Abstract: In some examples, linear and non-linear range-based plot pane selection may include receiving data that is to be displayed. Based on an increase or a decrease in a size of a range selector, a selection of a range of plot panes may be received from a plurality of available plot panes to display the data. Based on the received selection of the range of plot panes, a display of the data may be generated in plot panes included in the range of plot panes. The size of the range selector may be non-linearly proportional to the available plot panes to display the data.

Abstract: The disclosure relates to a method for avoiding contamination of a printing plate given surface-covering coating of a dust-forming recording medium (e.g. an uncoated paper) with a coating substance (e.g. a primer) in an inkjet printing operation. The method can include feeding the recording medium at a feed velocity that is greater than 20 meters per minute; continuously printing of the coating substance onto the recording medium by at least one print head including a plurality of print nozzles, the coating substance being printed at a constant, predetermined applied quantity per area. A nip between the print head and the recording medium is provided such that a fluid-dynamic eddy is created between the recording medium and the print head and/or the printing plate. The disclosure also related to a printing system that is configured to implement the method.

Abstract: In a method for preventing or reducing air vortex formation between a print plate and a recording medium upon printing to the recording medium with a coating substance (e.g. primer), the recording medium is provided at a feed velocity of at least 20 meters per minute, and a plurality of print nozzles of a print head are alternately activated to print the coating substance on recording medium to cover a surface of the recording medium with the coating substance. The activation can include only activating a portion of the plurality of print nozzles simultaneously. Further, a predetermined applied quantity of the coating substance per area is constantly printed onto the recording medium.

Abstract: The disclosure relates to a method for avoiding contamination of a printing plate given surface-covering coating of a dust-forming recording medium (e.g. an uncoated paper) with a coating substance (e.g. a primer) in an inkjet printing operation. The method can include feeding the recording medium at a feed velocity that is greater than 20 meters per minute; continuously printing of the coating substance onto the recording medium by at least one print head including a plurality of print nozzles, the coating substance being printed at a constant, predetermined applied quantity per area. A nip between the print head and the recording medium is provided such that a fluid-dynamic eddy is created between the recording medium and the print head and/or the printing plate. The disclosure also related to a printing system that is configured to implement the method.

Abstract: In a method for preventing or reducing air vortex formation between a print plate and a recording medium upon printing to the recording medium with a coating substance (e.g. primer), the recording medium is provided at a feed velocity of at least 20 meters per minute, and a plurality of print nozzles of a print head are alternately activated to print the coating substance on recording medium to cover a surface of the recording medium with the coating substance. The activation can include only activating a portion of the plurality of print nozzles simultaneously. Further, a predetermined applied quantity of the coating substance per area is constantly printed onto the recording medium.

Abstract: A device for analyzing measurement data having a plurality of data sets, each data set being assigned to a respective one of a plurality of measurements, each data set having multiple features being indicative of different fractions of a fluidic sample, the device comprising a cluster determining unit configured for determining feature clusters by clustering features from different data sets presumably relating to the same fraction, a spread determining unit configured for determining for at least a part of the feature clusters a spread of the features within a respective feature cluster, and a display unit configured for displaying at least the part of the feature clusters together with a graphical indication of the corresponding spread.

Abstract: A device (100) for analyzing measurement data having a plurality of data sets (206), each data set (206) being assigned to a respective one of a plurality of measurements, each data set (206) having multiple features (208) being indicative of different fractions of a fluidic sample, the device (100) comprising a cluster determining unit (108) configured for determining feature clusters (350) by clustering features (208) from different data sets (206) presumably relating to the same fraction, a spread determining unit (110) configured for determining for at least a part of the feature clusters (350) a spread (352) of the features (208) within a respective feature cluster (350), and a display unit (112) configured for displaying at least the part of the feature clusters (350) together with a graphical indication of the corresponding spread (352).

Abstract: Determining a property of a measured peak pattern having at least one peak includes extracting measured peak parameters from the measured peak pattern, and determining deviations of the measured peak parameters from reference values of a reference peak pattern. The reference peak pattern is represented by a spring model, with peak parameters being represented by corresponding springs. Determining a property of a measured peak pattern also includes determining a deformation energy necessary for deforming the reference peak pattern in a way that the deformed reference peak pattern substantially represents the measured peak pattern.

Abstract: A method for calibrating a sample peak pattern comprises aligning at least one second reference peak of the first calibration peak pattern with at least one corresponding second reference peak of the second calibration peak pattern, and performing an interpolation of the respective positions of the first reference peak in the first and the second calibration peak pattern, in order to derive a time dependence of the first reference peak's position. The method further comprises aligning the sample peak pattern relative to at least one of the calibration peak patterns in a way that the sample peak pattern's first reference peak is aligned with an interpolated position of the first reference peak according to the time dependence, and that at least one of the sample peak pattern's second reference peaks is aligned with at least one corresponding second reference peak of one of the calibration peak patterns.

Abstract: Determining a property of a measured peak pattern comprising at least one peak is described. The method comprises extracting measured peak parameters from the measured peak pattern, and of determining deviations of the measured peak parameters from reference values of a reference peak pattern. Said reference peak pattern is represented by a spring model, with peak parameters being represented by corresponding springs. The method further comprises determining a deformation energy necessary for deforming the reference peak pattern in a way that the deformed reference peak pattern substantially represents the measured peak pattern.