RU7787U1 - MULTI-CHANNEL DUAL FREQUENCY CONVERTER - Google Patents

Abstract

The circuit of a multi-channel microwave receiver with double frequency conversion, comprising a low-noise amplifier, a first mixer with a first local oscillator signal conditioning circuit, a first intermediate frequency amplifier (OPC), a second mixer with a second local oscillator signal conditioning circuit, a bandpass filter, a second intermediate frequency amplifier, characterized in that two band-pass filters are additionally introduced into the circuit of the first intermediate frequency (the first is at the output of the amplifier, and the second is at the input of the second mixer), signal gain control (ARCus) with a control circuit, switched on at the output of the first additionally introduced filter, and a switch installed between the ARCus and the second additionally introduced filter, as well as a signal switch of the first local oscillator installed in its formation circuit.

Description

MULTI-CHANNEL MICROWAVE 11SHE1UERZH WITH DB01-1NY FREQUENCY CONVERTER.

The proposed device relates to radio engineering, namely, to microwave receivers used in communication and navigation systems, and especially in airborne and ground-based radars.

Microwave receive / faces are known that are similar to those offered for the intended purpose and to the shunkodi (for example, see Radar Receiver. Pat. USA II 5475391, Н04В, publ. 1995; Radio receiver. A.S. USSR 1 1363487, Н04В 1/06 , I / IO, publ. 1987; Radio receiver. A.S. USSR I5I7I38, Н04В 1/06, publ. 1989).

Closest to the solution to the proposed one is an X-band receiver developed by f USA (see 7ilt unSaJ., 1994, (/. 37, 12, p. 78 - 79). This device is a low-noise monopulse input unit multi-channel dual frequency conversion radar receiver.

The device is assembled in a single housing of independent functional units in individual buildings.

Fir-tree - a circuit containing 3 identical channels is presented in FIG. I, where I is a coupler, 2 is a switch, 3 is a low-noise amplifier (SHU), 4 is a mirror channel filter (FZK), 5, 7 is a valve, 6 is a first mixer, 8, 10 is an amplifier of the first intermediate frequency (UPChu), 9 - tuning attenuator, II - second mixer (mixer with suppression of the mirror channel), 12, 15 - switch, 13, 14 - band-pass filter iltr (Ш1Ф), 16 - amplifier of the second intermediate frequency (yiHg), 17 - circuit of the first local oscillator , 18, 19 phase-locked loop generator (PLL), 20 - switch, 21 - amplifier, 22 - divider

M.kl1 b Н04В 1/06

power, 23 - circuit of the second local oscillator, 24 - power amplifier, 25 - power divider. This receiver is characterized by the following parameters:

Frequency Range 1 (8-10 GHz)

bandwidth of the input signal 500 11Hz

- gain 70 dB noise figure 2.5 dB

- Identity of amplitude - frequency characteristics (3 channels) 1.5 dB

-phase-frequency identity

characteristics (3 channels) 20 °

- isolation between channels more than 40 dB

-frequency suppression of the first

mirror channel more than 60 dB

-frequency suppression of the second

mirror channel 20 dB

The disadvantages of this receiver include the low frequency level of the second mirror channel, the lack of adjustment of the transmission coefficient and the absence of blanking of the radar transmitter signal, which is obvious from the circuit design of this device.

The technical problem to which the proposed utility model is directed is to increase the level of suppression of the frequency of the second mirror channel, providing a wide range of adjustment of the transmission coefficient and a large depth of blanking of the transmitter signal.

The problem is solved by the fact that in the circuit of a multi-channel VLF receiver with double frequency conversion, containing a low-sensing amplifier, the first mixer with the signal generation circuit of the first local oscillator, the amplifier of the first intermediate frequency (yiHj), the second mixer with the signal formation circuit of the second local oscillator, a band-pass filter and an amplifier of the second intermediate frequency, two band-pass filters are additionally introduced into the circuit of the first intermediate frequency (the first - on

VBcode yiI4j, and the second at the input of the second omeoei gel), an automatic gain control unit (ARC) with a control circuit included at the output of the first additional input filter, and a switch installed between the ARC and the second additional input filter, as well as a signal pickup the first local oscillator in the chain of its formation.

The block diagram of the proposed device containing identical receive channels with double frequency conversion, including the heterodyne signal generation circuit, is shown in FIG. 2, where I is a low-noise amplifier (MPU), 2 a mirror channel filter (FZK), 3 - a first mixer, 4, 5, 9, 13 valve, 6 - an amplifier of the first intermediate asthma (LGH- | -), 7, II, 14 - band-pass filter (1Sh), 8 - automatic gain control unit (ARC), 10, 18 - switch, 12 - second J-meter, 15 - amplifier of the second .megg daily. Frequency (UPChr), 16 - chain of formation of heterodyne signals, 17, 21 - power amplifier, 19, 23 - directional coupler, 20, 24 - power divider, 22 - band pass filter (BF), 25 control circuit.

The device operates as follows (see Fig. 2). The received signal from the antenna is fed to the input of the MPU (I), amplified, filtered by the FZK (2) and fed to the input of the first mixer (cJ), where, using the signal of the first local oscillator supplied through valve C 4) from the circuit for generating heterodyne signals C 16 ), is converted into a signal of the first .. inter-frequency frequency (D4j). This signal is preceded by entering the input of the second mixer (12), passes through the valve (5), amplifies the TFC .- (6), filters the PN (7), is regulated by the magnitude of the ARC (8) and through the valve (9) and the switch (10) enters the BF (II), where it is additionally filtered. In the second mixer (12), the Shu signal is mixed with

the signal of the second local oscillator supplied through the valve (13) from the heterodyne signal generation circuit (16) is converted into a second intermediate frequency (IF) signal, which is then filtered by the PN (14), amplified by the amplifier, if the amplifier (15), and is fed to the output of the device.

The introduction of additional BF (7) and PN (II) into the INj path allows the signal of the second mirror channel to be suppressed, and the introduction of the AGC system (8) provides a wide range of transmission coefficient adjustment (from suppression to amplification). The simultaneous operation of the switches (10) and (18) in the circuit Ш-г and the first local oscillator, respectively, from a single control circuit allows to obtain a large depth of signal blanking of the transmitter.

The inventive scheme, thanks to the introduction of the above nodes, allows you to flexibly adjust the characteristics of the device as a whole and provides its versatility for use in systems of various purposes, providing the choice of the optimal mode for integration into systems.

An example of a specific implementation "

In accordance with the proposed scheme, a 3-channel receiving device was developed. All nodes of the receiver are made according to Ш - technology in a single constrictive - technological design, which allows to optically combine the technical characteristics of individual functional units to obtain the best parameters of the device as a whole.

The device is characterized by the following parameters:

- wavelength range 3 cm

- frequency band of the input signal 500 - 800 MHz

transmission coefficient 30-40 dB

- transmitter signal blanking

with a speed of 100 not at a depth of 80 dB

- suppression of a signal of the first

channel mirror 60 dB

- suppression of a signal of the second

channel mirror 60 dB

- Identity of amplitude-frequency characteristics (3 channels) 1.5 dB

 phase-frequency identity

characteristics (3 channels) 20 °

Inter-channel isolation 40 dB

upper limit of linearity

10 W input characteristic

- output frequency 84 megapixels,

-operating temperature range - 60 + 70 ° С

- overall dimensions200 x 185 x 60 mm

- mass2 kg

Thus, the proposed succesful solution, implemented when creating the receiving device, allows to increase its selectivity, provides a wide range of transmission coefficient adjustment and a large depth of signal blanking of the transmitter with high speed, which makes it more universal when used in various systems and improves their tactics - specifications .

Claims (1)

The circuit of a multi-channel microwave receiver with double frequency conversion, containing a low-noise amplifier, a first mixer with a signal conditioning circuit of the first local oscillator, an amplifier of the first intermediate frequency (UPCH ₁ ), a second mixer with a signal conditioning circuit of the second local oscillator, a bandpass filter, a second intermediate frequency amplifier , characterized in that two band-pass filters are additionally introduced into the circuit of the first intermediate frequency (the first is at the output of the amplifier ₁ , and the second is at the input of the second mixer), automatic gain control (ARC) with a control circuit included at the output of the first additional input filter, and a switch installed between the ARC and the second additional input filter, as well as a signal switch of the first local oscillator installed in its generation circuit.