A slot antenna and an information terminal apparatus using the same are provided. The slot antenna comprises: a conductive housing; and at least one slot formed on the corner and edge of the conductive housing.

A slot antenna and an information terminal apparatus using the same are provided. The slot antenna comprises: a conductive housing; and at least one slot formed on the corner and edge of the conductive housing.

A multiband antenna includes main antenna, a switch circuit, and a parasitic antenna. The main antenna includes a radiating portion, a feeding portion, a grounding portion, and an extending portion coupled to the feeding portion and the grounding portion. The radiating portion is configured to generate a low frequency resonate mode. The switch circuit is configured to regulate an impedance matching characteristic of the multiband antenna, thereby regulating an operating frequency of the low frequency resonate mode. The parasitic antenna is positioned apart from and electromagnetically coupled to the main antenna, and configured to generate a high frequency resonate mode.

A multiband antenna includes main antenna, a switch circuit, and a parasitic antenna. The main antenna includes a radiating portion, a feeding portion, a grounding portion, and an extending portion coupled to the feeding portion and the grounding portion. The radiating portion is configured to generate a low frequency resonate mode. The switch circuit is configured to regulate an impedance matching characteristic of the multiband antenna, thereby regulating an operating frequency of the low frequency resonate mode. The parasitic antenna is positioned apart from and electromagnetically coupled to the main antenna, and configured to generate a high frequency resonate mode.

A wireless communication device includes a first antenna from which a first signal is transmitted; a second antenna through which a second signal is received in a frequency band that is different from a frequency band of the first signal; a first signal removal circuit configured to remove a component of a frequency band of the second signal from the first signal when the first signal removal circuit is electrically coupled to the first antenna; and a processor configured to determine whether to electrically connect the first signal removal circuit to the first antenna, based on an output strength of the first signal that is transmitted from the first antenna, when the second signal is received through the second antenna.

A wireless communication device includes a first antenna from which a first signal is transmitted; a second antenna through which a second signal is received in a frequency band that is different from a frequency band of the first signal; a first signal removal circuit configured to remove a component of a frequency band of the second signal from the first signal when the first signal removal circuit is electrically coupled to the first antenna; and a processor configured to determine whether to electrically connect the first signal removal circuit to the first antenna, based on an output strength of the first signal that is transmitted from the first antenna, when the second signal is received through the second antenna.

A communication device includes a housing, a system circuit board, and an antenna element. A metal plane of the housing is disposed on a back surface of the housing. An edge of the metal plane is aligned with an edge of the back surface. The antenna element includes a metal piece and a printed circuit board. The metal piece is disposed on a side surface of the housing. The metal piece extends along the edge of the metal plane. The metal piece is also separated from the edge of the metal plane by a nonconductive region. The printed circuit board includes a circuit. The printed circuit board has a first connection point and a second connection point. The first connection point is coupled to a signal source. The second connection point is coupled to the metal piece, and is used as a feeding point of the antenna element.

A wireless communication device includes a circuit board, a metal frame, and a slot antenna. The circuit board includes a multiple bandpass filter, a plurality of matching circuits, and a plurality of Radio Frequency (RF) modules. The metal frame surrounds the circuit board. The slot antenna includes a feeding portion, at least one grounding portion, and a radiating portion. The feeding portion and the at least one grounding portion are connected between the circuit board and the metal frame, the radiating portion and the circuit board enclose a slot. The radiating portion is formed on a portion of the metal frame. The slot antenna, the multiple bandpass filter, the plurality of matching circuits, and the plurality of RF modules are electrically connected in that order.

A wireless communication device includes a circuit board, a metal frame, and a slot antenna. The circuit board includes a multiple bandpass filter, a plurality of matching circuits, and a plurality of Radio Frequency (RF) modules. The metal frame surrounds the circuit board. The slot antenna includes a feeding portion, at least one grounding portion, and a radiating portion. The feeding portion and the at least one grounding portion are connected between the circuit board and the metal frame, the radiating portion and the circuit board enclose a slot. The radiating portion is formed on a portion of the metal frame. The slot antenna, the multiple bandpass filter, the plurality of matching circuits, and the plurality of RF modules are electrically connected in that order.

An antenna structure includes a main antenna, a parasitic antenna, a matching circuit and a switching circuit. The main antenna includes a feeding strip and a first radiating strip coupled to the feeding strip. The parasitic antenna includes a grounding strip and a second radiating strip coupled to the grounding strip. The second radiating strip is positioned adjacent to and apart from the first radiating strip, and further configured to electromagnetically couple to and be parasitically fed by the first radiating strip. The parasitic antenna and main antenna cooperatively generate at least one high-frequency resonate mode and a low-frequency resonate mode. The matching circuit is electronically coupled to the feeding strip. The switching circuit is electronically coupled to the matching circuit, and configured to regulate an inductance value of the matching circuit output to the feeding strip, thereby regulating a central frequency of the low-frequency resonate mode.