A smart rescue helmet for use by a rescuer at an action site is described. It includes a number of features enclosed in an outer shell which includes a shock-absorbing canopy and a visor. The features include a control module comprising a microcomputer contained inside the smart rescue helmet, a near-field display, a visible band camera, a thermal imaging camera, a sensor module monitoring physiological parameters along with a position of the rescuer; and a communication system.

If a distance from a current position to a guide point is less than a predetermined distance, a normal output process and a stop process of a guide image are repeatedly performed. If a priority display request for a guide image is performed, a priority output process of the guide image is performed prior to the stop process. If an interval between the priority output process and the normal output process performed after the priority output process is short, the priority output process continues until the normal output process starts.

Disclosed is a structure for fixing a riding recorder with helmet visor fasteners, including a visor, which is provided, in the inside thereof, with a plurality of first coupling members so as to be attached to a helmet with the first coupling members. A monitoring unit is mounted to a bottom of the visor and the monitoring unit includes at least one camera lens and a storage element such that when the monitoring unit is activated, the camera lens is operable to take images and stores the data of the images in the storage element.

A system for augmented reality comprises a helmet and a container body within which a video unit is housed that comprises a device for acquiring images of a real scene and a display device for displaying at least the aforementioned images. A support body is, furthermore, provided configured to engage the container body to the helmet. The container body and the support body are provided with respective first and second engagement members configured to selectively and alternatively removably engage the container body to the support body in a first engagement position, in which the device for acquiring images is arranged to acquire images with a first predetermined field of view and the display device is positioned within the field of view of the user, and at least a second engagement position, in which the device for acquiring images is arranged to acquire images with a second predetermined field of view.

A helmet with a sports camera comprises a body and a picture recording module which is detachably mounted on the body. The picture recording module includes an outer shell and a camera disposed in the outer shell. The camera is electrically connected to a control system; the control system is connected to a power module; the control system is further electrically connected to an LED indicator and an operating button; in use, through controlling the operating button, a user can take photos or record a video. Advantages of the helmet with a sports camera are summarized as follows. 1. The helmet and the camera are integrated, which facilitates the photographing of sceneries. 2. LED indicators and operation buttons on the helmet can control the start-up, shooting, or recording of the camera, and the micoUSB data interface can be used for charging, data copying, or connected to a PC camera. 3. An external vehicle-mounted display can be provided, which operates to real-time show the shot pictures or sceneries for users to browse through wireless communication technology.

An augmented-reality system is combined with a surveying system to make measurement and/or layout at a construction site more efficient. A reflector can be mounted to a wearable device having an augmented-reality system. A total station can be used to track a reflector, and truth can be transferred to the wearable device while an obstruction is between the total station and the reflector. Further, a target can be used to orient a local map of a wearable device to an environment based on a distance between the target and the wearable device.

A video recording system for a head safety device includes a microcontroller and an accelerometer mounted in the head safety device. The accelerometer is coupled to the microcontroller. A plurality of camera modules are mounted on the head safety device and coupled to the microcontroller. The camera modules are positioned facing outward to obtain images at different angles of an environment surrounding the head safety device. The microcontroller receives data from the accelerometer and automatically initiates video recording with the camera modules when movement of the head safety device, as sensed using the accelerometer, reaches or exceeds a selected movement threshold.

A head for a walk-around costume is provided that is adapted for enhanced visibility. The costume head includes an outer shell defining an interior space for receiving a head of a human performer. The outer shell includes an aperture allowing incoming light from an exterior space to enter the interior space, and an eye location for the human performer is spaced apart from the aperture when the head is received in the interior space. To provide an enlarged field of view, the costume head includes an optical viewfinder assembly disposed within the interior space of the outer shell between the aperture and the eye location. The optical viewfinder assembly is adapted for receiving the incoming light and transmitting the incoming light to the eye location to move a viewpoint of the human performer to the aperture to provide a larger field of view of the exterior space.

A system in an atmospheric suit includes a transparent organic light emitting diode (OLED) display including a substrate. The substrate is an inner surface of an inner shell of a helmet that is closest to a wearer of the atmospheric suit or the substrate is an inner surface of an outer shell of the helmet between the inner shell and the outer shell. The system also includes a controller to control a content displayed on the OLED display.

The disclosed device, system, and method may comprise one or more devices for digital personal protective equipment. These devices may be network enabled wearables. A plurality of sensors, data transmission mechanisms, self-illuminating LEDs, and communication mechanisms may be embedded in a suspension or harness in various embodiments. A number of sensors may likewise be provided in a glove or earbud (ear plug). The device may measure various aspects of a wearer's movement and transmit that data over a data connection (such as a wifi or mobile connection) to a server. The server may house project and human resources data, worker and condition information, and materials and supplies data, according to various examples of embodiments. The system may further comprise one or more applications which may interpret the data provided.