Abstract: The present subject matter relates to printhead-integrated ink level sensor (PILS) system. In an example implementation, the PILS system includes a sense capacitor plate in a fluid sensing chamber to sense a level of fluid in the fluid sensing chamber. The fluid sensing chamber is in fluid communication with a fluid reservoir of the printhead to receive fluid from the fluid reservoir. The sense capacitor plate includes at least one slot. The PILS system further includes at least one central clearing resistor and at least one peripheral clearing resistor to clear the fluid sensing chamber of the fluid. The central clearing resistor is provided in the at least one slot of the sense capacitor plate. The at least one peripheral resistor is provided in the fluid sensing chamber surrounding the sense capacitor plate.

Abstract: Examples include a plastic-based support substrate and at least one fluid ejection die coupled thereto. The at least one fluid ejection die comprises a nozzles for dispensing printing material. The plastic-based support substrate has a fluid communication channel formed therethrough, where the fluid communication channel is in fluid communication with the nozzles of the at least one fluid ejection die.

Abstract: Examples herein provide a device. The device includes a sample delivery component, which includes: a reagent chamber to contain at least one reagent; a sample chamber to contain a fluid sample; and a delivery channel extending from the reagent chamber and in fluid communication with the sample chamber and an output port, wherein the delivery channel is conducive to mixing the at least one reagent and the fluid sample to form a mixture before the mixture reaches the output port and be discharged therefrom. The device includes a testing cassette detachable from the delivery component, which includes: an input port in fluid communication with a microfluidic reservoir, the input port to receive the discharged fluid sample from the output port; and a micro-fabricated integrated sensor in a microfluidic channel extending from the microfluidic reservoir.

Abstract: A coated print medium can include a base stock having a basis weight of 35 gsm to 250 gsm, and a coating layer applied to the base stock at from 1 gsm to 50 gsm by dry weight. The base stock can include from 65 wt % to 95 wt % cellulose fiber with 20 wt % to 100 wt % being mechanical pulp, and from 5 wt % to 35 wt % inorganic pigment filler. The coating layer can include inorganic pigment particles having an average equivalent spherical diameter from 0.2 ?m to 3.5 ?m; a fixative agent including metal salt, cationic amine polymer, quaternary ammonium salt, quaternary phosphonium salt, or mixture thereof; and a polymer blend including water soluble polymer and water dispersible polymer having a Zeta potential greater than ?40 mV, wherein a weight ratio water soluble polymer to water dispersible polymer is from 1:25 to 1:1.

Abstract: A three-dimensional (3D) printing method includes applying a build material composition having a polymer particle and a radiation absorbing additive mixed with the polymer particle, the radiation absorbing additive being selected from the group consisting of inorganic near-infrared absorbers, organic near-infrared absorbers, and combinations thereof. The build material composition is preheated to a temperature below the melting temperature of the polymer particle by exposing the build material composition to radiation, the radiation absorbing additive increasing radiation absorption and accelerating the pre-heating of the build material composition. A fusing agent is selectively applied on at least a portion of the build material composition. The method further includes exposing the build material composition to radiation, whereby at least the polymer particle in the at least the portion of the build material composition in contact with the fusing agent at least partially fuses.

Abstract: A photosensitive material set can include a build material with polymeric particles having art average the from 10 ?m to 100 ?m and an average aspect ratio of less than 2:1, an inkjettable fluid suitable for application to the polymeric particles for 3D printing, and a photosensitive dopant. The photosensitive dopant can be blended with the polymeric particles, included in the inkjettable fluid, or both. The photosensitive dopant can have a first electrical property in a first chemical configuration and a second electrical property when modified to a second chemical configuration by exposure to photo electromagnetic radiation that is suitable to convert the photosensitive dopant from the first chemical configuration to the second chemical configuration.

Abstract: In one example in accordance with the present disclosure a method of is described. According to the method, usage data for an electronic device is obtained. An activity phase from a plurality of activity phases for the electronic device is selected based on the usage data. An activity phase has a corresponding timeout period and is defined by an inter-arrival threshold. The electronic device is instructed to enter a low power mode after being inactive for a time period at least as great as the timeout period corresponding to a selected activity phase.

Abstract: An e-paper imaging system includes a writing unit and a support surface to support a passive e-paper media in a position spaced apart from the writing unit. The writing unit includes a charge generator and an electrode array. The electrode array includes addressable holes to control charges flowing to the support surface.

Abstract: Examples relate to providing spatial analysis using attribute graphs. In one examples, there are a number of spatial points that each represent characteristics in a dimensional space. Non-data points are generated in the dimensional space, and a Delaunay triangulation is performed using the spatial points and the non-data points to generate a plurality of edges, where interior points of the plurality of non-data points that are in an interior space of the plurality of spatial points are excluded from the Delaunay triangulation. Next, spatial edges from the plurality of edges that each connect a spatial point that is connected to a first mixed edge to another spatial point that is connected to a second mixed edge are identified, where the spatial edges are used to generate a robust contour of a cluster of the spatial points.

Abstract: A printing device that may include a first print engine, a second print engine, and a web buffer device disposed between the first and second print engines to maintain an amount of web substrate therein, wherein the web buffer includes a first and second movable carriage, with at least one rotatable roller coupled to each of the two carriages and wherein the first and second movable carriages move synchronously away and toward each other to alter an amount of web present in the web buffer.

Abstract: Example implementations relate to multiple payload pantograph. Some examples may include a first pattern generation engine to generate a first pattern. The first pattern may be a data-bearing pattern encoding a first payload. Additionally, some examples may include a second pattern generation engine to generate a second pattern, the second pattern (by itself or in combination with the first pattern) may represent a second payload. The second payload may be camouflaged by a combination of the first pattern and the second pattern. Some examples may also include a pantograph generation engine to generate a multiple payload pantograph including the first pattern and the second pattern. The multiple payload pantograph may include the first pattern in one of the pantograph background or the pantograph foreground.

Abstract: A sample preparation system includes a sample input, a first chamber fluidly coupled to the sample input and containing a sample preparation reagent, a second chamber containing a surface enhanced Raman spectroscopy (SERS) sensor structure and a third chamber containing a sensor preparation solution. The sample input, the first chamber and the second chamber are fluidly coupled to one another in a series and the third chamber is fluidly coupled to the third chamber outside of the series so as to sequentially direct a sample received by the sample input through the first chamber to the second chamber and out of the second chamber and so as to direct the sensor preparation solution into the second chamber following discharge of the sample out of the second chamber.

Abstract: An apparatus includes a sample carrier having wells. Each of the wells has sides and a floor forming an interior. A surface enhanced Raman spectroscopy (SERS) structure is within the interior of each of the wells. A pneumatic port is connected to the interior of each of the wells. A pneumatic passage is connected to the pneumatic ports.

Abstract: An antenna and cap, in an example implementation, can include a system, comprising a computing device, a clearance region coupled to the computing device, and an antenna comprising a first antenna portion and a second antenna portion. The first antenna portion can be coupled to the computing device and to the clearance region, and the second antenna portion can be coupled to the clearance region. The system can include a first cap coupled to the second antenna portion via a first interconnection, and a second cap coupled to the second antenna portion via a second interconnection. The first cap and the second cap can be coupled to the computing device.

Abstract: In one example, a media guide for use in a printer having a print bar and a print zone adjacent to the print bar includes a movable blocker downstream from the print zone along a media path and movable though a range of motion to block print media from leaving the media path when exiting the print zone.

Abstract: Example implementations relate to obtaining information about and indicating a state of a storage device. In example implementations, an indication that a storage device is rebuilding address mappings may be received, and how much progress has been made in the rebuilding may be determined. A representation of the progress made in the rebuilding may be displayed.

Abstract: A media-sheet stacking system (10) for stacking media sheets on a device output tray (OT) comprises a kicker (25) to advance a media sheet along the output tray by pushing a trailing edge of the media sheet as it exits the device, and a movable element (32a) arranged to face the output tray across a space that receives media sheets exiting the device. A drive mechanism (33) is provided to drive the movable element in the direction of advance of the media sheet along the output tray.

Abstract: A pretreatment fluid for printing media with a pigment ink composition includes a liquid vehicle, at least one polymeric binder having pendant carboxyl groups, and an ammonium metal chelate cross-linker.

Abstract: Disclosed are techniques for video stream compression. A motion predicted frame and a current frame of video data are converted from a source color space to a perceptual color space. A delta (?) frame is calculated between the current frame and the motion predicted frame. Input color difference values between the current frame and the motion predicted frame are determined and mapped to a normalized output to create a tone mapped color difference image. The tone mapped color difference image and ? frame are multiplied to obtain a weighted ? frame. ? loss is calculated as the difference between the weighted ? frame and the ? frame. A variance map of the motion predicted frame is multiplied by the ? loss to obtain a ? preservation map. The weighted ? frame and ? preservation map are summed to obtain a modified ? frame which may be transformed, quantized and encoded.