Patent Grant
11923587
This application is a National Stage of International Patent Application No. PCT/EP2019/054536, filed on Feb. 25, 2019, which is hereby incorporated by reference in its entirety.
The disclosure relates to a transmission line for transmitting radiofrequency range current between a first conductive element and a second conductive element.
Future electronic devices need to support millimeter-wave bands, e.g. 28 GHz and 42 GHz, as well as sub-6 GHz bands in order to accommodate increased data rates. However, the volume reserved for all the antennas in a mobile electronic device is very limited and the added millimeter-wave antennas should ideally be accommodated to the same volume as the sub-6 GHz antennas. Increasing the volume reserved for antennas would make the electronic device larger, bulkier, and less attractive to users. Current millimeter-wave antennas either require such additional volume, or if placed in the same volume, significantly reduce the efficiency of sub-6 GHz antennas.
Current sub-6 GHz antennas are located on the metal frame of the electronic device and are of a capacitive coupling element type, a section of the metal frame being used as a capacitive coupling element antenna. The capacitive coupling element must be separated from the main conductive body of the device by a dielectric gap. The larger the gap between the metal frame and the main body, the better the performance of the sub-6 GHz antenna.
One drawback with currently known millimeter-wave antennas for metal frame electronic devices is that the millimeter-wave antenna short-circuits the metal frame, or causes a significant capacitive loading to it. The capacitive loading effectively decreases the gap between the capacitive coupling element antenna and the main body and thus deteriorates the operation of the sub-6 GHz antenna. Short-circuiting the metal frame also deteriorates the performance of the sub-6 GHz antenna.
Millimeter-wave antennas are conventionally placed as far as possible from the metal frame in order to not introduce additional capacitive loading. However, if the antenna is placed far from the frame, the radiation opening in the metal frame has to be comparatively large, and large openings in the metal frame to be avoided due to both aesthetic reasons and mechanical robustness. Furthermore, radiation from millimeter-wave antennas placed far from the frame is shadowed by the conductive components of the mobile device, which results in millimeter-wave beamforming deflecting, and thus limited beam coverage
Additionally, the trend towards very large displays, covering as much as possible of the electronic device, makes the space available for the different antennas very limited, forcing either the size of the antenna array to be significantly reduced, and its performance impaired, or a large part of the display to be inactive.
Exemplary embodiments of the present disclosure provide an improved transmission line.
According to a first aspect, there is provided a transmission line for transmitting radiofrequency range current between a first conductive element and a second conductive element, the transmission line comprising a signal current line and at least one return current line, the signal current line and the return current line(s) extending in parallel, each current line comprising at least one first segment and at least one second segment, each first segment being partially aligned with at least one adjacent second segment, aligned segments being separated by a first dielectric gap, each aligned first segment and second segment forming a capacitive coupling across the first dielectric gap.
This solution enables a transmission line which provides only small capacitive loading onto its surroundings, and which therefore can extend, e.g., through an antenna element formed by the first conductive element and the second conductive element without significantly affecting the performance of the antenna element. The capacitance is minimized by one or several dielectric gaps to both the signal current line and the return current line of the transmission line. Conventionally, signal lines can be equipped with gaps in case of filters, whereas return current lines are not provided with dielectric gaps because unbalanced lines are commonly used. However, in the present solution, balanced line with gaps both on signal and return paths are introduced to avoid short circuiting through the return path. The transmission line enables allocation of the millimeter-wave antennas at the second conductive element while feeding the millimeter-wave antennas by radio circuits allocated at first conductive element. Some embodiments comprise millimeter-wave antennas coupled to the second conductive element and fed by the disclosed transmission lines across the gap between the first and the second conductive element. Further embodiments configure sub-6 GHz antennas utilizing the same first and second conductive elements. Thus, the disclosed transmission line enables both sub-6 GHz antennas and millimeter-wave antennas utilizing effectively the same volume.
In a possible implementation form of the first aspect, the first segment(s) and the second segment(s) are arranged in a first plane, each first segment partially overlapping at least one adjacent second segment, aligned and overlapping segments being separated by the first dielectric gap in a first direction within the first plane, facilitating a spatially efficient solution which comprises as many dielectric gaps as necessary in order to produce low series capacitance. The capacitance of the gap between the first conductive element and the second conductive element is minimized by a sequence comprising first segment(s), and the second segment(s) are separated by a sequence of first dielectric gap(s), i.e. a sequence of series capacitances. Hence, the performance of the sub-6 GHz antenna is maximized.
In a further possible implementation form of the first aspect, each overlap between a first segment and a second segment generates an electromagnetic coupling enabling transmission above 10 GHz frequencies and which generates electromagnetic isolation, between the first segment and the second segment, below 10 GHz. The larger the dielectric gaps, the smaller the common mode capacitance and the less the transmission line affects its surroundings.
In summary, the disclosed transmission line, comprising a signal current line and at least one return current line and wherein each line comprises overlaps between a first segment and a second segment provides the following features. The common mode capacitance between the first conductive element and the second conductive element is minimized, thus enabling high performance sub-6 GHz antennas. The differential mode transmission loss is minimized above 10 GHz frequencies, thus enabling high performance millimeter-wave antennas. Out-of-band emissions from the millimeter-wave antennas are efficiently suppressed by the frequency-selective performance of the disclosed transmission line, thus assuring compliance of an electronic device, comprising such a transmission line, to corresponding emission standards.
In a further possible implementation form of the first aspect, each first segment and each second segment has a longitudinal extension of λ/16 to 3*λ/4, λ being a wavelength within the radiofrequency range. Each series capacitance of each dielectric gap is compensated with inductance of the corresponding first and second segments. Hence, the signal propagates along the transmission line without significant attenuation. When the capacitances are interleaved with inductive sections, the parasitic loading on the surrounding element is reduced and, if the surrounding element is a sub-6 GHz antenna, its operational bandwidth and efficiency is increased.
In a further possible implementation form of the first aspect, the first segment(s) further extend in a second plane and the second segment(s) further extend in a third plane, the second plane being parallel with the third plane, the second plane and the third plane being perpendicular to the first plane, allowing an as dense yet efficient transmission line as possible. The further extension in the second plane and in the third plane for the signal current line segments and for the return current line segments defines the type of transmission line. In some embodiments, two return current lines are configured with the signal current line in-between adjacent return current lines. This type of transmission line operates as a coplanar waveguide. The dimensions of the first segment(s) and the second segment(s) in the third plane as well as the spacing between signal current line segments and return current lines segments define the wave impedance of the coplanar waveguide transmission line. In alternative embodiments, one return current line is configured adjacent to the signal current line. This type of the transmission line operates as a differential balanced waveguide. The dimensions of the first segment(s) and the second segment(s) in the second and in the third plane, respectively, as well as the spacing between signal current line segments and the return current lines segments define the wave impedance of the differential balanced waveguide transmission line. In all embodiments, the wave impedances of the transmission line are defined by the dimensions of the first segment(s) and the second segment(s), minimizing the differential mode transmission loss above 10 GHz frequencies, thus enabling high performance millimeter-wave antennas.
In a further possible implementation form of the first aspect, each first segment is separated from an adjacent first segment by a second dielectric gap in a first direction within the second plane, and each second segment is separated from an adjacent second segment by a second dielectric gap in a first direction within the third plane, further minimizing the common mode capacitance between the first conductive element and the second conductive element. In some embodiments, the first segment(s) comprised in the signal current line are separated from adjacent first segment(s) comprised in the return current line by a second dielectric gap. The gap defines the wave impedance of the transmission line, thus minimizing differential mode transmission loss above 10 GHz frequencies, and enabling high performance millimeter-wave antennas.
In a further possible implementation form of the first aspect, the first segment(s) of the signal current line and the first segment(s) of the return current line(s) extend in parallel in the second plane, and the second segment(s) of the signal current line and the second segment(s) of the return current line(s) extend in parallel in the third plane, allowing both the signal current line and the return current line to be arranged in the same two parallel planes and the structure to be essentially two-dimensional due to the small distance between the two planes. This topology reduces the volume occupied by the transmission line, thus reducing the volume of the antenna within the electronic device.
In a further possible implementation form of the first aspect, the transmission line comprises one signal current line and one return current line, facilitating a balanced transmission line suitable for, e.g., balanced antennas.
In a further possible implementation form of the first aspect, each current line comprises one first segment and one second segment, the first segment being additionally separated from the second segment by a third dielectric gap in a second direction within the first plane, the second direction being perpendicular to the first direction, allowing the signal current line to extend in one plane and the return current line to extend in a further, parallel plane and the structure to be essentially three-dimensional. This topology further reduces the volume occupied by the transmission line, thus reducing the volume of the antenna within the electronic device.
In a further possible implementation form of the first aspect, the transmission line comprises one signal current line and two return current lines, the signal current line extending between the two return current lines, which is advantageous since transitions between conventional ungrounded coplanar waveguide and grounded transmission lines have low loss wide frequency band performance and occupies minimum volume. This topology also provides highly confined electric fields in the line, isolating the line from its environment.
In a further possible implementation form of the first aspect, the signal current line and the return current line are connected by a first conductive structure and a second conductive structure, a transmission line gap extending between the first conductive structure and the second conductive structure, the transmission line gap dividing the transmission line into a first transmission line part and a second transmission line part, the first conductive structure and the second conductive structure forming an inductive coupling between the first transmission line part and the second transmission line part. Relying on inductive coupling instead of capacitive coupling to transfer the signal may be advantageous since inductive loading generally predominates when designing a matching circuit for capacitive coupling elements. Furthermore, high frequency selectivity is enabled by inductive coupling between the first transmission line part and the second transmission line part, with impedance matching configured by the resonant capacitive gaps between the first and second segments. The high frequency selectivity efficiently suppresses out-of-band emissions from the millimeter-wave antennas, thus assuring compliance of the electronic device to corresponding emission standards.
According to a second aspect, there is provided an electronic device comprising a first conductive element and a second conductive element separated by a non-conductive volume, a first antenna and a second antenna configured at least partially within the non-conductive volume and/or the second conductive element, a first transmission line connecting the first conductive element to the first antenna across the non-conductive volume, and at least one second transmission line according to the above connecting the first conductive element to the second antenna across the non-conductive volume, each second transmission line introducing a parasitic capacitive load below 0.2 pF to a space formed by the non-conductive volume. The disclosed transmission line enables both a first antenna and a second antenna effectively utilizing the same volume.
Conventionally, return current lines are not provided with dielectric gaps since such an interruption in current is undesired due to it generating unintentional radiation which reduces the efficiency of the element comprising the return current line 5. However, in the present solution, such radiation may form part of the radiofrequency radiation generated by the first antenna and the second antenna. By allowing said transmission line to extend across the non-conductive volume, which volume forms part of the first antenna, two different antennas can be placed within the same volume, significantly reducing the space required for antennas within the electronic device.
In a possible implementation form of the second aspect, the electronic device further comprises a display, the first conductive element being a device chassis or a printed circuit board, the second conductive element being a metal frame, the display and the metal frame at least partially surrounding the device chassis and the printed circuit board, wherein radiofrequency radiation generated by the first antenna and the second antenna is transmitted through a dielectric gap separating the display and the metal frame. The present solution is suitable for solid metal frame electronic devices, in which no slots or cuts are required. Radiation is transmitted using the gap between display and metal frame, which enables display direction and end-fire beamforming and hence full-sphere omni coverage which is not blocked by the hand of the user of the electronic device. Furthermore, a ground plane of a conventional transmission line is not needed, and therefore the metal frame is not shorted.
In a further possible implementation form of the second aspect, the first antenna is a sub-6 GHz antenna, facilitating use of the present solution for current cellular bands and networks.
In a further possible implementation form of the second aspect, the second antenna is a millimeter-wave antenna, and a millimeter-wave antenna module is arranged between the first conductive element and the second conductive element. This solution enables the coexistence of sub-6 GHz antennas with millimeter-wave antennas, since the transmission line facilitates transfer of millimeter-wave signal from the millimeter-wave module to the antenna element on the metal frame. The coexistence of sub-6 GHz antennas with millimeter-wave antennas enables communication, by the electronic device, in 5G and beyond 5G cellular networks and wireless area networks.
These and other aspects of the present disclosure will be apparent from the exemplary embodiments described below.
In the following detailed portion of the present disclosure, exemplary aspects, embodiments and implementations will be explained in more detail with reference to the drawings, in which:
The first conductive element 2 and the second conductive element 3 are separated by a non-conductive volume 15, the first antenna 16 and the second antenna 17 are configured at least partially within the non-conductive volume 15 and/or the second conductive element 3. A first transmission line 18 connects the first conductive element 2 to the first antenna 16 across the non-conductive volume 15, and at least one second transmission line 1, described in more detail further below, connects the first conductive element 2 to the second antenna 17 across the non-conductive volume 15. Each second transmission line 1 introduces a parasitic capacitive load below 0.2 pF to a space formed by the non-conductive volume 15.
In one embodiment, the first antenna 16 is a sub6-GHz antenna, and hence the first transmission line 18 is a sub6-GHz feed. In a further embodiment, the second antenna 17 is at least one millimeter-wave antenna. A plurality of second antennas 17 may form an antenna array. A millimeter-wave antenna module 21 may be arranged between the first conductive element 2 and the second conductive element 3.
The above-mentioned transmission line 1 is adapted for transmitting radiofrequency range current between the first conductive element 2 and the second conductive element 3. The transmission line 1, shown in
Both the signal current line 4 and the return current line 5 comprises at least one first segment 6 and at least one second segment 7, arranged such that each first segment 6 is partially aligned with at least one adjacent second segment 7, and such that aligned segments are separated by a first dielectric gap 8. Each aligned first segment 6 and second segment 7 forms a capacitive coupling across the first dielectric gap 8. The return current line 5 is part of the ground used for the second antenna 17. Conventionally, return current line 5 are not provided with dielectric gaps since such an interruption in current is undesired due to it generating unintentional radiation which reduced the efficiency of the element comprising the return current line 5. However, in the present solution, such radiation forms part of the radiofrequency radiation generated by the first antenna 16 and the second antenna 17.
The first segments 6 and the second segments 7 may be arranged in a first plane P1, the planes referred to below being best shown in
In one embodiment, each first segment 6 and each second segment 7 has a longitudinal extension, with lengths optimized to compensate for the series capacitances within the pass band. In one embodiment, the lengths are between λ/16 and 3*λ/4, λ being a wavelength within the radiofrequency range of the millimeter-wave antenna 17. The series capacitances are compensated by the comparatively short dimensions of the first segments 6 and the second segments 7. In some embodiments, the operating frequency range of the millimeter-wave antenna 17 is within the 24 GHz to 70 GHz range. For example, the longitudinal extension of each first segment 6 and each second segment 7 may be 0.5 mm to 2 mm for the frequency bands 24 GHz to 29.5 GHz.
The first segments 6 may further extend in a second plane P2 and the second segments 7 may further extend in a third plane P3, the second plane P2 being parallel with the third plane P3, and the second plane P2 and the third plane P3 being perpendicular to the first plane P1.
In some embodiments, each first segment 6a is separated from an adjacent first segment 6b by a second dielectric gap 9a in a first direction P2a within the second plane P2, and each second segment 7a is separated from an adjacent second segment 7b by a second dielectric gap 9b in a first direction P3a within the third plane P3.
The first segments 6 of the signal current line 4 and the first segments 6 of the return current lines 5 may extend in parallel in the second plane P2, and the second segments 7 of the signal current line 4 and the second segments 7 of the return current lines 5 may extend in parallel in the third plane P3, as shown in
As shown in
As shown in
In one embodiment, shown in
Various aspects and implementations have been described in conjunction with various embodiments herein. However, other variations to the disclosed embodiments can be understood and effected by those skilled in the art in practicing the claimed subject-matter, from a study of the drawings, the disclosure, and the appended claims. In the claims, the word “comprising” does not exclude other elements or steps, and the indefinite article “a” or “an” does not exclude a plurality. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measured cannot be used to advantage.
Reference signs used in the claims shall not be construed as limiting the scope.
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2019/054536 | 2/25/2019 | WO |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2020/173537 | 9/3/2020 | WO | A |
| Number | Name | Date | Kind |
|---|---|---|---|
| 3805198 | Gewartowski | Apr 1974 | A |
| 5017897 | Ooi et al. | May 1991 | A |
| 5770987 | Henderson | Jun 1998 | A |
| 5825263 | Falt | Oct 1998 | A |
| 6034580 | Henderson et al. | Mar 2000 | A |
| 8791775 | Liu | Jul 2014 | B2 |
| 9859604 | Huang | Jan 2018 | B2 |
| 20170110787 | Ouyang et al. | Apr 2017 | A1 |
| 20180026341 | Mow et al. | Jan 2018 | A1 |
| Number | Date | Country |
|---|---|---|
| 206076482 | Apr 2017 | CN |
| 207781895 | Aug 2018 | CN |
| 2018206116 | Nov 2018 | WO |
| Entry |
|---|
| Park et al., “Hybrid Antenna Module Concept for 28 GHz 5G Beamsteering Cellular Devices,” total 3 pages, Institute of Electrical and Electronics Engineers, New York, New York, IEEE (2018). |
| Number | Date | Country | |
|---|---|---|---|
| 20220158318 A1 | May 2022 | US |
