According to examples, an apparatus may include a processor and a non-transitory computer readable medium that the processor may execute to initiate a testing process of the apparatus following a boot up of the apparatus, in which a popup message is displayed on the apparatus following the boot up and the popup message blocks performance of the testing process and in which the apparatus is to enter into a lock mode following the popup message being displayed. While the apparatus is in the lock mode, the apparatus may be caused to emerge from the lock mode, in which emergence from the lock mode is to dismiss the popup message from being displayed on the apparatus. In addition, execution of the testing process of the apparatus may be continued following dismissal of the popup message.

Provided is an electronic device. The electronic device may include a housing; a first printed circuit board (PCB) disposed in an internal space of the housing and including a plurality of first conductive terminals; a second PCB arranged parallel to the first PCB in the internal space, and including a plurality of second conductive terminals; and an interposer disposed between the first PCB and the second PCB to electrically connect the first PCB and the second PCB, the interposer including: a dielectric substrate including a first substrate surface facing the first PCB, a second substrate surface facing the second PCB, and a substrate side surface surrounding a space between the first substrate surface and the second substrate surface; a plurality of conductive vias formed to penetrate from the first substrate surface of the dielectric substrate to the second substrate surface, and electrically connecting the plurality of first conductive terminals to the plurality of second conductive terminals; and a first conductive pattern formed from at least a portion of the substrate side surface to the first PCB, wherein the first conductive pattern may be electrically connected to a first conductive pad formed on the first PCB and electrically connected to the at least one first electrical element.

There are provided systems and methods for mobile device diagnostics and provisioning, whereby connections are effectuated to communicate directly with hardware of mobile devices to perform diagnostics and other functions such as device erasure without the need to first install an app on the mobile device. In this manner, information such as detailed product identification, vendor identification, and diagnostic information may be quickly obtained from the mobile device, and diagnostics and erasure undertaken to return a previously owned device into the stream of commerce in an efficient manner.

The disclosure provides a method for reducing radiation and a mobile terminal. The method comprises: detecting whether a current operating mode of the mobile terminal is a voice call mode or a data communication mode; and if the current operating mode of the mobile terminal is the voice call mode, transmitting by an AP side a preset first AT command to a modem to control the modem to restore a maximum transmit power for normal operation; if the current operating mode of the mobile terminal is the data communication mode, transmitting by the AP side a preset second AT command to the modem to control the modem to reduce the maximum transmit power.

Disclosed is a double-path switching TX power detection circuit. A first detection module is separately connected to a power supply, a first radio frequency connector, and a second radio frequency connector; a second detection unit is connected to the second radio frequency connector; the first detection module and the second detection module control a current path of the power supply according to access states of the first radio frequency connector and the second radio frequency connector, respectively; the first detection module outputs a corresponding detection level signal, to determine whether a switching TX power function is enabled or disabled.

Disclosed is a double-path switching TX power detection circuit. A first detection module is separately connected to a power supply, a first radio frequency connector, and a second radio frequency connector; a second detection unit is connected to the second radio frequency connector; the first detection module and the second detection module control a current path of the power supply according to access states of the first radio frequency connector and the second radio frequency connector, respectively; the first detection module outputs a corresponding detection level signal, to determine whether a switching TX power function is enabled or disabled.

The disclosed technology includes a health engine that monitors and modifies customer-premises equipment (CPE) devices. The health engine can detect patterns in CPE device behavior, identify problems with CPE devices, and adjust CPE device configurations proactively or reactively to address problems or prevent problems. In some implementations, the health engine can instruct a CPE device or gateway to restart, update its software or firmware, notify a user of the CPE device of an unhealthy behavior pattern in a CPE device. The health engine can modify a CPE device prior to a user using the device or when the CPE device is inactive.

The disclosed technology includes a health engine that monitors and modifies customer-premises equipment (CPE) devices. The health engine can detect patterns in CPE device behavior, identify problems with CPE devices, and adjust CPE device configurations proactively or reactively to address problems or prevent problems. In some implementations, the health engine can instruct a CPE device or gateway to restart, update its software or firmware, notify a user of the CPE device of an unhealthy behavior pattern in a CPE device. The health engine can modify a CPE device prior to a user using the device or when the CPE device is inactive.

A location engine that estimates the barometric pressure measurement bias of a wireless terminal, resulting in an improved estimate of elevation of the wireless terminal. The location engine generates an estimate of measurement bias by comparing the barometric pressure measured by the wireless terminal while at that elevation and the barometric pressure that corresponds to an estimated elevation of the wireless terminal when it made the pressure measurement (i.e., the expected pressure). The estimated elevation is based on an inferred above-ground height and the local terrain elevation, and the expected pressure is based on the measurement of barometric pressure at the pressure reference and the estimated elevation. The location engine infers the height based on various techniques disclosed herein. The location engine can use the measurement bias to adjust subsequent pressure measurements reported by the wireless terminal, in order to generate an improved estimate of elevation of the wireless terminal.

A system includes a customer premises equipment (CPE) testing platform, a CPE testing rack, enclosures, and wireless components. The CPE testing rack is communicatively connected to the CPE testing platform and receptive to communication with wireless CPE devices. The enclosures are communicatively connected to the CPE testing rack. Each enclosure has wireless shielding to reduce outside wireless interference from entering the enclosure and to reduce wireless signals within the enclosure from exiting the enclosure. Each enclosure is receptive to installation therein a corresponding wireless CPE device. The wireless components are communicatively connected to the CPE testing platform. Each wireless component is mounted within a corresponding enclosure to wirelessly communicate with the corresponding wireless CPE device installed within the corresponding enclosure.