The disclosure relates to the technical field of soil humidity measurement, in particular to a soil humidity microwave remote sensing device with multi-mode compatibility via GNSS-R and a method of using the same. The device includes a direct RHCP antenna, reflective RHCP antenna, a reflective LHCP antenna, a combiner, switches, preamplifiers, down-conversion modules, sampling and quantizing modules, a capturing and closed-loop tracking module, an open-loop tracking module, a position calculating and controlling module and a soil humidity inverting module. The soil humidity microwave remote sensing device with multi-mode compatibility via GNSS-R realizes flexibly switching among different GNSS-R soil humidity microwave remote sensing working modes, so that the soil remote sensing device can fully utilize advantages of the different working modes to realize compatible multi-mode observation. The method realizes multi-mode, non-contact and large-area soil humidity measurement by utilizing the GNSS reflected signals.

In some embodiments, a phased array antenna, includes a plurality of antenna modules arranged in an antenna lattice configuration to form the phased array antenna, wherein an antenna module of the plurality of antenna modules includes an antenna element packaged together with an amplifier.

Omni-directional orthogonally-polarized antenna system for MIMO applications are disclosed herein. An example antenna system can have two arrays of horizontally polarized radiating elements, and two arrays of vertically polarized radiating elements, each array having roughly 180-degree radiation pattern, disposed about a central axis in a common horizontal plane, arrays of common polarization separated by 180-degrees, such that MIMO processing of signals to the arrays of common polarization results in a radiation pattern that is substantially constant over 360-degrees in azimuth.

A circuitry for feeding an antenna structure includes an input for LHCP signals, an input for RHCP signals as well as four antenna outputs. In addition, the circuitry includes first, second and third quadrature hybrids as well as at least two delay lines. The first quadrature hybrid is coupled, on the input side, to the first and second inputs and is coupled, on the output side, to the second and third quadrature hybrids. The second quadrature hybrid is coupled, on the output side, to two of the four antenna outputs, the third quadrature hybrid being coupled, on the output side, to two further ones of the four antenna outputs. The at least two delay lines are arranged at two of the four antenna outputs.

An antenna device includes an antenna element and a dummy antenna element. The antenna element is configured to construct a patch antennae. The dummy antenna is coupled to a ground layer by a conductive through portion which pass through a substrate in a thickness direction. A position of the conductive through portion with respect to the dummy antenna element is a first position on a straight line that divides an angle between a first straight line and a second straight line, or a second position in the neighborhood of the first position. The first straight pass through a first feed point and a center of dummy antenna element. The second straight passing through a second feed point and the center. The first feed point and the second feed point being feed points when the dummy antenna element generates circularly polarized waves.

An antenna assembly configured to be mounted on a glass structure. The antenna assembly comprises a multilayer structure comprising i) a superstrate layer comprising a thin dielectric material; ii) an antenna layer on which the superstrate layer is disposed, the antenna layer comprising an electrically conducting material; and ii) a first substrate layer on which the antenna layer is disposed. The antenna assembly further comprises a housing in which the multilayer structure is disposed. The housing is adapted for attachment to a surface of the glass structure. A dielectric characteristic of the superstrate layer compensates for a dielectric characteristic of the glass structure in order to reduce the variability of the operating frequency of the antenna assembly.

The present disclosure provides a two-dimensional antenna system. The two-dimensional antenna system includes a transmitting antenna array and a receiving antenna array. The transmitting antenna array includes one or more circularly polarized transmitting antennas having a first direction of rotation. The receiving antenna array includes two or more first circularly polarized receiving antennas having a second direction of rotation arranged in a first direction, and two or more second circularly polarized receiving antennas having the second direction of rotation arranged in a second direction. The first direction is perpendicular to the second direction, and the first direction of rotation is opposite to the second direction of rotation.

A multiband patch antenna, a method for receiving radio frequency signals in multiple bands by a multiband patch antenna and a method of producing a patch element are disclosed. The antenna comprises a substrate layer having a first surface and a second surface and a base element on the first surface. A multi-resonance patch element comprising a pattern of outward extending resonance formations is provided on the second surface. At least two proximity feed elements configured for connection to a multiband hybrid coupler circuit and extending within the substrate layer from the first surface to the second surface are also provided. The multi-resonance patch element is configured to leave areas where the proximity feed elements extend to the second surface uncovered by the multi-resonance patch element.

Omni-directional orthogonally-polarized antenna system for MIMO applications are disclosed herein. An example antenna system can have two arrays of horizontally polarized radiating elements, and two arrays of vertically polarized radiating elements, each array having roughly 180-degree radiation pattern, disposed about a central axis in a common horizontal plane, arrays of common polarization separated by 180-degrees, such that MIMO processing of signals to the arrays of common polarization results in a radiation pattern that is substantially constant over 360-degrees in azimuth.

An antenna system includes a first substrate, the first substrate being a dielectric substrate, a first patch on a first surface of the dielectric substrate and a second patch on a second surface of the dielectric substrate. The first and second patches are coupled to form a first capacitor with the dielectric substrate. A second substrate is coupled to the first substrate and a ground layer is provided on a first surface of the second substrate. An antenna feed is coupled to the second substrate.