RU2677103C1 - Microstrip low-pass filter - Google Patents

Abstract

FIELD: physics.SUBSTANCE: invention relates to microwave devices. Filter contains a substrate with a relative permittivity and thickness, on one side of which a metal screen is made, on the opposite side of the substrate there is an irregular strip conductor rolled in the form of a meander, wide and narrow segments thereof are microstrip resonators connected to each other in a cascade, forming five parallel rows, with wide segments in adjacent rows opposite the narrow ones.EFFECT: improvement of the frequency-selective properties of the microstrip low-pass filter, improving the manufacturability of its manufacture, as well as reducing the size of the structure.1 cl, 2 dwg

Description

The invention relates to techniques for microwave frequencies and can be used in the selective paths of receiving and transmitting systems.

Known miniature low-pass filter (Utility model of the Russian Federation No. 159123, Н01Р 1/203, Н03Н 7/09), containing inductors and capacitors, and the inductors in the amount of two, not interconnected by electric and magnetic fields, are made flat and placed on one layer of a multilayer substrate of a dielectric material with low losses of a microwave signal made using ceramic technology with a low firing temperature, six printing pads are also placed inside the substrate, with three pads, put on the top and bottom substrate layers are shielding.

The disadvantage of the described miniature low-pass filter is the use of a multilayer substrate and lumped elements in the design, which leads to its low manufacturability, and with an increase in the cutoff frequency of the filter, the dimensions of lumped elements decrease so much that the manufacture of the latter becomes practically impossible.

The closest in combination of essential features is a microstrip low-pass filter on a metal-dielectric zigzag line (Patent for invention of the Russian Federation No. 2364993, Н01Р 1/203), containing a substrate with a relative permittivity ε and thickness d, on one side of which an isotropic metal screen is made, and on the other hand, at least two identical metal conductors in the form of segments of zigzag lines located at a distance from each other not exceeding the width of the system formed by one wire th, between which are symmetrically located zigzag rectangular dielectric insert. The width of the microstrip filter is equal to a quarter of the slowed wavelength, and the dielectric insert is made of a material with a relative permittivity (8 ... 10) ε, with a width equal to the width of the metal conductors, and a thickness equal to (1.5 ... 2) d. The metal conductors of the segments of the zigzag lines can be electrically connected to each other and to the dielectric insert at points with the same phase of the slow wave field.

The disadvantages of the described microstrip low-pass filter on a metal-dielectric zigzag line are low frequency-selective properties due to the weak suppression of the power of electromagnetic waves at the frequencies of the obstacle band and the large unevenness of the transmission of power of electromagnetic waves at the frequencies of the passband, as well as the insufficiently sharp decrease in the frequency response in the frequency domain cut. Low manufacturability of filter manufacturing is associated with the use of a dielectric insert made of a material with a relative dielectric constant (8 ... 10) ε. In addition, such a filter, implemented on a polycor substrate, with a cut-off frequency of 1.8 ... 2.2 GHz has a relatively large overall dimension - 96.5 × 64.0 mm ² .

The objective of the invention is to improve the frequency-selective properties of the microstrip low-pass filter, increasing manufacturability, as well as reducing the size of the structure.

This problem is achieved by the fact that in a microstrip low-pass filter containing a substrate with a relative permittivity ε and thickness d, on one side of which a metal screen is made, according to the technical solution, an irregular strip conductor rolled in the form of a meander is located on the opposite side of the substrate, wide and whose narrow segments, which are microstrip resonators, are cascaded to each other, forming five parallel rows, and in adjacent rows, wide segments of p positioned opposite narrow. Due to this, an additional electromagnetic interaction arises between the resonators of adjacent rows, which allows for a steep decline in the frequency response of the filter in the region of the cutoff frequency.

The technical result of the invention is to improve the frequency-selective properties of the microstrip low-pass filter, increase the manufacturability of its manufacture when used in the construction of a monolithic dielectric substrate, as well as increase the miniature filter due to the claimed location of the rolled strip conductor on such a substrate.

The invention is illustrated by drawings: FIG. 1 - device microstrip low-pass filter, FIG. 2 - its amplitude-frequency characteristic, (frequency dependence of the transmission coefficients S ₂₁ , S ₁₁ ).

The inventive microstrip low-pass filter (Fig. 1) is implemented on a substrate (7) with a relative permittivity ε and thickness d, on one side of which a metal shield (2) is made, and on the opposite side of the substrate there is an irregular strip-shaped conductor rolled up in the form of a meander (3-19), wide (3, 5, 7, 9, 11, 13, 15, 17, 19) and narrow (4, 6, 8a, 10, 12, 14, 16a, 18) segments of which are connected to each other the other cascade, forming five parallel rows: (3-8a), (9-15), (16a-19-16a), (15-9), (8a-3). Between themselves, the rows are connected at the edges by a narrow segment of the strip conductor (8b) or (16b). In adjacent rows, wide segments of strip conductors are located opposite narrow ones: (3 and 14), (5 and 12), (7 and 10), (9 and 8a), (9 and 16a), (11 and 6), (11 and 18), (13 and 4), (13 and 18), (15 and 16a), (17 and 14), (17 and 10), (19 and 12). At the free ends of the strip of conductor strip (3) are the "input" and "output" of the filter.

The inventive filter is implemented on a monolithic dielectric substrate and, unlike the prototype, does not have a dielectric insert in the structure, therefore, it has greater manufacturability in manufacturing.

Let us examine the principle of the microstrip low-pass filter. The wide and narrow segments (3-19) of the strip conductor, located (Fig. 1) on the substrate (1) with dielectric constant ε and thickness d, rolled in the form of a meander, when the electromagnetic signal is fed to the “input”, perform the function of cascade half-wave microstrip resonators -connected to each other. An electromagnetic signal is sequentially propagated from one such resonator to another, and the transmitted signal is removed from the “output” of the filter. By selecting the ratio of the sizes of narrow and wide segments of the strip conductor (3-19), the passband of the low-pass filter is adjusted with the maximum allowable level of reflection loss in it S ₁₁ ≤ -14 dB.

Due to the folding of the strip conductor, an additional electromagnetic interaction arises between the resonators of adjacent rows and power attenuation poles are observed at the amplitude-frequency characteristic of the structure at the frequencies of the obstacle strip, including near the passband. Due to this, it is possible to realize a steep decline in the frequency response of the filter in the region of the cutoff frequency.

An example of a microstrip lowpass filter (Fig. 1). A monolithic substrate of 47.7 × 19.2 mm ² in size was used in the design from a polycor with a dielectric constant of ε = 9.8 and a thickness of d = 1 mm. Indents from the edges of the substrate to the segments of strip conductors (5, 7, 15, 16b) are equal to the thickness of the substrate. Note that the filter substrate area is approximately 6.7 times smaller than that of the prototype, and its cutoff frequency ƒ _c ≈ 2.5 GHz (Fig. 2) is slightly higher than that of the prototype filter (ƒ _c = 1.8 ... 2.2 GHz). In addition, the inventive filter at passband frequencies has significantly less unevenness in the passage of power of electromagnetic waves. On the amplitude-frequency characteristic of the structure (Fig. 2), there is a steeper decrease in the frequency response than in the prototype, as well as stronger attenuation in a more extended barrier band (at least -60 dB to a frequency of 5 GHz).

The design parameters of the inventive microstrip low-pass filter, and in particular the length and width of the segments of strip conductors: (3): 3.3 × 3.0 mm ² , (4): 7.9 × 0.4 mm ² , (5): 4.5 × 4.2 mm ² , (6 ): 6.6 × 0.2 mm ² , (7): 5.1 × 4.2 mm ² , (8a): 6.7 × 0.2 mm ² , (8b): 0.7 × 0.2 mm ² , (9): 4.8 × 3.9 mm ² , (10 ): 8.5 × 0.4 mm ² , (11): 4.8 × 4.8 mm ² , (12, 14): 8.4 × 0.4 mm ² , (13, 17): 4.8 × 4.7 mm ² , (15): 4.8 × 4.4 mm ² , (16b): 0.8 × 0.2 mm ² , (16a): 7.1 × 0.2 mm ² , (18): 8.9 × 0.4 mm ² , (19): 4.8 × 4.3 mm ² , respectively.

Thus, the inventive microstrip low-pass filter in comparison with the prototype filter has better frequency-selective properties: more powerful suppression of the power of electromagnetic waves at the frequencies of the obstacle, more uniform transmission through the frequencies of the passband, as well as a steeper decrease in the frequency response in the region cutoff frequencies. Improving the manufacturability of the filter is due to the use of a monolithic dielectric substrate instead of a hybrid one. The claimed location of the rolled strip conductor on the dielectric substrate allows you to significantly miniaturize the design of the filter.

Claims (1)

A low-pass microstrip filter containing a substrate with a relative permittivity ε and thickness d, on one side of which a metal screen is made, characterized in that on the opposite side of the substrate there is an irregular strip-shaped conductor folded in the shape of a meander, the wide and narrow segments of which are connected to each other cascading, forming five parallel rows, and in adjacent rows, wide segments are located opposite narrow ones.

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