Abstract: The invention provides an antenna for wireless devices which improves matching of the main antenna element and parasitic antenna element in the antenna. The antenna of the invention comprises a main antenna element and a parasitic antenna element, the main antenna element and the parasitic antenna element being separated from each other, a matching element is connected between the main antenna element and the parasitic antenna element, with an end of the matching element being electrically connected to a conductor strip of the main antenna element, and the other end being electrically connected to a conductor strip of the parasitic antenna element. Optimized antenna performance can be achieved by adjusting position and value of the matching element.

Abstract: According to various aspects, exemplary embodiments are provided of antenna radial systems. In one exemplary embodiment, an antenna radial system generally includes a washer having a channel disposed along a first side of the washer. A radial includes a locking portion configured to be received within the channel. The radial also includes elongate portions extending outwardly from the locking portion such that an angle is defined between each elongate portion and the locking portion. A bushing cooperates with the washer for sandwiching the radial's locking portion therebetween to thereby help retain the radial's locking portion within the channel.

Abstract: Exemplary embodiments are provided of omnidirectional MIMO antennas with polarization diversity. In one exemplary embodiment, an omnidirectional MIMO antenna generally includes an array of radiating antenna elements having a linear horizontal polarization and radiating omnidirectionally in azimuth. The antenna also includes at least one radiating antenna element having a linear vertical polarization and radiating omnidirectionally in azimuth. The vertically polarized radiating antenna is spaced-apart from the array. The antenna is operable for producing omnidirectional, vertically polarized coverage for at least one port, as well as omnidirectional, horizontally polarized coverage for at least one other port.

Abstract: The present invention relates to an antenna assembly comprising a support structure for carrying a radiating structure and at least one feeding clip, the antenna assembly is provided to be mounted on a PCB in a mobile communication device, the support structure comprises a top side part which is to be mounted substantially parallel with the PCB, the top side part is positioned, when mounted on the PCB, at a first distance from the PCB, and the radiating structure comprises at least one contact area located on the support structure. The antenna assembly is characterised in that the contact area for the radiating structure is located at a position on the support structure where a distance between the contact area and the PCB is less than the distance between said top side part and the PCB. The invention also relates to a feeding clip.

Abstract: A multi-band antenna device for a portable radio communication device has first and second radiating elements (10, 20). A controllable switch (30) is arranged between the radiating elements for selectively interconnecting and disconnecting thereof. The state of the switch is controlled by means of a control voltage input (VSwitch). A filter (40) that blocks radio frequency signals is arranged between the feeding portion and the control voltage input. A DC blocking arrangement (50) is arranged between a grounding portion (14) on the first radiating element and ground wherein the first and second radiating element are generally planar and arranged at a predetermined distance above a ground plane. By means of this arrangement, two broad and spaced apart frequency bands are obtained with retained performance and small overall size of the antenna device. A communication device comprising such an antenna device is also provided.

Abstract: An antenna assembly is provided that includes an antenna element depending from an antenna mounting base. The mounting base includes a shaft portion that uniformly tapers from a mounting end portion to a projecting end portion. The shaft portion includes grooves, or flutes, that each extends from the mounting end portion toward the projecting end portion, and that each has a curvature about an axis of the shaft portion. The grooves provide the shaft portion with an asymmetrical cross-sectional area that causes airflow impinging on the shaft portion to generate turbulence and scatter low air pressure regions that tend to form locally around the shaft portion. As a result, small vibrations generated by the low pressure regions are suppressed, and whistling sounds, noises, etc. associated with the vibrations may be reduced.

Abstract: An antenna assembly is provided that includes an antenna element depending from an antenna mounting base. The mounting base includes a shaft portion that uniformly tapers from a mounting end portion to a projecting end portion. The shaft portion includes grooves, or flutes, that each extends from the mounting end portion toward the projecting end portion, and that each has a curvature about an axis of the shaft portion. The grooves provide the shaft portion with an asymmetrical cross-sectional area that causes airflow impinging on the shaft portion to generate turbulence and scatter low air pressure regions that tend to form locally around the shaft portion. As a result, small vibrations generated by the low pressure regions are suppressed, and whistling sounds, noises, etc. associated with the vibrations may be reduced.

Abstract: Disclosed are a sliding opening and closing device and a portable terminal having the same. According to the first embodiment of the present invention, a slide plate is linked to a main plate to be slidable in one direction. Also, the main plate supports an elastic part so as to generate an elasticity power in one direction. A power transformation member receives the elasticity power of the elastic member, and transmits the elasticity power to the slide plate in the direction of the opening or the closing according to the position of the slide plate.

Abstract: The present invention relates to a method of production of an antenna pattern having a predetermined general outline, with an ink jet printer, laser activation device or similar device. The device creates the antenna pattern with a plurality of empty inner portions within the general outline.

Abstract: A quad-band antenna device (10) for a portable radio communication device comprises two radiating elements (12, 14) of different lengths and two common conductors (18, 20) of different lengths. One of the common conductors can be selectively connected in and out with respect to radio frequency signals in order to adjust the total electrical length of the antenna device, thereby making it operable in four different frequency bands.

Abstract: According to various aspects, exemplary embodiments are provided of contacts that may be compatible with surface mount technology. The contacts may be surface mountable for establishing an electrical pathway (e.g., electrical grounding contact, etc.) from at least one electrically-conductive surface on the substrate to another electrically-conductive surface (e.g., EMI shield, battery contact, etc.). In one exemplary embodiment, a contact generally includes a resilient dielectric core member. At least one outer electrically-conductive layer is electrocoated onto the resilient dielectric core member. A solderable electrically-conductive base member may be coupled to the resilient core member and/or the outer electrically-conductive layer. The base member may be in electrical contact with the outer electrically-conductive layer.

Abstract: An antenna device for use in a portable radio communication device comprises a ground plane (110), a microstrip line (114) connected to a feed point (116) for feeding and/or receiving radio frequency signals. A package (120) having an electrically conductive housing (122) is provided in the radio communication device, wherein the housing is provided above the ground plane and the microstrip line, wherein the housing is galvanically insulated from the microstrip line, and wherein the housing is capacitively coupled to the microstrip line. The antenna device thus has a large radiating area and thus providing better performance of the device. Also, an already existing part in the radio communication device, e.g., a battery package, can be used also as radiating element, saving space and costs.

Abstract: According to various aspects of the present disclosure, exemplary embodiments are of assemblies capable of providing board level EMI shielding and heat dissipation of one or more electrical components. Other aspects relate to components of such assemblies. Further aspects relate to methods of using EMI shielding and thermal management assemblies. Additional aspects relate to methods of making EMI shielding and thermal management assemblies, and methods of making the components thereof.

Abstract: According to various aspects, exemplary embodiments are provided of apparatus and methods relating to mounting antenna components, modules, and assemblies, such as antenna modules or RF amplifier modules. In an exemplary embodiment, a fastener includes a clamping portion. An actuator is configured to convert a rotational force applied for rotating the fastener into a clamping force applied to the mounting surface generally between the at least one antenna component and the clamping portion of the fastener, to thereby mount the at least one antenna component to the mounting surface.

Abstract: Electromagnetic-energy absorbing materials are combined with thermally conductive materials, such as those used for thermal management in association with electronic equipment, thereby suppressing the transmission of electromagnetic interference (EMI) therethrough. Disclosed are materials and processes for combining EMI-absorbing materials with thermally conductive materials thereby improving EMI shielding effectiveness in an economically efficient manner. In one embodiment, a thermally conductive EMI absorber is prepared by combining an EMI-absorbing material (for example, ferrite particles) with a thermally conducting material (for example, ceramic particles), each suspended within an elastomeric matrix (for example, silicone).

Abstract: A portable terminal generally includes a first or main body and a second or sub-body. The sub-body is slidable relative to the main body between a closed position and an opened position. The sub-body is configured to drop downwardly into a stepped-down portion of the main body when the sub-body is in the opened position. At least one biasing device or elastic means may be provided for applying a force for biasing the sub-body to drop downwardly towards the stepped-down portion.

Abstract: Disclosed are a sliding opening and closing device and a portable terminal having the same. According to the first embodiment of the present invention, a slide plate is linked to a main plate to be slidable in one direction. Also, the main plate supports an elastic part so as to generate an elasticity power in one direction. A power transformation member receives the elasticity power of the elastic member, and transmits the elasticity power to the slide plate in the direction of the opening or the closing according to the position of the slide plate.

Abstract: Disclosed herein is a multi-step hinge. The hinge includes a housing. A rotary member is rotatably installed inside of the housing. The rotary member has a retainer groove formed in the outer circumferential face thereof. A stopper is slidably installed at either side of the rotary member inside of the housing. The stopper has a retainer protrusion formed so as to be engaged with the retainer groove. A resilient member is disposed between the housing and the stopper. A portable terminal having the multi-step hinge is also disclosed.

Abstract: According to various exemplary embodiments, apparatus, systems, and methods are disclosed for use with antenna systems operable for receiving first and second signals having respective first and second frequencies. In one exemplary embodiment, a controller selectively controls whether an amplifier is electrically powered via a first receiver associated with the first frequency or a second receiver associated with the second frequency depending on whether the first receiver, second receiver, or both are present and activated.

Abstract: According to various aspects, exemplary embodiments are provided of shielding apparatus suitable for use in providing electromagnetic interference shielding for one or more electrical components on a substrate. In one exemplary embodiment, a shielding apparatus generally includes first and second walls. The first wall includes laterally spaced-apart detent protrusions. The second wall includes an edge portion disposed relative to the first wall such that an interface between the edge portion of the second wall and the first wall is substantially sealed against the ingress and/or egress of electromagnetic interference through the interface. The edge portion of the second wall is engaged generally between and laterally confined by the laterally spaced-apart detent protrusions of the first wall, such that the laterally spaced-apart detent protrusions inhibit movement of the second wall relative to the first wall.