Abstract: A digital light processing projector includes a light emitting diode (LED), a laser, a rotatable optical element, a reflector, a first filter, a second filter, a digital micro-mirror device (DMD), and a projection lens. The LED and the laser respectively emit a first and second homogeneous lights. The rotatable optical element converts a first portion of the second homogeneous light to a third homogeneous light, reflects the third homogeneous light, and transmits a second portion of the second homogeneous light. The reflector reflects the third homogeneous light. The first filter transmits the first homogeneous light, and reflects the second portion to the second filter. The second filter transmits the second portion and the first homogeneous light, and reflects the third homogeneous light to the DMD. The DMD modulates the first, second and third homogeneous lights to obtain optical images. The projection lens projects the optical images on a screen.

Abstract: An optical-electrical conversion module includes a circuit board, a planar optical waveguide formed on the circuit board, two first lenses and two second lenses mounted above the planar optical waveguide, a base plate electrically connected to the circuit board, and an optical signal emitting member and an optical signal receiving member mounted on the base plate. The planar optical waveguide forms two inclined surfaces. The base plate is positioned above the second lenses. Optical signals are reflected by the inclined surface, and are transmitted to the optical signal receiving member. The optical signal receiving member converts the optical signals to electrical signals to transmit to the circuit board. Electrical signals of the circuit board are converted to optical signals via the optical signal emitting member, and then are transmitted to the planar optical waveguide. The present disclosure further provides an optical transmission connecting assembly using the optical-electrical conversion module.

Abstract: A method for testing an LED die includes the following steps: setting control parameters; driving the LED die to emit light by applying an electric current to the LED die under the control parameters; detecting the wavelength of the light emitted by the LED die; and determining whether the LED die meets the predetermined electro-optical properties, based upon the relationship between the control parameters and the wavelength.

Abstract: An optical transmission assembly includes a first optical-electrical conversion module, a second optical-electrical conversion module and a optical waveguide connecting the first and the second optical-electrical conversion modules for transmitting optical signals. The first optical-electrical conversion module and the second optical-electrical conversion module each includes a circuit board, an optical signal emitting member, an optical signal receiving member, and a cover. The optical signal emitting member and the optical signal receiving member are mounted on the circuit board. The circuit board defines a positioning groove. The cover includes a latching portion latching with the positioning groove. The cover defines a latching groove. The optical waveguide includes a inserting portion to latch with the latching groove. The present disclosure further provides an optical-electrical conversion module.

Abstract: An optical fiber connecting assembly includes two optical-electrical conversion modules and a plurality of optical fibers for connecting with the optical-electrical conversion modules. The optical-electrical conversion module includes a circuit board, an optical signal receiving member and an optical signal emitting member mounted on the circuit board, a cover, and several lenses. The cover covers the optical signal receiving member and the optical signal emitting member, and is fixed with the circuit board with glue. A connecting surface of the cover facing towards the circuit board defines a glue-overflow hole, for receiving excessive glue. The first lenses are mounted on the cover, and couple with the optical signal receiving member and the optical signal emitting member, respectively. Each end of the optical fibers inserted into the cover and couple with the first lenses of one corresponding optical-electrical conversion module.

Abstract: A testing device includes a laser source, a current testing device, and a processor. The processor includes a user interface, a control unit, a calculation unit, and a data generation unit. The user interface receives user inputs to determine control parameters. The control unit controls the laser source to emit a laser beam on a photoelectric conversion die according to the control parameters. The laser beam has an optical output power value P. The control unit also controls the current testing device to measure a current value I output by the photoelectric conversion die after the laser beam irradiating on the photoelectric conversion die. The calculation unit calculates a photoelectric conversion efficiency F according to the formula: F=P/I. The data generation unit processes the photoelectric conversion efficiency F which indicates the electro-optical property of the photoelectric conversion die.

Abstract: An optical-electrical converting device includes a first substrate, a planar waveguide, a bearing member, a reflective member, a second substrate, a laser beam emitting member, and a driving chip. The first substrate includes a supporting surface. The planar waveguide is supported on the supporting surface, and includes a laser beam incident surface. The bearing member is supported on the supporting surface, and includes a sloped surface aligned with the laser beam incident surface. The reflective member is positioned on the sloped surface. The second substrate is supported on both the bearing member and the planar waveguide. The second substrate comprising a lower surface and an upper surface. The laser beam emitting member is positioned on the lower surface, and includes a laser beam emitting surface aligned with the reflective member. The driving chip is positioned on the upper surface, and is electrically connected to the laser beam emitting member.

Abstract: An exemplary assembly device includes a first loading plate, a movable pole, a driving element, a first camera module, a transparent fetching element, a first processor, a first adjusting element, and a controller. The first loading plate loads a first workpiece. The movable pole is positioned above the first loading plate. The driving element drives the movable pole. The first camera module is positioned on the movable pole, and captures an image of the first workpiece to obtain a first pre-compared image. The fetching element is positioned on the movable pole. The first processor determines whether the first workpiece deviates from a standard position through comparing the first pre-compared image with a first standard image. The first adjusting element adjusts the first workpiece to the standard position. The controller controls the fetching element and the driving element cooperatively to assemble the first workpiece to a second workpiece.

Abstract: An automatic braking system includes a laser module, an image capturing module, a braking module, and a control module. The laser module emits a laser beam along a forward direction of a vehicle and receives the reflected laser beam. The image capturing module captures a road image in front of the vehicle. The braking module slows the vehicle. The control module is electrically connected to the laser module, the image capturing module, and the braking module. When an intensity of the reflected laser beam is greater than a pre-set value, the image capturing module is controlled by the control module to captures the road image. When the control module decides that there are human characteristics in the road image, the control module activates the braking module.

Abstract: In a testing method for an LD, an LD die is held. Then, electric current increasing with a fixed increment and having a sequence of current values is supplied to the LD die to drive the LD die to emit light and a sequence of voltage values across the LD die and corresponding to the sequence of current values, respectively, is metered. A sequence of power values corresponding to the sequence of current values, respectively, is also metered. Next, an electro-optical property of the LD die is determined according to the sequence of current values, the sequence of voltage values, and the sequence of power values. Finally, if the LD die is determined to be qualified based upon the electro-optical property of the LD die, the LD die is packaged into the LD.

Abstract: In a testing method for a laser diode (LD) die, a sequence of current values of electric current increasing with a fixed increment is calculated. Then, control parameters are obtained. The electric current is applied to the LD die according to the control parameters. A sequence of voltage values across the LD die and a sequence of power values of light emitted form the LD die are measured according to the control parameters. A table and a graph are generated using the sequence of current values, the sequence of voltage values, and the sequence of power values. Both of the table and the graph indicate an electro-optical property of the LD die. Next, whether the LD die is qualified is determined based upon the table, the graph, and a predetermined electro-optical property.

Abstract: A vehicle lighting device includes a body, a light source and a reflecting module. The body defines an outputting opening. The light source includes an LED. The reflecting module includes a first reflector, a second reflector and a third reflector. One part of light incident to the first reflector is firstly reflected by the first reflector, secondly reflected by the second reflector, thirdly reflected by the third reflector, and finally travels out of the body via the outputting opening. Another part of the light incident to the first reflector is firstly reflected by the first reflector, secondly reflected by the third reflector, and finally travels out of the body via the outputting opening. The rest part of the light is incident to the third reflector and then is reflected by the third reflector to travel out of the body via the outputting opening.

Abstract: A mosquito killer includes a sonar module to detect a location of a mosquito, a low-power laser gun to emit a laser beam, a first reflecting mirror, a second reflecting mirror, and a controller. The first reflecting mirror reflects the laser beam to the second reflecting mirror. The second reflecting mirror is rotatable, and the controller is configured for receiving the location of the mosquito from the sonar module and controlling the second reflecting mirror to rotate to aim the laser beam to kill the mosquito.

Abstract: A pick-and-place device for transferring and positioning a plurality of workpieces includes a transferring mechanism and a handling assembly. The handling assembly includes at least two handling heads. Each of the at least two handling heads includes a handling portion for handling the plurality of workpieces. The handling portions of the at least two handling heads have different sizes. The transferring mechanism is capable of picking one of the handling head of the at least two handling heads according to sizes of the plurality of workpieces.

Abstract: A wireless communication network system includes a signal source terminal, a user terminal, an electrical-optical conversion module, and an optical-electrical conversion module. The electrical-optical conversion module electrically connects with the signal source terminal, for receiving electrical signals sent by the signal source terminal and converting the electrical signals into optical signals. The optical-electrical conversion module electrically connects with the user terminal, for receiving the optical signals and converting the optical signals into electrical signals. The signal source terminal, the user terminal, the electrical-optical conversion module and the optical-electrical conversion module cooperatively build, define, or form a wireless optical communication network.

Abstract: The present invention discloses a method for fabricating a heat-resistant, humidity-resistant oxide-confined vertical-cavity surface-emitting laser (VCSEL) by slowing down the oxidizing rate during a VCSEL oxidation process to thereby reduce stress concentration of an oxidation layer and by preventing moisture invasion using a passivation layer disposed on a laser window. The VCSEL device thus fabricated is heat-resistant, humidity-resistant, and highly reliable. In a preferred embodiment, the oxidation process takes place at an oxidizing rate of less than 0.4 ?m/min, and the passivation layer is a SiON passivation layer.