Abstract: A control device for a servo motor system is provided. The control device includes a segment parameter storage circuit, a velocity superposing circuit, a velocity transferring circuit and a pulse comparison circuit. The segment parameter storage circuit is electrically connected with the velocity superposing circuit and the pulse comparison circuit. The velocity transferring circuit is connected between the velocity superposing circuit and the pulse comparison circuit. The velocity superposing circuit updates a present velocity value according to a target velocity value and an increment. The velocity transferring circuit generates a PWM signal according to the present velocity value. The pulse comparison circuit transfers the PWM signal into a signal of a command pulse wave group and judges whether a pulse number of the PWM signal reaches a predetermined pulse number.

Abstract: A control device for a servo motor system is provided. The control device includes a segment parameter storage circuit, a velocity superposing circuit, a velocity transferring circuit and a pulse comparison circuit. The segment parameter storage circuit is electrically connected with the velocity superposing circuit and the pulse comparison circuit. The velocity transferring circuit is connected between the velocity superposing circuit and the pulse comparison circuit. The velocity superposing circuit updates a present velocity value according to a target velocity value and an increment. The velocity transferring circuit generates a PWM signal according to the present velocity value. The pulse comparison circuit transfers the PWM signal into a signal of a command pulse wave group and judges whether a pulse number of the PWM signal reaches a predetermined pulse number.

Abstract: A pulse processor includes a phase/pulse width sampler, a first calculator, a second calculator, a latching device, and a pulse width modulator. The phase/pulse width sampler generates an input direction signal, an input phase number and an input pulse width number according to a first signal and a second signal of the command pulse group. The first calculator is used for multiplying the input phase number by P/Q, thereby generating a target phase number, wherein P and Q are positive integers. The second calculator is used for multiplying the input pulse width number by Q/P, thereby generating a target pulse width number. The latching device receives the input direction signal and outputs a target direction signal. The pulse width modulator receives the target direction signal, the target phase number and the target pulse width number, and outputs a transferred pulse group.

Abstract: A pulse processor includes a phase/pulse width sampler, a first calculator, a second calculator, a latching device, and a pulse width modulator. The phase/pulse width sampler generates an input direction signal, an input phase number and an input pulse width number according to a first signal and a second signal of the command pulse group. The first calculator is used for multiplying the input phase number by P/Q, thereby generating a target phase number, wherein P and Q are positive integers. The second calculator is used for multiplying the input pulse width number by Q/P, thereby generating a target pulse width number. The latching device receives the input direction signal and outputs a target direction signal. The pulse width modulator receives the target direction signal, the target phase number and the target pulse width number, and outputs a transferred pulse group.

Abstract: A three-piece optical pickup lens includes, sequentially from an object side to an image side of the three-piece optical pickup lens along an optical axis thereof, an aperture stop, a first lens, a second lens, and a third lens. The first lens is a meniscus lens of positive refractive power. The second lens has an object side and an image side, on each of which at least one inflection point is formed at a position located between a center and a periphery of the second lens. The third lens has an object side and an image side, on each of which at least one inflection point is formed at a position located between a center and a periphery of the third lens, and has positive refractive power at paraxial region of optical axis.

Abstract: An imaging lens system with two lenses is provided. The imaging lens system with two lenses, along an optical axis from an object side to an image side, comprises an aperture stop; a first lens having positive refractive power and being a biconvex lens; and a second lens having negative refractive power and being a meniscus lens with a concave surface on the object side and a convex surface on the image side.

Abstract: An imaging lens system with two lenses is provided. The imaging lens system with two lenses, along an optical axis from an object side to an image side, comprises an aperture stop; a first lens having positive refractive power and being a biconvex lens; and a second lens having negative refractive power and being a meniscus lens with a concave surface on the object side and a convex surface on the image side.

Abstract: A three-piece optical pickup lens includes, sequentially from an object side to an image side of the three-piece optical pickup lens along an optical axis thereof, an aperture stop, a first lens, a second lens, and a third lens. The first lens is a meniscus lens of positive refractive power. The second lens has an object side and an image side, on each of which at least one inflection point is formed at a position located between a center and a periphery of the second lens. The third lens has an object side and an image side, on each of which at least one inflection point is formed at a position located between a center and a periphery of the third lens, and has positive refractive power at paraxial region of optical axis.

Abstract: An imaging lens system with two lenses is provided. The imaging lens system with two lenses, along an optical axis from an object side to an image side, includes an aperture stop; a first lens having positive refractive power and being a plano-convex lens with a convex surface on the image side; and a second lens having negative refractive power and being a meniscus lens with a concave surface on the object side and a convex surface on the image side.

Abstract: Along an optical axis from an object side to an image side, a short overall length imaging lens system with four lenses includes a first lens with positive power that is a meniscus spherical/aspherical lens with a convex surface on the object side; an aperture stop; a second lens with negative power that is a meniscus aspherical lens with a convex surface facing the object side; a third lens with positive power that is a meniscus aspherical lens and a concave surface on the object side; and a fourth lens with negative power that is a biconcave aspherical lens with at least one inflection point in the effective diameter range of the optical surface on the image side so as to make the positive power gradually change into negative power. Moreover, the imaging lens system satisfies the following conditions: 0.25 ? d ? ? 2 + d ? ? 4 + d ? ? 6 f s ? 0.40 ; 0.8 ? Y · tan ? ( ? ) Bf ? 2.

Abstract: A rain sensor mounted on a windshield of a vehicle comprises: a housing having an opening, at least an emitter disposed in the housing and used for emitting light beams, a coupler, and an optical detector. The coupler connecting and covering the opening of the housing, comprises: at least a collimator receiving and collimating the light beams into collimated light beams; and at least a groove having a deflection surface to reflect the collimated light beams that passes through the collimator and is incident to the deflection surface at an incident angle ? to the windshield. The optical detector disposed in the housing is used for receiving the collimated light beams reflected by the windshield and generating electrical signals. The present invention characterized in that the incident angle ? satisfies the following condition: 1.27<n*sin ?<1.52, wherein n is refractive index of the coupler.

Abstract: A two-element f-? lens used for a micro-electro mechanical system (MEMS) laser scanning unit includes a first lens and a second lens, the first lens is a positive refraction meniscus lens of which the convex surface is disposed on a side of a MEMS mirror, the second lens is a positive refraction meniscus lens of which the convex surface is disposed on the side of the MEMS mirror, at least one optical surface is an Aspherical surface in both main scanning direction and sub scanning direction, and satisfies special optical conditions. The two-element f-? lens corrects the nonlinear relationship between scanned angle and time into the linear relationship between image spot distances and time. The two-element f-? lens focuses the scan light to the target in the main scanning and sub scanning directions, such that the purpose of the scanning linearity effect and the high resolution scanning can be achieved.

Abstract: A two-element f-? lens used for a micro-electro mechanical system (MEMS) laser scanning unit includes a first lens and a second lens, the first lens is a positive refraction meniscus lens of which the convex surface is disposed on a side of a MEMS mirror, the second lens is a positive refraction meniscus lens of which the concave surface is disposed on the side of the MEMS mirror, at least one optical surface is an Aspherical surface in both main scanning direction and sub scanning direction, and satisfies special optical conditions. The two-element f-? lens corrects the nonlinear relationship between scanned angle and time into the linear relationship between image spot distances and time. The two-element f-? lens focuses the scan light to the target in the main scanning and sun scanning directions, such that the purpose of the scanning linearity effect and the high resolution scanning can be achieved.

Abstract: An miniature three-piece optical imaging lens with short back focal length, along an optical axis from the object side to the image side including: a first lens of positive refractive power that is a meniscus aspherical lens having a convex surface on the object side, an aperture stop, a second lens of negative refractive power that is a meniscus aspherical lens having a convex surface on the image side, a third lens of negative refractive power that is an aspherical lens whose center is on the optical axis, while on the lens center the convex surface is on the object side and the concave surface is on the image side. Moreover, from the center of the third lens element toward the edge, the refractive power changes from negative power, through an inflection point, to positive power. Furthermore, the optical imaging lens further satisfies conditions: 0.25 ? bf TL ? 0.4 wherein bf is back focal length, TL is total distance on the optical axis from the object side of the first lens to the image plane.

Abstract: The present invention discloses an aspherical LED angular optical lens for central distribution patterns and an LED assembly using the same. The optical lens comprises a concave surface on a source side and a convex surface on an project side. The LED assembly comprising the optical lens can accumulate light emitted from the LED die and generate a peak intensity of the central angular circle distribution pattern which is greater than 72° and smaller than 108°. The present invention only uses a single optical lens capable of accumulating light and forming a required distribution pattern to satisfy the requirement of a luminous flux ratio greater than 85% and the requirement of an illumination, a flash light of a cell phone or a flash light of a camera.

Abstract: Along an optical axis from an object side to an image side, a short overall length imaging lens system with four lenses includes a first lens with positive power that is a meniscus spherical/aspherical lens with a convex surface on the object side; an aperture stop; a second lens with negative power that is a meniscus aspherical lens with a convex surface facing the object side; a third lens with positive power that is a meniscus aspherical lens and a concave surface on the object side; and a fourth lens with negative power that is a biconcave aspherical lens with at least one inflection point in the effective diameter range of the optical surface on the image side so as to make the positive power gradually change into negative power. Moreover, the imaging lens system satisfies the following conditions: 0.25 ? d ? ? 2 + d ? ? 4 + d ? ? 6 f s ? 0.40 ; 0.8 ? Y · tan ? ( ? ) Bf ? 2.

Abstract: A wide-angle imaging lens system with two positive lenses is revealed. The imaging lens system includes a first lens with positive refractive power that is a biconvex aspherical lens and a second lens having positive refractive power that is a meniscus lens with concave surface facing the image side. In the concave surface of the second lens, the effective diameter range from the lens center to the edge includes at least one inflection point that changes the refractive power of the second lens from positive to negative. Moreover, the following conditions are satisfied by the imaging lens system: 2 ? ? ? 70 ° ; 0.3 ? bf TL ? 0.6 wherein bf is back focal length, TL is distance from an aperture stop to an image plane, and 2? is maximum field angle. Thus, the imaging lens system of the present invention has wide angle effects, short back focal length, and reduced overall length.

Abstract: A single-piece optical imaging lens and an array thereof are revealed. The optical imaging lens includes a lens and an image sensor arranged at an image-side surface of the lens. The lens includes an object-side surface, an image-side surface, an optical area, and a non-optical area. The optical imaging lens satisfies the following conditions: BFL/TTL=0.55˜0.81, OH/OD=1.0˜3.6. TTL is total length from the object-side surface of the lens on the optical axis to the image sensor. BFL is back focal length of the imaging lens. OD is the distance between an object on the optical axis and the object-side surface of the lens. OH is the largest height of an object vertical to the optical axis of OD. The single-piece optical imaging lens array is used to produce a plurality of single-piece optical imaging lenses by cutting.

Abstract: The present invention discloses an aspherical LED angular optical lens for narrow distribution patterns and an LED assembly using the same. The optical lens comprises a concave surface on a source side and a convex surface on a project side. The LED assembly comprising the optical lens can accumulate light emitted from the LED die and generate a peak intensity of the narrow angular circle distribution pattern which is greater than 15° and smaller than 30°. The present invention only uses a single optical lens capable of accumulating light and forming a required distribution pattern to satisfy the requirement of a luminous flux ratio greater than 85% and the requirement of an illumination, a flash light of a cell phone or a flash light of a camera.

Abstract: The present invention discloses an aspherical LED angular optical lens for wide distribution patterns and an LED assembly using the same. The optical lens comprises a concave surface on a source side and a convex surface on a project side. The LED assembly comprising the optical lens can accumulate light emitted from the LED die and generate a peak intensity of the wide angular circle distribution pattern which is greater than 120° and smaller than 180°. The present invention only uses a single optical lens capable of accumulating light and forming a required distribution pattern to satisfy the requirement of a luminous flux ratio greater than 85% and the requirement of an illumination, a flash light of a cell phone or a flash light of a camera.