RU2242852C1 - Signal receiver unit for satellite radio navigation systems - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: proposed unit designed for receiving signals of satellite radio navigation systems of the GLONASS, GPS, and other types has conducting case, receiver-processor board, as well as means designed for interconnecting/disconnecting input signal circuit and power circuit of active antenna assembly disposed on input board mounted on case wall at installation point of high-frequency block terminal used for connecting antenna assembly; input board is made of structural material of definite standardized dielectric constant which makes it possible to set up asymmetric microwave microstrip line on this board; disposed on one end of input board is ground plane with metal-free circle-shaped area inside, circle diameter being same as that of inner insulator of high-frequency block terminal; provided in center of this circle is metallized hole passing signal lead; disposed on other end of input board are contact pads, printed conductors, electric and radio components of electric circuit implementing interconnecting/disconnecting circuit of input signal circuit and power circuit of active antenna assembly; input board is secured so that its ground plane is in electric contact with case wall and with high-frequency block terminal body; signal lead of the latter on other end of input board is connected to contact member that functions as point of electrical interconnection/disconnection of input signal circuit and power circuit of active antenna assembly; power circuit output lead of the latter is connected to this contact member with filter element in the form of LC filter, its input and ground leads being connected to output and ground leads of supply voltage shaper for active antenna assembly disposed inside case separately from receiver-processor board; connected to same contact member is input signal circuit that has series-connected filter element in the form of capacitor and asymmetric microwave microstrip line; its output printed conductor is connected to coaxial cable central core that connects input board to receiver-processor board; cable is secured on input board so that electric contact is ensured between its uninsulated braided screen and contact pad electrically connected to ground plane. Receiver-processor of the unit is independent of power characteristics of active antenna assembly being connected.

EFFECT: eliminated stray pickups and induced noise, reduced loss in input signal line disposed beyond receiver-processor board.

1 cl, 7 dwg

Description

The invention relates to radio engineering and can be used in the construction of blocks of receivers of equipment for consumers of signals from satellite radio navigation systems (SRNS) such as GLONASS, GPS, etc.

A typical block construction of the equipment of consumers of SRNS signals, which is the subject of consideration in this application, is characterized by the fact that the antenna device that receives SRNS signals from the air, and the receiver of SRNS signals, which performs frequency conversion and subsequent processing of the received SRNS signals, are implemented as separate structural units interconnected by an antenna-feeder path [1, p.185] The advantage of such a block construction is the ability to configure equipment with different x characteristics and for various applications due to combinations of different types of SRNS signal receivers and antenna devices [1, p.185-186, fig. 12.1, 12.2], [2, p. 48-52], [3, p. 121-122 , fig. 7.10, 7.11] To the greatest extent possible, “passive” antenna devices, for example, of the type [4], [5], [6], which do not require power supply and, therefore, special means for matching “ nutrition ”when docked with various types of SRNS signal receivers. However, the use of equipment with “passive” antenna devices is possible under relatively favorable reception conditions and relatively short antenna-feeder paths.

In adverse conditions of reception of SRNS signals, as well as at sufficiently large (from several meters) antenna-feeder path lengths, antenna devices with integrated active amplifying elements are used, see, for example, [7], [8], [9], or equipped additional trunk amplifiers, see, for example, [10, figure 1, blocks 18, 20], [11, figure 1, blocks 1, 2], [12, figure 1, blocks 101, 102]. Such "active" antenna devices require the provision of their active elements with appropriate power.

At least two constructive solutions to the problem of providing power to active antenna devices are known.

The first of these solutions, presented, for example, in [9], is that the supply voltage is supplied to the active antenna device via separate wires. The advantage of this solution is the simplicity of implementation, as well as the ability to dock with an SRNS signal receiver, which is not equipped with means for powering an active antenna device. The disadvantage is the need to use separate wires for supplying power to the active antenna device, which is not always possible, and in addition, the presence of such wires can cause additional noise and induced interference.

The second of these solutions is that the supply voltage to the active antenna device is supplied through the same high-frequency coaxial cable through which the received SRNS signals are transmitted. This allows you to solve the problem of powering the active antenna device without the use of additional wires and the additional noise and induced interference caused by them. However, this solution requires equipping the blocks of the active antenna device and the receiver blocks of the SRNS signals with appropriate filtering means, providing the combination-separation of the signal circuit and the power circuit of the active antenna device.

For example, in the radio-electronic unit [13], the means providing combining-separation of the input signal circuit of the receiver-processor of the SRNS signals and the power circuit of the active antenna device connected to it are located directly on the receiver-processor board. The composition of these tools includes a high-frequency connector located on the receiver-processor board and filtering elements of the input signal circuit and the power circuit of the active antenna device associated with its signal output.

A similar solution for placing on the receiver-processor board the means used for combining-separating its input signal circuit and the power circuit of the active antenna device is implemented in the design of the SRNS signal receiver block [14], which, in part of this decision, was adopted as a prototype of the claimed signal block SRNS.

The SRNS signal receiver unit described in [14] contains a housing made of an electrically conductive material with connecting means installed on it for connecting external devices. Inside the case there is a receiver-processor board connected with these connecting means, designed for frequency conversion and correlation processing of SRNS signals (for example, GLONASS and GPS). SRNS signals are received on the receiver-processor board via an in-unit high-frequency coaxial cable connected to the receiver-processor board through the corresponding in-board high-frequency connector. In the opposite direction, from the receiver-processor board via the same high-frequency coaxial cable, the power voltage generated on the receiver-processor board is supplied for the active antenna device, which in [14] is located in the same housing as the receiver-processor board. For combining-separating the input signal circuit of the receiver-processor and the power circuit of the active antenna device, the receiver-processor board is equipped with appropriate means, which include filtering elements of the input signal circuit of the receiver-processor and the power circuit of the active antenna device. The filtering elements of the input signal circuit of the receiver-processor and the power circuit of the active antenna device are connected in a Y-shaped circuit with the signal output of the on-board high-frequency connector. The supply voltage for the active antenna device is formed from the internal supply voltage of the receiver-processor. Shielding the input signal circuit to eliminate spurious interference and induced noise is carried out by means of on-board shielding.

The constructive solution used in [14], which consists in combining and separating the input signal circuit of the receiver-processor and the power circuit of the active antenna device by means of the receiver-processor, is narrowly specialized, leading to the fact that each type of active antenna device characterized by certain power parameters must correspond to a certain type of receiver-processor board that provides this power. In fact, such a design solution makes the execution of the receiver-processor board dependent on the power characteristics of the active antenna device.

In the case under consideration of the block equipment of SRNS signal consumers, when the active antenna device and the receiver-processor are located in separate structural blocks, such a narrowly specialized solution, characterized by the placement of means for combining-separating the input signal circuit of the receiver-processor and the power circuit of the active antenna device on the receiver board -processor, does not allow to realize the advantage of block construction of equipment, in particular the possibility of using one type of receiver -Processor in combination with various types of active antenna devices.

The task to which the claimed invention is directed is to create a design of a receiver unit of the SRNS signals, which ensures the independence of the receiver-processor used in it from the power characteristics of the connected active antenna device. At the same time, the task of eliminating spurious interference and induced interference, as well as reducing losses in the input signal circuit when it is placed outside the receiver-processor board — on the input board carrying means designed to combine-separate the input signal circuit and the active antenna power circuit is being solved devices.

The solution to these problems makes it possible to implement various configurations of the SRNS signal consumer equipment, where one type of unified receiver-processor can be used in combination with various types of active antenna devices having different power characteristics and different designs, for example, with ship active antenna devices placed on the masts , with automobile active antenna devices placed on the roofs of automobiles, with aircraft active antenna devices tvam placed on the skin of the fuselage, with the active antenna devices, telecommunications base stations, are placed on the roofs of tall buildings or towers, etc.

The essence of the claimed invention lies in the fact that in the receiver unit of the SRNS signals, comprising a housing made of electrically conductive material with connecting means for connecting external devices located inside the housing and connected to these connecting means, a receiver-processor board designed for frequency conversion and correlation processing of the SRNS signals received by the active antenna device, received on the receiver-processor board by internal unit high-frequency coaxial cable, as well as means for combining-separating the input signal circuit and the power circuit of the active antenna device, containing filter elements of these circuits, unlike the prototype, means for combining-separating the input signal circuit and the power circuit of the active antenna devices located on the input board mounted on the wall of the housing at the installation site of the high-frequency block connector designed to connect an external high-frequency coaxial cable from the outside of the active antenna device. The input board is made of structural material with a certain normalized value of the coefficient of dielectric constant, which makes it possible to realize on it a microwave asymmetric microstrip line for transmitting SRNS signals to an in-block high-frequency coaxial cable connecting the input board to the receiver-processor board, on the first side of the input board there is an earthen plane inside of which a circle-shaped section is made free of metallization, the diameter of which coincides with the diameter the insulator of the high-frequency block connector, and in its center there is a metallized hole through which the signal output of the high-frequency block connector passes, on the second side of the input board there are contact pads, printed conductors, including the signal conductor of the specified microwave asymmetric microstrip line, and radio-electronic elements of the electrical circuit, implements on the input board a combination-separation circuit of the input signal circuit and the power circuit of the active antenna device In this case, the input board is fixed to the housing wall so that its ground plane is in electrical contact with the housing wall and with the housing of the high-frequency block connector.

The signal output of the high-frequency block connector on the second side of the input board is connected to the contact element, which is the point of electrical association-separation of the input signal circuit and the power circuit of the active antenna device, with this contact element connected to its output terminal, the power circuit of the active antenna device made on the input board with its filter element, while its input and ground terminals are connected through a bundle with output and ground terminals located inside the housing It is flax from the receiver-processor board of the supply voltage driver for the active antenna device that is connected to its input printed conductor by an input signal circuit made on the input board, which contains its filter element and the specified microwave asymmetric microstrip line, while its output is printed the conductor is connected to the central core of an intra-unit high-frequency coaxial cable fixed to the input board so that it is provided with an insulating contact liberated from its outer insulation shielding with a pad having an electrical connection with an earth plane, said central core compound vnutriblochnogo high frequency coaxial cable with a printed conductor output signal input circuit implemented by surface mounting.

In preferred embodiments, the entrance board is made using foil laminate as a structural material with a specific, selected from 4.0 to 5.5 normalized dielectric constant, such as foil-coated epoxy fiberglass brand FR4; the signal circuit filtering element is a capacitor mounted on the input board by surface mounting, the active antenna device’s filtering element of the power circuit is an LC filter made in the form of one or two L-shaped LC links in series, where the first conclusions are connected to each other inductive and capacitive components, the second output of the capacitive component and the second output of the inductive component form the input, ground and output terminals of the LC link, respectively in the case of the LC-filter in the form of one LC-link, the input, ground and output terminals of this LC-link form the input, ground and output terminals of the LC-filter, and in the case of the LC-filter in the form of two sequentially connected LC-links of the input and the ground terminals of the first LC link and the output terminal of the second LC link form the input, ground and output terminals of the LC filter, while the input, ground and output terminals of the LC filter are the input, ground and output terminals of the active power circuit antenna device a.

The invention, its feasibility and the possibility of industrial application are illustrated in figures 1-6, illustrating an example implementation of the inventive unit of the receiver of the SRNS signals.

Figure 1 presents a schematically claimed block of the receiver of signals of the SRNS, General view (the receiver-processor board and the carrier board are shown conditionally without electronic components);

figure 2 is a fragment of a General view illustrating the simultaneous fastening of the high-frequency block connector and the input board on the wall of the housing of the receiver unit of the SRNS signals;

figure 3 is an example of the implementation of the input board, where figa is a view from the side of the earth plane, figb is a view from the side of the electric and radio elements;

figure 4 is an example of an electrical circuit combining-separating the input signal circuit and the power circuit of the active antenna device, implemented in the receiver unit of the SRNS signals;

figure 5 is a fragment of the input board illustrating the connection of the Central core of the intra-unit high-frequency coaxial cable with the output printed conductor of the input signal circuit by surface mounting;

6 is a fragment of the input board, illustrating the fastening on the input board of an intra-unit high-frequency coaxial cable.

The inventive receiver unit of the SRNS signals in the considered exemplary embodiment (Figs. 1-6) comprises a housing 1 made of an electrically conductive material, the shape of which is close to the shape of a flattened rectangular parallelepiped. Structurally, the housing 1 consists of a base 2, a removable cover 3 and a hinged side walls 4 and 5. The base 2 is equipped with mounting tabs 6, which allow mounting the receiver unit of the SRNS signals on the surface of the installation object of the block.

On the walls 4 and 5 of the housing 1, connecting means are installed for connecting external devices to the receiver unit of the SRNS signals. The connecting means include low-frequency block connectors 7 located on the wall 4 (for example, type PC plugs according to ABО.364.047 TU), designed to connect the corresponding external low-frequency wire harnesses from an external power source and external peripheral devices for data processing and / or indication, and also placed on the wall 5 high-frequency block connector 8 (for example, type SR-50-150FV VRO.364.011 TU), designed to connect an external high-frequency coaxial cable from an external active antenna about devices (external devices, including an active antenna device, are not shown in FIGS. 1-6).

Inside the housing 1 on the wall 5 at the installation site of the high-frequency block connector 8, an input board 9 is installed (Figs. 1, 2, 3), on which an electric circuit for combining-separating the input signal circuit and the power circuit of the active antenna device is installed (Figs. 3, 4 )

Inside the housing 1, on the carrier board 10, there is a receiver-processor 11 board designed for frequency conversion and correlation processing of SRNS signals (for example, GLONASS, GPS) received on the receiver-processor board 11 via an intra-unit high-frequency coaxial cable 12 connecting the input board 9 s the receiver-processor board 11. Structurally, the receiver-processor board 11 can be made according to the type of receiver-processor boards described, for example, in [15] and [16].

With the input board 9, an intra-block high-frequency coaxial cable 12 is connected directly by soldering (Fig. 3b, 5, 6). An internal unit high-frequency coaxial cable 12 is connected to the receiver-processor board 11 through a high-frequency cable connector 13 and a high-frequency connector 14 mounted on the receiver-processor board 11 (Fig. 1). The length of the internal high-frequency coaxial cable 12 is selected based on the possibility of folding the wall 5 from the base 2.

The receiver-processor board 11 is also connected to the low-frequency block connectors 7 located on the wall 4. This communication is carried out through electrical circuits passing through the connectors located on the receiver-processor board 11, through the electrical elements and connectors located on the carrier board 10 (in FIG. .1-6 are not shown), and then through the bundles 15 connected to the low-frequency block connectors 7. The length of the bundles 15 is selected based on the possibility of folding the wall 4 from the base 2.

The input board 9 is made of structural material with a certain normalized value of the coefficient of dielectric constant, which makes it possible to realize on it a microwave asymmetric microstrip line for transmitting input signals of the SRNS (gigahertz frequency range) to an intra-block high-frequency coaxial cable 12 connecting the input board 9 to the receiver-processor board 11. In an advantageous embodiment, the implementation of the input board 9 is made using alloyed laminate with a specific, selected in the range from 4.0 to 5.5, the normalized value of the coefficient of dielectric constant, such as foil-coated epoxy fiberglass brand FR4 (or similar).

On the first side of the input board 9 (Fig. 3a), directly adjacent to the wall 5, there is an earthen plane 16, inside which a circle-free section 17 is made, which diameter is the same as the diameter of the inner insulator 18 located inside the high-frequency block case 19 connector 8 (figure 2). The end part of the housing 19 of the high-frequency block connector 8 protruding from the wall 5 is in contact with the earth plane 16 in a circle around the portion 17, and the signal output 20 of the high-frequency block connector 8 passes through a metallized hole 21 made in the center of the portion 17 (Figs. 2, 3). In practice, for direct contact of the housing 19 of the high-frequency block connector 8 with the ground plane 16, it is enough that its end part protrudes from the wall 5 by 0.1-0.2 mm. This is achieved by performing the wall 5 of a certain thickness.

In this example, the signal output 20 of the high-frequency block connector 8, passing through a metallized hole 21, made in the center of section 17, is soldered on the second side of the input board 9 on the contact element 22, which is the point of electrical association-branching of the input signal circuit and the power circuit of the active antenna device (Fig.2, 3b, 4).

In addition to the contact element 22 on the second side of the input board 9 (Fig 3b) there are contact pads 24 for the bolt connection elements that are simultaneously fastened to the high-frequency block connector 8 and the input board 9 on the wall 5 connected to the ground plane 16 by means of metallized holes 23 and also connected with the ground plane 16, the contact pad 25 for securing the internal unit high-frequency coaxial cable 12. Also, on the second side of the input board 9 are pads, printed e conductors and electric radio circuitry implementing the input circuit board 9-division combining the input signal circuit and power supply circuit of the active antenna device.

The input board 9 is fixed on the wall 5 in such a way as to ensure reliable electrical contact of its earth plane 16 with the wall 5 and with the housing 19 of the high-frequency block connector 8.

Electrical contact of the ground plane 16 with the wall 5 is carried out over the entire area of the ground plane 16. This is due to the fact that the surface of the wall 5 in the contact zone with the ground plane 16 is made flat and smooth, and the input board 9 is pulled to the wall 5 with a certain force, provided by fasteners.

The electrical contact of the ground plane 16 with the housing 19 of the high-frequency block connector 8 is ensured, firstly, due to the electrically conductive properties of the wall 5, and secondly, due to the specified direct contact of the end portion of the housing 19 of the high-frequency block connector 8 protruding from the ground plane 16 with the ground plane 16 and thirdly, due to galvanic coupling implemented by the electrically conductive elements of the bolted connection, which simultaneously fastens the high-frequency block connector 8 and the input boards 9 on wall 5.

In this example, the simultaneous fastening of the high-frequency block connector 8 and the input board 9 on the wall 5 is carried out by electrically conductive elements of the bolted connection - screws 26 with nuts 27 and washers 28 (figure 2). In this case, the screws 26 pass through the mounting holes 29 in the flange of the high-frequency block connector 8, through the holes 30 in the wall 5, and then through the metallized holes 23 in the input board 9. From their heads, the screws 26 are in contact with the flange of the high-frequency block connector 8, and from the side of nuts 27 and washers 28, with contact pads 24 connected by means of metallized holes 23 to the earthen plane 16.

The considered constructive measures for the implementation of the input board 9 and its connection with the high-frequency block connector 8 provide effective, with fairly low losses, coordination of heterogeneous elements of the design - coaxial elements of the high-frequency block connector 8 and printed elements of the input board 9 operating in the conditions of the GHz frequency range ( for GLONASS / GPS, the frequency range is from 1.2 to 1.7 GHz). At the same time, due to the shielding properties of the housing 1, effective shielding of the electrical circuitry performed on the input board 9 from spurious interference and induced interference is provided.

The electrical circuit performed on the input board 9 implements a Y-shaped combination-separation circuit of the input signal circuit and the power circuit of the active antenna device with a common point, structurally made in the form of a contact element 22, to which, as noted above, the signal output 20 of the high-frequency block connector is connected 8.

In this example, the input signal circuit performed on the input board 9 contains a filter element in series in the form of a capacitor 31 and a microwave asymmetric microstrip line 32 with a signal conductor 33 (Fig. 4). Capacitor 31 is a surface mounted capacitor, for example, NPO-50V-56pF ± 5% s.0603 type capacitor. The input signal circuit is connected to the contact element 22 by its input printed conductor 34, and by its output printed conductor, the function of which in this example is performed by the end of the signal conductor 33 of the microwave unbalanced microstrip line 32, with the central core 35 of the internal unit high-frequency coaxial cable 12, for example, a cable of the type RG 174 or PK-50-1.5-21 (Fig.3b, 4).

The connection of the Central core 35 of the internal high-frequency coaxial cable 12 with the output printed circuit of the input signal circuit, the function of which is the end of the signal cable 33 of the microwave unbalanced microstrip line 32, is carried out by the surface mounting method (Fig.3b, 5). In this case, the intra-block high-frequency coaxial cable 12 is fixed on the input board 9 so that it is provided with electrical contact from the shielding braid 36, which is released from the external insulation, with the contact pad 25, which is electrically connected to the ground plane 16. In this example, the intra-block high-frequency coaxial cable 12 is secured for due to the soldered wire brace 37, as well as due to the direct soldering of its shielding braid 36 to the contact pad 25 (Fig.3b, 6).

Made on the input board 9, the power circuit of the active antenna device contains a filter element in the form of an LC filter 38 (figure 4). This circuit is connected to the contact element 22 by its output terminal, and by its input and ground terminals through the harness 39 with the output and ground terminals of the supply voltage driver 40 for the active antenna device (Fig. 3b, 4). The length of the bundle 39 is selected based on the possibility of folding the side wall 5 from the base 2 (figure 1).

In this example, the LC filter 38, which acts as a filter element of the power circuit of the active antenna device, is made in the form of two L-shaped LC links 41 ₁ and 41 ₂ connected in series, and in each of the LC links 41 the first leads of the inductive (L) 42 and capacitive (C) 43 components form the input terminal of the LC link 41, the second terminal of the capacitive component 43 forms the ground terminal of the LC link 41, and the second terminal of the inductive component 42 forms the output terminal of the LC link 41. Capacitive components 43 represent by myself non-polar capacitors. In the case under consideration, two LC-links 41 ₁ and 4 41 ₂ (Figs. 3b, 4) in series and input terminals of the first LC-link 41 ₁ (those first and second terminals of the capacitive component 43 ₁ ) form the input and ground terminals of the LC- filter 38, and the output terminal of the second LC link 41 ₂ (i.e., the second terminal of the inductive component 42 ₂ ) forms the output terminal of the LC filter 38. The input, ground, and output terminals of the LC filter 38 are the input, ground, and output terminals, respectively made on the input board 9 of the power circuit of the active antenna device itelnoy ripple filtering on an input power supply circuit between the active antenna device LC-filter input and earth terminals 38 included additional capacitive filter component 44 (3b, 4), which is an electrolytic capacitor.

In the simplest embodiment, the LC filter 38 may be implemented as a single LC link 41 (not shown in FIGS. 1-6). In this case, the input, ground, and output terminals of the LC link 41 form the input, ground, and output terminals of the LC filter 38, i.e. input, ground and output terminals of the power circuit of the active antenna device.

Shaper 40 of the supply voltage for the active antenna device is placed on the carrier board 10 separately from the receiver-processor board 11 (Fig. 1). Its location is selected taking into account the convenience of installation / disassembly. The output characteristics of the supply voltage driver 40 for the active antenna device are selected based on the power characteristics of the active antenna device connected to this sample of the SRNS signal receiver unit. In practice, the supply voltage driver 40 for the active antenna device can be made in the form of a DC voltage converter, implemented, for example, on the DCIM DC converters integrated circuit by MAXIM [17]. The nomenclature range of these microcircuits is such that it allows you to generate any desired supply voltage for active antenna devices used in the technique of receiving signals from SRNS GLONASS and GPS. The input voltage to the supply voltage driver 40 for the active antenna device can, for example, be supplied through a voltage buffer converter located on the carrier board 10 (not shown in FIGS. 1-6).

The operation of the claimed unit of the receiver signals SRNS is as follows.

External peripheral devices for data processing and / or indication and an external power source are connected to the low-frequency block connectors 7 using the corresponding external low-frequency wire harnesses. In this case, the corresponding input voltages are supplied to the receiver-processor board 11 and the supply voltage driver 40 for the active antenna device.

An active antenna device is connected to the high-frequency block connector 8 using an external high-frequency coaxial cable. The design of the active antenna device can be any, for example, it can be a GLONASS / GPS antenna with a built-in amplifying element or a GLONASS / GPS antenna with a separate trunk antenna amplifier. The power characteristics of the active antenna device and the output characteristics of the driver 40 are consistent.

The voltage from the driver 40 is supplied to the input board 9 through the harness 39, and on the input board 9 passes through the LC filter 38 and is supplied to the contact element 22, which is the point of electrical association-separation of the input signal circuit and the power circuit of the active antenna device. From the contact element 22, the supply voltage for the active antenna device is supplied to the signal output 20 of the high-frequency block connector 8 and then, via an external high-frequency coaxial cable, to the active antenna device. In the opposite direction through an external high-frequency coaxial cable to the high-frequency block connector 8 received signals received by the active antenna device SRNS signals.

The SRNS signals received by the active antenna device, for example, GLONASS and GPS signals (frequency range from 1.2 to 1.7 GHz), from the signal output 20 of the high-frequency block connector 8 are supplied to the contact element 22 of the input board 9. From the contact element 22, the SRNS signals through the input printing conductor 34, the capacitor 31, and the signal conductor 33 of the microwave unbalanced microstrip line 32 to the central core 35 of the internal unit high-frequency coaxial cable 12, and then through the internal unit high-frequency coaxial cable b 12 and connectors 13 and 14 to the receiver-processor board 11.

The parameters of the capacitor 31, which performs the function of a filter element of the input signal circuit, and the parameters of an LC filter 38 connected to it by a Y-shaped circuit, which performs the function of a filter element of the power circuit of the active antenna device, are selected in such a way that efficient isolation is made on the input board 9 input signal circuit and power circuit of the active antenna device.

On the receiver-processor board 11, the SRNS signals undergo a private conversion with decreasing the frequency to tens of megahertz, analog-to-digital conversion, and then correlation and functional processing with the selection of the output information in the form of low-frequency digital signals (for example, in the RS-232, RS-422 format , RS-485 or otherwise). These digital signals are transmitted via bundles 15 to the corresponding terminals of the low-frequency block connectors 7, from where they are transmitted to peripheral devices.

Thus, in the inventive SRNS signal block, the receiver-processor board 11, which is the most complex and expensive part of the block, does not carry the function of generating a supply voltage for the active antenna device and the function of combining and separating the input signal circuit and the power circuit of the active amplifier device, which takes place in electronic blocks [13] and [14]. These functions are distributed between the supply voltage driver 40 for the active antenna device located on the carrier board 10 and the input board 9 mounted on the wall 5 of the housing 1 together with the high-frequency block connector 8. This decision makes the execution of the receiver-processor board 11 independent of the power characteristics active antenna device, which significantly expands the ability to configure consumer equipment, in particular the ability to use one type of unified receiver - a processor with various types of active antenna devices that differ in their power supply. In this case, the adaptation (by power) of a specific structural modification of the receiver array of the SRNS signals to a specific active antenna device is provided only by installing the appropriate driver 40 of the supply voltage for the active antenna device (“DC-DC Converters” chip), which does not present a problem. At the same time, the proposed implementation of an electrical circuit that implements the function of combining-separating the input signal circuit and the power circuit of the active antenna device on a separate input board 9 installed in the manner described above with direct contact with the high-frequency block connector 8 and with the wall 5 of the housing 1, provides elimination of spurious interference and induced noise while reducing losses in the input signal circuit when placing it outside the receiver-processor board a 11.

From the above it follows that the inventive SRNS signal receiver unit is feasible, industrially realizable and solves the technical task to create a design of the SRNS signal receiver unit, which ensures the independence of the receiver-processor used in it from the power characteristics of the connected active antenna device while eliminating spurious interference and induced interference, as well as reducing losses in the input signal circuit when placing it outside the receiver-processor board.

Sources of information

1. Global satellite radio navigation system GLONASS. Edited by V.N. Kharisova, A.I. Perova, V.A. Boldin. M., IPPR, 1998.

2. On-board devices of satellite radio navigation. / I.V. Kudryavtsev, I.N. Mishchenko, A.I. Volynkin et al., Ed. V.S. Shebshaevich, Moscow: Transport, 1988.

3. V.V. Shkiryatov. Radio navigation systems and devices. M .: Radio and communications, 1984.

4. US No. 5323168, H 01 Q 1/38, publ. 06/21/1994.

5. US No. 6198439 (B1), H 01 Q 1/38, publ. 03/06/2001.

6. US No. 5349365, H 01 Q 11/08, H 01 Q 1/36, publ. 09/20/1994.

7. US No. 6016128, H 01 Q 11/12, H 01 Q 7/00, H 01 Q 1/42, publ. 01/18/2000.

8. US No. 5272485, H 01 Q 23/00, H 01 Q 1/38, publ. 12/21/1993.

9. US No. 4853703, H 01 Q 1/38, publ. 08/01/1989.

10. US No. 5416712, G 01 S 5/02, G 06 F 15/50, H 01 Q 1/42, publ. 05/16/1995.

11. US No. 5402441, G 01 S 5/02, publ. 03/28/1995.

12. IP No. 7-128423, G 01 S 5/14, publ. 05/19/1995.

13. RU No. 2172081 (C1), H 05 K 1/00, 1/11, 1/14, 3/46, publ. 08/10/2001.

14. RU No. 2190941 (C1), H 05 K 1/00, publ. 10/10/2002.

15. RU No. 2172080 (C1), H 05 K 1/00, 1/11, 1/14, 3/46, publ. 08/10/2001.

16. RU No. 2188522 (C1), H 05 K 1/14, H 01 P 11/00, publ. 08/27/2002.

17. Electronic components, 2001, No. 4, p. 42.

Claims (4)

1. The receiver unit of the signals of satellite radio navigation systems, comprising a housing made of an electrically conductive material with connecting means installed thereon for connecting external devices, a receiver-processor board located inside the housing and connected to these connecting means, for frequency conversion and correlation processing of received active antenna device signals of satellite radio navigation systems (SRNS) received on the receiver board ka-processor via an in-block high-frequency coaxial cable, as well as means intended for combining-separating the input signal circuit and the power circuit of the active antenna device, containing filter elements of these circuits, characterized in that the means intended for combining-separating the input signal circuit and circuit power supply of the active antenna device, located on the input board mounted on the wall of the housing at the installation site of the high-frequency block connector, designed for the external high-frequency coaxial cable from an external active antenna device, the input board is made of structural material with a certain normalized value of the coefficient of dielectric constant, which makes it possible to realize on it a microwave asymmetric microstrip line for transmitting SRNS signals to an in-block high-frequency coaxial cable connecting the input board to the receiver board processor, on the first side of the input board there is an earthen plane, inside and which made a circle-free section in the form of a metallization, the diameter of which coincides with the diameter of the internal insulator of the high-frequency block connector, and in its center there is a metallized hole through which the signal output of the high-frequency block connector passes, on the second side of the input board there are contact pads, printed conductors , including the signal conductor of the specified microwave asymmetric microstrip line, and electrical elements of the electrical circuit that implements the input There is a circuit for combining-separating the input signal circuit and the power circuit of the active antenna device, the input board is fixed to the housing wall so that its ground plane is in electrical contact with the housing wall and the housing of the high-frequency block connector, and the signal output of the high-frequency block connector on the second side the input board is connected to the contact element, which is the point of electrical association-separation of the input signal circuit and the power circuit of the active antenna device, with This contact element is connected by its output terminal to the power circuit of the active antenna device, made on the input board, with its filter element, while its input and ground terminals are connected through a bundle to the output and ground terminals located inside the housing separately from the receiver-processor board of the power supply voltage shaper for the active an antenna device connected to the same contact element by its input printed conductor, an input signal circuit made on the input board, containing the filter element and the specified microwave asymmetric microstrip line are sequentially connected, while its output printed conductor is connected to the central core of the intra-unit high-frequency coaxial cable fixed to the input board so that it is electrically contacted from the shielding braid that is freed from external insulation and has a contact area with an electrical pad connection to the ground plane, and the specified connection of the Central core of the intra-unit high-frequency coaxial About the cable with the output printed conductor of the input signal circuit is carried out by the method of surface mounting. 2. The block according to claim 1, characterized in that the input board is made using a foil laminate as a structural material with a specific, selected in the range from 4.0 to 5.5, normalized dielectric constant, such as foil-coated epoxy fiberglass brand FR4 . 3. The unit according to claim 1, characterized in that the filtering element of the signal circuit is a capacitor mounted on the input board by surface mounting. 4. The block according to claim 1, characterized in that the filter element of the power supply circuit of the active antenna device is an LC filter made in the form of one or two series-connected L-shaped LC links, where the first leads of the inductive and capacitive components are connected , the second output of the capacitive component and the second output of the inductive component form the input, ground and output terminals of the LC link, respectively, and in the case of an LC filter in the form of one LC link, the input, ground and output terminals of this LC link they form the input, ground and output terminals of the LC filter, and in the case of an LC filter in the form of two series-connected LC links, the input and ground terminals of the first LC link and the output terminal of the second LC link form the input, ground and output terminals of the LC filter, while the input, ground, and output terminals of the LC filter are the input, ground, and output terminals of the active antenna device’s power supply circuit.

Images