RU2742049C1 - Meander line delay with face communication, protecting from ultrashort pulses with increased duration - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to electrical engineering and can be used for protecting electronics from ultrashort pulses. Technical result is achieved due to time-separated pulse of even mode, pulse, which occurs due to asymmetry of cross-section of line, and pulse of odd mode by value of double product of line length and minimum of running delays of even and odd line modes. Selection of line cross-section parameters additionally provides value of difference of running delays of odd and even modes of line, multiplied by line length, not less than sum of front durations, flat top and decay of the pulse supplied to the line, and equality of tripled value of the minimum of running delays of even and odd line modes to the maximum value of these delays.

EFFECT: technical result is longer duration of ultrashort pulse, protection from which can be provided.

1 cl, 3 dwg

Description

At present, an urgent task is to protect radio electronic equipment (REA) from ultrashort pulses (SCI) of the nanosecond and subnanosecond ranges, which are capable of penetrating into various nodes of the REE, bypassing the electromagnetic screens of devices. Traditional circuitry means of protection against such impulses are filters, decoupling devices, noise suppressors, discharge devices, and constructive ones are protective shields and methods for increasing the uniformity of screens, grounding and methods for reducing the impedances of power circuits. It is known that the protection devices switched on at the input of the equipment have a number of disadvantages (low power, insufficient speed, parasitic parameters), which make it difficult to properly protect against powerful SQI. Effective protection over a wide range of influences requires complex multi-stage devices. Meanwhile, along with high performance, practice requires simplicity and low cost of protection devices; therefore, it is necessary to develop new protection devices against SQI.

Closest to the claimed device is a meander delay line with a face link, which protects against ultra-short pulses [Invention patent No. 2606709. Meander line delay with face link, protecting against ultra-short pulses / A.T. Gazizov, A.M. Zabolotsky, S.P. Kuksenko - Application No. 2015137545; announced 09/02/2015; published 01/10/2017], from one reference conductor, two signal conductors parallel to it and to each other, connected at one end, and a dielectric medium consisting of a dielectric substrate and ambient air, the reference conductor of which is located on one side of the dielectric substrate with one of the signal conductors, and the second signal conductor is located symmetrically to the first one with respect to the dielectric substrate, and the parameters of the cross-section of the line are chosen such that the geometric mean value of the characteristic impedances of the even and odd modes is equal to the characteristic impedance of the path into which the line is connected, the value of the minimum of the linear delays of the even and of the odd line modes, as well as the modulus of their difference, multiplied by the line length, is greater than the sum of the durations of the front, flat top and falloff of the pulse applied to the line.

The disadvantage of the prototype device is the short duration of the SQI, from which the protection of the electronic equipment can be provided.

A delay line consisting of one reference conductor, two signal conductors parallel to it and to each other connected at one end, and a dielectric medium consisting of a dielectric substrate and ambient air, the reference conductor of which is located on one side of the dielectric substrate with one of the signal conductors, and the second signal conductor is located symmetrically to the first one with respect to the dielectric substrate, and the parameters of the cross-section of the line are chosen such that the geometric mean value of the characteristic impedances of the even and odd modes is equal to the characteristic impedance of the path in which the line is connected, the values of the minimum of the linear delays of the even and odd modes line, as well as the modulus of their difference, multiplied by twice the length of the line, is greater than the sum of the durations of the front, flat top and decay of the pulse supplied to the line, characterized in that the choice of the parameters of the cross-section of the line additionally provides the value of the difference the number of linear delays of the odd and even line modes, multiplied by the line length, not less than the sum of the durations of the front, flat top and fall of the pulse fed into the line, and the equality of the triple value of the minimum of the linear delays of the even and odd line modes to the value of the maximum of these delays ...

The advantage of the proposed device, in contrast to the prototype device, is the increased duration of the SQI, the protection from which can be provided.

The technical result is an increase in the duration of the SQI, which can be completely decomposed in a loop of a meander delay line with a face link. The technical result is achieved due to the time spacing of the pulse of the even mode, the pulse arising from the asymmetry of the cross section of the line (hereinafter referred to as additional), and the pulse of the odd mode by the value of the double product of the line length and the minimum of the linear delays of the even and odd line modes. This is ensured by the equality of the three times value of the minimum of the linear delays of the even and odd line modes to the value of the maximum of these delays. Providing this condition makes it possible to increase the duration of the initial pulse, which can be expanded in the line. The first four pulses (cross-talk pulse, pulses of even and odd modes, and an additional pulse) are the result of decomposition of the original pulse and are spaced relative to each other in time by the same time value equal to twice the product of the line length and the minimum of the linear delay values of the even and odd modes. Later, pulses (the fifth and subsequent ones) caused by reflections will arrive at the end of the line, and they are spaced from the first four pulses and relative to each other by a value equal to twice the product of the line length and the minimum of the values of the linear delay of the even and odd modes. Thus, due to the decomposition of the initial pulse into a sequence of pulses of smaller amplitude, protection against SQI is provided, and due to the separation of these pulses by an amount equal to twice the product of the line length and the minimum of the values of the linear delay of the even and odd modes, an increased (compared to the device -prototype) duration of the SQI, which can be expanded in such a line. In this case, the maximum duration of a completely decomposable SQI corresponds to the double product of the line length and the value of the smallest of the linear delays of the even or odd line modes. The above qualitative assessments of the attainability of the technical result are confirmed below by the quantitative estimates obtained as a result of modeling.

, соединенных между собой на дальнем конце. Один из проводников на ближнем конце линии соединен с источником импульсных сигналов, представленным на схеме идеальным источником э.д.с. с внутренним сопротивлением R1. Другой проводник соединен с приемным устройством, представленным на схеме сопротивлением R2. Воздействующий импульс имеет форму трапеции с параметрами: амплитуда э.д.с. 2 кВ, длительность плоской вершины 1 нс, а фронта и спада - по 0,5 нс.FIG. 1a shows a cross-section of the inventive line, with the following parameters: w and t are the width and thickness of the conductors, respectively, s is the distance between the signal and reference conductors, h is the thickness of the dielectric substrate, ε _r is the relative dielectric constant of the substrate. FIG. 1b shows the connection diagram of the claimed line. The line consists of two parallel conductors, each with a length

connected at the far end. One of the conductors at the near end of the line is connected to a source of pulsed signals, represented in the diagram by an ideal source of emf. with internal resistance R1. Another conductor is connected to the receiving device, represented in the diagram by the resistance R2. The acting pulse has the shape of a trapezoid with the following parameters: the amplitude of the emf. 2 kV, the duration of the flat top is 1 ns, and the rise and fall of 0.5 ns.

To minimize reflections from the ends of the line, the internal resistances of the emf source and loads are taken equal to the geometric mean of the wave impedances of the even and odd line modes.

The cross-sectional parameters in FIG. 1a are chosen so that the conditions

where τ _max and τ _min are the largest and smallest of the linear delays of the even (τ _e ) and odd (τ _o ) modes, respectively, at _r , t _d and t _ƒ are the duration of the front, flat top and fall of the pulse, respectively.

The fulfillment of condition (1) ensures the decomposition of the SQI into a cross-talk pulse and the main signal, the fulfillment of condition (2) is the decomposition of the main signal into pulses of even and odd modes, the fulfillment of condition (3) is the decomposition of the main signal into a pulse of even and odd line modes and an additional a pulse between mode pulses, and the fulfillment of condition (4) ensures the decomposition of the SQI with a longer duration (up to 3 / τ _min ), in contrast to the prototype device.

. Вычисленные матрицы С, L и Z линии:First, consider the expansion of the SQI in the line under conditions (1-3) Cross-sectional parameters that ensure these conditions: w = 15 mm, t = 105 μm, s = 1 mm, d = w, h = 6 mm, ε _r = 4 ... Line conductor length

... Calculated matrices С, L and Z lines:

The values of the resistances R1 and R2 turned out to be equal to 61.921 ohms.

The received linear delays of the even and odd line modes: τ _e = 4.77 ns / m, τ _o = 6.02 ns / m. Substituting the known values of the variables into conditions (1), (2), and (3), we obtain 16.22 ns ≥ 2 ns, 4.25 ns ≥ 2 ns, and 2.125 ns ≥ 2 ns, respectively. Thus, conditions (1-3) are satisfied, but condition (4) is not fulfilled, since the threefold value of the linear delay of the even mode is not equal to the value of the linear delay of the odd mode. The waveform at the end of such a line when exposed to a 2 ns trapezoidal pulse is shown in Fig. 2a, from which it can be seen that the SQI at the end of the line is represented by a sequence of four pulses of lower amplitude (cross-talk, an even-mode pulse, an additional pulse, and an odd-mode pulse). In this case, the maximum signal amplitude at the line output does not exceed 0.4 kV. With an increase in the duration of the influencing pulse to 11 ns, its passage along the meander line loop leads to a complete decomposition of the original signal into only two main pulses (Fig.2b): a cross-talk pulse at the near end and a pulse that is the result of a superposition of pulses of an even mode, additional and odd fashion. In this case, the signal amplitude increases to 0.8 kV. Thus, the device does not provide adequate protection against SQI with durations exceeding 2 ns.

. Вычисленные матрицы погонных параметров:To prove the feasibility of the proposed device, consider a delay line with cross-sectional parameters that provide condition (4): w = 1000 μm, t = 137 μm, s = 5 μm, d = 3w, h = 1200 μm, ε _r = 500. Line conductor length

... Calculated matrices of linear parameters:

The values of the resistances R1 and R2 turned out to be equal to 4.25 ohms.

The received linear delays of the even and odd line modes: τ _e = 19.49 ns / m, τ _o = 58.61 ns / m. Substituting the known values of the variables into conditions (1), (2), and (3), we obtain 15.59 ns ≥ 11 ns, 31.3 ns ≥ 11 ns, and 15.65 ns ≥ 11 ns, respectively. Thus, conditions (1-3) are satisfied. Condition (4) is also satisfied, since the ratio of the delays of the even and odd modes is 3.007. Thus, condition (4) is satisfied up to the second digit.

FIG. 3 shows the waveforms at the output of the claimed device when exposed to a pulse in the form of a trapezoid with a duration of 2 and 11 ns. As seen in FIG. 3a, when exposed to a pulse with a short duration (2 ns), its passage along the meander line loop also leads to the decomposition of the signal into 4 main pulses (cross-talk pulse, even-mode pulse, additional pulse, and odd-mode pulse). Later, impulses caused by reflections in the line arrive at the end of the line. In this case, the maximum signal amplitude at the line output does not exceed 0.293 kV, in contrast to the prototype device. From FIG. 3b, it can be seen that the passage of the meander line of a pulse with a duration of 11 ns along the loop also leads to its decomposition into 4 main pulses, the maximum amplitude of which also does not exceed 0.293 kV. In this case, the delay between the decomposition pulses is equal to the value equal to the product of the doubled line length and the minimum of the linear delays of the even and odd line modes.

Thus, the technical result is shown, the achievement of which is directed by the claimed line - an increase in the duration of the SKI, protection from which can be provided.

Claims (1)

A delay line consisting of one reference conductor, two signal conductors parallel to it and to each other connected at one end, and a dielectric medium consisting of a dielectric substrate and ambient air, the reference conductor of which is located on one side of the dielectric substrate with one of the signal conductors, and the second signal conductor is located symmetrically to the first one with respect to the dielectric substrate, and the parameters of the cross-section of the line are chosen such that the geometric mean value of the characteristic impedances of the even and odd modes is equal to the characteristic impedance of the path in which the line is connected, the values of the minimum of the linear delays of the even and odd modes line, as well as the modulus of their difference, multiplied by twice the length of the line, is greater than the sum of the durations of the front, flat top and decay of the pulse supplied to the line, characterized in that the choice of the parameters of the cross-section of the line additionally provides the value of the difference the number of linear delays of the odd and even line modes, multiplied by the line length, not less than the sum of the durations of the front, flat top and fall of the pulse fed into the line, and the equality of the triple value of the minimum of the linear delays of the even and odd line modes to the value of the maximum of these delays ...

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