RU148915U1 - TRANSMISSION MODULE OF AN ACTIVE PHASED ANTENNA ARRAY OF A RADAR STATION - Google Patents

Abstract

The transceiver module of the active phased antenna array of the radar station, consisting of transceiver channels, a removable secondary power supply unit, a control unit, characterized in that planar placement in the case of two identical multilayer printed circuit boards, structurally combining 4 transceiver channels, including 6 a bit phase shifter and a 5-bit attenuator, which are common to the receiving and transmitting parts of the transceiver channels, two 1: 4 divider probing impu xy and the control signal of the receiving part, the adder 4: 1 of the receiving signals, functionally combined with the adder of the control signal of the transmitting part, and the control unit, which are also common for four transceiver channels, and the mutual screening of the channels is carried out using screen partitions, which are also elements attaching the multilayer printed circuit board to the case of the transceiver module, a removable secondary power supply unit is installed in a sealed compartment on the back of the transceiver a module, in the same compartment on the inside of the cover there is a board including a 1: 2 divider of the probe pulse, a 1: 2 divider of the control signal of the receiving part and a 2: 1 adder of the receiving signals and control signal of the transmitting part, while the module cover is a radiator for fuel elements of the secondary power supply unit, and the base of the module is a radiator for the output amplifiers of the transmitting part.

Description

The utility model relates to radar, in particular to L-band transceiver modules (APM), designed to operate as part of an active phased antenna array (AFAR) of a radar station.

The transmitting and receiving module is the most massive AFAR unit and the most difficult to develop due to the need to place the receiving and transmitting channels with a power source, control over the PMD in one volume of all microelectronics, while ensuring heat removal. The overall dimensions of the PPM are determined by the possibility of placing them on the antenna array. The maximum values of the transverse dimensions of the PPM should be less than the radiation wavelength to ensure an acceptable working angular sector of the radar station, and the longitudinal dimensions are limited by the condition of minimizing losses in microwave connecting microstrip lines between individual electronic micro nodes. In order to reduce weight and size parameters and simplify the design, it is most rational to design AFAR based on multichannel transceiver modules [1, 2, 3].

Known PPM AFAR [4], comprising a receive / transmit switch for 2 positions with a switch connected to it. The transmitting channel includes a controllable and additional n-bit step phase shifters connected to one control circuit, two matching amplifiers, preliminary and output power amplifiers. The receiving channel includes a controllable and additional n-bit step phase shifters, two matching amplifiers, a controllable and additional n-bit step attenuators, a microwave power divider, a low-noise amplifier, and a protective device. Phase shifters and attenuators are connected to the same control circuit. A second receiving channel is connected to the second output of the power divider.

The disadvantages of this device are: the inclusion in the composition of each channel PPM additional receiving channel, which significantly increases the cost of AFAR; separation of the output of the transmitting channel from the input of the receiving channel, which requires the use of a second emitter; the presence of additional controlled phase shifters and attenuators, which leads to high complexity of the control circuit of the PPM.

The closest to the proposed utility model for circuitry and design solution is the AFAR module adopted for the prototype [5], which includes four independent transceiver channels in which all microwave nodes, receive-transmit switch boards, as well as individual control nodes, power and protection are placed in pairs on two base plates mounted symmetrically on the top and bottom in the module housing, forming a structure with mirror symmetry relative to two mutually perpendicular planes passing through longitudinal axis of the module. A control unit common for four transceiver channels, including storage capacitor assemblies, as well as supply voltage stabilization units, monitoring and protection units, is located in the middle part of the module and have an asymmetric design. Relatively massive longitudinal bases are provided in the module housing, which carry a liquid cooling channel.

The disadvantages of the prototype are the complexity of the design, a significant number of wired installation, increasing the complexity of manufacturing and increasing the likelihood of errors in the electrical connection associated with the human factor, as well as the use of a difficult to implement liquid cooling system.

The technical result of the utility model is to improve technical and economic characteristics, namely, reducing the weight of the module, reducing the complexity and cost of manufacturing the module, simplifying the design, as well as increasing the reliability of the transceiver system as a whole.

The specified technical result is achieved by the fact that in the well-known multi-channel module, consisting of transceiver channels, a control unit and a removable secondary power supply unit, planar placement in the case of two identical multilayer printed circuit boards is introduced, structurally combining four transceiver channels, including controlled 6-bit a phase shifter and a 5-bit attenuator, which are common for the receiving and transmitting parts of the transceiver channels, two 1: 4 divisors of the probe pulse and control signal of the receiving part, the adder 4: 1 of the receiving signals, functionally combined with the adder of the control signal of the transmitting part and the control unit, which is common for four transceiver channels, which leads to a significant reduction in the complexity due to the manufacture of 4 transceiver channels at once for one technological cycle and a significant reduction in wiring inside the module. Improving the reliability, reducing the mass and cost of the transceiver module is achieved by reducing the number of circuit elements that are common to the receiving and transmitting part of the transceiver channel, and elements common to 4 transceiver channels. Screen partitions are installed on the surface of the multilayer printed circuit board for mutual screening of channels. The secondary power supply unit is installed in a sealed compartment on the back of the transceiver module. In the same compartment, on the inside of the lid, there is a board including a 1: 2 divider of the probe pulse, a 1: 2 divider of the control signal of the receiving part and an adder 2: 1 of the receiving signals and control signal of the transmitting part, while the PPM cover is a radiator for heat elements of the secondary power supply unit, and the base of the module is a radiator for the output amplifiers of the transmitting part.

To explain the proposed utility model in FIG. 1 shows a multilayer printed circuit board, combining 4 transceiver channels, where the following notation:

1 - receiving part of the transceiver channels;

2 - transmitting part of the transceiver channels;

3 - divider 1: 4 of the probe pulse, divider 1: 4 of the control signal of the receiving part, the adder 4: 1 of the receiving signals, functionally combined with the adder of the control signal of the transmitting part;

4 - control unit;

5 - technological connectors.

In FIG. 2 shows the transceiver channel of the 8-channel PPM, where the designations are:

6 - directional coupler of the receiving part;

7 - protection device;

8 - bandpass filter;

9 - low-noise broadband amplifier;

10 - controlled 6-bit phase shifter;

11 - controlled 5-bit attenuator;

12 - ferrite decoupling devices;

13 - output amplifier;

14 - 2-stage pre-amplifier;

15 - directional coupler of the transmitting part;

16 - keys;

17 - managed antenna switch.

In FIG. 3 shows the design of the 8-channel PPM, where the designations are:

18 - module housing;

19 - screen partitions;

20 - the basis of the PPM;

21 - removable secondary power supply unit;

22 - PPM cover;

23 - fuel elements of a removable secondary power supply unit;

24 - board, including a 1: 2 divider of the probe pulse, a 1: 2 divider of the control signal of the receiving part and an adder 2: 1 of the receiving signals and the control signal of the transmitting part.

The multilayer printed circuit board shown in figure 1, structurally combines four transceiver channels with alternating reception (1) and transmitting (2) parts connected to a divider 1: 4 of the probe pulse, a divider 1: 4 of the control signal of the receiving part, adder 4 : 1 receiving signals, functionally combined with the adder of the control signal of the transmitting part (3), and the control unit (4), which is common to four transceiver channels. In this case, the upper layer of a multilayer printed circuit board on which transceiver channels with the above dividers and adders are implemented is a microwave material from an organic foil dielectric, and the subsequent layers in which the control signals are separated are made of fiberglass-based material. The presence of technological connectors on the board (5) allows for phased tuning of channels outside the module case.

The figure 2 shows a transceiver channel, which includes: a directional coupler of the receiving part (6); a protection device (7) designed to limit the received signals by amplitude; bandpass filter (8), which serves to filter out-of-band received signals; low-noise broadband amplifier (9), designed to amplify the signals received from the emitters of the antenna system; a controlled 6-bit phase shifter (10), designed to control the phase of the received and emitted signals and generate a radiation pattern for receiving / transmitting the antenna array; controlled 5-bit attenuator (11), designed to control the amplitude of the received and radiated signals, the transceiver diagram of the antenna array and the weight distribution on the fabric of the antenna array; ferrite decouplers (12); output amplifier (13), necessary for the final amplification of the emitted high-frequency signal, at the input of which a 2-stage pre-amplifier (14) is installed; directional coupler of the transmitting part (15). In this case, the controlled phase shifter (10) and attenuator (11) are common for the receiving (1) and transmitting (2) parts of the transceiver channel, for the implementation of their joint operation, keys (16) are installed at the input and output for switching and transmitting, switching the mode reception / transmission; managed antenna switch (17).

The use of common for the receiving (1) and transmitting (2) parts and common for 4 transceiver channels elements increases the reliability of the module, reduces weight and cost.

The eight-channel PPM, the design of which is shown in Figure 3, includes two identical 4-channel boards installed on the basis of the sealed module case (18) using mechanical fastening. The planar placement of all eight transceiver channels and the replacement of wired installation with printed wiring, provide ease of assembly and configuration of the module, and can eliminate electrical wiring errors associated with the human factor.

Each receiving and transmitting part of the transmitting and transmitting channels, an area with phase shifters and attenuators, an area with dividers and an adder, as well as a control unit are separated by screen partitions (19), which are also elements of the board mounting to the module case and are installed on the PCB case using screws . The complete uniformity of the channels and mutual screening make it possible to ensure the identity of the electrodynamic characteristics of all 8 transceiver channels.

For maximum heat transfer, the output amplifiers (13) of the transmitting part (2) of the transceiver channels, implemented on promising field effect transistors, are mounted directly on the PPM base (20), made in the form of a fin radiator, which ensures the optimal thermal operation of transistors and increases the reliability of the transmitting device.

To ensure the minimum dimensions, a removable secondary power supply unit (21), which is common for 8 transceiver channels, is located in a sealed compartment on the back of the module in a region free from the radiator. To ensure optimal thermal conditions, the secondary power supply unit board (21) is mounted on the PPM cover (22) with the installation of fuel elements (23) of the removable secondary power supply unit (21) in the card slots directly on the module cover, which simultaneously serves as a radiator. The removable design of the secondary power supply unit (21) allows its adjustment outside the PPM housing. In the same compartment, on the base of the module (20), a board (24) is installed in the area shielded with the help of the milled partition and the false cover, which includes two dividers 1: 2 of the probe pulse and the control signal of the receiving part and the adder 2: 1 of the receiving signals and control signal transmitting part.

Currently, the company is making a prototype of the proposed transceiver module AFAR radar station.

Thus, the proposed utility model, which differs fundamentally from the prototype by the combination of 4 transceiver channels with a control unit, a 1: 4 probe pulse divider and a 1: 4 pilot signal divider of the receiving part and a 4: 1 adder of the receiving signals, functionally combined with the pilot signal adder the transmitting part into one multilayer printed circuit board allows, while maintaining the advantages of the prototype, to significantly reduce the weight, complexity and cost of manufacturing PPM, simplify the design, and also increase s reliability transceiver system, which is an important prerequisite seriynoprigodnosti products.

Literature

1. Active phased array antennas. Edited by D.I. Voskresensky, A.I. Kanaschenkova. M. “Radio Engineering”, 2004, p. 18-22.

2. The concept of creating an airborne radar system with an active PAR. Yu.N. Guskov. Radio systems: Radio-electronic complexes, 2002, No. 1, p. 26-27.

3. AFAR - a step towards solving the problem. E.N. Egorov A.I. Sinani. World of Avionics: Production and Technology. 2003, No. 5, p. 31-32.

4. RF patent No. 2454763, H01Q 21/00, 2010

5. RF patent No. 2380803, H01Q 21/00, 2008

Claims (1)

The transceiver module of the active phased antenna array of the radar station, consisting of transceiver channels, a removable secondary power supply unit, a control unit, characterized in that planar placement in the case of two identical multilayer printed circuit boards, structurally combining 4 transceiver channels, including 6 a bit phase shifter and a 5-bit attenuator, which are common for the receiving and transmitting parts of the transceiver channels, two 1: 4 divider probing impu xy and the control signal of the receiving part, the adder 4: 1 of the receiving signals, functionally combined with the adder of the control signal of the transmitting part, and the control unit, which are also common for four transceiver channels, and the mutual screening of the channels is carried out using screen partitions, which are also elements attaching the multilayer printed circuit board to the case of the transceiver module, a removable secondary power supply unit is installed in a sealed compartment on the back of the transceiver a module, in the same compartment on the inside of the cover there is a board including a 1: 2 divider of the probe pulse, a 1: 2 divider of the control signal of the receiving part and a 2: 1 adder of the receiving signals and control signal of the transmitting part, while the module cover is a radiator for fuel elements of the secondary power supply unit, and the base of the module is a radiator for the output amplifiers of the transmitting part.

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