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Cooling of heat dissipating components became an important topic in the last decades. Sometimes a simple solution is possible, such a placing critital component closer to the fan outlet. On the other hand this component will heat the air which has to cool the other components further away from the fan outlet. If a substrate bearing a one dimensional array of heat dissipating components, is cooled by forced convection only, an integral equation relating temperature and power is obtained. The forced convection will be modelled by a simple analytical wake function. It will be demonstrated that the integral equation can be solved analytically using fractionol calculus.

(1) Y. Cengel: "Heat transfer", Mc Graw Hill, Boston,2003, chapter 15.

(2) I. Sokolov, J. Klafter and A. Blumen: "Fractional kinetics", Physics To-day, 2002, vol.55, nr.11, p.48-54.

(3) R. Magin, S. Boregowda and C. Deodhar: "Modelling of pulsating pe-ripheral bioheat transfer using fractional calculus and constructal theory", International Journal of Design and Nature, 2007, vol.1, nr.1, p.18-33.

(4) A. M. Anderson and R. J. Moat: "The adiabatic heat transfer coecient and the superposition kernel function: Part I: Data for arrays of atpacks for dierent low conditions", Journal of Electronic Packaging, 1992, vol.12, p.14-21.

(5) A. M. Anderson and R. J. Moat: "The adiabatic heat transfer coe-cient and the superposition kernel function: Part II: Modeling atpack data as a function of channel turbulence", Journal of Electronic Packaging, 1992, vol.112, p.14-21.

(6) O. Leon, G. De Mey, E. Dick: "Study of the optimal layout of cooling ns in forced convection cooling", Microelectronics Reliability, 2002, vol.42, p.1101-1111.

(7) R. A. Wirtz and P. Dykshoorn: "Heat transfer from arrays of

at packs in a channel ow", Proceedings 4th IEPS conference, Baltimore, p.318-326.

(8) R. A. Wirtz: "Forced air cooling of low prole air cooling", in "Air cool-ing technology for electronic equipment" (ed.: S. J. Kim and S. W. Lee), CRC Press, New York, 1996, p.92-102.

(9) S. S. Kang: "The thermal wake function for rectangular electronic mod-ules", Journal of Electronic Packaging, 1994, vol.116, p.55-59.

(10) G. De Mey, M. Felczak and B. Wiecek: "Exact solution for optimal placement of electronic components on linear array using analytical thermal wake function", Electronics Letters, 2008, vol.44, p.1216-1217.

(11) M. Abramowitz and I. Stegun: "Handbook of mathematical functions", Dover, New York, 1970, p.255-258.