Chandrayaan-3’s failure-based design is an approach to spacecraft design that focuses on identifying and mitigating potential failures. This is done by designing the spacecraft with redundancy and flexibility, so that it can continue to function even if some components fail.
Failure-based design is a key part of Chandrayaan-3’s design, as it is a complex mission with many moving parts. By identifying and mitigating potential failures, the Indian Space Research Organisation (ISRO) is increasing the chances of success for the mission.
Here are some of the ways in which Chandrayaan-3’s failure-based design is implemented:
- Redundancy: The spacecraft has multiple redundant systems in place, so that if one system fails, another can take over. For example, Chandrayaan-3 has two sets of solar panels, so that if one set fails, the other set can still provide power to the spacecraft.
- Flexibility: The spacecraft is designed to be flexible, so that it can adapt to changes in the environment or unexpected events. For example, Chandrayaan-3 has a system that can adjust the spacecraft’s orbit if it encounters unexpected drag from the Earth’s atmosphere.
- Testing: Chandrayaan-3 has been extensively tested to identify and mitigate potential failures. This testing has included both physical testing and computer simulations.
The failure-based design of Chandrayaan-3 is a key factor in the mission’s chances of success. By identifying and mitigating potential failures, ISRO is increasing the chances that Chandrayaan-3 will be able to successfully complete its mission.
WHAT IS CHANDRAYAAN-3’S FAILURE-BASED DESIGN?
Failure-based design is an approach to engineering that focuses on identifying and mitigating potential failures. This is done by designing the system with redundancy and flexibility, so that it can continue to function even if some components fail.
Redundancy means having multiple copies of critical components. This way, if one component fails, another can take over. For example, Chandrayaan-3 has two sets of solar panels, so that if one set fails, the other set can still provide power to the spacecraft.
Flexibility means designing the system so that it can adapt to changes in the environment or unexpected events. For example, Chandrayaan-3 has a system that can adjust the spacecraft’s orbit if it encounters unexpected drag from the Earth’s atmosphere.
Testing is an important part of failure-based design. By testing the system under a variety of conditions, engineers can identify potential failures and develop mitigation strategies. Chandrayaan-3 has been extensively tested to identify and mitigate potential failures. This testing has included both physical testing and computer simulations.
The failure-based design of Chandrayaan-3 is a key factor in the mission’s chances of success. By identifying and mitigating potential failures, ISRO is increasing the chances that Chandrayaan-3 will be able to successfully complete its mission.
Here is an analogy that might help you understand failure-based design. Imagine you are building a house. You could design the house with a single foundation, but if that foundation fails, the whole house will collapse. A better approach would be to design the house with multiple foundations, so that if one foundation fails, the others can still support the house. This is the same principle behind failure-based design.
Failure-based design is a complex and challenging engineering discipline, but it is essential for the success of many complex systems. Chandrayaan-3 is a prime example of a mission that has benefited from failure-based design.