Abstract: A conductive layer includes a microwave transformer for scaling the intensity of a microwave signal of a first frequency by a scaling factor. The transformer includes a first physical area delimited with a closed curve on the conductive layer for receiving the microwave signal from a first space angle and re-emitting a ray of the microwave signal to a second space angle. A ratio of the first physical area to the second physical area is smaller than 0.5. The ratio of the first effective area to the first physical area is larger than the ratio of the second effective area to the second physical area. The scaling factor is the ratio of the maximal intensity of the re-emitted ray and the intensity of a ray through an open aperture having a physical area equivalent to the second physical area in the same direction than the re-emitted ray.

Abstract: A wall or façade structure for improving quality of reception of a wireless communication device inside a building from a base station located outside of the building. The building has the structure as a part of a building envelope. The structure, which is configured to boost transmission of electromagnetic signals through the building envelope, includes at least one electrically conductive low emissivity surface, a first aperture and a second aperture. The apertures are isolated from each other for providing narrow aperture diffraction and to obtain diversity reception at a first frequency in shadow areas inside the building. A distance between the apertures is between 1 and 10 meters to provide an envelope correlation coefficient of less than 0.1 for said apertures at the first frequency.

Abstract: A device for enhanced electromagnetic communication through a coated transparent substrate is provided. The device includes a first transparent conductive (TC) layer having a first surface and a second TC layer having a second surface. The first surface is parallel to the second surface. The device also includes a first section extending through the first TC layer from the first surface and aligned with an axis that extends from the first surface to the second surface. The first section is configured to enhance electromagnetic communication through the coated transparent substrate. The device further includes a second section extending through the second TC layer from the second surface and offset from the axis that extends from the first surface to the second surface. The second section is configured to enhance electromagnetic communication through the coated transparent substrate.

Abstract: A device for enhanced microwave permeability through a coated transparent substrate includes a first surface of the device and a second surface of the device each forming an exterior boundary of the device. The device includes a first section extending through the device from the first surface to the second surface. The first section enhances a permeability of a first microwave band through the coated transparent substrate. The device also includes a second section extending through the device from the first surface to the second surface. The second section enhances a permeability of a second microwave band through the coated transparent substrate. The device further includes a third section extending through the device. The third section includes a location where the first section and the second section merge. The third section enhances a permeability of a third microwave band through the coated transparent substrate.

Abstract: A conductive layer includes a microwave transformer for scaling the intensity of a microwave signal of a first frequency by a scaling factor. The transformer includes a first physical area delimited with a closed curve on the conductive layer for receiving the microwave signal from a first space angle and re-emitting a ray of the microwave signal to a second space angle. A ratio of the first physical area to the second physical area is smaller than 0.5. The ratio of the first effective area to the first physical area is larger than the ratio of the second effective area to the second physical area. The scaling factor is the ratio of the maximal intensity of the re-emitted ray and the intensity of a ray through an open aperture having a physical area equivalent to the second physical area in the same direction than the re-emitted ray.

Abstract: A device and method for repeating wireless electromagnetic signals from a first side of a space divider to a second side of the space divider. The device provides discriminated communication channels at a first frequency range between the two spaces. The device includes a dual polarized repeater including a dielectric member, and conductive members as a group of radiators. The dual polarized repeater is installed into a discontinuity region of the space divider and provides an increment of a bistatic radar cross section through the discontinuity region for a first and second incident signals. A part of the first incident signal is scattered as a first beam by the device, and a part of the second incident signal is scattered as a second beam on the second side of the space divider. The dual polarized repeater provides cross polarization discrimination for the first and second incident signals.

Abstract: A device for receiving and re-radiating electromagnetic signals. The device includes at least a wave guide with a first set of slot radiators for receiving electromagnetic signals, and a second set of slot radiators for transmitting electromagnetic signals generated on the basis of the received electromagnetic signals in the waveguide. The first set of slot radiators includes one or more slot radiators, and the second set of slot radiators includes one or more slot radiators. The device also relates to a method for receiving and re-radiating electromagnetic signals by a device including at least a waveguide, and the use of the device as a repeater of electromagnetic signals, for transferring electromagnetic signals through a structure, and/or as a building product.

Abstract: A wall or façade structure for improving quality of reception of a wireless communication device inside a building from a base station located outside of the building. The building has the structure as a part of a building envelope. The structure, which is configured to boost transmission of electromagnetic signals through the building envelope, includes at least one electrically conductive low emissivity surface, a first aperture and a second aperture. The apertures are isolated from each other for providing narrow aperture diffraction and to obtain diversity reception at a first frequency in shadow areas inside the building. A distance between the apertures is between 1 and 10 meters to provide an envelope correlation coefficient of less than 0.1 for said apertures at the first frequency.

Abstract: In an embodiment, conductive structural members of a device acting as NFC antenna are described. According to an embodiment, a device comprises: two conductive structural members, each comprising a first electrical end and a second electrical end, a dielectric isolation being configured between the first electrical end of the first conductive structural member and the first electrical end of the second conductive structural member; two NFC antenna feeds, the first feed being electrically coupled with the first electrical end of the first member, the second feed being electrically coupled with the first electrical end of the second member; two grounding components, one each grounding the second electrical end of the conductive structural members; at least one additional antenna feed configured for a frequency other than that of NFC, coupled to either of the two members.

Abstract: A building material including at least one electrically conductive low emissivity surface provided with an opening for boosting the transmission of an electromagnetic signal through the building material, the opening having a substantially lower electrical conductivity than the low emissivity surface. The edge of the opening provided in said low emissivity surface constitutes at least one closed edge curve, and said opening defines a closed envelope curve so that said opening is within the closed envelope curve, and the surface defined by the closed envelope curve has an area substantially larger than the area of the opening within the closed envelope curve and a length substantially smaller than the length of the closed envelope curve, whereby at least one such low emissivity surface area is formed within the area defined by the closed envelope curve, at which the closed envelope curve is not congruent with the edge curve.

Abstract: A building material including at least one electrically conductive low emissivity surface provided with an opening for boosting the transmission of an electromagnetic signal through the building material, the opening having a substantially lower electrical conductivity than the low emissivity surface. The edge of the opening provided in said low emissivity surface constitutes at least one closed edge curve, and said opening defines a closed envelope curve so that said opening is within the closed envelope curve, and the surface defined by the closed envelope curve has an area substantially larger than the area of the opening within the closed envelope curve and a length substantially smaller than the length of the closed envelope curve whereby at least one such low emissivity surface area is formed within the area defined by the closed envelope curve, at which the closed envelope curve is not congruent with the edge curve.

Abstract: A device for receiving and re-radiating electromagnetic signals. The device includes at least a wave guide with a first set of slot radiators for receiving electromagnetic signals, and a second set of slot radiators for transmitting electromagnetic signals generated on the basis of the received electromagnetic signals in the waveguide. The first set of slot radiators includes one or more slot radiators, and the second set of slot radiators includes one or more slot radiators. The device also relates to a method for receiving and re-radiating electromagnetic signals by a device including at least a waveguide, and the use of the device as a repeater of electromagnetic signals, for transferring electromagnetic signals through a structure, and/or as a building product.

Abstract: A device for receiving and re-radiating electromagnetic signals. The device includes at least a waveguide with a first set of slot radiators for receiving electromagnetic signals, and a second set of slot radiators for transmitting electromagnetic signals generated on the basis of the received electromagnetic signals in the waveguide. The first set of slot radiators includes one or more slot radiators, and the second set of slot radiators includes one or more slot radiators. The device also relates to a method for receiving and re-radiating electromagnetic signals by a device including at least a waveguide, and the use of the device as a repeater of electromagnetic signals, for transferring electromagnetic signals through a structure, and/or as a building product.

Abstract: An electrical device is disclosed, comprising a conductive chassis having a groove, wherein the conductive chassis comprises a housing or a frame of the electrical device; and dielectric material filled inside the groove; wherein the groove is configured as a waveguide and transmits a signal of the electrical device.

Abstract: According to one aspect, there is provided a wireless radio module comprising a millimeter wave wireless communication transceiver configured to output radar signals for physiological measurement, a millimeter wave antenna array connected to the millimeter wave wireless communication transceiver and configured to transmit the radar signals and to receive reflected radar signals, and a processing unit configured to analyze the received reflected radar signals to determine changes in a spectrum reflecting at least one of heart rate or respiration.

Abstract: In one example, a contactless millimeter wave coupler comprises a metallic plate. The contactless millimeter wave coupler further comprises a crossed slot arranged in the metallic plate. The contactless millimeter wave coupler further comprises an antenna arrangement mounted beneath the crossed slot. The antenna arrangement comprises a first linearly polarized antenna and a second linearly polarized antenna arranged in a cross configuration relative to each other. The contactless millimeter wave coupler further comprises a wave guiding layer of dielectric material arranged above the antenna arrangement in alignment with the crossed slot and the antenna arrangement.

Abstract: In an embodiment, conductive structural members of a device acting as NFC antenna are described. According to an embodiment, a device comprises: two conductive structural members, each comprising a first electrical end and a second electrical end, a dielectric isolation being configured between the first electrical end of the first conductive structural member and the first electrical end of the second conductive structural member; two NFC antenna feeds, the first feed being electrically coupled with the first electrical end of the first member, the second feed being electrically coupled with the first electrical end of the second member; two grounding components, one each grounding the second electrical end of the conductive structural members; at least one additional antenna feed configured for a frequency other than that of NFC, coupled to either of the two members.

Abstract: An antenna arrangement comprises a casing comprising a flange and a collar extending upwards from the flange. A magnetic loop antenna coil covers an outer surface of at least one of the flange and the collar at least partly. A magnetic material layer is arranged between the magnetic loop antenna coil and the outer surface of the flange and the collar to guide the magnetic flux generated by the magnetic loop antenna coil, the magnetic material layer covering both the flange and the collar at least partly.

Abstract: An electrical device is disclosed, comprising a conductive chassis having a groove, wherein the conductive chassis comprises a housing or a frame of the electrical device; and dielectric material filled inside the groove; wherein the groove is configured as a waveguide and transmits a signal of the electrical device.

Abstract: In one example, a contactless millimeter wave coupler comprises a metallic plate. The contactless millimeter wave coupler further comprises a crossed slot arranged in the metallic plate. The contactless millimeter wave coupler further comprises an antenna arrangement mounted beneath the crossed slot. The antenna arrangement comprises a first linearly polarized antenna and a second linearly polarized antenna arranged in a cross configuration relative to each other. The contactless millimeter wave coupler further comprises a wave guiding layer of dielectric material arranged above the antenna arrangement in alignment with the crossed slot and the antenna arrangement.