Abstract: An optical lighting assembly for use with a vehicular outside rearview mirror includes a printed circuit board (PCB) having a light source such as a light emitting diode (LED) mounted thereon. An optical device such as a light pipe is positioned adjacent to the LED for propagating light away from the LED. A mirror element includes at least one indicia where light escaping from the light pipe is used to illuminate the indicia.

Abstract: A controller system configured to control an electrochromic device and method thereof are provided, wherein the controller system includes an electrochromic device having a first substantially transparent substrate, a second substantially transparent substrate approximately parallel to the first substantially transparent substrate such that a chamber is defined by the first and second substantially transparent substrates, and an electrochromic medium between the first and second substantially transparent substrates, and a controller in communication with the electrochromic device, wherein the controller is configured to monitor electrical power supplied to the electrochromic device and adjust the electrical power supplied to the electrochromic device to maintain the electrochromic device in an approximately minimum transmission state.

Abstract: An electrochromic device including a first substantially transparent substrate having an electrically conductive material associated therewith; a second substrate having an electrically conductive material associated therewith; and an electrochromic medium contained within a chamber positioned between the first and second substrates which includes: at least one solvent; at least one anodic electroactive material; at least one cathodic electroactive material; wherein at least one of the anodic and cathodic electroactive materials is electrochromic; and a creep resistant crosslinked polyelectrolyte gel matrix.

Abstract: A display panel, a method for manufacturing the display panel and a display device are provided. The display panel comprises a first transparent substrate (1) and a second transparent substrate (2) disposed opposite to the first transparent (1), the display panel further comprises a black matrix (3) disposed between the first transparent substrate (1) and the second transparent substrate (2), wherein the black matrix (3) together with the first transparent substrate (1) and the second transparent substrate (2) forms a plurality of pixel spaces separated from each other, electrochromatic material (4) disposed in each of the pixel spaces, and the display panel further comprises a first electrode and a second electrode, the plurality of pixel spaces being disposed between the first electrode and the second electrode.

Abstract: A method for control of electrochromic devices is revealed. First a duty cycle of PWM is changed to a preset Q value according to a signal detected by a detector while the electrochromic device is switched to the colored state. The Q value represents electric charge that corresponds to colored-state transmittance. Then turn off the PWM. Thus the response time for coloration and the transmittance of the electrochromic device are maintained within a preset range, without being affected by ambient temperature, setting time and aging of the materials used. Thus the electrochromic device is more convenient to use and having more practical value.

Abstract: A variable reflectance vehicular electro-optic rearview mirror reflective element assembly includes a front substrate and a rear substrate with a perimeter seal disposed therebetween. The front substrate has a first surface and a second surface opposite the first surface, with the second surface having a transparent electrically conductive coating disposed thereat. The rear substrate has a third surface and a fourth surface, with the third surface having a conductive reflector coating disposed thereat. The reflector coating may include a plurality of layers having first and second layers of nickel chromium. The front substrate may have a perimeter band disposed along a perimeter region of the second surface. The perimeter band may include a plurality of layers having first and second layers of nickel chromium.

Abstract: Provided is an optical system having at least two or more lenses, wherein at least one of the lenses comprises an anti-reflection film formed by a wetting method on a part of or the entirety of the light beam effective surface thereof, and wherein at least one of the lenses other than the lens comprising the anti-reflection film is fixed to the space between the lens and a barrel for holding the lens via an energy-curable resin to be filled therein.

Abstract: At the time of temporary firing for fixing a glass layer 3 to a glass member 4, the glass layer 3 is irradiated with laser light L2 through the glass member 4 from the glass member 4 side. This fully heats a part of the glass layer 3 on the glass member 4 side and thus can improve the adhesion of the glass layer 3 to the glass member 4. Further, even when irradiated with the laser light L2 at such a laser power as to melt both edge parts of the glass layer 3, the part of the glass layer 3 on the side opposite from the glass member 4 (i.e., the part of the glass layer 3 fused to the other glass member) is prevented from being crystallized by excess heat input, whereby the fusing state of the glass layer 3 with respect to the other glass member can be made uniform.

Abstract: A reflective color display may include a first electrode layer and a second electrode layer facing each other. An electrochromatic layer may be formed on the first electrode layer. The electrochromatic layer may include an electrochromatic material that is structured to display a color, to appear black, or to become transparent according to a voltage applied thereto. An electrolyte layer may contact the electrochromatic layer. The electrolyte layer may be located between the first electrode layer and the second electrode layer. A reflective layer may be disposed on the second electrode layer.

Abstract: A light source (600) includes: a plurality of LEDs (610), including one or more first LEDs (612) configured to emit first light having a first color, one or more second LEDs (614) configured to emit second light having a second color, and one or more third LEDs (616) configured to emit third light having a third color; a mixing device (620) configured to mix the first light, the second light, and the third light into a mixed light, wherein the mixing device includes an exit window (640) configured such that the mixed light is emitted from the mixing device through the exit window; and a light-conversion material (6300 provided at the exit window, wherein the light-conversion material is configured to convert the first light from the first color to a lime color.

Abstract: A rearview mirror assembly for a vehicle includes a mirror casing and an electro-optic reflective element assembly disposed at the mirror casing. A second surface of a front substrate of the reflective element assembly has a transparent conductive coating established thereat and a third surface of a rear substrate has a conductive coating established thereat. An electrical connector may be disposed at the fourth surface and in electrically conductive continuity with the transparent conductive coating and/or the conductive coating. The electrical connector may include a connector attaching portion for attaching at the fourth surface and a conductor attaching portion for soldering or welding an electrical conductor or wire to the electrical connector when the electrical connector is attached at the fourth surface. The conductor attaching portion is spaced from the plane of the connector attaching portion and the fourth surface of the rear substrate.

Abstract: A vehicle lighting module is provided that includes a lens having a plurality of near-field lens elements, an input surface, and an exit surface. The lighting module also includes an LED light source that directs incident light through the input surface and out of the exit surface. The plurality of lens elements is configured to transmit from the exit surface a collimated light pattern containing at least 60% of the incident light. Further, a vehicle headlamp assembly is provided that includes a plurality of vehicle lighting modules, each module comprising a lens, and an LED light source that directs incident light through the lens. The assembly further includes a case for housing the lighting modules. The lens includes a plurality of lens elements configured to transmit at least 60% of the incident light in a collimated, vehicular light pattern.

Abstract: A manual dimmable mirror assembly includes a mirror element having a first substantially transparent substrate and a second substantially transparent substrate. The first and second substantially transparent substrates are substantially parallel and define a cavity that contains an electro-optic medium. The mirror assembly also includes an input device and a controller in communication with the input device. The controller configured to control electrical power supplied to the mirror element, such that the mirror element transitions from a substantially clear state to a substantially dark state at least partially based upon the communication from the input device.

Abstract: A vehicular rearview assembly that has a rounded outer perimeter edge to satisfy safety standards and contains an EC element having a complex peripheral ring, a front surface that is fully observable from the front of the assembly, and a user interface with switches and sensors that activate and configure, in cooperation with electronic circuitry of the assembly, pre-defined function(s) or device(s) of the assembly in response to the user input applied to the user interface. A complex peripheral ring may include multiple bands the structures of which is adapted to provide for specified optical characteristics of light, reflected off of the ring. Electrical communications between the electronic circuitry, the mirror element, and the user interface utilize connectors configured to exert a low contact force, onto the mirror element, limited in part by the strength of adhesive affixing the EC element to an element of the housing of the assembly.

Abstract: An exterior rearview mirror assembly suitable for a vehicle includes an attachment portion and a casing portion having a variable reflectance mirror reflective element. A mirror reflector is disposed at at least a portion of a surface of a rear substrate of the reflective element. The mirror reflector includes a stack of thin films having at least a first metal thin film and a second metal thin film. The first metal thin film is formed of a metal material that has a specific resistivity of less than about 1×10?3 ohm·cm and the second metal thin film is formed of a metal material that has a specific resistivity of less than about 1×10?3 ohm·cm. No part of the rear substrate extends beyond any part of a front substrate of the reflective element. An indicator is disposed rearward of the reflective element and, when actuated, illuminates through the reflective element.

Abstract: A vehicular rearview assembly with a mirror element having a curved or rounded edge on the first surface that is fully observable from the front of the assembly, a complex peripheral ring, and a user interface with switches and sensors that activate and configure pre-defined function(s) or device(s) of the assembly in response to the user input applied to the user interface. The mirror element is supported by a hybrid carrier co-molded of at least two materials, a portion of which is compressible between the housing shell and an edge of the mirror element. The peripheral ring may include multiple bands. Electrical communications between the electronic circuitry, the mirror element, and the user interface utilize connectors configured to exert a low contact force, onto the mirror element, limited in part by the strength of adhesive affixing the EC element to an element of the housing of the assembly.

Abstract: The present invention relates to improved electro-optic rearview mirror elements and assemblies incorporating the same.

Abstract: A stereoscopic image display device includes a barrier panel that includes a first barrier panel configured to partially reflect light, and a second barrier panel provided on the first barrier panel configured to partially absorb light. Each of the first barrier panel and the second barrier panel includes an electrochromic element and electrodes respectively provided on opposite surfaces of the electrochromic element.

Abstract: This invention discloses how electrooptic devices including electrochromic devices that can be fabricated as tags or labels; and further the materials used, device structures and how these can be processed by printing technologies and on flexible substrates. In addition, systems using displays of such devices and their integration with other components are described for forming labels and tags, etc, that may be actuated wirelessly or powered with low voltage and low capacity batteries.

Abstract: Optical MEMS scanning micro-mirror comprising: —a movable scanning micro-mirror (101), being pivotally connected to a MEMS body (102) substantially surrounding the lateral sides of the micro-mirror, —a transparent window (202) substantially covering the reflection side of the micro-mirror; —wherein a piezo-actuator assembly (500) and a layer of deformable transparent material (501) are provided on the outer portion of said window (202); —the piezo-actuator assembly (500) being arranged at the periphery of the layer of transparent material (501); —said piezo-actuator assembly (500) and transparent material (501) cooperating so that when actuated, the piezo-actuator assembly (500) causes micro-deformation of the transparent material (501), thereby providing an anti-speckle effect. The invention also provides the corresponding micro-projection system and method for reducing speckle.

Abstract: A vehicular exterior rearview mirror assembly includes a mirror head portion and a reflective element having a glass substrate and a mirror reflector coated at a surface of the glass substrate. The reflective element is configured to provide a rearward field of view of at least about 15 degrees relative to a side of the vehicle and provides a substantially undistorted reflected image as viewed by the vehicle driver. The glass substrate is formed utilizing a bending element having a free form curvature. The reflective element, when accommodated by the mirror head portion at the side of the vehicle and as viewed by the driver, includes an image plane that establishes an object plane. Coordinates of the image plane and of the object plane are determined, at least in part, by the mirror size and by the free form curvature of the bending element used to form the glass substrate.

Abstract: A display mirror assembly for a vehicle includes a front shield having a first side and a second side. A partially reflective, partially transmissive element is mounted on the first side. A rear shield is disposed behind the front shield. A display module is mounted between the front shield and the rear shield and includes in order from the front shield: a display; an optic block; a heat sink having an edge lit PCB mounted along a top edge thereof; and a PCB. The front shield is secured to at least one component of the display module with a first retaining feature and the rear shield is secured to at least one component of the display module with a second retaining feature. A housing at least partially surrounds the partially reflective, partially transmissive element, the front shield, carrier plate, display module, and rear shield.

Abstract: This invention discloses conductive busbars and sealants for electrooptic devices including electrochromic mirrors and windows. The conductive busbars are formed from materials comprising nanoparticles, and the sealants comprise of additives that promote a two phase morphology and use of adhesion promotion additives with crosslinkers. Methods to deposit busbars and then to connect these busbars to electrical connectors are also disclosed.

Abstract: A light modulation layer of a full-color reflective display (112), the light modulation layer including an addressing layer (404); a mirror (406) positioned above the addressing layer (404), the mirror (406) configured to reflect light of a predetermined wavelength band; and an electro-optic layer (416) positioned above the mirror (406), the electro-optic layer (416) configured to absorb light of a predetermined wavelength band in response to a signal received from a switching device (204) of the addressing layer (404).

Abstract: An interior rearview mirror assembly includes a mirror casing and a prismatic reflective element. The mirror casing is a unitarily molded mirror casing having at least one attachment surface. The prismatic reflective element includes a glass substrate having a front surface and a rear surface and a perimeter edge about a periphery of the glass substrate. A mirror reflector is established at the rear surface of the glass substrate. The perimeter edge of said glass substrate has a generally rounded surface disposed between the front surface and the mirror casing. The prismatic reflective element is attached at the attachment surface of the mirror casing. The perimeter edge of the glass substrate is exposed to and is viewable by the driver of the vehicle when the interior rearview mirror assembly is normally mounted in the vehicle.

Abstract: There are provided a display and an electronic unit capable of enhancing visibility. The display includes: a plurality of pixels each including a light-emission device, and having a light-transmission region in at least a part thereof; and one or more transmittance control devices capable of controlling a transmittance of incident light.

Abstract: A display system for use in a controlled vehicle is provided, and includes a rearview assembly having a display device located behind a mirror element, a camera system configured to acquire images of a scene external of the controlled vehicle, and a processing system configured to receive a signal representative of the acquired images and to produce an image of the scene on the display device of the rearview assembly, wherein the processing system is further configured to adjust the photosensitivity of the camera system based on an input from at least one of an ambient light sensor and a direct glare sensor.

Abstract: An electro-optic system is provided that includes a front element having first and second surfaces, a rear element including third and fourth surfaces, wherein the front and rear elements are sealably bonded together in a spaced-apart relationship to define a chamber, and an electro-optic medium contained in the chamber, and the electro-optic medium is adapted to be in at least a high transmittance state and a low transmittance state.

Abstract: A porous electrode sheet (1) includes a resin film (2) being transparent and having insulating properties, and a transparent electrode (3) placed on one face (2a) of the resin film (2). The resin film (2) is provided with a plurality of through holes (21) extending linearly from the one face (2a) to the other face (2b). The transparent electrode (3) has openings (31) at positions corresponding respectively to the through holes (21). The through holes (21) of the resin film (2) and the openings (31) of the transparent electrode (3) communicate with each other, and thereby form passages (10) penetrating the porous electrode sheet (1) in the thickness direction.

Abstract: An interior rearview mirror assembly for a vehicle includes a mirror casing and an electro-optic reflective element. The reflective element has an electro-optic active region where an electro-optic medium is disposed and bounded by a perimeter seal. A transparent electrically conductive coating is established at the rear surface of the front substrate at the electro-optic active region. A perimeter portion of the front substrate extends beyond a corresponding perimeter portion of the rear substrate to establish a user input region that is outboard of the electro-optic active region. A user input, such as a touch sensor, is disposed at the user input region, and the user input is not in electrical contact with the transparent electrically conductive coating at the rear surface of the front substrate. The user input is operable to detect the presence or touch of a person's finger at the user input region.

Abstract: An optics arrangement includes a multi-channel imaging system for optical sampling of an object plane in visual fields, abutting or overlapping in the object plane, of a plurality of optical channels of the multi-channel imaging system, and a waveguide arranged between the object plane and the multi-channel imaging system so as to guide light in the waveguide laterally, the waveguide having a plurality of redirecting structures arranged on a side of the waveguide facing the object plane and/or a side of the waveguide facing the multi-channel imaging system, the redirecting structures being arranged in dead zones between the visual fields of the optical channels, and the redirecting structures being configured to deflect the guided light in the direction of the object plane such that the object plane is illuminated.

Abstract: An autostereoscopic display device includes a display, a parallax barrier, a driver and a controller. The parallax barrier is placed in front of the display and includes a matrix of barrier blocks. The driver is electrically connected to the parallax barrier. The controller is in communication with the driver and controls the driver such that the barrier block in the i-th line and j-th column is switched on to a transparent state and the other barrier blocks are switched off to a nontransparent state, where i and j satisfy the following condition formulae: j=i+nk, i?N, and j?M, i and j are positive integers, n is an integer, k is a positive integer constant, N is the number of the lines of the barrier blocks, and M is the number of the columns of the barrier blocks.

Abstract: An exterior rearview mirror assembly for a vehicle includes a mirror head portion and a reflective element accommodated by the mirror head portion. The reflective element includes a glass substrate and a mirror reflector coated at a surface of the glass substrate. The reflective element is configured to provide a field of view of at least about 15 degrees at the side of the vehicle and provides a substantially undistorted reflected image as viewed by the driver of the vehicle. The reflective element may have a width dimension of less than about 15 cm and a height dimension of less than about 9 cm. The mirror substrate is curved or formed via a hydro-bending process utilizing at least one bending element, which may be CNC formed in accordance with a free form pattern of curvatures.

Abstract: Aspects of the present invention include systems for reflective digital light processing (DLP). Embodiments include a light source, a plurality of optically reflective switching devices each having an optically reflective layer in contact with a substrate; a circuit means and power source; controller logic; a projection means; and a display means; wherein each of said plurality of devices is a capable of receiving light from said light source and thereafter reflecting said received light in direct response to a reflective state condition of said each device.

Abstract: Provided is a display unit that includes: a pair of a first substrate and a second substrate that are arranged in opposition to each other; a display layer provided between the first substrate and the second substrate; and a display mode switching layer having an aperture for each pixel, and provided between the display layer and the second substrate.

Abstract: A rearview assembly for a vehicle includes a housing. A carrier is operably connected with the housing and supports a display. A circuit board is disposed in the housing. A sensing system is disposed proximate the display and is connected with the circuit board. A switching assembly is operably connected with the circuit board. Actuation of the switching assembly when the sensing system has been activated enables a function of the rearview assembly.

Abstract: An interior rearview mirror assembly for a vehicle includes a mirror casing and an electro-optic reflective element. The reflective element has an electro-optic active region where an electro-optic medium is disposed and bounded by a perimeter seal. A transparent electrically conductive coating is established at the rear surface of the front substrate at the electro-optic active region. A perimeter portion of the front substrate extends beyond a corresponding perimeter portion of the rear substrate to establish a user input region that is outboard of the electro-optic active region. A user input, such as a touch sensor, is disposed at the user input region, and the user input is not in electrical contact with the transparent electrically conductive coating at the rear surface of the front substrate. The user input is operable to detect the presence or touch of a person's finger at the user input region.

Abstract: A power supply for supplying direct current (DC) power from a pulse width modulated (PWM) source includes a connector configured to be in electrical communication with a PWM power source. A hold-up circuit is in electrical communication with the connector and is configured to convert electrical power supplied from the PWM power source to DC power. This DC power is supplied to a drive circuit where a microcontroller is configured to control the drive circuit by supplying the DC power from the drive circuit to a load.

Abstract: An exterior surface covering has a colored outer layer that transmits infrared radiation and an inner layer with a thermochromic pigment that absorbs heat at low temperature and reflects at high temperatures. The outer layer conceals the color change of the thermochromic pigment.

Abstract: A rearview mirror assembly for a vehicle includes a mirror casing and an electro-optic reflective element assembly disposed at the mirror casing. A second surface of a front substrate of the reflective element assembly has a transparent conductive coating established thereat and a third surface of a rear substrate has a conductive coating established thereat. An electrical connector may be disposed at the fourth surface and in electrically conductive continuity with the transparent conductive coating and/or the conductive coating. The electrical connector may include a connector attaching portion for attaching at the fourth surface and a conductor attaching portion for soldering or welding an electrical conductor or wire to the electrical connector when the electrical connector is attached at the fourth surface. The conductor attaching portion is spaced from the plane of the connector attaching portion and the fourth surface of the rear substrate.

Abstract: A controller or control method may be designed or configured to operate without information about the current temperature of the device and/or the device's environment. Further, in some cases, the controller or control method is designed or configured to control transition of an optical device to an intermediated state between two end states. For example, the controller may be configured to control a transition to a state of transmissivity that is intermediate between two end states of transmissivity. In such case, the device has three or more stable states of transmissivity.

Abstract: A lens module includes an infrared absorbing filter. The infrared absorbing filter includes an electrochromic substrate. The electrochromic substrate changes from colorlessness to blue when a preset voltage is applied on the electrochromic substrate. The electrochromic substrate is configured for absorbing the infrared constituent of incoming light rays when the color is changed to blue.

Abstract: A reflective display device has multiple display pixels. Each pixel has at least three color sub-pixels disposed side-by-side for three primary colors respectively. At least one color sub-pixel has a light shutter with adjustable transmission, a luminescent layer containing a luminescent material that emits light of a selected color, and a mirror for reflecting light corresponding to that selected color.

Abstract: An apparatus, method, and process that includes a substantially transparent substrate having a first surface, a second surface, and edge extending around at least a portion of a perimeter of the substantially transparent substrate, wherein the edge being a laser induced channel edge having enhanced edge characteristics.

Abstract: A manual dimmable mirror assembly includes a mirror element having a first substantially transparent substrate and a second substantially transparent substrate. The first and second substantially transparent substrates are substantially parallel and define a cavity that contains an electro-optic medium. The mirror assembly also includes an input device and a controller in communication with the input device. The controller configured to control electrical power supplied to the mirror element, such that the mirror element transitions from a substantially clear state to a substantially dark state at least partially based upon the communication from the input device.

Abstract: A system is configured to reduce glare form a trailing vehicle. The system may include a forward facing light sensor, partially enclosed in an interior mirror housing. This forward facing light sensor is configured to detect ambient light, such that the system can determine a day time condition or a nighttime condition. The system may also include rear facing light sensors, each included in separate mirror assemblies. Based upon an ambient light detected and a glare of a trailing vehicle, the system may be configured to change the reflectance of an electro-optic element in order to reduce glare independently in the separate mirror assemblies.

Abstract: Aspects of the present invention include systems for reflective digital light processing (DLP). Embodiments include a light source, a plurality of optically reflective switching devices each having an optically reflective layer in contact with a substrate; a circuit means and power source; controller logic; a projection means; and a display means; wherein each of said plurality of devices is a capable of receiving light from said light source and thereafter reflecting said received light in direct response to a reflective state condition of said each device.

Abstract: An optical element such as a reflector defining a differentiable fiducial surface having a first portion, with a flat region, that seamlessly adjoins, along a curved line, a second portion having a two-dimensionally curved region. The quality of optical imaging in the reflector is drastically improved by reducing the ratio of optical powers measured in two perpendicular directions along the two-dimensionally curved portion of the surface. The vehicular rearview assembly including such a reflector possesses a field-of-view (FOV) that is significantly higher than the FOV of a conventional flat mirror and facilitates visual access to a “blind spot” behind the vehicle.

Abstract: An electro-optic medium comprises at least one leuco dye such that the electro-optic medium can develop at least two differing colors upon exposure to two or more differing stimuli. The medium allows for development of differing colors in differing areas of the medium, thus allowing formation of intrinsic color within differing areas of a single layer of the same electro-optic medium. In an electrophoretic medium, the colors may be developed within the electrophoretic particles or within the fluid in which the particles are dispersed.

Abstract: An exterior rearview mirror assembly includes a variable reflectance mirror reflective element. A mirror reflector of the mirror reflective element includes a stack of thin films having at least two thin films. At least one of the thin films is formed of a material that has a specific resistivity of less than about 1×10?2 ohm·cm, and at least one of the thin films is a thin metal film. An electrochromic medium is disposed in an interpane cavity of the mirror reflective element and is bounded by a perimeter seal. A reflective perimeter layer is disposed at a second surface of a front substrate proximate a perimeter edge of the front substrate. The perimeter layer generally conceals the perimeter seal from view by a driver of the vehicle normally viewing the front substrate when the exterior rearview mirror assembly is mounted at the vehicle.