Abstract: A system, method, and computer-program product includes displaying a plurality of factor-setting user interface (UI) control elements configured to receive an input of characters for specifying a set of design of experiment factors for creating a design of experiment (DOE), displaying a plurality of factor type UI control elements configured to receive input for specifying a factor type of a plurality of factor types, displaying a plurality of dynamic rows of editable UI control elements configured to receive inputs of experimental values for the set of DOE factors, and displaying a composite factor UI control component configured to receive inputs for generating one or more control signals that add or remove one or more DOE factors of the set of DOE factors.

Abstract: The present disclosure provides an endoscopic apparatus and associated methods. The apparatus may include a steerable tool having a first flexible tube concentrically nested within a second flexible tube. The apparatus may include an end cap disposed on the steerable tool, an image sensor disposed on the end cap, and one or more light sources disposed on the end cap. The apparatus may be configured for accessing a region within a middle ear cavity of a patient. As such, the apparatus may further include a flexible tube, through which the steerable tool may extend, as well as a pre-curved rigid tube, through which the flexible tube may extend, thus allowing the apparatus to be deployed for middle ear access.

Abstract: A system, method, and computer-program product includes displaying a plurality of factor-setting user interface (UI) control elements configured to receive an input of characters for specifying a set of design of experiment factors for creating a design of experiment (DOE), displaying a plurality of factor type UI control elements configured to receive input for specifying a factor type of a plurality of factor types, displaying a plurality of dynamic rows of editable UI control elements configured to receive inputs of experimental values for the set of DOE factors, and displaying a composite factor UI control component configured to receive inputs for generating one or more control signals that add or remove one or more DOE factors of the set of DOE factors.

Abstract: The present disclosure provides a CAN network topology for an HVAC communication system. The CAN network topology comprises at least three primary nodes having a predetermined termination impedance and a plurality of end nodes coupled to each primary node, wherein the predetermined termination impedance is set to the optimal setting of 180 ohms. Advantageously, the present disclosure eliminates the need for physically setting CAN node terminations. This reduces install time and removes variability of the install settings. Further, removing this variability reduces the risk for post-installation call-backs due to incorrect system setup. The present disclosure optimizes signal slew rate, which improves signal reliability.

Abstract: Methods and the like according to the disclosure can include receiving a connection request from a portable device (where the connection request comprises at least one of a predefined code or encryption token), determining a first value of at least one parameter of a first wireless signal of a first signal pathway (where the first signal pathway is between the portable device and a first component of the HVAC system), determining a second value of the at least one parameter of a second wireless signal of a second signal pathway (where the second signal pathway is between the portable device and a second component of the HVAC system), authenticating the portable device, wherein the authenticating is based, at least in part, on the connection request, the first value, and the second value, and, in response to the portable device being authenticated, granting access to the HVAC system.

Abstract: Methods and related systems for operating a climate control system for an indoor space are disclosed. In an embodiment, the method includes establishing a connection between a device and a hub of the climate control system along a first signal pathway, wherein at least a portion of the first signal pathway comprises a short-range radio connection between the device and a first component of the system. In addition, the method includes monitoring one or more parameters of the first signal pathway and one or more parameters of a second signal pathway extending between the device and the hub, wherein at least a portion of the second signal pathway comprises a short-range radio connection between the device and a second component of the system. Further, the method includes re-routing the connection between the portable device and the system hub from the first signal pathway to the second signal pathway.

Abstract: Methods and related systems for operating a climate control system for an indoor space are disclosed. In an embodiment, the method includes establishing a connection between a device and a hub of the climate control system along a first signal pathway, wherein at least a portion of the first signal pathway comprises a short-range radio connection between the device and a first component of the system. In addition, the method includes monitoring one or more parameters of the first signal pathway and one or more parameters of a second signal pathway extending between the device and the hub, wherein at least a portion of the second signal pathway comprises a short-range radio connection between the device and a second component of the system. Further, the method includes re-routing the connection between the portable device and the system hub from the first signal pathway to the second signal pathway.

Abstract: Methods and related systems for operating a climate control system for an indoor space are disclosed. In an embodiment, the method includes establishing a connection between a device and a hub of the climate control system along a first signal pathway, wherein at least a portion of the first signal pathway comprises a short-range radio connection between the device and a first component of the system. In addition, the method includes monitoring one or more parameters of the first signal pathway and one or more parameters of a second signal pathway extending between the device and the hub, wherein at least a portion of the second signal pathway comprises a short-range radio connection between the device and a second component of the system. Further, the method includes re-routing the connection between the portable device and the system hub from the first signal pathway to the second signal pathway.

Abstract: The present disclosure provides a CAN network topology for an HVAC communication system. The CAN network topology comprises at least three primary nodes having a predetermined termination impedance and a plurality of end nodes coupled to each primary node, wherein the predetermined termination impedance is set to the optimal setting of 180 ohms. Advantageously, the present disclosure eliminates the need for physically setting CAN node terminations. This reduces install time and removes variability of the install settings. Further, removing this variability reduces the risk for post-installation call-backs due to incorrect system setup. The present disclosure optimizes signal slew rate, which improves signal reliability.

Abstract: The present disclosure provides a CAN network topology for an HVAC communication system. The CAN network topology comprises at least three primary nodes having a predetermined termination impedance and a plurality of end nodes coupled to each primary node, wherein the predetermined termination impedance is set to the optimal setting of 180 ohms. Advantageously, the present disclosure eliminates the need for physically setting CAN node terminations. This reduces install time and removes variability of the install settings. Further, removing this variability reduces the risk for post-installation call-backs due to incorrect system setup. The present disclosure optimizes signal slew rate, which improves signal reliability.

Abstract: The present disclosure provides a CAN network topology for an HVAC communication system. The CAN network topology comprises at least three primary nodes having a predetermined termination impedance and a plurality of end nodes coupled to each primary node, wherein the predetermined termination impedance is set to the optimal setting of 180 ohms. Advantageously, the present disclosure eliminates the need for physically setting CAN node terminations. This reduces install time and removes variability of the install settings. Further, removing this variability reduces the risk for post-installation call-backs due to incorrect system setup. The present disclosure optimizes signal slew rate, which improves signal reliability.

Abstract: A method and composition for tRNA synthetases that activate and aminoacylate nonstandard and noncognate amino acids to tRNA adaptor molecules is described that can be used to generate custom designed protein products for uses in medicinal, therapeutic, diagnostic, biotechnology, engineering, and spectroscopy applications. Some tRNA synthetases naturally misactivate and misaminoacylate noncognate amino acids. Many of these tRNA synthetases, including but not limited to leucyl-, isoleucyl-, and valyl-tRNA synthetases, have evolved proofreading and editing mechanisms to correct these mistakes. Inactivation of the enzyme's editing activity allows and facilitates production and accumulation of tRNAs that are misaminoacylated with nonstandard and noncognate amino acids. These misaminoacylated tRNAs can be used to introduce novel amino acids into proteins.