Abstract: A control method of a driving mechanism is provided, including: the driving mechanism provides a first electrical signal from a control assembly to the driving mechanism to move the movable portion into an initial position relative to the fixed portion, wherein the control assembly includes a control unit and a position sensing unit; the status signal of an inertia sensing unit is read; the control unit sends the status signal to the control unit to calculate a target position; the control unit provides a second electrical signal to the driving assembly according to the target position for driving the driving assembly; a position signal is sent from the position sensing unit to the control unit; the control unit provides a third electric signal to the driving assembly to drive the driving assembly according the position signal.

Abstract: Herein disclosed are a method and a test probe for testing an electrical component. The electrical component comprises at least a first electrode and a second electrode. The method comprises the following steps: covering the first electrode with a first conducting flexible layer; driving a first electrode contact to electrically connect a first end of the first electrode contact with the first electrode via the first conducting flexible layer; covering the second electrode with a second conducting flexible layer; and driving a second electrode contact to electrically connect a second end of the second electrode contact with the second electrode via the second conducting flexible layer. The first conducting flexible layer is an anisotropic conductive film.

Abstract: Herein disclosed are a method and a test probe for testing an electrical component. The electrical component comprises at least a first electrode and a second electrode. The method comprises the following steps: covering the first electrode with a first conducting flexible layer; driving a first electrode contact to electrically connect a first end of the first electrode contact with the first electrode via the first conducting flexible layer; covering the second electrode with a second conducting flexible layer; and driving a second electrode contact to electrically connect a second end of the second electrode contact with the second electrode via the second conducting flexible layer. The first conducting flexible layer is an anisotropic conductive film.

Abstract: A communication device of handling a public land mobile network (PLMN) selection in a roaming network comprises a storage unit for storing instructions and a processing means coupled to the storage unit. The processing means is configured to execute the instructions stored in the storage unit. The instructions comprise determining that the communication device is roaming; selecting a preferred roaming PLMN with a preferred roaming PLMN ID to camp on, if the preferred roaming PLMN ID stored in a subscriber identity module (SIM) of the communication device; and selecting a first roaming PLMN with a first roaming PLMN ID to camp on, if the preferred roaming PLMN ID is not stored in the SIM of the communication device, or the communication device does not find the preferred roaming PLMN and the first roaming PLMN ID is associated with a first home PLMN ID of the communication device.

Abstract: A solar cell testing system includes a multifunctional testing light source, a measuring unit, and an arithmetic unit. The multifunctional testing light source is configured to be switched to output a simulated solar light to a solar cell or asynchronously output a plurality of narrowband lights to the solar cell. The measuring unit is coupled to the solar cell and measures the solar cell's response to the simulated solar light and response to the asynchronously outputted narrowband lights. The arithmetic unit is coupled to the multifunctional testing light source and the measuring unit; it determines the solar cell's conversion efficiency and spectral response based on the solar cell's response to the simulated solar light and response to the asynchronously outputted narrowband lights.

Abstract: A solar cell testing system includes a multifunctional testing light source, a measuring unit, and an arithmetic unit. The multifunctional testing light source is configured to be switched to output a simulated solar light to a solar cell or asynchronously output a plurality of narrowband lights to the solar cell. The measuring unit is coupled to the solar cell and measures the solar cell's response to the simulated solar light and response to the asynchronously outputted narrowband lights. The arithmetic unit is coupled to the multifunctional testing light source and the measuring unit; it determines the solar cell's conversion efficiency and spectral response based on the solar cell's response to the simulated solar light and response to the asynchronously outputted narrowband lights.

Abstract: The invention employs a group of LED devices as a light source for emitting light with different wavelengths towards the solar cell under test. A set of test signal data composed of mutually orthogonal test signals are used to power the LED devices to emit light. The solar cell, upon receiving light from the LED devices powered by the test signal data, generates detected values which are in turn converted into electric signals. A processor device is then used to separate component signals contributed by the respective LED devices from the signals and compare the component signals to the output power level corresponding to the test signal data and/or to the optical energy levels radiated from the respective LED devices, thereby obtaining the spectral response of the solar cell to the different wavelengths of light.

Abstract: A sunlight simulator and solar cell measuring device consisting of detecting device is disclosed, in which the housing is a closed space consisting of an opening gate, the closed space is internally installed with a light source which is used to emit a light toward the opening gate, and a splitting unit is installed on the travelling path of the light for dividing the light into a first light-beam and a second light-beam, herein the first light-beam is projected onto the solar cell under measurement located at the opening gate as a solar cell measuring device; in addition, a detecting device is installed on the travelling path of the second light-beam for receiving the second light-beam, and then a signal can be outputted by the detecting device in order to monitor the irradiation variation of the light emitted by the light source, thus ensuring the precision of the solar cell measurement.