Abstract: A coupler for coupling an endoscope to a camera head includes a base configured to mount to the camera head and to receive an eyepiece of the endoscope; a clamp for clamping the eyepiece in the base, the clamp configured to move laterally relative to a longitudinal axis of the coupler between a clamping position and non-clamping position; at least one clamping arm rotatably connected to the clamp and comprising a pin that moves in a slot of the base, wherein when the clamp moves laterally toward the clamping position, movement of the pin in the slot causes the at least one clamping arm to rotate into engagement with the eyepiece; and a button for pressing by a user to move the clamp from the clamping position to the non-clamping position.

Abstract: A bowl assembly for a micro puree machine including an inner beaker and an outer bowl. The inner beaker is configured to receive ingredients and has an exterior bottom surface that includes a beaker alignment feature. The outer bowl is configured to receive the inner beaker therein. The outer bowl includes an interior bottom surface that includes a bowl alignment feature and an exterior bottom surface that includes a bowl securing element. The beaker alignment feature of the inner beaker exterior bottom surface is complementary to the bowl alignment feature of the outer bowl interior bottom surface such that, at times the inner beaker is positioned in the outer bowl, the complementary bowl alignment feature and inner beaker alignment feature prevent rotation of the inner beaker relative to the outer bowl. The bowl securing element is configured to receive and attach to a platform of a micro puree machine.

Abstract: Core-shell particles have a hydrophobic core and a shell formed of o containing hyperbranched polymers (HP). The HP can be covalently bound to the one or more materials that form the core or coated thereon. The HP coating can be modified to adjust the properties of the particles. For example, unmodified HP coatings resist non-specific protein absorption. Alternatively, the hydroxyl groups on the HP coating can be chemically modified to form functional groups that react with functional groups on tissue to adhere the particles to the tissue, cells, or extracellular materials, such as proteins. Such functional groups include, but not limited to, aldehydes, amines, and O-substituted oximes. Topical formulation for application to the skin contain these HP coated nanoparticles. In some embodiments, the particles include cosmetic, therapeutic, diagnostic, nutraceutical, and/or prophylactic agents, such as those used as sunblock compositions.

Abstract: A weapon usage monitoring system that monitors information about at least a first weapon and a second weapon includes a mobile networking hub, a first weapon response device, a second weapon response device and an edge compute resource. The mobile networking hub can provide a local area network (LAN). The first weapon response device can have a first sensor that senses first weapon response data about the first weapon. The first weapon response device can communicate the first weapon response data to the mobile networking hub. The second weapon response device can have a second sensor that senses second weapon response data about the second weapon. The second weapon response device can communicate the second weapon response data to the mobile networking hub. An edge compute resource can aggregate the first and second weapon response data from the mobile networking hub into aggregated weapon response data.

Abstract: Systems and methods are provided for weapon system monitoring and virtual reality presentation, including a connection point that receives signals from a plurality of sensors within a deployment location, a server device running application software that receives the signals from the connection point and processes the signals to generate a virtual reality depiction of the deployment location, and a graphical user interface presenting a field of view of the virtual reality depiction of the deployment location.

Abstract: Systems and methods are provided for combining video and virtual reality presentations, comprising a server device running application software that receives, at a connection point, a plurality of video signals from a plurality of assets within a deployment location, a video processing facility configured to sync the plurality of video signals to generate a time-matched, unified video depiction of the deployment location, where the unified video depiction presents at least one of positions, orientations, actions or affiliations of the plurality of the assets within the deployment location, and a graphical user interface presenting a field of view of the unified video depiction of the deployment location.

Abstract: Systems and methods are provided for weapon system monitoring, historical usage analysis, and performance evaluation of a plurality of assets within a deployment location, where each asset of the plurality includes one or more sensors that record operational information of each asset and are used to produce at least one signal, including a server device running application software that uses the signal received from each asset to detect and store situational state data of each asset and performance level data of a party associated with each asset, and a machine learning system that uses the situational state data and the performance level data to determine an operational profile of the party.

Abstract: Systems and methods are provided for monitoring geolocations of a plurality of weapons within a deployment location, where each of the weapons includes one or more sensors that produce more or more signals, including a response infrastructure configured for management of the weapons, a server device running application software that uses the one or more signals received from each of the weapons to detect a geolocation of a weapon and causes the response infrastructure to determine if the detected geolocation of the weapon conforms to the stored rule regarding the permitted weapon geolocation, and a threat detection and analysis module that performs an action based on a confirmation that the detected geolocation of the weapon does not conform to the stored rule regarding the permitted weapon geolocation.

Abstract: Systems and methods are provided for combining video and virtual reality presentations, including a server device running application software that receives sensor signals at a connection point from a plurality of assets within a deployment location and processes the signals to generate a virtual reality depiction of the deployment location, and a graphic user interface presenting a field of view of the virtual reality depiction of the deployment location, where the virtual reality depiction is combined with video derived from the deployment location in the graphic user interface presentation.

Abstract: Systems and methods are provided for weapon monitoring, including a weapon measurement system with one or more sensors that record longitudinal operational information of a plurality of weapons and are used to produce a plurality of signals, a connection point that receives the plurality of signals within a deployment location, a server device running application software that uses the plurality of signals received from the plurality of weapons to detect and store longitudinal situational state data of each weapon of the plurality of weapons, and a machine learning system that uses the longitudinal situational state data to calculate a weapon system failure state.

Abstract: Systems and methods are provided for deployment location monitoring and threat analysis, comprising producing, at a device within a deployment location, a signal including sensor information recorded using one or more sensors of the device and metadata regarding the device, transmitting, from the device, the signal to a server device running application software, processing, by the application software, the signal to detect a threat within the deployment location, determining, by the application software, an action to perform in response to the detected threat and presenting within a graphical user interface a virtual reality depiction of the deployment location with images generated based at least in part on data received from the device.

Abstract: Systems and methods are provided for weapon monitoring and event prediction system, comprising an inertial measurement unit located in a weapon that is configured to generate weapon usage data indicative of at least one of a movement of the weapon, an orientation of the weapon, a direction of the weapon, or a location of the weapon, a communication circuit configured to communicate the generated weapon usage data to a device external to the weapon, a storage facility configured to store generated weapon usage data collected sequentially over a specified time period, and a machine learning facility configured to build at least one analytic model specifying weapon longitudinal situational state data and usage data predictive of the occurrence of a specified event or weapon system failure.

Abstract: Systems and methods are provided for firearm usage monitoring, including a battery configured to power components of the firearm, a communication interface and a controller running application software configured to: power, via the battery, the components of the firearm in a first sensing mode; monitor, via the communication interface, density of electromagnetic radiation proximate the firearm; harvest, in response to the electromagnetic radiation density exceeding, power from the electromagnetic radiation via a wireless-energy harvesting mechanism having a receiving antenna configured to receive a local electromagnetic signal, a rectifier configured to convert the received signal to direct current, and a DC-DC converter configured to alter voltage of the direct current to a desired voltage; and operate, via the battery and the harvested power, the components of the firearm in a second sensing mode, the second sensing mode expending more energy than the first sensing mode.

Abstract: Systems and methods are provided for firearm monitoring and remote support of a plurality of firearms within a deployment location, wherein each firearm includes one or more sensors that record sensor information used to produce a signal, a response infrastructure configured for deployment to the deployment location, and a server device running application software that uses the signals received from each of the firearms to detect a threat within the deployment location and causes the deployment of the response infrastructure to the deployment location, wherein the response infrastructure supports users of the plurality of firearms in addressing the detected threat.

Abstract: Systems and methods are provided for a firearm monitoring system comprising an inertial measurement unit configured to generate data indicative of at least one of a movement of the firearm, an orientation of the firearm, a direction of the firearm, or a location of the firearm, and a communication circuit configured to communicate the data generated using the inertial measurement unit to a device external to the firearm, and a microcontroller module configured to deliver power from a power source to at least one of the inertial measurement unit or the communication circuit, wherein at least the inertial measurement unit is disposed within a barrel structure of the firearm.

Abstract: Systems and methods are provided for firearm monitoring and remote support of a plurality of connection points within a deployment location, wherein each connection point of the plurality of connection points is configured to receive signals produced at one or more firearms proximate to the connection point within the deployment location, wherein each connection point of the plurality of connection points is further configured to communicate the received signals to a server device located outside of the deployment location, and a server device, wherein the server device runs application software that receives the signals from each of the connection points and uses the sensor information included in the signals to detect a threat within the deployment location.

Abstract: A firearm usage monitoring system configured to store data about location, movement, orientation, and direction of a firearm while in use and includes a hard-wired data and power connection, configured to receive data and power from a wired source. A UART to USB controller is communicatively coupled to the data and power connection and configured to send data to and receive data from the data and power connection. A microprocessor sends data to and receives data from the UART to USB controller. A motion monitor is communicatively coupled to the microprocessor module further comprising a gyroscope, an accelerometer and a compass configured to communicate data about movement, orientation, and direction of the firearm. Memory is communicatively coupled to the microprocessor and the motion monitor. Data about the location and position of the firearm in 3D space is transmitted from the motion monitor and GPS and then stored in the memory.

Abstract: Systems and methods are provided for a firearm monitoring system comprising an inertial measurement unit configured to generate data indicative of at least one of a movement of the firearm, an orientation of the firearm, or a direction of the firearm, and a communication circuit configured to communicate the data generated using the inertial measurement unit to a device external to the firearm, and a microcontroller module configured to deliver power from a power source to at least one of the inertial measurement unit or the communication circuit, wherein at least the inertial measurement unit is disposed within an action structure of the firearm.

Abstract: Systems and methods are provided for weapon monitoring, including a weapon measurement system with one or more sensors that record longitudinal operational information of a plurality of weapons and are used to produce a plurality of signals, a connection point that receives the plurality of signals within a deployment location, a server device running application software that uses the plurality of signals received from the plurality of weapons to detect and store longitudinal situational state data of each weapon of the plurality of weapons, and a machine learning system that uses the longitudinal situational state data to calculate a weapon system failure state.

Abstract: Systems and methods are provided for firearm event monitoring, including an inertial measurement unit and a hall-effect sensor mounted on a firearm, a server device running application software that receives signals from the inertial measurement unit and the hall-effect sensor, and a machine learning module configured to create and run identification algorithms, using data derived from the received signals from the inertial measurement unit and the hall-effect sensor indicative of a discharge event type, wherein the discharge event type is one of an ammunition discharge event, a misfire discharge event or a dry-fire discharge event.