[03/Tennsift/04]

Questions and Answers

What engineering principle does Flow.BI follow?

• Adding complexity only when needed (correct)
• Maximizing complexity for all solutions
• Minimizing complexity at all times
• Adding complexity without reason

How does having less entities in Flow.BI affect solutions?

• It has no impact on solution speed
• It often translates into faster solutions (correct)
• It results in more entities
• It leads to more complex solutions

What is the result of following engineering principles in Flow.BI?

• Less entities (correct)
• Constant entities
• More entities
• Unpredictable entities

Flow.BI adds complexity only when it is absolutely necessary.

True (A)

Having less entities in Flow.BI often leads to slower solutions.

False (B)

Every complexity in Flow.BI has a reason and can be explained.

True (A)

Match the following engineering principles with their descriptions in Flow.BI:

Adding complexity only when needed = Every complexity has a reason and can be explained Results in less entities = Less entities often translate into faster solutions (less joins) Definition of "Best" in Flow.BI = Flow.BI follows engineering principles Complexity in Flow.BI = Complexity in Flow.BI has a reason and can be explained

Match the following outcomes with their causes in Flow.BI:

Less entities = Faster solutions (less joins) Adding complexity only when needed = Engineering principles in Flow.BI Every complexity has a reason and can be explained = Flow.BI's approach to complexity Following engineering principles = Definition of "Best" in Flow.BI

Match the following statements with their meanings in Flow.BI:

Results in less entities = Less entities often lead to faster solutions Adding complexity only when needed = Complexity is introduced in Flow.BI with a reason and explanation Flow.BI follows engineering principles = Definition of "Best" in Flow.BI Every complexity has a reason and can be explained = Approach to complexity in Flow.BI

What is one of the most important engineering principles related to designing systems in terms of cost, energy consumption, and other resources?

Efficiency (C)

Which engineering principle focuses on designing systems that are safe for users and the environment?

Safety (D)

What engineering principle emphasizes the need to design systems that can withstand unexpected stresses and failures?

Reliability (D)

Which engineering principle involves designing systems with modularity and built-in test points to ensure they meet requirements and perform as expected?

Testability (D)

What is the engineering principle that requires considering the manufacturability of designs by using cost-effective and scalable materials and processes?

Manufacturability (B)

Which engineering principle emphasizes designing systems that are easy to maintain and repair?

Maintainability (B)

Which engineering principle emphasizes the responsibility to design and build systems that are safe for users and the environment?

Safety (C)

What principles do software engineers use to design and implement complex software systems?

Modularity, abstraction, and encapsulation (C)

Which principles do electrical engineers use to design and build electrical circuits?

Ohm's law and Kirchhoff's laws (B)

What principles do mechanical engineers use to design and build machines and other mechanical systems?

Newton's laws of motion and thermodynamics (B)

What are engineering principles essential for when designing and building systems?

Designing and building safe, reliable, efficient, manufacturable, testable, and maintainable systems (A)

What is the purpose of following engineering principles?

To ensure that systems meet the needs of users and stakeholders (A)

What do modular components and designing systems for accessibility mean in engineering?

Using interchangeable parts and making systems usable by all individuals (B)

What do specific engineering principles cater to in different disciplines?

They cater to the specific needs and requirements of each discipline (A)

Engineering principles are only applicable to software engineering.

False (B)

Ohm's law and Kirchhoff's laws are used by mechanical engineers to design and build machines.

False (B)

Engineering principles are not essential for designing safe and reliable systems.

False (B)

Newton's laws of motion and thermodynamics are used by mechanical engineers to design and build machines.

True (A)

Engineers can help ensure that their systems meet the needs of users and stakeholders by following engineering principles.

True (A)

Modularity, abstraction, and encapsulation are principles used by electrical engineers to design and build electrical circuits.

False (B)

All engineering principles are discipline-specific and do not overlap.

False (B)

Engineering principles are not based on scientific knowledge and experience

False (B)

Engineers do not have a responsibility to design and build systems that are safe for users and the environment

False (B)

Efficiency in engineering does not involve optimizing systems for performance and minimizing waste

False (B)

Maintainability is not an important engineering principle

False (B)

Reliability in engineering does not involve designing systems that can perform their intended function consistently and accurately

False (B)

Testability in engineering does not involve designing systems with modularity and built-in test points

False (B)

Manufacturability is not a consideration for engineers when designing systems

False (B)

Match the following engineering principles with their respective disciplines:

Modularity, abstraction, and encapsulation = Software engineering Ohm's law and Kirchhoff's laws = Electrical engineering Newton's laws of motion and thermodynamics = Mechanical engineering General principles and specific engineering principles = All engineering disciplines

Match the following engineering principles with their purposes in designing systems:

Safety, reliability, efficiency, manufacturability, testability, and maintainability = Ensuring system quality and meeting user needs Modularity, abstraction, and encapsulation = Designing and implementing complex software systems Ohm's law and Kirchhoff's laws = Designing and building electrical circuits Newton's laws of motion and thermodynamics = Designing and building machines and mechanical systems

Match the following general engineering principles with their specific application:

Modularity, abstraction, and encapsulation = Design and implementation of complex software systems Ohm's law and Kirchhoff's laws = Design and build electrical circuits Newton's laws of motion and thermodynamics = Design and build machines and mechanical systems Safety, reliability, efficiency, manufacturability, testability, and maintainability = Designing and building safe, reliable, efficient, manufacturable, testable, and maintainable systems

Match the following principles with their role in ensuring system functionality and performance:

Modularity, abstraction, and encapsulation = Improving system design and implementation Ohm's law and Kirchhoff's laws = Ensuring electrical system functionality Newton's laws of motion and thermodynamics = Ensuring mechanical system functionality Safety, reliability, efficiency, manufacturability, testability, and maintainability = Ensuring overall system quality and performance

Match the following engineering principles with their descriptions:

Safety = Design and build systems that are safe for users and the environment Reliability = Design systems that can perform their intended function consistently and accurately Efficiency = Optimizing systems for performance and minimizing waste Maintainability = Design systems that are easy to maintain and repair

Match the following engineering principles with their focus areas:

Safety = User and environmental protection Reliability = Consistent and accurate system performance Efficiency = Cost, energy consumption, and resource optimization Maintainability = Ease of maintenance and repair

Match the following engineering principles with their responsibilities:

Safety = Mitigating potential hazards for users and the environment Reliability = Designing systems to withstand unexpected stresses and failures Efficiency = Optimizing systems for cost-effective and resource-efficient performance Maintainability = Ensuring ease of maintenance and repair for systems

Match the following engineering principles with their testing focus:

Safety = Considering all potential hazards and taking steps to mitigate them Reliability = Designing systems that can be easily tested to ensure performance Efficiency = Optimizing systems for performance and minimizing waste Maintainability = Designing systems with modularity and built-in test points

Match the following engineering principles with their consideration areas:

Safety = Considering all potential hazards for users and the environment Reliability = Accounting for all possible operating conditions and designing for unexpected stresses Efficiency = Optimizing systems for cost, energy consumption, and other resources Maintainability = Considering ease of maintenance and repair for systems

Match the following engineering principles with their design requirements:

Safety = Design and build systems that are safe for users and the environment Reliability = Design systems that can perform their intended function consistently and accurately Efficiency = Optimizing systems for cost-effective and resource-efficient performance Maintainability = Designing systems that are easy to maintain and repair

Match the following engineering principles with their key objectives:

Safety = Design and build systems that are safe for users and the environment Reliability = Design systems that can perform their intended function consistently and accurately Efficiency = Optimizing systems for cost-effective and resource-efficient performance Maintainability = Designing systems that are easy to maintain and repair

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