KR20210017028A - Dielectric waveguide filter - Google Patents

Abstract

The present invention relates to a dielectric waveguide filter. The dielectric waveguide filter includes: a dielectric waveguide body wherein each of a plurality of dielectrics forms a resonator subunit to be connected and a slot forming a coupling window between adjacent resonator subunits is provided to consecutively pass electromagnetic waves; and sending-end and receiving-end subunits formed at ends of the dielectric waveguide body respectively to deliver the electromagnetic waves through a waveguide. The dielectric waveguide body has a path extension structure such that a pass path of the electromagnetic waves progressing through the inside of every one of the resonator subunits can become longer than a physical length on the outside, and the sending-end and receiving-end subunits have a wall dented inward, which is opposed to a wall where a sending end and a receiving end are attached, wherein the wall dented outward forms a mono-layered or multilayered base.

Description

Dielectric waveguide filter

The present invention relates to a dielectric resonator, and more particularly, to a dielectric waveguide filter having a reduced size while maintaining a frequency characteristic.

With the popularization of wireless mobile communication services, the demand for wireless relay devices is increasing, and in particular, the demand for small/lightweight relay devices is rapidly increasing. [0003] Dielectric resonators are widely used as electronic devices with dielectric resonant properties and as components of RF devices such as communication equipment and repeaters. With the rapid development of information and communication technology, portable equipment using various frequency bands is on the rise. In accordance with this trend, there is an increasing demand for a filter that can be miniaturized and operated at high power, and has high frequency temperature stability.

Dielectric resonators or dielectric ceramic filters are widely used as components of radio frequency (RF) devices such as communication equipment and repeaters because they are well suited to these needs. Dielectric resonators have advantages in that they have superior resonant characteristics at high frequencies compared to filters using general LC circuits, have high frequency temperature stability, and can withstand high operating power. The prior art literature presented below introduces classification of dielectric resonators, resonant frequencies, resonant modes, and utilization methods in such resonators.

Meanwhile, in the 5G era with the rapid development of information and communication technology, the communication system eliminates the repeater that was in charge of the relay function to cover the communication shadow area between the base station and the base station, and communicates to cover all cells directly with only the base station. The system is changing. Accordingly, the demand for a dielectric waveguide filter having a good frequency characteristic and a small size while maintaining a high power according to the performance of a base station and having a low price is greatly increasing. To this end, component manufacturers are designing various designs to further reduce the existing size, and are also making efforts to reduce spurious, which is an unnecessary harmonic component other than the target frequency.

Dielectric Resonator in Microwave, Eui-Seok Hong, Journal of the Korean Institute of Electrical Engineers 32,3 ('83.3) pp.22-27 ISSN 1975-8359 Registered in KCI, Korean Institute of Electrical Engineers, 1983.

The technical problem to be solved by the embodiments of the present invention is to overcome the limitation of the occurrence of harmonic signal components in the unwanted frequency band in the conventional rectangular waveguide filter, and the size of the filter while maintaining the frequency characteristics required by the market. In the case of a structure in which unit dielectric blocks are stacked in the height direction or the transmission direction of electromagnetic waves is changed to reduce the structure of the dielectric waveguide filter, the structure of the dielectric waveguide filter becomes complicated and the inconvenience of forming a different coupling pattern accordingly is solved. It aims to solve the problem of increasing process cost, product tolerance and defective rate due to cumbersome manufacturing process.

In order to solve the above technical problem, in the dielectric waveguide filter according to an embodiment of the present invention, each of a plurality of dielectrics is connected to form a resonator sub-unit, and a coupling window between adjacent resonator sub-units ( a dielectric waveguide body provided with a slot constituting a coupling window to continuously pass electromagnetic waves; And a transmitting end and a receiving end sub-unit each formed at an end of the dielectric waveguide body and transmitting electromagnetic waves through the dielectric waveguide, wherein the dielectric waveguide body passes electromagnetic waves traveling through the inner side of each resonator sub-unit. The path extension structure is provided so that the path is longer than the physical length of the outside, and the transmitting end and the receiving end sub-units have a wall surface opposite to the wall surface to which the transmitting end and the receiving end are attached to be concave inwardly, but formed concave inwardly. The wall surface forms a single or multi-layered base surface.

In the dielectric waveguide filter according to an embodiment, the transmitting end and the receiving end sub-unit may form a trench structure or a stepped structure inside a wall surface opposite to a wall surface to which the transmitting end and the receiving end are attached.

In the dielectric waveguide filter according to an embodiment, the transmitting end and the receiving end sub-units have either a hexahedral hole structure or a cylindrical hole structure from the center of the upper or lower wall to the inside of the body while leaving an outer support area. Can be formed.

In the dielectric waveguide filter according to an embodiment, the dielectric waveguide body and the transmitting end and receiving end sub-units may be configured to have different heights. In addition, the transmitting end and the receiving end sub-units may be configured to have at least a lower height than the dielectric waveguide body.

In the dielectric waveguide filter according to an embodiment, the dielectric waveguide body considers the passage path of the electromagnetic wave lengthened by the path extension structure provided for each resonator sub-unit so that harmonic components other than the required pass frequency band are reduced. , It may be formed to have a length shorter than the required length of the waveguide according to the resonance frequency.

In the dielectric waveguide filter according to an embodiment, the dielectric waveguide body may determine the length of the resonator sub-unit such that a harmonic component other than a required pass frequency band is reduced or the harmonic component is away from the pass frequency band. .

In the dielectric waveguide filter according to an embodiment, the path extension structure has an upper or lower wall surface of the resonator sub-unit concave inside the body so as to intersect with the traveling direction of the electromagnetic wave, the concave formed inside the body. The upper or lower wall surface may form a single or multi-layered base surface. In addition, the height of the base surface may be formed differently from each other for each resonator sub-unit.

In the dielectric waveguide filter according to an embodiment, the path extending structure may form either a trench structure or a stepped structure from the upper or lower wall surface to the inside of the body across the length direction of the waveguide. Further, the path extension structure forms either a hexahedral hole structure or a cylindrical hole structure from the center of the upper or lower wall surface to the inside of the body while leaving an outer support region.

In the dielectric waveguide filter according to an embodiment, the dielectric waveguide body may form a continuous stepped structure in which adjacent resonator sub-units are configured to have different heights of the resonator sub-units. In addition, in the dielectric waveguide body, heights of adjacent resonator sub-units may be determined so that a difference in impedance between the resonator sub-units can be induced. Further, the dielectric waveguide body forms a step structure in which the height of the resonator sub-unit gradually increases as the distance from the transmitting end and the receiving end sub-unit increases, so that the height near the center of the length direction of the dielectric waveguide body is highest. Can be configured.

In the dielectric waveguide filter according to an embodiment, the dielectric waveguide body may be formed symmetrically on both sides of the waveguide body through which the slots forming the coupling window pass through. In addition, the dielectric waveguide body may be asymmetrically formed only on one side of the waveguide body through which the slot forming the coupling window passes.

In order to solve the above technical problem, each of a plurality of dielectrics according to another embodiment of the present invention is connected to form a resonator sub-unit and forms a coupling window between adjacent resonator sub-units. A method of designing a dielectric waveguide filter comprising a dielectric waveguide body provided with a slot to continuously pass electromagnetic waves, and a transmitting end and a receiving end respectively formed at the ends of the dielectric waveguide body and transmitting electromagnetic waves through the dielectric waveguide, (a) receiving, by an apparatus for designing a dielectric waveguide filter, a parameter for a required frequency characteristic of an electromagnetic wave; (b) calculating a length of a target waveguide assuming that the electromagnetic wave passes through the dielectric waveguide filter in consideration of the cross section of the waveguide, but based on the input parameter; (c) The dielectric waveguide filter design device is reduced from the length of the target waveguide in consideration of the path extension structure formed such that the passage path of the electromagnetic wave traveling through the inner side of the resonator sub-unit is longer than the physical length of the outer side. Determining an overall size of the sized dielectric waveguide body; And (d) determining the height of the dielectric waveguide body or the transmitting end and receiving end sub-units such that harmonic components other than the pass frequency band required by the design device of the dielectric waveguide filter are reduced.

In the method of designing a dielectric waveguide filter according to another embodiment, the step (c) of determining the overall size of the dielectric waveguide body comprises: (c1) an upper or lower wall surface of the resonator sub-unit so as to cross the traveling direction of the electromagnetic wave. Considering the path extension structure formed concave in the body, but determining the length of each of the resonator sub-units such that a harmonic component other than a required pass frequency band is reduced or the harmonic component is away from the pass frequency band. ; And (c2) determining the number of required resonator sub-units in consideration of the length of the target waveguide from the determined length of each of the resonator sub-units.

In the method of designing a dielectric waveguide filter according to another embodiment, the step (d) of determining a height of a dielectric waveguide body or a transmitting end and a receiving end sub-unit includes (d1) the dielectric waveguide body and the transmitting end and receiving end sub-units. Determining that the sub-units of the transmitting end and the receiving end have a height lower than that of the dielectric waveguide body, but configured to have different heights from each other; And (d2) forming a step structure in which the height of the resonator sub-unit gradually increases as the distance from the transmitting end and the receiving end increases, but the height near the center of the lengthwise direction of the dielectric waveguide body is the highest, and between the resonator sub-units It may include; determining heights of adjacent resonator sub-units so that a difference in impedance can be induced.

Embodiments of the present invention reduce the size of the entire waveguide filter through a path extension structure provided inside the resonator sub-unit, while maintaining the frequency characteristics in accordance with the purpose, and suppressing spurious occurrences of harmonic signal components in unwanted frequency bands. In addition, by utilizing the low-pass characteristic of a corrugated structure in which the characteristic impedance varies depending on the height of the resonator sub-unit, an effect of further enhancing the spurious reduction width can be obtained. Furthermore, by implementing the waveguide body of an integrally formed single-layer structure rather than a lamination method, the manufacturing process can be simplified and the cost and defect rate can be reduced at the same time.

1 is a diagram illustrating a dielectric waveguide filter having a path extending structure according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating a path through which an electromagnetic wave is transmitted through the dielectric waveguide filter of FIG. 1 according to an embodiment of the present invention.
3 is a diagram illustrating a correlation between the size of a dielectric waveguide and a resonance frequency band.
4 is a diagram for explaining a principle in which the length of the dielectric waveguide filter is shortened by the path extension structure adopted by the embodiments of the present invention.
5 is a diagram illustrating a structure of a general rectangular waveguide filter and a graph of a frequency characteristic according thereto.
6 is a diagram illustrating a structure of a dielectric waveguide filter employing a path extension structure proposed by embodiments of the present invention and a graph of a frequency characteristic according thereto.
FIG. 7 is a diagram for comparing spurious generated according to the waveguide filter of FIG. 5 and the waveguide filter of FIG. 6.
8 is a view for explaining a method of determining a low pass characteristic of a dielectric waveguide filter employing a path extension structure according to embodiments of the present invention.
9 to 11 are views showing various embodiments of the path extension structure.
12 and 13 are diagrams showing various implementation examples of a slot structure forming a coupling window.
14 and 15 are views showing the structure of a prototype of the present invention manufactured by changing the path extension structure and the height of the resonator sub-unit.
16 is a flowchart illustrating a method of designing a dielectric waveguide filter having a path extension structure according to another embodiment of the present invention.

Prior to describing the embodiments of the present invention, after examining the characteristics and problems of a rectangular waveguide used in the field of conventional dielectric resonator technology, embodiments of the present invention are adopted to solve these problems. Here is an overview of the technical means.

In order to reduce the size of the conventional dielectric waveguide filter, the volume is kept small by stacking resonators in the height direction or folding the filter in a specific direction (such as a'C' shape or a'D' shape). However, it was possible to reduce the size of such a design, but in actual production, a three-dimensional multi-layer structure was formed, and in order to plate between the lower layer and the upper layer resonator, or to put a pattern between the lower layer and the upper layer, it is cumbersome to re-join after each additional pattern insertion operation. The process took place. This, in turn, caused a problem in that the work process was lengthened and complicated, resulting in a high ratio of product tolerance and defective rate, and high cost.

In addition, in the conventional square waveguide filter, a problem in which unnecessary harmonic signal components appear in an unwanted frequency band has been discovered, and a technical means for effectively suppressing this has also been required.

Accordingly, embodiments of the present invention are conceived from the recognition of the above problem, and have good frequency characteristics, reduce their size, and reduce and control second to third harmonic frequencies, that is, spurious. I would like to propose.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. However, in the following description and the accompanying drawings, detailed descriptions of known functions or configurations that may obscure the subject matter of the present invention will be omitted. In addition, throughout the specification, "including" a certain component means that other components may be further included, rather than excluding other components unless specifically stated to the contrary.

The terms used in the present invention are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In the present application, terms such as "comprise" or "comprise" are intended to designate the existence of a set feature, number, step, action, component, part, or a combination thereof, but one or more other features or It is to be understood that the presence or addition of numbers, steps, actions, components, parts, or combinations thereof does not preclude the possibility of preliminary exclusion.

Unless otherwise defined, all terms, including technical and scientific terms, used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms as defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning of the context of the related technology, and should not be interpreted as an ideal or excessively formal meaning unless explicitly defined in this application. .

1 is a view showing a dielectric waveguide filter having a path extension structure according to an embodiment of the present invention, and shows the perspective view (A) and the side view (B) matched.

The dielectric waveguide body 10 is connected to each of a plurality of dielectrics to form a resonator sub-unit, and a slot forming a coupling window between adjacent resonator sub-units is provided and connected. Electromagnetic waves are continuously passed along the resonator sub-unit. In this case, unlike a method of manufacturing the dielectric waveguide body 10 using a unit dielectric block used in an industrial field, it is preferable that the dielectric waveguide body 10 is designed and integrally formed to meet the initially required specifications.

The dielectric waveguide body 10 is provided with a path extension structure 15 so that the passage path of the electromagnetic wave traveling through the inside of each resonator sub-unit is longer than the physical length of the outside. It is preferable that the path extension structure 15 is formed such that the upper or lower wall surface of the resonator sub-unit is concave inside the body so as to basically cross the traveling direction of the electromagnetic wave. In FIG. 1, the path extension structure 15 is represented by a two-story step structure or an overlapping trench structure, but is not limited to this example. The path extension structure 15 was largely introduced for two purposes. First, a design in which multiple steps are provided for each resonator sub-unit has the effect of making the actual travel distance of electromagnetic waves longer than the physical size of the waveguide. And second, it has the effect of reducing spurious generated in a frequency band higher than the pass frequency band. In particular, in the case of the first effect, the overall size of the resonator is significantly reduced as the length of the resonator is shortened compared to the frequency characteristics required in actual implementation.

Meanwhile, by configuring the heights of the resonator sub-units to be different from each other, adjacent resonator sub-units may form a continuous stepped structure. Although FIG. 1 shows the height of each resonator sub-unit equally, from the point of view of implementation, the resonator sub-units have a certain directionality and may be designed in various ways, such as increasing or decreasing the height. The reason for the configuration with different heights is that the aforementioned spurious reduction effect can be further enhanced by utilizing the low-pass characteristic of a corrugated structure whose characteristic impedance varies according to the height of each resonator sub-unit. More specific implementations of this will be introduced later through FIGS. 9 to 15.

The transmitting end and the receiving end sub-units 20 and 30 are respectively formed at the ends of the dielectric waveguide body 10 to transmit electromagnetic waves through the dielectric waveguide, respectively, and a transmitting end 25 and a receiving end 35 may be provided. have. In terms of implementation, the transmitting end 25 and the receiving end 35 may form either N-type or SMA-type connector by perforating a hole in the vertical direction. It is also possible to form an SMD type connector by inserting a strip line in the ring part.

In addition, the transmitting end and the receiving end sub-units 20 and 30 have a wall surface opposite to the wall surface to which the transmitting end 25 and the receiving end 35 are attached, but the wall surface that is concave inwardly is formed in a single layer or multilayer It is desirable to form the base surface of. In particular, the transmitting end and the receiving end sub-units 20 and 30 form a trench structure or a stepped structure 27 and 37 in the inner side of the wall facing the wall to which the transmitting end 25 and the receiving end 35 are attached. The frequency characteristics can be improved or the effect of reducing spurious can be enhanced.

2 is a diagram showing a path through which an electromagnetic wave is transmitted through the dielectric waveguide filter of FIG. 1 according to an embodiment of the present invention. The path extension structure adopted by the embodiments of the present invention has a three-dimensional stepped step. It was implemented through a dielectric waveguide filter.

Referring to FIG. 2, the input electromagnetic waves pass through the coupling window along adjacent resonators and combine the resonant frequencies to form a filter.If there is a step-shaped step in each resonator sub-unit, the electromagnetic wave does not go straight. Since it proceeds along the stairs, the physical straight line outside the resonator is relatively short in order to have the same path length as required when implementing the actual waveguide filter.

3 is a diagram illustrating a correlation between the size of a dielectric waveguide and a resonance frequency band.

The dielectric waveguide filter forms a resonator structure through which electromagnetic waves in TE mode travel, and the frequency of each resonator is determined from Equation 1 below.

Here, f _c is a cut-off frequency, which is one of the characteristics of the TE mode waveguide type resonator. Due to the characteristics of the structure of the waveguide, the waveguide cannot transmit when it is not above a specific frequency, and the frequency corresponding to the wavelength at the time when only reflection is made in place without the propagation of the wave is called the cutoff frequency. In addition, c is the speed of light, ε is the dielectric constant of the dielectric material, and m, n, and l are the number of times the electric field distribution according to the width (width), length (height) and waveguide length of the waveguide cross section, respectively. It is a subscript of the waveguide mode determined according to, and a, b, and d denote the width (width), length (height), and waveguide length of the waveguide cross section, respectively.

Referring to FIG. 3, when the width (width) and length (height) of the waveguide are constant, the resonance frequency is determined by the length d. As shown in FIG. 2, the resonator sub- Since the length of each unit is substantially shortened, the length of the entire filter is also shortened.

FIG. 4 is a view for explaining the principle that the length of the dielectric waveguide filter is shortened by the path extension structure adopted by the embodiments of the present invention. As described with reference to FIG. 2, the same by the path extension structure 15 It is shown that the physical outer length of the waveguide filter can be relatively shortened in (B) compared to (A) even with an electromagnetic wave passing path. That is, the dielectric waveguide body may be formed to have a length shorter than the length of the waveguide required according to the resonance frequency in consideration of the passage path of the electromagnetic wave lengthened by the path extension structure provided for each resonator sub-unit.

FIG. 5 is a diagram illustrating a structure of a general rectangular waveguide filter and a graph of a frequency characteristic according thereto, and it can be seen that it is composed of seven-stage unit dielectric blocks at a center frequency of 3.7 GHz.

The electromagnetic wave entering through the input terminal passes through the apertures of resonators adjacent to each other (meaning the space between the symmetrical wall and the wall) and exhibits a desired frequency characteristic. The size of the aperture depends on the coupling value designed for the desired frequency characteristics.

Accordingly, the waveguide structure of FIG. 6 having a three-dimensional stepped path extension structure was designed to solve the weakness of a long length of a dielectric rectangular waveguide filter while having the same frequency characteristics as FIG. 5.

Looking at the structure of the waveguide filter of FIG. 6 and the frequency characteristic graph corresponding thereto, it can be seen that although the length of the resonator is shortened, it shows a frequency characteristic similar to that of FIG. 5 and flows of electromagnetic waves along the adjacent resonator. In this case, the physical length of the waveguide filter required to secure the same frequency characteristic is much shorter in the case of FIG. 6 than in FIG. 5.

FIG. 7 is a diagram for comparing spurious generated by each of the waveguide filter of FIG. 5 and the waveguide filter of FIG. 6, and (A) is a diagram showing frequency characteristics showing the spurious phenomenon of a conventional rectangular waveguide filter And (B) is a diagram showing a frequency characteristic in which spurious is greatly reduced through a waveguide filter structure according to embodiments of the present invention.

In particular, when using the low-pass characteristic of a corrugated structure whose characteristic impedance varies depending on the height of the waveguide resonator, the shape of the waveguide filter with a path extension structure is always above the passband frequency compared to the conventional conventional dielectric waveguide filter. The spurious generated can be strongly suppressed. Compared to (A) of FIG. 7, in (B), it can be seen that the harmonic components ranging from 5.7 to 6.5 GHz are significantly reduced.

The half-wave resonant frequency of the waveguide filter appears as a spurious response. As the length of each end of the waveguide is designed to be shorter, the half-wave resonant frequency can be sent to a higher side, thereby obtaining excellent spurious characteristics. Accordingly, the three-dimensional stepped step serves to reduce the spurious always occurring above the pass frequency band by shortening the length of each step, or to separate it further to a higher level. In order to implement this more effectively, the spurious problem in the existing dielectric waveguide filter can be further improved by using the low-pass characteristic of a waveform structure having a characteristic impedance proportional to the height of each resonator.

Therefore, in the dielectric waveguide body according to the embodiments of the present invention, a path extension structure should be designed in the resonator sub-unit so that harmonic components other than the required pass frequency band are reduced. Further, the dielectric waveguide body may determine the length of each resonator sub-unit to be as short as possible so that the harmonic components other than the required pass frequency band are reduced or the harmonic components are moved away from the pass frequency band.

8 is a view for explaining a method of determining a low pass characteristic of a dielectric waveguide filter employing a path extension structure according to embodiments of the present invention.

When using the low-pass characteristic of the corrugated structure as shown in Fig. 8, when the center frequency is f ₀ and the pass band is f ₁ to f ₂ , the vertical of the low-pass waveguide filter using the lowest frequency mode TE ₁₀ If (width) a is determined, the electrical length θ ₀ of the low pass cutoff frequency f _c can be approximated to the electrical length θ ₂ at f ₂ as shown in Equation 2 below.

Referring to Equation 2, θ ₀ is determined by f ₂ and the length d of each end of the resonator. The length d of each stage of the resonator is related to the spurious characteristics, and since θ ₀ is a function of this length, it affects the characteristic impedance of each stage of the resonator. Therefore, in a corrugated waveguide, the characteristic impedance of each stage is proportional to the height, so in the corrugated waveguide having a low-pass filter that configures the height of the central part of the waveguide high, the length d and the length of the resonator are respectively You can control the spurious characteristics according to the height.

In the above, the path extension structure implemented inside the waveguide filter and the height adjustment of the resonator sub-unit maintains good frequency characteristics even though the size is reduced, while reducing the spurious above the frequency passband, while inducing an impedance difference, thereby reducing the spurious width. A waveguide filter that further enhances Hereinafter, implementation examples of various types of waveguide filters that have shown excellent performance through repeated experiments based on the above-described basic principle will be introduced.

9 to 11 are views showing various embodiments of the path extension structure.

Previously, it has been described that the path extension structure employed in the embodiments of the present invention may be formed to be concave inside the body of the upper or lower wall surface of the resonator sub-unit so as to cross the traveling direction of the electromagnetic wave. In addition, it has been described that the transmitting end and the receiving end sub-unit also has a wall surface opposite to the wall surface to which the transmitting end and the receiving end are attached to be concave inwardly, but the wall surface concave inwardly can form a single layer or multi-layer base surface. In terms of the effect, it was confirmed that the structure in which all of them coexist exhibits excellent performance in reducing spurious, but above all, it was found that the latter (base surface formed in the transmitting end and the receiving end sub-units) has a greater effect on the performance.

9 shows a structure in which an upper or lower wall surface concave inside the body forms a single-layer or multi-layer base surface in this path extension structure. In addition, the height of the base surfaces 15A and 15B at this time may be formed differently for each resonator sub-unit, and the path extension structure is a trench from the upper or lower wall surface to the inside of the body across the length direction of the waveguide. ) It can form either a structure or a staircase structure. For example, it may be implemented as a three-story staircase structure 15A, a second-story staircase structure 15B, or a combination thereof. Further, FIG. 9 illustrates a step structure in which the height of the resonator sub-unit gradually increases toward the center of the waveguide.

10 is designed by slightly different relationship between the transmitting end and the receiving end sub-units 20 and 30 and the dielectric waveguide body 10. In the dielectric waveguide filter according to embodiments of the present invention, the dielectric waveguide body 10 and the transmitting end and receiving end sub-units 20 and 30 may be configured to have different heights. -The units 20 and 30 are configured to have a height lower than that of the dielectric waveguide body 10 at least.

In addition, the transmitting end base surface 27 and the receiving end base surface 37 formed in the transmitting end and receiving end sub-units 20 and 30, and the path extension structure 15C formed in the dielectric waveguide body 10 are also designed differently. Unlike the structure previously presented through FIG. 9, in FIG. 10, in implementing the transmitting end base surface 27, the receiving end base surface 37 and the path extension structure, the body from the center of the upper or lower wall surface while leaving the outer support area A hexahedral hole structure 15C was formed inside. The hole structure 15C corresponds to the trench structure or the staircase structure of FIG. 9, and thus can be manufactured more easily, and has the advantage of having a structurally higher strength. Of course, it is natural that other types of hole structures other than hexahedral holes can be used.

Due to various limitations in the field where the dielectric waveguide filter is used, it may be difficult to reflect all theoretically optimized design elements. Even in this case, the configuration of forming the base surface 27 and the base surface 37 of the transmitting end and the base surface 37 of the transmitting end and the receiving end sub-units 20 and 30 is very important and has an absolute effect on performance. In addition, it was confirmed that it is a very important factor to keep the height of the transmitting end and the receiving end sub-units 20 and 30 lower than the height of the dielectric waveguide body 10. That is, the structural features presented for the transmitting end and the receiving end sub-units 20 and 30 in the embodiments of the present invention take precedence over the structural features presented for the dielectric waveguide body 10, and the spurious suppression effect through this configuration Was found to be able to maximize.

Meanwhile, FIG. 11 illustrates a step structure in which the height of each resonator sub-unit gradually decreases toward the center of the waveguide. In addition, a cylindrical hole structure 15D was formed by modifying the hexahedral hole structure 15C illustrated in FIG. 10.

As described above, in the dielectric waveguide body, it is preferable that the heights of adjacent resonator sub-units are determined so that a difference in impedance between the resonator sub-units can be induced. In summary, the dielectric waveguide body forms a step structure in which the height of the resonator sub-unit gradually increases as the distance from the transmitting end and the receiving end sub-unit increases, but the height near the center of the length direction of the dielectric waveguide body is highest (i.e. , The center portion of the waveguide may be convex). On the other hand, the dielectric waveguide body forms a step structure in which the height of the resonator sub-unit gradually decreases as the distance from the transmitting end and the receiving end sub-units decreases, but the height near the center of the length direction of the dielectric waveguide body is lowest (i.e. , The center portion of the waveguide may be concave).

12 and 13 are diagrams showing various implementation examples of a slot structure forming a coupling window.

12 illustrates a structure in which slots forming a coupling window for electromagnetic coupling of each dielectric sub-unit are symmetrical (17A, 17B). In addition, the height of each dielectric sub-unit is configured differently, but the height of the three-dimensional step is different. That is, in the dielectric waveguide body, slots forming the coupling window may be formed symmetrically on both sides of the waveguide body through which electromagnetic waves pass.

On the other hand, FIG. 13 illustrates a structure in which the slots forming the coupling window for electromagnetic coupling of each dielectric sub-unit are made of asymmetric (17C) rather than symmetrical. In addition, the height of each dielectric sub-unit is configured differently, but the height of the three-dimensional step is different. That is, the dielectric waveguide body may be asymmetrically formed only on one side of the waveguide body through which the slot forming the coupling window passes through the electromagnetic wave. This implementation method was devised for the convenience of manufacturing an integrally formed waveguide body.

14 and 15 are diagrams showing the structure of the prototype of the present invention manufactured by changing the path extension structure and the height of the resonator sub-unit, and the best frequency through experiments of various embodiments of the present invention It shows an example in which spurious suppression was easily achieved while showing characteristics.

14 and 15 adopt a corrugated structure in which the height of the dielectric sub-unit gradually increases toward the center of the waveguide (convex shape) to achieve easy spurious suppression by having a low-pass filter characteristic. Could Each dielectric sub-unit has a hexahedral or cylindrical path delay structure, and the transmitting end and the receiving end sub-units on both sides have base surfaces of a multistage structure concave inwardly. Although such a structure has shown very excellent frequency characteristics and spurious suppression performance through experiments to date, it is natural that a dielectric waveguide filter of a different type from that of Fig. 14 or 15 can be derived as long as the technical principle of the present invention is maintained. And is not limited to the illustrated structure.

Furthermore, it can be seen that a communication device including various types of dielectric waveguide filters described above can be derived, and that such a communication device can be usefully utilized in a 5G environment.

16 is a flowchart illustrating a method of designing a dielectric waveguide filter having a path extension structure according to another embodiment of the present invention. The design method of FIG. 16 is a reconstruction of the design of the dielectric waveguide filter of FIGS. 1 and 9 to 15 described above in terms of time-series manufacturing, and may be implemented through a series of instructions executed by an automated design device. . Accordingly, the hardware configuration itself has been outlined or omitted to avoid duplication of description.

FIG. 16 is a diagram in which a plurality of dielectrics are connected to form a resonator sub-unit, and a slot forming a coupling window between adjacent resonator sub-units is provided to continuously pass electromagnetic waves. A dielectric waveguide filter including a transmitting end and a receiving end that is provided at each end of the dielectric waveguide body and transmits electromagnetic waves through the dielectric waveguide is assumed as a basic configuration.

In step S1610, the device for designing a dielectric waveguide filter receives a parameter for a required frequency characteristic of an electromagnetic wave. These parameters may include determining factors required for driving the TE mode resonator and variables of the above-described equations.

In step S1620, the device for designing the dielectric waveguide filter calculates the length of the target waveguide assuming that the electromagnetic wave goes straight through based on the input parameter while considering the cross section of the waveguide. That is, first, assuming that there is no path extension structure, a necessary passage path for electromagnetic waves is obtained.

In step S1630, the device for designing the dielectric waveguide filter, considering the path extension structure formed such that the passage path of the electromagnetic wave traveling through the inside of the resonator sub-unit is longer than the physical length of the outside, from the length of the target waveguide. Determine the overall dimensions of the reduced size dielectric waveguide body. In this process, by reducing the length of the entire waveguide and each resonator sub-hold through the path extension structure, it is possible to derive a resonator structure that maintains frequency characteristics and suppresses spurious at the same time.

More specifically, in this process, first consider the path extension structure formed by concave the upper or lower wall surface of the resonator sub-unit to the inside of the body so as to intersect with the traveling direction of the electromagnetic wave, but harmonic components other than the required pass frequency band The length of each of the resonator sub-units is determined such that it decreases or the harmonic component is away from the pass frequency band. Then, the number of required resonator sub-units may be determined in consideration of the length of the target waveguide from the determined lengths of each of the resonator sub-units.

In step S1640, the device for designing the dielectric waveguide filter determines the height of the dielectric waveguide body or the transmitting and receiving end sub-units so that harmonic components other than the required pass frequency band are reduced.

More specifically, in this process, the dielectric waveguide body and the transmitting end and the receiving end sub-units are configured to have different heights, but the transmitting end and the receiving end sub-units are determined to have at least a lower height than the dielectric waveguide body. Then, a step structure is formed in which the height of the resonator sub-unit gradually increases as the distance from the transmitting end and the receiving end increases, but the height near the center of the lengthwise direction of the dielectric waveguide body is the highest, and the impedance between the resonator sub-units The height of adjacent resonator sub-units can be additionally determined so that a difference in (impedence) can be induced.

According to the above-described embodiments of the present invention, the size of the entire waveguide filter is reduced through the path extension structure provided inside the resonator sub-unit, while maintaining the frequency characteristics in accordance with the purpose, and harmonic signal components in the unwanted frequency band. By suppressing the spurious appearing, and utilizing the low-pass characteristic of a corrugated structure in which the characteristic impedance varies depending on the height of the resonator sub-unit, the spurious reduction width can be further enhanced. Furthermore, by implementing the waveguide body of an integrally formed single-layer structure rather than a lamination method, the manufacturing process can be simplified and the cost and defect rate can be reduced at the same time.

In the above, the present invention has been looked at around the various embodiments. Those of ordinary skill in the art to which the present invention pertains will be able to understand that the present invention can be implemented in a modified form without departing from the essential characteristics of the present invention. Therefore, the disclosed embodiments should be considered from an illustrative point of view rather than a limiting point of view. The scope of the present invention is shown in the claims rather than the foregoing description, and all differences within the scope equivalent thereto should be construed as being included in the present invention.

10: dielectric waveguide body
15, 15A, 15B, 15C, 15D: path extension structure
17A, 17B, 17C: slot
20: transmitting end sub-unit
25: transmitting end (connection terminal)
27: base surface of the transmitting end
30: receiving end sub-unit
35: receiving end (connection terminal)
37: receiving end base surface

Claims (20)

A dielectric waveguide body in which each of a plurality of dielectrics is connected to form a resonator sub-unit and has a slot forming a coupling window between adjacent resonator sub-units to continuously pass electromagnetic waves ; And
Including; a transmitting end and a receiving end sub-units respectively formed at the ends of the dielectric waveguide body to transmit electromagnetic waves through the dielectric waveguide,
The dielectric waveguide body is provided with a path extension structure so that the passage path of the electromagnetic wave traveling through the inner side for each resonator sub-unit is longer than the physical length of the outer side,
The transmitting end and the receiving end sub-units have a wall surface opposite to the wall surface to which the transmitting end and the receiving end are attached to be concave inwardly, but the wall surface concave inwardly forms a single-layer or multi-layered base surface. The method of claim 1,
The transmitting end and the receiving end sub-units,
A dielectric waveguide filter that forms a trench structure or a stepped structure inside a wall surface opposite to a wall surface to which the transmitting end and the receiving end are attached. The method of claim 1,
The transmitting end and the receiving end sub-units,
A dielectric waveguide filter that forms either a hexahedral hole structure or a cylindrical hole structure from the center of the upper or lower wall surface to the inside of the body while leaving the outer support region. The method of claim 1,
The dielectric waveguide body and the transmitting end and the receiving end sub-units are configured to have different heights from each other. The method of claim 4,
The transmitting end and the receiving end sub-units,
A dielectric waveguide filter configured to have a height lower than at least the dielectric waveguide body. The method of claim 1,
The dielectric waveguide body,
In consideration of the passage path of the electromagnetic wave lengthened by the path extension structure provided for each resonator sub-unit to reduce harmonic components other than the required pass frequency band, it is formed to be shorter than the length of the waveguide required according to the resonance frequency. , Dielectric waveguide filter. The method of claim 1,
The dielectric waveguide body,
A dielectric waveguide filter for determining a length of the resonator sub-unit such that a harmonic component other than a required pass frequency band decreases or the harmonic component moves away from the pass frequency band. The method of claim 1,
The path extension structure,
The upper or lower wall surface of the resonator sub-unit is concave inside the body so as to intersect with the traveling direction of the electromagnetic wave, and the upper or lower wall surface concavely formed inside the body forms a single-layer or multi-layer base surface, a dielectric waveguide filter. The method of claim 8,
The dielectric waveguide filter, wherein the height of the base surface is different from each other for each resonator sub-unit. The method of claim 8,
The path extension structure,
A dielectric waveguide filter, forming either a trench structure or a stepped structure from the upper or lower wall surface to the inside of the body across the length direction of the waveguide. The method of claim 8,
The path extension structure,
A dielectric waveguide filter that forms either a hexahedral hole structure or a cylindrical hole structure from the center of the upper or lower wall surface to the inside of the body while leaving an outer support region. The method of claim 1,
The dielectric waveguide body,
A dielectric waveguide filter, wherein adjacent resonator sub-units form a continuous stepped structure by configuring the heights of the resonator sub-units to be different from each other. The method of claim 12,
The dielectric waveguide body,
A dielectric waveguide filter, wherein the heights of adjacent resonator sub-units are determined so that a difference in impedance between the resonator sub-units can be induced. The method of claim 12,
The dielectric waveguide body,
A dielectric waveguide filter configured to form a stepped structure in which the height of the resonator sub-unit gradually increases as the distance from the transmitting end and the receiving end sub-unit increases, so that the height near the center of the lengthwise direction of the dielectric waveguide body is highest. The method of claim 1,
The dielectric waveguide body,
The dielectric waveguide filter, wherein the slots constituting the coupling window are formed symmetrically on both sides of the waveguide body through which electromagnetic waves pass. The method of claim 1,
The dielectric waveguide body,
The dielectric waveguide filter, wherein the slot constituting the coupling window is asymmetrically formed only on one side of the waveguide body through which electromagnetic waves pass. A communication device comprising the dielectric waveguide filter of any one of claims 1 to 16. A dielectric waveguide body in which each of a plurality of dielectrics is connected to form a resonator sub-unit and has a slot forming a coupling window between adjacent resonator sub-units to continuously pass electromagnetic waves And In the method of designing a dielectric waveguide filter comprising a transmitting end and a receiving end respectively formed at the ends of the dielectric waveguide body to transmit electromagnetic waves through the dielectric waveguide,
(a) receiving, by an apparatus for designing a dielectric waveguide filter, a parameter for a required frequency characteristic of an electromagnetic wave;
(b) calculating a length of a target waveguide assuming that the electromagnetic wave passes through the dielectric waveguide filter in consideration of the cross section of the waveguide, but based on the input parameter;
(c) The dielectric waveguide filter design device is reduced from the length of the target waveguide in consideration of the path extension structure formed such that the passage path of the electromagnetic wave traveling through the inner side of the resonator sub-unit is longer than the physical length of the outer side. Determining an overall size of the sized dielectric waveguide body; And
(d) determining the height of the dielectric waveguide body or the transmitting end and receiving end sub-units such that harmonic components other than the pass frequency band required by the design device of the dielectric waveguide filter are reduced; including, of a dielectric waveguide filter Design method. The method of claim 18,
The step (c),
(c1) Consider the path extension structure formed by concave the upper or lower wall of the resonator sub-unit to the inside of the body so as to intersect with the traveling direction of the electromagnetic wave, but the harmonic component other than the required pass frequency band is reduced or the harmonic Determining a length of each of the resonator sub-units such that a component is away from the pass frequency band; And
(c2) determining the number of required resonator sub-units in consideration of the length of the target waveguide from the determined length of each of the resonator sub-units. The method of claim 18,
The step (d),
(d1) configuring the dielectric waveguide body and the transmitting end and receiving end sub-units to have different heights, and determining that the transmitting end and receiving end sub-units have at least a lower height than the dielectric waveguide body; And
(d2) A stepped structure in which the height of the resonator sub-unit gradually increases as the distance from the transmitting end and the receiving end increases, but the height near the center of the lengthwise direction of the dielectric waveguide body is the highest, and the impedance between the resonator sub-units Determining the height of the adjacent resonator sub-units so that a difference in (impedence) can be induced; including, a method of designing a dielectric waveguide filter.

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