

Access to datasets and facilities

Waste Treatment and Recycling

How might we develop recovery and recycling solutions for the sludge and waste water treatment?

Up to S$130,000 funding from QRDI Council to support solution development and piloting

Up to S$20,000 grant support from EnterpriseSG

Access to datasets and facilities

Sustainable Infrastructure/System

How might we develop a carbon footprint calculator for aluminium production to enable carbon footprint accounting effectively and transparently?

Up to S$130,000 funding from QRDI Council to support solution development and piloting

Up to S$20,000 grant support from EnterpriseSG

Access to datasets and facilities

Sustainable Infrastructure/System

How might we develop an Environmental Impact Assessment (EIA) Tool to assess the environmental footprint for new projects within the Environmental Assessment Department more effectively?

Up to S$130,000 funding from QRDI Council to support solution development and piloting

Up to S$20,000 grant support from EnterpriseSG

Access to datasets and facilities

Sustainable Insurtech Ecosystem

How can we use generative Artificial Intelligence (Gen AI) in the insurance value chain?

Up to S$130,000 funding from QRDI Council to support solution development and piloting

Up to S$20,000 grant support from EnterpriseSG

Access to datasets and facilities

Sustainable Insurtech Ecosystem

How might we develop novel ESG-related insurance propositions, solutions, products and services for our customers?

Up to S$130,000 funding from QRDI Council to support solution development and piloting

Up to S$20,000 grant support from EnterpriseSG

Access to datasets and facilities

BACKGROUND OF THE PROBLEM

Indoor point-to-point journeys in complex places such as airports, shopping malls and convention centres can be particularly daunting for persons with mobility issues (eg. elderly, family with infants), and/or persons with disabilities and/or mental disorders.

Using the segment of individuals who suffer from mobility issues as an example, it is estimated that 12.1% of U.S. adults have a mobility disability with serious difficulty walking or climbing stairs. Similarly, mobility and movement issues account for 19.5% of people with difficulties in Qatar In addition, it is estimated that 31.1% of U.S. adults experience some form of anxiety disorder at some time in their lives. For Qatar, depression and anxiety account for 17.5% of mental health disorders diagnosed.

A self-driving indoor travel cart can enhance accessibility and make way-finding easier for persons with special needs so they can spend more time enjoying the experiences at the designated venues.

Whilst advances are progressively being made in outdoor self-driving cars, their indoor equivalents are next to non-existent currently with a limited number of prototypes being explored globally. Similarly, autonomous indoor robots are not designed to transport people.

A handful of companies do provide autonomous wheelchairs although these do not currently carry more than 1 person; this is an issue since persons with mobility or disability issues usually will be accompanied by one caregiver.

In light of all the above, we are looking for novel solutions to develop an indoor autonomous travel cart for indoor point-to-point journeys.

Given the multitude of challenges that need to be solved before indoor autonomous travel carts can become safe and economically viable for use, QRDI Council and MATAR is open to suggestions from prospective solution providers on crafting a scope of the proto-type/design to fit within with initial allocated stage 1 funding. We understand more funding might be necessary for further roll-out and are open to look at that post Phase 1.

TECHNICAL REQUIREMENTS / PERFORMANCE CRITERIA:

Technical Requirements:

Previous experience with developing similar technical solutions as well as experience in aesthetics/ergonomic designs
Ability to deliver and install working proto-type consisting of least the following:
- Electric autonomous indoor self-driving cart with incursion avoidance system with the capacity to transport at least 2 people with a compartment to hold hand-held luggage
- On-board touchscreen for indoor maps, points of interest selection, and automatic path generation
- External digital display panel capable of showing dynamic content (eg sponsor message)
- Inclusion of a web-based dashboard for operators to remotely monitor the location and status of the cart
Provision of reports demonstrating the efficacy of the solution throughout the trial period
Recommendations on future solution design incorporating lessons learnt during trial
Provision of detailed design and proposal for a cost-effective scaled-up solution

Performance Criteria:

Performance criteria will be assessed on a case-by-case basis depending on the specific proposal.

COST TARGET

Cost targets will be determined on a case-by-case basis. Prospective solution providers are asked to provide a proposal outlining what can be achieved within the allocated stage 1 funding. We additionally, invite solution providers to suggest proposal options on various build/configuration of proto-types.

TIMEFRAME FOR DEVELOPMENT

Phase 1 POC development: 2-4 months

Phase 2 Roll-out: to be determined on a case-by-case basis

POTENTIAL MARKET / BUSINESS OPPORTUNITY

If the solution is successful, we are willing to support a further roll-out within multiple premises and for multiple use cases within Qatar. Additionally, we believe there are significant opportunities to roll out the solution in other geographical markets where complex establishments are prevalent such as convention centres, shopping, airports etc.

RESOURCES

Up to S$130,000 funding from QRDI Council to support solution development and piloting
Up to S$20,000 grant support from EnterpriseSG
Specific support by the end-user including (but not limited to):
- Access to the end-user to enable domain knowledge
- Access to relevant datasets
- Access to co-working space and lab facilities

OTHER CONSIDERATIONS

For novel IP is being generated as part of the collaboration, QRDI Council will follow its IP policy in line with its open innovation directive and practices. please refer to the following link QRDI Intellectual Property Policy.pdf (windows.net)

BACKGROUND OF THE PROBLEM

Qatar's National Vision 2030 includes provisions for responsible management of the environment with harmony and balance between economic, social development and environmental protection.

In support of the National Vision, MATAR is keen to explore usage of sustainable energy sources for its asset operations. Solar energy is a renewable and clean source of energy that can help reduce greenhouse gas emissions and combat climate change. Floating solar panels at sea can offer a promising way to harness this energy without compromising land use.

Solar panels on sea surface have some advantages over land-based ones, such as:

They do not take up valuable land that could be used for other purposes.
They can produce more electricity, as they are cooled by the water and the wind, which improves their efficiency. According to a study by Utrecht University, floating solar panels at sea perform almost 13% better on average than panels installed on land, and in some months they even generated 18% more energy. The difference is due to the lower temperatures at sea and less cloud cover.

Floating solar energy solutions are already in use at a number of sites around the world, but on lakes, rather than the sea. Some of the problems that need to be solved before solar panels on sea can be effectively adopted are:

Salt corrosion and marine fouling: Solar panels on the sea are exposed to salt water, marine organisms and bird droppings that can damage the materials and reduce the efficiency of the panels. Therefore, solar panels on sea need to be more durable and resistant to these environmental factors than solar panels on land.
Impact from Waves: Waves can cause the panels to tilt or move, affecting their orientation and stability
Anchoring and cabling: Solar panels on sea need to be securely anchored to the seabed or floating platforms, which may require additional costs and engineering solutions.
Transmission of Energy: Solar panels on sea need to be connected to the grid or storage systems by underwater cables, which may pose technical difficulties
Access: Due to being sea-based, the maintenance of these panels requires special resources and tools

Matar is therefore looking for novel solutions that solve some of the key challenges associated with floating solar panels including:

Durability: To protect the solar panels from salt corrosion and marine fouling, special coating materials and methods are needed to make the panels more durable and resistant.
Efficiency: Cleaning technologies are needed to remove the dirt and debris that may accumulate on the panels and reduce their efficiency; these may include self-cleaning coatings, robotic cleaners, or water jets to keep the panels clean.
Adaptability Design: To cope with the shading and wave effects, solar panels on sea need to have adaptive and resilient designs that can optimise their performance and stability in different conditions; these may include using bifacial solar panels that can capture light from both sides, or tilting mechanisms that can adjust the orientation of the panels according to the sun position and wave direction.
Anchoring: To securely anchor the solar panels to the seabed or floating platforms, innovative anchoring solutions are needed to reduce the costs and engineering challenges; these may include using mooring systems, tension-leg platforms, or spar buoys to anchor the panels.
Maintenance: To access & maintain these panels at their optimum efficiency.
Grid Connection: To connect sea-based solar panels to the grid or storage systems, underwater cables need to be developed that can withstand the water pressure and currents, and minimise technical difficulties.

Given the multitude of challenges that need to be solved before solar panels on the sea can be effectively adopted, it is proposed that this open innovation call is initially limited to address the first 5 innovation challenges outlined above. That is, the ‘Grid Connection’ is excluded from this open innovation call.

MATAR acknowledges that a single solution provider might not be able to solve all 5 challenges at once. Hence, we are willing to consider any solution that helps to solve any of the issues mentioned though with preferences given to providers able to solve multiple of these challenges.

TECHNICAL REQUIREMENTS / PERFORMANCE CRITERIA:

Technical Requirements:

Solutions providers should have previous experience with developing similar solutions
Solutions providers should have the ability to deliver and install working prototype sea-based solar energy solutions comprising of:
1. Durable, adaptable, efficient and sea-anchored system
2. Solar to-energy conversion measurement instrumentation to continually monitor the efficiency of solution at sea
3. Remote sensing and control capability where data and instructions are transmitted via mobile or satellite connections back to the land base of operation
Ability to make multiple trips to sea installation to make adjustments to optimise the operation of the prototype unit
Provision of reports demonstrating of efficacy of the solution throughout the trial period
Provide recommendations on future solution design incorporating lessons learned during trial
Provision of detailed design and proposal for an efficient scaled-up solution

Performance Criteria:

Performance criteria will be assessed on a case-by-case basis depending on the specific proposal.

COST TARGET

Cost targets will be determined on a case-by-case basis.

TIMEFRAME FOR DEVELOPMENT

Phase 1 POC development: 2-4 months

Phase 2 Roll-out: to be determined on a case-by-case basis

POTENTIAL MARKET / BUSINESS OPPORTUNITY

If the solution is successful, we are willing to support a further roll-out with other countries in the area that have bordering sea shores.

RESOURCES

Up to S$130,000 funding from QRDI Council to support solution development and piloting
Up to S$20,000 grant support from EnterpriseSG
Specific support by the end-user including (but not limited to):
- Access to the end-user to enable domain knowledge
- Access to relevant datasets
- Access to co-working space and lab facilities

OTHER CONSIDERATIONS

BACKGROUND OF THE PROBLEM

In today's economy, transportation and logistics play a crucial role, leading to substantial investments in airports, seaports, and logistics capacity worldwide. These investments, costing billions and having long lead times, are essential to meet growing demand. Yet, there are alternative ways to increase capacity and economic growth. By utilising cutting-edge AI, particularly deep reinforcement learning, we can devise smarter allocation strategies to achieve an estimated 10% throughput increase.

This project aims to use deep reinforcement learning to address high-value resource allocation challenges for industries like seaports, airports, train terminals, and logistics centres.

These industries currently rely on a mix of human decision-making and traditional resource management systems (RMS), governed by simple rules and constraints. However, traditional RMS tools, struggle to consider trade-offs over different time frames, historical behavior patterns, or adapt to new information. This complexity surpasses human cognitive capacity and traditional RMS computational capabilities. Solving it requires quantum computing or reinforcement learning to devise novel strategies to balance trade-offs and navigate short-term and long-term scenarios.

OPPORTUNITY

The advancements in Analytics & AI present an untapped opportunity to:

Create unconventional asset resource allocation strategies more cost-effectively than expanding infrastructure.
Achieve a higher level of efficiency and greater rewards, targeting at least a 10% increase over baseline scenarios.
Reduce lost economic activity due to lengthy expansion lead times or scarce capital funding.
Potentially avoid the expansion cost for projects where authorities face scarce capital funding.
Broaden the decision-making scope to encompass customer experience, commercial considerations, and partner considerations.

Examples of Competitive Scenarios

In airport scenarios, we might face decisions like:

Prioritising a full A380 aircraft (400 passengers) with long layovers and high duty-free spending over two smaller A320 aircraft (100 PAX each) with short connection times.
Deciding to keep a stand as a buffer due to frequent delays.

The solution should include:

A user-configurable interface for adjusting reward/penalty levels for desirable and undesirable behaviours.
A stochastic policy that introduces nonlinearity and randomness for solving complex real-world resource allocation problems.

Adaptability to suit various industries and resource management challenges. MATAR acknowledges the necessity of domain knowledge and offers its expertise to enable solution providers to create scalable solution for potential customers post-implementation.

TECHNICAL REQUIREMENTS / PERFORMANCE CRITERIA:

Technical Requirements:

Solutions providers should have previous experience with developing solutions utilising ‘Reinforcement Learning’
Solution providers should be capable of delivering and installing a working prototype. This prototype should include:
1. Reinforcement Learning model for recommending airport-stand allocation scenarios based on user-defined and weighted rewards criteria.
2. Provision of reports illustrating the benefits and trade-offs of various allocation strategies, including a comparison with MATAR's existing simple 'rules-based' gates allocation scheme.
Solution providers should offer recommendations for future solution design, integrating lessons learned during the trial.
Detailed design and a proposal for a cost-effective scaled-up solution that can seamlessly integrate recommended airport resource allocation into the existing resource management system (RMS).

Performance Criteria:

Performance criteria will be assessed on a case-by-case basis depending on the specific proposal.

COST TARGET

Cost targets will be determined on a case-by-case basis.

TIMEFRAME FOR DEVELOPMENT

Phase 1 POC development: 2-4 months

Phase 2 Roll-out: to be determined on a case-by-case basis

POTENTIAL MARKET / BUSINESS OPPORTUNITY

If the solution is successful, we are willing to support a further roll-out in locations such as airports, sea-ports, road or air freight fleets and logistics centres.

RESOURCES

Up to S$130,000 funding from QRDI Council to support solution development and piloting
Up to S$20,000 grant support from EnterpriseSG
Specific support by the end-user including (but not limited to):
- Access to the end-user to enable domain knowledge
- Access to relevant datasets
- Access to co-working space and lab facilities

OTHER CONSIDERATIONS

BACKGROUND OF THE PROBLEM

Increasing global demand for clean water has led to a surge in sludge production, posing significant challenges for municipalities, industrial wastewater treatment firms, and private asset owners. MATAR acknowledges this challenge and seeks economically viable options for sludge recovery and recycling at its onsite Wastewater Treatment Plant.

Usage of sludge produced by wastewater treatment plants includes and is not limited to the following:

Recycling: Primarily in agriculture, this includes reinstating eroded sites, forestry, and urban landscaping. Recycling enables the reintroduction of sludge elements (carbon, nitrogen, phosphorus) into geochemical cycles.
Energy recovery: Conversion into biogas, syngas, bio-oil, further converted into electricity, mechanical energy, and heat.
Sludge as a source of high-value materials for products like animal feeds, bioplastics, biofuels, and bio stimulants.
Usage in development or derivative of construction materials.
Usage in construction materials development.

The recycling and recovery of dry sludge from wastewater treatments faces several challenges:

Sludge treatment techniques are influenced by local climate conditions, with temperature affecting treatment performance.
Incineration is sometimes preferred for sludge volume reduction but may generate harmful emissions and ash residues.
Direct land application as agricultural fertilizers poses potential nitrogen leakage into groundwater, and sludge may contain heavy metals, pathogens, and organic pollutants.
Thermochemical conversion technologies for energy recovery face challenges, including high costs, technical difficulties, and market barriers.
Thermochemical conversion technologies can be applied to sludge for energy recovery, However, these technologies also face some challenges such as high capital and operating costs, technical difficulties, and market barriers.

MATAR seeks innovative solutions to address these challenges through:

Advanced Analytical Methods: Employ techniques like life cycle assessment, techno-economic analysis, and multi-criteria decision analysis to evaluate sludge management options' environmental and economic performance.
Thermochemical Conversion Refinement: Develop cost-effective thermochemical conversion technologies (pyrolysis, gasification, etc.) to produce valuable products from sludge, reducing its volume and mass.
Nutrient Recovery: Improve techniques for recovering nutrients like phosphorus and nitrogen from sludge and its byproducts.
Novel Valorization Pathways: Explore innovative pathways involving microalgae and purple bacteria cultures growing on sludge. These pathways can yield high-quality proteins, lipids, and carbohydrates for applications such as animal feed, bioplastics, biofuels, and bio-stimulants, while reducing organic matter and nutrient content in the sludge.

In light of the challenges in making sludge recovery and recycling economically viable, MATAR is interested in exploring innovative combinations for these processes at its onsite Wastewater Treatment Plant.

Monthly sludge production varies from 200-500 tons, averaging 330 tons. Production will double after the 2024-2026 airport expansion.

TECHNICAL REQUIREMENTS / PERFORMANCE CRITERIA:

Technical Requirements:

Solutions providers should have previous experience with developing similar solutions.
Solutions providers should have the ability to deliver and install working proto-type solution(s) comprising addressing any of the above innovations.
Provision of reports demonstrating of efficiency/efficacy of solution(s) throughout the trial period.
Provide recommendations on future solution designs incorporating lessons learned during trial.
Provision of detailed design and proposal for scaled-up solution(s).

Performance Criteria:

Performance criteria will be assessed on a case-by-case basis depending on the specific proposal.

COST TARGET

Cost targets will be determined on a case-by-case basis.

TIMEFRAME FOR DEVELOPMENT

Phase 1 PoC development: 2-4 months.

Phase 2 Roll-out: to be determined on a case-by-case basis.

POTENTIAL MARKET / BUSINESS OPPORTUNITY

If the solution is successful, we are willing to support a further roll-out within different wastewater treatment plants. We are aware that similar issues exist in some other plants in the region, further highlighting additional expansion opportunities.

RESOURCES

Up to S$130,000 funding from QRDI Council to support solution development and piloting
Up to S$20,000 grant support from EnterpriseSG
Laboratory test analysis reports for two years can be made available to solution providers as long as confidentiality agreements are signed. The report(s) gives a representation of the typical nature of the sludge produced.
Specific support by the end-user including (but not limited to):
- Access to the end-user to enable domain knowledge
- Access to relevant datasets
- Access to co-working space and lab facilities

OTHER CONSIDERATIONS

BACKGROUND OF THE PROBLEM

Qatar's National Vision 2030 includes provisions for responsible management of the environment with harmony and balance between economic, social development and environmental protection. In support of this national vision, MATAR is keen to explore the usage of self-sorting mechanisms to accurately separate recyclable material such as plastic, aluminium, glass and general waste at the source where the bins are located in public-facing areas.

We acknowledge smart recycling bin solutions are available to achieve this result although existing solutions face a number of limitations including:

Usability issues in public venues which negatively impacts the effectiveness of these units. For example, existing available solutions require extensive user interaction to correctly place the right type of waste in the right way into the bin.
Existing solutions are designed primarily for designated recycling places where the depositors/users have financial incentives to get cash refunds by navigating complex UIs on the bins. These solutions are not designed to target segment users of public venues, as they require the user to interact with an app, a camera, or a screen to sort their waste. [Example] This same technology will not work in public venues like shopping malls, offices, libraries, universities, schools, streets, airports etc where the depositors/users simply need to throw the waste into a bin and expect the bin to sort out the intricacies of recycling.
Existing solutions do not know how to empty left-over liquids inside bottles, they do not have ways to unscrew and separate plastic caps from PEP or glass bottles.
They are not always accurate or reliable in sorting and identifying different types of waste, especially when the waste is mixed, contaminated, or damaged.

MATAR is therefore looking for a novel Smart Bin solution to solve the aforementioned problems. Specifically, solutions should:

Achieve an accuracy of sortation as close as possible to 100%.
Have an intuitive design requiring no interaction with users, [Example]
Have an ergonomic design and height reachable by persons on wheelchairs.

Given the multitude of challenges that need to be solved before smart bins can become ergonomically and accurately viable for sorting waste at the source, QRDI Council and MATAR are open to suggestions from prospective on developing solutions that fix all or parts of the innovation problems.

For example, solution providers may choose to focus solely on developing a single-purpose smart-bin for plastic and glass bottles only and include no provision for the sortation of paper and other wastes. It is envisaged that such a singular solution may contain a robotic mechanism to unscrew and separate plastic caps from PEP bottles, unscrew metallic caps from glass bottles, and then empty left-over liquids inside those bottles.

TECHNICAL REQUIREMENTS / PERFORMANCE CRITERIA:

Technical Requirements:

Solution providers should have previous experience with developing similar solutions.
Solution providers should have the ability to deliver and install working proto-type addressing accuracy, intuitiveness and ergonomics.
Solution providers should have the ability to make multiple trips to the installation site to make adjustments and optimise the operation of the prototype.
Provision of reports demonstrating the efficacy of the solution throughout the trial period.
Provide recommendations on future solution design incorporating lessons learned during trial.

Performance Criteria:

Performance criteria will be assessed on a case-by-case basis depending on the specific proposal.

COST TARGET

Final production version of the unit cost should not exceed $US3000. Proposals will be assessed on a case-by-case basis.

TIMEFRAME FOR DEVELOPMENT

Phase 1 POC development: 2-4 months

Phase 2 Roll-out: to be determined on a case-by-case basis

POTENTIAL MARKET / BUSINESS OPPORTUNITY

If the solution is successful, we are willing to support a further roll-out within key establishments such as hotels, convention centres, shopping malls, offices, airports etc.

RESOURCES

Up to S$130,000 funding from QRDI Council to support solution development and piloting
Up to S$20,000 grant support from EnterpriseSG
Specific support by the end-user including (but not limited to):
- Access to the end-user to enable domain knowledge
- Access to relevant datasets
- Access to co-working space and lab facilities

OTHER CONSIDERATIONS

BACKGROUND OF THE PROBLEM

This challenge statement is jointly supported by the Ministry of Environment and Climate Change as well as its potential end-user Qatar Industrial Manufacturing Company (QIMC)(Q.S.C). The Ministry will utilize and supply the solution to end-user(s), and provide some of the funding for the initial POC/Pilot with the end goal for the solution to be adopted by the end-user post POC.

The innovator/developer of the “calculator” will integrate various international codes and standards of the aluminium industry in the measurement systems, against which Qatari production of aluminium shall be calibrated. The scope of this project involves creating a user-friendly software tool that enables aluminium industry professionals in Qatar to input production data and calculate the carbon footprint of aluminium throughout its lifecycle.

The calculator will utilise accurate algorithms aligned with international standards and local regulations, considering factors like energy sources and regional specifics. It will offer a streamlined user interface, generate detailed carbon footprint reports, and provide user support. Data security and privacy measures will be implemented. The calculator's scope excludes external data collection, regulatory compliance validation, policy recommendations, and ongoing software maintenance.

Ideally, the tool would include measuring and calculating emissions for scopes 1, 2 and 3 since regulations will require such measurements by 2026. The tool should be built in accordance with the regulations of the European Commission’s Carbon Border Adjustment Mechanism (CBAM) which will start in 2026. There will be a revision by the European Parliament in three years for the current CBAM to include Scope 3 emissions. The following offers a comprehensive guide on CBAM’s: https://taxation-customs.ec.europa.eu/carbon-border-adjustment-mechanism_en#guidance-documents

In-Scope:

Data Collection and Input: relevant data from various stages of aluminium production, such as raw material extraction, energy consumption, transportation, etc.
Calculation Algorithms: based on relevant standards and guidelines to accurately calculate carbon emissions at different stages of the aluminium production lifecycle.
User Interface (UI) Development: a user-friendly interface that guides users through the data input process, parameter selection, and generating carbon footprint reports.
Carbon Footprint Reporting: detailed reports that provide a breakdown of carbon emissions by process, source, and overall carbon footprint. The reports should be informative and easy to understand.
Compliance with Standards: the software aligns with applicable international standards and guidelines for carbon accounting in the aluminium industry.
Accuracy and Verification: mechanisms for accuracy and verification to ensure that the calculations and results are reliable. This might involve providing information about data sources, assumptions, and methods used.
Customization for Qatar: Adapting the calculator to the specific context of Qatar's aluminium industry, considering factors like energy sources, local processes, and regulatory requirements.
User Support and Training: resources and support to help users effectively use the calculator, interpret results, and address any questions or issues.
Security and Data Privacy: appropriate security measures to protect user data and ensure data privacy.

Out of scope:

External Auditing: External audits for verification purposes will be out of scope. The calculator could be designed for internal use and potentially verified by external parties separately.
Policy Recommendations: or strategic decisions based on the calculator's results might be beyond the scope. The calculator provides data; users interpret and act upon it.
Software Maintenance and Updates: initial development is within scope, but ongoing software maintenance, updates, and enhancements might be considered separately, unless defined and stipulated to be within scope of selected developer(s).

TECHNICAL REQUIREMENTS / PERFORMANCE CRITERIA:

Technical requirements:

Obtaining accurate and comprehensive data from various stages of aluminium production can be challenging.
Integrating data from multiple sources and formats can be complex. Creating a streamlined process for data input and validation is essential.
Developing accurate algorithms that calculate carbon emissions based on various inputs, considering the intricacies of different production processes and energy sources, requires careful consideration.
Developing algorithms that account for the full lifecycle of aluminium production while considering various emission factors, conversion factors, and regional specifics can be technically complex.
Ensuring the software can handle large datasets and complex calculations efficiently without significant slowdowns or errors is important for user satisfaction.
Keeping the calculator up to date with changing standards, guidelines, and emission factors requires a system for updating the model and user interface.
Customising the calculator for the Qatar context, including specific energy sources, regulations, and industry practices, might require significant adjustments to the software's logic and parameters.
Designing methods to validate and verify the accuracy of calculated results can be challenging, especially when users have varying data quality and levels of understanding.
Designing the software to be scalable, accommodating a growing number of users and potential expansions in scope, is important for long-term usefulness.

Relevant regulatory standards:

The European Commission has recently announced (stringent) environmental standards for the continent’s aluminium imports. The standards are meant to match those of local European production of aluminium and will be applicable starting the year 2026. For Qatari production of aluminium to meet exportation goals to the European Union, and other regions in the world, there shall be an environmental plan, measures and metrics that encompass carbon footprint.

COST TARGET

Cost targets will be determined on a case-by-case basis.

TIMEFRAME FOR DEVELOPMENT

Phase 1 POC development: 2-4 months

Phase 2 Roll-out: to be determined on a case-by-case basis

POTENTIAL MARKET / BUSINESS OPPORTUNITY

In case the solution provider is able to develop a solution that fits our requirements, we believe there are additional opportunities for implementation for adjacent products such as steel. Additionally, solution providers can scale through increasing the number of licenses of their solutions across multiple different customers in the region.

RESOURCES

Up to S$130,000 funding from QRDI to support solution development and piloting
Up to S$20,000 grant support from EnterpriseSG
Specific support by the end-user including (but not limited to):

Access to the end-user to enable domain knowledge
Access to relevant datasets
Access to co-working space and lab facilities

OTHER CONSIDERATIONS

For novel IP is being generated as part of the collaboration, QRDI will follow its IP policy in line with its open innovation directive and practices. please refer to the following link QRDI Intellectual Property Policy.pdf (windows.net)

BACKGROUND OF THE PROBLEM

The Environmental and Social Impact Assessment (ESIA) is a comprehensive study conducted to determine the potential environmental and social effects resulting from a prospective new project. It ensures that the potential impacts (both positive and negative) on the environment and communities are assessed and considered in line with environmental and social laws and standards. Currently, the review and evaluation process for ESIA studies for new projects is lengthy, leading to prolonged wait times for the issuance of essential environmental permits. This delay stems from the vast amounts of data, information, and studies required for comprehensive assessments.

The end goal for the solution is to be adopted by the Ministry of Environment and Climate Change as the end-user post POC. The developed solution can be used for forecasting new developmental cases as well as future environmental situations based on current data.

In-Scope:

Improve the decision-making process to proceed with new project developments.
Provide a more precise project assessment of environmental system analysis.
Make predictions for different cases as well as future studies.
Save time and manpower required.
Expedite the EIA review and environmental permit issuance process.

Out of scope:

Post-Issue Monitoring: The EIA is primarily designed for assessment prior to project execution. Continuous monitoring after environmental permits have been issued is not within the EIA's scope.
External Data Integration: While the EIA will use specific datasets provided, automatic integration with external databases or real-time data sources arenot included, at least at this initial stage of development.
Legal & Regulatory Recommendations: The EIA will assess against existing standards and laws but will not provide recommendations for legal actions or suggest changes to existing regulations.
Financial & Economic Analysis: The focus is on environmental and social impacts. Economic implications or cost-benefit analyses of projects are not addressed by the EIA.
Project Management Capabilities: The EIA will not offer project management features such as re/scheduling, re/budgeting, or resource re/allocation.
Historical Analysis: The EIA will not provide detailed analyses or reviews of past projects or retrospective EIA studies.
Training and Certification: While the EIA will offer guidance and assessment capabilities, it will not serve as a platform for official EIA certification or training.

TECHNICAL REQUIREMENTS / PERFORMANCE CRITERIA:

Technical requirements:

An air & emission model for the Qatar geographical region with a focus on industrial areas specifically (priority).
A sea water model for the Qatar economical marine areas.
A land model with all relevant information related to land soil, plants, other biological diversity data, reserves, etc.
Integration of environmentally sensitive areas (land & marine) data in the models.
Utilisation of historical data to optimise the model’s effectiveness.
Ability to make EIA forecasts and studies for any kind of new project entry.
Ability to provide data on specified areas or on a sectoral basis.
EIA needs to Act like a decision-making tool for any new project entry.
The model accuracy needs to be higher than 85% based on historical data.

The project may be conducted in distinct development phases. The first priority is to develop the emissions model. Further models can subsequently be added.

Relevant regulatory standards:

Environmental Protection Law No. 30 of 2002, EPA standards & best environmental practices.

COST TARGET

Cost targets will be determined on a case-by-case basis.

TIMEFRAME FOR DEVELOPMENT

Phase 1 POC development: 2-4 months

Phase 2 Roll-out: to be determined on a case-by-case basis

POTENTIAL MARKET / BUSINESS OPPORTUNITY

We believe the EIA decision tool once developed can be rolled out to other departments within the Ministry as well as universities and consulting firms. Additionally, we are willing to support further rollout for other countries.

RESOURCES

Up to S$130,000 funding from QRDI to support solution development and piloting
Up to S$20,000 grant support from EnterpriseSG
Specific support by the end-user including (but not limited to):

Access to the end-user to enable domain knowledge
Access to relevant datasets
Access to co-working space and lab facilities

Note: Access to Ministry data is subject to confidentiality agreement requirements

OTHER CONSIDERATIONS

BACKGROUND OF THE PROBLEM

Generative AI represents a transformative opportunity for the insurance industry as it has the potential to vastly improve and streamline all areas of the insurance value chain. QIC sees many different application areas and use cases for the insurance industries which include (but are certainly not limited to):

Underwriting Efficiency: AI can analyse vast datasets to automate underwriting processes, quickly assessing risks, and streamlining the policy issuance process. This leads to faster decision-making and reduces operational costs.
Claims Processing: Generative models can assist in claims validation by comparing historical data to current claims, helping to identify potentially fraudulent or inaccurate claims. This accelerates claims settlement and minimises losses.
Risk Assessment: AI can generate synthetic data to simulate various risk scenarios, enabling insurers to refine their risk models. This allows for more accurate premium pricing and risk management.
Customer Engagement: AI-driven chatbots and virtual assistants can enhance customer interactions by providing instant support and personalised policy recommendations, improving customer satisfaction and loyalty.
Fraud Detection: Generative AI can identify anomalies and patterns in claims data to detect potential fraud, helping insurers proactively mitigate losses and maintain trust in the industry.
Product Customization: AI can analyse customer data to create personalised insurance products that better meet individual needs, increasing policyholder retention.
Predictive Analytics: Generative models can forecast future trends and events, enabling insurers to adapt their strategies and policies in response to changing market conditions and emerging risks.
Compliance and Risk Management: AI can assist insurers in complying with regulatory requirements and maintaining a comprehensive view of risk exposures, ensuring sound governance.

Since the potential applications in generative AI for insurance are so vast, QIC does not want to limit the specific use cases or applications scenarios solution providers can propose as part of this challenge statement. We are looking for solutions across different Insurance areas like Retail, Commercial, Reinsurance etc.

In Scope

Everything in Insurance needs validated data. The longitude of this data depends on the type of insurance. We are looking for partners that have a validated insurance use case with other insurers.
We are looking for startups that have domain expertise specifically in the insurance field.
Ideally, we are looking for startups that have done specific Gen Ai related projects with insurers in Asia.

Out of Scope

Solution providers that have generic generative AI solutions but no insurance industry domain knowledge will not be considered.
We are looking for technology startups for this challenge. We are not looking for (data) consultants.
FinTech-related solutions or solution providers will not be considered.

TECHNICAL REQUIREMENTS / PERFORMANCE CRITERIA:

Technical requirements and performance criteria will be evaluated on a case-by-case basis depending on the proposed application area and use case.

COST TARGET

No specific cost target has been set. Proposals will be assessed on a case-by-case basis.

TIMEFRAME FOR DEVELOPMENT

Phase 1 POC development: 2-4 months

Phase 2 Roll-out: to be determined on a case-by-case basis

POTENTIAL MARKET / BUSINESS OPPORTUNITY

QIC is a market leading insurer in MENA. A pilot with us will open the market for the solution provider. If the solution is successful, we are willing to support further rollout. Additionally, we are willing to connect a successful solution provider to the MENA InsurTech Association to further expand network and opportunities in the region.

RESOURCES

Up to S$130,000 funding from QRDI to support solution development and piloting
Up to S$20,000 grant support from EnterpriseSG
Specific support by the end-user including (but not limited to):
- Access to the end-user to enable domain knowledge
- Access to relevant datasets
- Access to co-working space and lab facilities

OTHER CONSIDERATIONS

BACKGROUND OF THE PROBLEM

ESG (Environmental, Social, and Governance) considerations present a significant opportunity for the insurance industry since ESG it covers all aspects of business including: (1) risk mitigation – taking into consideration environmental factors is increasingly becoming important for risk mitigation and modelling, (2) market demand – increasingly customers are looking for insurance-related products in line with ESG goals and commitments.

By leveraging technology to integrate ESG considerations into their operations, the insurance industry can address emerging environmental and social challenges, tap into new markets, and contribute to a more sustainable future. Hence, QIC sees many different application areas and use cases for ESG service(s), solutions and products in the industries which include (but are certainly not limited to):

Risk Assessment: Technology can analyse ESG factors such as climate change, social dynamics, and corporate governance to evaluate risks more comprehensively. This assists insurers in pricing policies accurately and mitigating potential losses.
Green Insurance Policies such as environmental liability insurance, responsible underwriting and investment guidelines etc.
Data Analytics: Utilizing big data and AI, insurers can assess ESG data to inform underwriting and claims decisions. This data-driven approach enables insurers to promote sustainability and reduce environmental impact.
Regulatory Compliance: Tech solutions can help insurers adhere to evolving ESG-related regulations and reporting requirements, ensuring transparency and adherence to industry standards.
Sustainability Reporting: Advanced data analytics and reporting tools enable insurers to communicate their ESG efforts to stakeholders, enhancing transparency and corporate responsibility.

Since the potential applications in ESG for insurance are so vast, QIC does not want to limit the specific use cases or applications scenarios solution providers can propose as part of this challenge statement. We are looking for solutions across all domains including the commercial and the consumer-facing domains.

In Scope

Solutions that see ESG as a business opportunity. QIC is looking to bring new solutions to the market that drive business growth and can be incorporated into the core business functions.
We are looking for startups that have domain expertise specifically in the insurance field.
Besides startups, we can also consider more mature scaleups for this challenge statement.

Out of Scope

Solution providers that have generic ESG solutions but no insurance industry domain knowledge will not be considered.
We are looking for technology startups for this challenge. We are not looking for (data) consultants.
FinTech-related solutions or solution providers will not be considered.

TECHNICAL REQUIREMENTS / PERFORMANCE CRITERIA:

Technical requirements and performance criteria will be evaluated on a case-by-case basis depending on the proposed application area and use case.

COST TARGET

No specific cost target has been set. Proposals will be assessed on a case-by-case basis.

TIMEFRAME FOR DEVELOPMENT

Phase 1 POC development: 2-4 months
Phase 2 Roll-out: to be determined on a case-by-case basis

POTENTIAL MARKET / BUSINESS OPPORTUNITY

QIC is a market-leading insurer in MENA. A pilot with us will open the market for the solution provider. If the solution is successful, we are willing to support further rollout. Additionally, we are willing to connect a successful solution provider to the MENA InsurTech Association to further expand the network and opportunities in the region.

RESOURCES

Up to S$130,000 funding from QRDI to support solution development and piloting
Up to S$20,000 grant support from EnterpriseSG
Specific support by the end-user including (but not limited to):
- Access to the end-user to enable domain knowledge
- Access to relevant datasets
- Access to co-working space and lab facilities

Qatar-Singapore Joint Innovation Challenge

Fostering innovation and collaboration between Singapore-based startups and Qatari entities across critical sectors such as energy, environmental sustainability, insurance, and information technology.

CHALLENGE AREAS

CHALLENGE STATEMENTS

Show All

By Category

By Challenge Statement Owners

How can we enhance the process, installations, or longevity of sea-floating solar energy farming?

How might we build an optimised allocation system to enable the planning and optimisation of high value and limited asset resources for transportation in airports?

How might we develop recovery and recycling solutions for the sludge and waste water treatment?

How might we develop a carbon footprint calculator for aluminium production to enable carbon footprint accounting effectively and transparently?

How might we develop an Environmental Impact Assessment (EIA) Tool to assess the environmental footprint for new projects within the Environmental Assessment Department more effectively?

How can we use generative Artificial Intelligence (Gen AI) in the insurance value chain?

How might we develop novel ESG-related insurance propositions, solutions, products and services for our customers?

Qatar-Singapore Joint Innovation Challenge

Fostering innovation and collaboration between Singapore-based startups and Qatari entities across critical sectors such as energy, environmental sustainability, insurance, and information technology.

CHALLENGE AREAS

CHALLENGE STATEMENTS

Show All

By Category

By Challenge Statement Owners

How can we enhance the process, installations, or longevity of sea-floating solar energy farming?

How might we build an optimised allocation system to enable the planning and optimisation of high value and limited asset resources for transportation in airports?

How might we develop recovery and recycling solutions for the sludge and waste water treatment?

How might we develop a carbon footprint calculator for aluminium production to enable carbon footprint accounting effectively and transparently?

How might we develop an Environmental Impact Assessment (EIA) Tool to assess the environmental footprint for new projects within the Environmental Assessment Department more effectively?

How can we use generative Artificial Intelligence (Gen AI) in the insurance value chain?

How might we develop novel ESG-related insurance propositions, solutions, products and services for our customers?

MATAR

1How might we develop an indoor autonomous travel cart for indoor point-to-point journeys in complex spaces such as airports or shopping malls?

BACKGROUND OF THE PROBLEM

TECHNICAL REQUIREMENTS / PERFORMANCE CRITERIA:

COST TARGET

TIMEFRAME FOR DEVELOPMENT

POTENTIAL MARKET / BUSINESS OPPORTUNITY

RESOURCES

OTHER CONSIDERATIONS

MATAR

1How can we enhance the process, installations, or longevity of sea-floating solar energy farming?

BACKGROUND OF THE PROBLEM

TECHNICAL REQUIREMENTS / PERFORMANCE CRITERIA:

COST TARGET

TIMEFRAME FOR DEVELOPMENT

POTENTIAL MARKET / BUSINESS OPPORTUNITY

RESOURCES

OTHER CONSIDERATIONS

MATAR

2How might we build an optimised allocation system to enable the planning and optimisation of high-value and limited asset resources for transportation in airports?

BACKGROUND OF THE PROBLEM

OPPORTUNITY

TECHNICAL REQUIREMENTS / PERFORMANCE CRITERIA:

COST TARGET

TIMEFRAME FOR DEVELOPMENT

POTENTIAL MARKET / BUSINESS OPPORTUNITY

RESOURCES

OTHER CONSIDERATIONS

MATAR

3How might we develop recovery and recycling solutions for the sludge and wastewater treatment?

BACKGROUND OF THE PROBLEM

TECHNICAL REQUIREMENTS / PERFORMANCE CRITERIA:

COST TARGET

TIMEFRAME FOR DEVELOPMENT

POTENTIAL MARKET / BUSINESS OPPORTUNITY

RESOURCES

OTHER CONSIDERATIONS

MATAR

5How might we develop a next-generation self-sorting recycling bin that outperforms existing solutions on usability, accuracy and reliability?

BACKGROUND OF THE PROBLEM

TECHNICAL REQUIREMENTS / PERFORMANCE CRITERIA:

COST TARGET

TIMEFRAME FOR DEVELOPMENT

POTENTIAL MARKET / BUSINESS OPPORTUNITY

RESOURCES

OTHER CONSIDERATIONS

MoECC

4How might we develop a carbon footprint calculator for aluminium production to enable carbon footprint accounting effectively and transparently?

BACKGROUND OF THE PROBLEM

TECHNICAL REQUIREMENTS / PERFORMANCE CRITERIA:

COST TARGET

TIMEFRAME FOR DEVELOPMENT

POTENTIAL MARKET / BUSINESS OPPORTUNITY

RESOURCES

OTHER CONSIDERATIONS

MoECC

5 How might we develop an Environmental Impact Assessment (EIA) Tool to assess the environmental footprint for new projects within the Environmental Assessment Department more effectively?

BACKGROUND OF THE PROBLEM

TECHNICAL REQUIREMENTS / PERFORMANCE CRITERIA:

COST TARGET

TIMEFRAME FOR DEVELOPMENT

POTENTIAL MARKET / BUSINESS OPPORTUNITY

RESOURCES

OTHER CONSIDERATIONS

QIC

6 How can we use generative Artificial Intelligence (Gen AI) in the insurance value chain?