| dc.description |
In an earlier Internal Technical Memorandum (1)
and in subsequent
work(2), it has been demonstrated that a particular kind of resistance
network, in which non-linear elements are associated with each mesh
point, can be made to represent an exact analogue to a non-degenerate
semiconductor system in the equilibrium or quasi-equilibrium state.
The term !exact' in this context implies that the difference equation
which governs the potential distribution in the network becomes identical,
for the limit of vanishing mesh interval, with the differential equation
for the electrostatic potential within the semiconductor system, i.e.
the Shockley-Poisson equation. From this type of analogue network
information concerning the variation of maximum field intensity and of
junction capacitance with applied bias voltages can be obtained for one,
two and three dimensional configurations of p and n type regions of
arbitrary geometry and impurity concentration profiles.
One limitation to the applicability of the analogue technique arises
from the restriction to quasi-equilibrium conditions. This restriction
precludes the investigation of situations in which current flow contributions
to the carrier concentration pattern become significant - for example, in
the case of strongly forward biassed p-n junctions, and of p-i-n junctions
and transistors operating at high injection levels. In the present paper,
the problems involved in an extension of the basic analogue method to the
treatment of non-equilibrium situations are examined, and means for their
solution are discussed. A review of the methods previously described
and an illustration of the nature of their limitations is given in Section
2. This is followed, in Sections 3 to 7, by a detailed treatment of
the case of a current carrying semiconductor system in one dimension
which leads to a theoretically possible realization in terms of resistancenetwork/
analogue computer techniques, which is, however, too complex to. be
considered practical. Section 8 discusses means for the simplification of
the proposed schemes and leads to the description of a relatively simple
system in which a significant reduction in equipment complexity has been
made possible by the adoption of an operating mode based upon an iterative
process of successive approximations. The extension of the technique
to three dimensions is outlined in Section 9. |
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