References

Abbassi, M.B., M.H. Gahruei and S. Vahidi, 2012. Comparison of the performances of biodiesel, diesel and their compound in Air standard diesel-atkinson cycle. J. Am. Sci., 8: 223-229.
Direct Link  |  

Al-Sarkhi, A., B.A. Akash, J.O. Jaber, M.S. Mohsen and E. Abu-Nada, 2002. Efficiency of Miller engine at maximum power density. Int. Commun. Heat Mass Transfer, 29: 1159-1167.
CrossRef  |  Direct Link  |  

Al-Sarkhi, A., I. Al-Hinti, E. Abu-Nada and B. Akash, 2007. Performance evaluation of irreversible Miller engine under various specific heat models. Int. Commun. Heat Mass Trans., 34: 897-906.
CrossRef  |  

Al-Sarkhi, A., J.O. Jaber and S.D. Probert, 2006. Efficiency of a Miller engine. Applied Energy, 83: 343-351.
CrossRef  |  

Brunt, M.F.J., H. Rai and A.L. Emtage, 1998. The calculation of heat release energy from engine cylinder pressure data. SAE Technical Paper No. 981052, University of Central England.

Ceviz, M.A. and I. Kaymaz, 2005. Temperature and air-fuel ratio dependent specific heat ratio functions for lean burned and unburned mixture. Energy Convers. Manage., 46: 2387-2404.
CrossRef  |  

Chen, L., J. Wang and F. Sun, 2008. Power density analysis and optimization of an irreversible closed intercooled regenerated Brayton cycle. Math. Comput. Modell., 48: 527-540.
CrossRef  |  

Chen, L., Y. Ge and F. Sun, 2010. The performance of a Miller cycle with heat transfer, friction and variable specific heats of working fluid. Termotehnica, 14: 24-32.

Ebrahimi, R., 2010. Effects of variable specific heat ratio of working fluid on performance of an endoreversible diesel cycle. J. Energy Inst., 83: 1-5.

Ebrahimi, R., 2010. Performance analysis of a dual cycle engine with considerations of pressure ratio and cut-off ratio. Acta Physica Polonica A, 118: 534-539.

Ebrahimi, R., 2011. Thermodynamic modeling of performance of a Miller cycle with engine speed and variable specific heat ratio of working fluid. Comput. Math. Applied, 62: 2169-2176.
CrossRef  |  

Fukuzawa, Y., H. Shimoda, Y. Kakuhama, H. Endo and K. Tanaka, 2001. Development of high efficiency Miller cycle gas engine. Tech. Rev., 38: 146-150.

Gatowski, J.A., E.N. Balles, K.M. Chun, F. Nelson, J.A. Ekchian and F.B. Heywood, 1984. A heat release analysis of engine pressure data. SAE Technical Paper No. 841359, Massachusetts Institute of Technology.

Ge, Y., L. Chen, F. Sun and C. Wu, 2005. Effects of heat transfer and friction on the performance of an irreversible air-standard Miller cycle. Int. Commun. Heat Mass Trans., 32: 1045-1056.
CrossRef  |  

Ge, Y., L. Chen, F. Sun and C. Wu, 2005. Effects of heat transfer and variable specific heats of working fluid on performance of a Miller cycle. Int. J. Ambient Energy, 26: 203-214.

Ge, Y., L. Chen, F. Sun and C. Wu, 2005. Reciprocating heat-engine cycles. Applied Energy, 81: 397-408.
CrossRef  |  

Gogoi, T.K. and D.C. Baruah, 2010. A cycle simulation model for predicting the performance of a diesel engine fuelled by diesel and biodiesel blends. Energy, 35: 1317-1323.
CrossRef  |  

Hatamura, K., M. Hayakawa, T. Goto and M. Hitomi, 1997. A study of the improvement effect of Miller-cycle on mean effective pressure limit for high-pressure supercharged gasoline engines. JSAE Rev., 18: 101-106.
CrossRef  |  

Jesudason, C.G., 2009. Focus on the clausius inequalities as a consequence of modeling thermodynamic systems as a series of open carnot cycles. Math. Comput. Modell., 49: 835-842.
CrossRef  |  

Kesgin, U., 2005. Efficiency improvement and NOx emission reduction potentials of two-stage turbocharged Miller cycle for stationary natural gas engines. Int. J. Energy Res., 29: 189-216.
CrossRef  |  Direct Link  |  

Klein, M., 2004. A specific heat ratio model and compression ratio estimation. Ph.D. Thesis, Department of Electrical Engineering, Linkoping University, Sweden.

Lin, J.C. and S.S. Hou, 2008. Performance analysis of an air-standard Miller cycle with considerations of heat loss as a percentage of fuel's energy, friction and variable specific heats of working fluid. Int. J. Thermal Sci., 47: 182-191.
CrossRef  |  

Miller, R.H., 1947. Supercharging and internally cooling for high output. ASME Trans., 69: 453-464.

Parlak, A., 2005. The effect of heat transfer on performance of the diesel cycle and exergy of the exhaust gas stream in a LHR diesel engine at the optimum injection timing. Energy Convers. Manage., 46: 167-179.
CrossRef  |  

Sasaki, M., S. Araki, T. Miyata and T. Kawaji, 2002. Development of capacitor hybrid system for urban buses. JSAE Rev., 23: 451-457.
CrossRef  |  

Wu, C., P.V. Puzinauskas and J.S. Tsai, 2003. Performance analysis and optimization of a supercharged Miller cycle Otto engine. Applied Thermal Eng., 23: 511-521.
CrossRef  |  

Zhao, Y. and J. Chen, 2007. Performance analysis of an irreversible Miller heat engine and its optimum criteria. Applied Thermal Eng., 27: 2051-2058.
CrossRef  |