Abstract: A display component controls a viewing angle in a display system that achieves a strong private mode and enhanced brightness in the private and public modes as compared to conventional configurations. A display system that is operable in the private mode and the public mode includes the display component in combination with an image panel.

Abstract: A flexible circular polarizer includes from a viewing side: a substrate; a liquid crystal (LC) polarizer layer; and a quarter wave plate reactive mesogen (RM) retarder layer. An optical axis of the RM retarder is aligned in a first direction and a transmission axis of the LC polarizer is aligned in a second direction different from the first direction, and an angle between the first and second directions has a value of 45°±15°. At least one of the substrate and the LC polarizer has a surface configuration that imparts an alignment to an adjacent non-viewing side layer. The LC polarizer layer may have a surface configuration that imparts an alignment to the RM retarder in the first direction, and/or the substrate may have a surface configuration that imparts an alignment to the LC polarizer in the second direction. A flexible display system includes from a viewing side the flexible circular polarizer, and a display device that is adhered to the flexible circular polarizer.

Abstract: A flexible circular polarizer is provided that is suitable for flexible and bendable display systems. A flexible circular polarizer includes from a non-viewing side: a substrate; a quarter wave plate reactive mesogen (RM) retarder layer; and a liquid crystal (LC) polarizer layer. An optical axis of the RM retarder at a first position in the RM retarder layer is aligned in a first direction and a transmission axis of the LC polarizer is aligned in a second direction different from the first direction. At least one of the substrate and the RM retarder has a surface configuration that imparts an alignment to an adjacent viewing side layer. A flexible display system includes from a viewing side the flexible circular polarizer and a display device that is adhered to the flexible circular polarizer. The flexible display system is repeatedly reconfigurable between a planar state and a non-planar state, such as being bent, folded, rolled, flexed, and/or curved from the planar state.

Abstract: A display device includes an optical stack arrangement including from the viewing side: a front polarizer; a first electrode layer; a viewing side bistable liquid crystal (LC) alignment layer; an LC layer; a non-viewing side bistable LC alignment layer; a second electrode layer; and a rear polarizer. The bistable LC alignment layers induce alignment of LC molecules of the LC layer adjacent to respective surfaces of the bistable LC alignment layers. The non-viewing side bistable LC alignment layer is switchable between two stable LC alignment states and the viewing side bistable LC alignment layer is also switchable between two stable LC alignment states. A combination of structural parameters of the viewing side and non-viewing side bistable LC alignment layers and the front and rear polarizers renders the display device operable to achieve four stable distinct optical states, each stable distinct optical state having a different optical response when viewed from the viewing side of the display device.

Abstract: A liquid crystal device (LCD) includes from the viewing side: a first electrode layer; a viewing side first liquid crystal (LC) alignment layer; an LC layer; a non-viewing side second LC alignment layer; and a second electrode layer; wherein one of the electrode layers is a common electrode layer and the other of the electrode layers is a segmented electrode layer, and at least one of the first and second LC alignment layers is a bistable alignment layer that is switchable between a first alignment state and a second alignment state. The LCD is operated by applying a first voltage pulse to the segmented electrode layer and applying a second voltage pulse to the common electrode layer (Vcom pulse), the first and second voltage pulses combining to form a resultant voltage pulse. The bistable alignment layer switches from the first alignment state to the second alignment state when a magnitude of the resultant voltage pulse exceeds a switching voltage threshold.

Abstract: A liquid crystal (LC) device includes an optical stack arrangement including from the viewing side: a first electrode component; a first LC alignment layer; an LC layer; a second LC alignment layer; and a second electrode component. A voltage is applied to the LC device to create a potential difference between the first and second electrode components to switch an alignment of liquid crystals of selected portions of the LC layer from a first state when no voltage is applied to a second state when the voltage is applied. The first and second LC alignment layers are vertical alignment layers that induce a vertical alignment of the liquid crystals such that the first state when no voltage is applied is a vertical alignment state, and the liquid LC crystals switch to a planar alignment state as the second state when the voltage is applied.

Abstract: A liquid crystal device (LCD) has improved brightness by the use of a patterned alignment structure. The LCD includes a liquid crystal (LC) layer; an electrode arrangement configured to apply an electric field to the LC layer, the electrode arrangement including a patterned electrode layer having a plurality of individual electrode elements and adjacent individual electrode elements are spaced apart from each other by an inter-electrode gap; and a patterned alignment structure that is deposited on the patterned electrode layer and is positioned to align LC molecules of the LC layer. The patterned alignment structure is configured such that a stronger anchoring energy is present at electrode edges of the individual electrode elements of the patterned electrode layer, as compared to a weaker anchoring energy present at electrode centers of the individual electrode elements and/or present at least at a portion of the inter-electrode gaps between adjacent individual electrode elements.

Abstract: A switchable view angle control device for a privacy view display system includes an electrically switchable view angle control LCD that is operable in a first state and a second state; a front polarizer located on a viewing side of the switchable view angle control LCD; and a polarized light source located on a non-viewing side of the switchable view angle control LCD that emits polarized light. When the switchable view angle control LCD in the first state, the view angle control device operates in a narrow angle view mode in which off-axis polarized light from the polarized light source is changed by the switchable view angle control LCD so that the off-axis light is absorbed by the front polarizer, and on-axis light passes through the switchable view angle control LCD and the front polarizer.

Abstract: A switchable view angle control device includes an electrically switchable zenithal bistable liquid crystal display view angle control liquid crystal device (ZBD view angle control LCD) that is operable in a first state and a second state; a front polarizer located on a viewing side of the switchable ZBD view angle control LCD; and a polarized light source located on a non-viewing side of the switchable ZBD view angle control LCD that emits light that is polarized in a first direction. When the switchable ZBD view angle control LCD in the first state, the view angle control device operates in a narrow angle view mode in which the polarization of the light from the polarized light source is changed by the switchable ZBD view angle control LCD to be polarized in a second direction that is at least partially absorbed by the front polarizer, and on-axis light passes through the switchable ZBD view angle control LCD and the front polarizer.

Abstract: A method of fabricating a liquid crystal device (LCD) minimizes changes to optical properties of an internal RM retarder. In exemplary embodiments, the fabricating method comprises depositing a plurality of layers in an optical stack, the plurality of layers including from a viewing side: a first linear polariser; an external retarder; a colour filter substrate; a colour filter layer; an internal reactive mesogen (RM) retarder alignment layer; an internal reactive mesogen (RM) retarder; a liquid crystal (LC) layer; a thin film transistor (TFT) substrate; and a second linear polarizer. Any layer that is deposited after the internal RM retarder on a non-viewing side relative to the color filter substrate, and in direct contact with the internal RM retarder, has a solvent concentration at deposition of less than 15% of a solvent that can alter optical properties of the internal RM retarder (e.g., less than 15% NMP).

Abstract: A liquid crystal device (LCD) is configured for minimizing unwanted internal ambient light reflections. The LCD includes a plurality of layers, the layers comprising from a viewing side: a first linear polariser; an external retarder that is made of a cyclic olefin polymer (COP) material or a cyclic olefin copolymer (COC) material; a colour filter substrate; a colour filter layer; an internal reactive mesogen (RM) retarder alignment layer; an internal reactive mesogen (RM) retarder; a liquid crystal (LC) layer; and a second linear polarizer. The external retarder and the internal RM retarder are configured such that the optical properties (for example light polarization control function) of the external retarder and the internal retarder are matched to negate each other for light passing through the external retarder and the internal RM retarder. The LCD simultaneously maintains high image quality in both high and low ambient lighting conditions.

Abstract: A reconfigurable parallax barrier panel, for use in a display system with a 3D mode, includes a first substrate, a second substrate, and an electro-optic material positioned between the first and second substrates. The first and second substrates each respectively has a plurality of first and second electrodes, the electrodes being independently addressable from one another and comprising a plurality of electrode portions extending along a first direction and laterally spaced from one another along a second direction different from the first direction. The electrode portions of the first electrodes are arranged in a cyclic arrangement having a first pitch, and the electrode portions of the second electrodes are arranged in a cyclic arrangement having a second pitch that is different to the first pitch. The first and second electrodes are driven to generate different reconfigurable parallax barrier arrays corresponding to different viewing distances in a 3D mode of operation.

Abstract: A reconfigurable parallax barrier panel, for use in a display system with a 3D mode, includes a first substrate, a second substrate, and an electro-optic material positioned between the first and second substrates. The first and second substrates each respectively has a plurality of first and second electrodes, the electrodes being independently addressable from one another and comprising a plurality of electrode portions extending along a first direction and laterally spaced from one another along a second direction different from the first direction. The electrode portions of the first electrodes are arranged in a cyclic arrangement having a first pitch, and the electrode portions of the second electrodes are arranged in a cyclic arrangement having a second pitch that is different to the first pitch. The first and second electrodes are driven to generate different reconfigurable parallax barrier arrays corresponding to different viewing distances in a 3D mode of operation.