Work place: College of Engineering Air Force Engineering University Xi’an, Shannxi Province, China
E-mail: meifeifff@163.com
Website:
Research Interests: Engineering
Biography
Fei Mei was born in Jinxian, Jiangxi Province,China on July 30th 1984. Mei is now a doctor candidate at Air Force Engineering University(AFEU), City of Xi’an, Shannxi Province. Mei was awarded the Degree of Bachelor of Engineering in aeronautics in AFEU on July 22th, 2006.Mei received the Degree of Master in aerospace propulsion theory and engineering in AFEU on April, 2009.
He has been worked to build an aero-engine test and data acquisition system in propulsion system laboratory in AFEU from Oct.2006 to Mar.2007. Then he has devoted to simulation and experiment study of aircraft exhaust plume flow field. His current research interest is infrared signature of aircraft.
By Fei Mei Shiguo Chen YingHong Li Yong Jiang Jing Cai ShuKun Zhang
DOI: https://doi.org/10.5815/ijem.2012.03.07, Pub. Date: 29 Jun. 2012
An infrared imaging prediction model of exhaust plume was developed to understanding the infrared characteristics of exhaust plume. The method is based on the irradiance calculation of all pixels on the focal plane array. In order to compute the irradiance incident on each pixel, the gas radiation transfer path in the plume for the instantaneous field of view (IFOV) corresponds to the pixel was solved by the simultaneous equation of a cylinder which covers the exhaust plume and the line of sight. Radiance for the transfer path was calculated by equation of radiation transfer for nonscattering gas. The radiative properties of combustion were computed by Malkmus model with EM2C narrow band database(25cm-1). The pressure, species concentration for the path was determination by CFD analysis. The relatively intensity of each pixel was transferred to color in the display according to gray map coding and hot map coding. Infrared image of the exhaust plumes from a subsonic axisymmetric nozzle was predicted with the model. By changing the parameters, such as FOV and space resolution , the image of different imaging system can be predicted for varying relatively position of camera and the plume.
[...] Read more.By Fei Mei Shiguo Chen Yong Jiang Jing Cai
DOI: https://doi.org/10.5815/ijigsp.2011.04.07, Pub. Date: 8 Jun. 2011
Based on the irradiance calculation of all pixels on the focal plane array, a preliminary infrared imaging prediction model of exhaust plume that have considered the geometrical and the thermal resolution of the camera was developed to understanding the infrared characteristics of exhaust plume. In order to compute the irradiance incident on each pixel, the gas radiation transfer path in the plume for the instantaneous field of view corresponds to the pixel was solved by the simultaneous equation of a enclosure cylinder which covers the exhaust plume and the line of sight. Radiance of the transfer path was calculated by radiation transfer equation for nonscattering gas. The radiative properties of combustion needed in the equation was provided by employing Malkmus model with EM2C narrow band database(25cm-1). The pressure, species concentration along the path was determination by CFD analysis. The relative irradiance intensity of each pixel was converted to color in the display according to gray map coding and hot map coding. Infrared image of the exhaust plumes from a subsonic axisymmetric nozzle with different relative position of camera and the plume was predicted with the model. By changing the parameters, such as FOV and space resolution, the image of different imaging system can be predicted.
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