This application claims the priority benefit of Taiwan application serial no. 111140661, filed on Oct. 26, 2022. The entirety of the above-mentioned patent application is hereby incorporated by reference herein and made a part of this specification.
This disclosure relates to an electronic device, in particular to an electronic device having an antenna module with broadband characteristics.
An antenna module of a conventional electronic device is disposed inside an all-metal casing and is interfered by the all-metal casing, which results in the antenna module not having good broadband characteristics. Therefore, how to enable an antenna module to have good broadband characteristics is an urgent issue to be solved in this field.
The disclosure provides an electronic device, and an antenna module thereof with good broadband antenna characteristics.
The electronic device of the disclosure includes a metal casing and at least one antenna module. The metal casing includes at least one window. The at least one antenna module is disposed inside the at least one window. The at least one antenna module includes a first radiator and a second radiator. The first radiator includes a feeding end, a first ground end joined to the metal casing, a second ground end, a first portion extending from the feeding end to the first ground end, and a second portion extending from the feeding end to the second ground end. A first coupling gap is between the second radiator and the first portion. A second coupling gap is between at least part of the second radiator and the metal casing, and the second radiator includes a third ground end joined to the metal casing.
In an embodiment of the disclosure, the second portion includes a first subportion, a second subportion, and a third subportion sequentially connected. The first subportion is connected to the feeding end. The second subportion is connected to the second ground end. The third subportion extends from the second subportion and is parallel to the first subportion.
A third coupling gap is between the first subportion and the third subportion. A fourth coupling gap is between the third subportion and the metal casing.
In an embodiment of the disclosure, the metal casing includes a first edge, a second edge, a third edge, and a fourth edge surrounding the window and sequentially connected. The first ground end is joined to the first edge. The second ground end and the third ground end are joined to the third edge. The second coupling gap is between the second radiator and the second edge.
In an embodiment of the disclosure, the second subportion is joined to the fourth edge.
In an embodiment of the disclosure, the second portion, the third coupling gap, and the fourth coupling gap are excited at a first high-frequency band. The first subportion and the second subportion are excited at a second high-frequency band. The first portion is excited at a third high-frequency band. The first portion, the second radiator, and the second coupling gap are excited at a fourth high-frequency band.
In an embodiment of the disclosure, the second radiator includes a notch facing the second portion near the third ground end to form a fifth coupling gap.
In an embodiment of the disclosure, the first radiator, the first coupling gap, the second radiator, and the fifth coupling gap are excited at a low-frequency band.
In an embodiment of the disclosure, the metal casing includes at least one antenna cavity recessed on an outer surface. An opening of the at least one antenna cavity forms the at least one window. The at least one antenna module is disposed in the at least one antenna cavity.
In an embodiment of the disclosure, the at least one antenna module includes multiple antenna modules. The at least one antenna cavity includes multiple antenna cavities. The antenna cavities are not communicated with each other. The antenna modules are disposed in the respective antenna cavities.
In an embodiment of the disclosure, a distance between adjacent two of the antenna modules is between 5 mm and 25 mm.
Based on the above, the antenna module of the electronic device of the disclosure radiates at the high-frequency band and the low-frequency band through multiple radiation paths formed by the first radiator and the second radiator joined to the metal casing, so that the antenna module has good broadband antenna characteristics. Since the antenna module is disposed on (the inside of) the notch inside the window of the metal casing and is not covered by the metal casing, the antenna module may be prevented from being shielded by the metal casing and having the antenna characteristics affected.
Please refer to
The body 114 of the metal casing 110 includes at least one antenna cavity corresponding to the at least one antenna module. An opening of the at least one antenna cavity forms at least one window. The antenna module is disposed on the corresponding bracket 130a, and the antenna module is disposed inside the corresponding window and is disposed in the corresponding antenna cavity. Here, the at least one antenna module includes two antenna modules 120a and 120b, and the electronic device 100 includes two corresponding brackets 130a (only one bracket 130a is schematically shown here), two antenna cavities 116a and 116b, and two windows 115a and 115b, but not limited thereto.
The two antenna cavities 116a and 116b are not communicated with each other, so as to prevent the two antenna modules 120a and 120b from interfering with each other. The metal casing 110 further includes a first edge E1, a second edge E2, a third edge E3, and a fourth edge E4 surrounding the window 115a and sequentially connected. The first edge E1 is located above the third edge E3 in the Y-axis direction. The second edge E2 is located on the left side of the fourth edge E4 in the X-axis direction.
As shown in
A distance between adjacent antenna modules 120a and 120b (
As shown in
The antenna module 120a of this embodiment is multi-path grounded (to be described below) through a first radiator 122 and a second radiator 128 (
A first coupling gap C1 is between the second radiator 128 (positions B1-B7) of the antenna module 120a and the first portion 124 (the positions A1 and A9) of the first radiator 122, and a second coupling gap C2 is between the second radiator 128 (the positions B1-B7) and the second edge E2 of the metal casing 110. The first coupling gap C1 is between 0.25 mm and 0.75 mm, such as 0.5 mm. The second coupling gap C2 is between 1.5 mm and 2.5 mm, such as 2 mm.
The second portion 126 (the positions A1-A8) of the first radiator 122 includes a first subportion 126a (the positions A1-A3), a second subportion 126b (the positions A4, A7, and A8), and a third subportion 126c (the positions A5 and A6) sequentially connected. The first subportion 126a (the positions A1-A3) is connected to the feeding end (the position A1), the second subportion 126b (the positions A4, A7, and A8) is connected to the second ground end (the position G2) and is also joined to the fourth edge E4, and the third subportion 126c (the position A5 and A6) extends from the second subportion 126b and is parallel to the first subportion 126a.
A third coupling gap C3 is between the first subportion 126a (the positions A1-A3) and the third subportion 126c (the positions A5 and A6). A fourth coupling gap C4 is between the third subportion 126c (the positions A5 and A6) and the metal casing 110. The third coupling gap C3 is between 2 mm and 3 mm, for example, 2.5 mm. The fourth coupling gap C4 is between 2.5 mm and 3.5 mm, for example, 3 mm.
In addition, the second radiator 128 (the positions B1-B7) includes a third ground end (a position G3) joined to the third edge E3 of the metal casing 110. The second radiator 128 (the positions B1-B7) includes a notch 129 facing the second portion 126 near the third ground end (the position G3). As shown in
The user may adjust the sizes of the first coupling gap C1, the second coupling gap C2, the third coupling gap C3, the fourth coupling gap C4, and the fifth coupling gap C5 by adjusting the areas of the first radiator 122 (the positions A1-A9) and the second radiator 128 (the positions B1-B7).
In addition, as shown in
The antenna module 120a has multiple high-frequency radiation paths and a low-frequency radiation path to be excited at multiple high-frequency bands and a low-frequency band. Specifically, as shown in
A second high-frequency radiation path is the path from the feeding end (the position A1) through the second portion 126 (the positions A1-A8) of the first radiator 122 to the second ground end (the position G2), thereby being excited at a second high-frequency band. The second high-frequency band is between 5150 MHz and 6100 MHz.
A third high-frequency radiation path is the path from the feeding end (the position A1) through the first portion 124 (the positions A1 and A9) of the first radiator 122 to the first ground end (the position G1), thereby being excited at a third high-frequency band. The third high-frequency band is between 6100 MHz and 7100 MHz. In addition, the path from the first radiator 122 (the positions A1-A9) to the first ground end (the position G1), the path from the second radiator 128 (the positions B1-B7) to the third ground end (the position G3), and the second coupling gap C2 may be excited at a fourth high-frequency band. The fourth high-frequency band is between 7100 MHz and 7600 MHz. Besides, a position of a center frequency of the fourth high-frequency band can be adjusted by adjusting the distance of the second coupling gap C2.
The antenna module 120a further includes a low-frequency radiation path. The low-frequency radiation path is the path from the first radiator 122 (the positions A1-A9) to the first ground end (the position G1), the second portion 126 (the positions A1-A8) to the second ground end (the position G2), and the first coupling gap C1, the fifth coupling gap C5, and the second radiator 128 (the positions B1-B7) connected to the third ground end (the position G3), thereby being excited at the low-frequency band. The low-frequency band is between 2400 MHz and 2500 MHz. The center frequency of the low-frequency band may be adjusted by adjusting the size of the fifth coupling gap C5.
Referring to
Due to differences in the placement positions (
In addition, due to the good isolation between the two antenna modules 120a and 120b, no additional isolation elements need to be disposed between the two antenna cavities 116a and 116b, which can improve the space utilization efficiency of the electronic device 100 and reduce the overall volume of the electronic device 100, so that the electronic device 100 is suitable for small military standard monitoring devices.
For example, as shown in
Referring to
The bracket 130a illustrated in
As shown in
As shown in
In addition, please refer to
To sum up, the antenna module of the electronic device of the disclosure radiates multiple high-frequency bands and a low-frequency band through multiple radiation paths joined by the first radiator and the second radiator to the metal casing, so that the antenna module has good broadband characteristics. Since the antenna module is disposed inside the window on the outer surface of the metal casing and is not enclosed by the metal casing, the antenna module may be prevented from being shielded by the metal casing and having the antenna characteristics affected.
The antenna module is suitable for a Wi-Fi 6E broadband antenna and may be excited at the first high-frequency band, the second high-frequency band, the third high-frequency band, the fourth high-frequency band, and the low-frequency band. The first high-frequency band is between 4950 MHz and 5150 MHz. The second high-frequency band is between 5150 MHz and 6100 MHz. The third high-frequency band is between 6100 MHz and 7100 MHz. The fourth high-frequency band is between 7100 MHz and 7600 MHz. The low-frequency band is between 2400 MHz and 2500 MHz. When the electronic device includes two antenna modules, the two antenna modules are disposed in two independent and isolated antenna cavities to prevent the two antenna modules from interfering with each other. According to the test results, the two antenna modules have good isolation between each other and have good voltage standing wave ratio and good efficiency in the low-frequency band and the high-frequency bands.
Number | Date | Country | Kind |
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111140661 | Oct 2022 | TW | national |