An electric power charge and discharge system for an electronic device having a battery, by which the electronic device can be used for a long period of time. In a wireless communication device including a wireless driving portion including a first battery and a wireless charging portion including a second battery, the first battery is charged by electric power from a fixed power supply and the second battery is charged by using electromagnetic waves existing in an external space. Further, the first battery and the second battery are discharged alternately, and during a period in which the first battery is discharged, the second battery is charged.

An electric power charge and discharge system for an electronic device having a battery, by which the electronic device can be used for a long period of time. In a wireless communication device including a wireless driving portion including a first battery and a wireless charging portion including a second battery, the first battery is charged by electric power from a fixed power supply and the second battery is charged by using electromagnetic waves existing in an external space. Further, the first battery and the second battery are discharged alternately, and during a period in which the first battery is discharged, the second battery is charged.

A charging apparatus including a device holder disposed within a cavity, wherein the device holder is pivotably attached to a base and is configured to receive a first device type and continuously charge the first device as the device holder rotates from a first position to a second position and throughout rotation from the first position to the second position. The charging apparatus may include a charging element disposed within the cavity that is configured to receive and charge a second device type.

A charging apparatus including a device holder disposed within a cavity, wherein the device holder is pivotably attached to a base and is configured to receive a first device type and continuously charge the first device as the device holder rotates from a first position to a second position and throughout rotation from the first position to the second position. The charging apparatus may include a charging element disposed within the cavity that is configured to receive and charge a second device type.

A fixing support bracket for charging connector is provided, comprising a tightening ring and a carrying unit, wherein the tightening ring is elastic and can expand when stretched, the carrying unit is engaged to a partial section of the tightening ring, the carrying unit is provided with at least a front stopper and at least a rear stopper, with a placement space between the front stopper and the rear stopper, the placement space is used for placing an object, and the object is an electronic mobile device. As such, the electronic mobile device can be carried by the fixing support bracket during charging.

A fixing support bracket for charging connector is provided, comprising a tightening ring and a carrying unit, wherein the tightening ring is elastic and can expand when stretched, the carrying unit is engaged to a partial section of the tightening ring, the carrying unit is provided with at least a front stopper and at least a rear stopper, with a placement space between the front stopper and the rear stopper, the placement space is used for placing an object, and the object is an electronic mobile device. As such, the electronic mobile device can be carried by the fixing support bracket during charging.

When it comes to monitoring human health, today's consumers are limited to so called “health trackers,” which count steps and calculate calorie burns. Traditional health trackers are only capable of measuring heart rate and are limited to external measurements. These devices are not capable of obtaining the internal body data and do not have access to human fluids. The personal health shield personal cloud case cover (or “health PCCC”) can not only analyze human fluids but also fluids being consumed by the user (food and drinks). The data collected from the fluids is then compared to a cloud or local data base. The results are displayed on a phone, tablet, personal computers, television, or any other device either mounted in the PCCC or connected to the health PCCC.

Embodiments relate to a wearable communications node (WCN) with mesh networking capabilities. The WCN, which is worn on the user's torso, includes an enclosure and shoulder strap(s) as well as communications device, antenna element(s), and battery conductively coupled to a control circuit. The enclosure includes a top area and an oppositely positioned bottom area. The shoulder strap is pivotably attached proximate to the top area and the bottom area. The communications device is rigidly affixed within the enclosure. The antenna element is conductively coupled to the communications device as well as rigidly affixed to the enclosure or flexibly affixed the shoulder strap. The control circuit is configured to establish, via the communications device, a self-organizing wide area network with a plurality of computing devices that each connects directly, dynamically, and non-hierarchically to the WAN. The antenna element includes a conductive composition that includes graphene dispersed in a polymer matrix.

Embodiments relate to a wearable communications node (WCN) with mesh networking capabilities. The WCN, which is worn on the user's torso, includes an enclosure and shoulder strap(s) as well as communications device, antenna element(s), and battery conductively coupled to a control circuit. The enclosure includes a top area and an oppositely positioned bottom area. The shoulder strap is pivotably attached proximate to the top area and the bottom area. The communications device is rigidly affixed within the enclosure. The antenna element is conductively coupled to the communications device as well as rigidly affixed to the enclosure or flexibly affixed the shoulder strap. The control circuit is configured to establish, via the communications device, a self-organizing wide area network with a plurality of computing devices that each connects directly, dynamically, and non-hierarchically to the WAN. The antenna element includes a conductive composition that includes graphene dispersed in a polymer matrix.

Disclosed is a wireless power transmitter for wirelessly delivering power to a receiver device, the wireless power transmitter including: a plurality of unit cells configured to radiate one or more radio frequency (RF) power transmission waves, each unit cell in the plurality of unit cells including: (i) a metal portion having an interior perimeter that surrounds an aperture defined by the metal portion; and (ii) an antenna that is aligned with the aperture in a first dimension, the antenna being configured to radiate one or more RF power transmission waves for wirelessly charging a receiver device. The one or more RF power transmission waves leak from the wireless power transmitter at least in part through the aperture when the receiver device is positioned within a threshold distance from the unit cell.