Abstract: A method is provided for controlling transponder replies to Mode-S interrogation signals. The method includes receiving Mode-S signals containing P5 and P6 pulses each having certain amplitudes. Each P6 pulse contains a sync phase reversal (SPR) signal followed by a data segment containing Mode-S data. The P5 pulse is asynchronous with respect to the P6 pulse and is timed to overlay the SPR signal. The method includes, analyzing each P5 and corresponding P6 pulse, identifying the SPR signal correctly in the received Mode-S signals in which the amplitude of the P6 pulse is at least 12 dB greater than the amplitude of the P5 pulse and in no more than 2% of the received Mode-S signals in which the amplitude of the P6 pulse is at least 3 dB less than the amplitude of the P5 pulse, and replying to the Mode-S signals where the SPR signal is correctly identified.

Abstract: A Mode-S transponder is provided for detecting synchronization phase reversal (SPR) signal. The transponder includes a receiver for receiving a Mode-S signal that contains a P6 pulse having a Mode-S data segment and an SPR signal therein. The transponder also includes a phrase detector that detects a phase change between first and second states in the received Mode-S signal. The phase detector includes an SPR qualifier that determine whether, following a state change, the Mode-S signal remains at one of the first and second states for at least a predetermined minimum time sufficient to qualify as a detector enable signal.

Abstract: An electronic equipment module, as well as a system and a method for mounting electronic equipment modules are disclosed, an electronic equipment module is provided as a symmetrical casting. The electronic equipment module includes a first chassis unit which attaches to a second chassis unit. Each chassis unit has a mounting recess adapted to receive one or more circuit assemblies. The mounting recesses can be separated by a cover applied to one unit, the other unit, or both. The module is normally mounted within a unit rack, and thus, can have a removably attachable, and re-orientable keyed surface on its rear face which mates with a corresponding keyed surface on the interior surface of the unit rack. The mounting system includes a mounting frame, a plurality of electronic equipment modules, and a unit rack coupled to at least one of the electronic equipment modules and the mounting frame.

Abstract: Systems and methods are provided for integrating cockpit controls and data associated with the controls into a single interface having a bezel surrounding a single display. Furthermore in one embodiment, a system includes two bezels having individual and duplicate controls affixed thereon, where each bezel surrounds a display operable to present data related to the controls. Moreover, the bezels are proximate to one another. Additionally in one embodiment, a system, having an audio control panel interposed between two bezels, is provided.

Abstract: A DMA computer system (10) for driving a peripheral device such as an LCD display (12) of a GPS receiver without stealing excessive cycles from a CPU (18). The DMA computer system (10) includes a CPU (18), a first memory (20) that may be written to or read by the CPU (18), a second memory (22) that may be written to or read by the CPU (18), and a DMA controller (24) coupled with the CPU (18) and the second memory (22). The DMA controller (24) is operable to: read data from the second memory (22) and transfer the data to the peripheral device; delay the CPU (18) from accessing the second memory (22) while the DMA controller (24) is reading data from the second memory (22); enable the CPU (18) to regain access to the second memory (22) once the DMA controller (24) has finished reading data from the second memory (22); and allow the CPU (18) to access the first memory (20) without delay even while the DMA controller (24) is reading data from the second memory (22).