An emergency signaling system is disclosed. The system includes a receptacle and a painting device. The painting device is covered in a paint material and stored in the receptacle. The receptacle can be used to launch the painting device onto a surface, such as a roof, in the event that a user needs to signal a search and rescue team or anyone near their present location. The painting device, upon contact with a surface, creates a painted signal. The painted signal can have different shapes according to the shape of the painting device. The painting device can include weight members or flexible frame members to facilitate opening the painting device from a closed or folded configuration to a fully open configuration once the painting device has been launched from the receptacle.

Disclosed is a system for generating alerts communicated to emergency responders and/or contacts indicating a location of an incident. The system comprises a housing, one or more light sources, and a computing processor. A switch is located in the housing and configured to be accessible to a user. When the switch is actuated by a user indicating an incident, the processor provides power to the at least one light source to output light from the housing thereby indicating the location of the system. The system may also control a speaker to output an audible signal and a transmitter to transmit an emergency signal with location information to a device of an emergency responder and/or an emergency contact. The present invention may also be embodied in a software application that is implemented on a mobile device to thereby leverage the components of the mobile device to send alerts.

According to embodiments of the present invention, a kit for generating a distress signal based on solar energy is disclosed. This kit comprises: a base unit that includes a base plate, a long-distance communication module coupled to one side of the base plate, at least one processor, and a battery; and a plurality of arm units that are spaced from one another and arranged around the periphery of the base plate, and are connected to the base plate through a first hinge, wherein each arm unit includes: a first arm plate that is connected to the base plate at one end thereof through the first hinge, and can rotate around a folded portion of the first hinge as a rotation axis in a clockwise or counter-clockwise direction; a first solar module and a first light emitting module, which are attached to one side of the first arm plate facing the rotation direction in a clockwise direction; a second arm plate that is connected to the other end opposite to the one end of the first arm plate through a second hinge, and can rotate around a folded portion of the second hinge as a rotation axis in a clockwise or counter-clockwise direction; and a second solar module and a second light emitting module, which are attached to one side of the second arm plate facing the rotation direction in a counter-clockwise direction, wherein the at least one processor controls the first solar module and the second solar module to generate electric energy using the received light energy, and then to store the generated electric energy in the battery, and also can control the first light emitting module and the second light emitting module to emit light using the electric energy stored in the battery.

A method for rescue support involves distributing transponder devices to individuals in a geographic region and causing the transponder devices to be activated. If a large-scale emergency situation occurs, a fleet of unmanned aerial vehicles are operated within the geographic region to receive distress signals transmitted by the activated transponder devices. A computer system processes the distress signals to obtain detection data for the individuals, the detection data comprising a location of the respective transponder device and a health status of the respective individual. The computer system generates, based on the location and health status of the respective individual, a prioritization chart for the geographic region, the prioritization chart being indicative of one or more sub-regions to be prioritized for a rescue operation.

A signal device for maritime distress rescue and a surveillance device for maritime distress rescue are provided. The signal device for maritime distress rescue which is carried by a user aboard a vessel may include a first communicator configured to communicate with a surveillance device for maritime distress rescue of the vessel, a first position detector configured to generate first position information of the signal device at a predetermined time interval, and a first controller configured to receive second position information of the surveillance device from the surveillance device at a predetermined time interval and determine whether the first position information is within a safe area of the vessel that is set on the basis of the second position information. Accordingly, when a distress occurs, it is possible to transmit a distress signal without operating a switch while minimizing power consumption of the signal device.

Threat identification devices, systems, and methods are disclosed which identify and locate various threats and provide a variety of countermeasures to reduce the loss of life in an attack. In one implementation, a device is provided with a housing and a plurality of tubes coupled to and extending from the housing. Sensors are located within the tubes for sensing external conditions. A control unit is in electronic communication with the sensors. Upon detection of an external condition, the sensors transmit a signal to the control unit, which activates countermeasures, including rotating light sources to identify the location of the external condition as well as preferred escape routes. The control unit may also transmit signals to other devices in the environment, including video panels and speakers, to provide instructions.

An example beacon system includes a housing, a laser module at least partly retained within the housing, and a controller operable to control the laser module.

An apparatus that facilitates search and rescue, for example, in open water. The apparatus comprises a substrate with a particular geometry and a perimeter. The apparatus further comprises a cover positioned atop the substrate with the cover also having a particular geometry and perimeter, which correspond to the geometry and perimeter of the substrate. An air-tight seal seals the substrate perimeter to the cover perimeter and creates a sealed internal region. A liquid-releasable vessel holding an illuminable dye located in the sealed internal region, along with an activator that is also located in the sealed internal region. When the liquid-releasable vessel releases the illuminable dye, the illuminable dye reacts with the activator, thereby resulting in illumination of the illuminable dye. The liquid-releasable vessel comprises an opening with a release mechanism (e.g., clamp, etc.).

A self-assembling network is configured to automatically and dynamically connect devices used in operations carried out on or near roads bearing vehicle and pedestrian traffic. An automatic, ad hoc network connecting existing and new devices can be used to enhance safety by gathering and exchanging safety critical information. In some cases, existing equipment can be augmented with a network controller and radio frequency communications to permit the devices to join a wireless local network and exchange information over the network. New devices, including wearable devices, can be configured to act as nodes on the wireless local network. Establishing the relative position of vehicles, sensors, wearables, and other nodes on the disclosed ad hoc wireless network allows the coordination of functions based on position.

An instant alert notifier and docking station for use in emergency situations. Several notifiers and docking stations can be located through a building. In use, the user presses a button and pulls the device cover, which causes the notifier to (1) snap a still image of the person removing the notifier, (2) trigger a “code red” alert and/or activate flashing red LEDS on the docking stations where they are located throughout the building and/or (3) switch from a front to a rear camera operation. Using the notifier, real time video and still images can be captured and uploaded to first responder devices. The pressing of the button or removal of the notifier from the docking station can also cause the system to stream live video to the first responders from all of the other notifiers in the building still contained within their docking stations.