A luggage container with built-in external compartment, which includes a case having an outer side and an inner side and a drawer configured to be slid in and out of the case. The case includes a coupling portion formed on the inner side, the coupling portion protruding from the inner side, and the coupling portion is shaped to receive a fastening element. The case is shaped to form a space between a surface of an object onto which the case is coupled and a surface of the inner side to receive the drawer. The drawer is shaped to remain within the case when the drawer is pulled out of the case such that the case and the drawer are not separated even when the drawer is pulled out maximally.

Various improvements for portable containers such as luggage. Various systems, devices and methods are provided for increasing functionality for luggage and other portable containers, for example for personal travel. These improvements include a power box for portable energy provision while traveling, that may optionally be integrated with a suitcase; a portable document handler for convenient and secure transportation of documents; and an elastic strap designed to better secure luggage, as well as optionally providing a visual identifier for a bag. These improvements may optionally be used together or separately.

Various improvements for portable containers such as luggage. Various systems, devices and methods are provided for increasing functionality for luggage and other portable containers, for example for personal travel. These improvements include a power box for portable energy provision while traveling, that may optionally be integrated with a suitcase; a portable document handler for convenient and secure transportation of documents; and an elastic strap designed to better secure luggage, as well as optionally providing a visual identifier for a bag. These improvements may optionally be used together or separately.

According to an exemplary embodiment, an electronic luggage device may be disclosed. The electronic luggage device may be fully TSA compliant. The device may be capable of communicating both wirelessly and by wired connection(s) to other devices. The electronic luggage device may also charge other devices by battery and in turn be charged by other electric power facilities. The electronic luggage device may have GPS capabilities, an intelligent sleep-mode, multiple various charging and communicatory ports, a recessed telescoping handle fixture, a hidden battery compartment, and a high capacity removable battery. The removable battery may be retained by any locking means understood by a person having ordinary skill in the art. The removable battery may be automatically or manually ejected. This may be accomplished by a spring-loaded force, a slot and rail system, or equivalents as would be understood by a person having ordinary skill in the art.

According to an exemplary embodiment, an electronic luggage device may be disclosed. The electronic luggage device may be fully TSA compliant. The device may be capable of communicating both wirelessly and by wired connection(s) to other devices. The electronic luggage device may also charge other devices by battery and in turn be charged by other electric power facilities. The electronic luggage device may have GPS capabilities, an intelligent sleep-mode, multiple various charging and communicatory ports, a recessed telescoping handle fixture, a hidden battery compartment, and a high capacity removable battery. The removable battery may be retained by any locking means understood by a person having ordinary skill in the art. The removable battery may be automatically or manually ejected. This may be accomplished by a spring-loaded force, a slot and rail system, or equivalents as would be understood by a person having ordinary skill in the art.

According to an exemplary embodiment, an electronic luggage device may be disclosed. The electronic luggage device may be fully TSA compliant. The device may be capable of communicating both wirelessly and by wired connection(s) to other devices. The electronic luggage device may also charge other devices by battery and in turn be charged by other electric power facilities. The electronic luggage device may have GPS capabilities, an intelligent sleep-mode, multiple various charging and communicatory ports, a recessed telescoping handle fixture, a hidden battery compartment, and a high capacity removable battery. The removable battery may be retained by any locking means understood by a person having ordinary skill in the art. The removable battery may be automatically or manually ejected. This may be accomplished by a spring-loaded force, a slot and rail system, or equivalents as would be understood by a person having ordinary skill in the art.

According to an exemplary embodiment, an electronic luggage device may be disclosed. The electronic luggage device may be fully TSA compliant. The device may be capable of communicating both wirelessly and by wired connection(s) to other devices. The electronic luggage device may also charge other devices by battery and in turn be charged by other electric power facilities. The electronic luggage device may have GPS capabilities, an intelligent sleep-mode, multiple various charging and communicatory ports, a recessed telescoping handle fixture, a hidden battery compartment, and a high capacity removable battery. The removable battery may be retained by any locking means understood by a person having ordinary skill in the art. The removable battery may be automatically or manually ejected. This may be accomplished by a spring-loaded force, a slot and rail system, or equivalents as would be understood by a person having ordinary skill in the art.

A system for identifying and following a moving electronic device, the system includes an antenna for receiving a transmitting signals, a plurality of sensors for distance measurement, a processor, and a memory in communication with the processor. The memory storing instructions that, when executed by the processor, cause the processor to determine a speed and a direction of the moving electronic device; adjust a movement path of the system based on the determined speed and direction of the moving electronic device; determine a distance between the moving electronic device and the system; command the system to follow the moving electronic device within a predetermined range of the distance while identifying and avoiding an obstacle in the movement path of the system.

An identification system includes an identification device and a communication device. The identification device is attached to an article and including a sensor. The identification device is configured to operate in a plurality of modes and configured to switch between modes of the plurality of modes based on one or more conditions of a surrounding environment sensed by the sensor. The identification device is configured to send data to a server. The communication device of a user of the identification system is configured to receive data including location data of the identification device from the server using short message service protocols or messages through a signaling channel.

An identification system includes an identification device and a communication device. The identification device is attached to an article and including a sensor. The identification device is configured to operate in a plurality of modes and configured to switch between modes of the plurality of modes based on one or more conditions of a surrounding environment sensed by the sensor. The identification device is configured to send data to a server. The communication device of a user of the identification system is configured to receive data including location data of the identification device from the server using short message service protocols or messages through a signaling channel.