A radome having an integrated antenna array and an antenna assembly having the same are described herein. A method for fabricating a radome having an integrated antenna array is also described herein. In one example, a radome is provided that includes a radome shell and an antenna array. The antenna array has a radiating surface and a backside surface. The radome shell is affixed to the antenna array forming an independent unitary structure separable from other components of an antenna assembly.

A radome having an integrated antenna array and an antenna assembly having the same are described herein. A method for fabricating a radome having an integrated antenna array is also described herein. In one example, a radome is provided that includes a radome shell and an antenna array. The antenna array has a radiating surface and a backside surface. The radome shell is affixed to the antenna array forming an independent unitary structure separable from other components of an antenna assembly.

The present disclosure relates to a reader, such as a reader for a physical access control system. The reader can include first and second antennas, each designed or configured for receiving ultra-wide band (UWB) signals. The reader can also include a mounting plane configured for mounting the reader to a surface. An axis aligning the first and second antennas can be arranged substantially perpendicular relative the mounting plane. A material can be provided between the first and second antennas The material can have a thickness that defines a distance between the first and second antennas of less than a half wavelength of the UWB signal through air (λ.sub.A/2), the material configured to slow down electromagnetic waves passing therethrough such that the thickness of the material provides an effective separation distance of the first and second antennas of at least a half wavelength of the UWB signal through air (λ.sub.A/2).

The invention is directed to a decorative vehicle element including a, preferably radio-transmissive, substrate having a first surface on a first side and a second surface on a second side; and a first surface, preferably radio-transmissive, decorative coating on the substrate, the decorative coating including a decorative layer consisting of a metal or consisting of an alloy including a metal; as well as a radar system including a radio wave transmitter, a radio wave receiver and a decorative element, especially radome.

Disclosed embodiments can pertain to process indicator enhancements. A process indicator can include a dye material that has electrical properties such as conductivity and capacitance that can be employed to determine whether observed conditions are acceptable or not to sterilize medical equipment. Furthermore, the indicators can employ amplification, a specialized antenna, or both to allow signals, such as an electronic property value, to be communicated through sterilization containers that can shield or degrade signals. A number and location of indicators can also be determined and utilized to assist in visual inspection of the indicators as well as automatic evaluation.

The present invention provides a radome substrate and a preparation method thereof. The radome substrate includes: 5 to 10 parts of polyphenylene ether resin, 70 to 85 parts of ceramic masterbatch, 10 to 15 parts of hollow microbead masterbatch, 1 to 3 parts of a compatibilizer, and 0.1 to 0.3 parts of a lubricant. The radome substrate prepared according to the method provided in the present invention has a high dielectric constant and stress cracking resistance performance.

A display apparatus and an antenna assembly are provided. The display apparatus includes: a display; a first circuit board including at least one electronic part configured to process an image signal for displaying an image on the display; a second circuit board including at least one antenna configured to transmit and receive a radio frequency (RF) signal for communication between the display apparatus and an external apparatus; and a spacer provided between the first circuit board and the second circuit board, and configured to space the first circuit board and the second circuit board apart from each other. Thus, radiation performance in the antenna is improved with easy design based on the structure of the display apparatus. Thus, radiation performance in the antenna is improved with easy design based on the structure of the display apparatus.

An electromagnetic-wave-transmissive module of a vehicle radar is provided to minimize a dielectric impact reflection effect, which occurs when an electromagnetic wave radiated from an antenna is transmitted through a radome and a transmissive cover The electromagnetic-wave-transmissive module includes one or more of a radome covering the antenna and a transmissive cover, which is disposed to be spaced apart from a front side of the antenna and through which a radio wave radiated from the antenna and then transmitted through the radome is subsequently transmitted. At least one coating layer, which includes PTFE and which has a dielectric permittivity higher than the dielectric permittivity of air and lower than the dielectric permittivity of the radome and the transmissive cover, is formed on the surface of at least one of the radome and the transmissive cover.

An electromagnetic-wave-transmissive module of a vehicle radar is provided to minimize a dielectric impact reflection effect, which occurs when an electromagnetic wave radiated from an antenna is transmitted through a radome and a transmissive cover The electromagnetic-wave-transmissive module includes one or more of a radome covering the antenna and a transmissive cover, which is disposed to be spaced apart from a front side of the antenna and through which a radio wave radiated from the antenna and then transmitted through the radome is subsequently transmitted. At least one coating layer, which includes PTFE and which has a dielectric permittivity higher than the dielectric permittivity of air and lower than the dielectric permittivity of the radome and the transmissive cover, is formed on the surface of at least one of the radome and the transmissive cover.

An electronic device that communicates a packet or a frame is described. This electronic device includes: at least an antenna having an antenna radiation pattern; an interface circuit; and an antenna cover that includes an integrated static lens, where the antenna cover is selected from a set of antenna covers that includes different integrated static lenses. During operation, the interface circuit may transmit, from the antenna, wireless signals corresponding to the packet or the frame, where the integrated static lens modifies the antenna radiation pattern of the antenna. For example, the integrated static lens may cause the wireless signals to converge or diverge. Alternatively, the integrated static lens may change an angular elevation of the antenna radiation pattern and/or may provide a correction for pathloss as a function of angle. Note that the integrated static lens may be a stepwise approximation to a predefined function.