Embodiments of the present invention provide a data transmission method, a data transmission apparatus, a processor, and a mobile terminal. The data transmission method includes: determining, by a mobile terminal, whether to use multiple data channels to transmit to-be-transmitted data; if determining to use the multiple data channels to transmit the to-be-transmitted data, selecting, by the mobile terminal, at least two activated data channels for the to-be-transmitted data according to current traffic information and service quality information that are of the multiple data channels; and using, by the mobile terminal, the selected at least two data channels to transmit the to-be-transmitted data.

A seamless three-dimensional cover (1) for an electronic device (2), the seamless three-dimensional cover (1) comprising of at least one glass base layer (3) and at least one glass rim layer (4). At least one layer of color inducing film (5) is arranged between at least one of the base layer (3) and the rim layer (4), or between two adjacent rim layers (4). The base layer (3), the rim layer(s) (4), and the layer of color inducing film (5) are fused together to form the seamless three-dimensional cover (1). This facilitates a strong and durable three-dimensional cover, which cover is translucent as well as at least partially colored. Furthermore, the cover does not affect the function of components such as millimeter-wave antennas.

A modular ruggedized protective case for a mobile communications device is disclosed. In embodiments, the protective case includes a flexible (e.g., rubberized) primary housing partially enclosing the mobile device and itself partially surrounded or enclosed by a rigid secondary housing. The secondary housing includes port protectors for concealing or shielding connector ports (e.g., USB, HDMI, AC, other like power/data inputs) of the mobile device. The protective case includes an adapter for a type cover keyboard, e.g., capable of partially covering the display surface of the mobile device when closed and serving as a keyboard or other input device when opened; the type cover adapter attached to a connection port and provides for transmission of control input from the type cover to the mobile device when the mobile device is enclosed in the protective case.

SCSP is a basic mobile phone with added feature . . . SOLAR CHARGING MODE. For when needing or wanting to charge device during daylight hours. Eliminates having to use “already existing” built-in charging port when no source of electrical power is available or nearby. Example use: When enjoying out-door activities such as fishing, hiking, exercising or just normal everyday device use. Also convenient when out with family and/or friends at an Amusement Park, Zoo, Baseball game or at the Beach; things of that nature. Device will have same normal functions, power ON/OFF button, volume UP/DOWN buttons, “Bixby button” (optional). Headphone port, charging port “for night-time use”. Reset port, and S-Pen “stylus pen” (optional). Camera(s), light, fingerprint sensor and speakerphone. Added feature will be the solar screen/glass/film built-in on the front and back of device. Included is Safety Automatic “shut-off” built-in so device will not over charge, and is Water Proof. How to operate Solar Charge/Charging is either by touch screen “just like turning on/off flashlight on phone” and a ON/OFF solar charge button located directly underneath device ON/OFF button that can be pressed and Solar Charge option will be displayed on device “front” screen. I Ramon Flores Jr. claim to be the inventor of the SCSP (Self Charging Solar Phone).

There is disclosed a mobile terminal including a case comprising an electric control unit in which electronic components are loaded; a display unit coupled to a front surface of the case; a frame coupled to the case and supporting a rear surface of the display unit, the frame comprising a metallic material; a mainboard loaded in the case; a drive chip loaded in the mainboard; a shield can covering components loaded in the mainboard, the shied comprising a hole formed, corresponding to the drive chip; a thermal conductivity sheet comprising one surface in contact with a top surface of the drive chip and the other surface in contact with an inner surface of the frame; and a flexible material insertedly filling in a space formed between the thermal conductivity sheet and the frame, so that the heat generated in the drive chip of the mobile terminal may be effectively emitted and that only the portion of the mobile terminal, where the drive chip is loaded, may be prevented from being heated when the user is using the mobile terminal and the other components may be prevented from being damaged by the heat.

The present invention provides a terminal control method and a terminal, and relates to the field of electronic devices. The method includes when a magnetic field sensed by a Hall device of a terminal in a standby state is less than or equal to a first preset threshold, activating a sensor of the terminal, where the Hall device is configured to sense a magnetic field generated by a magnet in a protective case of the terminal. The method also includes obtaining, by using detection data of the sensor, whether the terminal is obstructed, and maintaining the standby state of the terminal when it is obtained that the terminal is obstructed. The method and the terminal provided in the present invention are applied to the terminal.

Provided is a portable electronic device with an embedded electric shock protection function. A portable electronic device with an embedded electric shock protection function according to an exemplary embodiment of the present invention comprises: a circuit board; a camera module mounted on the circuit board; a conductive cover disposed to cover a part of an upper side of the camera module; a conductive connecting part mounted on the circuit board and configured to come into electrical contact with the conductive cover; and an electric shock protection element mounted on the circuit board to be connected in series to the conductive connecting part and configured to pass static electricity introduced from the conductive cover and block a leakage current of an external power source introduced into a ground of the circuit board.

In particular embodiments, one or more notifications are presented on a screen of a personal computing device while the personal computing device is in a locked state. Entry of one or more user responses may be detected on the personal computing device while still in the locked state. Each user response may be associated with at least one notification. An authorization event associated with the personal computing device may be detected, thereby unlocking the personal computing device. The one or more user responses on the personal computing device may then be presented to the user for confirmation. Once user confirmation is received, confirmed user responses may then be published.

In exemplary implementations of this invention, a shape controller controls the shape of a bladder as the bladder inflates. The shape controller includes a first set of regions and a second set of regions. The second set of regions is more flexible than the first set of regions. The shape controller is embedded within, or adjacent to, a wall of the bladder. When the bladder is inflated, the overall shape of the bladder bends in areas adjacent to the more flexible regions of the shape controller. For example, the shape controller may comprise paper and the more flexible regions may comprise creases in the paper. Or, for example, the more flexible regions may comprise notches or indentations. In some implementations of this invention, a multi-state shape display changes shape as it inflates, with additional bumps forming as pressure in the display increases.

A piezoelectric cooling system and method for driving the cooling system are described. The piezoelectric cooling system includes a first piezoelectric cooling element and a second piezoelectric cooling element. The first piezoelectric cooling element is configured to direct a fluid toward a surface of a heat-generating structure. The second piezoelectric cooling element is configured to direct the fluid to an outlet area after heat has been transferred to the fluid by the heat-generating structure.