RU2816545C2 - Phase shifter with possibility of output mode adjustment and antenna - Google Patents

Abstract

FIELD: wireless communication equipment.

SUBSTANCE: invention relates to wireless communication antennas. Essence: a phase changer for use with an antenna includes a fixed dielectric plate and a movable sliding plate. Fixed circuits are located on the fixed dielectric plate. Movable sliding plate is located on the surface of the fixed dielectric plate. On the movable sliding plate there is a plurality of sliding chains corresponding to each of the fixed chains. Fixed chain is made with possibility of connection with at least one corresponding sliding chain and formation together with it of phase-shifting chain. Fixed circuit comprises input line, first output line, power dividing line and second output line arranged to form open circuit. Power dividing line comprises an input power dividing section, a first output power dividing section and a second output power dividing section connected to each other. Sliding chain comprises one-way connecting line connecting input line with first output line, input power dividing line connecting the input line with the input power dividing section, first output connecting line connecting first output line with first output section of power division, and a second output connecting line connecting the second output line to the second output power section. When the phase shifter is in the operating mode of the two-channel output, the antenna is in the operating mode of a narrow beam in the vertical plane. Antenna is configured to adjust orientation by moving the movable sliding plate.

EFFECT: providing the possibility of controlling the output mode of the phase shifter to implement the function of switching the output mode of the antenna in the vertical plane.

14 cl, 8 dwg

Description

TECHNICAL FIELD

The present invention relates to the field of mobile communication antennas and, in particular, to a phase shifter with output mode control and an antenna.

BACKGROUND OF THE ART

As an important part of a wireless communication system, the base station antenna plays an important role in transmitting and receiving a wireless communication signal, and its performance is directly related to the communication quality provided by the entire communication system. With the rapid development of mobile communication technology, basic technical solutions such as multi-band array and large array have been applied to the electronically tuned base station antenna. At the same time, to solve problems in a number of special situations, additional requirements are imposed on the operational characteristics of the antenna, in particular - ensuring overlap in high-rise buildings and amplification in areas where the reception of the base station signal is stopped, while the electronically tuned antenna must be made with the ability to switch to operating Wide beam mode to meet occlusion requirements in special situations.

The beam width of the known antenna in the vertical plane is fixed, which does not satisfy the need for beam switching. In view of the above, there is a need to create a new phase shifter with the function of adjusting the output mode.

SUMMARY OF THE INVENTION

In order to solve the above problems, the present invention proposes a phase shifter with the ability to regulate the output mode, configured to implement the function of switching the output mode of a known antenna in the vertical plane, and also proposes an antenna with a phase shifter with the ability to regulate the output mode.

According to the technical solution of the present invention, a phase shifter with the ability to regulate the output mode is proposed, containing:

a stationary dielectric plate, wherein stationary circuits are located on the stationary dielectric plate; And

a movable sliding plate, wherein the movable sliding plate is located on the surface of a stationary dielectric plate on which the stationary circuits are located, wherein a plurality of sliding chains corresponding to each of the stationary circuits are located on the movable sliding plate, wherein the stationary circuit is configured to be connected to at least at least one corresponding sliding chain and forming, together with it, a phase-shifting circuit, wherein the movable sliding plate is configured to slide relative to the stationary dielectric plate to switch the sliding chain connected to the stationary circuit and adjust the phase of the output signal of the phase-shifting circuit.

In addition, the output mode adjustable phase shifter also includes a sliding limit mechanism, wherein the sliding limit mechanism includes a sliding sheet buckle, wherein a safety groove is disposed on the movable sliding plate, wherein the sliding sheet buckle is disposed to pass through the safety groove for connection with the fixed dielectric plate, wherein the sliding sheet buckle is located on the movable sliding plate with a tight fit, whereby when the fixed chain and the sliding chain are connected, the fixed chain and the sliding chain are in contact in a mating connection.

In addition, a clamping hook is disposed on the sliding sheet buckle, and a sliding sheet buckle attachment hole is suitably located in the fixed dielectric plate, wherein the clamping hook is disposed to pass through the safety groove to engage with the sliding sheet buckle mounting hole for the purpose of fastening a sliding sheet buckle to a stationary dielectric plate, wherein a pressure sheet is also located on the sliding sheet buckle, wherein the pressure sheet is pressed against the movable sliding plate, due to which the stationary chain and the sliding chain are in contact at said mating joint.

In addition, an installation post is also located on the sliding sheet buckle, and a sliding sheet buckle installation hole is located in the fixed dielectric plate under the installation post, and the installation post is aligned with the sliding sheet buckle installation hole to install the sliding sheet buckle to the desired position.

In addition, the phase shifter with the ability to regulate the output mode also contains a transmission element, wherein the transmission element is connected to the movable sliding plate, and the movable sliding plate is driven by the transmission element.

In addition, the transfer element includes a transfer column, wherein a transfer hole for the transfer column is located in the movable sliding plate, wherein the transfer element is connected to the movable sliding plate through the interaction of the transfer column with the transfer hole, while on the stationary dielectric plate accordingly a guide groove is located, wherein the transfer post is positioned to pass through the transfer hole to pass into the guide groove.

Further, the fixed circuit includes an input line, a first output line, a power sharing line, and a second output line arranged to form an open circuit, wherein the power sharing line includes an input power sharing portion, a first output power sharing portion, and a second output portion. power sharing portions coupled to each other, wherein the sliding chain includes a one-way connecting line connecting the input line to the first output line, an input power sharing connecting line connecting the input line to the input power sharing portion, a first output connecting line connecting the first an output line to the first output power sharing portion, and a second output connecting line connecting the second output line to the second output power sharing portion.

In addition, the input line is located parallel to the open end of the first output line at a certain distance, while the input power section is located parallel to the direction of movement of the movable sliding plate, the input power section is parallel to the first output power section at a certain distance, and the open end of the second output The power section is located parallel to the second output line at a certain distance.

In addition, if two or more fixed circuits are located on the stationary dielectric plate, a decoupling line is located between two adjacent second output lines.

In addition, at the input section of the power section there is an input resistance conversion line, at the first output section of the power section there is a first resistance conversion line, at the second output section of the power section there is a second resistance conversion line, wherein the input section of the power section, the first output section of the power section , the second output power section, the input resistance conversion line, the first resistance conversion line, the second resistance conversion line and the second output line can be adjusted according to the line width and line length.

In addition, the one-way connecting line, the first output connecting line, the second output connecting line and the input power sharing connecting line can be adjusted in line shape, width and length.

In addition, the stationary circuit is placed on a stationary dielectric plate by etching a printed circuit board (PCB), while the sliding circuit is placed on a movable sliding plate by etching a PCB.

In addition, one surface of the moving sliding plate, on which the sliding chain is located, is coated with a polytetrafluoroethylene (PTFE) film, insulating it from the sliding chain.

In addition, when the input line is connected to the first output line through the sliding chain, the phase shifter is in the single-channel output operating mode; wherein, when the input line is connected to both the first output line and the second output line through a sliding chain, the phase shifter is in the dual-channel output operating mode, and the phase of the output signal of the first output line remains unchanged, while under the influence of the movement of the movable sliding plate the phase of the output signal of the second output line changes.

An antenna is proposed with a phase shifter disclosed above with the ability to regulate the output mode, while when the phase shifter is in the single-channel output operating mode, the antenna is in the wide beam operating mode in the vertical plane, when the phase shifter is in the dual-channel output operating mode, the antenna is in the narrow beam operating mode beam in a vertical plane, while under the action of moving the movable sliding plate, the phase of the output signal of the second output line changes, while the antenna is configured to regulate its orientation by moving the movable sliding plate.

The proposed phase shifter with the ability to regulate the output mode has two modes: single-channel output and dual-channel output and is designed to switch from one to another of these two modes, while the dual-channel output mode includes a phase shift function. The antenna with a phase shifter has a wide beam operating mode and a narrow beam operating mode with the ability to adjust the orientation in the vertical plane. The phase shifter is designed to not only implement the function of switching a known antenna from a wide beam mode to a narrow beam mode in a vertical plane and vice versa, but also allows it to comply with modern requirements for the layout of a large antenna array.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic diagram of the general structure of a phase shifter with the ability to regulate the output mode according to one of the embodiments of the present invention;

FIG. 2 is a perspective view of the general structure of a phase shifter according to one of the embodiments of the present invention;

FIG. 3 is a schematic diagram of the topology of a fixed circuit on a fixed dielectric plate according to one embodiment of the present invention;

FIG. 4 is a schematic diagram of the topology of a sliding chain on a movable sliding plate according to one embodiment of the present invention;

FIG. 5 is a schematic diagram of the arrangement of phase shifter lines in single-channel output mode according to one of the embodiments of the present invention;

FIG. 6 is a schematic diagram of the arrangement of phase shifter lines in dual-channel output mode according to one of the embodiments of the present invention;

FIG. 7 is a schematic diagram of a power sharing line topology according to one embodiment of the present invention; And

FIG. 8 is a schematic diagram of the structure of a sliding sheet buckle according to one embodiment of the present invention.

Position numbers: 1 - fixed plate; 100 - fixed chain; 110 - input line; 111 - power dividing line; 112 - first output line; 113 - second output line; 120 - metal base grounding; 130 - guide groove; 140 - hole for fastening the sliding leaf buckle; 141 - hole for installing a sliding sheet buckle; 150 - input end; 151 - first output end; 152 - second output end; 160 - input power section; 161 - first output power section; 162 - second output section of the power section; 170 - input resistance conversion line; 171 - first resistance conversion line; 172 - second resistance conversion line; and 180 - disconnecting line;

2 - movable sliding plate; 200 - movable dielectric plate; 210 - power sharing input connecting line; 211 - first output connecting line; 212 - second output connecting line; 213 - single-channel connecting line; 220 - safety groove; 230 - transfer hole; and 240 - PTFE film;

300 - sliding leaf buckle; 310 - installation column; 320 - clamping hook; and 330 - pressure sheet; And

400 - transmission element; and 410 - transfer column.

IMPLEMENTATION OF THE INVENTION

The technical solution of the present invention will be clearly and fully disclosed below with reference to the drawings. It should be noted that the drawings in the embodiments are provided solely to schematically illustrate the basic idea of the present invention, and only show those components that relate to the present invention, but are not designed to take into account the number, shape and size of the components in actual implementation. The type, number, and scale of components may be subject to arbitrary changes in actual implementation, and the layout of components may be more complex.

In the embodiment of the present invention in FIG. 1 - FIG. 8, a phase shifter with the ability to regulate the output mode is proposed, which can be used for a single-row antenna with dual polarization and contains:

a fixed dielectric plate 1, wherein fixed circuits 100 are located on the fixed dielectric plate 1. The embodiment of FIG. 3 comprises two fixed circuits 100, wherein each fixed circuit 100 includes an input line 110, a first output line 112, a power sharing line 111, and a second output line 113 arranged to form an open circuit, wherein the power sharing line 111 includes an input power section 160, a first output power section 161 and a second output power section 162 connected to each other. The second output line 113 corresponds to the second output section 162 of the power section, and the first output line 112 corresponds to the first output section 161 of the power section.

In the embodiment of FIG. 3, the power split line 111 is equivalent to a two-way power divider, with one end of the input line 110 being the input end 150 and the other end of the input line being open. One end of the first output line 112 is the first output end 151, and the other end of the first output line is open. Both the input and output ends of the power sharing line 111 are open. One end of the second output line 113 is a second output end 152, and the other end of the second output line is open.

In the embodiment of FIG. 3, the input line 110 is parallel to the open end of the first output line 112 at some distance, the input power sharing portion 160 is parallel to the first output power sharing portion 161 at some distance, and the open end of the second output line 113 is parallel to the second output power sharing portion 162 at some distance. distance. The distance between parallel lines in each of the three groups of parallel lines can be adjusted depending on the actual layout.

In addition, in one embodiment, the power sharing line 111 also includes an input impedance conversion line 170, a first impedance conversion line 171, and a second impedance conversion line 172.

The phase shifter also includes a movable sliding plate 2, wherein the movable sliding plate 2 is located on the surface of a stationary dielectric plate 1 on which the stationary circuits 100 are located, while on the movable sliding plate 2 there are a plurality of sliding chains 200 corresponding to each of the stationary circuits 100, with In this case, the fixed chain 100 is configured to connect with at least one corresponding sliding chain 200 and form, together with it, a phase-shifting circuit, while the movable sliding plate 2 is configured to slide relative to the stationary dielectric plate 1 to switch the sliding chain 200 connected to fixed circuit 100, and adjusting the phase of the output signal of the phase-shifting circuit.

In one embodiment of FIG. 4, the sliding chain 200 includes an input power sharing line 210 connecting the input line 110 to the input power sharing portion 160, a first output connecting line 211 connecting the first output line 112 to the first output power sharing portion 161, a second output connecting line 212, connecting the second output line 113 to the second output power sharing portion 162, and a one-way connecting line 213 connecting the input line 110 to the first output line 112.

In one embodiment of FIG. 4, both the power sharing input connecting line 210 and the first output connecting line 211 are straight, and the second phase shift connecting line 212 and the single-channel connecting line 213 are U-shaped.

In FIG. 5 shows that in one embodiment, in the single-channel output mode, the movable sliding plate 2 can no longer slide relative to the fixed dielectric plate 1. In this case, the single-channel connecting line 213 is configured to connect to the input line 110 and the first output line 112, wherein the input line 110 and the first output line 112 are switched from an open circuit state to a conducting state. After input from the input line input end 150, the signal can only be output through the first output end 151, thereby realizing a single-channel output mode. In addition, this state of the phase shifter antenna allows the implementation of a wide beam operating mode.

In one embodiment of FIG. 6, in the dual output mode, the movable sliding plate 2 can be moved relative to the fixed dielectric plate 1, the power sharing input connecting line 210 is connected to the input line 110 and the power sharing input portion 160, the first output connecting line 211 can be connected to the first output line 112, and with the first output power section 161, and the second output connecting line 212 may be connected to the second output line 113 and the second output power section 162. The input line 110, the power sharing line 111, the first output line 112 and the second output line 113 are switched from an open circuit state to a conducting state. In this case, the single-channel connecting line 213 is located outside the connection area of the corresponding fixed circuit lines and is in an idle state. After input from the input end 150, the signal passes through the power splitting input connecting line 210, after which it is divided into two signals by a power divider. One signal is output by the first output end 151 on the first output connecting line 211, and the other signal is output by the second output end 152 on the second output connecting line 212, thereby realizing a dual-channel output mode. In this case, when the movable sliding plate 2 moves, the phase of the signal output through the second output end 152 also changes. Thus, in this case, the use of a phase shifter antenna allows the implementation of a narrow beam operating mode with the ability to adjust the orientation. The position of the movable sliding plate in FIG. 6 is shown for illustrative purposes only, but in practice, movement of the movable sliding plate 2 may occur within a certain range from left to right relative to the indicated position, thereby adjusting the phase of the signal output by the second output end 152 in a dual-channel output mode.

In addition, in FIG. 6 shows that in one embodiment, in dual output mode, the distance between the two second power sharing output portions 162 is relatively small, wherein the decoupling line 180 is positioned to shorten the connection between said two second power sharing output portions 162 and thereby , increasing the degree of channel separation.

In FIG. 2 shows that in one embodiment of the present invention, one surface of the movable sliding plate 2 on which the sliding chain 200 is located is coated with a layer of PTFE film 240 to reduce the friction force generated by the movable sliding plate 2 during the movement process and protect the sliding chain from the movable sliding plate 2 from abrasion during the specified movement.

In FIG. 1 and FIG. 2 shows that in one embodiment of the present invention, the dielectric layers and line layers of the fixed dielectric plate 1 and the movable sliding plate 2 are arranged relative to each other in the following order from top to bottom: movable sliding plate 2 → power sharing input connecting line 210, first output connecting line line 211, second output connecting line 212 and single-channel connecting line 213→ input line 110, power sharing line 111, first output line 112, phase shift output line 113 and decoupling line 180→ fixed dielectric plate 1→ metal base ground 120.

In one embodiment of the present invention, adjusting parameters such as the shape, length, and width of single-channel connecting line 213 improves impedance matching for single-channel output mode.

Adjusting the input resistance conversion line 170, the first resistance conversion line 171 and the second resistance conversion line 172 on the power division line 111 along the length and width of the line allows not only to optimize the resistance matching in the dual-channel output mode, but also to adjust the output power of the first output end 151 and the second output end 152. Adjustment of parameters such as the shape, width and length of the input connection line 210, the first output connection line 211 and the second output connection line 212 can effectively optimize the impedance matching in the dual output mode. In addition, by matching the lines near the input power section 160, the first output power section 161 and the second output power section 162 and the output phase shift line 113, the impedance matching can be optimized.

In FIG. 1, FIG. 2, FIG. 3 and FIG. 4B shows that in one embodiment, the phase shifter also includes a sliding limit mechanism, wherein the sliding limit mechanism includes a sliding sheet buckle 300, wherein the movable sliding plate 2 is located between the stationary dielectric plate 1 and the sliding sheet buckle 300, wherein a safety groove 220 is located on the movable sliding plate 2, and the sliding sheet buckle 300 is arranged to pass through the safety groove 220 for connection with the stationary dielectric plate 1, while the sliding sheet buckle 300 is located on the movable sliding plate 2 with a tight fit, as a result, when the fixed chain 100 and the sliding chain 200 are connected, the fixed chain 100 and the sliding chain 200 are in contact in a mating connection.

Specifically, a clamping hook 320 is disposed on the sliding sheet buckle 300, and a sliding sheet buckle mounting hole 140 is suitably disposed in the fixed dielectric plate, and a clamping hook 320 on the sliding sheet buckle 300 is positioned to pass through a safety groove 220 on the movable sliding plate and a hole 140 for fastening the sliding sheet buckle in the fixed chain for engaging the fixed dielectric plate 1, while a pressure sheet 330 is also located on the sliding sheet buckle 300, and the pressure sheet 330 is pressed against the movable sliding plate 2, due to which the fixed chain 100 and the sliding chain 200 are in contact at said mating junction. Due to this, the frictional force of the movable sliding plate when it moves relative to the fixed chain does not go beyond the acceptable range, while simultaneously ensuring the connection of the movable sliding plate with the fixed chain and thereby preventing the movable sliding plate from being unable to move due to excessive friction force.

An installation post 310 is also located on the sliding sheet buckle 300, and a sliding sheet buckle installation hole 141 is located in the fixed dielectric plate 1 under the installation post 310, and the installation post 310 is aligned with the sliding sheet buckle installation hole 141 to install the sliding sheet buckle 300 in the desired position and thereby preventing rotation of the sliding leaf buckle. At the same time, the installation post 310 also makes it possible to avoid deflection of the movable sliding plate in the vertical direction along the moving path, and thereby prevents resistance mismatch due to deflection of the movable sliding plate. In other embodiments of the present invention, a plurality of clamp hooks may be used in place of the mounting post 310 to perform this function.

In one embodiment of the present invention, the output mode adjustable phase shifter also includes a transmission element 400, wherein the transmission element 400 is coupled to the movable sliding plate 2, and the movable sliding plate 2 is driven by the transmission element 400.

The transfer element 400 includes a transfer column 410, and in the movable sliding plate 2 there is a transfer hole 230 for the transfer column, while the transfer element 400 is connected with the movable sliding plate 2 due to the interaction of the transfer column 410 with the transfer hole 230, while on A guide groove 130 is suitably disposed on the fixed dielectric plate 1, wherein the guide groove 130 is formed along the moving direction of the movable sliding plate, and the transfer post 410 is positioned to pass through the transfer hole 230 to pass into the guide groove 130.

Movement of the transfer post 410 is achieved by applying an external pulling force to the transfer element 400, wherein the transfer post 410 is positioned to pass through a transfer hole 230 in the movable sliding plate to move into the guide groove 130 to more accurately control the movement of the movable sliding plate. The safety groove 220 on the movable sliding plate is formed along the moving direction of the movable sliding plate 2, which can prevent unwanted contact of the movable sliding plate with the clamping hook 320 on the sliding sheet buckle 300 during the movement, and also prevent the sliding sheet buckle 300 from loosening and thereby the occurrence of problems such as resistance mismatch due to the loosening of the movable sliding plate caused by the loosening of the sliding sheet buckle 300.

In one embodiment of the present invention, the sliding sheet buckle is machined by injection molding and contains a heat-resistant insulating material, and its functions include providing limits to the movable sliding plate and connecting the movable sliding plate to the stationary chain. The transfer element is manufactured mechanically by injection molding, contains heat-resistant insulating material, and its functions include driving a movable sliding plate.

The output mode adjustable phase shifter in this embodiment has a simple structure, can be reconfigured, has a relatively small overall size, and meets the requirement for a compact layout of a large antenna array. The phase shifter is configured to implement two output modes: single-channel output or dual-channel output, and the dual-channel output mode also includes a phase shift function. The movable sliding plate is adjusted to realize these two output modes, followed by two modes of antenna vibrator radiation: wide beam and narrow beam. For the phase shifter, the traditional method of etching PPS is used, and the phase shifter has a simple structure, which simplifies installation and wiring, and also has a low cost, which makes it suitable for mass production.

In addition, the present invention provides the following advantages over the known technical solution.

1. Possibility of changing the layout. Suitable topologies for the single link trunk and the second output trunk can be selected depending on the actual applications, which can effectively prevent problems associated with a specific line length from occurring.

2. Low complexity of coordination. By adjusting parameters such as the shape and length of connecting lines, standing waves at the single-output and dual-output input channels can be effectively adjusted, thereby reducing the difficulty of identifying and eliminating standing waves in the device as a whole.

3. Low attenuation. The connection of both the fixed chain and the sliding chain according to the principle of a direct connecting transmission line provides relatively low attenuation compared to the known implementation mode with an open circuit section.

In one embodiment, the present invention also provides an antenna with a phase shifter disclosed above with the ability to adjust the output mode, while when the phase shifter is in the single-channel output operating mode, the antenna is in the vertical wide beam operating mode, when the phase shifter is in the dual-channel operating mode. output, the antenna is in the operating mode of a narrow beam in the vertical plane, while under the action of moving the movable sliding plate, the phase of the output signal of the second output line changes, and the antenna is configured to regulate its orientation by moving the movable sliding plate.

The above embodiment is only one embodiment of the present invention, which is not limited to it. Any other changes, modifications, substitutions, combinations and simplifications without departing from the essence and principle of the invention should be considered as falling within the scope of protection of the present invention.

Those skilled in the art will appreciate that the present invention is not limited to the features of the embodiments disclosed above, and that the present invention may be embodied in other particular forms without departing from the spirit or essential features of the present invention. Therefore, the above embodiments are to be considered as examples and are not limiting in any way, it being understood that the scope of the present invention is defined by the appended claims and not by the above description, and includes all modifications without departing from the spirit and within the scope of decisions , equivalent to the elements according to the claims of the present invention.

It should also be understood that while the invention has been described in accordance with embodiments, no embodiment comprises only one discrete technical solution. The description is set forth in this manner solely for the purpose of explanation and those skilled in the art should consider the description as a whole. The technical solutions of each of the embodiments can be suitably combined to create other embodiments that may be understood by those skilled in the art.

Claims (17)

1. A phase shifter with the ability to regulate the output mode, containing: a stationary dielectric plate, wherein stationary circuits are located on the stationary dielectric plate; And a movable sliding plate, wherein the movable sliding plate is located at one surface of the stationary dielectric plate on which the stationary circuits are located, while on the movable sliding plate there are a plurality of sliding chains corresponding to each of the stationary circuits, wherein the stationary circuit is configured to be connected to at least one corresponding sliding chain and forming, together with it, a phase-shifting circuit, wherein the movable sliding plate is configured to slide relative to the stationary dielectric plate to switch the sliding chain connected to the stationary circuit and adjust the phase of the output signal of the phase-shifting circuit; wherein the fixed circuit contains an input line, a first output line, a power sharing line and a second output line located to form an open circuit, wherein the power sharing line contains an input power sharing section, a first output power sharing section and a second output power sharing section, connected each other, wherein the sliding chain contains a one-way connecting line connecting the input line with the first output line, an input power sharing line connecting the input line with the input power sharing section, a first output connecting line connecting the first output line with the first output section of the section power, and a second output connecting line connecting the second output line with the second output power sharing portion. 2. A phase shifter with the ability to regulate the output mode according to claim 1, additionally containing a sliding limiting mechanism, wherein the sliding limiting mechanism contains a sliding sheet buckle, and a safety groove is located on the movable sliding plate, and the sliding sheet buckle is located with the ability to pass through the safety a groove for connecting to the fixed dielectric plate, wherein the sliding sheet buckle is located on the movable sliding plate with a tight fit, whereby when the fixed chain and the sliding chain are connected, the fixed chain and the sliding chain are in contact in a mating connection. 3. A phase shifter with the ability to regulate the output mode according to claim 2, characterized in that a clamping hook is located on the sliding sheet buckle, while a hole for fastening the sliding sheet buckle is appropriately located in the stationary dielectric plate, and the clamping hook is located with the ability to pass through the safety a groove for engaging with the fastening hole of the sliding sheet buckle for the purpose of attaching the sliding sheet buckle to the stationary dielectric plate, wherein a pressure sheet is also disposed on the sliding sheet buckle, wherein the pressure sheet is pressed against the movable sliding plate, whereby the stationary chain and the sliding chain are in contact in the specified conjugate connection. 4. A phase shifter with the ability to regulate the output mode according to claim 2, characterized in that an installation post is also located on the sliding sheet buckle, while in the fixed dielectric plate there is a hole for installing the sliding sheet buckle under the installation post, and the installation post is aligned with the installation hole sliding leaf buckle to set the sliding leaf buckle to the desired position. 5. A phase shifter with the ability to regulate the output mode according to claim 1, additionally containing a transmission element, wherein the transmission element is connected to a movable sliding plate, and the movable sliding plate is set in motion by means of the transmission element. 6. A phase shifter with the ability to regulate the output mode according to claim 5, characterized in that the transfer element contains a transfer column, and in the movable sliding plate there is a transfer hole for the transfer column, and the transfer element is connected to the movable sliding plate due to the interaction of the transfer column with a transfer hole, wherein a guide groove is suitably disposed on the fixed dielectric plate, wherein the transfer post is arranged to pass through the transfer hole to pass into the guide groove. 7. A phase shifter with the ability to regulate the output mode according to claim 1, characterized in that the input line is located parallel to the open end of the first output line at a certain distance, while the input section of the power section is located parallel to the direction of movement of the movable sliding plate, while the input section of the power section is located parallel to the first output power section at a certain distance, while the open end of the second output power section is located parallel to the second output line at a certain distance. 8. A phase shifter with the ability to regulate the output mode according to claim 1, characterized in that if two or more fixed circuits are located on a stationary dielectric plate, a decoupling line is located between two adjacent second output lines. 9. A phase shifter with the ability to regulate the output mode according to claim 1, characterized in that the input resistance conversion line is located at the input section of the power section, the first resistance conversion line is located at the first output section of the power section, and the second conversion line is located at the second output section of the power section resistance, wherein the input power section, the first output power section, the second output power section, the input resistance conversion line, the first resistance conversion line, the second resistance conversion line and the second output line can be adjusted according to the line width and line length. 10. A phase shifter with the ability to regulate the output mode according to claim 1, characterized in that the one-way connecting line, the first output connecting line, the second output connecting line and the input power sharing connecting line can be adjusted in shape, width and length of the line. 11. A phase shifter with the ability to regulate the output mode according to claim 1, characterized in that the fixed circuit is separated on a stationary dielectric plate by etching a printed circuit board (PCB), and the sliding circuit is separated on a movable sliding plate by etching the PCB. 12. A phase shifter with the ability to regulate the output mode according to claim 1, characterized in that one surface of the movable sliding plate, on which the sliding chain is located, is covered with a polytetrafluoroethylene (PTFE) film, isolating it from the sliding chain. 13. A phase shifter with the ability to regulate the output mode according to claim 1, characterized in that when the input line is connected to the first output line through a sliding chain, the phase shifter is in the single-channel output operating mode; Moreover, when the input line is connected to both the first output line and the second output line through a sliding chain, the phase shifter is in the dual-channel output operating mode, while the phase of the output signal of the first output line remains unchanged, while under the influence of the movement of the movable sliding plate, changing the phase of the output signal of the second output line. 14. An antenna with a phase shifter with the ability to adjust the output mode according to clause 13, while when the phase shifter is in the single-channel output operating mode, the antenna is in the wide beam operating mode in the vertical plane, when the phase shifter is in the dual-channel output operating mode, the antenna is in operating mode of a narrow beam in a vertical plane, while under the action of moving the movable sliding plate, the phase of the output signal of the second output line changes, while the antenna is configured to regulate its orientation by moving the movable sliding plate.