Develop a computer code (you can use any platform of your choice; MATLAB, C, Python,
Excel etc.) that can simulate a constant volume combustion cycle. Use the programming flow explained in
class notes (lecture 7, pages 11-12).
Input parameters:
Compression ratio: 10 and 14.
Exhaust pressure, Pe: 100 kPa
Manifold (inlet) temperature, Ta: 290 K
Heat input: 2600 kJ/kg.
Assume an ideal cycle with isentropic expansion and compression.

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Requirement: Develop a computer code (you can use any platform of your choice; MATLAB, C, Python, Excel etc.) that can simulate a constant volume combustion cycle. Use the programming flow explained in class notes (lecture 7, pages 11-12). Input parameters: Compression ratio: 10 and 14. Exhaust pressure, Pe: 100 kPa Manifold (inlet) temperature, Tạ: 290 K Heat input: 2600 kJ/kg. Assume an ideal cycle with isentropic expansion and compression. Deliverables (minimum) - The program file – original matlab, C, Excel ete file (size less than 10 MB). - A report (single pdf file with a size less than 10 MB) consisting of: o Plots of volumetric efficiency vs P/Pe, indicated fuel conversion efficiency vs P/Pe, exhaust residual fraction vs P:/Pe, exhaust temperature vs P:/Pe for two different values of compression ratio (re = 10 and re = 14) where P; is inlet pressure with values 50 kPa, 75 kPa, 100 kPa, 125 kPa, 150 kPa. Note that the last two values indicate supercharged operation. o Discussion of the results You are free to present other interesting results and discuss them.

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