A head up display arrangement for a motor vehicle includes at least one camera capturing images of a scene outside of the motor vehicle, and wirelessly transmitting first video signals indicative of the captured images. A receiver wirelessly receives the first video signals and transmits second video signals dependent upon the first video signals. A head up display system is communicatively coupled to the receiver and receives the second video signals. The head up display system reflects a light field off of a windshield of the motor vehicle such that the reflection is visible to a driver of the vehicle as a virtual image. The light field is dependent upon the second video signals.

A head up display arrangement for a motor vehicle includes at least one camera capturing images of a scene outside of the motor vehicle, and wirelessly transmitting first video signals indicative of the captured images. A receiver wirelessly receives the first video signals and transmits second video signals dependent upon the first video signals. A head up display system is communicatively coupled to the receiver and receives the second video signals. The head up display system reflects a light field off of a windshield of the motor vehicle such that the reflection is visible to a driver of the vehicle as a virtual image. The light field is dependent upon the second video signals.

An example electrophoretic display device includes: an outer substrate and an inner substrate; and at least one color-changing layer comprising: a plurality of driven electrodes and at least one reference electrode; a plurality of microstructures disposed between the driven electrodes and the reference electrode, the microstructures containing an electrophoretic media; and a controller coupled to the driven electrodes, the controller configured to: obtain image data representing an image to be displayed by the electrophoretic display device; select a subset of the driven electrodes based on a mapping of the image data to the driven electrodes; and drive the subset of driven electrode to induce a voltage difference to change the electromagnetic field applied to the electrophoretic media in the microstructures aligned with the subset of driven electrodes.

An example electrophoretic display device includes: an outer substrate and an inner substrate; and at least one color-changing layer comprising: a plurality of driven electrodes and at least one reference electrode; a plurality of microstructures disposed between the driven electrodes and the reference electrode, the microstructures containing an electrophoretic media; and a controller coupled to the driven electrodes, the controller configured to: obtain image data representing an image to be displayed by the electrophoretic display device; select a subset of the driven electrodes based on a mapping of the image data to the driven electrodes; and drive the subset of driven electrode to induce a voltage difference to change the electromagnetic field applied to the electrophoretic media in the microstructures aligned with the subset of driven electrodes.

An electrochromic element, which includes a pair of electrodes and an electrochromic layer disposed between the electrodes. The electrochromic layer contains at least one of two or more kinds of anode electrochromic materials, or two or more kinds of cathode electrochromic materials. All of one of the anode electrochromic materials and the cathode electrochromic materials have an equal molecular length, or have a molecular length ratio of (large molecular length)/(small molecular length) of 1.4 or less, the electrochromic element being such that even when a driving environment temperature changes, its gradation can be controlled under a state in which its absorption spectrum is retained.

Briefly, a method for verifying the visual perceptibility of a display is provided. An intended message is written to a bistable display. Pixels that comprise portions of the message are measured and evaluated to determine if the message actually displayed on the bistable display was perceptible by a human or a machine. In some cases, information regarding the message actually perceivable from the display may be stored for later use. Responsive to determining that a message is perceivable or not perceivable, alarms may be set, one or more third parties notified, or additional display features may be set.

Briefly, a method for verifying the visual perceptibility of a display is provided. An intended message is written to a bistable display. Pixels that comprise portions of the message are measured and evaluated to determine if the message actually displayed on the bistable display was perceptible by a human or a machine. In some cases, information regarding the message actually perceivable from the display may be stored for later use. Responsive to determining that a message is perceivable or not perceivable, alarms may be set, one or more third parties notified, or additional display features may be set.

Briefly, a method for verifying the visual perceptibility of a display is provided. An intended message is written to a bistable display. Pixels that comprise portions of the message are measured and evaluated to determine if the message actually displayed on the bistable display was perceptible by a human or a machine. In some cases, information regarding the message actually perceivable from the display may be stored for later use. Responsive to determining that a message is perceivable or not perceivable, alarms may be set, one or more third parties notified, or additional display features may be set.

An electrochromic element, includes: a pair of electrodes (3, 5); and an electrochromic layer (7) disposed between the pair of electrodes (3, 5), the electrochromic element being controlled in transmittance by pulse width modulation, in which: the electrochromic layer (7) contains at least one of two or more kinds of anode electrochromic materials, or two or more kinds of cathode electrochromic materials; and all of one of the anode electrochromic materials and the cathode electrochromic materials have an equal molecular length, or have a molecular length ratio of (large molecular length)/(small molecular length) of 1.4 or less, the electrochromic element being such that even when a driving environment temperature changes, its gradation can be controlled under a state in which its absorption spectrum is retained.

Briefly, a method for verifying the visual perceptibility of a display is provided. An intended message is written to a bistable display. Pixels that comprise portions of the message are measured and evaluated to determine if the message actually displayed on the bistable display was perceptible by a human or a machine. In some cases, information regarding the message actually perceivable from the display may be stored for later use. Responsive to determining that a message is perceivable or not perceivable, alarms may be set, one or more third parties notified, or additional display features may be set.