Aerospace & Aviation
Homeland Security
Advance Warships
Future Mobility
STREAM vs STEM
Infrastructure
Life Sciences
Renewable Energy
Smart Agriculture
Oil and Gas
Mining
Naval Innovations
Defense Navy, on the other hand, refers to nations' maritime military wing. Naval ships are those which are used at times of international crises to protect the water boundaries of a nation from getting infiltrated or attacked unduly. The maritime sector, and the naval Defense industry in particular, is a strategic asset worldwide.
MDs is an all-round expert in naval Defence. In order to succeed in a context where the equilibrium is changing, MDs relies on its unique positioning as innovation specialists. It allows MD Consortium, to tailor its reply to each navy's needs in the finest detail of aerial-frigate industries and technologies.
MDs looking to working alongside the navy for over the next 10 years as designer, manufacturer and integrator of surface TSAMA Aerial Frigate and submersible aircraft. TSAMA offers an efficient, and ensures to the navy’s the sovereignty.
The TSAMA are respectively inspired by the multisession frigate and ship subsurface ballistic (SSB) submersible. in addition to the aerial features. … The successful design of the TSAMA demonstrates our ability to manage complex programs in very challenging environments.
MDs naval solution of TSAMA, have proven to be world leaders in functionality, quality and value in terms of features related to the international naval markets.
Managing TSAMAs, it’s the most complex project in the world and can provide efficient and innovative solutions during the cycle of its development. MDs ensures transfer of technology for the navies to enable them to become fully autonomous in terms of naval Defense.
Catch-up Cycle
The innovation of the TSAMA aircraft can provide a framework for knowing the extent of the upcoming successive changes in the manufacture of alternatives to naval warships, including the future submersible vertical crane TSAMA aircraft being an upcoming alternative. The innovation of the TSAMA aircraft with the passage of time will inform those interested about what will happen during the next ten years of changes.
TSAMA Future Series - Modular Submersible VTOL, Future Vertical Lift (FVL), Optionally Piloted Aircraft (OPA). ... TSAMA - (T) Tandem Ducted Propellers, (S) Submersible, (A) Amphibious, (M) Modular Autonomous Units, (A) AI Capability, the project has patents and more than 17 strategic intellectual properties in aircraft series Future TSAMA, innovation done, development started since 2003 and will be ready for service in 2027. ... It should be noted that these are inexpensive aircraft, and it will not take several years to assemble a large number of future TSAMA series aircraft.
A catch-up cycle occurs over time in one sector, and this has happened in the military marine industry. In catch-up cycles, lagging companies and countries are emerging as the new international leaders, while old innovations are losing ground. The old leaders are being deposed by the new ones.
To identify factors at the base of catch-up cycles, this TSAMA aircraft innovation adopts a sectoral system framework and identifies windows of opportunity that may emerge during the long-term development of the industry.
This innovation contains three windows related to specific dimensions of a sectional system. One dimension relates to changes in knowledge and technology. The second dimension relates to changes in demand, and the third dimension involves changes in institutions and public policy.
The combination of the opening of a window (technological, or institutional/policy) and the responses of firms and other components of the sectoral system of the lagging states and the present states determines the changes in the TSAMA industrial leadership and how they can catch up.
The term future mobility covers all modes of transport – those that already exist and new ones that will be created. From electric vehicles and autonomous cars to e-scooters, hyperloops and solar powered planes, these changes to mobility are being driven by massive social, economic and technological trends.
The future of mobility offers new possibilities for interaction, sustainability, accessibility and autonomy. These possibilities are exciting, but with change comes risk. As we revolutionise movement over the next few decades, we must prioritise the health and safety of people.
The city aims to allow people to move without their cars and ensure that public transport, walking, wheeling, and cycling Infrastructure is prioritized. The plan aims to reduce traffic through pedestrian priority zones, car-free streets, and focus on people.
The mobility plan for 2030, the city aims to allow people to move without their cars and ensure that public transport, walking, wheeling, and cycling Infrastructure is prioritized. The plan aims to reduce traffic through pedestrian priority zones, car-free streets, and focus on people.
By 2050, the way in which people move around is unlikely to see any drastic change. Wheeled vehicles will still roam city streets, and existing public transit networks will remain highly utilised.
The future of mobility is something we can envision clearly now: the on-demand driverless car that shows up at your door; the buses, trains, and planes that communicate in real time for seamless connections; the city traffic grid that constantly updates as demand changes.
The Future Mobility Zone is the ultimate stage for transport and smart mobility start-ups engineering the future, connecting them to the region's most influential companies, investors, and media.
FROM INNOVATIVE IDEAS TO REAL-APPLICATIONS
MD Consortium, mobility innovation solutions, is a partnership between leading worldwide innovaton labs and manufacturers of vehicle adaptations who have a shared mission of providing independence and freedom through urban air mobility accessibility.
The Innovation Programme aims to resolve urban air mobility challenges facing cities of the ASEAN Countries via action orientated innovation. We co-create ideas that lead to the proposal of projects in response to our open-call for proposals of cooperations, the demonstration of new solutions in real life, resolve urban mobility challenges, and the creation of commercial value.
The Programme develops partnerships across and beyond the ASEAN Countries and addresses regulatory and behavioral changes needed to improve urban life quality for all citizens.
INNOVATION CHALLENGE AREAS
Over 500+ urban air mobility challenges were identified by cities across the ASEAN Countries. These challenges were reworked into 11 wider “Challenge Areas”. Each year a work programme is developed with a focus on a number of the innovation challenge areas:
• Improving Urban Health Care Via (IAMI) Air Mobility
• Nutritious Via (IAMI) Air Mobility
• Active Mobility
• Intramodal and Intermodal Transportation
• Mobility infrastructure
• Mobility for all
• Pollution reduction
• Sustainable city logistics
• Creating public realm
• Future mobility
• Mobility and energy
urban mobility wants to wake up in the morning and think the future is going to be great - and that’s what being a breakthrough Urban-Aerial-faring civilization is all about. It’s about believing in the future and thinking that the future will be best than the bygone.
Also, the project is focused on lowering 70% of the cost of Urban AirMobility by innovate a cross-technology. … Vertical integration is a strategy that allows IAMI's project to streamline its operations by taking direct ownership of various stages of its production process rather than relying on external contractors or suppliers.
Urban air mobility to Strengthening the capacity of Central Asian countries to develop sustainable urban mobility policy. Shared mobility services are the part of the shared economy, which is based on the idea of rational use of limited resources, which creates an opportunity for a person to afford high-quality goods and services at a reasonable price.
Provides, contribute to a more efficient use of available resources and to achieve a number of UN sustainable development goals. Various forms of shared mobility are increasingly being included in the urban multimodal transport system and impact social and public life of urban residents in the areas of economics, ecology, and safety.
A & D Innovations:
The aerospace industry encompasses the manufacture of a wide range of aircraft and spacecraft products (including passenger and military aeroplanes, helicopters, and gliders, as well as spacecraft, launch vehicles, satellites, and other space-related items).
Aerospace and defense (A&D) companies build aircraft, ships, spacecraft, weapon systems, and defense equipment. Companies in the aerospace and defense industry are expected to go further digital, with smart factories taking over the supply chain eventually, giving rise to more efficient production along with a faster design-to-delivery process.
The development of the aerospace high-tech industry is closely related to military applications, but more importantly, the tremendous progress humans have made in this industry has had a significant and far-reaching impact on many aspects of the economy and life, driving and changing the face of the world. In the 21st century, the role of aerospace activities will far exceed the field of science, and will have a wider impact on politics, economy, military and human social life, and will continue to create new scientific and technological achievements and huge economic benefits.
New Technology Trends in The Aerospace Industry: According to Advanced Manufacturing, new manufacturing technologies will help the aerospace industry to embrace a brighter future: advanced design technologies, digital assistants, augmented reality (AR) and virtual reality (VR), new manufacturing materials, collaborative robots, and advanced computing capabilities.
Our vision is superior to others. We can change the rules of the game for the global construction toy market by forcing major companies in the world to follow suit with the intellectual property we own, as no company in the world has been able to provide construction toys that are miniature models of real construction such as the wonders of the world such as the pyramids and the Chinese Wall. The great, round city of Baghdad. And all the other historical monuments of the world, as well as the future construction of our lives.
STEM is an educational curriculum that combines science, technology, engineering, and math. It is meant to be a comprehensive approach; instead of teaching each subject separately, educators aim to incorporate some or all elements of STEM into each project. STEAM incorporates all the elements of STEM, but adds art to the mix.
STREAM adds one more layer to STEM and STEAM: reading and writing. Advocates of STREAM see literacy as an essential part of a well-rounded curriculum, as it requires critical thinking as well as creativity. STREAM projects are similar to STEM or STEAM, but fold in the components of reading and writing.
The global construction toys market size was valued at USD 12.72 billion in 2022 and is expected to grow at a compound annual growth rate (CAGR) of 6.6% from 2023 to 2030. The rising recognition of the benefits associated with construction toys in the cognitive development of kids is expected to accelerate the growth of the industry. These products help develop spatial reasoning in children, which is anticipated to drive the demand from education systems. For instance, bricks and blocks toys are included in the early grades of education. Holistic development to develop creativity and imagination among children is the objective of including these games for children in kindergarten.
From 2023 to 2030, the Educational Toy market displays a consistent and positive growth direction, indicating a favorable outlook for the industry. This growth is propelled by several key factors, including increasing consumer demand, advancements in technology, and shifting consumer preferences.
Stem Toys Market size is growing at a moderate pace with substantial growth rates over the last few years and is estimated that the market will grow significantly in the forecasted period i.e., 2023 to 2030. The educational toys market is poised to grow by $16,043.98 during 2023-2027, accelerating at a CAGR of 8.7% during the forecast period.
STEM education is important for several reasons. It refers to the integration of science, technology, engineering, and mathematics into a cohesive, interdisciplinary and applied learning approach1. This approach is not just academic theory—STEM education includes the appropriate real-world application and teaching methods1. As a result, students in any subject can benefit from STEM education.
One of the most direct and powerful arguments for the importance of STEM education is how relevant STEM is in the workforce. Employment in STEM occupations has grown 79 percent in the past three decades, according to U.S. Bureau of Labor Statistics2. In addition, STEM jobs are projected to grow an additional 11 percent from 2020 to 2030.
The study of STEM subjects teaches critical-thinking skills and instills a mindset that will help students find success across numerous areas and disciplines2. However, too often the opportunity to learn and to be inspired by STEM is not available. Only 20 percent of high school graduates are prepared for college-level coursework in STEM majors.
STEM education is also important for the future of innovation and prosperity. The pace of innovation is accelerating globally, and with it the competition for scientific and technical talent. Now more than ever the innovation capacity of the States and its prosperity and security—depends on an effective and inclusive STEM education ecosystem.
Oil and gas exploration is the search by petroleum geologists and geophysicists for deposits of hydrocarbons, particularly petroleum and natural gas, in the Earth’s crust using petroleum geology.
The Global Seismic Survey Market is estimated to be USD 1.91 Bn in 2023 and is expected to reach USD 2.38 Bn by 2028, growing at a CAGR of 4.48%.
The Global Seismic Survey Market is segmented based on Service, Technology, and Geography, By Service, the market is classified into Data Acquisition and Data Processing & Interpretation. By Technology, the market is classified into 2D, 3D, and 4D.
The process of oil and gas exploration typically consists of four stages: search and exploration, well construction, production, and abandonment.
Exploration in the Oil and Gas industry refers to the research and discovery of potential drilling and extraction sites and reserves for crude oil. This is done by conducting multiple surveys, analyses, and tests on the areas of interest.
Muayad Alsamaraee, and MD-Consortium and JAI team in Jordan Since 2003 they invented a solution for that by using magnetic survey, one of the tools used by exploration geophysicists in their search for mineral-bearing ore bodies or even oil-bearing sedimentary structures.
Magnetic surveys are a geophysical method to image anomalies in the earth's magnetic field caused by source bodies within the sub-surface. Oil and gas exploration use magnetic anomalies to detect faults and igneous intrusions.
Based on the characteristics of the geomagnetism, numbers of methods have been developed. The principal idea is employed based on the matching algorithms, such as MSD (Mean Square Difference), MAD (Mean Absolute Difference), ICCP (Iterative Closest Contour Point Algorithm), traditional matching algorithms strongly depend on a priori geomagnetic map, which is quite challenging to acquire during practice. the missions of navigation and tracking systems in underwater, overwater and/or Air environments.
Scientists know that today the Earth's magnetic field is powered by the solidification of the planet's liquid iron core. The cooling and crystallization of the core stirs up the surrounding liquid iron, creating powerful electric currents that generate a magnetic field stretching far out into space.
As water flows around the planet, these ions are deflected by the Earth's magnetic field – positive ions are pushed one-way, negative ions the other. This builds up volumes of positively and negatively charged water, sometimes on a scale of thousands of kilometers.
The geomagnetic field of the earth is very similar to the field of a bar magnetic and has played a major part in navigation over the centuries. By using a compass needle which aligns itself with the magnetic poles of the earth, navigators were able to determine which direction was North and which was South.
Magnetic anomaly navigation uses scalar magnetometers as sensors to measure differences in magnetic fields. Comparing these measurements with magnetic-field maps can provide information resulting in position determination.
A marine magnetic survey is the measurement of Earth's magnetic field intensity or its components (such as vertical component) along a series of profiles over an area of interest with the objective of measuring the magnetism of the ocean floor.
Humans do not have a magnetic sense, despite having a cryptochrome (cry2) in the retina which is magneto sensitive when exposed to light. A 2019 study found that magnetic fields do affect human alpha brain waves, but it is not known whether this results in any change in behavior.
Gravity and magnetic anomalies are defined as the deviation of the observed quantities, i.e., gravitational acceleration (or simply gravity) and magnetic flux density, respectively, from the expected value of a reference Earth.
The source of these anomalies is primarily permanent magnetization carried by titanomagnetite minerals in basalt and gabbro’s. They are magnetized when ocean crust is formed at the ridge. As magma rises to the surface and cools, the rock acquires a thermoremanent magnetization in the direction of the field.
A magnetic anomaly is the change in magnitude of the earth's magnetic field with respect to the expected value for that location. Large volumes of magnetic materials will change the intensity of the earth's field. The units of magnetic anomalies are nanotesla (nT) or the equivalent gamma.
Scientists know that today the Earth's magnetic field is powered by the solidification of the planet's liquid iron core. The cooling and crystallization of the core stirs up the surrounding liquid iron, creating powerful electric currents that generate a magnetic field stretching far out into space.
As water flows around the planet, these ions are deflected by the Earth's magnetic field – positive ions are pushed one-way, negative ions the other. This builds up volumes of positively and negatively charged water, sometimes on a scale of thousands of kilometers.
The geomagnetic field of the earth is very similar to the field of a bar magnetic and has played a major part in navigation over the centuries. By using a compass needle which aligns itself with the magnetic poles of the earth, navigators were able to determine which direction was North and which was South.
Magnetic anomaly navigation uses scalar magnetometers as sensors to measure differences in magnetic fields. Comparing these measurements with magnetic-field maps can provide information resulting in position determination.
A marine magnetic survey is the measurement of Earth's magnetic field intensity or its components (such as vertical component) along a series of profiles over an area of interest with the objective of measuring the magnetism of the ocean floor.
Humans do not have a magnetic sense, despite having a cryptochrome (cry2) in the retina which is magneto sensitive when exposed to light. A 2019 study found that magnetic fields do affect human alpha brain waves, but it is not known whether this results in any change in behavior.
Infrastructure monitoring is the oxygen to your infrastructure. It collects all the data needed to provide a complete picture of availability, performance, and resource efficiency so your applications and services remain up and available to your users.
Worldwide critical infrastructure protection market was valued at USD 132.42 billion in 2021 and is expected to grow at a CAGR of 3.4% during the forecast period. The rising threat of disruption in cyber security is the major driving factor for the industry growth in the forecast period.
As the requirement for the protection of critical infrastructure, physical & cyber systems are rising due to natural disasters, terrorist attacks and cyber hackers are growing, which has debilitating impacts on economic security and public health. Thus, the demand for critical infrastructure protection across various end-user industries is rising globally.
It includes healthcare, financial institutions, defense, energy & power, commercial sector, chemical manufacturing, oil & gas, transport, and others. Moreover, strict government regulations towards public protection play a vital role in boosting CIP industry demand. Additionally, rising government and private investments in the security sector are enhancing industry expansion. Along with these rising R&D activities toward the safety & security sector is pushing the critical infrastructure protection industry growth across the world in projected years.
This is done by collecting health and performance data from servers, virtual machines, containers, databases, and other backend components in a tech stack. Infrastructure monitoring provides visibility into the health of backend components that run your applications, allowing you to ensure that critical services are available for users and that they work as expected. Performance monitoring helps in identifying issues by collecting and analyzing data from various components of a system, such as servers, virtual machines, containers, databases, and other backend components.
By analyzing this data, can identify performance-related issues such as response time, resource utilization, and application downtime. This allows to quickly identify and address issues before they impact users.
The relationship between innovation and affordable clean energy is a critical one. Innovations in technology and processes have the potential to make clean energy more affordable, accessible, and scalable. Conversely, the adoption of affordable and clean energy can provide a significant impetus for innovation and development of new solutions.
Innovations have played a significant role in driving down the cost of renewable energy sources such as solar, wind, and hydropower. Technological advances such as improved solar panels and more efficient wind turbines have made these renewable sources of energy more competitive with fossil fuels. Furthermore, innovations in energy storage technologies have made it possible to store renewable energy for use when the sun isn't shining or the wind isn't blowing, thereby increasing the reliability and versatility of clean energy.
Innovation has led to the development of new business models and financing mechanisms that make clean energy more accessible to consumers. For instance, the advent of community solar projects has made it possible for individuals to pool their resources to invest in solar energy installations, even if they don't have the physical space or financial resources to install solar panels on their roofs. Innovations in financing mechanisms such as green bonds, energy efficiency mortgages, and pay-as-you-go systems have also made it easier for consumers and businesses to invest in clean energy projects.
The adoption of affordable and clean energy can provide a significant impetus for innovation. For example, the increased demand for electric vehicles has spurred innovation in battery technology, leading to more efficient, longer-lasting, and cheaper batteries. The growth of the renewable energy sector has also created new opportunities for innovation in energy storage, grid management, and other related fields.
Innovative solutions are critical to making affordable and clean energy accessible to all. In recent years, there has been a surge in innovative solutions for clean energy that promise to revolutionize the energy landscape. Here are some examples of such innovative solutions:
Off-grid solar solutions: Off-grid solar solutions, such as solar home systems and mini-grids, are being used to provide electricity to remote and off-grid communities. These solutions use small-scale solar panels and battery storage to provide electricity to households and small businesses.
Smart grids: Smart grids are intelligent electricity networks that optimize the generation, distribution, and consumption of electricity. These systems use real-time data and automation to ensure that the electricity grid is running efficiently and sustainably.
Energy storage solutions: Energy storage solutions are critical to ensuring that renewable energy sources, such as solar and wind power, can be used efficiently. Solutions such as lithium-ion batteries, flow batteries, and compressed air energy storage (CAES) are being used to store energy for use when demand is high.
Energy-efficient buildings: Energy-efficient buildings are designed to reduce energy consumption and greenhouse gas emissions. These buildings use technologies such as insulation, high-efficiency lighting, and smart heating and cooling systems to reduce energy consumption.
Sustainable transportation: Sustainable transportation solutions, such as electric vehicles (EVs) and alternative fuels, are being used to reduce greenhouse gas emissions from the transportation sector. EVs use electricity as a fuel, which can be generated from renewable energy sources, while alternative fuels such as biofuels and hydrogen can be produced from renewable sources.
Blockchain-based energy trading: Blockchain technology is being used to enable peer-to-peer energy trading, allowing individuals and businesses to buy and sell renewable energy directly from one another. This technology allows consumers to take control of their energy consumption and reduce their reliance on traditional energy providers.
MD-AGRO AI INNOVATION IN THE AGRICULTURE
MD-Agro is keen to bringing drones, robots, autopilot, artificial intelligence, and Internet-of-things into the world of agricultural production. It creates a smart agriculture ecosystem that leads us into the era of Agriculture 4.0 characterized as automation, precision, and efficiency.
Advancing Agriculture worldwide. We aim to build the infrastructure of agriculture for the next 30 years, that will provide the world with sufficient, diversified, and safe food.
MD-Agro Plan is evolving from an innovative technology company towards a Smart Agriculture Ecosystem. The most significant difference between them is not how big the scale but how heavy it shoulders. Global Vision is like a torch we hold meanwhile pursuing our dreams. Even if some of us might start a new career decades after, we’d still be proud of what we once did to improve people’s life.
Crop Spraying Drone market size is estimated to be worth USD 600 million in 2021 and is forecast to a readjusted size of USD 3 billion 2028 with a CAGR of 25% over the analysis period." A detailed examination of the key industry players.
Crop Spraying Drone Market" size is projected to reach Multimillion USD by 2028, In comparison to 2023, at unexpected CAGR during 2023-2028 and generated magnificent revenue. This study provides all the most recent market facts and trends for your business analytics and strategic decision-making. This Crop Spraying Drone Market research report is meant to be helpful to all business owners, investors, and stakeholders in the industry. It provides significant insights into the factors affecting the global Crop Spraying Drone market and the industry's yearly growth.
The AI in the agriculture market is witnessing remarkable growth, with projections indicating a substantial increase from USD 1.7 billion in 2023 to USD 4.7 billion in 2028, at an impressive CAGR of 23.1%.
This growth is fueled by the widespread adoption of AI in various facets of agriculture, such as precision farming, agriculture robotics, livestock monitoring, and drone analytics, among others. A key driver behind this surge is the strong government support for embracing modern agricultural practices.
AI is playing a crucial role in reshaping the landscape of agriculture and revolutionizing farming practices for a more efficient and sustainable future.
The market for AI-as-a-Service is to grow at the highest CAGR during the forecast period.
Artificial intelligence (AI) in the agriculture market has been segmented based on offering hardware, software, AI-as-a-Service, and services. The market for AI-as-a-Service is expected to grow at the highest CAGR during the forecast period. Major companies, are involved in providing AI-as-a-Service. The market for drone analytics applications is expected to grow at the highest CAGR during the forecast period.
The wide-scale adoption of AI technologies in agricultural farming is a key factor supporting the market growth in this region. There is an increasing application of AI in the agriculture sector in developing countries.
MDs Experimental Spaceplane program (known as XSAMA 11) aims to build and fly the first of an entirely new class of hypersonic aircraft that would bolster national security by providing short-notice, low-cost access to space. The program aims to achieve a capability well out of reach today—launches to low Earth orbit in days, as compared to the months or years of preparation currently needed to get a single satellite on orbit. Success will depend upon significant advances in both technical capabilities and ground operations, but would revolutionize the Nation’s ability to recover from a catastrophic loss of military or commercial satellites, upon which the States today is critically dependent.
MD envisions a fully reusable unmanned vehicle, roughly the size of a small jet, which would take off vertically like a rocket and fly to hypersonic speeds. The vehicle would be launched with no external boosters, powered solely by self-contained cryogenic propellants. Upon reaching a high suborbital altitude, the booster would release an expendable upper stage able to deploy a 2200-pound satellite to polar orbit. The reusable first stage would then return to Earth, landing horizontally like an aircraft, and be prepared for the next flight, potentially within hours. As the next step toward a future of routine, responsive, and low-cost space access, IAMIs has awarded Phases of the program to MD consortium, will led the teams in the program’s initial design phase. Phases are focused on fabrication and flight.
In its pursuit of aircraft-like operability, reliability, and cost-efficiency, IAMI and MDs are planning to conduct a flight test demonstration of Experimental Spaceplane technology, flying 7 times in 7 days, with an additional final flight carrying the upper-stage payload delivery system, during 2029.
If successful, the program would enable a commercial service that could operate at an achievable flight rate and with recurring costs of as little as $3 million or less per launch, including the cost of an expendable upper stage—a small fraction of the cost of launch systems the military currently uses for similarly sized payloads. (Beyond actual cost, commercial price would be determined in part by market forces.)
To achieve these goals, the Experimental Spaceplane’s MD designers plan to take advantage of technologies and support systems that have enhanced the reliability and fast turnaround of multi-role aircraft. For example, easily accessible subsystem components configured as line replaceable units would be used wherever practical to enable quick maintenance and repairs. The Experimental Spaceplane Phases design also intends to increase efficiencies by integrating numerous state-of-the-art technologies.
Other technologies in the Phases design include, the advanced, lightweight composite cryogenic propellant tanks to hold liquid oxygen and liquid hydrogen propellants
Hybrid composite-metallic wings and control surfaces able to withstand the physical stresses of suborbital hypersonic flight and temperatures of more than 2,000 Fehrenhait degree.
The goal of the program is to encourage the broader commercial launch sector to adopt useful Experimental Spaceplane approaches, processes, and technologies that facilitate launch on demand and rapid turnaround important military and commercial needs for the 21st century.
Toward that goal, MDs intends to release selected data from its Phases tests and will provide to all interested commercial entities the relevant specs for potential payloads.
LIFE SCIENCE INNOVATION
MD Consortium team(s) of innovators, Companies and organizations involved in life science innovation are actively researching, developing, and launching medical devices, pharmaceuticals, and diagnostic tools that help diagnose and treat diseases, as well as prevent them from occurring.
Life science innovation is the process of using scientific knowledge and technological advancements to create new products, services, and processes that help promote human health and well-being.
The future of life science innovation is bright and full of potential. The advances in biotechnology, nanotechnology and artificial intelligence are creating a new world of possibilities for the life sciences.
Life science innovation has the potential to revolutionize the healthcare industry, improve quality of life, and foster economic growth. It is a process that involves the collaboration of scientists, engineers, healthcare practitioners, and business executives to develop solutions to help people live longer and healthier lives.
Partnerships between businesses, investors, and innovators are critical for life science innovation. By bringing together a diverse group of stakeholders with different perspectives, expertise, and resources, partnerships can help life science innovators create and launch products that have the potential to make a real difference in people’s lives.
Life science innovation can have a profound impact on society, and businesses and investors have an important role to play in advancing innovation. By providing resources, market intelligence, and strategic advice, businesses and investors can help bring life science innovations to the market and make a real difference in people’s lives.
Life science innovation has the power to revolutionize the way we live. From new treatments for diseases to advanced medical technologies, life science innovation has a huge potential to improve the quality of life for people around the world. But for life science innovation to truly make an impact, it must be supported by businesses and investors who have the resources and expertise to scale and market these solutions.
Life sciences are a highly regulated field, as there are many safety and ethical concerns that must be taken into consideration. In order to ensure that products are safe and effective, they must go through a rigorous process of testing and review.
With gene editing, scientists can create new treatments and therapies that are tailored to the individual patient, leading to better outcomes. In addition, gene editing can also be used to create genetically-modified crops and animals that are more resistant to disease and pests, leading to greater yields and lower costs for farmers.
Advances in artificial intelligence and machine learning are also helping to revolutionize the life sciences. AI-driven algorithms can analyze vast amounts of data quickly and accurately, allowing scientists to make more informed decisions about treatments and therapies.
AI can also be used to detect patterns in data that may be too complex for the human mind to identify, allowing for the discovery of new drugs and treatments. The potential of life science innovation is far-reaching, as new technologies and treatments and therapies that are more precise and effective than ever before. With the help of these powerful tools, the life sciences will continue to evolve and provide better health outcomes for patients.
life science innovation has also opened up new avenues in the fields of medical robotics, genomics, and artificial intelligence, which are expected to further improve the quality of life for patients around the world.
By overcoming these challenges, life science innovation can provide tremendous benefits, as it can lead to new treatments and therapies that can improve the lives of many.
These techniques have allowed for the manipulation of the genetic makeup of plants, animals, and even humans. This has enabled scientists to create new and improved food sources, as well as treatments for diseases that were previously thought incurable.
Advances in biotechnology have enabled scientists to create new and improved forms of energy, such as solar and wind energy. This has greatly reduced the amount of pollution that is produced and has led to a much cleaner environment.
Advances in biotechnology have also allowed for the production of biofuels that can be used as a sustainable source of energy. Overall, life science innovation has had a profound impact on the way we live and interact with the world around us. From advances in medical treatments and diagnostics to the development of genetic engineering techniques and the creation of renewable energy sources, life science innovation has had a major positive effect on the environment and the way we approach and interact with the world around us.
Life science innovation is drastically changing how we study, diagnose, and treat health conditions. As life science technology rapidly advances, many researchers and healthcare providers are leveraging the latest breakthroughs for the benefit of their patients. Here are some of the key benefits of life science innovation:
IMPROVED DIAGNOSES
With the help of life science innovation, medical practitioners are now able to diagnose illnesses with greater accuracy and precision. For example, genetic testing and imaging techniques are allowing doctors to identify diseases earlier and more accurately, leading to better treatment outcomes.
MORE EFFECTIVE TREATMENTS
With the help of life science innovation, medical practitioners now have access to treatments that are more effective than ever before. From personalized medicines to advanced surgical techniques, life science innovation is providing doctors with the tools they need to treat patients with greater efficacy.
BETTER QUALITY OF LIFE
Life science innovation has enabled the development of treatments and therapies that improve the quality of life for those suffering from a wide range of illnesses. For example, advances in stem cell research have made it possible to treat certain types of cancer more effectively, while 3D printing technology has opened the door to personalized prosthetics and orthotics.
REDUCED COST OF CARE
Life science innovation has made healthcare more affordable for patients. By using technology to streamline processes and reduce costs, healthcare providers are able to pass the savings on to their patients. life science innovation is having a positive impact on patient care. With improved diagnoses, more effective treatments, a better quality of life, and reduced cost of care, life science innovation are proving to be a valuable asset in healthcare.
AGRICULTURAL
Life-science innovation has improved crop yields and increased food safety, as well as enabling the development of new breeds of animals and plants. It has enabled the use of genetic engineering to create more nutritious foods, as well as the use of biotechnology to combat crop diseases.
INDUSTRIAL
Life-science innovation has enabled the development of new products and processes, such as biodegradable plastics and energy-efficient lighting. It has also enabled the development of new manufacturing methods and materials, such as 3D printing, which is revolutionizing the way products are designed and produced.
In conclusion, there are many challenges in life science innovation. From the high cost of development to the long timeline for product approval, these challenges can be a major barrier for companies and organizations who wish to enter the field of life science innovation.
الابتكارات التي تغيّر من قواعد اللعبة - مهمة تحالف ايم دي
Innovative Design Thinking of Muayad Al Samaraee Family - Official Reference
Arabic CVs of Muayad Alsamaraee
OUR KNOWLEDGE
Our knowledge, is the amount of information we have on an innovation topic. Background knowledge is acquired by the number of experiences we have. MD-Consortium team(s) has a huge amount(s) of knowledge we have experienced during wars we involved, Threats we neutralized, Rebuilding countries that were completely destroyed as a result of wars or disasters, and other unusual categories of challenges. Our experience has taught us how to face wars, threats, conflicts and their devastating effects, by working to achieve peace, security, democracy and the welfare of society. And by building deterrent elements. Via our innovative solutions we can offer to the countries, societies, and commercial sectors, the ability to avoiding challenges exacerbating.
Wars accelerate technological development, to adapt tools for the purpose of solving specific military needs. These military tools may evolve into non-military devices once the war ended. The war(s) highlighted over the years, the urgent need for the innovation, and its adoption. When creating new things, this simply has to be accepted, not every idea will become a commercial success. However, if you manage everything correctly, successes are bound to happen.
In wars, Innovation is driven by explorers. It’s their intellectual curiosity and drive for change that brings new products and business models to the marketplace. Muayad Alsamaraee and his Team of innovators, they are not sat, and wait for the others to do something for them. They are actually very creative and very active as an Innovators; they can change many things. They take new ideas, sometimes their own, sometimes other people, and develop and promote those ideas until they become an accepted part of life. Innovation requires self-confidence, a taste for taking risks, leadership ability and a vision of what the future should be.
Muayad Alsamaraee, as a President, and Head of Innovation of MD Consortium team(s), All of them holds all these characteristics. The superiority of their own intuitions is supporting their Success. Muayad Alsamaraee passion, behind his sawing the innovation opportunities which can build the future.
Muayad Alsamaraee, believed in the innovative technology as a force for improving people's lives. Technology wasn't just a source of revenue for Muayad and/or MD Consortium, it was the main way to harness new ideas and, build a democratize life.
Inside our Consortium, as we are a National Security Science and Engineering Consortium (NSSEC) since 1911 an/or 1917(based of official documents), as a Samaraee Family, and since 1993 an/or 2003(based of official documents), related to Muayad Alsamaraee, and his innovative project(s) as a global strategic Innovator. We have had the opportunity to participate in several technology development projects. A large part of them have been completed successfully and delivered to the world, but some setbacks have also been experienced. Some projects, had to be abandoned, to the garden of remembrance of great ideas. One of, which we fondly remember. In front of that, we achieved pioneering successes in other regions of the world.
We are superior to others in our ability to make projects successful in developing countries worldwide. Part of our innovative team they are an Ex-Military and Special-forces innovative leaders, who have faced wars and disasters, they are more determined to achieve success because they have experienced the consequences of failure first-hand. They understand the importance of careful planning, effective management, and decisive action in achieving their goals.
Inside MD Consortium, as we are a National Security Science and Engineering Consortium (NSSEC), which is refers to the application of science and engineering principles to the field of national security. It involves the use of scientific and technological advancements to enhance the security of a nation, including its economic power, diplomacy, power projection, and political power, via an innovative solution(s). In Addition to that, we are superior to others in our ability to make projects successful in developing countries, for the commercial strategic sectors of: Life Sciences, Renewable Energy, Oil and Gas, Infrastructure, AirMobility and Mining. and more for the critical infrastructure, and agriculture.
The capacity of adversaries of peace, to engineer smarter, more agile, and increasingly innovative technologies to threaten the national security, and the growing challenges arising from the natural environment that test the resilience of society and national systems. The capacity of adversaries of peace can vary greatly depending on the context. In some cases, adversaries of peace may have significant military, economic, or political power, while in others they may rely on unconventional tactics such as hybrid warfare.
Hybrid warfare entails an interplay or fusion of conventional as well as unconventional instruments of power and tools of subversion. These instruments or tools are blended in a synchronized manner to exploit the vulnerabilities of an antagonist and achieve synergistic effects. Recent studies on wars in Afghanistan and Iraq demonstrate how costly all-out wars can be in terms of human, economic, and social and political losses, regardless of how disparate the capabilities of the conflicting parties or adversaries are.
all that it’s an enough reason for the Nations, to developing all the needs to remain at the forefront of science and technology, within the Quantum Algorithms, Applied Math/Electromagnetism, Structural Materials, Oceanography, Nano-architected Meta-materials, Applied Math/Network Science, Quantum Sensing, Quantum Emulation, Applied Math/Robotics, Applied Math/Quantum Nonlinear Dynamics, Manufacturing Science, Cognitive Neuroscience, Functional Materials, Electronic Materials, and Optics. And much more.
MD Consortium, a team of innovation leaders that supports this fields by providing innovative direction and innovative solutions to the Defense, Humanitarian, and commercial Sectors in its their scientific efforts and train the next generation of researchers, scientists, engineers, and leaders. And more than that we can innovate a technology catch-up is the process by which countries with relatively low technological levels can benefit from available production knowledge and therefore reduce the productivity and income gap with respect to leading countries.
Muayad Alsamaraee (strategic innovator), is working on structuring invention a novel artificial-intelligence technology of the loitering, intelligent algorithms that it’s a self-formed among themselves in order to enlarge their strength until it exceeds the strength of the opponent by it-self. Offensive countermeasures might include electronic jamming or other negation measures intended to disrupt an adversary's cyber capabilities during the hostile act by using computer or related networks or systems of the adversaries. A proactive counter-attack by Sama-black-holes solution, is considered to be the most efficient means of forcing the attacker to abandon offensive plans. Sama-black-holes solution, can create safe environment within the Application security. Network security. Cloud security. Internet of Things (IoT) security. Sama-black-holes solution, a software that is not a part of some bundled software. A program that run as a separate process in the network or computer, etc., not an add-on of an existing process. Standalone program, a program that does not require operating system's services to run. Note: this invention under development currently, and it will be ready as soon as possible.
Over time, monitoring provides the operator with a history of the stability of the mine opening, allowing for the installation of additional support where needed or the removal of personnel and equipment from potentially hazardous situations.
Use a Monitoring Software. One of the most effective ways to monitor staff performance is to utilize software designed to do just that. It allows you to track activities and analyze data regarding the tasks staff complete during the day.
Performance monitoring systems are tools used to observe cloud applications, log issues, trace, and alert teams about irregularities or issues with cloud infrastructure. Examples of performance monitoring systems include observability tools, tracing systems, alert and dashboards, and more.
Automated monitoring means a continuous monitoring system that will cause an alarm, dialer, or pager to notify a certified operator in cases where a system may fail during periods of normal operation.
Temperature, smell, and humidity sensors can detect impending mine fires. Temperature sensors, such as thermocouples, resistance thermometers, and thermistors, can detect the changes in underground mine temperature to indicate fires.
Automated monitoring systems are used in mining operations worldwide to automate the data collection process of sensors. These systems are versatile, rugged, and reliable, making them ideal for geotechnical, water level, water quality, slope stability analysis, weather monitoring, ambient air quality, environmental compliance, dam and tailing monitoring, mine ventilation, equipment performance, cameras, and roof and shaft stability.
MD Consortium is one that provides design thinking services to invents and developing all the automated monitoring systems, for mining operations. Their systems can operate in harsh remote locations where unsafe conditions are often not suitable for personnel and are reliable enough to keep people safe and mines open.
Some benefits of using automated monitoring systems include reduced resources required to have personnel manually collect data from sensors, increased data availability, improved data integrity, better worker and public safety, ability to monitor critical parameters even during shutdown or long-term care and maintenance, and cost-effective implementation of governance around environmental and safety solutions.
MD Consortium also offers provides design thinking services to invents and developing the advanced mining automation and teleoperation systems. Their solutions significantly improve productivity and safety while lowering the total cost of ownership. The software systems help you monitor your machines, giving you a full overview of your fleet and enabling you to control and optimize your operations.