Industries

Zero gravity influences the cell structure of plants; the tissue growth on plants could be radically different in space. Several experiments using the culture of cells, tissues, and small organisms on the orbit helps to increase our understanding of biological processes in microgravity.

Ocean circulation patterns play a crucial role in climate regulation and are essential for keeping our planet safe and habitable. Monitoring various factors that affect the earth, like sea-level changes, climatic changes, volcanic activities, landslides, groundwater monitoring, land and sea ice density, pollution, and so on, are easy from outer space using various sensors and imaging techniques. Solar activity also can have an impact on the earth's atmosphere and weather patterns. Solar flares send tons of energy across space that can potentially wreak havoc on the satellites used for communications and navigation. It can also disrupt our power grids and can be hazardous for the astronauts in space.

Living in microgravity causes several physiological and biochemical changes in the human body. Research is underway to learn the consequences of physiological adaptations for human health and ways to counteract those changes in the human body. As such, space exploration is a major driving force behind the development of advanced medical machines. Continued research in this area would help us prepare for prolonged missions that extend beyond the earth's field of influence.

This unique microgravity environment allows different physical properties to dominate systems, and these have been harnessed for a wide variety of physical sciences. Studies in weightlessness can reveal properties that are important for energy production or environmental protection. Space research has already increased knowledge on combustion, liquids in porous substances and how dust particles behave.

In a connected world, IoT devices are set to play a pivotal role. IoT devices are set to revamp the transport infrastructure, including public transport networks. Connected cars and similar transport modules require a steady stream of data from transport hubs and satellites.

Vehicles of the future require a constant stream of data from transport hubs and satellites to be mobile.

Another area of growth is going to be asset tracking, as goods worth millions and billions are traveling across the globe every day. When a ship approaches a destination port, the communication devices of the port and ship can automatically exchange useful logistic information to ensure maximum efficiency and safety.

As traffic density increases every day, eyes from the skies can undoubtedly help us remove congestion from our roads. When an accident occurs or during high-density traffic, the satellites can immediately identify those situations and notify the transport hubs. Such information will help the traffic enforcement agencies to alert the vehicles in the vicinity so that they can move on to an efficient route.

Drones are rapidly making inroads into the transport sector. Now, they deliver anything from pizzas to medicines. Soon, they would become the first choice responders during incidents. Due to their remarkable agility, drones can reach incident spots that are hard to reach by other means and quickly provide vital assistance.

Major automobile manufacturers are now adding more semi-autonomous and autonomous vehicles on the road. Vehicles with assisted driving capabilities rely on connected services and global navigation satellite systems (GNSS) for their operations. In such scenarios, satellite constellations play a crucial role in delivering reliable GNSS connectivity for autonomous vehicles.