Abstract: Techniques are described for improving dimensional accuracy, and more specifically z-axis or vertical dimensional accuracy in generating a 3 dimensional (3D) object comprising a plurality of formable layers. In one example, a height configuration parameter, such as a selected layer height, a print resolution, one or more tolerance values for certain layers or portions of a 3D object to be printed, etc., and a total object height, may be obtained. A first height corresponding to a subset of the plurality of formable layers may be selected based on the received height configuration parameter and the total object height. In some aspects, the first height may include a global layer height for the 3D object. The first height may be selected to optimize accuracy of the height configuration parameter or the total object height.

Abstract: Animal sustenance-dispensing stations described herein may be capable of supplying food or water to animals, of controlling electrical loads that prevent liquid sustenance freeze-up or overheating and other loads that help sanitize the sustenance, that illuminate the station, or that generate sounds; of acquiring and processing data from a variety of sensors both internal and external to the station, and of reporting both raw and processed data. They may also be capable of wirelessly communicating with other stations, or with non-station devices over wireless communication networks to facilitate reporting of sensor and other data, and to support configuration of station controller operational and reporting behavior. Station configurations may facilitate monitoring of video and audio activity of nearby animals, tagged animals visiting the station, weather conditions in the station's vicinity, station food or water supply levels, and other parameters according to the sensors of a given embodiment.

Abstract: Methods, systems, and devices are described herein for improving dimensional accuracy in generating a three dimensional (3D) object. In one aspect, first data may be received, for example from a first sensor, with the first data corresponding to at least a first dimension or measurement of a filament extrudable by a 3D printer. Similarly, second data may be received, for example from a second sensor, with the second data corresponding to at least a second dimension of the filament extrudable by the 3D printer. Based on the first and the second data, an amount of filament provided to a hotend of the 3D printer may be determined. During generation of the 3D object, a speed at which the filament is provided to the hotend may be adjusted based on the determined amount of filament provided to the hotend to more accurately generate the 3D object.

Abstract: Techniques are described for improving dimensional accuracy, and more specifically z-axis or vertical dimensional accuracy in generating a 3 dimensional (3D) object comprising a plurality of formable layers. In one example, a height configuration parameter, such as a selected layer height, a print resolution, one or more tolerance values for certain layers or portions of a 3D object to be printed, etc., and a total object height, may be obtained. A first height corresponding to a subset of the plurality of formable layers may be selected based on the received height configuration parameter and the total object height. In some aspects, the first height may include a global layer height for the 3D object. The first height may be selected to optimize accuracy of the height configuration parameter or the total object height.

Abstract: Animal sustenance-dispensing stations described herein may be capable of supplying food or water to animals, of controlling electrical loads that prevent liquid sustenance freeze-up or overheating and other loads that help sanitize the sustenance, that illuminate the station, or that generate sounds; of acquiring and processing data from a variety of sensors both internal and external to the station, and of reporting both raw and processed data. They may also be capable of wirelessly communicating with other stations, or with non-station devices over wireless communication networks to facilitate reporting of sensor and other data, and to support configuration of station controller operational and reporting behavior. Station configurations may facilitate monitoring of video and audio activity of nearby animals, tagged animals visiting the station, weather conditions in the station's vicinity, station food or water supply levels, and other parameters according to the sensors of a given embodiment.

Abstract: Powered flying animal sustenance-dispensing stations described herein may be capable of supplying food or water to flying animals, of controlling electrical loads that prevent liquid sustenance freeze-up or overheating and other loads that help sanitize the sustenance, that illuminate the station, or that generate sounds; of acquiring and processing data from a variety of sensors both internal and external to the station, and of reporting both raw and processed data. They may also be capable of wirelessly communicating with other stations, or with non-station devices over wireless communication networks to facilitate reporting of sensor and other data, and to support configuration of station controller operational and reporting behavior.