A display system is disclosed and includes a display and a reflective polarizer disposed on the display. For substantially normally incident light, for a primary wavelength λ.sub.b, the reflective polarizer transmits at least 60% of the incident light having a first polarization state x and reflects at least 60% of the incident light having an orthogonal second polarization state y. For each of a first wavelength λ.sub.uv and a second wavelength λ.sub.bg, 0<λ.sub.b-λ.sub.uv≤100 nm#and 0<λ.sub.bg-λ.sub.b≤100 nm, the reflective polarizer transmits at least 40% of the incident light for each of the first and second polarization states.

A wavelength division multiplexing structure includes: a first reflecting surface; a second reflecting surface; a first optical filter; a second optical filter; and a pretreatment device. The light that is incident on the first reflecting surface forms a first C-shaped light path in C-shaped or approximately C-shaped and enters the first optical filter. The light that is incident on the first reflecting surface forms a non-coplanar straight line with the light that is reflected by the second reflecting surface. The light that is incident on the pretreatment device forms a pretreatment light path, enters the first optical filter. The light in the pretreatment light path coincides with the light in the first C-shaped light path that is incident on the first optical filter from the second reflecting surface.

The present invention provides an illumination optical system for illuminating an object, comprising: a first light-transmissive member and a second light-transmissive member, and a control unit configured to control drive of the first light-transmissive member and the second light-transmissive member, therein, while the control unit drives the first light-transmissive member such that an incident angle of light to the first light-transmissive member increases, the control unit drives the second light-transmissive member such that the incident angle of light to the second light-transmissive member decreases, thereby changing the intensity of the light exiting from the illumination optical system.

Scopes such as medical imaging camera head devices and methods are provided using light captured by an endoscope system or other medical scope or borescope. At least one polarizing optical element manipulates the polarization properties of image light. The manipulated image light is focused on an image sensor including polarizers for each pixel. Multiple images are produced based sets of pixels having the same orientation of polarizer. The resulting images are combined with high dynamic range techniques.

Provided are a vehicle monitoring method and a vehicle monitoring system. The vehicle monitoring method includes that: a polarization angle of polarized light in a sky image reflected by a vehicle window in a monitoring scenario is calculated, and a light-filtering polarization angle is calculated according to the polarization angle of the polarized light in the sky image reflected by the vehicle window, where the polarized light in the sky image is formed by scattered sunlight in a sky region corresponding to the sky image; the polarized light in the sky image reflected by the vehicle window in the monitoring scenario is filtered out according to the light-filtering polarization angle; and the monitoring scenario is imaged to form a monitoring image.

A display module and a display device are provided. The display module includes a display panel, and an anti-reflection film disposed on a light-emitting side of the display panel. The anti-reflection film includes a buffer layer and a function layer disposed on a side of the buffer layer away from the display panel, and a refractive index of the buffer layer is greater than a refractive index of the function layer.

A viewing angle control system is used in combination with a high-definition image display device and sufficiently shields light emitted in a direction oblique to a normal direction of a film. The viewing angle control system includes at least a first polarizer, a retardation layer, and a second polarizer in this order, where an absorption axis of the first polarizer forms an angle of 45° or greater with respect to a surface, the retardation layer satisfies Expression (1): an in-plane retardation Re of the retardation layer satisfies an expression of 80 nm<Re<250 nm, and Expression (2): in a case of Nz=Rth/Re+0.5, an expression of 1.5<Nz<6 or −5<Nz<−0.5 is satisfied, where Rth represents a retardation of the retardation layer in a thickness direction, and the second polarizer has an absorption axis in an in-plane direction.

An image sensor having a brightness self-adjust capability is provided. The image sensor can include a light adjustment layer made of adaptive optical materials and a set of pixels. The image sensor can also include a control circuit configured to generate control signals to control adjustment of one or more light transparency levels at the set of pixels on the light adjustment layer based on the light intensity distribution. The image sensor can further include a sensor array configured to receive lights and facilitate output of image and/or video signals based on the received lights. For facilitating light adjustment, the control circuit can be configured to obtain light intensity distribution from a pre-sensor or the sensor array.

The present invention relates to a device and a method for limiting the output of a laser, wherein a reflecting device arranged in the optical path of a laser beam comprises a switching layer which comprises or consists of a material exhibiting a metal-insulator transition and a reflecting layer which is positioned downstream of the switching layer in the optical path of the laser beam, wherein the reflecting device is configured such that an output of the laser beam when it is incident upon the reflecting device which exceeds a predefined threshold causes a change in the refractive index of the material in the switching layer, and the output of the laser beam reflected by the reflecting device is thus reduced as compared to the output of the laser beam when it is incident upon the reflecting device due to reduced reflection by the reflecting device.

Devices, methods and systems related to an adjustable polarization filter assembly are described that can be implemented as part of an eyewear or another viewing device to provide the ability to tune the polarization of light that is received based on user and environmental inputs. One example device includes a first rotatable polarization filter that is configured to change a polarization of the incident light, and a second rotatable polarization filter that is also configured to rotate and modify a polarization of light that is incident thereon. The two filters together, via rotation of the first and the second filters, can block any eigenpolarization state on a Poincaré sphere and transmit an orthogonal polarization state. The described devices provide improved viewing capability in different environmental conditions, such as under water, in haze or fog, in outdoor and indoor environments, and in day and night times.