Linear array antenna systems are used in X-scan aircraft location systems and methods able to avoid disabling azimuth error conditions caused by multipath reflections under roll and pitch conditions during aircraft carrier landing operations. Aircraft azimuth and elevation data is derived based upon time of incidence at an aircraft location of two transverse, diagonally oriented, scanned antenna beams. The aircraft location data is derived by comparing time of incidence data with data on known timing of scanning of the beams, which have diagonally-oriented fan beam patterns. A plurality of vertically oriented radiating elements are typically positioned along a line diagonal to the vertical to produce a diagonally oriented fan beam pattern. Beam scanning results from relative adjustment of signal portions supplied to the radiating elements. While beam scanning is nominally diagonal, the vertical radiation cut-off characteristics of the elements constrain vertical radiation and thereby enhance provision of a desired horizontally oriented approach window. A particular embodiment uses spaced feeds along a traveling-wave input waveguide, with coupling to radiating elements by interconnecting waveguide sections of successively longer length, to provide broad-band equalization of signal supply path lengths.

An aircraft take-off and landing system, wherein a symbol of a specified configuration is employed as an instrument means for take-off and landing. This symbol is formed by directed extended references made up of electromagnetic pencil beams with a wavelength which is within atmospheric windows, produced by at least one source of electromagnetic radiation, positioned on a flight platform. The electromagnetic pencil beams are oriented in space so that they determine the configuration of a symbol and, simultaneously, indicate the course and glide slope of an aircraft take-off and landing path, set a spatical take-off and landing corridor wherein this path lies, and show additionally various limits of a take-off and landing platform or various marker points of an estimated take-off and landing path. The method of aircraft take-off and landing, according to the proposed system, consists in flying an aircraft on a symbol of a specified configuration, its distortions being indicative of the aircraft's deviation from the estimated take-off and landing path and their magnitude being indicative of the deviation direction and value. The proposed system may be made purely instrumental or visual, permitting both automatic and manual flying of an aircraft and is 100 or 1,000 times more accurate than conventional systems with localizers and glide slope transmitters. The aircraft flying method, according to the proposed system, is characterized by exceptional simplicity and reliability, it remains consistent at all stages of a take-off or landing path.

A microwave locating system is provided for locating known features and distinguishing between different types of features. The locating system includes a plurality of modulated microwave power sources located on known features and radiating modulated microwave signals having modulated frequencies selected in accordance with the known features. A video detection sensor camera is located remote from the sources for sensing microwave signals within a field of view and providing location signals for each of the sources. The camera includes an array of receiver elements which provide narrow bandwidth filtering so as to identify received signals as one of a plurality of selected modulated frequencies. The locating system further provides an image of the location signals which distinguishes between different selected located features.

An aircraft take-off and landing system, wherein a symbol of a specified configuration is employed as an instrument means for take-off and landing. This symbol is formed by directed extended references made up of electromagnetic pencil beams with a wavelength which is within atmospheric windows, produced by at least one source of electromagnetic radiation, positioned on a flight platform. The electromagnetic pencil beams are oriented in space so that they determine the configuration of a symbol and, simultaneously, indicate the course and glide slope of an aircraft take-off and landing path, set a spatical take-off and landing corridor wherein this path lies, and show additionally various limits of a take-off and landing platform or various marker points of an estimated take-off and landing path. The method of aircraft take-off and landing, according to the proposed system, consists in flying an aircraft on a symbol of a specified configuration, its distortions being indicative of the aircraft's deviation from the estimated take-off and landing path and their magnitude being indicative of the deviation direction and value. The proposed system may be made purely instrumental or visual, permitting both automatic and manual flying of an aircraft and is 100 or 1,000 times more accurate than conventional systems with localizers and glide slope transmitters. The aircraft flying method, according to the proposed system, is characterized by exceptional simplicity and reliability, it remains consistent at all stages of a take-off or landing path.

An aircraft take-off and landing system, wherein a symbol of a specified configuration is employed as an instrument means for take-off and landing. This symbol is formed by directed extended references made up of electromagnetic pencil beams with a wavelength which is within atmospheric windows, produced by at least one source of electromagnetic radiation, positioned on a flight platform. The electromagnetic pencil beams are oriented in space so that they determine the configuration of a symbol and, simultaneously, indicate the course and glide slope of an aircraft take-off and landing path, set a spatial take-off and landing corridor wherein this path lies, and show additionally various limits of a take-off and landing platform or various marker points of an estimated take-off and landing path. The method of aircraft take-off and landing, according to the proposed system, consists in flying an aircraft on a symbol of a specified configuration, its distortions being indicative of the aircraft's deviation from the estimated take-off and landing path and their magnitude being indicative of the deviation direction and value. The proposed system may be made purely instrumental or visual, permitting both automatic and manual flying of an aircraft and is 100 or 1,000 times more accurate than conventional systems with localizers and glide slope transmitters. The aircraft flying method, according to the proposed system, is characterized by exceptional simplicity and reliability, it remains consistent at all stages of a take-off or landing path.