Abstract: An optical filter configured to transmit light of a predetermined wavelength includes a substrate; a first conductive thin film that is disposed on the substrate and has apertures extending through the first conductive thin film and arranged with a period of less than the predetermined wavelength; and a second conductive thin film at least a portion of which faces the apertures so as to be separated from the apertures.

Abstract: The present invention refers to a pane construction, particularly to be used in a motor vehicle, comprising transparent panes, layers and/or foils made of glass, ceramic, plastic or organic material, which are connected in a layered manner in a laminate, wherein the pane construction has transparent infrared (=IR) filtering layer means or a IR filtering foil for filtering of infrared (IR) radiation of the sunlight impinging the pane construction.

Abstract: Regarding an optical filter comprising a light-transmitting substrate, a gradient refractive index thin film with a refractive index change in the film thickness direction formed on the substrate and an anti-reflection structure formed on the gradient refractive index thin film, the gradient refractive index thin film is formed so as to have light absorbing characteristic and a refractive index characteristic such that the refractive index change comprising plural changing points with increases and decreases of the refractive index has a tendency to reduce from the side of the substrate toward the side of the anti-reflection structure. The optical filter has excellent environmental resistance and low reflection. The optical filter can be suitably used in an imaging optical system of an optical apparatus or a display of an electronic device.

Abstract: An object of the present invention is to provide: a color material dispersion liquid which is able to form a coating film with high luminance, excellent heat resistance and excellent light resistance. Disclosed is a color material dispersion liquid comprising a color material represented by the following general formula (I), a specific dispersant, and a specific solvent, wherein molybdenum and tungsten are contained in a polyoxometalate anion in the color material, and a molar ratio between the molybdenum and the tungsten is 0.4:99.6 to 15:85: (Symbols shown in the general formula (I) are described in the Description.

Abstract: An apparatus for controlling a color of a film includes a dyeing bath to dip a washed PVA film in an aqueous iodine solution and an aqueous potassium solution and then dye the PVA film therewith, a complementary bath to dip the PVA film in an aqueous potassium solution and then dye the PVA film therewith, a device oven to dry the PVA film having the oriented iodine and potassium, a 4-stage oven to dry the PVA film dried in the device oven, and a central controller to predict a color value of the polarizing film.

Abstract: Multilayer reflecting polarizing films are disclosed having increased in-plane refractive index differences between adjacent microlayers along both the pass and block axis, and having negative refractive index differences between adjacent microlayers along the thickness or z-axis. Major front and back surfaces of the film exposed to air provide a Fresnel reflectivity component to the pass axis reflectivity, and the microlayers provide a microlayer component to the pass axis reflectivity, such microlayer component preferably having a reflectivity of p-polarized light that increases with incidence angle faster than the Fresnel reflectivity component decreases so as to substantially avoid off-axis gain peaks for p-polarized light. The films preferably utilize a relatively small total number of microlayers, arranged in a single coherent stack with monotonic optical repeat unit thickness profile, and at least some microlayers preferably include polyethylene naphthalate or a copolymer thereof.

Abstract: An embodiment of an optical film includes: a polarization layer; a first phase retardation layer; a second phase retardation layer; and a light blocking layer disposed between the first phase retardation layer and the second phase retardation layer and extending along a circumference of the second phase retardation layer, wherein the polarization layer is disposed on the first phase retardation, the first phase retardation layer is disposed on the second phase retardation layer, an in-plane retardation value of the first phase retardation layer at a standard wavelength of about 550 nanometers is in a range from about 240 nanometers to about 300 nanometers, and an in-plane retardation value of the second phase retardation layer at the standard wavelength is in a range from about 110 nanometers to about 160 nanometers.

Abstract: An optical-compensation film, an optical-compensation polarizing sheet and a liquid crystal display are disclosed.

Abstract: An optical device for generating a frequency comb includes an optical source and a first waveguide comprising a nonlinear optical medium operable to mix at least two input optical waves to generate a plurality of first optical waves. The optical device also includes a second waveguide concatenated to the first waveguide and characterized by a first dispersion characteristics and operable to compress the waveforms of the plurality of first optical waves and to reduce a frequency chirp introduced by the first waveguide. The optical device additionally includes a third waveguide concatenated to the second waveguide. The third waveguide comprises a nonlinear optical medium and is operable to mix the plurality of first optical waves to generate a plurality of second optical waves and to increase a total number of second optical waves with respect to a total number of first optical waves.

Abstract: An optical component has an elongate length extending between first and second ends and a width transverse to and substantially smaller than the length and extending between first and second sides. The optical component includes a refractive portion disposed between the first and second sides and extending along the length between the first and second ends, and a plurality of separate reflective portions. At least one of the plurality of separate reflective portions is spaced from the refractive portion and extending along the length between the first and second ends.

Abstract: The invention provides a backlight module including: a planar illuminant portion having a first surface and emitting light from the first surface; an optical film assembly adhered to the first surface of the planar illuminant portion and having a bottom optical film and at least an upper optical film layered above the bottom optical film; and a ring-shaped frame surrounding the planar illuminant portion and having a first extension portion extending along a direction parallel to the first surface, wherein the bottom optical film extends toward the ring-shaped frame more than the upper optical film such that the first extension portion covers at least an edge of the bottom optical film.

Abstract: The disclosure provides a display backlight unit and its light down conversion film. The light down conversion film may include a quantum-dot layer sandwiched between input substrate and an exit substrate. First and second refractive asymmetric micro-prisms are disposed on two opposite input and first exit surfaces of the input substrate, respectively. On the input surface of the input substrate, multiple arrays of the asymmetric refractive asymmetric micro-prisms preserve the large off-axis angle of incident light with first wavelength. On the first exit surface of the input substrate, multiple arrays of the refractive asymmetric micro-prisms increase the reflectance of the large incident angle light. A second exit surface of the exit substrate includes refractive symmetric micro-prisms. The refractive asymmetric micro-prisms of the input substrate and the refractive asymmetric micro-prisms of the exit substrate have rounded tips and valleys for enhancing refraction of the first light and the second light.

Abstract: A display device includes a display panel, a backlight unit outputting light to the display panel, and an optical member refracting or reflecting the light output from the backlight unit and providing the display panel with the light. The backlight unit includes a light source emitting the light, a light guide plate scattering the light emitted from the light source and irradiating the scattered light to a front surface of the backlight unit, a reflective sheet reflecting the light, which is irradiated to a rear surface of the light guide plate, to the light guide plate, a quantum dot sheet for converting the light, which is irradiated to the front surface of the light guide plate, into a white light, and a light-converting material provided on an edge portion of the reflective sheet to convert the light into the white light.

Abstract: A lighting assembly includes a light engine and a light guide. The light engine edge lights the light guide and includes a control assembly that controls light output according to one or more parameters to produce light output from the lighting assembly with a desired characteristic. Lighting assemblies are combined to form a modular lighting assembly.

Abstract: The high intensity light output of edge lighting point light sources such as LEDs may generate undesired leakage light that is optically conducted by way of a continuum of the material of a components affixing adhesive member. In accordance with present disclosure, air filled grooves or other such discontinuities are formed in the adhesive member along respective light output pathways of the respective point light sources. One corresponding embodiment comprises spaced apart LEDs mounted on an FPCB; a light guide plate (LGP) disposed adjacent to the LEDs; a main support accommodating the LEDs and the LGP; and an adhesive member formed to affix together the FPCB, the main support, and the light guide, wherein the adhesive member is patterned to define air filled grooves along respective light output pathways of the LEDs.

Abstract: A planar light source apparatus has a light guide plate, a light source arranged on a side face of the light guide plate, a mounting substrate on which the light source is mounted, and a frame body that holds the light guide plate. The frame body has a plurality of projection portions on an inner side of the frame body. The light source is arranged between the projection portions. The frame body, the mounting substrate, and the light guide plate are fixed via a fixing member. The light source has a pair of electrode terminals. The mounting substrate has a land portion on which the electrode terminals are mounted. Connection portions are provided by which the electrode terminals and the land portion are electrically connected. The projection portions have a thickness defined by a surface on the mounting substrate side and an opposite surface relative thereto.

Abstract: In an optical waveguide having plural cores including a pair of adjacent cores with an identical core structure, a minimum value D of center-center distance between the adjacent cores is 15 ?m to 60 ?m, each of the plural cores has a bent portion fixed in a radius of curvature Rb of not more than 7 mm, a bend supplementary angle of the bent portion is 58° to 90°, a height of the optical waveguide is defined as a height of not more than 10 mm, and a crosstalk of the adjacent cores is not more than 0.01.

Abstract: An apparatus includes a rigid support and a first cantilever including a first optical fiber and a first rigid ribbon. The first optical fiber and the first ribbon, together include a first neutral surface. The first optical fiber is connected to the rigid support. The first optical fiber includes at least one first wave-guiding core running parallel to the first neutral surface. Each of the at least one first wave-guiding core includes at least one first reflector. The first rigid ribbon is affixed to the first optical fiber and to said first rigid support. The apparatus further includes a first membrane surrounding the first cantilever.

Abstract: An apparatus for generating long-period gratings in an optical fiber is disclosed herein. The apparatus includes an intensity adjusting unit and a period adjusting unit that come into contact with a portion of an optical fiber where gratings will be generated. The intensity adjusting unit includes a press part configured to press the portion of the optical fiber where gratings will be generated against a grating generating unit, and an intensity adjusting mechanism configured to apply force to the press part. The period adjusting unit includes a period adjusting mechanism configured to selectively increase and decrease the length of the grating generating unit.

Abstract: The optical waveguide includes: a lower clad layer, a core layer, an upper clad layer, a substrate, and a mirror, the lower clad layer, the core layer, and the upper clad layer being sequentially laminated to the substrate, the mirror being formed on the core layer, in which the substrate has an opening, the maximum diameter of the opening is larger than that of luminous flux reflected by the mirror, and the maximum diameter of the opening is 240 ?m or less. The optical waveguide is capable of transmitting a light signal regardless of the type of the substrate, suppressing the spread of a light signal reflected from the mirror, and transmitting a light signal with a low optical transmission loss.

Abstract: An optical device includes an optical bench and two flip-chip bonded optical chips. The optical bench includes a large area slab waveguide structure which has an input facet facing the first optical chip, an output facet facing the second optical chip, and one or more curved facet which reflects the slab mode light such that the input optical mode coupled through the input facet diverges in the slab waveguide plane as it propagates, reflects at the one or more curved facets, and focuses to an output optical mode at the output facet with mode size larger than the input optical mode in the in-plane direction. During fabrication, after the first optical chip is flip-chip bonded, the location of the focused output optical mode on the output facet is determined, and then the second optical chip is flip-chip bonded based on the determined location of the output optical mode.

Abstract: The present invention relates to a semiconductor device (1) for use in at least an optical application comprising: at least an optically passive aspect (2) that is operable in substantially an optically passive mode, and at least an optically active material (3) comprising at least a material that is operable in substantially an optically active mode, wherein: the optically passive aspect (2) further comprises at least a crystalline seed layer (4), the optically active material (3) being epitaxially grown in at least a predefined structure (5) provided in the optically passive aspect (2) that extends to at least an upper surface (4?) of the crystalline seed layer (4), and the optically passive aspect (2) is structured to comprise at least a passive photonic structure (6), wherein the crystalline seed layer (4) comprises a crystalline wafer and wherein the optically active material (3) comprises at least one of: a III-V material and a II-VI material.

Abstract: An optical device that includes means for thermal stabilization and control is described. The optical device can be a ring resonator, or another device that requires accurate control of the phase of the optical signal. In an example involving an optical resonator, a thermal stabilization system includes a temperature sensor, a control circuit, and a heater local to the resonator. The temperature sensor can be a bandgap temperature sensor formed of a pair of matched p/n junctions biased in operation at different junction currents.

Abstract: A portable splicer for an optical fiber can include a first case half and second case half with respective exterior and interior surfaces, which can be hingedly attached to define a case having an interior case surface. At least two clamps for receiving the cable to be spliced and a fuser can be attached to the interior case surface. A deployed configuration for the splice can be established, wherein the first exterior and second exterior surfaces are co-planar. In the deployed configuration, the fuser is located between the two clamps and the fuser and clamps are substantially co-planar. A first channel can be formed in the first exterior surface and a second channel can be formed in the second exterior surface. A bar can be slidably disposed within one of the channels, and can be extended into the other channel to thereby fix the case halves in the deployed configuration.

Abstract: An optical fiber fusion splicer includes: a pair of right and left V-grooved stands having V-grooves for butting tips of a pair of optical fibers each other while positioning the tips of a pair of optical fibers; a pair of elastic members respectively supporting the pair of V-grooved stands and formed into the form of an elastically deformable plate; a fixed base on which the pair of elastic members is mounted, whereby the pair of V-grooved stands is fixed thereto through the pair of elastic members, and which is long in a right-left direction; and a pair of micrometers aligning the tips of the pair of optical fibers by finely moving the pair of V-grooved stands with respect to each other while elastically deforming the pair of elastic members by pressing the pair of V-grooved stands from forward and backward directions.

Abstract: Actuator systems (10) are provided for inducing one or more static deflections, such as bends, in optical waveguides (12), to alter spectral characteristics of an optical signal transmitted through the waveguide. The actuator systems (10) can include actuators (28) that deflect the waveguide (12), and a controller (40) that controls the actuators (28) so that the deflections in the waveguide (12) are tailored to produce desired spectral characteristics in the optical signal. The actuator systems (10) can be used in conjunction with, for example, a fused fiber optic coupler (12) to form a wavelength selective switch. The actuator systems (10) can be used in conjunction with other types of waveguides to form other types of optical signal processors (14).

Abstract: A method for manufacturing a polarizing splitter includes providing a substrate including a top surface; forming a ridged asymmetric Y-shaped waveguide and a base by etching the substrate from the top surface into an inner region, the base includes an upper surface paralleling with the top surface, the ridged asymmetric Y-shaped waveguide projects from the upper surface of the base, and includes an input section configured for transmitting both a transverse electric wave and a transverse magnetic wave, a first branch configured for transmitting the transverse magnetic wave only, and a second branch configured for transmitting the transverse electric wave only, the first and the second branches branch from the input section; and forming a pair of strip-shaped first electrodes on the upper surface of the base, the strip-shaped first electrodes arranged at opposite sides of the input section and parallel with a central axis of the input section.

Abstract: A high density optical fiber switch module comprises a box body whose front end is provided with several optical fiber adapters, the top surface or bottom surface of the optical fiber adapter is provided with a first positioning groove which extending along the direction perpendicular to a direction in which the optical fiber plug is inserted into the optical fiber adapter, and a first positioning protrusion matching with the first positioning groove is arranged on the inner surface of the box body so that when the first positioning protrusion is latched within the first positioning groove, the optical fiber adapter is fixed to the front end of the box body.

Abstract: A small diameter, shielded, fine wire glass fiber conductor which is capable of transmitting optical and electrical signals in environments with electromagnetic interference or radio frequency interferences. The conductor includes a fiber core, a first insulation layer, a conductive layer, a second insulation layer, a shielding layer, and an outer coating. Applications include use in aerospace, automotive, and other vehicles as well as potential use in electrostimulation devices, such as pacemaker leads, vascular guidewires and other medical applications.

Abstract: A female hardened fiber optic connector for terminating an end of a fiber optic cable that is suitable for making an optical connection with another hardened cable assembly and cable assemblies using the same are disclosed. The female hardened fiber optic connector includes a connector assembly, a crimp body, a connector sleeve, and female coupling housing. The connector sleeve has one or more orientation features that cooperate with one or more orientation features inside the female coupling housing. The crimp body has a first shell and a second shell for securing the connector assembly at a front end of the shells and a cable attachment region rearward of the front end for securing a cable.

Abstract: A compact optical splitter module is disclosed. One type of compact optical splitter module is a planar attenuated splitter module that includes a branching waveguide network having j?1 50:50 splitters that form up to n?2j output waveguides having associated n output ports, wherein only m<n output ports are suitable for transmitting light to the at least one external output device. This provides a 1×m splitter module wherein each output port has the attenuation of a 1×n splitter module, thereby obviating the need for external attenuation. Another type of compact optical splitter module is a direct-connect splitter module that eliminates the need for an optical fiber array when coupling to external optical fibers. Another type of compact optical splitter module is a microsplitter module that serves as device and module at the same time and that eliminates the differentiation between device and module. The integration of device and module also makes manufacturing the microsplitter module cost-effect.

Abstract: An assembling device for assembling optical fibers in the main body includes a support member and a blocking member. The support member includes a top surface. The top surface defines a receiving cavity and a supporting recess communicating with the receiving room. The blocking member includes a blocking surface. The blocking member is partially received in the receiving cavity. The blocking surface is exposed in the supporting recess. The supporting recess is configured for supporting the main body and contacting distal ends of the optical fibers.

Abstract: An apparatus comprising a first photonic device comprising a waveguide loop configured to guide a first light from a first location of a surface to a second location of the surface, and a second photonic device comprising a light source configured to provide the first light, and a first alignment coupler optically coupled to the light source and configured to optically couple to the waveguide loop at the first location, a second alignment coupler configured to optically couple to the waveguide loop at the second location, and a photodetector optically coupled to the second alignment coupler and configured to detect the first light when the waveguide loop is aligned with the first alignment coupler and the second alignment coupler, and generate, based on the detection and on the received light, an electrical signal.

Abstract: This disclosure provides an optical assembly, comprising a base body and a wave filtering apparatus. A first slot is disposed on an upper surface of the base body. A total internal reflection surface and a connecting part are formed in the first slot. The total internal reflection surface reflects collimated light formed by a first lens from a light emitting apparatus. The wave filtering apparatus comprises a first part removably connected to the connecting portion, and a second portion forming a beam splitting surface. The wave filtering apparatus has a light-pervious optical coating at least on the beam splitting surface of the apparatus, and is configured to split the collimated light reflected from the total internal reflection surface into a first beam and a second beam. The first beam travels towards the side where the third lens is located, and the second beam travels towards a photoelectric detection apparatus.

Abstract: An optical communication cable is provided. The optical communications cable includes a cable body having an outer surface, an inner surface and a channel defined by the inner surface. An optical transmission element is located in the channel. The cable includes an ink layer positioned on the outer surface of the cable body, and the ink layer is formed from charged ink droplets adhered to the outer surface of the cable body. The cable also includes a translucent layer coupled to the outer surface of the cable body over the ink layer such that the ink layer is located between the outer surface of the cable body and an inner surface of the translucent layer.

Abstract: An optical fiber cable splicing box is provided that can easily connect together optical fiber cables that include a metal wire and an optical fiber. Optical fiber cable splicing box 1 includes a pair of cable holders 3A, 3B aligned in a predetermined direction fixed to a body 2, a mechanical splice 4 that optically connects together ends of optical fibers 91A and 91B, a pair of contact portions 80A and 80B respectively provided on the pair of cable holders 3A and 3B, and a metal plate 5 having conductivity. The contact portions 80A and 80B include a first connecting portion 84c that is electrically connected to metal wires 92a and 92b of optical fiber cables 90A and 90B by penetrating into a jacket 94, and a base portion 83 that is electrically conducting with the first connecting portion 84c and electrically connected to a metal plate 5.

Abstract: Optical fiber distribution enclosure (1), comprising a housing base (40) and a housing cover (20), engageable with each other to form a housing of the enclosure (1), a slack fiber storage device (50), arranged within the housing when the housing base (40) and the housing cover (20) are engaged with each other, a tray holder (60), arranged within the housing when the housing base (40) and the housing cover (20) are engaged with each other, on which tray holder (60) one or more fiber-optic trays (70) can be mounted, characterized in that the housing base (40), the slack fiber storage device (50) and the tray holder (60) are integrally formed as one piece.

Abstract: A damping device of an optical element of a projection exposure machine includes at least two mass dampers arranged spaced apart from one another, the vibration absorbers each having at least one damper mass and at least one damping element and the damper masses of the at least two mass dampers being interconnected by at least one connecting element. The optical element can be part of a projection exposure machine.

Abstract: A ball cage centered lens assembly is provided including an axially thick lens; an outer mechanical cell; an intermediate cage positioned between the axially thick lens and the outer mechanical cell; a plurality of deformable elements positioned within the cage, between the axially thick lens and the mechanical cell, and in contact with the axially thick lens and the outer mechanical cell.

Abstract: An imaging lens module includes an imaging lens assembly and a first optical component. The imaging lens assembly has an optical axis and includes a lens element. The lens element includes an effective optical portion, which is non-circular and disposed on a center of the lens element. The first optical component has a non-circular opening hole. The effective optical portion of the lens element of the imaging lens assembly is corresponded to the non-circular opening hole of the first optical component.

Abstract: A lens driving device and the lens holder cannot tilt when the lens holder moves up due to the coil energized. The inside holding portion (14a) of the front spring member (14A) is connected to the surface of the +Z side of the front connection portion (13b) of the lens holder (13), the inside holding portion (14a) of the rear spring member (14B) is connected to the surface of the +Z side of the rear connection portion (13c), the outside diameter of which is larger than the outside diameter of the front connection portion (13b), the outside holding portion (14b) is connected with the base (12) in the manner of shifting the inside holding portion (14a) towards the ?Z side, so as to apply the pressure of the ?Z-axis direction to the lens holder (13).

Abstract: A lens driver circuit determines the resonant frequency at a number of positions that a lens can move to so that the lens can move from an old position to a new position in two steps where the second step occurs a delay time after the first step. The delay time can be one-half of the period of the resonant frequency at the new position.

Abstract: A lens mount with a mount ring (1) having a mount ring axis (1.1), at which mount ring (1) is provided an edge support (1.2) which is radially extended with respect to the mount ring axis (1.1), with a round optical component (2) which contacts the edge support (1.2) by an end face and with an intermediate ring (3) which contacts the other end face of the optical component (2) and which is fixed in position opposite the mount ring (1), e.g., by means of a screw ring (4.1). Three point-shaped first protuberances (1.3) and second protuberances (3.3), respectively, are provided at the edge support (1.2) and at the intermediate ring (3) in each instance on an imaginary circular ring (1.4) of identical size at angular distances relative to one another, and one each of the first protuberances (1.3) and one each of the second protuberances (3.3) lie in each instance on an imaginary straight line (5) running parallel to the mount ring axis (1.1) through the edge region (2.2).

Abstract: An electronic device includes a threaded spacer and a biasing element to reduce backlash. The threaded spacer includes a thread end point that is offset from the thread start point of the carrier frame. The offset thread ending and starting points create a gap between the threaded spacer and the carrier frame. The biasing element applies a force to the threaded spacer, thereby reducing the backlash between the lens and the carrier frame, while at the same time allowing the lens to be rotated for focus adjustments.

Abstract: A driving apparatus includes a first axial member that is arranged so as to extend in a predetermined direction, where the predetermined direction is the axial direction of the first axial member, and a driving unit that is configured to generate a first driving force in the axial direction and a second driving force in a direction intersecting the axial direction, where the first and second driving forces are to be applied to the first axial member.

Abstract: In a lithography tool used in fabricating microelectronic devices, autofocus (AF) systems provide automatic image focusing before making exposures. To reduce production of erroneous results based on interaction of a beam of AF light with certain regions on lithographic substrates, a subject AF device has a sending unit and a receiving unit. The sending unit directs an AF light beam to the substrate, and the receiving unit receives AF light reflected from the substrate. The receiving unit has a system photodetector and a patterned optical element that receives AF light from the substrate and transmits a selected diffraction order(s) of said light. The system photodetector senses light of the selected diffraction order of reflected AF light while at least one additional photodetector detects divergent reflected AF light. Substrate areas exhibiting unusual amounts of divergent light may indicate a focus-error condition. The AF systems can be configured as fringe-projection or slit-projection AF systems.

Abstract: A lens barrel includes a cam frame, a zoom motor unit driving the cam frame to rotate, and a fifth group unit engaging with the cam frame through a fifth cam follower. The cam frame is provided with an internal gear engaging with the zoom motor unit, and a fifth cam groove engaging with the fifth cam follower. The fifth cam groove is continuous with a tooth space formed between two adjacent teeth of the internal gear. The fifth cam follower is smaller than the tooth space to pass through the tooth space.

Abstract: The lens barrel includes a stationary tube, a cam ring, and a rectilinear motion tube. The rectilinear motion tube is moved by the rotation of the cam ring in the optical axis direction. A lens frame holding a lens is moved by a driving unit (feed screw and a motor) in the optical axis direction. The stationary tube includes a main guide bar in the optical axis direction. The rectilinear motion tube includes another main guide bar in the optical axis direction. The lens frame includes first and second fitting portions slidably supported by the main guide bars in the optical axis direction, and the first and second fitting portions are disposed separately in the optical axis direction, and the main guide bars are disposed in different positions around the optical axis.

Abstract: Provided are a photographic lens and an electronic apparatus including the photographic lens. The photographic lens includes a first lens that has a positive refractive power and includes a biconvex lens, a second lens that has a negative refractive power, a third lens that has a positive refractive power, and a fourth lens that has a negative refractive power. The first, second, third, and fourth lenses are arranged sequentially from an object-side to an image-side.

Abstract: An optical image capturing system, sequentially including a first lens element, a second lens element, a third lens element and a fourth lens element from an object side to an image side, is disclosed. The first lens element has positive refractive power. The second lens element, the third lens element and the fourth lens element have refractive power respectively. At least one of the image side surface and the object side surface of each of the four lens elements are aspheric. The optical lens elements can increase aperture value and improve the imagining quality for use in compact cameras.