MCQOPTIONS
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MCQOPTIONS
This section includes 10 Mcqs, each offering curated multiple-choice questions to sharpen your Computational Fluid Dynamics knowledge and support exam preparation. Choose a topic below to get started.
| 1. |
Which of these is not an equivalent to for substantial derivative? |
| A. | Lagrangian derivative |
| B. | Material derivative |
| C. | Total derivative |
| D. | Eulerian derivative |
| Answer» E. | |
| 2. |
Substantial derivative is the same as ________ of differential calculus. |
| A. | Partial derivative |
| B. | Instantaneous derivative |
| C. | Total derivative |
| D. | Local derivative |
| Answer» D. Local derivative | |
| 3. |
Which of these terms represent the convective derivative of temperature (T)? |
| A. | ( vec{V}. nabla T ) |
| B. | ( frac{DT}{Dt} ) |
| C. | T |
| D. | ( frac{ partial T}{ partial t} ) |
| Answer» B. ( frac{DT}{Dt} ) | |
| 4. |
Substantial derivative = _____ + _____ |
| A. | Partial derivative, convective derivative |
| B. | Local derivative, convective derivative |
| C. | Local derivative, partial derivative |
| D. | Total derivative, convective derivative |
| Answer» C. Local derivative, partial derivative | |
| 5. |
A flow property has substantial derivative. What does this imply? |
| A. | The property is a function of both time and space |
| B. | The property is a function of time only |
| C. | The property is a function of space only |
| D. | The property is independent of time and space |
| Answer» B. The property is a function of time only | |
| 6. |
Which of these statements best defines local derivative? |
| A. | Time rate of change |
| B. | Spatial rate of change |
| C. | Time rate of change of a moving point |
| D. | Time rate of change at a fixed point |
| Answer» E. | |
| 7. |
The simplified form of substantial derivative can be given by __________ |
| A. | ( frac{DT}{Dt}= frac{ partial T}{ partial t}+ nabla T ) |
| B. | ( frac{DT}{Dt}= frac{ partial T}{ partial t}+ nabla .T ) |
| C. | ( frac{DT}{Dt}= frac{ partial T}{ partial t}+ vec{V}. nabla T ) |
| D. | ( frac{DT}{Dt}= frac{ partial T}{ partial t}+ nabla times T ) |
| Answer» D. ( frac{DT}{Dt}= frac{ partial T}{ partial t}+ nabla times T ) | |
| 8. |
Substantial derivative applies to ____________ |
| A. | Both stationary and moving models |
| B. | Only moving models |
| C. | Only stationary models |
| D. | Neither stationary nor moving models |
| Answer» C. Only stationary models | |
| 9. |
Expand the substantial derivative D /Dt. |
| A. | ( frac{D rho}{Dt}= frac{d rho}{dt}+u frac{d rho}{dx}+v frac{d rho}{dy}+w frac{d rho}{dz} ) |
| B. | ( frac{D rho}{Dt}= frac{ partial rho}{ partial t}+u frac{d rho}{dy}+v frac{d rho}{dz}+w frac{d rho}{dx} ) |
| C. | ( frac{D rho}{Dt}= frac{d rho}{dz}+u frac{ partial rho}{ partial y}+v frac{ partial rho}{ partial z}+w frac{ partial rho}{ partial t} ) |
| D. | ( frac{D rho}{Dt}= frac{ partial rho}{ partial t}+u frac{ partial rho}{ partial x}+v frac{ partial rho}{ partial y}+w frac{ partial rho}{ partial z} ) |
| Answer» E. | |
| 10. |
How is the substantial derivative of velocity vector denoted? |
| A. | ( frac{D vec{V}}{Dt} ) |
| B. | ( frac{d vec{V}}{dt} ) |
| C. | ( frac{ partial vec{V}}{ partial t} ) |
| D. | ( frac{D vec{V}}{Dx} ) |
| Answer» B. ( frac{d vec{V}}{dt} ) | |