SASER is a device consisting of a double barrier heterostructure (DBH) tailored in such a way that the energy difference between the two lowest electronic resonant levels in the well is close to the LO-phonon energy. This LO-phonon decays in a pair of phonons producing an intense coherent beam of short wavelength TA phonons (a SASER beam). In previous works we studied an elementary model [1, 2], its dynamics [3] and the polaronic effects on its static properties [4]. In this paper the system is described by a tight-binding Hamiltonian for the electrons, a single confined mode for the LO-phonon and the electron–phonon interaction. This interaction produces, near the condition for phonon emission, a pair of polaronic states through which the electron can tunnel. We have obtained for this model an analytical solution applied to the study of the dynamical properties. In a small region of the applied bias, depending on the relevant parameters of the system, an instability appears. By an adequate adjustment of these parameters it is possible to control the extension and characteristics of the instability region. The temporal behavior of the solutions is characterized applying the usual criteria for dynamical systems.