Medios, imágenes y memoria: el Valle de los Caídos

Since the first decade of the 21st century, the Valley of the Fallen has been established as an object of controversy related to the new policies of memory. In recent years the "Historical Memory" has been a recurring concept in the mass media. While it is true that since 2011 this issue has been overshadowed in the political agenda, even today we continue to access information that refers to our recent past, from perspectives that demand actions of ethic, symbolic, political or economic repair. Many of these reports could be framed within a broader discourse, akin to a concept of "historical memory". These media texts are part of a larger problem that is troubling modern western societies and that has presented a remarkable recovery since the late nineties: debates or polemics on memory. In this paper we propose to study the nature of these media texts. We assume that the mass media configure their texts from frameworks or pre-existing frames. For this research, we propose an analysis of content based on the theory of framing to identify what is the typical journalistic discourse and the modalities of interpretive general framework applied in a number of texts and broadcasts about the Valley of the Fallen...

Measurement limitations in knife-edge tomographic phase retrieval of focused IR laser beams

An experimental setup to measure the three-dimensional phase-intensity distribution of an infrared laser beam in the focal region has been presented. It is based on the knife-edge method to perform a tomographic reconstruction and on a transport of intensity equation-based numerical method to obtain the propagating wavefront. This experimental approach allows us to characterize a focalized laser beam when the use of image or interferometer arrangements is not possible. Thus, we have recovered intensity and phase of an aberrated beam dominated by astigmatism. The phase evolution is fully consistent with that of the beam intensity along the optical axis. Moreover, this method is based on an expansion on both the irradiance and the phase information in a series of Zernike polynomials. We have described guidelines to choose a proper set of these polynomials depending on the experimental conditions and showed that, by abiding these criteria, numerical errors can be reduced.