The SuperCam instrument was selected by NASA in July 2014 and has been implemented on the Mars 2020 Perseverance rover. This instrumental suite gathers four different remote-sensing techniques including a very compact Infrared Spectrometer (IRS). For several reasons of costs and planning and after a risk mitigation phase, the use of full commercial-off-the-shelf photodiodes from TELEDYNE JUDSON J19 Series as detector for the IRS was decided. This paper describes the procurement, evaluation, and qualification philosophy of these photodiodes, providing information on the subsystems of the SuperCam instrument and the description of these photodiodes. Critical and fragile parts of the photodiode as the thermo electric cooler, have been particularly studied. In conclusion, the component was space qualified using the original use of the particle impact noise detection test applied for a mechanical screening purpose, with correlation between performance and fine leak, screening and the lot acceptance test processes.

Electron Beam Induced Current is a powerful tool for Scanning Electron Microscopy (SEM) imaging mode. In this paper, the history and evolution of this technique are discussed. Some important defects are presented as well as their technological interpretation. A new custom amplifier is presented and its implementation in Time Resolved EBIC (TREBIC) is also proposed, the main differences with EBIC are pointed out.

It is necessary for space applications to evaluate the sensitivity of electronic devices to radiations. It was demonstrated that radiations can cause different types of effects to the devices and possibly damage them [1][2]. The interest in the effect of Single Event Transient (SET) has recently risen because of the increased ability of parasitic signals to propagate through advanced circuit with gate lengths shorter than 0.65 nm and to reach memory elements (in this case they become Single Event Upset (SEUs)). Analog devices are especially susceptible to perturbations by such events which can induce severe consequences, from simple artifacts up to the permanent fail of the device. This kinds of phenomena are very difficult to detect and to acquire, because they are not periodical. Furthermore, they can vary a lot depending on different parameters such as device technology and biasing. The main obstacle for the analysis is due to the maximum frequency of these signals, which is unknown. It is consequently difficult to set a correct sample frequency for the acquisition system. In this document a methodology to evaluate SETs in analog devices is presented. This method allows to acquire automatically these events and to easily study the sensitivity of the device by analyzing a “SETs cartography”. The advantages are different: it allows to easily acquire and analyze the SETs in an automatic way; the obtained results allow the user to accurately characterize the device under test; and, finally, the costs due to the implementation of the tests are lower than a classical analysis performed by a particle accelerator.

VLSI internal testing through silicon substrate has been widely studied and techniques like Time Resolved Emission has given impressive results. Nevertheless, Integrated Circuits (IC) are still evolving with more and more complex functions and various kinds of signals that could be split into two main categories: data and control. Controls activate specific block and according to the wide range of different blocks and device complexity, the first analysis task is to check block activity related to control line status. In this paper, we show how Time Resolved Imaging can precisely answer this challenge even in up-to-date technologies at low power supply.