JP4751462B2 - Portable radio - Google Patents

Description

  The present invention relates to a portable wireless device having a foldable casing.

  In recent years, there has been a growing need to mount a plurality of antenna elements in a portable radio device in order to receive diversity in digital television broadcasting or to adopt a MIMO communication system that supports high-speed and large-capacity transmission.

  Conventionally, a portable wireless device is known in which an upper housing and a lower housing are connected to each other by a hinge portion so as to be freely opened and closed, and includes a plurality of antenna elements (for example, Patent Document 1). In Patent Document 1, a metal frame of an upper housing and a hinge portion fed from a wireless circuit of a lower housing are electrically connected, and a first antenna element is configured by the hinge portion and the metal frame. The second antenna element is configured by the ground pattern on the circuit board.

JP 2005-6096 A

  However, in Patent Document 1, since the entire upper and lower housings are configured as one antenna system, another antenna system having the same size cannot be arranged, and a plurality of antennas having the same performance cannot be configured. Or there is a problem that it cannot be used as an antenna for MIMO communication.

  This invention is made | formed in view of this point, and it aims at providing the portable radio which can comprise the several antenna which has the same performance in a housing | casing.

  A portable wireless device according to the present invention includes a first housing, a second housing, a third housing, and a first circuit provided in the first housing and having a first ground portion. A substrate, a second circuit board provided in the second casing and having a second ground portion, and a third circuit board provided in the third casing and having a third ground portion. The first housing and the second housing are pivotably coupled, and the first hinge portion electrically connected to the first ground portion, the second housing, and the A second hinge part rotatably coupled to the third casing and electrically connected to the third ground part; provided on the second circuit board; and the first hinge part A first power supply unit that is electrically connected; and a second power supply unit that is provided on the second circuit board and is electrically connected to the second hinge unit. Land portions and constitute a first dipole antenna by the second ground unit, a configuration which constitutes the second dipole antenna by the second ground unit and the third ground portion.

  The portable wireless device of the present invention includes a first housing, a second housing, a third housing, and a first ground portion provided in the first housing and having a first ground portion. Circuit board, a second circuit board provided in the second casing and having a second ground part, and a third circuit provided in the third casing and having a third ground part A first hinge part that rotatably connects the substrate, the first casing, and the second casing, and is electrically connected to the second ground part, and the second casing And the third casing are pivotably connected to each other and a second hinge part electrically connected to the third ground part, and the first hinge is provided on the first circuit board. A first power supply unit that is electrically connected to the second circuit unit, and a second power supply unit that is provided on the second circuit board and is electrically connected to the second hinge unit. The first ground unit and the second ground portion constitute a first dipole antenna, a configuration which constitutes the second dipole antenna by the second ground unit and the third ground portion.

  According to the present invention, it is possible to configure a plurality of antennas having equal performance inside the housing.

FIG. 3 is a plan view of the portable wireless device according to Embodiment 1 of the present invention in an open state. The figure which shows the structure of the diversity antenna fed from the 1st electric power feeding part which concerns on Embodiment 1 of this invention. The figure which shows the structure of the diversity antenna electrically fed from the 2nd electric power feeding part which concerns on Embodiment 1 of this invention. Plan view of portable wireless device according to Embodiment 2 of the present invention in an open state The figure which shows the structure of the diversity antenna electrically fed from the 1st electric power feeding part which concerns on Embodiment 2 of this invention. The figure which shows the structure of the diversity antenna electrically fed from the 2nd electric power feeding part which concerns on Embodiment 2 of this invention. Plan view of a vertically opened state of the portable wireless device according to the third embodiment of the present invention Plan view of a laterally opened state of the portable wireless device according to the third embodiment of the present invention The figure which shows the structure of the diversity antenna electrically fed from the 1st electric power feeding part which concerns on Embodiment 3 of this invention. The figure which shows the structure of the diversity antenna electrically fed from the 2nd electric power feeding part which concerns on Embodiment 3 of this invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

(Embodiment 1)
FIG. 1 is a plan view of portable radio device 100 according to Embodiment 1 of the present invention in an open state.

  The portable wireless device 100 includes a first housing 101, a second housing 102, a third housing 103, a first hinge unit 104, a second hinge unit 105, and a third hinge. Part 106, fourth hinge part 107, circuit board 108, circuit board 109, circuit board 110, radio circuit 111, radio circuit 112, first power supply part 113, and second power supply part 114, a first signal connection cable 115, and a second signal connection cable 116.

  The first housing 101 has a rectangular shape in a plan view, and the first hinge portion 104 and the second hinge portion 105 form the Y direction in FIG. 1 (the flat side of the first housing 101 and the second housing). The first housing 102 is connected to the second housing 102 so as to be rotatable in a direction opposite to and away from the plane side of the 102. The first housing 101 has a circuit board 108.

  The second housing 102 is coupled to the first housing 101 by the first hinge portion 104 and the second hinge portion 105 so as to be rotatable in the Y direction of FIG. In addition, the second housing 102 is arranged in the X direction of FIG. 1 (the plane side of the second housing 102 and the plane side of the third housing 103 by the third hinge portion 106 and the fourth hinge portion 107. Are coupled to the third housing 103 so as to be rotatable in a direction facing and a direction away from each other. The second housing 102 includes a circuit board 109 provided with a wireless circuit 111, a wireless circuit 112, a first power feeding unit 113, and a second power feeding unit 114.

  The third housing 103 is connected to the second housing 102 by a third hinge portion 106 and a fourth hinge portion 107 so as to be rotatable in the X direction of FIG. The third housing 103 has a circuit board 110.

  The first hinge portion 104 is fixed to the first housing 101 and is formed of a conductive material. Further, the first hinge portion 104 is rotatably connected to the second hinge portion 105, and is centered on the rotation axis P <b> 1 with respect to the first housing 101 via the second hinge portion 105. Thus, the second casing 102 can be rotated. Further, the first hinge portion 104 is electrically connected to the second hinge portion 105 and the ground portion of the circuit board 108.

  The second hinge portion 105 is fixed to the second housing 102 and is formed of a conductive material. The second hinge portion 105 is rotatably connected to the first hinge portion 104 and is centered on the rotation axis P <b> 1 with respect to the second housing 102 via the first hinge portion 104. Thus, the first casing 101 can be rotated. The second hinge portion 105 is electrically connected to the first hinge portion 104. The second hinge unit 105 is electrically connected to the first power supply unit 113.

  The third hinge portion 106 is fixed to the second housing 102 at a side that intersects the side to which the second hinge portion 105 of the second housing 102 is connected, and is formed of a conductive material. The third hinge portion 106 is rotatably connected to the fourth hinge portion 107, and is centered about the rotation axis P <b> 2 via the fourth hinge portion 107 with respect to the second housing 102. Thus, the third housing 103 is made rotatable. Further, the third hinge portion 106 is electrically connected to the fourth hinge portion 107. The third hinge unit 106 is electrically connected to the second power feeding unit 114.

  The fourth hinge portion 107 is fixed to the third housing 103 and is formed of a conductive material. Further, the fourth hinge portion 107 is rotatably connected to the third hinge portion 106, and is centered on the rotation connection P <b> 2 via the third hinge portion 106 with respect to the third housing 103. Thus, the second casing 102 can be rotated. The fourth hinge portion 107 is electrically connected to the third hinge portion 106 and the ground portion of the circuit board 110.

  The circuit board 108 is provided on the first housing 101, and a ground portion (not shown) is printed over the entire bottom surface. The ground portion of the circuit board 108 is electrically connected to the first hinge portion 104. The ground portion of the circuit board 108 is not limited to printing and may be separated from the circuit board 108.

  The circuit board 109 includes a wireless circuit 111, a wireless circuit 112, a first power supply unit 113, and a second power supply unit 114. The circuit board 109 is provided on the second casing 102, and a ground portion (not shown) is printed over the entire bottom surface. The ground portion of the circuit board 109 is not limited to printing and may be separated from the circuit board 109.

  The circuit board 110 is provided on the third housing 103, and a ground portion (not shown) is printed over the entire bottom surface. The ground portion of the circuit board 110 is electrically connected to the fourth hinge portion 107. The ground portion of the circuit board 110 is not limited to printing and may be separated from the circuit board 110.

  The ground part separate from the circuit board 108, the ground part separate from the circuit board 109, or the ground part separate from the circuit board 110 is electrically conductive, such as a shield case, plating deposited on a resin, or a sheet metal reinforcing the board. Any material can be used as long as it is made of a material having a property.

  The wireless circuit 111 is provided on the second hinge part 105 side of the circuit board 109 and is electrically connected to the ground part of the circuit board 109. The wireless circuit 111 is electrically connected to the first power feeding unit 113.

  The wireless circuit 112 is provided on the third hinge part 106 side of the circuit board 109 and is electrically connected to the ground part of the circuit board 109. In addition, the wireless circuit 112 is electrically connected to the second power feeding unit 114.

  The first power supply unit 113 is provided on the circuit board 109 and is electrically connected to the wireless circuit 111. Further, the first power supply unit 113 is electrically connected to the second hinge unit 105.

  The second power feeding unit 114 is provided on the circuit board 109 and is electrically connected to the wireless circuit 112. The second power feeding unit 114 is electrically connected to the third hinge unit 106.

  The first signal connection cable 115 transmits a signal between the circuit board 108 and the circuit board 109. The first signal connection cable 115 electrically connects the ground part of the circuit board 108 and the ground part of the circuit board 109. In addition, the first signal connection cable 115 is disposed at a predetermined distance r1 from the first power feeding unit 113. Here, the distance r <b> 1 is a distance at which the first signal connection cable 115 is not electrically influenced by the first power feeding unit 113. Note that, since the first signal connection cable 115 is grounded, it is difficult to form an electric field by the first power supply unit 113 when the first signal connection cable 115 is disposed in the vicinity of the first power supply unit 113.

  The second signal connection cable 116 transmits a signal between the circuit board 109 and the circuit board 110. The second signal connection cable 116 electrically connects the ground part of the circuit board 109 and the ground part of the circuit board 110. The second signal connection cable 116 is arranged at a predetermined distance r2 from the second power feeding unit 114. Here, the distance r <b> 2 is a distance at which the second signal connection cable 116 is not electrically influenced by the second power feeding unit 114. Note that since the second signal connection cable 116 is grounded, it is difficult to form an electric field by the second power supply unit 114 when it is disposed in the vicinity of the second power supply unit 114.

  Next, the opening / closing operation of the portable wireless device 100 will be described with reference to FIG.

  In the closed state (not shown) where the first housing 101, the second housing 102, and the third housing 103 overlap in the vertical direction, the second housing 102 is shown in FIG. 1 and then the third housing 103 is rotated in the X1 direction of FIG. 1 around the rotation axis P2, thereby opening the state shown in FIG.

  In the opened state of FIG. 1, the third casing 103 is rotated in the X2 direction of FIG. 1 around the rotation axis P2, and then the second casing is centered on the rotation axis P1. The closed state is obtained by rotating 102 in the Y1 direction in FIG.

  Next, the antenna current flow in the portable wireless device 100 will be described with reference to FIGS. 2 and 3. FIG. 2 is a diagram illustrating a configuration of the diversity antenna that is fed from the first feeding unit 113. FIG. 3 is a diagram illustrating a configuration of a diversity antenna that is fed from the second feeding unit 114.

  As shown in FIG. 2, in the case of a diversity antenna fed from the first feeding unit 113, the first feeding unit 113 is connected to the ground of the circuit board 108 via the second hinge unit 105 and the first hinge unit 104. Power to the part. As a result, the antenna current e1 flows downward in FIG. 2 in the ground portion of the circuit board 108. Further, a housing current b1 flows downward in FIG. 2 at the ground portion of the circuit board 109. An area that operates as a ground part by flowing a part of the casing current b1 flowing in the ground part of the circuit board 109 to the ground part of the circuit board 110 via the second signal connection cable 116. Can be increased.

  3, in the case of a diversity antenna fed from the second feeding unit 114, the second feeding unit 114 is connected to the circuit board 110 via the third hinge unit 106 and the fourth hinge unit 107. Power is supplied to the ground part. As a result, the antenna current e2 flows toward the left in FIG. 3 in the ground portion of the circuit board 110. Further, the housing current b2 flows toward the left in FIG. 3 in the ground portion of the circuit board 109. A part of the housing current b2 that flows in the ground portion of the circuit board 109, b2 ′, also flows to the ground portion of the circuit board 108 via the first signal connection cable 115, so that an area that operates as the ground portion is defined. Can be bigger.

  According to the present embodiment, the antenna current e1, the housing current b1, and the housing current b1 ′, and the antenna current e2, the housing current b2, and the housing current b2 ′ have the same antenna length and different current distributions. Two antenna systems can be configured, and a diversity effect can be obtained.

  Further, according to the present embodiment, the dominant antenna current e1 and casing current b1, and the antenna current e2 and casing current b2 flow in directions orthogonal to each other, so that a polarization diversity effect can be obtained.

  As described above, according to the present embodiment, the hinge portion that connects the first housing and the second housing and the hinge portion that connects the second housing and the third housing are two. By supplying power to each of the two hinge portions, two dipole antennas can be formed inside the casing. As a result, a plurality of antennas having equal performance can be configured inside the housing, and a diversity antenna or an antenna for MIMO communication can be configured. In addition, according to the present embodiment, the antenna current can flow in the directions orthogonal to each other in each diversity antenna, so that the polarization diversity effect can be obtained. In addition, according to the present embodiment, since the power feeding unit and the signal connection cable are arranged at a predetermined distance, it is possible to eliminate the influence of the power feeding unit on the signal connection cable, such as generation of noise. Further, according to the present embodiment, the dipole antenna is configured by supplying power to the ground portion of the circuit board of the first housing and the ground portion of the circuit board of the third housing which are separated from each other. Thus, the distance between the dipole antennas can be increased and the correlation can be lowered, so that the antenna performance of the diversity antenna can be improved. Furthermore, due to the influence of the casing current flowing via the first signal connection cable or the second signal connection cable, the area operating as the ground portion can be increased, and the dipole antenna can be operated in a wide band. .

(Embodiment 2)
FIG. 4 is a plan view of portable wireless device 400 according to Embodiment 2 of the present invention in an open state.

  The portable wireless device 400 includes a first housing 401, a second housing 402, a third housing 403, a first hinge unit 404, a second hinge unit 405, and a third hinge. Part 406, fourth hinge part 407, circuit board 408, circuit board 409, circuit board 410, wireless circuit 411, wireless circuit 412, first power supply part 413, and second power supply part 414, a first signal connection cable 415, a second signal connection cable 416, and a coaxial cable 417.

  The first housing 401 has a rectangular shape in a plan view, and the first hinge portion 404 and the second hinge portion 405 form the Y direction in FIG. The first housing 402 is coupled to the second housing 402 so as to be rotatable in a direction facing and away from the plane side of the surface 402. In addition, the first housing 401 includes a circuit board 408 provided with a wireless circuit 411, a wireless circuit 412, and a first power feeding unit 413.

  The second housing 402 is connected to the first housing 401 so as to be rotatable in the Y direction of FIG. 4 by the first hinge portion 404 and the second hinge portion 405. In addition, the second housing 402 is arranged in the X direction in FIG. 4 (the flat side of the second housing 402 and the flat side of the third housing 403 by the third hinge portion 406 and the fourth hinge portion 407. Are coupled to the third housing 403 so as to be rotatable in the opposite direction and the away direction. In addition, the second housing 402 includes a circuit board 409 provided with a second power feeding unit 414.

  The third housing 403 is connected to the second housing 402 by the third hinge portion 406 and the fourth hinge portion 407 so as to be rotatable in the X direction of FIG. The third housing 403 includes a circuit board 410.

  The first hinge 404 is fixed to the first housing 401 and is formed of a conductive material. The first hinge unit 404 is rotatably connected to the second hinge unit 405, and is centered on the rotation axis P1 with respect to the first housing 401 via the second hinge unit 405. Thus, the second housing 402 can be rotated. In addition, the first hinge unit 404 is electrically connected to the first power feeding unit 413.

  The second hinge portion 405 is fixed to the second housing 402 and is formed of a conductive material. The second hinge portion 405 is rotatably connected to the first hinge portion 404 and is centered about the rotation axis P1 with respect to the second housing 402 via the first hinge portion 404. Thus, the first casing 401 can be rotated. The second hinge portion 405 is electrically connected to the first hinge portion 404. Further, the second hinge portion 405 is electrically connected to the ground portion of the circuit board 409.

  The third hinge portion 406 is fixed to the second housing 402 at a side that intersects the side to which the second hinge portion 405 of the second housing 402 is connected, and is formed of a conductive material. The third hinge portion 406 is rotatably connected to the fourth hinge portion 407, and is centered on the rotation axis P2 with respect to the second casing 402 via the fourth hinge portion 407. Thus, the third housing 403 can be rotated. The third hinge portion 406 is electrically connected to the fourth hinge portion 407. The third hinge portion 406 is electrically connected to the second power feeding portion 414. Further, the third hinge portion 406 is electrically connected to the ground portion of the circuit board 409.

  The fourth hinge portion 407 is fixed to the third housing 403 and is formed of a conductive material. The fourth hinge portion 407 is rotatably connected to the third hinge portion 406, and is centered on the rotation axis P2 with respect to the third casing 403 via the third hinge portion 406. Thus, the second housing 402 can be rotated. The fourth hinge portion 407 is electrically connected to the third hinge portion 406 and the ground portion of the circuit board 410.

  The circuit board 408 includes a wireless circuit 411, a wireless circuit 412, and a first power feeding unit 413. The circuit board 408 is provided in the first housing 401, and a ground portion (not shown) is printed over the entire bottom surface. The ground portion of the circuit board 408 is electrically connected to the radio circuit 411 and the radio circuit 412. Note that the ground portion of the circuit board 408 is not limited to printing and may be separated from the circuit board 408.

  The circuit board 409 includes a second power feeding unit 414. The circuit board 409 is provided on the second housing 402, and a ground portion (not shown) is printed over the entire bottom surface. The ground portion of the circuit board 409 is electrically connected to the second hinge portion 405 and the third hinge portion 406. Note that the ground portion of the circuit board 409 is not limited to printing and may be separated from the circuit board 409.

  The circuit board 410 is provided on the third housing 403, and a ground portion (not shown) is printed over the entire bottom surface. The ground portion of the circuit board 410 is electrically connected to the fourth hinge portion 407. The ground portion of the circuit board 410 is not limited to printing and may be separated from the circuit board 410.

  A ground part separate from the circuit board 408, a ground part separate from the circuit board 409, or a ground part separate from the circuit board 410 is electrically conductive, such as a shield case, plating deposited on a resin, or a sheet metal reinforcing the board. Any material can be used as long as it is made of a material having a property.

  The wireless circuit 411 is provided on the circuit board 408 and is electrically connected to the ground portion of the circuit board 408. In addition, the wireless circuit 411 is electrically connected to the first power feeding unit 413.

  The wireless circuit 412 is provided on the circuit board 408 and is electrically connected to the ground portion of the circuit board 408. The radio circuit 412 is electrically connected to the second power feeding unit 414 via the coaxial cable 417.

  The first power supply unit 413 is provided on the circuit board 408 and is electrically connected to the wireless circuit 411. The first power feeding unit 413 is electrically connected to the first hinge unit 404.

  The second power supply unit 414 is provided on the circuit board 409 and is electrically connected to the wireless circuit 412 via the coaxial cable 417. In addition, the second power feeding unit 414 is electrically connected to the third hinge unit 406.

  The first signal connection cable 415 transmits a signal between the circuit board 408 and the circuit board 409. The first signal connection cable 415 electrically connects the ground portion of the circuit board 408 and the ground portion of the circuit board 409. The first signal connection cable 415 is arranged with a predetermined distance r10 from the first power feeding unit 413. Here, the distance r <b> 10 is a distance at which the first signal connection cable 415 is not electrically affected by the first power feeding unit 413. Note that since the first signal connection cable 415 is grounded, it is difficult to form an electric field by the first power supply unit 413 when the first signal connection cable 415 is disposed in the vicinity of the first power supply unit 413.

  The second signal connection cable 416 transmits a signal between the circuit board 409 and the circuit board 410. The second signal connection cable 416 electrically connects the ground part of the circuit board 409 and the ground part of the circuit board 410. The second signal connection cable 416 is disposed at a predetermined distance r11 from the second power feeding unit 414. Here, the distance r <b> 11 is a distance at which the second signal connection cable 416 is not electrically influenced by the second power feeding unit 414. Note that since the second signal connection cable 416 is grounded, it is difficult to form an electric field by the second power supply unit 414 when the second signal connection cable 416 is disposed in the vicinity of the second power supply unit 414.

  The coaxial cable 417 electrically connects the wireless circuit 412 and the second power feeding unit 414.

  Next, the opening / closing operation of the portable wireless device 400 will be described with reference to FIG.

  When the first housing 401, the second housing 402, and the third housing 403 overlap each other in the up-down direction (not shown), the second housing 402 is shown in FIG. 4 and then the third casing 403 is rotated in the X1 direction of FIG. 4 about the rotation axis P2, thereby opening the state shown in FIG.

  In the opened state of FIG. 4, the third casing 403 is rotated in the X2 direction of FIG. 4 around the rotation axis P2, and then the second casing is centered on the rotation axis P1. A closed state is obtained by rotating 402 in the Y1 direction of FIG.

  Next, the flow of antenna current in portable wireless device 400 will be described with reference to FIGS. 5 and 6. FIG. 5 is a diagram illustrating a configuration of a diversity antenna fed from the first feeding unit 413. FIG. 6 is a diagram illustrating a configuration of a diversity antenna that is fed from the second feeding unit 414.

  From FIG. 5, in the case of a diversity antenna fed from the first feeding unit 413, the first feeding unit 413 is connected to the ground of the circuit board 409 via the first hinge unit 404 and the second hinge unit 405. Power to the part. Further, the first power supply unit 413 supplies power to the ground part of the circuit board 410 via the ground part of the circuit board 409, the third hinge part 406, and the fourth hinge part 407. As a result, the antenna current e10 flows upward in FIG. 5 in the ground portion of the circuit board 409, and a part of the antenna current e10 in the ground portion of the circuit board 410 is supplied with the second signal connection. Since it flows toward the left in FIG. 5 via the cable 416, the area operating as the antenna portion can be increased. Further, the housing current b10 flows upward in FIG. 5 at the ground portion of the circuit board 408.

  Further, from FIG. 6, in the case of a diversity antenna fed from the second feeding unit 414, the second feeding unit 414 is connected to the circuit board 410 via the third hinge unit 406 and the fourth hinge unit 407. Power is supplied to the ground part. As a result, the antenna current e11 flows toward the left in FIG. 6 in the ground portion of the circuit board 410. Further, the housing current b11 flows toward the left in FIG. 6 in the ground portion of the circuit board 409. A part of the casing current b11 flowing in the circuit board 409, b11 ′, also flows through the first signal connection cable 415 to the circuit board 408, so that an area operating as a ground portion can be increased. .

  According to the present embodiment, the dominant antenna current e10 and housing current b10 and the antenna current e11 and housing current b11 constitute two antenna systems having the same antenna length but different feeding positions and current distributions. And a diversity effect can be obtained.

  As described above, according to the present embodiment, the hinge portion that connects the first housing and the second housing and the hinge portion that connects the second housing and the third housing are two. By supplying power to each of the two hinge portions, two dipole antennas can be formed inside the casing. As a result, a plurality of antennas having equal performance can be configured inside the housing, and a diversity antenna or an antenna for MIMO communication can be configured. In addition, according to the present embodiment, since the power feeding unit and the signal connection cable are arranged at a predetermined distance, it is possible to eliminate the influence of the power feeding unit on the signal connection cable, such as generation of noise. Furthermore, the area that operates as the ground portion or the antenna portion can be increased due to the influence of the current flowing through the first signal connection cable or the second signal connection cable, and the dipole antenna can be operated in a wide band. it can.

(Embodiment 3)
FIG. 7 is a plan view of the portable wireless device 700 according to Embodiment 3 of the present invention in a vertically opened state. FIG. 8 is a plan view of the portable wireless device 700 according to Embodiment 3 of the present invention in a laterally open state.

  7 and 8 has a second hinge portion 701 instead of the second hinge portion 405, compared to the portable wireless device 400 according to the second embodiment shown in FIG. 7 and 8, parts having the same configurations as those in FIG.

  The portable wireless device 700 includes a first housing 401, a second housing 402, a third housing 403, a first hinge portion 404, a third hinge portion 406, and a fourth hinge. Unit 407, circuit board 408, circuit board 409, circuit board 410, wireless circuit 411, wireless circuit 412, first power feeding unit 413, second power feeding unit 414, and first signal connection It is mainly composed of a cable 415, a second signal connection cable 416, a coaxial cable 417, and a second hinge portion 701.

  The first housing 401 has a rectangular shape in plan view, and is connected to the second housing 402 so as to be rotatable in the Y direction of FIG. 7 by the first hinge portion 404 and the second hinge portion 701. The first casing 401 is connected to the second casing 402 by the first hinge portion 404 and the second hinge portion 701 so as to be rotatable in the Z direction of FIG. In addition, the first housing 401 includes a circuit board 408 provided with a wireless circuit 411, a wireless circuit 412, and a first power feeding unit 413.

  The second housing 402 is connected to the first housing 401 so as to be rotatable in the Y direction of FIG. 7 by the first hinge portion 404 and the second hinge portion 701. The second housing 402 is coupled to the third housing 403 by a third hinge portion 406 and a fourth hinge portion 407 so as to be rotatable in the X direction of FIGS. Further, the second housing 402 is connected to the first housing 401 so as to be rotatable in the Z direction in FIG. 8 by the first hinge portion 404 and the second hinge portion 701. In addition, the second housing 402 includes a circuit board 409 provided with a second power feeding unit 414.

  The first hinge 404 is fixed to the first housing 401 and is formed of a conductive material. In addition, the first hinge unit 404 is rotatably connected to the second hinge unit 701 and is centered about the rotation axis P1 with respect to the first housing 401 via the second hinge unit 701. Thus, the second casing 402 can be rotated in the Y direction in FIG. 7 and the second casing 402 can be rotated in the Z direction in FIG. 8 about the rotation axis P3. . That is, the first hinge portion 404 is connected to the first casing 401 and the second casing 402 via the second hinge portion 701 in two directions different from each other in the Y direction in FIG. 7 and the Z direction in FIG. And can be rotated. In addition, the first hinge unit 404 is electrically connected to the first power feeding unit 413.

  The second hinge portion 701 is fixed to the second casing 402 and is formed of a conductive material. The second hinge portion 701 is rotatably connected to the first hinge portion 404 and is centered about the rotation axis P1 with respect to the second housing 402 via the first hinge portion 404. Thus, the second casing 402 can be rotated in the Y direction in FIG. 7 and the second casing 402 can be rotated in the Z direction in FIG. 8 about the rotation axis P3. . In other words, the second hinge unit 701 is connected to the first casing 401 and the second casing 402 via the first hinge unit 404 in two directions different from each other in the Y direction in FIG. 7 and the Z direction in FIG. And can be rotated. The second hinge portion 701 is electrically connected to the first hinge portion 404. Further, the second hinge portion 701 is electrically connected to the ground portion of the circuit board 409.

  Next, the opening / closing operation of the portable wireless device 700 will be described.

  First, the opening / closing operation in the vertically opened state will be described with reference to FIG.

  When the first casing 401, the second casing 402, and the third casing 403 overlap each other in a closed state (not shown), the second casing 402 is shown in FIG. Then, the third casing 403 is rotated in the X1 direction in FIG. 7 around the rotation axis P2 to be in the vertically opened state in FIG.

  Further, in the vertically opened state of FIG. 7, the third casing 403 is rotated about the rotation axis P2 in the X2 direction of FIG. 7, and then the second casing is centered on the rotation axis P1. It is in a closed state by rotating 402 in the Y1 direction of FIG.

  Next, the opening / closing operation in the laterally open state will be described with reference to FIG.

  In the closed state, the second casing 402 is rotated in the Z1 direction in FIG. 8 around the rotation axis P3, and then the third casing 403 is centered on the rotation axis P2 in FIG. By turning in the X1 direction, the side opening state of FIG. 8 is obtained.

  Further, in the laterally opened state of FIG. 8, the third casing 403 is rotated about the rotation axis P2 in the X2 direction of FIG. 8, and then the second casing is centered on the rotation axis P3. The closed state is obtained by rotating 402 in the Z2 direction of FIG.

  Next, the flow of antenna current in portable wireless device 700 will be described with reference to FIGS. FIG. 9 is a diagram illustrating a configuration of the diversity antenna that is fed from the first feeding unit 413 in the horizontally opened state. FIG. 10 is a diagram illustrating a configuration of a diversity antenna that is fed from the second feeding unit 414 in a horizontally opened state. Note that the flow of the antenna current in the vertically open state is the same as that in FIGS.

  From FIG. 9, in the case of a diversity antenna fed from the first feeding unit 413, the first feeding unit 413 is connected to the ground of the circuit board 409 via the first hinge unit 404 and the second hinge unit 701. Power to the part. As a result, the antenna current e20 flows upward in FIG. 9 in the ground portion of the circuit board 409, and the housing current b20 flows in the left direction in FIG. 9 in the ground portion of the circuit board 408. A part of the current e20 ′ of the antenna current e20 flowing in the ground portion of the circuit board 409 also flows to the ground portion of the circuit board 410 via the first signal connection cable 416, so that an area operating as the antenna portion is defined. Can be bigger.

  Further, from FIG. 10, in the case of a diversity antenna fed from the second feeding unit 414, the second feeding unit 414 is connected to the circuit board 410 via the third hinge unit 406 and the fourth hinge unit 407. Power is supplied to the ground part. As a result, the antenna current e21 flows upward in FIG. 10 in the ground portion of the circuit board 410. Further, a housing current b21 flows upward in FIG. 10 in the ground portion of the circuit board 409. A part of the current b21 ′ of the casing current b21 flowing in the ground portion of the circuit board 409 also flows to the circuit board 408 via the first signal connection cable 415, thereby increasing the area operating as the ground portion. be able to.

  According to the present embodiment, the dominant antenna current e20 and housing current b20, and the antenna current e21 and housing current b21 can form two antenna systems having the same antenna length and different current distributions. And a diversity effect can be obtained.

  As described above, according to the present embodiment, the hinge portion that connects the first housing and the second housing and the hinge portion that connects the second housing and the third housing are two. By supplying power to each of the two hinge portions, two dipole antennas can be formed inside the casing. As a result, a plurality of antennas having the same performance can be configured inside the casing of the portable wireless device that can be in the two open states of the vertically open state and the horizontally open state, and the diversity antenna or the antenna for MIMO communication Can be configured. In addition, according to the present embodiment, since the power feeding unit and the signal connection cable are arranged at a predetermined distance, it is possible to eliminate the influence of the power feeding unit on the signal connection cable, such as generation of noise. Furthermore, the area that operates as the ground portion or the antenna portion can be increased due to the influence of the current flowing through the first signal connection cable or the second signal connection cable, and the dipole antenna can be operated in a wide band. it can.

  Note that in this embodiment, the two wireless circuits and the first power feeding unit are provided in the first housing. However, the present embodiment is not limited to this, and the two wireless circuits and the first power feeding unit are provided. You may provide a 2nd electric power feeding part in a 2nd housing | casing. In this case, the polarization diversity effect can be obtained in the vertically open state.

  In the first to third embodiments described above, the respective housings are connected to each other by two hinge portions so as to be rotatable. However, the present invention is not limited to this, and the respective housings are connected to each other by one hinge portion. You may connect so that rotation is possible respectively. In the first to third embodiments described above, the wireless circuit or the power feeding unit is provided in the first casing or the second casing. However, the present invention is not limited thereto, and the third casing is provided. A diversity circuit may be configured by providing a wireless circuit or a power feeding unit.

  The present invention is suitable for application to a portable wireless device having a foldable casing.

DESCRIPTION OF SYMBOLS 100 Portable radio | wireless machine 101 1st housing | casing 102 2nd housing | casing 103 3rd housing | casing 104 1st hinge part 105 2nd hinge part 106 3rd hinge part 107 4th hinge part 108 Circuit board 109 Circuit board 110 Circuit board 111 Radio circuit 112 Radio circuit 113 First power supply section 114 Second power supply section 115 First signal connection cable 116 Second signal connection cable

Claims (5)

A first housing;
A second housing;
A third housing;
A first circuit board provided in the first housing and having a first ground portion;
A second circuit board provided in the second casing and having a second ground portion;
A third circuit board provided in the third casing and having a third ground portion;
A first hinge portion that rotatably couples the first housing and the second housing, and is electrically connected to the first ground portion;
A second hinge portion that rotatably connects the second housing and the third housing, and is electrically connected to the third ground portion;
A first power supply unit provided on the second circuit board and electrically connected to the first hinge unit;
A second power feeding portion provided on the second circuit board and electrically connected to the second hinge portion;
With
A portable radio device comprising a first dipole antenna comprising the first ground part and the second ground part, and a second dipole antenna comprising the second ground part and the third ground part. A first housing;
A second housing;
A third housing;
A first circuit board provided in the first housing and having a first ground portion;
A second circuit board provided in the second casing and having a second ground portion;
A third circuit board provided in the third casing and having a third ground portion;
A first hinge part rotatably connecting the first casing and the second casing and electrically connected to the second ground part;
A second hinge portion that rotatably connects the second housing and the third housing, and is electrically connected to the third ground portion;
A first power supply unit provided on the first circuit board and electrically connected to the first hinge unit;
A second power feeding portion provided on the second circuit board and electrically connected to the second hinge portion;
With
A portable radio device comprising a first dipole antenna comprising the first ground part and the second ground part, and a second dipole antenna comprising the second ground part and the third ground part.   The portable wireless device according to claim 1, wherein the first hinge unit connects the first housing and the second housing so as to be rotatable in two different directions. A first signal connection cable that transmits a signal between the first circuit board and the second circuit board and is disposed at a predetermined distance from the first power supply unit;
And a second signal connection cable that transmits a signal between the second circuit board and the third circuit board and is disposed at a predetermined distance from the second power feeding unit. The portable wireless device according to claim 1 or 2.   The portable wireless device according to claim 1 or 2, wherein a diversity antenna is constituted by the first dipole antenna and the second dipole antenna.

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