RU190044U1 - COMPACT DOUBLE RING BRIDGE - Google Patents

Abstract

The utility model relates to radio engineering and can be used in radar, radio navigation, communications, antenna systems and radio measurements as an independent device, as well as a functional unit for building power dividers, phase shifters, mixers, modulators, discriminators, power adders, chart-forming elements. The technical result is to reduce the overall dimensions. The compact double ring bridge contains four input transmission lines with a characteristic impedance R, seven low-pass filters connected to each other via tees, a second, eleventh, ninth, fifth low-pass filters with input resistors and a phase transfer coefficient of 90 ° at the central operating frequency, a third low pass filter with input impedance R = R⋅2 and phase transfer coefficient 90 °, the sixth low pass filter with input resistance and phase transfer ratio 180 °, the seventh low pass filter with input oprotivleniem R = R⋅2 transfer coefficient and phase 270 °. 1 hp f-ly, 3 ill.

Description

The utility model relates to radio engineering and can be used in radar, radio navigation, communications, antenna systems and radio measurements as an independent device, as well as a functional unit for building power dividers, phase shifters, mixers, modulators, discriminators, power adders, chart-forming elements.

At present, the design of a quadrature directional coupler, made in the form of two identical segments of a transmission line, for example, a coaxial cable, 1/8 wavelength in a line and containing two concentrated coupling capacitances, which are connected at the ends of segments between potential conductors ("Devices of addition and distribution of high-frequency oscillations." Edited by ZI Model. Ed. "Soviet Radio", M. 1980. P. 86-87, Fig. 6.6). The disadvantages of this technical solution are: narrow band of operating frequencies and large overall size.

Another frequently used design is a quadrature directional coupler on elements with lumped parameters. The coupler is a symmetrical eight-port network consisting of high-pass filters ("Wideband microwave devices on elements with lumped parameters" Karpov V.M., Malyshev V.A., Perevoshchikov I.V. - M .: Radio and Communication, 1984 . p. 67-72, Fig. 5.5). With a wide operating frequency band, this coupler contains a large number of elements, and, therefore, has large overall dimensions, low reliability and repeatability during mass production, high cost, difficult to manufacture and configure.

Also known is the microstrip double ring bridge, which contains a dielectric substrate, one surface of which is metallized, and the other microstrip line is rolled into a ring with a length of 1.5 λ _l , to which an additional contour with a length equal to the wavelength is added, where λ _l is the wavelength in line [Patent Single layer double ring hybrid magic-tee No. US 5412354 from 05/02/1995]. The device provides a signal from the input to the two outputs. The disadvantages of this microstrip bridge are: large overall dimensions, especially at low frequencies, as well as spurious bandwidths at neighboring frequencies.

The utility model is aimed at reducing the overall dimensions of microwave bridges. The technical result achieved in the implementation of the utility model is to reduce the lengths of the transmission line segments as part of the microwave bridge.

и фазой коэффициента передачи 90° на центральной рабочей частоте, второй фильтр нижних частот с входным сопротивлением R₃ = R₁ ⋅ 2 и фазой коэффициента передачи 90°, четвертый фильтр нижних частот с входным сопротивлением

и фазой коэффициента передачи 180°, пятый фильтр нижних частот с входным сопротивлением R₃=R₁ ⋅ 2 и фазой коэффициента передачи 270°, где первый вход первого фильтра нижних частот соединен с первым входом устройства и первым входом третьего фильтра нижних частот, второй вход первого фильтра нижних частот соединен с первым входом второго и четвертого фильтров нижних частот, второй вход второго фильтра нижних частот соединен со вторым входом устройства и первым входом пятого фильтра нижних частот, второй вход пятого фильтра нижних частот соединен со вторым входом четвертого фильтра нижних частот и первым входом седьмого фильтра нижних частот, второй вход седьмого фильтра нижних частот соединен с четвертым входом устройства и первым входом шестого фильтра нижних частот, второй вход шестого фильтра нижних частот соединен с третьим входом устройства и вторым входом третьего фильтра нижних частот.The technical result is achieved due to the fact that the compact double ring bridge contains four input transmission lines with an impedance R ₁ , seven low-pass filters connected to each other through tees, first, third, sixth, seventh low-pass filters with input impedances

and the phase of the transmission coefficient 90 ° at the central operating frequency, the second low-pass filter with the input resistance R ₃ = R ₁ ⋅ 2 and the phase of the transmission coefficient 90 °, the fourth low-pass filter with the input resistance

and the phase of the transmission coefficient 180 °, the fifth low-pass filter with the input resistance R ₃ = R ₁ ⋅ 2 and the phase of the transmission coefficient 270 °, where the first input of the first low-pass filter is connected to the first input of the device and the first input of the third low-pass filter, the second input the first low pass filter is connected to the first input of the second and fourth low pass filters, the second input of the second low pass filter is connected to the second input of the device and the first input of the fifth low pass filter, the second input of the fifth low pass filter is connected Inna with the second input of the fourth low-pass filter and the first input of the seventh low-pass filter, the second input of the seventh low-pass filter is connected to the fourth input of the device and the first input of the sixth low-pass filter, the second input of the sixth low-pass filter is connected to the third input of the device and the second input of the third low pass filter.

The low-pass filter, having a phase-frequency characteristic in the required frequency band, which coincides with the phase-frequency characteristic of the transmission line, has a shorter length than it does. Thus, the use of low-pass filters instead of segments of transmission lines allows to reduce the overall dimensions of the device.

The invention is illustrated by the figures, which depict:

in fig. 1 - the preferred topology of the proposed microstrip double ring bridge with asymmetrically made low-pass filters implemented on a dielectric substrate with a relative dielectric constant of 4.4 and a thickness of 1 mm; top view, where Al, A2, A3, A4 are the entrances of the bridge; also in FIG. 1 shows low-pass filters labeled 1, 2, 3, 4, 5, 6, 7;

in fig. 2 - plots of S-parameters modules versus frequency, expressed in decibels;

in fig. 3 is a graph of the frequency dependence of the phase difference between the outputs of the bridge.

The microstrip bridge has four 50-ohm input transmission lines, consists of seven low-pass filters in microstrip performance, connected to each other via tees.

Microstrip double ring bridge works as follows. We set the input impedance of all inputs to 50 ohms. The left ring can be represented as a 5-input device with the inputs A1, A3, A4 and the inputs at the nodes of the junction of the ring on the left and right. In fact, the double ring bridge is an extension to the well-known ring bridge design. Using the even-odd mode method ("Method of analysis of symmetrical four-port networks", J. Reed and GJ Wheeler, MTT-4 Trans., No. 4, October 1956, and "Hybrid ring directional couplers for arbitrary power division" , MTT-9 Trans., No. 4, November 1961), it can be shown that for the 5-input device formed by the ring on the left, the wave impedances of the ring transmission lines and their length correspond to those for a simple ring bridge. For convenience, the inputs at the junction points of the two rings will be considered to have an input resistance of 100 Ohms, which in this case will serve as an analogue of the resistance of the ballast resistor in the circuit of the ring power divider with ballast resistance (for example, V. Volman, V. Pimenov. Technical Electrodynamics - M: "Communication", 1971). The response of the even mode is achieved by simply exciting the input A3. The response of the odd mode is achieved by antiphase excitation of the inputs at the junctions of the two rings. For the realization of such antiphase excitation, a simple power divider connected to the A2 input is used, with output lengths quarter of the wavelength in the line and three quarters of the wavelength in the line of the central frequency. This divider closes the ring on the right. The wave impedances of the lines in this divider must be equal to 100 ohms, since the input impedance of the inputs A1, A2, A3, A4 was set to 50 Ohms, in which case the input A2 would be matched. In this case, when the input A3 is excited, the inputs A1 and A4 will be in-phase excited, and the input A2 will remain unexcited; when A2 input is excited, A1 and A4 inputs will be excited out of phase, and A3 input will remain unexcited. As an additional advantage, the proposed bridge does not have spurious bandwidths at frequencies that are multiples of the center frequency of the operating range. The use of low-pass filters instead of the transmission line segments allows for an effective miniaturization of the structure. Due to the asymmetric implementation of low-pass filters (the introduction of wide lines inside), the overall dimensions of the device are further reduced.

и R₃=R₁⋅2=50⋅2=100 Ом.For a standard wave impedance R ₁ = 50 Ohm, the input impedances of the low-pass filters will be equal

and R ₃ = R ₁ ⋅ 2 = 50⋅2 = 100 Ω.

As an additional advantage, the proposed microwave bridge does not have spurious bandwidths at frequencies that are multiples of the center frequency of the operating range. The use of low-pass filters instead of the transmission line segments allows for an effective miniaturization of the structure. Due to the asymmetrical implementation of low-pass filters (the introduction of wide lines inside), the overall dimensions of the device are further reduced.

To confirm the feasibility of the chosen technical solution, a prototype of a utility model of a microstrip bridge was made with the following technical characteristics:

the voltage standing wave ratio (VSWR) of the bridge inputs is not more than 1.2;

the amplitude unbalance between the output channels of the bridge does not exceed 0.7 dB, in accordance with the data in FIG. 2;

the phase difference between the outputs differs from 0 ° and 180 ° by no more than ± 2 °, which is shown in FIG. 3

The area of the compact microwave bridge is 1081 mm ² , which is 83% less than the area occupied by the standard bridge construction.

Claims (2)

1. Compact double ring bridge, characterized in that it contains four input transmission lines with an impedance R ₁ , seven low-pass filters connected to each other through tees, first, third, sixth, seventh low-pass filters with input impedances

and the phase of the transmission coefficient 90 ° at the central operating frequency, the second low-pass filter with the input resistance R ₃ = R ₁ 12 and the phase of the transmission coefficient 90 °, the fourth low-pass filter with the input resistance

and the phase of the transmission coefficient 180 °, the fifth low-pass filter with the input resistance R ₃ = R ₁ ⋅2 and the phase of the transmission coefficient 270 °, where the first input of the first low-pass filter is connected to the first input of the device and the first input of the third low-pass filter, the second input the first low pass filter is connected to the first input of the second and fourth low pass filters, the second input of the second low pass filter is connected to the second input of the device and the first input of the fifth low pass filter, the second input of the fifth low pass filter is connected with the second input of the fourth low-pass filter and the first input of the seventh low-pass filter, the second input of the seventh low-pass filter is connected to the fourth input of the device and the first input of the sixth low-pass filter, the second input of the sixth low-pass filter is connected to the third input of the device and the second input of the third low pass filter. 2. Compact double ring bridge according to Claim. 1, characterized in that all low-pass filters have an asymmetrical design.

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