RU2514090C1 - Device for storing frequencies of microwave signals - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: invention relates to radio engineering and can be used in receivers which are part of radio monitoring and radio countermeasure equipment. The device for storing frequencies of microwave signals consists of first and second frequency conversion stages. The first frequency conversion stage includes: eight mixers, four power dividers, two adders having three inputs each, four switches, four heterodynes and six electrical filters. The second frequency conversion stage includes: an input power divider, an output adder, two π/2 phase sections, two input mixers and two output mixers, a heterodyne and two digital memory devices.

EFFECT: controlling the operating frequency range and dynamic range by suppressing combination frequencies, arising in the second stage, in the first frequency conversion stage.

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Description

The invention relates to the field of radio engineering and can be used in receiving devices that are part of the equipment for radio surveillance and countermeasures.

A device for storing frequencies of microwave signals using a delay line, which is used as a coaxial cable bay or waveguide [1]. The disadvantage of this device is the short delay time, as well as the large size of the device and large losses in the delay line. To obtain large delays, acoustic delay lines were also used. Since the propagation velocity of acoustic waves in various material media is much lower than the speed of light, the physical dimensions of such delay lines are approximately 10 ⁵ times smaller than the dimensions of the cable, equivalent in delay [1]. The disadvantage of these devices is the loss and delay limits.

It is also known ultrafast memory device with digital memory frequencies of microwave signals [2], adopted as a prototype of the invention (figure 1). The prototype contains six mixers: input 1 and output 2 of the first stage of frequency conversion, two input 8, 9 and two output mixers 10, 11 of the second stage of frequency conversion, local oscillator 3 of the first stage of frequency conversion, input power divider 4 with two outputs, output adder 5 with two inputs, two phase sections 6, 7 on π / 2, the local oscillator 12 of the second stage of frequency conversion and the first 13 and second 14 digital memory devices.

The input of the input mixer 1 is the input of the device for storing frequencies of microwave signals, and the output of the output mixer 2 is the output of a device for storing frequencies of microwave signals. The output of the mixer 1 is connected to the input of the power divider 4. The heterodyne inputs of the mixers 1 and 2 are connected to the output of the local oscillator 3.

The heterodyne inputs of two input 8, 9 and two output 10.11 mixers of the second frequency conversion stage are connected to the output of the second local oscillator 12.

The first output of the power splitter 4 is connected to the input of the first input mixer 8 of the second conversion stage, the output of which is connected to the input of the first digital memory device 13. The output of the device 13 is connected to the signal input of the first output mixer 10 of the second frequency conversion stage, the output of which is connected to the input of the first phase section 7, the output of which is connected to the first input of the adder 5.

The second output of the power divider 4 is connected to the input of the second phase section 6, the output of which is connected to the signal input of the second input mixer 9, the output of which is connected to the second digital memory device 14. The output of the device 14 is connected to the signal input of the second output mixer 11 of the second frequency conversion stage, the output of which is connected to the second input of the adder 5.

The output of the adder 5 is connected to the signal input of the output mixer 2 of the first stage of frequency conversion.

The principle of operation of the second stage of frequency conversion, the scheme of which is shown in figure 2, is as follows. The frequencies of the input microwave signals are reduced in the mixers 1, 8, 9 and fed to the digital memory devices 13, 14, in which they are converted from analog form to digital, stored and then converted to analog form, and their frequencies are restored to the frequencies of the input microwave signals.

Several microwave signals with any type of frequency and phase modulation can be recorded and read at the same time. Moreover, the storage time of information is not limited. As devices of digital memory 13, 14 can be used devices described, for example, in a utility model [3].

Consider the operation of the device for storing frequencies of microwave signals on the example of the device described in [2]. The frequencies of microwave signals before and after their conversion and the frequency of local oscillators are also borrowed from the same article, which does not reduce the generality of the subsequent consideration.

The frequencies of the input microwave signals using the input mixer 1 and the first local oscillator 3 are sequentially converted from the operating range of 8.0 ... 16.0 GHz to the range of 0.75 ... 1.25 GHz. Then the frequencies using the mixers 8, 9 and the second local oscillator 12 are converted from the range of 0.75 ... 1.25 GHz into the operating frequency range of the digital memory device, after which, using the mixers 10, 11 and the second local oscillator 12 are converted back to the frequency range 0, 75 ... 1.25 GHz, and then using the output mixer 2 and the first local oscillator 3 are converted into the operating frequency range of the device for storing frequencies of microwave signals 8.0 ... 16.0 GHz. As follows from the article [2], a feature of this device is the ability to memorize the frequencies of microwave signals that vary in the frequency range 0.5 GHz wide with the help of digital memory devices operating in a frequency band no wider than 0.25 GHz.

The input microwave signal converted by the first mixer 1 is divided into two equal parts by a power divider 4 (Fig.1, 2). From the first output of the divider 4, the signal enters the left branch of the device at the input of the mixer 8, with the help of which it is converted from the frequency range 0.75 ... 1.25 GHz into the operating frequency range of the digital memory device Ω _min ... 0.25 GHz. The value of the lower boundary of the range Ω _{min is} close to zero. The local oscillator frequency 12 is chosen equal to 1 GHz [2]. From the output of the mixer 8, the microwave signal is fed to the input of a digital memory device 13 containing an analog-to-digital converter, a storage device and a digital-to-analog converter. From the output of the digital memory device, the microwave signal is fed to the input of the mixer 10, with the help of which its frequency is converted to the range 0.75 ... 1.25 GHz, and after changing the phase to π / 2 using the phase section 7, it is transmitted to the first input of the adder 5.

From the second output of the power divider 4, the microwave signal enters the right branch of the device, which is similar to the left, except that in it the phase section on π / 2 6 is connected between the second output of the divider 4 and the input of the mixer 9, and the output of the mixer 11 is connected to the second adder input 5.

The sequence of conversion of microwave signals by the second stage of frequency conversion and the formulas that determine the signals themselves are shown in tables 1, 2, 3, 4 (Figs. 7, 8, 9, 10). Tables 1 and 2 are constructed for the case when the frequency of the microwave signal is ω <ω _g , where ω _{g is the} frequency of the local oscillator signal 12, and tables 3 and 4 for the case of ω> ω _g . Tables 1 and 3 are built for the left branch of the scheme, and tables 2 and 4 for the right branch. The “Signal” column contains formulas for microwave signals coming from the elements recorded in the first column of the table to the input of the elements recorded in the second column. For example, from table 1 it follows that in the case ω <ω _{g, the} microwave signal coming from the mixer 8 of the left branch to the digital memory device 13 has the form u = a ₁ UsinΩt, where Ω = ω _g -ω, U and ω are the amplitude and the frequency of the input microwave signal, a _n - coefficient taking into account losses during the conversion of microwave signals.

Using the aforementioned tables 1, 2, 3, and 4, microwave signals are determined that are generated as a result of repeated conversion in the second stage of the frequency conversion (FIG. 2) and are supplied from the output of the second stage to the input of the output mixer of the first stage 2 (FIG. 1). In the case of ω <ω _g (tables 1, 2, Figs. 7, 8), the microwave signals arrive at the first and second inputs of the adder 5:

From these ratios it is seen that the microwave signals u ₁ and u ₃ go to the inputs of the adder 5 in antiphase and cancel each other out, and the microwave signals u ₂ and u ₄ will have equal phases, add up in the adder 5 and come from its output to the signal input mixer 2 of the first stage of frequency conversion, in which the frequency of the microwave signal will be restored to its original value in the frequency range 8.0 ... 16.0 GHz.

In the case of ω> ω _g (tables 3 and 4, Figs. 9, 10), the microwave signals arrive at the first and second inputs of adder 5:

It can also be seen from these relations that, in antiphase, microwave inputs u ₆ and u ₈ arrive at the inputs of adder 5 and cancel each other out, while microwave signals u ₅ and u ₇ have the same phases, add up and come from the output of adder 5 to the input of output mixer 2 , in which the frequency of the microwave signal will be restored to its original value of 8.0 ... 16.0 GHz.

The disadvantage of the described device for storing the frequencies of microwave signals is the possibility of forming in the operating range of the output frequencies of the device along with the useful microwave signal of a large number of combinational components formed at the outputs of the mixers of the second conversion stage 8, 9, 10, 11 (figure 2) [4]. Moreover, the number of these components substantially depends on how much the frequencies of useful microwave signals arriving at the second conversion stage differ from the local oscillator frequency 12. This property is a consequence of the fact that the frequency of the local oscillator 1 GHz is equal to the average value of the input frequency range of the second conversion stage 0, 75 ... 1.25 GHz, i.e. on the frequency axis is located in the middle of the input frequency range. If during the tuning of the frequency of the input microwave signal its value on the left or right along the frequency axis tends to the value of the local oscillator frequency (to 1 GHz), then the value of the intermediate frequency equal to the difference in the values of the input microwave signal and local oscillator tends to zero. In this case, the relative bandwidth of intermediate frequencies increases sharply, tending to an infinite number of octaves. As a result of this, a large number of combinational frequencies fall into the band of output (intermediate) frequencies. This can be seen in Figs. 3 and 4, which show the spectra of the output frequencies of the mixers 10 and 11 for the case of ω> ω _g. In addition to the heterodyne and useful output microwave signals with frequencies ω _g and ω = ω _g + Ω _, the mixers will also form combination components with frequencies ω = ω _g + mΩ. The difference in the combination frequencies is either Ω or a multiple of it. Here, Ω is the working frequency of the microwave signal supplied to the inputs of digital memory devices 13 and 14, am are integers of the natural number series: 0, 1, 2, 3 ... The useful signal in Figs. 3, 4 is marked with the number 1.

By changing the frequency of the local oscillator 12, this problem cannot be solved, because the device designed according to the circuit shown in [2] and shown in figure 1 will not work due to violations of the phase relationships of the microwave signals at the outputs of the left and right branches of the second stage of the frequency conversion (figure 2).

Some combination components and heterodyne signals can be suppressed by using balanced or double balanced mixers [5]. In this case, the number of combinational components in the output frequency spectrum will decrease, but the problem will not be solved. The combination components with frequencies ω = ω _g −mΩ in the case under consideration will be absent in the output spectra, since, as was shown above, they will be suppressed by the device of the second conversion stage (Fig. 2). Thus, due to an increase in the relative width of the range of output (intermediate) frequencies, a large number of unsuppressed combinational components will always be present in the output frequency band [5]. In addition, at a frequency of 1 GHz and in a small area around this point on the frequency axis, the device made according to the scheme in figure 2 will not work due to the equality or proximity of the frequencies of the input signals to the local oscillator frequency. This area is determined by the parameters of the digital memory device, namely, the value of the lower limit of the operating frequency range of this device Ω _min .

From the frequency plans shown in FIGS. 3 and 4, it can be seen that the combination frequencies will not fall into the output frequency band only if the condition Ω> ΔΩ / 2 is satisfied, where Ω is the frequency of the input microwave signal of the digital memory device, and ΔΩ is the working bandwidth frequencies of digital memory devices 13 and 14, equal in this case to 0.25 GHz. The multiplication of microwave output signals in radio surveillance devices will lead to ambiguity in the results. In the case of radio interference, to reduce the efficiency of the equipment, since with limited power of the output amplifier of the station, the output power will be distributed between a large number of components of the output spectrum, so the power level of the useful output signal will be much less than the required value.

The areas affected by the combination frequencies in FIGS. 3, 4 are shaded. Figure 5 shows the frequency plans of the input signals for the range of 8.0 ... 12.0 GHz (A), the second stage of conversion (B) and output signals (C), in which the affected areas are also shaded. It can be seen from the above frequency plans that in the frequency range of the output signals, the areas of ambiguity and ambiguity alternate with a period equal to the width of the working frequency range of the digital memory devices 13 and 14, equal to 0.25 GHz. In this case, the uniqueness of reproduction will be only in half the range of input frequencies of the entire device, which is the main disadvantage of the prototype.

Common features of the prototype and invention of the first (MSS) stage of frequency conversion: first 1, second 2 mixers, first local oscillator 3, the output of which is connected to the heterodyne inputs of the first 1 and second 2 mixers. In addition, the input of the first mixer 1 is the input of the device for storing frequencies of microwave signals, the output of the second mixer 2 is the output of a device for storing frequencies of microwave signals.

General features of the prototype and invention of the second (VHF) stage of frequency conversion: input power divider 4, which has two outputs - the first and second, output adder 5 with two inputs - the first and second, two phase sections on π / 2 6, 7 - the second and the first, two input mixers 8, 9 - the first and second and two output mixers 10, 11 - the first and second, local oscillator 12, two digital memory devices 13, 14 - the first and second, and the input of the input divider 4 is the input of the device VSPCH 15 and the output of the output adder 5 is the output of the device VSPCH 15, and the heterodyne inputs of two input 8, 9 and two output 10, 11 mixers are connected to the output of the local oscillator 12 VHF, the first output of the input power divider 4 VHF is connected to the signal input of the first input mixer 8, the output of which is connected to the input of the first digital memory device 13, the output of which connected to the signal input of the first output mixer 10, the output of which is connected to the input of the first phase section 7, the output of which is connected to the first input of the adder 5 VHF, in addition, the second output of the input power divider 4 VHF connected to the input th second phase section 6, whose output is connected to the signal input of the second input of the mixer 9, the output of which is connected to the input of the second digital storage device 14, whose output is connected to the signal input of the second output of the mixer 11 whose output is connected to the second input of the adder (5).

An object of the invention is to expand the range of operating frequencies and increase the dynamic range of input microwave signals, which can significantly improve the technical parameters of radio surveillance equipment and countermeasures, making it operational in a wide dynamic range and in a wide frequency range of input signals.

The technical result of the invention is to double the range of operating frequencies of the device for storing frequencies of microwave signals and increase the dynamic range of the device by more than 30 ... 50 dB. The prototype effectively works only at frequencies that make up half the working frequency range of the device.

The technical result of the invention is achieved due to the fact that in the first stage of frequency conversion (PPSCH) are additionally introduced: four power dividers 16, 17, 18 and 19, two adders 20 and 21, four switches 22, 23, 24 and 25, three local oscillators 26, 27 and 28, six electric filters 29, 30, 31, 32, 33 and 34, six mixers 35, 36, 37, 38, 39 and 40.

The introduction of new elements and new connections into the HRPC allows eliminating the combination components formed in the second stage of frequency conversion from the operating frequency range of the microwave signal frequency storage device, which in turn allows eliminating the frequency ambiguity region in the operating frequency range of the device, which solves the problem .

The invention is illustrated by drawings:

Figure 1 shows the electrical diagram of a device for storing frequencies of microwave signals (prototype).

Figure 2 shows the electric circuit of the second stage of frequency conversion of devices for storing frequencies of microwave signals of the prototype and invention.

Figure 3 shows the spectrum of the output frequencies of the second stage of frequency conversion, provided that Ω> ΔΩ / 2.

Figure 4 shows the spectrum of the output frequencies of the second stage of frequency conversion, provided that Ω> ΔΩ / 2.

Figure 5 shows:

A) - section of the frequency range of the input signals 8.0 ... 12.0 GHz;

B) - frequency plan at the output of the second stage of frequency conversion;

B) - areas affected by combination components in the range of 8.0 ... 12.0 GHz.

Figure 6 shows an electrical diagram of a device for storing frequencies of microwave signals according to the invention.

Fig. 7 in table 1 shows the formulas for the signals coming from the elements recorded in the first column of the table to the input of the elements recorded in the second column for the case ω <ω _g , the left branch.

Fig. 8 in table 2 shows the formulas for the signals coming from the elements recorded in the first column of the table to the input of the elements recorded in the second column for the case ω <ω _g , the right branch.

In Fig. 9, Table 3 shows the formulas for the signals coming from the elements recorded in the first column of the table to the input of the elements recorded in the second column for the case ω <ω _g , left branch.

Figure 10 in table 4 shows the formula for the signals coming from the elements recorded in the first column of the table to the input of the elements recorded in the second column for the case ω <ω _g , the right branch.

11 in table 5 shows the input and output frequencies of the mixers of the second conversion stage 35 and 36, the frequencies of the local oscillators 26 and 28 and the frequency of the local oscillator signal of the mixer 36.

12, table 6 shows the input and output frequencies of the mixers of the second conversion stage 37 and 38, the frequencies of the local oscillators 27, 28 and the frequency of the local oscillator signal of the mixer 37.

In the drawings, the designations are introduced: 1 and 2 - the first and second mixers of the first stage of frequency conversion (PSPCH); 3 - heterodyne PSPCH; 4 - input power dividers of the second stage of frequency conversion (VHPS); 5 - output adder VSPCH; 6 and 7 - phase sections on π / 2 of the HPLC; 8 and 9 - input mixers VSPCh; 10 and 11 - output mixers VSPCh; 12 - a heterodyne of VSPCh; 13 and 14 - the first and second devices of digital memory VSPH; 15 - device VSPCH; 16, 17, 18, 19 - power dividers PSPCH; 20 and 21 - adders ПСПЧ; 22, 23, 24, 25 - PSPCH switches; 26, 27, 28 - heterodyne PSPCH; 29, 30, 31, 32, 33, 34 - electric filters PSPCH; 35, 36, 37, 38, 39, 40 - PSPCH mixers.

The technical result of the invention is achieved due to the fact that the device according to the invention (figure 2, 6) contains the first and second stage of frequency conversion 15.

The first stage of frequency conversion (PPSCH) (6) includes: eight mixers 1, 2, 35, 36, 37, 38, 39, 40 - the first, second, third, fourth, fifth, sixth, seventh and eighth, four power divider 16, 17, 18, 19 - the first, second, third and fourth, which have two outputs, two adders 20, 21 - the first and second, which have three inputs - the first, second and third, four switches 22, 23, 24, 25 - first, second, third and fourth, four local oscillators 3, 26, 27, 28 - first, second, third and fourth, six electric filters 29, 30, 31, 32, 33, 34 - first, second third third fifth, fifth and sixth.

The second stage of frequency conversion (VHF) (figure 2) 15 includes: input power divider 4, which has two outputs - the first and second, output adder 5 with two inputs - the first and second, two phase sections on π / 2 6, 7 - second and first, two input mixers 8, 9 - first and second, two output mixers 10, 11 - first and second, local oscillator 12, two digital memory devices 13, 14 - first and second.

Electrical connections of the blocks according to the invention (Fig.6)

The output of the first local oscillator 3 is connected to the heterodyne inputs of the first 1 and second 2 mixers, the signal input of the first mixer 1 being the input of the device for storing frequencies of microwave signals, and the output of the second mixer 2 is the output of the device for storing frequencies of microwave signals.

The output of the first mixer 1 is connected to the input of the first power splitter 16, the outputs of which are connected respectively to the inputs of the first 22 and second 23 switches.

The output of the first switch 22 is connected to the input of the second power divider 17, the outputs of which are connected respectively to the inputs of the first and second electric filters 29, 30, the outputs of which are connected respectively to the first and second inputs of the first adder 20, the output of which is connected to the input of the VSPCh device 15. Output VSPCH 15 is connected to the input of the third power divider 18, the outputs of which are connected respectively to the inputs of the third and fourth switches 24, 25.

The output of the third switch 24 is connected to the input of the fourth power divider 19, the outputs of which are connected respectively to the inputs of the third 31 and fourth 32 electric filters, the outputs of which are connected respectively to the first and second inputs of the second adder 21, the output of which is connected to the signal input of the second mixer 2.

The output of the second switch 23 is connected to the signal input of the third mixer 35, the output of which is connected to the input of the fifth electric filter 33, the output of which is connected to the signal input of the fourth mixer 36, the output of which is connected to the third input of the first adder 20.

The output of the fourth switch 25 is connected to the signal input of the fifth mixer 37, the output of which is connected to the input of the sixth electric filter 34, the output of which is connected to the signal input of the sixth mixer 38, the output of which is connected to the third input of the second adder 21.

The output of the fourth local oscillator 28 is connected to the inputs of the seventh and eighth mixers 39, 40.

The outputs of the second local oscillator 26 are connected respectively to the heterodyne inputs of the third and seventh mixers 35, 39.

The output of the third local oscillator 27 is connected to the heterodyne inputs of the sixth 38 and eighth 40 mixers.

The output of the seventh mixer 39 is connected to the local input of the fourth mixer 36, and the output of the eighth mixer 40 is connected to the local input of the fifth mixer 37.

The electrical connections of the blocks in the VSPCH 15 (figure 2)

The input of the input divider 4 VHF is the input of the device VSPH 15, and the output of the output adder 5 VHF is the output of the device VSPH 15.

The heterodyne inputs of the two input 8, 9 HPV mixers are connected to the output of the local oscillator 12, the first output of the input power splitter 4 of the HPLC is connected to the signal input of the first input mixer 8, the output of which is connected to the input of the first digital memory device 13, the output which is connected to the signal input of the first output mixer 10, the output of which is connected to the input of the first phase section 7, the output of which is connected to the first input of the adder 5 VSPCH.

The second output of the input power splitter 4 VHF is connected to the input of the second phase section 6, the output of which is connected to the signal input of the second input mixer 9 VHF, the output of which is connected to the input of the second digital memory device 14, the output of which is connected to the signal input of the second output mixer 11 VHF, the output of which is connected to the second input of the adder 5 VHF, the output of which is the output of the VHF.

The elements of the microwave device according to the invention are standard and can be performed, for example, in a microstrip design based on thin or thick films. For the design of the above elements, the Microwave Office application package that contains a powerful and flexible CAD software package can be used. In his working library there are programs for designing the mentioned elements.

As digital memory devices, the device described, for example, in [3] can be used.

A device for storing frequencies of microwave signals (figure 1) works as follows. For greater clarity, consideration of the principle of operation of the device will conduct it using the frequency values given in article [2], which does not violate the generality of the review. For the normal functioning of the device, it is necessary to exclude the frequency region adjacent to the local oscillator frequency, which is equal to 1 GHz in this case. For this, it is necessary to satisfy the condition Ω> ΔΩ / 2, where Ω is the frequency of the input signal of the digital frequency memory device, and ΔΩ is the working frequency bandwidth of the digital frequency memory device, which is part of the second stage of frequency conversion 15. In this case, Ω can vary in frequency range Ω _min ... 0.25 GHz, where Ω _min is the value of the lower boundary of the range, usually close to zero. Fulfillment of the aforementioned condition will approximately halve the operating frequency band of digital memory devices (13 and 14 in FIG. 1), narrowing it to 0.125 ... 0.25 GHz, which in turn deprives the device of one of its main advantages.

To achieve this goal, the frequency range of the input microwave signals of the second-stage frequency conversion device 0.75 ... 1.25 GHz is divided into four sub-bands:

1 subband 0.75 ... 0.875 GHz; 2 subrange 0.875 ... 1.0 GHz; 3 subrange 1.0 ... 1.125 GHz; 4 subrange 1.125 ... 1.25 GHz.

To memorize the frequencies of the second and third subbands, the frequencies of these microwave signals are converted, respectively, into the first and fourth subbands, stored, and then the original values are restored. To simplify the filtering process, it is advisable to convert frequencies from the second subband to the fourth and from the third to the first.

The frequencies of the input microwave signals by the first conversion stage using the mixer 1 and local oscillator 3 are converted into the frequency range 0.75 ... 1.25 GHz and fed to the input of the divider 16, the output arms of which are loaded with switches 22 and 23. From the output of the switch 22, the microwave signals are fed to the input of the power divider 17, the outputs of which are loaded with electric filters 29 and 30, tuned to the frequencies of the 1st and 4th subranges, and after summing in the adder 20, they are fed to the input of the device of the second stage of frequency conversion 15, where digital memory is stored Microwave frequencies of these signals.

To memorize the frequencies of the microwave signals of the second and third subbands, the frequencies of these microwave signals are converted into the first and fourth subbands. Direct heterodyne conversion using one mixer and one heterodyne generator does not solve the problem, since with direct and reverse frequency conversion, as in the device made according to the scheme in Fig. 1, a large number of combinational components are formed at the output of the mixer in the working frequency band order. This problem can be solved by the compensation method, which greatly facilitates the filtering of the microwave output signals of the mixer, which is described in detail in the books [7] and [8] and the patent [9]. The essence of the method is to use double frequency conversion. During the first conversion, which performs the “up-conversion” along the frequency axis, the signal frequencies increase and the relative band decreases, which reduces the likelihood of combinational frequencies falling into the output band of the converter. In this case, the combination components, whose frequencies nevertheless fall into the operating frequency band, will have high orders and, accordingly, low power levels. The second conversion converts the frequencies of the microwave signals "down" along the frequency axis into a given frequency range.

In this case, the frequency conversion of microwave signals is as follows. The input microwave signals from the output of the switch 23 are fed to the input of the mixer 35, which are converted upward along the frequency axis, filtered by an electric filter 33, after which the mixer 36 is converted to a predetermined frequency range and through the adder 20 fed to the input of the device of the second stage of frequency conversion 15. Note that if the frequencies of the heterodyne signals of the converters 35 and 36 are the same, then the frequencies of the signals at the input of the converter 35 and at the output of the converter 36 will also be the same. To convert the frequencies of the signals from the second and third ranges to the first and fourth ranges, the local oscillator frequencies of the converters 35 and 36 must differ from each other by a predetermined amount. This is achieved by the fact that the signal of the local oscillator 26 enters the mixer 35 directly, and the mixer 36 with a given frequency shift, carried out using the local oscillator 28 and mixer 39.

The values of the heterodyne frequencies of the mixers 35 and 36 are selected significantly more than the frequencies of the input microwave signals (five to ten times or more), which allows you to effectively filter the useful signals from the powerful combination components and low-order harmonics with the filter 33.

After the microwave signals pass through the device of the second frequency conversion stage 15, the frequencies of the microwave signals of the second and third subbands are restored to their original values also using compensation circuits containing mixers 37, 38 and 40, a filter 34 and a local oscillator 27. To change the heterodyne frequencies of the mixers 36 and 37, the same generator 28 is used, since in the first and in the second case, the change in the frequency value is the same. The work of compensation schemes has been described in detail above. Obviously, frequency conversion of the signals of the first and fourth subbands is not required. Devices operating in these subbands are connected to the device of the second stage of frequency conversion 15 at the same time.

In the range of input and output frequencies of 0.75 ... 1.25 GHz, it was designed according to the scheme of Fig.6 and using tables 1, 2, 3 and 4, the first stage of frequency conversion of the device for remembering frequencies of microwave signals. A device operating in the frequency range 0 ... 0.25 GHz is considered as a digital memory. A possible variant of generating the frequencies of the heterodyne signals of the mixers 35 and 36 is shown in Table 5, and the mixers 37 and 38 in Table 6. The subbands were switched by changing the values of the heterodyne frequencies of the generators 26 and 27 included in the right branch of the circuit (in compensation frequency conversion devices). The values of the local oscillator frequencies of the mixers 35, 36, 37, 38 are shown in tables 5 and 6 in columns 2 and 5. The local oscillator 28 provides the necessary difference in the local oscillator frequencies of the mixers 35, 36 and 37, 38. The frequency value of this local oscillator is shown in columns 4 of tables 5 and 6.

As a result of testing the devices described above, the technical result of the invention was achieved: the operability of the device for storing frequencies of microwave signals in the entire operating frequency range was ensured. The dynamic range of the device according to the invention, compared with the prototype, is increased by more than 50 dB in the entire range of operating frequencies.

Distinctive features of the invention. Four power dividers 16, 17, 18, 19 - the first, second, third and fourth, which have two outputs, two adders 20, 21 - the first and second, which have three inputs - the first, second and third, four switches 22 23, 24, 25 - the first, second, third and fourth, three local oscillators 26, 27, 28 - the second, third and fourth, six electric filters 29, 30, 31, 32, 33, 34 - the first, second, third, the fourth, fifth and sixth, six mixers 35, 36, 37, 38, 39, 40 - the third, fourth, fifth, sixth, seventh and eighth.

The output of the first mixer 1 is connected to the input of the first power splitter 16, the outputs of which are connected respectively to the inputs of the first 22 and second 23 switches, the output of the first switch 22 is connected to the input of the second power splitter 17, the outputs of which are connected respectively to the inputs of the first and second electric filters 29, 30, the outputs of which are connected respectively to the first and second inputs of the first adder 20, the output of which is connected to the input of the device VSPCH 15, the output of which is connected to the input of the third power divider 18, the outputs to otorogo connected respectively to the inputs of the third and fourth switches 24, 25.

The output of the third switch 24 is connected to the input of the fourth power divider 19, the outputs of which are connected respectively to the inputs of the third 31 and fourth 32 electric filters, the outputs of which are connected respectively to the first and second inputs of the second adder 21, the output of which is connected to the signal input of the second mixer 2.

The output of the second switch 23 is connected to the signal input of the third mixer 35, the output of which is connected to the input of the fifth electric filter 33, the output of which is connected to the signal input of the fourth mixer 36, the output of which is connected to the third input of the first adder 20.

The output of the fourth switch 25 is connected to the signal input of the fifth mixer 37, the output of which is connected to the sixth electric filter 34, the output of which is connected to the signal input of the sixth mixer 38, the output of which is connected to the third input of the second adder 21.

The output of the fourth local oscillator 28 is connected to the inputs of the seventh and eighth mixers 39, 40, and the outputs of the second local oscillator 26 are connected respectively to the heterodyne inputs of the third and seventh mixers 35, 39.

The output of the third heterodyne 27 is connected to the heterodyne inputs of the sixth 38 and eighth 40 mixers, the output of the seventh mixer 39 is connected to the heterodyne input of the fourth mixer 36, and the output of the eighth mixer 40 is connected to the heterodyne input of the fifth mixer 37.

Literature

1. Yu.M. Perunov, K.I. Fomichev, L.M. Yudin. "Radio-electronic suppression of information channels of weapon control systems." - Moscow, Radio Engineering, 2008, p. 156 - 168.

2. A.Afinov. "Directions for improving the REP means of individual aircraft protection." "Foreign Military Review", 1998, No. 9, pp. 35-43.

3. RF patent (utility model) No. 66587 dated 03/05/2007

4. "Crystal Detectors", edited by E.J. Pumper, ed. Sov. Radio, Moscow, 1950, volume 1, pp. 178-187.

5. M.E. Movshovich, "Semiconductor frequency converters", "Energy", Leningrad branch, 1974, p. 244, 245.

6. V.N. Oleinikov, V.V. Boykov, V.A. Lukyanchuk. "Double balanced microwave mixer." Communication technology. Radio measuring equipment. Issue 7 (32), 1980, Moscow, pp. 56-64.

7. D.N. Shapiro, A.A. Payin, "Fundamentals of the theory of frequency synthesis." Moscow, Radio and Communications, 1981, pp. 111-118.

8. V. A. Levin, G. A. Norkin, "Radio-technical filtering systems with return heterodyning." Moscow, "Soviet Radio", 1979, p. 30.

9. RF patent No. 2133078 dated July 26, 1996.

Claims (1)

A device for storing frequencies of microwave signals, containing the first (MSS) and second (MSS) stages of frequency conversion, the MSS includes the first, second mixers, the first local oscillator, the output of which is connected to the heterodyne inputs of the first and second mixers, in addition, the input of the first mixer is the input of the device for storing the frequencies of microwave signals, the output of the second mixer is the output of the device for storing the frequencies of microwave signals, and the VSPCH includes: an input power divider, which has two outputs - the first and second, the output sum a motor with two inputs - the first and second, two phase sections on π / 2 - the second and first, two input mixers - the first and second and two output mixers - the first and second, local oscillator, two digital memory devices - the first and second, and the input the input divider is the input of the HPV device, and the output of the output adder is the output of the HPV device, the heterodyne inputs of the two input and two output mixers being connected to the output of the HPLC local oscillator, the first output of the input HPV power divider is connected to the signal input of the first input mixer, the output of which is connected to the input of the first digital memory device, the output of which is connected to the signal input of the first output mixer, the output of which is connected to the input of the first phase section, the output of which is connected to the first input of the adder VSPCH, in addition, the second output of the input power divider with the input of the second phase section, the output of which is connected to the signal input of the second input mixer, the output of which is connected to the input of the second digital memory device, the output of which is connected to the signal stroke of the second output of the mixer whose output is connected to the second input of the adder, characterized the fact that the following are introduced into the MSSP device: four power dividers - the first, second, third and fourth, which have two outputs, two adders - the first and second, which have three inputs - the first, second and third, four switches - the first, the second, third and fourth, three local oscillators - the second, third and fourth, six electric filters - the first, second, third, fourth, fifth and sixth, six mixers - the third, fourth, fifth, sixth, seventh and eighth, and the output of the first mixer connected to the input of the first power divider, cat outputs horn are connected respectively to the inputs of the first and second switches, the output of the first switch is connected to the input of the second power divider, the outputs of which are connected respectively to the inputs of the first and second electric filters, the outputs of which are connected respectively to the first and second inputs of the first adder, the output of which is connected to the input of the device VSPCH, the output of which is connected to the input of the third power divider, the outputs of which are connected respectively to the inputs of the third and fourth switches, and the output is third its circuit breaker is connected to the input of the fourth power divider, the outputs of which are connected respectively to the inputs of the third and fourth electric filters, the outputs of which are connected respectively to the first and second inputs of the second adder, the output of which is connected to the signal input of the second mixer, in addition, the output of the second switch is connected to the signal input of the third mixer, the output of which is connected to the input of the fifth electric filter, the output of which is connected to the signal input of the fourth mixer, the output of which the second is connected to the third input of the first adder, and the output of the fourth switch is connected to the signal input of the fifth mixer, the output of which is connected to the sixth electric filter, the output of which is connected to the signal input of the sixth mixer, the output of which is connected to the third input of the second adder, in addition, the output of the fourth the local oscillator is connected to the inputs of the seventh and eighth mixers, and the outputs of the second local oscillator are connected respectively to the heterodyne inputs of the third and seventh mixers, in addition, the output of the three the fifth oscillator is connected to the heterodyne inputs of the sixth and eighth mixers, the output of the seventh mixer is connected to the heterodyne input of the fourth mixer, and the output of the eighth mixer is connected to the heterodyne input of the fifth mixer.

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