Abstract: The present disclosure discloses a light source module and an illuminating device. The light source module and the device include adjusting the peak wavelength, the peak intensity and the chromaticity coordinate of the blue light, the red light and the yellow-green light in the irradiation light emitted by the light source module to be within the preset ranges, respectively.

Abstract: The present disclosure discloses a smart lighting system and a control method for the smart lighting system. The smart lighting system includes: an environment acquisition module being configured to acquire environment information and at least one lighting module, and where the environment acquisition module includes: a color detection unit configured to acquire color information in an environment; an auxiliary detection unit configured to acquire auxiliary information in the environment, wherein the environment information is determined by using the color information and/or the auxiliary information; an operational unit and a control unit configured to determine a control signal according to the environment information; and where the at least one lighting module includes: a driving unit configured to determine a driving signal according to the control signal; and at least one light source configured to receive the driving signal and emit light according to the driving signal.

Abstract: Embodiments of the present disclosure disclose an illuminating device, a control method thereof and a control system thereof, which can acquire the color of an illuminated object and adjust irradiating light emitted by the illuminating device according to the color of the object. The control method includes switching on the illuminating device to project initial detection light to an illuminated object, acquiring initial reflected light of the illuminated object, obtaining an initial color of the illuminated object according to the initial reflected light, switching off the illuminating device projecting the initial detection light to the illuminated object, acquiring an environment color of an environment provided with the illuminating device, correcting the initial color according to the environment color to obtain a corrected color, acquiring target irradiating light according to the corrected color, and controlling the illuminating device to project the target irradiating light to the illuminated object.

Abstract: The present disclosure discloses a smart lighting system and a control method for the smart lighting system. The smart lighting system includes: an environment acquisition module being configured to acquire environment information and at least one lighting module, and where the environment acquisition module includes: a color detection unit configured to acquire color information in an environment; an auxiliary detection unit configured to acquire auxiliary information in the environment, wherein the environment information is determined by using the color information and/or the auxiliary information; an operational unit and a control unit configured to determine a control signal according to the environment information; and where the at least one lighting module includes: a driving unit configured to determine a driving signal according to the control signal; and at least one light source configured to receive the driving signal and emit light according to the driving signal.

Abstract: Embodiments of the present disclosure disclose an illuminating device, a control method thereof and a control system thereof, which can precisely adjust the color of irradiating light according to the color of an object. In the embodiment of the present disclosure, a next detection light is obtained according to reflected light of a previous detection light. When the color difference of reflected light of the previous detection light and the next detection light is less than a preset color difference range, the illuminating device is controlled to project the next detection light to an illuminated object.

Abstract: An electrowetting device and a method of electrowetting may be provided. An electrode may be provided. The electrode has a graphene layer having a first side and a second side that opposes the first side. The electrode also has a dielectric layer disposed on the first side of the graphene layer. A liquid droplet is disposed on the dielectric layer. A voltage is applied through the droplet and the electrode. A contact angle between the dielectric layer and an edge of the liquid droplet contacting the dielectric layer changes in response to the applied voltage.

Abstract: A graphene biosensor is formed on an electrically insulating substrate with a single-layer graphene sheet arranged between two metallic electrodes. The graphene sheet is in electrical contact with the metallic electrodes. The graphene sheet has perforations creating edges in the graphene sheet. The perforations may be holes on a micrometer scale or in a nanometer scale. The biosensor can be configured as an ISFET. The graphene sheet may comprise affinity probes immobilized on the edges for attaching specific molecules to the graphene sheet. Several graphene sheets may be arranged in a microarray with different affinity probes on different graphene sheets. The sensor may also be arranged on the distal end of a catheter for in situ measurements in a body vessel.

Abstract: An electrowetting device and a method of electrowetting may be provided. An electrode may be provided. The electrode has a graphene layer having a first side and a second side that opposes the first side. The electrode also has a dielectric layer disposed on the first side of the graphene layer. A liquid droplet is disposed on the dielectric layer. A voltage is applied through the droplet and the electrode. A contact angle between the dielectric layer and an edge of the liquid droplet contacting the dielectric layer changes in response to the applied voltage.