5 Must Know Facts For Your Next Test

1. When calculating the probability of multiple components functioning correctly, if the components are independent, you can multiply their individual probabilities together.
2. In systems where components are dependent, the calculation becomes more complex, requiring an understanding of how the failure of one component affects others.
3. High reliability in systems is often achieved through redundancy, where additional components are included to take over if one fails.
4. The probability of failure of a system is often more significant than individual component failures, as it can result from interactions between components.
5. Understanding this probability is essential in fields like engineering and safety management to minimize risks and ensure system effectiveness.

Review Questions

• How do you calculate the probability of multiple independent components functioning correctly in a system?
  • To calculate the probability of multiple independent components functioning correctly, you simply multiply the individual probabilities of each component working. For example, if Component A has a probability of 0.9 and Component B has a probability of 0.8, then the overall probability of both functioning correctly is 0.9 * 0.8 = 0.72. This means there's a 72% chance that both components will work without failure.
• Discuss how the dependency of components affects the overall probability of a system functioning correctly.
  • When components are dependent, calculating the overall probability of correct functioning becomes more complicated. The failure of one component can influence others, changing their probabilities based on their interactions. For instance, if Component A fails and it directly affects Component B's ability to function, then B's probability must be adjusted accordingly. This interdependence highlights the importance of understanding both individual component reliability and their relationships within the system.
• Evaluate how redundancy can improve the probability of multiple components functioning correctly in critical systems.
  • Redundancy enhances the overall reliability of critical systems by providing backup options if primary components fail. For instance, in an engineering context, using duplicate systems or parts means that even if one fails, others can take over seamlessly. By increasing the number of functional paths or components, redundancy raises the collective probability that at least one will operate correctly at any given time. This strategic addition significantly lowers the risk of complete system failure, making it vital for applications where reliability is crucial.

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