SU1262603A1 - Microstrip filter - Google Patents

Abstract

The invention relates to radio engineering. Increased selectivity is provided while simultaneously linearizing the phase response frequency. On the diel. The substrate with the metallization is placed with a series of half-wave U-shaped resonators (TACs) 3. The sides 6 of each TAC 3 are placed between the sides 6 of the adjacent TACs 3 and are electromagnetically connected with them and with the sides of the other TACs located in these neighboring TACs. Extreme TPSs are associated with input and output lines 4 and 5, respectively. Because the transfer of energy from the input line 4 to the output line 5 takes place simultaneously in several ways, i.e. the possibility of independent control of the frequency response and phase response. 2 Il. (L j

Description

The invention relates to radio engineering and can be used in radio engineering devices, in particular in frequency selection devices with increased requirements for selectivity and phase response distortion.

The purpose of the invention is to increase the selectivity while improving the linearity of the phase-frequency characteristics.

Figure 1 shows a microstrip filter, side view; figure 2 - topology of the filter.

The microstrip filter contains located on the dielectric substrate 1 with metallization 2 in series, and electromagnetically coupled half-wave U-shaped resonators 3, input and output lines 4 and 5, respectively, associated with the extreme ones. In this case, the sides 6 of each half-wave U-shaped resonator 3 are located between the stacks 6 of the adjacent half-wave U-shaped resonators 3 n are additionally electromagnetically connected to the sides 6 of other half-wave U-shaped resonators 3 located in these adjacent half-wave U-shaped resonators 3.

The microstrip filter operates as follows.

Three main half-wave U-shaped resonators 3 can be distinguished as the main component of the microstrip filter. If the ends of the two outermost ones, inserted between the ends of the middle, would not interact with each other, then the proposed implementation of the microstrip filter retains the main path of energy transfer to the output line 5 and at least allows you to reduce the size. But the interaction of the extreme of the three half-wave U-shaped resonators 3 gives additional ways of transferring energy to the output line 5. The interacting sides 6 of the extreme half-wave U-shaped resonators 5 form an elementary link consisting of two homogeneous connected microstrip lines, one pair of the same name ends which serves as its input and output, and the other is in idle mode. If the phase velocities of normal waves propagating in coupled microstrip lines are not equal, the link is band-pass and with a length of its lines equal to about a quarter of the wavelength at the central frequency of the passband, a damping pole is formed to the left of it, which makes it possible to increase selectivity in the low-frequency region. Because. Since the energy transfer from the input line 4 to the output line 5 is carried out simultaneously in several ways, the circuit can be non-phase. In circuits of a minimum phase type, there is the possibility of independent up-. the regulation of the amplitude-frequency and phase-frequency (PFC) characteristics. In particular, it is possible to maximally approximate the phase response to a linear dependence in most of the passband.

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Claims (1)

. The invention relates to radio engineering and can be used in radio engineering devices, in particular, in frequency selection devices with increased requirements for selectivity and phase distortions. The purpose of the invention is to increase the selectivity while simultaneously improving the linearity of the frequency response. Figure 1 shows the microstrip filter, side view; figure 2 - the topology of the filter. The microstrip filter contains on the dielectric substrate 1 with metallization 2 a series circuit and electromagnetically connected half-wave U-shaped resonators 3, input and output lines 4 and 5, respectively, associated with the outermost ones. In this case, sides 6 of each half-wave U-shaped resonator 3 are placed between a stack of 6 neighboring half-wave U-shaped resonators 3 and are additionally electromagnetically connected to sides 6 of other half-wave U-shaped resonators 3 placed in these neighboring half-wave U-shaped resonators 3. Microstrip filter works as follows. As a main component of a microstrip filter, three successively located half-wavelength U-shaped resonators 3 can be distinguished. If the ends of the two extreme ones, which were inserted between the ends of the middle, would not interact with each other, the proposed implementation of the microstrip filter retains the main transmission path energy to the output line 5 and, as a minimum, allows to reduce the size. But the interaction of the extreme of the three half-wave U-shaped resonators 3 gives additional paths of energy transfer to the high-speed line 5. The interacting sides of the six extreme half-wave U-shaped resonators 3 form an elementary link consisting of two homogeneous connected microstrip lines, one pair of like the ends of which serve as its entrance and exit, and the friend is in idle mode. With the unequal phase velocities of normal waves propagating in the associated microstrip lines, the link is band passing and, with a length of its lines equal to about a quarter of the wavelength at the center frequency of the passband, a damping pole is formed to the left of it, which allows an increase in selectivity low frequency range. Because. energy is transferred from input line 4 to output line 5 simultaneously in several ways, then the circuit may be non-minimally phase. In chains of not minimal phase type, there is the possibility of independent yn. the amplitude-frequency and phase-frequency (phase response) characteristics. In particular, it is possible to bring the frequency response as close as possible to the linear dependence in most of the pass band. A microstrip filter comprising two half-wave U-shaped resonators, electromagnetically interconnected, one side of each of which is placed between the sides of the other, and an input and output lines associated with extreme half-wave U-shaped resonators, characterized in In order to increase the selectivity while simultaneously improving the linearity of the phase-frequency characteristic, half-wave U-shaped resonators were additionally added to it, with the sides of each half-wave U-shaped p resonator placed between sides of adjacent U-shaped half-wave resonators and further electromagnetically coupled with the other sides of U-shaped half-wave resonators arranged in these neighboring U-shaped half-wave resonators. FIG. one