Abstract: Described herein are ECAM systems and methods of operating such systems or, more specifically, methods of determining the spacing between build plates and printheads before deposits contact the printheads. A method may comprise positioning a build plate and a printhead (e.g., comprising a copper deposit) at a set orientation relative to each other and for some time (e.g., to allow changes in the electrolyte between the build plate and the printhead and/or changes to the printhead's electrode surface). Thereafter, a measuring voltage is applied between each pixelated electrode of the printhead and a measuring reference plate (which may be the build plate or another plate) while obtaining one or more current values. These current values are then compared to the calibration data set to determine the distances between this electrode and the build plate or, more specifically, the deposit on the build plate.

Abstract: Described herein are electrochemical-additive manufacturing methods and systems using such methods. A method comprises depositing a material onto a deposition electrode by flowing a current between that deposition electrode and each of multiple individually-addressable electrodes, forming an electrode array. These currents are independently controlled based on a target map and using deposition control circuits, each coupled to one individually-addressable electrode. The target map is generated by a system controller based on various characteristics of the system (e.g., the performance of each deposition control circuit and/or individually-addressable electrode, electrolyte composition) and the desired characteristics of the deposited material (e.g., deposition location, uniformity, morphology). Furthermore, when the deposition electrode and the electrode array move relative to each other, the system controller dynamically updates the target map based on their relative positions.

Abstract: Described herein are electrochemical-additive manufacturing methods and systems using such methods. A method comprises depositing a material onto a deposition electrode by flowing a current between that deposition electrode and each of multiple individually-addressable electrodes, forming an electrode array. These currents are independently controlled based on a target map and using deposition control circuits, each coupled to one individually-addressable electrode. The target map is generated by a system controller based on various characteristics of the system (e.g., the performance of each deposition control circuit and/or individually-addressable electrode, electrolyte composition) and the desired characteristics of the deposited material (e.g., deposition location, uniformity, morphology). Furthermore, when the deposition electrode and the electrode array move relative to each other, the system controller dynamically updates the target map based on their relative positions.

Abstract: Described herein are electrochemical-additive manufacturing methods and systems using such methods. A method comprises depositing a material onto a deposition electrode by flowing a current between that deposition electrode and each of multiple individually-addressable electrodes, forming an electrode array. These currents are independently controlled based on a target map and using deposition control circuits, each coupled to one individually-addressable electrode. The target map is generated by a system controller based on various characteristics of the system (e.g., the performance of each deposition control circuit and/or individually-addressable electrode, electrolyte composition) and the desired characteristics of the deposited material (e.g., deposition location, uniformity, morphology). Furthermore, when the deposition electrode and the electrode array move relative to each other, the system controller dynamically updates the target map based on their relative positions.

Abstract: Described herein are electrochemical-additive manufacturing methods and systems using such methods. A method comprises depositing a material onto a deposition electrode by flowing a current between that deposition electrode and each of multiple individually-addressable electrodes, forming an electrode array. These currents are independently controlled based on a target map and using deposition control circuits, each coupled to one individually-addressable electrode. The target map is generated by a system controller based on various characteristics of the system (e.g., the performance of each deposition control circuit and/or individually-addressable electrode, electrolyte composition) and the desired characteristics of the deposited material (e.g., deposition location, uniformity, morphology). Furthermore, when the deposition electrode and the electrode array move relative to each other, the system controller dynamically updates the target map based on their relative positions.

Abstract: Described herein are electrochemical-additive manufacturing methods and systems using such methods. A method comprises depositing a material onto a deposition electrode by flowing a current between that deposition electrode and each of multiple individually-addressable electrodes, forming an electrode array. These currents are independently controlled based on a target map and using deposition control circuits, each coupled to one individually-addressable electrode. The target map is generated by a system controller based on various characteristics of the system (e.g., the performance of each deposition control circuit and/or individually-addressable electrode, electrolyte composition) and the desired characteristics of the deposited material (e.g., deposition location, uniformity, morphology). Furthermore, when the deposition electrode and the electrode array move relative to each other, the system controller dynamically updates the target map based on their relative positions.

Abstract: Described herein are electrochemical-additive manufacturing methods and systems using such methods. A method comprises depositing a material onto a deposition electrode by flowing a current between that deposition electrode and each of multiple individually-addressable electrodes, forming an electrode array. These currents are independently controlled based on a target map and using deposition control circuits, each coupled to one individually-addressable electrode. The target map is generated by a system controller based on various characteristics of the system (e.g., the performance of each deposition control circuit and/or individually-addressable electrode, electrolyte composition) and the desired characteristics of the deposited material (e.g., deposition location, uniformity, morphology). Furthermore, when the deposition electrode and the electrode array move relative to each other, the system controller dynamically updates the target map based on their relative positions.

Abstract: A device (10) and method for clamping or otherwise securing an esophagus between the crop and certain internal organs, including the viscera, and substantially simultaneously cutting or otherwise separating, or weakening for subsequent predictable separation, the esophagus at or near the clamped location, thereby avoiding pulling apart the crop and the resulting contamination of the carcass.

Abstract: A device (10) and method for clamping or otherwise securing an esophagus between the crop and certain internal organs, including the viscera, and substantially simultaneously cutting or otherwise separating, or weakening for subsequent predictable separation, the esophagus at or near the clamped location, thereby avoiding pulling apart the crop and the resulting contamination of the carcass.

Abstract: A shackle for retaining and associating a carcass, such as, for example, a poultry carcass, with a conveyor system for transporting the carcass along a processing line. The shackle includes a disengagement, or breakaway, feature in which at least a portion of the shackle carrying the carcass automatically disengages from the conveyor system under a pre-established condition involving an increase in downward force, such as, for example, when the shackle becomes caught or otherwise impeded. The disengagement is accomplished by the opening, or separation, of bendable arms in response to the downward force created by the caught or impeded shackle, which creates or widens a gap between the arms that, in turn, causes the at least a portion of the shackle to be released. Once the shackle is disengaged, the conveyor can resume normal travel along the processing line, and processing operations can continue.

Abstract: A system for enhancing data access over a communications link is disclosed. In accordance with a particular embodiment, a system for retrieving an object over a computer network includes a network client with a browser for rendering an object to a user and a user interface enabling the user to establish an encoding preference. A remote scaling server is coupled between the network client and the computer network, and includes a remote proxy and an encode service provider. The remote scaling server is configured to request a user-specified encoding preference from the network client, retrieve an object from the computer network using the remote proxy, encode the object using the encode service provider in accordance with the requested user-specified encoding preference, and transmit the encoded object to the network client using the remote proxy. The disclosed system thus enables users to dynamically influence the trade-off between quality of content and download speed.

Abstract: A communications system having a first server and a first client connected to the first server through a first network, wherein the first server selectively sends a set of InfoBites to the first client based on a filter. A method for distributing information for the above communications system, including the steps of deriving a set of InfoBites, filtering the set of InfoBites based on the filter into a filtered set of InfoBites, and, transmitting the filtered set of InfoBites to the first client.