RU2401488C1 - Two-channel shf switch - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: in SHF incorporating three equal wave impedance transmission lines (TL), one TL receives the SHF signal, the other two lines - the first and the second- are SHF signal output lines. Each of two output TLs contains at least four electronic switches in the form of field transistors (FT) with Schottky barrier junction, and source of the first FT with Schottky barrier junction is connected with input TL, its drain is connected with TL at the first output. Drain of the second FT with Schottky barrier junction is connected via TL segment which length is equal to eigth of wave-length and wave impedance is equal to that of TL with TL at input. Source of this FT is grounded and gates of FT with Schottky barrier junction are connected with one source of constant control voltage. The switch is provided with two additional TL segments which lengths are equal to eigth of wave-length in TL and wave impedances are equal to wave impedance of TL at switch input. Drain of the third FT with Schottky barrier junction is connected with one of the ends of the first additional TL segment and the other end of this FT is connected with TL at the first output. Drain of the fourth FT with Schottky barrier junction is connected with TL at the second output and via the second additional TL segment - with the drain of the second FT with Schottky barrier junction; at the same time, sources of the third and the fourth FT with Schottky barrier junction are grounded.

EFFECT: operating bandwidth expansion, lowering SHF losses and increase in attenuation of SHF signal.

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Description

The invention relates to microwave technology, and in particular to two-channel microwave switches on semiconductor devices.

The two-channel microwave switch contains one input and two outputs for the signal microwave channels.

The two-channel microwave switch is controlled from a constant voltage source. With one constant voltage, one channel opens and the second closes. An open channel is characterized by an amplitude-frequency characteristic - microwave losses in the working frequency band, a closed channel is characterized by an amplitude-frequency characteristic - attenuation of a microwave signal in the working frequency band.

In this case, the microwave losses should be as small as possible, and the attenuation of the microwave signal should be as large as possible.

A known two-channel microwave switch containing a connection of three transmission lines with the same wave impedance, one transmission line is used to input a microwave signal, the other two are for output, an electronic key, which is used as a field-effect transistor with a Schottky barrier, while the source of the field-effect transistor with a barrier Schottky is grounded, and a constant control voltage is applied to the shutter.

In this case, segments of transmission lines are additionally introduced into the switch, which are equal to a quarter and a half wavelength in the transmission line, and wave impedance equal to the wave impedance of the transmission line, while one ends of the additional segments of the transmission lines are connected to the output transmission lines each at a distance, equal to a quarter of the wavelength in the transmission line, from the connection of three transmission lines, and the others are interconnected and connected to the drain of the field-effect transistor with a Schottky barrier [1].

Known two-channel microwave switch containing a connection of three transmission lines with the same wave impedances, one transmission line is used to input the microwave signal, the other two are for output, each of the two transmission lines at the output contains at least one electronic key, as field-effect transistors with a Schottky barrier are used, while the sources of field-effect transistors with a Schottky barrier are grounded, and a constant control voltage is applied to the gates.

At the same time, at least one segment of the transmission line with a length equal to a quarter of the wavelength in the segment of the transmission line and wave impedance equal to the wave resistance of the transmission line is introduced into one of the transmission lines at the output of the microwave signal, while one end of the segment of the transmission line is connected with this transmission line at the output, and the other end with the drain of the corresponding field-effect transistor with a Schottky barrier, the drain of the other field-effect transistor with a Schottky barrier is connected to another transmission line at the output, and their gates are interconnected and connected to one source of constant control voltage, while the distances from the connection point of three transmission lines to the connection point of a segment of the transmission line with this transmission line at the output and to the drain of another field-effect transistor with a Schottky barrier are equal to a quarter of the wavelength in the transmission lines [2].

The presence in these two-channel switches of three segments of the transmission line with a length equal to a quarter of the wavelength corresponding to the central frequency of the working frequency band leads to the fact that at a frequency twice the center frequency, these segments become resonant, which significantly limits the width of the working frequency band, and the amplitude-frequency characteristics of the switch at frequencies close to this frequency deteriorate sharply, which indicates an increase in microwave losses and a decrease in the attenuation of the microwave signal.

All this excludes the possibility of using these switches in broadband microwave devices.

Known two-channel microwave switch containing three transmission lines with the same wave impedances, one transmission line is used to input the microwave signal, the other two are for output, each of the two transmission lines at the output contains at least one electronic key, which are used field-effect transistors with a Schottky barrier, while the drain of each first and second field-effect transistors with a Schottky barrier is connected to the corresponding transmission line at the output, the source of the first is connected to the transmission line at the input, second the first field-effect transistor with a Schottky barrier is located from the transmission line at the input at a distance equal to a quarter of the wavelength in the transmission line, its source is grounded, and the gates of the field-effect transistors with a Schottky barrier are interconnected and connected to one source of constant control voltage [3 - prototype] .

The presence of only one quarter-wave length of the transmission line in the two-channel microwave switch compared to the first two analogues of the transmission line significantly reduces the effect of resonances on the amplitude-frequency characteristics of the switch, and as a result, a slight extension of the working frequency band, a decrease in microwave losses, and an increase in the attenuation of the microwave signal.

In this switch, each of the transmission lines at the output can be equipped with several electronic keys - field-effect transistors with a Schottky barrier. However, since they are connected directly with each other, this does not provide the possibility of reducing microwave losses and increasing attenuation of the microwave signal only by increasing their number.

Moreover, since this two-channel microwave switch, like the previous ones, has a quarter-wave length of the transmission line, which, as indicated above, limits the possibility of its use for switching microwave signals in a wide working frequency band and to obtain a significant reduction in microwave losses and to increase the attenuation of the microwave signal .

The technical result of the invention is a significant expansion of the working frequency band, reducing microwave losses and increasing attenuation of the microwave signal.

The technical result is achieved by the claimed two-channel microwave switch containing three transmission lines with the same wave impedances, one transmission line is intended for input of the microwave signal, two others, the first and second for output, each of the two transmission lines at the output contains at least one an electronic key, which are used field-effect transistors with a Schottky barrier, while the source of the first field-effect transistor with a Schottky barrier is connected to the transmission line at the input, its drain is connected to the transmission line at the first output, the drain of the second field-effect transistor with a Schottky barrier is connected through a segment of the transmission line to the transmission line at the input, and its source is grounded, and the gates of the field-effect transistors with a Schottky barrier are connected to one source of constant control voltage.

In which each of the two transmission lines at the output contains,

- at least two electronic keys - two field-effect transistors with a Schottky barrier,

- and the drain of the second field-effect transistor with a Schottky barrier is connected to the transmission line at the input through a segment of the transmission line with a length equal to one eighth of the wavelength in the transmission line and a wave resistance equal to the wave resistance of the transmission line at the input,

- two additional segments of the transmission line with lengths equal to one eighth of the wavelength in the transmission line and wave impedances equal to the wave resistance of the transmission line at the input of the switch are introduced into the switch,

- while the drain of the third field-effect transistor with a Schottky barrier is connected to one of the ends of the first additional segment of the transmission line, and its other end to the transmission line at the first output,

- the drain of the fourth field-effect transistor with a Schottky barrier is connected to the transmission line at the second output and through the second additional segment of the transmission line with the drain of the second field-effect transistor with a Schottky barrier,

- in this case, the sources of the third and fourth field-effect transistors with a Schottky barrier are grounded.

SUMMARY OF THE INVENTION

The combination of all the essential features of the claimed two-channel microwave switch, including with the proposed connection of all the elements of the two-channel microwave switch will allow the following.

The presence in each channel of the switch of at least two field-effect transistors with a Schottky barrier provides the possibility of including active resistances and capacitances of field-effect transistors with a Schottky barrier through additional segments of transmission lines that transform the value of the active resistances and capacities of field-effect transistors with a Schottky barrier to optimal thereby reducing the microwave open channel loss and increasing the attenuation of the microwave signal of the closed channel and, as a result, reducing microwave losses and increasing attenuation microwave signal of the two-channel microwave switch as a whole.

The connection of the drain of the second field-effect transistor with a Schottky barrier with a transmission line at the input through a segment of the transmission line with a length equal to one eighth of the wavelength in the transmission line and a wave resistance equal to the wave resistance of the transmission line at the input and thereby eliminating the quarter-wave length of the transmission line from the switch , and with it the resonant nature of the behavior of the amplitude-frequency characteristics of the two-channel microwave switch and, as a result, the expansion of the working frequency band, the reduction of microwave losses and Microwave attenuation.

Performing all three segments of the transmission line:

firstly, of the same length equal to one eighth of the wavelength in the transmission line, and

secondly, with the same wave impedances equal to the wave impedance of the transmission line at the input of the two-channel microwave switch, it eliminates the occurrence of inhomogeneities in the places of their connection and thereby eliminates the possibility of re-reflection of the microwave signal, and thereby the deterioration of the amplitude-frequency characteristics and, as a result, - expanding the working frequency band, reducing microwave losses and increasing attenuation of the microwave signal of the two-channel microwave switch.

The invention is illustrated by drawings.

Figure 1 gives the topology of a two-channel microwave switch, where

- connection of three transmission lines, one of which is intended for input 1 of the microwave signal, and the other two 2 and 3 are for output of the microwave signal,

- two electronic keys - two field-effect transistors with a Schottky barrier 4 and 5, respectively,

- piece of transmission line 6,

- source of constant control voltage 7,

- two electronic keys - two field-effect transistors with a Schottky barrier 8 and 9, respectively,

- two additional segments of the transmission line 10 and 11, respectively.

Figure 2 is a schematic diagram of a two-channel microwave switch.

Figure 3 shows the frequency dependence of the attenuation Ao of the microwave signal in the transmission lines at the output of the two-channel microwave switch, where

curve 1 corresponds to the indicated dependence in the transmission line at output 2, and

curve 2 - in the transmission line at output 3.

Figure 4 shows the frequency dependence of the amount of microwave losses in the transmission lines at the output of a two-channel microwave switch, where

curve 1 corresponds to the indicated dependence in the transmission line at output 2, and

curve 2 - in the transmission line at output 3.

Example.

As an example, a two-channel microwave switch is considered.

All elements of the two-channel microwave switch are made in integral integral design on a semiconductor substrate of gallium arsenide with a thickness of 0.1 mm using the classic thin-film technology.

Wherein:

Three transmission lines - at input 1, at output 2 and 3 are each made with a conductor width of 0.08 mm.

The transmission lines at input 1 and output 2 and 3 are interconnected.

The length of the transmission line 6 and the additional lengths of the transmission line 10 and 11 are made the same:

- a length equal to 1.5 mm, which corresponds to one eighth of the wavelength in a segment of the transmission line, and a width equal to 0.08 mm, and

- wave impedances equal to the wave impedance of the transmission line at the input of the two-channel switch.

Four electronic keys - four field-effect transistors with a Schottky barrier 4, 5, 8, 9, while the sources of field-effect transistors with a Schottky barrier 5, 8, 9 are grounded, and the gates of all field-effect transistors with a Schottky barrier are interconnected and connected to one constant source control voltage 7.

In this case, the source of the first field-effect transistor with a Schottky barrier 4 is connected to the transmission line at the input 1, its drain is connected to the transmission line at the first output 2, the drain of the second field-effect transistor with a Schottky barrier 5 is connected through a segment of the transmission line 6 with the transmission line at the input 1. The drain of the third field-effect transistor with a Schottky barrier 8 is connected to one of the ends of the first additional segment of the transmission line 10, and its other end is connected to the transmission line at the first output 2, the drain of the fourth field-effect transistor with a Schottky barrier 9 is connected to the transmission line and at the second output 3 and through the second additional segment of the transmission line 11 with the drain of the second field-effect transistor with a Schottky barrier 6.

Microwave switch operation.

When applying to the gates of field-effect transistors with a Schottky barrier 4, 5, 8 and 9 a constant control voltage U of 0 V, from one source of constant control voltage 7, all four field-effect transistors with a Schottky barrier become open.

In this case, field effect transistors with a Schottky barrier have a low resistance Z Open.

The low resistance of the field effect transistor with a Schottky barrier 4 is connected in series with the transmission line at the first output 2 and practically does not affect the microwave signal.

The low resistance of the third additional field-effect transistor with a Schottky barrier 8, included through the first additional segment of the transmission line 10, will be significantly larger than the wave resistance of the transmission line at output 2.

As a result, the microwave signal from the transmission line at the input 1 of the switch will propagate along the transmission line of the first output 2 with low losses.

The small resistances of the field effect transistor with a Schottky barrier 5 and the second additional field effect transistor with a Schottky barrier 9 are connected to ground and are practically short circuits for the microwave signal.

As a result, the microwave signal from the transmission line at the input 1 of the switch will propagate in the transmission line at the second output 3 is very attenuated.

In this case, the microwave signal from the transmission line at input 1 is transmitted to the transmission line at output 2 with a small amount of microwave loss Ap, and to the transmission line at output 3 with a large amount of attenuation of the microwave signal Ao.

When applying to the gates of field-effect transistors with a Schottky barrier 4, 5, 8, and 9 a negative control voltage U exceeding the cutoff voltage Uotc in absolute value, all field-effect transistors with a Schottky barrier will be closed.

In this case, field effect transistors with a Schottky barrier have a large resistance Zzakr.

Great resistance Zcl. a field-effect transistor with a Schottky barrier 4, connected in series in transmission line 2, will increase microwave losses. The high resistance of the field effect transistor with a Schottky barrier 8, connected through the first additional segment of the transmission line 10, is transformed into a low resistance at the end of this additional segment of the transmission line and will be an almost short circuit for the microwave signal.

As a result, the microwave signal from the transmission line at the input 1 of the switch will propagate along the transmission line of the first output 2 is very attenuated.

High resistance of the second field-effect transistor with a Schottky barrier 5 and the fourth field-effect transistor with a Schottky barrier 9, connected in parallel to the transmission line at the second output 3, will have a slight effect on the propagation of the microwave signal.

In this case, the microwave signal from the transmission line at input 1 is transmitted to the transmission line at output 2 with a large attenuation value Ao, and to the transmission line at output 3 with a small amount of microwave loss Ap.

On the manufactured samples of the two-channel microwave switch, the values of microwave losses Ap and attenuation of the microwave signal Ao were measured respectively in the transmission lines at output 2 and 3 when a microwave signal was fed to the transmission line at input 1.

The results are shown in figure 3 and 4.

As can be seen from figure 3 and figure 4, the working frequency band is 15 GHz, which is two times more than that of the prototype.

As can be seen from figure 3, the attenuation values of the microwave signal Ao in both channels of the microwave switch in the working frequency band exceed - 40 dB, which is about 1.8 times more than that of the prototype.

As can be seen from figure 4, the magnitude of the microwave losses in both channels of the microwave switch in the working frequency band does not exceed 1 dB, which is approximately 1.2 times less than that of the prototype.

Thus, the claimed two-channel microwave switch in comparison with the prototype will allow:

- increase the width of the working frequency band by about 2 times.

- increase the attenuation of the microwave signal by about 1.8 times.

- reduce the amount of microwave losses by about 1.2 times.

Information sources

1. RF patent №2335832 IPC Н01Р 1/15, priority of March 23, 2007, publ. 10/10/08.

2. RF patent No. 2306641 IPC Н01Р 1/15, priority dated March 29, 2006, publ. 09/20/07

3. RF patent No. 2313866 IPC Н01Р 1/15, priority of April 27, 2006, publ. 12/27/07 - prototype.

Claims (1)

A two-channel microwave switch containing three transmission lines with the same wave impedances, one transmission line is used to input the microwave signal, two others, the first and second are for output, each of the two transmission lines at the output contains at least one electronic key, which are used field-effect transistors with a Schottky barrier, while the source of the first field-effect transistor with a Schottky barrier is connected to the transmission line at the input, its drain - to the transmission line at the first output, the drain of the second field-effect transistor with ba the Schotky device is connected through a piece of the transmission line to the input transmission line, and its source is grounded, and the gates of the field-effect transistors with the Schottky barrier are connected to one source of constant control voltage, characterized in that each of the two transmission lines at the output contains at least two electronic keys - two field-effect transistors with a Schottky barrier, and the drain of the second field-effect transistor with a Schottky barrier is connected to the input transmission line through a segment of the transmission line with a length equal to one eighth of the wavelength in the transmission line , and a wave impedance equal to the impedance of the transmission line at the input, two segments of the transmission line with lengths equal to one eighth of the wavelength in the transmission line and wave impedances equal to the impedance of the transmission line at the input of the switch are additionally introduced into the switch, with a drain of the third a field transistor with a Schottky barrier is connected to one of the ends of the first additional segment of the transmission line, and its other end is connected to the transmission line at the first output, the drain of the fourth field-effect transistor and with the Schottky barrier it is connected to the transmission line at the second output and through the second additional segment of the transmission line with the drain of the second field-effect transistor with the Schottky barrier, while the sources of the third and fourth field-effect transistors with the Schottky barrier are grounded.

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