A multi-frequency wireless access device including a first waveguide having a pair of parallel metal plates with open sides and a slot in one of the metal plates, the slot permitting radiation to leak out, the leaked radiation illuminating a range of angles depending on frequency.

A multi-frequency wireless access device including a first waveguide having a pair of parallel metal plates with open sides and a slot in one of the metal plates, the slot permitting radiation to leak out, the leaked radiation illuminating a range of angles depending on frequency.

Examples disclosed herein relate to a radiating structure having a plurality of slotted transmission lines, each transmission line including a plurality of boundary lines defining each transmission line, wherein slots are positioned in each transmission line and include a first set of slots interspersed with a second set of slots, the second set of slots having a size smaller than the first set of slots, and a plurality of irises positioned proximate each of the slots and along the length of each transmission line. The radiating structure also has an array of radiating elements proximate the slotted transmission lines so as to receive a transmission signal from the slotted transmission lines and generate a radiation pattern corresponding to the transmission signal.

This document describes a folded waveguide for antenna. The folded waveguide may be an air waveguide and includes a hollow core that forms a rectangular opening in a longitudinal direction at one end, a closed wall at an opposite end, and a sinusoidal shape that folds back and forth about a longitudinal axis that runs in the longitudinal direction through the hollow core. The hollow core forms a plurality of radiation slots, each including a hole through one of multiple surfaces that defines the hollow core. The radiation slots are arranged on the one surface to produce a particular antenna pattern. The radiation slots and sinusoidal shape enable the folded waveguide to prevent grating lobes from appearing in the particular antenna pattern on either side of a horizontal-polarity, main beam, or to prevent X-band lobes from appearing in the particular antenna pattern on either side of a vertical-polarity, main beam.

This document describes a folded waveguide for antenna. The folded waveguide may be an air waveguide and includes a hollow core that forms a rectangular opening in a longitudinal direction at one end, a closed wall at an opposite end, and a sinusoidal shape that folds back and forth about a longitudinal axis that runs in the longitudinal direction through the hollow core. The hollow core forms a plurality of radiation slots, each including a hole through one of multiple surfaces that defines the hollow core. The radiation slots are arranged on the one surface to produce a particular antenna pattern. The radiation slots and sinusoidal shape enable the folded waveguide to prevent grating lobes from appearing in the particular antenna pattern on either side of a horizontal-polarity, main beam, or to prevent X-band lobes from appearing in the particular antenna pattern on either side of a vertical-polarity, main beam.

A manufacturing method of a TFT substrate is a manufacturing method of a TFT substrate in which each of a source electrode and a drain electrode includes a lower source metal layer and an upper source metal layer. The manufacturing method of the TFT substrate includes the steps of: forming an upper source metal layer by etching an upper conductive film with the first resist layer as an etching mask; forming a lower source metal layer by etching a lower conductive film; removing the first resist layer and forming a second resist layer covering the upper source metal layer; and forming a source contact portion and a drain contact portion by etching a contact layer by dry etching with the second resist layer as an etching mask.

A manufacturing method of a TFT substrate is a manufacturing method of a TFT substrate in which each of a source electrode and a drain electrode includes a lower source metal layer and an upper source metal layer. The manufacturing method of the TFT substrate includes the steps of: forming an upper source metal layer by etching an upper conductive film with the first resist layer as an etching mask; forming a lower source metal layer by etching a lower conductive film; removing the first resist layer and forming a second resist layer covering the upper source metal layer; and forming a source contact portion and a drain contact portion by etching a contact layer by dry etching with the second resist layer as an etching mask.

Formed waveguide antennas using one or metal sheets can improve the materials and manufacturing process of a radar assembly. For example, the radar system can include a printed circuit board (PCB) and a metal sheet attached to the PCB. The metal sheet can be formed to provide multiple waveguide antennas that each include multiple waveguide channels. Multiple radiation slots can be formed on a surface of each of the multiple waveguide channels. The PCB can include an MIMIC and a thermally conductive material covering a portion of a first and a second surface of the PCB. The metal sheet can also be formed to provide a shield for the MIMIC. In this way, the described techniques and systems permit the waveguide antennas to formed with materials and a manufacturing process that reduce costs while still providing high performance (e.g., minimized loss).

A container is provided that includes an RFID module, and further includes an insulating base material that forms an outer shape of the container; a metal film formed on a first main surface of the insulating base material; and a slit formed in the metal film. Moreover, the RFID module includes an RFIC element, a filter circuit that transmits a current caused by an electromagnetic wave at a unique resonance frequency serving as a communication frequency to the RFIC element, and first and second electrodes connected to the filter circuit. The metal film is formed to wrap around an outer periphery of the container in a direction intersecting the slit, and the first and second electrodes of the RFID module are electrically connected to the metal film across the slit formed between the first electrode and the second electrode.

RADAR sensor assemblies/modules, particularly those for vehicles. In some embodiments, the assembly may comprise a plurality of waveguides, each waveguide of the plurality of waveguides being defined by a waveguide groove. A slot may be positioned to extend along an axis of each of the plurality of waveguide grooves. Each of the waveguides may be further defined, at least in part, by a periodic feature that extends back and forth in a periodic manner along at least a portion of its respective waveguide and a plurality of periodic signal confinement structures, a first periodic signal confinement structure of which may extend adjacent to a first side of each of the plurality of waveguides, and a second periodic signal confinement structure which may extend along a second side of each of the plurality of waveguides opposite the first side.