Abstract: A wheel fastener alarm assembly is provided having a fastener body with a first portion defining a wrenching surface and a cavity, and a second portion with a threaded portion to attach and detach from a wheel of a vehicle. A sensor array is disposed in the cavity of fastener body to detect an attribute of the fastener body and generate an output signal based on the attribute of the fastener body. An antenna connected to the sensor array to transmit the signal to a remote location. A cap is secured to the first portion of the fastener body and covers the wrenching surface and the cavity opening to define a capped fastener body.

Abstract: An apparatus for scanning and decoding barcodes includes an imager, a sample imaging area, and a processor. The imager is configured to capture images within a selectable field of view. The sample imaging area is configured to support a plurality of sample/tissue containers. Each sample/tissue container of the plurality of sample/tissue containers comprises a respective barcode. At least a portion of the plurality of sample/tissue containers are positioned within the field of view, such that a plurality of the respective barcodes is within the field of view. The processor is configured to receive captured images from the imager. The processor is configured to detect and decode each of the plurality of respective barcodes present in a first image of the captured images. The processor is also configured to define an associated region of interest for each barcode present in the first image.

Abstract: This application relates to a building energy analysis and management system for measurement and verification of building performance. The system can analyze, optimize, manage, maintain, trouble shoot, and/or modify building systems, such as HVAC systems, in connection with the building energy usage. Measurements may be gathered for one or more HVAC units coupled to pressure independent valves, and sent to one or more Surge Panels that pass data to remote analysis servers, which can receive other system or external data. The analysis servers compare measurements to predicted values and can standardize the predicted values to account for external conditions. The comparison can result in difference values used to generate probable causes and optimization recommendations. The system outputs reports or other data display using a graphical user interface that can be adjusted for an anticipated user.

Abstract: A speaker can have a main body with a generally spheroidal shape, which can be supported standing on its end. The speaker can include a subwoofer that faces forward. A plurality of mid-range drivers can be distributed around the sub-woofer, facing generally forward and radially outward. A plurality of tweeters can be distributed around the sub-woofer, facing generally forward and generally outward. The outer housing portion of the speaker can be covered with a fabric material. A user interface ring 162 can be touch sensitive to receive input, and can have a plurality of lights that can be illuminated separately to convey information to the user.

Abstract: Provided are wellbore treatment fluids and methods to introduce these treatment fluids in a subterranean formation. The treatment fluids include a diverter material and an aqueous carrier fluid. Further, the diverter material comprises a composite material of a polyvinyl alcohol and a plasticizer. The diverter material includes particles having a particle size distribution of about 2 to about 10 U.S. mesh and an aspect ratio of 20:1 or less. The treatment fluid is introduced into a permeable zone of a subterranean formation, wherein the permeable zone is part of a wellbore that is permeated or penetrated by fractures and fissures. The diverter material diverts at least partially the treatment fluid to a different portion of the subterranean formation.

Abstract: Implantable devices formed of materials which are not readily imageable, and which may shift from a delivery configuration to a deployment configuration upon deployment, are delivered and deployed with a deployment/delivery device having sensors generating a signal indicating contact of the delivery/deployment device with tissue to guarantee purchase of the implantable device with tissue upon deployment. The implantable device may be a tissue anchor with talons which shift from a delivery configuration to a deployed configuration. The sensors may be positioned along a distal end of the delivery/deployment device to indicate purchase of the device with tissue, to ensure purchase of the talons with tissue upon deployment. The sensors may include at least three sensors, which may be spaced apart from one another, to indicate full contact of the distal end of the delivery/deployment device with tissue. The sensors may optionally be aligned with the talons.

Abstract: Embodiments herein relate to implantable medical devices including a power subunit with a first biocompatible electrically conductive shell configured for direct contact with an in vivo environment. In some embodiments a lithium anode can be disposed within the first biocompatible electrically conductive shell in direct electrical communication with a feedthrough pin, wherein the feedthrough pin is electrically isolated from the first biocompatible electrically conductive shell. A cathode can also be disposed within the first biocompatible electrically conductive shell and can be in direct electrical communication with the first biocompatible electrically conductive shell. The first biocompatible electrically conductive shell has a positive electrical potential. The implantable medical device further includes an electronics control subunit with a control circuit disposed within a second biocompatible electrically conductive shell. Other embodiments are included herein.

Abstract: A fixation device for engaging heart valve leaflets includes a center member with a first end, an opposite second end, and a length extending therebetween, first and second arms each having a first free end and an opposite second end, the second end of each arm extending from the second end of the center member, the first and second arms biased in a first position adjacent the center member and moveable to a second position spaced apart from the center member, and an actuator configured to move the first and second arms from the first position to the second position.

Abstract: Embodiments herein relate to implantable medical devices including a power subunit with a first biocompatible electrically conductive shell configured for direct contact with an in vivo environment. In some embodiments a lithium anode can be disposed within the first biocompatible electrically conductive shell in direct electrical communication with a feedthrough pin, wherein the feedthrough pin is electrically isolated from the first biocompatible electrically conductive shell. A cathode can also be disposed within the first biocompatible electrically conductive shell and can be in direct electrical communication with the first biocompatible electrically conductive shell. The first biocompatible electrically conductive shell has a positive electrical potential. The implantable medical device further includes an electronics control subunit with a control circuit disposed within a second biocompatible electrically conductive shell. Other embodiments are included herein.

Abstract: Embodiments herein relate to implantable medical devices including a welded joint with reduced residual stress. In a first aspect, an implantable medical device is included having a power subunit comprising a first biocompatible electrically conductive shell, an anode disposed therein, a cathode disposed therein, and a lid. The implantable medical device can further include an electronics control subunit comprising a second biocompatible electrically conductive shell, and a control circuit disposed therein. Both of the first and second biocompatible electrically conductive shells can include first and second opposed wide sides, first and second opposed narrow sides, and four rounded corners. The first shell can be welded to the lid around a perimeter thereof forming a weld line. The weld line can have a weld line terminus and the weld line terminus can be positioned on a narrow side or a rounded corner. Other embodiments are also included herein.

Abstract: A dual media spray nozzle assembly for cleaning an optical viewer or sensor lens is disclosed. The assembly includes two media pathways that terminate in two arrays at the target cleaning area. The nozzle arrays are coplanar. The two media may be activated sequentially or simultaneously. The assembly includes a cover, a spray element, and a media inlet body. The nozzles are formed in a curved, semi-annular opening of the spray element. The spray element includes front and back sides. Formed on the front side is a first media flow path associated with a first media inlet formed on the media inlet body. The first media flow path is associated with the first array of nozzles. Formed on the back side is a second media flow path associated with second media inlets formed on the media inlet body. The second media path is associated with the second array of nozzles.

Abstract: An apparatus and method are provided for imaging and analyzing images of tissue samples. The apparatus includes an imager, a lighting system, and a processor. The imager is configured to capture images within a selectable field of view. A tissue sample container is positionable within the field of view. The imager is configured to capture images of a plurality of tissue sample containers. The lighting system is configured to illuminate the field of view. The processor is configured to receive a first plurality of captured images of tissue sample containers. The processor is configured to analyze the first plurality of captured images and to determine whether there is tissue missing from any ones of the first plurality of captured images.

Abstract: An apparatus for scanning and decoding barcodes includes an imager, a sample imaging area, and a processor. The imager is configured to capture images within a selectable field of view. The sample imaging area is configured to support a plurality of sample/tissue containers. Each sample/tissue container of the plurality of sample/tissue containers comprises a respective barcode. At least a portion of the plurality of sample/tissue containers are positioned within the field of view, such that a plurality of the respective barcodes is within the field of view. The processor is configured to receive captured images from the imager. The processor is configured to detect and decode each of the plurality of respective barcodes present in a first image of the captured images. The processor is also configured to define an associated region of interest for each barcode present in the first image.

Abstract: An apparatus is provided for scanning and decoding barcodes in a tray or other container containing multiple items, such as tissue samples, that are identified with discrete barcodes. The apparatus includes an imager, a lighting system, and a processor. The imager is configured to capture images within a selectable field of view. At least a portion of a bulk sample container, which is configured to carry a plurality of sample/tissue containers, is positioned within the field of view. The lighting system is configured to evenly light the field of view. The processor is configured to receive the captured images from the imager. The processor is further configured to analyze a first image of the captured images and to detect and decode the barcodes present in the first image.

Abstract: The disclosed inventive concept provides a fluid accessory for facilitating the dispensing of fluid onto a vehicle's windshield, cameras, sensors, or the like. The fluid accessory includes a body having an inlet portion and an outlet portion in which an inlet adapter and an outlet adapter, respectively, are fitted. The fluid accessory also includes a sleeve which is fitted within the body and around the inlet adapter. The body includes a plurality of longitudinal protrusions extending radially into the body. The sleeve and longitudinal projections cooperate to define a plurality of debris collection channels for collecting debris flowing within the fluid and through the fluid accessory. The fluid accessory also includes a filter media, such as a filter media, which is positioned between the outlet adapter and the body.

Abstract: Embodiments herein relate to implantable medical devices including a welded joint with reduced residual stress. In a first aspect, an implantable medical device is included having a power subunit comprising a first biocompatible electrically conductive shell, an anode disposed therein, a cathode disposed therein, and a lid. The implantable medical device can further include an electronics control subunit comprising a second biocompatible electrically conductive shell, and a control circuit disposed therein. Both of the first and second biocompatible electrically conductive shells can include first and second opposed wide sides, first and second opposed narrow sides, and four rounded corners. The first shell can be welded to the lid around a perimeter thereof forming a weld line. The weld line can have a weld line terminus and the weld line terminus can be positioned on a narrow side or a rounded corner. Other embodiments are also included herein.

Abstract: Embodiments herein relate to implantable medical devices including a power subunit with a first biocompatible electrically conductive shell configured for direct contact with an in vivo environment. In some embodiments a lithium anode can be disposed within the first biocompatible electrically conductive shell in direct electrical communication with a feedthrough pin, wherein the feedthrough pin is electrically isolated from the first biocompatible electrically conductive shell. A cathode can also be disposed within the first biocompatible electrically conductive shell and can be in direct electrical communication with the first biocompatible electrically conductive shell. The first biocompatible electrically conductive shell has a positive electrical potential. The implantable medical device further includes an electronics control subunit with a control circuit disposed within a second biocompatible electrically conductive shell. Other embodiments are included herein.

Abstract: An apparatus and method are provided for imaging and analyzing images of tissue samples. The apparatus includes an imager, a lighting system, and a processor. The imager is configured to capture images within a selectable field of view. A tissue sample container is positionable within the field of view. The imager is configured to capture images of a plurality of tissue sample containers. The lighting system is configured to illuminate the field of view. The processor is configured to receive a first plurality of captured images of tissue sample containers. The processor is configured to analyze the first plurality of captured images and to determine whether there is tissue missing from any ones of the first plurality of captured images.

Abstract: An apparatus is provided for scanning and decoding barcodes in a tray or other container containing multiple items, such as tissue samples, that are identified with discrete barcodes. The apparatus includes an imager, a lighting system, and a processor. The imager is configured to capture images within a selectable field of view. At least a portion of a bulk sample container, which is configured to carry a plurality of sample/tissue containers, is positioned within the field of view. The lighting system is configured to evenly light the field of view. The processor is configured to receive the captured images from the imager. The processor is further configured to analyze a first image of the captured images and to detect and decode the barcodes present in the first image.