Abstract: A method of achieving heightened quantum efficiencies and extended photocathode lifetimes is provided that includes using an electron beam bombardment to activate color centers in a CsBr film of a photocathode, and using a laser source for pumping electrons in the color centers of the photocathode.

Abstract: A method and system for determining at least one property of a strobe cover are disclosed. The determined property of the strobe cover may then be analyzed to determine whether it is the proper property for the strobe device. The property of the strobe cover may include the color of the strobe cover (such as clear, blue, amber, etc.), the shape of the strobe cover (such as a strobe cover with a lens or a strobe cover without a lens), the material of the strobe cover, etc. The method and system may include determining the property of the strobe cover and checking whether the determined property is the expected property of the strobe cover (such as the expected color of the strobe cover). The strobe cover may include one or more property indicators. The one or more property indicators may interface with a circuit, such as mechanically interface with the circuit, in order for the circuit to determine the property of the strobe cover.

Abstract: A Signal generation and correction circuit with an LED diode (D1) and a photo-transistor (Q1) having corresponding inputs and outputs (d1e, d1a and q1e, q1a), as well as connecting lines (1, 2) leading to current terminals (A, B). The inputs and outputs (d1e, d1a) and/or (q1e, q1a) of the diode (D1) and the photo cell (Q1) arc connected so as to form a parallel circuit, wherein a resistor (R2) is arranged in the photo-transistor line (3) between the output (q1a) and the node (K) with the connecting line (2) and wherein a resistor (R1) is arranged in the line (2) between the node (K) and the current terminal (B). A transistor (Q2) is connected with its base (q2b) to the output (q1a) or the photo-transistor line (3), whereas the collector terminal (q2c) is connected via a resistor (R3) to the connecting line (1). The collector current has a value of 0 when a photo current flows in the photo transistor (Q1).

Abstract: The present invention aims to provide a display device comprised of a matrix array of pixels on a monolithic screen, each pixel addressed by an infrared scanning laser. The screen is primarily a phototransistor circuit, which produces a light output at each pixel on which the laser scans. As the laser strikes a photosensitive region on the display, hole and electron pairs are created and they persist to provide light output of a slowly degrading intensity. Reverse polarizing the transistor circuit terminates light output. Modulating the laser's duration and or intensity provides a proportional intensity output at each pixel. The display screen is designed to be removable from its location within a housing.