RU2774522C2 - Feeder device, antenna, and electronic device - Google Patents

Abstract

FIELD: communication.

SUBSTANCE: present invention proposes a feeder device, an antenna, and an electronic device and relates to the field of communication. The feeder device includes a phase shifter, an adder and a jumper component. The phase shifter has the first cavity, the adder has the second cavity, the first cavity is adjacently connected to the second cavity, and the phase shifter is connected to the adder by means of the jumper component.

EFFECT: size of a feeder device is decreased, and level of signal losses is reduced.

9 cl, 14 dwg

Description

The present invention claims the priority of Chinese Patent Application No. 201711310137.7 dated Dec. 11, 2017, entitled "FEEDER DEVICE, ANTENNA AND ELECTRONIC DEVICE", which is incorporated herein by reference in its entirety.

The field of technology to which the invention belongs

The present invention relates to the field of communications and, in particular, to a feeder device, an antenna and an electronic device.

State of the art

The antenna is one of the important components of the electronic device, and the electronic device receives and sends data using the antenna. The antenna includes components such as a feeder device and a radiating element. The feeder device is configured to convert current signals that have different frequency bands to be sent into current signals with intensity and phase required by the radiating element, and then the radiating element converts the converted current signals into electromagnetic wave signals and emits electromagnetic wave signals .

However, the volume of the existing structure of the feeder device is relatively large, and in particular, the connection between the phase shifter and the adder is not tight enough, and the signal loss of the feeder device is relatively large.

The essence of the invention

In order to reduce the bulk of the feeder device and reduce the signal loss of the feeder device, embodiments of the present invention provide a feeder device, an antenna, and an electronic device. Technical solutions are as follows.

According to a first aspect, the present invention provides a feeder device including a phase shifter, a summer, and a jumper component. The phase shifter has a first cavity, the adder has a second cavity, the first cavity is adjacent to the second cavity, and the phase shifter is connected to the adder using a jumper component. Thus, the distance between the phase shifter and the combiner can be shortened so that the jumper component is relatively short, thereby reducing the volume of the feeder device and reducing the signal loss of the feeder device.

In a possible implementation of the first aspect, the number of phase shifters contained in the feed device is equal to M, M is an integer greater than 1, and the first cavities of different phase shifters are the same cavity.

In a possible implementation of the first aspect, the number of phase shifters contained in the feed device is equal to M, M is an integer greater than 1, and the first cavities of different phase shifters are different cavities. Thus, isolation between two adjacent phase shifters can be increased and signal influence mutually generated between two adjacent phase shifters can be reduced.

In an exemplary implementation of the first aspect, when the first cavities of the different phase shifters are different cavities, the first cavities of the different phase shifters are stacked side by side in an up-down direction, or stacked side by side from left to right. In particular, the walls of the upper and lower cavities of the different first cavities are laminated, or the walls of the left and right cavities of the different first cavities are laminated. The lamination may be partial lamination or full lamination, that is, part or all of the wall of the upper cavity of one first cavity of two different first cavities is laminated to part or all of the wall of the lower cavity of another first cavity. Alternatively, part or all of the wall of the right cavity of one first cavity of two different first cavities is laminated to part or all of the wall of the left cavity of the other first cavity. Top, bottom, left and right are just examples here. This is not limited in the present invention. Thus, the various first cavities become denser to facilitate the connection between the phase shifter and the phase shifter, and the connection between the phase shifter and the adder, thereby. reducing losses in the feeder device.

In a possible implementation of the first aspect, the number of adders contained in the feeder device is N, where N is an integer greater than or equal to 1; and the second cavity of the j-th adder has only one chamber, the j-th adder further includes M tributary blocks, all M tributary blocks correspond to the same second cavity, and the j-th output end of the i-th phase shifter is connected to i- m tributary block of the j-th adder using a jumper component, where i = 1, 2, ... and M. Thus, the number of cavities can be reduced, thereby reducing the volume of the feeder device and facilitating the miniaturization of the feeder device.

In a possible implementation of the first aspect, the number of adders included in the feeder device is N, where N is an integer greater than or equal to 1; and the second cavity of the j-th adder includes M chambers, and the j-th adder further includes M tributary blocks, where M is an integer greater than 1, and j = 1, 2, ... and N. i-th the tributary block of the j-th adder is in a one-to-one correspondence with the i-th chamber, and the j-th output end of the i-th phase shifter is connected to the i-th tributary block of the j-th adder using a jumper component, where i = 1, 2 , ... and M. Thus, the isolation between two adjacent adders and the isolation between tributaries of the same adder can be increased, thereby improving the performance of the feeder device.

In an exemplary embodiment of the first aspect, the M chambers of the second cavity are arranged side by side in a top-to-bottom direction, or are arranged side by side in a left-to-right direction. In particular, the chamber walls of two adjacent chambers are fully or partially laminated. Thus, the adder chambers are easily connected to each other adjacently, so that the adder structure is denser to facilitate the connection between the adder and the adder and the connection between the adder and the phase shifter, thereby reducing the loss of the feeder device.

In a possible implementation of the first aspect, at least one first cavity and at least one second cavity are formed as one. In particular, part or all of the wall of the lower cavity of the first cavity and part or all of the wall of the upper cavity of the second cavity are the same cavity wall, or part or all of the wall of the left cavity of the first cavity and part or all of the wall of the right cavity of the second cavity are one and the same cavity wall. Top, bottom, left and right are just examples here. This is not limited in the present invention. Thus, at least one first cavity is adjacently connected to at least one second cavity, thereby reducing the losses caused by the connection between the first cavity and the second cavity.

In a possible implementation of the first aspect, the jumper component includes a metal sheet and a plug connector, where the plug connector is fixed to the edge of the metal sheet; and a metal sheet is welded to the phase shifter and a plug connector is inserted into the adder, or a metal sheet is welded to the adder and the plug connector is inserted into the phase shifter. Thus, when the plug connector is inserted into the phase shifter, the metal sheet is supported so that the metal sheet is welded to the combiner; or, when the plug connector is inserted into the adder, the metal sheet is supported so that the metal sheet is welded to the phase shifter.

In a possible implementation of the first aspect, the metal sheet and the plug connector are made in one piece.

According to a second aspect, the present invention provides an antenna including a feeder device according to any of the first aspect or possible implementations of the first aspect.

According to a third aspect, the present invention provides an electronic device including a feeder device according to any of the first aspect or possible implementations of the first aspect and/or an antenna according to the second aspect.

Brief description of the drawings

Fig. 1 is a diagram of an antenna according to an embodiment of the present invention;

fig. 2 is a block diagram of a feeder device according to an embodiment of the present invention;

fig. 3 is a block diagram of another feeder device according to an embodiment of the present invention;

fig. 4 is an external view diagram of a feeder device according to an embodiment of the present invention;

fig. 5 is a plan view of a feeder device according to an embodiment of the present invention;

fig. 6 is a diagram of a jumper component according to an embodiment of the present invention;

fig. 7 is a diagram of another feeder device according to an embodiment of the present invention;

fig. 8 is an external view diagram of another feeder device according to an embodiment of the present invention;

fig. 9 is an oblique view of a feeder device according to an embodiment of the present invention;

fig. 10 is a diagram of another jumper component according to an embodiment of the present invention;

fig. 11 is a diagram of a sliding carrier according to an embodiment of the present invention;

fig. 12 is a diagram of a first wired network according to an embodiment of the present invention;

fig. 13 is a diagram of another first wired network according to an embodiment of the present invention; and

fig. 14 is a diagram of another sliding carrier according to an embodiment of the present invention.

Description of Embodiments

For the purpose of explaining the objects, technical solutions and advantages of the present invention, embodiments of the present invention are described in further detail below with reference to the accompanying drawings.

The antenna is one of the important components of an electronic device. Referring to FIG. 1, the antenna includes components such as at least M signal inputs a, a feeder device b, and at least N radiating elements c. Feeder device b has M inputs and N outputs. Each of the M inputs of the feeder device b is connected to one signal input a, and each of the N outputs of the feeder device b is connected to one radiating element c or one column of radiating elements c. M is an integer greater than 1 and N is an integer greater than or equal to 1.

The feeder device b receives current signals which have different frequency ranges and which are input via M signal inputs a, obtains at least N current signals having different current intensities and phases, based on the received current signals of different frequency bands, and sends one of received current signals to each radiating element c/each column of radiating elements c. Each radiating element c/each column of radiating elements c receives one of the current signals, converts the current signal into an electromagnetic wave signal, and emits an electromagnetic wave signal. For detailed implementations of feeder device b, see the content in any of the following embodiments.

Referring to FIG. 2 or fig. 3, an embodiment of the present invention provides a feeder device including:

a phase shifter 1, an adder 2 and a jumper component 3, where the phase shifter 1 has a first cavity 11, the adder 2 has a second cavity 21, the first cavity 11 is adjacently connected to the second cavity 21, and the phase shifter 1 is connected to the adder 2 by means of a jumper component 3.

The feeder device may include M phase shifters 1 and N adders 2.

Perhaps each phase shifter 1 has one input and X outputs, where X is an integer greater than or equal to N. Each adder 2 has M inputs and one output. The j-th output of the i-th phase shifter 1 is connected to the i-th inputs of the j-th adder 2 using a jumper component 3, where i = 1, 2, ... and M, and j = 1, 2, ... and N. When N is less than X, some outputs of each phase shifter 1 are free. In particular, the outputs are not connected, reserved, unprocessed, and may not be connected to the totalizer.

The input of the i-th phase shifter 1 is connected to one signal input a on the antenna and is configured to: receive the current signal, which has one frequency band and which is input through the signal input a, change the phase of the current signal, change the current intensity of the current signal, and obtain X current signals having different current intensities and phases. The X current signals still belong to the same frequency band and one of the current signals is output from each output.

The j-th adder is connected to one radiating element c/one column of radiating elements c on the antenna and is configured to: receive a current signal of one frequency band from the j-th output of the first phase shifter 1, receive a current signal of another frequency band from the j-th output of the second of the phase shifter 1, ..., receive the current signal of another frequency band from the jth output of the Mth phase shifter 1, that is, receive the current signals of the M frequency bands, combine the M current signals of the frequency bands into one current signal, and inject one current signal into emitting element c.

In the present invention, the technical problem is solved, the first cavity 11 is adjacent to the second cavity 21, and the distance between the phase shifter 1 and the summer 2 becomes relatively short, so that the jumper component 3 is also relatively shorter, thereby reducing the cost and signal loss of the feeder device.

Possibly, the first cavity 11 and the second cavity 21 can be made in one piece. For example, part or all of the wall of the lower cavity of the first cavity 11 and part or all of the wall of the upper cavity of the second cavity 21 are the same cavity wall; or part or all of the wall of the left cavity of the first cavity 11 and part or all of the wall of the right cavity of the second cavity 21 are the same cavity wall. Top, bottom, left and right are just examples here. This is not limited in the present invention.

The M phase shifters 1 and N adders 2 may be arranged according to the following two layouts.

In the first layout diagram with reference to FIG. 2 and FIG. 4, M phase shifters 1 may be arranged next to each other in the up-down direction, and N adders 2 may be arranged in series one after the other. That is, N adders 2 are placed side by side in the left and right directions. In addition, each of the adders 2 is located next to the M phase shifters 1.

For example, in the example shown in FIG. 2, the feeder device includes a first phase shifter 1a and a second phase shifter 1b, that is, M = 2. The first phase shifter 1a and the second phase shifter 1b are placed next to each other in the top-down direction. Referring to FIG. 5, the feeder device includes a first adder 2aa, a second adder 2ab, and a third adder 2ac, that is, N = 3. The first adder 2aa, the second adder 2ab, and the third adder 2ac are placed in series one after the other.

In the first layout, the structure of the jumper component 3 is shown in FIG. 6, and the jumper component 3 includes a metal sheet 31 and a plug connector 32. The width of the metal sheet 31 is larger than the width of the plug connector 32, and the plug connector 32 is fixed on the edge of the metal sheet 31. Referring to FIG. 6(1) of FIG. 6(3), two opposite ends of the metal sheet 31 are bent in the same direction into curved portions, and the plug connector 32 is fixed in one of the curved portions. The widths and shapes of the metal sheet 31 and the plug connector 32 in this document are only examples. This is not limited in the present invention.

Referring to FIG. 2, the other bent part of the metal sheet 31 is welded to the phase shifter 1, and the plug connector 32 is inserted into the adder 2, or the other bent part of the metal sheet 31 is welded to the adder 2, and the plug connector 32 is connected to the phase shifter 1 to make the connection between the phase shifter 1 and the adder 2.

During implementation, the j-th output of the i-th phase shifter 1 is welded to the metal sheet 31, the plug connector 32 is plug-in connected to the i-th input of the j-th adder 2, and a connector is provided at the i-th input end of the j-th adder 2. Alternatively, , the i-th input end of the j-th adder 2 is welded to the metal sheet 31, the plug connector 32 is plug-in connected to the j-th output end of the i-th phase shifter 1, and a connector is provided at the j-th output end of the i-th phase shifter 1.

In the first arrangement, the first cavities 11 of the different phase shifters 1 may be different cavities. For example, in the example shown in FIG. 2, the first cavity 11a of the first phase shifter 1a and the first cavity 11b of the second phase shifter 1b are two different cavities. Alternatively, referring to FIG. 7, the first cavities of 11 different phase shifters 1 are the same cavity. For example, in the example shown in FIG. 7, the first phase shifter 1a and the second phase shifter 1b have the same first cavity 11.

For the structure in which the first cavities 11 of the different phase shifters 1 are different cavities, the first cavities 11 of the different phase shifters 1 may be arranged next to each other in the top-down direction. For example, in the examples shown in FIG. 2 and FIG. 4, the first cavity 11a of the first phase shifter 1a and the first cavity 11b of the second phase shifter 1b are arranged next to each other in the top-down direction.

For a structure in which the first cavities 11 of different phase shifters 1 are different first cavities, the structures of the phase shifters 1 may be the same. For the i-th phase shifter, the 1st phase shifter 1 may further include a phase shift unit 12 in addition to the first cavity 11.

Referring to FIG. 5 (FIG. 5 is a plan view of FIG. 2), the phase shifter 12 has one Pin input end and X output ends (not shown in FIG. ), and the phase shifter 12 is installed in the first cavity 11. The Pin input end can exit from the first cavity 11 and be used as the input end of the i-th phase shifter 1, and the j-th output end is connected to the i-th input end of the j-th adder with the jumper component 3.

For a structure in which the first cavities 11 of different phase shifters 1 are the same cavity, as shown in FIG. 7, each phase shifter 1 further has a corresponding phase shifter 12, the structures of the phase shifters 12 of the phase shifters 1 may be the same, and the phase shifters 12 of the phase shifters 1 are installed in the same first cavity 11. In such a structure, the i-phase shifter 12 th phase shifter 1 has one input end Pin and X output ends (not shown in the drawing). The input end Pin can exit the first cavity 11 and be used as the input end of the i-th phase shifter 1, and the j-th output end is connected to the i-th input end of the j-th adder with a jumper component 3.

For a structure in which the first cavities 11 of different phase shifters 1 are the same cavity, in order to reduce the mutual influence of the signal generated between two adjacent phase shift blocks 12, the distance between two adjacent phase shift blocks 12 may be larger than the distance between two adjacent phase shift blocks 12 in the example shown in FIG. 2.

For the aforementioned i-th phase shifter 1, the phase shift unit 12 of the i-th phase shifter 1 is configured to: receive a current signal that has one frequency band and which is input by the input end a of the antenna signal, change the phase of the current signal, change the intensity of the signal current, obtain X current signals having different current intensities and phases, and output one of the current signals from each output.

Perhaps referring to FIG. 2 and FIG. 4, in the first arrangement, for each adder 2, for example, for the j-th adder 2, the second cavity 21 of the j-th adder 2 includes M chambers 211, and the M chambers 211 may be arranged next to each other in the top direction. -way down. The j-th adder 2 further includes M tributary blocks 22, and the i-th tributary block 22 of the j-th adder 2 is in one-to-one correspondence with the i-th chamber 211 of the j-th adder 2. The j-th output end i th phase shifter 1 is connected to the i-th tributary block 22 of the j-th adder 2 using component 3 of the jumper.

For example, in the example shown in FIG. 2, the jth adder 2 may include two tributaries 22: a first tributary 2a and a second tributary 2b. The second cavity 21 of the j-th adder 2 includes two chambers 211: a first chamber 21a and a second chamber 21b. The first chamber 21a and the second chamber 21b are arranged next to each other in the top-down direction, the first tributary block 2a corresponds to the first chamber 21a, and the first tributary block 2a is connected to the j-th output end of the first phase shifter 1a using a jumper component 3. The second tributary block 2b corresponds to the second chamber 21b, and the second tributary block 2b is connected to the j-th output end of the second phase shifter 1b using a jumper component 3.

Referring to FIG. 2, for each adder 2, for example, for the j-th adder 2, the input end of the i-th tributary block 22 in the j-th combiner 2 is the i-th input end of the j-th adder 2 and is connected to the j-th output end of i th phase shifter 1 using jumper component 3. The output ends of the M tributaries 22 contained in the j-th adder 2 are all connected to the output 23, and then the output 23 is connected to the output end Pout of the j-th adder.

Referring to FIG. 5, the i-th tributaries 22 of the adders 2 can cooperate with each other, and a relatively large distance can be maintained between two adjacent i-th tributaries 22 in the i-th tributaries 22 of the adders 2 in order to reduce the signal influence mutually generated between the two adjacent i-th tributary blocks 22.

Alternatively, the i-th tributaries 22 of the adders 2 may not interact with each other. I-th tributary blocks 22 adders 2 are in different chambers. Thus, the isolation between two adjacent tributaries 22 can be increased.

Perhaps referring to FIG. 7, according to the first layout, the second cavity 21 of the jth adder 2 has a total of one chamber, each adder 2 further includes M tributary blocks 22, and M tributary blocks 22 are installed in the second cavity 21. M all tributary blocks 22 correspond to the same camera. The j-th output end of the i-th phase shifter 1 is connected to the i-th tributary block 22 of the j-th adder using the jumper component 3.

In the implementation of FIG. 7, M tributary blocks 22 contained in the jth adder 2 are placed side by side in the top-down direction. The input end of the i-th tributary block 22 in the j-th adder 2 is the i-th input end of the j-th adder 2 and is connected to the j-th output end of the i-th phase shifter 1 using the jumper component 3. The output ends of all three M tributaries contained in the jth adder 2 are all connected to pin 23, and then the pin 23 is connected to the output end Pout of the jth adder 2.

For some electronic devices, the volume of such an electronic device is usually relatively large, the electronic device does not impose high requirements on the antenna size, and a relatively large antenna volume can be allowed. In this case, the second cavity 21 of the adder 2 has one chamber, and the height of the second cavity 21 is relatively large. Thus, the distance between two adjacent tributary blocks 22 can be relatively large, thereby reducing the influence of two adjacent tributary blocks 22 on each other.

Alternatively, for some electronic devices, the antenna of the electronic device does not impose high requirements on the isolation of the adder 2. In this case, the second cavities 21 of the adders 2 have the same chamber and, additionally, an insulating plate is located between two adjacent tributary blocks 22 in the second cavity 21. The material of the insulating plate may be metallic.

Possibly, the second cavities 21 of the adders 2 can communicate with each other. In the second cavity 21, a relatively large distance can be maintained between two adjacent adders 2 in order to reduce the effect of a signal mutually generated between two adjacent adders 2.

Alternatively, the second cavities 21 of the adders 2 may not communicate with each other. That is, the second cavities 21 of the adders 2 are different second cavities 21. Thus, the isolation between two adjacent adders 2 can be increased.

In the second layout diagram, with reference to FIG. 3 and FIG. 8, M phase shifters 1 may be placed side by side in a left-to-right direction, and N adders 2 may be placed in series above the M phase shifters 1, or N adders 2 may be placed in series below the M phase shifters 1.

For example, in the examples shown in FIG. 3 and FIG. 9, the feeder device includes a first phase shifter 1a, a second phase shifter 1b, and a third phase shifter 1c, that is, M = 3, and includes a first adder 2aa, a second adder 2ab, a third adder 2ac, a fourth adder 2ad, and a fifth adder 2ae, that is, N = 5. The first phase shifter 1a, the second phase shifter 1b, and the third phase shifter 1c are arranged side by side in the left-right direction, and the first adder 2aa, the second adder 2ab, the third adder 2ac, the fourth adder 2ad, and the fifth adder 2ae are arranged in series above the three phase shifters 1.

In the second layout diagram in FIG. 10 shows the structure of the jumper component 3, and the jumper component 3 includes a metal sheet 31 and a plug connector 32. The width of the metal sheet 31 is larger than the width of the plug connector 32, and the plug connector 32 is fixed on the edge of the metal sheet 31.

The metal sheet 31 has a flat structure and is welded to the phase shifter 1, and the plug connector 32 is connected by a plug to the combiner 2, or the metal sheet 31 is welded to the adder 2, and the plug connector 32 is plug connected to the phase shifter 1 to make the connection between the phase shifter 1 and the combiner 2 in vertical direction.

During implementation, the j-th output end of the i-th phase shifter 1 is welded to the metal sheet 31, the plug connector 32 is plug-in connected to the i-th input end of the j-th adder 2, and a connector is provided at the i-th input end of the j-th adder 2 Alternatively, the i-th input end of the j-th adder 2 is welded to the metal sheet 31, the plug connector 32 is plug-in connected to the j-th output end of the i-th phase shifter 1, and a connector is provided at the j-th output end of the i-th phase shifter 1 .

For jumper component 3 in FIG. 6 or FIG. 10, the metal sheet 31 and the plug connector 32, which are in the jumper part 3, can be integrally formed.

In the second arrangement, the first cavities 11 of the different phase shifters 1 may be different first cavities 11. For example, in the example shown in FIG. 3, the first cavity 11a of the first phase shifter 1a, the first cavity 11b of the second phase shifter 1b, and the first cavity 11c of the third phase shifter 1c are three different cavities, and the first three cavities 11 are arranged next to each other in the left-to-right direction.

Referring to FIG. 3, in the second layout, the structures of the phase shifters 1 may be the same. For the i-th phase shifter, the 1st phase shifter 1 may further include a phase shift unit 12 in addition to the first cavity 11.

The phase shift block 12 has one input end Pin and X output ends (not shown), and the phase shift block 12 is installed in the first cavity 11. The input end Pin can extend from the first cavity 11 and be used as the input end of the i-th phase shifter 1, and the j-th output end is connected to the i-th input end of the j-th adder with a jumper component 3.

Perhaps referring to FIG. 3 and FIG. 8, in the second arrangement for the jth adder 2, the second cavity 21 of the jth adder 2 includes M chambers 211, and the M chambers 211 may be arranged side by side in a left-to-right direction. The adder 2 further includes M tributary blocks 22, the i-th tributary block 22 of the j-th adder 2 is in one-to-one correspondence with the i-th camera 211, and the j-th output end of the i-th phase shifter 1 is connected to the i- and tributary block 22 using jumper component 3.

For example, in the example shown in FIG. 3, the second cavity 21 of the jth adder 2 includes three chambers 211: a first chamber 21a, a second chamber 21b, and a third chamber 21c. The adder 2 further includes a first tributary block 2a, a second tributary block 2b, and a third tributary block 2c. The first chamber 21a, the second chamber 21b and the third chamber 21c are arranged side by side in the left-to-right direction. The first tributary block 2a corresponds to the first chamber 21a, and the first tributary block 2a is connected to the j-th output end of the first phase shifter 1a using a jumper component 3. The second tributary block 2b corresponds to the second chamber 21b, and the second tributary block 2b is connected to the j-th output end of the second phase shifter using a jumper component 3. The third tributary block 2c corresponds to the third chamber 21c, and the third tributary block 2c is connected to the j-th output by the end of the third phase shifter 1c with the jumper component 3.

Referring to FIG. 3, for each adder 2, for example, for the j-th adder 2, the input end of the i-th tributary block 22 in the j-th adder 2 is the i-th input end of the j-th adder 2 and is connected to the j-th output end i th phase shifter 1 using jumper component 3. The output ends of the M tributaries 22 contained in the j-th adder 2 are all connected to the output 23, and then the output 23 is connected to the output end Pout of the j-th adder.

Referring to FIG. 9, the chambers 211 of the adders 2 can communicate with each other. In the i-th chamber 211, a relatively large distance between two adjacent i-th tributary units 22 can be maintained in order to reduce signal interference between two adjacent i-th tributary units 22.

Alternatively, the i-th cameras 211 of the adders 2 may not communicate with each other. That is, the ith cameras 211 of the adders 2 are different cameras. Thus, the isolation between two adjacent i-th tributary blocks 22 can be increased.

The material of the first cavity 11 of the i-th phase shifter in any of the above arrangements may be metallic, and the first cavity 11 may be used as the ground end of the i-th phase shifter 1. The material of the second cavity 21 of the j-th adder 2 may be metallic, and the second cavity 21 can be used as the ground end of the jth adder 2.

For the phase shift unit 12 of the i-th phase shifter 1 in any of the above arrangements, referring to FIG. 2, fig. 3 and FIG. 7, the phase shift unit 12 includes a first reference carrier 121 and a first wire network 122, where the first wire network 122 is installed in the first cavity 11 of the phase shifter 1 using the first reference carrier 121, and the first wire network 122 has one input end Pin and X output ends (not shown in the drawing).

The input terminal Pin of the first wire network 122 extends from the first cavity 11 and is used as the input terminal Pin of the i-th phase shifter 1, and the j-th output end of the first wire network 122 is connected to the i-th input end of the j-th adder 2.

Optionally, the first wire network 122 may be fixed on the surface of the first support carrier 121. For example, the first support carrier 121 is a printed circuit board carrier, and the first wire network 122 is a copper clad layer of the printed circuit board.

The input end Pin of the first wired network 122 is connected to one signal input end on the antenna and is configured to: receive a current signal that has one frequency band and which is input by signal input end a, change the phase of the current signal, change the intensity of the signal current, receive X signals current having different current intensities and phases, and output one of the current signals from each output end.

Perhaps referring to FIG. 2, fig. 3 and FIG. 7, the moving slots are located on two opposite inner side walls of the first cavity 11, and the first support carrier 121 is mounted in the first cavity 11 using the moving slots on the two inner side walls.

Perhaps still referring to FIG. 2, fig. 3 and FIG. 7, the phase shift unit 12 further includes a slide carrier 123, a moving hole is provided in the first support carrier 121, the slide carrier 123 is installed in the moving hole, and the slide carrier 123 can slide in the moving hole.

The draw bar may be used to move the sliding carrier 123 in the moving hole. The sliding carrier 123 is in contact with the first wire network 122. Sliding the sliding carrier 123 in the moving hole can change the phase of the current signal output by the first wire network 122 from each output end.

Perhaps referring to FIG. 2, sliding carrier 123 includes:

the first slider e and the second slider f, where the first slider e and the second slider f are bent together to form the slider 123.

Perhaps referring to FIG. 1, the cassette structure g is located between the first slide carrier e and the second slide carrier f, and the cassette structure g allows the first slide carrier e and the second slide f to be jointly bent to form the slide carrier 123.

Perhaps referring to FIG. 11, at each of the two ends of the slide carrier 123, at least one through hole h is provided.

Perhaps referring to FIG. 11, there is also a draw hole k at at least one end of the two ends of the slide carrier 123, and the draw bar can engage the draw hole k so that the draw bar drives the slide carrier 123 to slide.

In the ith phase shifter 1, there are a plurality of structures of the first wired network 122. In the present invention, the following two structures of the first wired network 122 are listed. The other structures are not listed one after the other, and the two structures are respectively as follows.

With regard to the first structure of the first wired network 122, see FIG. 12. The first wired network 122 has one input end Pin and three output ends P1, P2, and P3, and further includes:

the main power divider 401, the first phase shift line 402 and the second phase shift line 403, where

the input end Pin of the main power divider 401 is the input end of the i-th phase shifter 1, the first output end of the main power divider 401 is connected to the input end of the first phase shift transmission line 402, and the output end of the first phase shift transmission line 402 is used as the first output end P1 of the i-th phase shifter 1; and

the second output end P2 of the main power divider 401 is used as the second output end P2 of the i-th phase shifter 1, the third output end of the main power divider 401 is connected to the input end of the second phase shift transmission line 403, the output end of the second phase shift transmission line 403 is used as the third output end P3 of the i-th phase shifter 1.

In the first structure, referring to FIG. 11, two through holes h are provided at two ends of the slide carrier 123, respectively.

With regard to the second structure of the first wired network 122, see FIG. 13. The first wired network 122 has one input end Pin and five output ends P1, P2, P3, P4, and P5, and further includes:

the main power divider 501, the first power divider 502, the second power divider 503, the first phase shift link 504, the second phase shift link 505, the third phase shift link 506, and the fourth phase shift link 507, where

the input end Pin of the main power divider 501 is the input end Pin of the i-th phase shifter 1, the first output end is connected to the input end of the first phase shift transmission line 504, and the output end of the first phase shift transmission line 504 is connected to the input end of the first power divider 502;

the first output end of the first power divider 502 is used as the first output end P1 of the i-th phase shifter 1, the second output end is connected to the input end of the second phase shift transmission line 505, and the output end of the second phase shift transmission line 505 is used as the second output end P2 of the i-th phase shifter;

the second output end of the main power divider 501 is used as the third output end P3 of the i-th phase shifter 1, the third output end is connected to the input end of the third phase shift transmission line 506, and the output end of the third phase shift transmission line 506 is connected to the input end of the second power divider 503; and

the first output end of the second power divider 503 is used as the fourth output end P4 of the i-th phase shifter, the second output end is connected to the input end of the fourth phase shift transmission line 507, and the output end of the fourth phase shift transmission line 507 is used as the fifth output end P5 of the i-th phase shifter.

In the second structure, referring to FIG. 14, four through holes h are provided at two ends of the slide carrier 123.

For the i-th tributary block 22 of the j-th adder 2 in any of the above arrangements, referring to FIG. 2, fig. 3 and FIG. 7 and the i-th tributary block 22 includes:

the second support medium 221 and the second wire network 222, where the second wire network 222 is installed in the chamber 211 corresponding to the i-th tributary block 22 using the second support medium 221; and

the input end of the second wire network 222 is connected to the j-th output end of the i-th phase shifter 1 by a jumper component 3, and the output end is connected to the output end Pout of the j-th adder 2.

Optionally, on two opposite inner side walls of the chamber 211 are moving slots corresponding to the i-th tributary block 22, and the second support carrier 221 is installed in the chamber 211 corresponding to the i-th tributary block 22 using moving slots on the two inner side walls.

In this embodiment of the present invention, since the first cavity is adjacent to the second cavity, the distance between the phase shifter and the combiner becomes relatively short, so that the jumper component is also relatively short, which reduces feeder cost and signal loss.

An embodiment of the present invention provides an antenna including a feeder device provided in any of the above embodiments.

An embodiment of the present invention provides an electronic device including the feeder device provided in any of the above embodiments and/or the antenna provided in the previous embodiments.

The above descriptions are merely exemplary embodiments of the present invention, but are not intended to limit the present invention. Any modification, equivalent substitution or improvement made without deviating from the spirit and principle of the present invention shall be within the protection of the present invention.

Claims (18)

1. Feeder device, containing: M phase shifters, N adders and at least one jumper component in which N is an integer greater than or equal to 1, M is an integer greater than 1, each of the phase shifters has X output ends, where X is an integer greater than or equal to N, each, each of the adders has M input ends, one an output end and M tributary blocks, each of the input ends corresponding to a tributary block of M tributary blocks; the first cavity of the i-th phase shifter is adjacently connected to the second cavity of the j-th adder; and The j-th output end of the i-th phase shifter is connected to the i-th tributary block of the j-th adder with a jumper component of at least one jumper component, where i=1, 2, ..., and M, j=1, 2 , ... , and N; in which, when the second cavity of the j-th adder contains M cameras, the i-th tributary block of the j-th adder is in one-to-one correspondence with the i-th camera; or, when the second cavity of the j-th adder consists of one chamber, M tributary blocks correspond to one chamber. 2. Feeder device according to claim. 1, in which the first cavities of different phase shifters are the same cavity or the first cavities of different phase shifters are different cavities. 3. The feeder device according to claim 2, wherein when the first cavities of the different phase shifters are different cavities, the first cavities of the different phase shifters are adjacent to each other in the top-down direction or are adjacent to each other in the left-to-right direction. 4. The feeder device according to claim 1, wherein the M chambers contained in the second cavity are placed next to each other in the top-down direction or are located next to each other in the left-to-right direction. 5. Feeder device according to any one of paragraphs. 1-4, in which the first cavity of the i-th phase shifter and the second cavity of the j-th adder are made as one. 6. Feeder device according to any one of paragraphs. 1-5, in which the jumper component contains: a metal sheet and a plug connector in which the plug connector is fixed to an edge of the metal sheet; and wherein the j-th output end of the i-th phase shifter, connected to the i-th tributary block of the j-th adder via a jumper component of at least one jumper component, comprises: a metal sheet welded to the phase shifter and a plug connector connected to the j-th adder; or a metal sheet welded to the j-th adder and a plug-in connector connected to the i-th phase shifter. 7. Feeder device according to claim 6, in which the metal sheet and the plug connector are made in one piece. 8. An antenna containing a feeder device according to any one of paragraphs. 1-7. 9. An electronic device containing a feeder device according to any one of paragraphs. 1-7 and/or an antenna according to claim 8.

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