• DocumentCode
    1919208
  • Title

    Calculation of the temperature development in electronic systems by convolution integrals

  • Author

    Gerstenmaier, Y.C. ; Wachutka, G.

  • Author_Institution
    Corp. Technol., Siemens AG, Munich, Germany
  • fYear
    2000
  • fDate
    2000
  • Firstpage
    50
  • Lastpage
    59
  • Abstract
    The temperature evolution at selected locations in an electronic set-up can be determined for arbitrary pulses of dissipated power once the thermal impedance of these locations to the ambient is known. The method used is the evaluation of the convolution integral of power evolution and thermal impedance in the time domain. A precise definition of the thermal impedance “junction to ambient” ZthJA for power semiconductor devices and its relation to ZthJC (junction to case) is given. By using a quantum mechanical analog to the heat conduction equation, a representation of the impedances in terms of eigenfunctions and eigenvalues of the underlying differential operator is established. It is shown that generally, for systems of finite extension, the time-constant spectrum is discrete, positive and approaching zero with increasing number index. The model thus obtained can be fitted to the Zth functions, which are received either by measurement or by simulation of the complete set-up. Analytical closed-form expressions for the temperature evolution in case of simple power waveforms are derived. Using this for the interpolation of arbitrary power pulses, a considerable gain in computation speed for the convolution integrals by a factor 50 is obtained. The method described is far superior to fast Fourier transformation with respect to both accuracy and speed, and it can be adapted to the nonlinear case, where the power evolution depends not only on time but also on the temperature itself. The results are elucidated by application to a numerically challenging problem. Also multichip-modules under load cycle stress conditions are treated. The resulting temperature functions of the different layers of the set-up are a valuable basis for discussing reliability issues
  • Keywords
    circuit simulation; convolution; eigenvalues and eigenfunctions; equivalent circuits; finite element analysis; integral equations; interpolation; multichip modules; power semiconductor devices; semiconductor device models; temperature distribution; thermal management (packaging); thermal resistance; FEM models; arbitrary power pulses; arbitrary pulses; closed-form expressions; computation speed; convolution integral; differential operator; dissipated power; eigenfunctions; eigenvalues; electronic set-up; equivalent thermal circuit; fast accurate algorithm; heat conduction equation; hot spot temperatures; interpolation; junction to ambient; junction to case; load cycle stress conditions; multichip-modules; nonlinear case; power evolution; power semiconductor devices; quantum mechanical analog; reliability issues; simple power waveforms; simulation; temperature distribution; temperature evolution; thermal impedance; time domain; time-constant spectrum; Computational modeling; Convolution; Differential equations; Eigenvalues and eigenfunctions; Impedance; Integral equations; Power semiconductor devices; Power system modeling; Quantum mechanics; Temperature;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Semiconductor Thermal Measurement and Management Symposium, 2000. Sixteenth Annual IEEE
  • Conference_Location
    San Jose, CA
  • Print_ISBN
    0-7803-5916-X
  • Type

    conf

  • DOI
    10.1109/STHERM.2000.837061
  • Filename
    837061