Individual Data Processing Units (DPUs) are commonly used for operational control and specific data processing of scientific space instruments. To overcome the limitations of traditional rad-hard or fully commercial design approaches, a System-on-Chip (SoC) solution based on state-of-the-art FPGA is introduced. This design has been successfully demonstrated in space on Venus Express. From this, a reconfigurable DPU design for future advanced imaging sensors is derived using embedded processing cores. In addition, a SoC design variant is presented based on recently available FPGA technology with integrated hardwired processor, which is capable to support also high end payload applications.
The transport properties of various systems are studied here in the context of three different models. These are: (i) the disordered Hubbard model applicable to correlated binary alloys with a general disorder, (ii) the Anderson model used in describing the Kondo physics of a quantum dot connected to the external superconducting leads, and (iii) the Ranninger-Robaszkiewicz model applied to the study of optical properties of the system with preformed electron pairs above the temperature of transition to the superconducting state. We calculate the density of states, specific heat, the Wilson ratio and conductivity of the correlated binary alloy with off-diagonal disorder. We investigate the conditions under which the Kondo peak appears in the density of states and in the conductance of a dot coupled to the external superconducting leads. We analyze the effect of the pseudogap on the optical spectra in the high temperature superconductors described by the boson-fermion model.
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