The present invention refers to an antenna less wireless handheld or portable device comprising a communication module including a radiating system capable of transmitting and receiving electromagnetic wave signals in a first frequency region and in a second frequency region, wherein the highest frequency of the first frequency region is lower than the lowest frequency of the second frequency region. The radiating system comprising a radiating structure and at least one internal port, wherein the input impedance of the radiating structure at the/each internal port when disconnected from the radiofrequency system has an imaginary part not equal to zero for any frequency of the first frequency region; and wherein said radiofrequency system modifies the impedance of the radiating structure, providing impedance matching to the radiating system in the at least two frequency regions of operation of the radiating system.

The present invention refers to an antenna less wireless handheld or portable device comprising a communication module including a radiating system capable of transmitting and receiving electromagnetic wave signals in a first frequency region and in a second frequency region, wherein the highest frequency of the first frequency region is lower than the lowest frequency of the second frequency region. The radiating system comprising a radiating structure and at least one internal port, wherein the input impedance of the radiating structure at the/each internal port when disconnected from the radiofrequency system has an imaginary part not equal to zero for any frequency of the first frequency region; and wherein said radiofrequency system modifies the impedance of the radiating structure, providing impedance matching to the radiating system in the at least two frequency regions of operation of the radiating system.

An antenna structure includes a side frame, a first feed portion, a second feed portion, and a first ground portion. The side frame defines a first gap and a second gap. The side frame is divided into a first radiating portion by the first gap and the second gap. When the first feed portion supplies current, the current flows through a first resonance section and is grounded through the first ground portion to activate a first operating mode and a second operating mode. When the first feed portion supplies current, the current flows through a second resonance section and is grounded through the second feed portion to activate a third operating mode. When the second feed portion supplies current, the current flows through the second resonance section and the first resonance section, and is grounded through the first ground portion to activate a fourth operating mode.

Devices and methods for implementing MIMO in metal ring structures using tunable electrically small antennas. In some embodiments, the metal ring structure includes a mobile device including electrically small antennas arranged on it, tunable band-stop circuits, wherein each of the electrically small antennas has a largest dimension that is substantially equal to or less than one-tenth of a length of a wavelength corresponding to a frequency within a communications operating frequency band. In some embodiments, the tunable electrically small antennas utilize parts of the metal ring structure of the mobile device as antenna radiators. The TESA are tunable for low-band frequencies between about 600 MHz-960 MHz. Additionally, the TESA have a wide bandwidth in high-band between about 1700 MHz-2700 MHz. In order to separate the TESA radiators from the rest of the metal ring structure, the radiators are connected by insulating material.

Devices and methods for implementing MIMO in metal ring structures using tunable electrically small antennas. In some embodiments, the metal ring structure includes a mobile device including electrically small antennas arranged on it, tunable band-stop circuits, wherein each of the electrically small antennas has a largest dimension that is substantially equal to or less than one-tenth of a length of a wavelength corresponding to a frequency within a communications operating frequency band. In some embodiments, the tunable electrically small antennas utilize parts of the metal ring structure of the mobile device as antenna radiators. The TESA are tunable for low-band frequencies between about 600 MHz-960 MHz. Additionally, the TESA have a wide bandwidth in high-band between about 1700 MHz-2700 MHz. In order to separate the TESA radiators from the rest of the metal ring structure, the radiators are connected by insulating material.

An antenna structure includes a housing, a feeding portion, and a connecting portion. The housing defines a gap and a groove. The housing forms a radiating portion and a coupling portion through the gap and the groove. A portion of the housing between the feeding portion and the gap forms a first radiating section. The connecting portion is electrically connected to one end of the coupling portion adjacent to the gap. When the feeding portion supplies current, the current flows through the feeding portion and the first radiating section, and is coupled to the connecting portion through the gap to activate a first operating mode. When the feeding portion supplies current, the current flows through the feeding portion and the first radiating section, and is coupled to the coupling portion through the gap to activate a second operating mode.

In a wireless communication device, an impedance matching circuit includes a first layered coil conductor one end of which is connected to a first I/O terminal, the first layered coil conductor includes loop conductors including a plurality of layers, and a second layered coil conductor one end of which is connected to the other end of the first layered coil conductor and the other end of which is respectively connected to a second I/O terminal, the second layered coil conductor includes loop conductors including a plurality of layers. On the surface of the wireless communication device, first and second terminal electrodes are connected via first and second in-plane conductors and first and second inter-layer conductors to any of the loop conductors of the first and second layered coil conductors. Connection locations of the first and second in-plane conductors to the first and second layered conductors determine the antenna element-side impedance seen by the first and second I/O terminals of the wireless IC chip.

In a wireless communication device, an impedance matching circuit includes a first layered coil conductor one end of which is connected to a first I/O terminal, the first layered coil conductor includes loop conductors including a plurality of layers, and a second layered coil conductor one end of which is connected to the other end of the first layered coil conductor and the other end of which is respectively connected to a second I/O terminal, the second layered coil conductor includes loop conductors including a plurality of layers. On the surface of the wireless communication device, first and second terminal electrodes are connected via first and second in-plane conductors and first and second inter-layer conductors to any of the loop conductors of the first and second layered coil conductors. Connection locations of the first and second in-plane conductors to the first and second layered conductors determine the antenna element-side impedance seen by the first and second I/O terminals of the wireless IC chip.

There is disclosed a reconfigurable antenna device comprising a substrate having first and second opposed ends and first and second opposed side edges, the substrate incorporating a main groundplane. The antenna device further comprises a dipole antenna having first and second arms each having a proximal portion and a distal portion, the proximal portions extending substantially adjacent and parallel to the first end of the substrate and the distal portions respectively extending substantially adjacent and parallel to the first and second side edges of the substrate. Distal ends of the first and second arms are connected to the main groundplane or otherwise grounded. Additionally, there is provided a main chassis antenna having first and second arms extending substantially adjacent and parallel to the first end of the substrate. The main chassis antenna is configured for excitation by RF currents in the main groundplane. Finally, there are provided first and second auxiliary chassis antennas, the first auxiliary chassis antenna being disposed at the first end of the substrate substantially adjacent to the proximal portion of first arm of the dipole antenna and the first arm of the main chassis antenna, and the second auxiliary chassis antenna being disposed at the first end of the substrate substantially adjacent to the proximal portion of the second arm of the dipole antenna and the second arm of the main chassis antenna. The first and second auxiliary chassis antennas are configured for excitation by RF currents in the main groundplane.

There is disclosed a reconfigurable antenna device comprising a substrate having first and second opposed ends and first and second opposed side edges, the substrate incorporating a main groundplane. The antenna device further comprises a dipole antenna having first and second arms each having a proximal portion and a distal portion, the proximal portions extending substantially adjacent and parallel to the first end of the substrate and the distal portions respectively extending substantially adjacent and parallel to the first and second side edges of the substrate. Distal ends of the first and second arms are connected to the main groundplane or otherwise grounded. Additionally, there is provided a main chassis antenna having first and second arms extending substantially adjacent and parallel to the first end of the substrate. The main chassis antenna is configured for excitation by RF currents in the main groundplane. Finally, there are provided first and second auxiliary chassis antennas, the first auxiliary chassis antenna being disposed at the first end of the substrate substantially adjacent to the proximal portion of first arm of the dipole antenna and the first arm of the main chassis antenna, and the second auxiliary chassis antenna being disposed at the first end of the substrate substantially adjacent to the proximal portion of the second arm of the dipole antenna and the second arm of the main chassis antenna. The first and second auxiliary chassis antennas are configured for excitation by RF currents in the main groundplane.