A helmet assembly for a spacesuit or other protective suit is disclosed. In embodiments, the helmet assembly includes an external face shield attachable to the spacesuit and providing the spacesuit user with a forward field of view. The helmet assembly includes suit status displays hard-mounted to the external face shield at a periphery or edge of the forward field of view (e.g., upper, lower, left, right). Each suit status display includes a linear or one-dimensional array of individual light emitting diodes (LED) in communication with a suit controller of the spacesuit. Each LED array receives from the suit controller suit status data (e.g., consumables levels, suit performance, position data) communicated to the user by illuminating one or more of the individual LED units.

An intelligent head-mounted apparatus, including: a head-mounted apparatus body; a communication element operable to receive navigation signals and a locating element operable to determine location information, both of which are disposed on the head-mounted apparatus body; and a controller disposed on the helmet apparatus body and operable to control at least one vibrating element based on the navigation signals and the location information; vibrating elements operable to vibrate under the control of the controller. The user of this apparatus can learn navigation information only by perceiving the vibration without being distracted by observing the navigation information, so that the safety of receiving navigation information during riding is improved. A control method of the intelligent head-mounted apparatus is further provided.

An computer readable non-transitory recording medium records an image processing program causes a computer to function as: an image acquisition unit that acquires an image obtained by photographing a detection target area including an object; an occurrence frequency calculation unit that calculates for each color an occurrence frequency of the color in the image, based on the image acquired by the image acquisition unit; and a low frequency color determination unit that determines a low frequency color being a color low in occurrence frequency as compared with other colors based on the occurrence frequency for each color calculated by the occurrence frequency calculation unit.

The present invention provides a smart helmet falling detection method and a smart helmet. The falling detection method includes following steps: initializing a system, determining a free fall, determining a collision, determining motionlessness, and generating an emergency signal according to a detection result that a motionlessness event occurs within a fourth duration after the collision event occurs. The smart helmet includes a three-axis acceleration sensor and a controller. For the smart helmet falling detection method and the smart helmet provided in the present invention, the acceleration is measured by the three-axis acceleration sensor installed on the smart helmet, and whether a riding falling event occurs is determined by analyzing change of the acceleration, and alarm is given according to the falling event, such that the problem of falling detection and calling for help in a riding process is solved in a targeted manner.

An apparatus is presented for improving the noticeability of a hat. The apparatus includes a light source configured to produce light upon receiving electrical energy. The apparatus also includes a mount coupled to the light source and configured to selectively attach to and detach from the hat. The mount, when attached to the hat, orients the light source to project light away from an exterior surface of the hat into an ambient environment of the hat. The exterior surface includes at least one of a left-side exterior surface and a right-side exterior surface. The apparatus additionally includes a battery receptacle electrically-coupled to the light source and having electrical contacts for coupling to one or more batteries. Hats having improved noticeability and methods for improving the noticeability of a hat are also presented.

Systems and methods for replicating vehicular illumination are disclosed. According to an aspect, a system includes a detector configured to sense light emitted by a host light of a host vehicle for detecting a lighting state of the host light. The system also includes a communications system configured to communicate the detected lighting state between the host light and the remote light. Further, the system includes a remote light being located on one of the host vehicle and an operator of the host vehicle and configured to replicate the lighting state of the host light.

A head lowering and turning reminding device, a control method thereof and a helmet are disclosed. The reminding device is disposed on a vehicle or worn by a user of the vehicle, and includes: a speed sensor configured to detect a ground speed of the vehicle; a head posture monitoring module configured to monitor a head posture of the user and generate a signal relevant to a head rotating action of the user; a recognition module configured to receive the signal and recognize at least one of a head lowering action and a head turning action of the user and a duration time of this action; and an alarm module configured to output an alarm for reminding the user upon the ground speed being greater than a speed threshold and the duration time exceeding a preset time threshold.

In some examples, a system includes a head-mounted device, a visor that includes a reflective object that is substantially transparent in a visible light spectrum and embodied at a physical surface of the visor, at least one visor attachment assembly that couples the visor to the head-mounted device; at least one optical sensor; and at least one computing device communicatively coupled to the at least one optical sensor, the at least one computing device comprising a memory and one or more computer processors that: receive, from the optical sensor, an indication of light outside of a visible light spectrum that is reflected from the reflective object; determine, based at least in part on the light outside of a visible light spectrum that is reflected from the reflective object, a position of the visor; and perform, based at least in part on the position of the visor, at least one operation.

Vehicle signaling configurable to various articles and apparel is provided. An example system allows a user to dynamically assign vehicle signals for activating brake lights, turn signals, running lights, headlights, police emergency lights, and so forth, to user-selected lights built into articles and apparel. Vehicle signals may be wirelessly assigned to lights on articles and apparel through a smart phone application, or other portable software means. The system forms a self-managing wireless network, to which the user can add any number of additional illuminated articles and pieces of illuminated apparel, which are automatically sensed and integrated. An example helmet spoiler, for example, has a receiver for processing a wireless signal from a vehicle, to actuate brake lights, turn signals, headlights, and the like on the spoiler itself. In a police implementation, a helmet actuates police flashers on the helmet based on an assigned wireless signal from a police vehicle.

A force transfer system includes a body and an article. The article includes a first portion forming a first lateral axis and a second portion forming a second lateral axis, the axes being offset. An intermediate member is disposed between the first portion and the second portion, and holds the second portion to the first portion. A stimulus received by the first portion causes a temporary alteration of the intermediate member from an initial condition, the alteration of the intermediate member thereby causing a change in a characteristic of the second portion. The intermediate member subsequently returns to the initial condition, thereby causing a change in a characteristic of the first portion, which is influenced by the change in the characteristic of the second portion. The change in the characteristic of the first and second portions prevents at least a portion of the stimulus from reaching the body.