A remote assistance workstation 12 comprises a communications module 54, a user interface (UI) module 52, and a controller 56, for being coupled to a portable device 14 that includes a pair of augmented reality (AR) glasses 36 worn by a first responder to carry out an action using an object with a subject at a scene. The UI module 52 renders a remote assistant graphical user interface (GUI) 100 that includes (i) a first pane 96 for displaying a live video stream of a remote assistance request and (ii) a second pane 98 for displaying a 2D representation of the object at the scene being moveable therein by remote assistant inputs. The GUI 100 renders a corresponding item of 3D virtual content within the first pane relative to a reference point. The controller 56 outputs remote assistance signals to the portable device 14 for displaying the item of 3D virtual content 38 on the AR glasses in a live view of the scene, appearing at a location determined by the remote assistant inputs moving the 2D representation within the second pane 98 for assisting the first responder at the scene.

Apparatus and associated methods relate to fitting a virtual mask to a virtual face by first fitting a chin region of the virtual mask to the virtual face, then determining an virtual mask angle that maintains the fitted chin region while simultaneously fitting a nose-bridge region of the virtual mask to the virtual face, and then calculating a fit-quality metric corresponding to the fitted position. In an illustrative embodiment, the fitted chin region may include the high curvature menton region of the chin. In some examples, a virtual mask may be virtually pressed toward the virtual face using a predetermined force corresponding to a force of a mask securing device of a real mask corresponding to the virtual mask In an exemplary embodiment, the fitting of a virtual mask to a virtual face may advantageously yield a mask's fit quality in a brief amount of time.

A safety system includes (a) a rope or lanyard; (b) a safety hook attached to the rope or lanyard; (c) a load detection sensor retrofit to the hook without altering the structural integrity of the hook; and (d) a transmitter arranged to convey a load status signal.

A rescue package is disclosed which is sized for launching from a moving platform such as an aircraft. The platform having a chute adapted to launch a rescue package which in an embodiment uses a container the same size as a container used to house a convention sonobuoy. The rescue package arrangement includes a container body externally sized and shaped to be launched from a moving platform using a launch tube and contains a main parachute located within the container; a drogue chute associated with the container deployed after deployment from the moving platform and connected to the main parachute by a drogue chute tether; a decelerator chute connected to the container and arranged to deploy with or after the drogue chute is deployed, and a delay mechanism arranged to delay deployment of the main parachute for a period of time after the drogue chute is deployed from the container. The container is adapted to contain a payload including at least one of the group of items: inflatable life raft, potable water, long-life food, matches, handheld light sources, handheld beacons, handheld communication devices, cell batteries, rope, water proof sheet material, blankets, sunscreen, hats, insect repellent, containers, utensils, sea-sickness tablets, water bailer, sponges, and wherein the decelerator chute assists the stabilisation of the container during at least a portion of the flight of the container.

A rescue package is disclosed which is sized for launching from a moving platform such as an aircraft. The platform having a chute adapted to launch a rescue package which in an embodiment uses a container the same size as a container used to house a convention sonobuoy. The rescue package arrangement includes a container body externally sized and shaped to be launched from a moving platform using a launch tube and contains a main parachute located within the container; a drogue chute associated with the container deployed after deployment from the moving platform and connected to the main parachute by a drogue chute tether; a decelerator chute connected to the container and arranged to deploy with or after the drogue chute is deployed, and a delay mechanism arranged to delay deployment of the main parachute for a period of time after the drogue chute is deployed from the container. The container is adapted to contain a payload including at least one of the group of items: inflatable life raft, potable water, long-life food, matches, handheld light sources, handheld beacons, handheld communication devices, cell batteries, rope, water proof sheet material, blankets, sunscreen, hats, insect repellent, containers, utensils, sea-sickness tablets, water bailer, sponges, and wherein the decelerator chute assists the stabilisation of the container during at least a portion of the flight of the container.

In some examples, a system includes an article of personal protective equipment (PPE) having at least one sensor configured to generate a stream of usage data; and an analytical stream processing component comprising: a communication component that receives the stream of usage data; a memory configured to store at least a portion of the stream of usage data and at least one model for detecting a safety event signature, wherein the at least one model is trained based as least in part on a set of usage data generated by one or more other articles of PPE of a same type as the article of PPE; and one or more computer processors configured to: detect the safety event signature in the stream of usage data based on processing the stream of usage data with the model, and generate an output in response to detecting the safety event signature.

In some examples, a system includes an article of personal protective equipment (PPE) having at least one sensor configured to generate a stream of usage data; and an analytical stream processing component comprising: a communication component that receives the stream of usage data; a memory configured to store at least a portion of the stream of usage data and at least one model for detecting a safety event signature, wherein the at least one model is trained based as least in part on a set of usage data generated by one or more other articles of PPE of a same type as the article of PPE; and one or more computer processors configured to: detect the safety event signature in the stream of usage data based on processing the stream of usage data with the model, and generate an output in response to detecting the safety event signature.

Embodiments in the present description are provided for a lever adapter device for use in lifting a vehicle or other heavy objects. Additional embodiments in the present description are provided for a Bi-pod rescue strut system for use in stabilizing a vehicle or other object. The lever adapter device includes stabilizing feet and one or more support legs. The lever adapter device further includes a hinge disposed at an end of each support leg. The lever adapter device further includes a rotatable attachment link that enables options for the orientation of a lifting device to assist in lifting the vehicle or the other heavy objects.

Embodiments in the present description are provided for a lever adapter device for use in lifting a vehicle or other heavy objects. Additional embodiments in the present description are provided for a Bi-pod rescue strut system for use in stabilizing a vehicle or other object. The lever adapter device includes stabilizing feet and one or more support legs. The lever adapter device further includes a hinge disposed at an end of each support leg. The lever adapter device further includes a rotatable attachment link that enables options for the orientation of a lifting device to assist in lifting the vehicle or the other heavy objects.

Embodiments in the present description are provided for a lever adapter device for use in lifting a vehicle or other heavy objects. Additional embodiments in the present description are provided for a Bi-pod rescue strut system for use in stabilizing a vehicle or other object. The lever adapter device includes stabilizing feet and one or more support legs. The lever adapter device further includes a hinge disposed at an end of each support leg. Each support leg is extendable and retractable towards or away from the other support leg. The lever adapter device further includes a jack attachment piece and one or more hinges, which are also connected to the one or more support legs. The jack attachment piece is configured to be removably connected to a jack, such as a HI-LIFT jack, or to other lifting devices to assist in lifting the vehicle or the other heavy objects.