RU2199839C1 - Radio-electronic unit - Google Patents

Abstract

FIELD: radio electronics; receiving and processing signals from satellite radio-navigation systems. SUBSTANCE: radio-electronic unit has printed-circuit board with N≥6 conducting layers; outer conducting layers carry printed conductors, contact pads, electric and radio components and connector for external devices; inner layers are used to dispose printed conductors. Electric and radio components are grouped in regions of which first one is region of electric and radio components designed for reception and frequency conversion of signals; second region is that of electric and radio components meant for digital processing of signals. First and second ground shielding areas provided in second and (N - 1) conducting layers relate to first region. Power area and third ground shielding area, each being made in respective inner conducting layer, relate to second region. Power conductors concentrated in i-th inner conducting layer, where 2 <i <N + 1, are made in the form of printed conductors fanning out from center in the form of equipotential flat disposed within first region. Fan- out center is connected to output lead of first power filter whose input lead is connected by means of separate printed conductor to output lead of second power filter which is also connected to power area related to second region, Ground sections connected through respective metallized holes of interlayer connections to first and second ground shielding areas are made on free surfaces of conducting layers 3 to (N + 1) in the first region. EFFECT: provision for eliminating stray pickups and induced noise with various types of components densely disposed on board and fed from common power supply. 4 cl, 9 dwg

Description

 The invention relates to electronics and can be used in the construction of blocks of electronic equipment, in particular radio electronic blocks, designed to receive and process signals from satellite radio navigation systems (SRNS).

 A feature of the design of radio-electronic units that receive and process SRNS signals is the need to use different types of functional elements and nodes — various analog microwave and RF devices that implement the processes of receiving and frequency conversion of input microwave signals, as well as various digital devices — correlators processors, interface converters operating at significantly lower frequencies and implementing digital signal processing operations, including correlation operations th search, tracking, and generate output signals representative of navigation information, necessary for the consumer [1, p.112, Fig.47; p.126, fig. 64].

 Since the design of the radio-electronic unit that receives, frequency converts, and digitally processes the input microwave signals, in particular the SRNS signals, must combine the indicated heterogeneous elements and nodes, the problem arises of their structural combination with the provision of electromagnetic compatibility in a tight arrangement within one designs. Since such a design problem does not have a generally accepted solution, when developing specific models of equipment, individual design decisions and techniques have to be applied.

 For example, the constructions of volume modules [2], [3], [4], in which microwave signals are received, converted, and digitally processed, are known. The basic design principle, implemented in [2], [3], [4], is that the functional units of the electrical circuit are performed on separate microcards. These microcards are installed, for example, in metal frames, and then assembled in the form of a package in the body of a volumetric integrated module. The electrical connections between the microboards are carried out by means of a patch board installed perpendicular to the ends of the microboards. The problems of electromagnetic compatibility in such designs are solved by performing microboards on the same type of elements operating at close frequencies, as well as, if necessary, inter-board shielding and the use of separate (micro-boards) power.

 In planar structures, for example, presented in [5, p. 51-50, Fig. 2.9; from. 70-71, Fig. 3.6], [6], the problems of electromagnetic compatibility are solved by placing microplates on which the functional units of the electrical circuit are made in the corresponding sockets of a monolithic metal base covered by a metal cover. The metal base is a supporting element in this design, and also serves as a screen. The placement of microboards in the slots separated from each other by a metal layer makes it possible in such designs to exclude the mutual influence of heterogeneous functional units of the electric circuit on each other, to eliminate spurious interference and induced interference. However, the use of a monolithic metal base with slots for accommodating microplates increases the mass and dimensions of the structure.

 Known electronic unit [7, p. 24, fig. 3,2], representing a planar structure in which microboards, on which separate functional units of the electric circuit are made, are mounted horizontally on the lower side of the carrier switching circuit board, on the upper side of which the remaining electrical components of the electric circuit are located. Micro-boards and radio-electronic elements on the carrier switching board are grouped by functional zones. The functional areas are separated by vertical shielding metal partitions, which are located on the upper side of the carrier switching board. Grouping by functional zones and separation of functional zones by external shielding partitions is a design technique that allows solving electromagnetic compatibility problems in this design (to eliminate the mutual influence of different types of functional nodes on each other, to eliminate spurious interference and induced interference). At the same time, the use of a circuit board as a common load-bearing element for microboards and electro-radio elements makes it possible to reduce the dimensions of this design in comparison with designs where microboards are located in the sockets of the metal base.

 Common to the considered designs is the use of functional units in them, made on separate microboards. Such a design technique corresponds to the design principle set forth, for example, in [5, p. 11-13], the essence of which is to unite structurally completed simple structural units into more complex ones. The attractiveness of this design technique is due to the ease of implementation of individual structural units. However, the payment for the benefits associated with such a constructive implementation of individual functional units is the inevitable increase in size and complexity of the design of the electronic unit as a whole.

 As a prototype of the claimed radio-electronic unit, a radio-electronic unit is adopted, described in [8], which solves the problem of constructively combining different types of functional units (analog microwave and high-frequency nodes, digital low-frequency nodes) with ensuring their electromagnetic compatibility in a tight arrangement on one multilayer printed circuit board.

 The electronic unit [8], adopted as a prototype, contains a printed circuit board with the number of conductive layers N≥6, in which the outer first and last (N-th) conductive layers are printed conductors, pads, radio electronic elements and connectors for external connections, and in the inner conductive layers - the remaining printed conductors of an electrical circuit designed for receiving, frequency converting and digital processing of signals, for example, the signals of the SRNS "GLONASS" and "GPS". Interlayer connections of printed conductors are carried out by means of metallized holes of interlayer connections.

 The radio-electronic elements placed on the printed circuit board are grouped into zones, the first of which is the zone of placement of radio-electronic elements intended for receiving and frequency conversion of signals, and the second is the zone of placement of radio-electronic elements intended for digital signal processing. In the first zone there is also a high-frequency connector designed to connect the receiving antenna, and in the second zone - a low-frequency connector designed to connect external devices.

 The first zone corresponds to the first and second shielding ground planes connected to each other by means of metallized holes of the interlayer connections, made in the inner second and penultimate (N-1) -th conductive layers adjacent to the outer first and last N-th conductive layers. The first zone in the prototype block also corresponds to the plane of the analog power supply, located in one of the inner conductive layers, free from the placement of shielding earth planes.

 The second zone corresponds to the third shielding earth plane and the digital power plane, each located in its own internal conductive layer. The third shielding earthen plane in the prototype block consists of separate earthen plots interconnected by earthen lintels. The plane of the digital power supply of the second zone in the prototype device also consists of separate sections of power, the connection between which is carried out, for example, from the outside through external power sources. The considered implementation of the third shielding earth plane and the digital power plane from separate sections follows from the principle adopted in the prototype unit for the principle of placing radio electronic elements of the second zone in functional sections, for which individual power and shielding are used. If this principle is rejected, i.e., when using the common (without division into sections) power supply, the third shielding earth plane and the digital power plane are performed without the specified division into sections.

 In the first zone, analog signals coming from the receiving antenna, for example, GLONASS and GPS signals with frequencies in the range from 1200 to 1700 MHz, are amplified, filtered out from interference and converted with lowering the carrier frequency using the corresponding analog and analog-to-digital functional nodes. In the second zone, the signals are subjected to multichannel correlation processing, processing in a digital processor and interface elements with the formation of output signals that carry navigation information for the consumer. In the process of processing, the signals pass sequentially from the first zone to the second, while in the first zone the signals pass sequentially from one functional node to another, and in the second zone from one functional section to another.

 The considered design solutions and techniques implemented in the prototype block allow solving the problem of electromagnetic compatibility, i.e. the task of eliminating spurious interference and induced interference and eliminating the mutual influence of heterogeneous (analog and digital) radio and electronic elements in the conditions of their placement on one printed circuit board. In this case, the greatest effect on eliminating spurious interference and induced interference is ensured when in the first zone the functional units of the electric circuit are arranged strictly linearly in accordance with the sequence of signal processing, and in the second zone the radio-electronic elements are placed territorially strictly in their functional areas - areas with individual power supply and shielding .

 Since in the prototype block the best result is ensured under the condition of individual supply of functional areas provided by several external power sources, this significantly narrows the scope of its possible application. In addition, the placement of electro-radio elements of the second zone is geographically strictly in terms of its functional areas - areas with individual power supply and shielding - increases the dimensions of the prototype unit, which also limits the scope of its possible application. In particular, these design features of the prototype unit do not allow it to be used in a "pocket" ("wearable") device, in which one external power source is used and in which strict requirements for minimizing the dimensions and tight placement of radio-electronic elements and printed conductors do not allow placing radio-electronic elements in the second zone, territorially strictly according to their functional areas with the provision of individual nutrition and shielding, and in the first zone it is not possible to arrange the functional nodes of the ele The circuit diagram is strictly linear in accordance with the sequence of signal processing.

 The technical problem to be solved by the claimed invention is directed is the elimination of spurious interference and induced interference under the indicated conditions of dense placement on the printed circuit board of various types of radio-electronic elements and the use of one external power source for their power supply.

 The essence of the invention lies in the fact that in a radio electronic unit containing a printed circuit board with the number of conductive layers N≥6, in which the outer first and Nth conductive layers are printed conductors, contact pads, electronic components and connectors for external connections, and in internal conductive layers - the remaining printed conductors of an electrical circuit designed for receiving, frequency conversion and digital signal processing, and interlayer connections of printed conductors are carried out by metalized holes of interlayer connections, the radio-electronic elements placed on the printed circuit board are grouped into zones, the first of which is the zone of placement of radio-elements used for receiving and frequency conversion of signals, and the second is the zone of placement of radio-elements used for digital signal processing, the first zone corresponds to each other with the other, through the metallized holes of the interlayer connections, the first and second shielding earthen planes, respectively about in the inner second and (N-1) -th conductive layers adjacent to the outer first and Nth conductive layers, and the second zone corresponds to the power plane and the third shielding earth plane, each made in its own inner conductive layer, in contrast to the prototype in the first zone, power conductors concentrated in the inner ith conductive layer, where 2 <i <N-1, are made in the form of printed conductors diverging by rays from a branching unit located within the boundaries of the first zone and representing an equipotential area the center of the branching unit is connected through the corresponding metallized hole of the interlayer connections to the output terminal of the first power filter, the ground terminal of which is connected to the first and second shielding ground planes, and the input terminal is connected via a separate printing conductor to the output terminal of the second power filter, input and ground terminals which are connected respectively to the contact elements "Power" and "Earth", designed to supply voltage to the circuit board from an external power source, moreover, all indicated earth shields are connected to the Earth contact element, and to the output terminal of the second power filter is also the power plane belonging to the second zone, while in the internal from the third to (N-2) -th conductive layers on areas that remain within the boundaries of the first zone free from the placement of printed conductors, metallized holes of interlayer connections not subject to grounding, and the specified branching unit, earthen sections, connections are made through the corresponding metallized holes of the interlayer connections with the first and second shielding earthen planes, at least in the places where the earthing leads of the corresponding electro-radio elements of the first zone are connected to them.

 In preferred embodiments having practical application, the connection of the Earth contact element with the first and second screening earth planes is carried out through the third screening earth plane, which is made in one inner conducting layer with the first or second screening earth plane and connected to it by means of an earth bridge , the first power filter is made in the form of a pass-through noise suppression filter, and the second power filter is made in the form of a pass-through noise-canceling con the denser.

 The essence of the invention, its feasibility and the possibility of industrial application are illustrated by the example of the design of the radio electronic unit, which acts as a navigation receiver-processor of the SRNS GLONASS and GPS signals and is implemented on a printed circuit board with N = 6 conductive layers. Drawings illustrating in this example the design features of the claimed radio electronic unit, explaining the essence of the invention, are presented in figures 1-9.

In FIG. 1 shows a sectional view of the printed circuit board in the considered example of its implementation with six conductive layers (the location of the printed conductors and metallized holes of the interlayer connections is conventional, the radio and radio elements are not conventionally shown);
in FIG. 2 is an example illustrating grouping by zones of electro-radio elements located in the outer first conductive layer (view from the side of electro-radio elements, printed conductors are conventionally not shown);
in FIG. 3 is an example illustrating the grouping by zones of electro-radio elements located in the outer sixth conductive layer (view of the “transparency” from the side of the outer first conductive layer, the layers are conditionally transparent, the printed conductors are not conventionally shown);
in FIG. 4 - an example of a print pattern of the inner second conductive layer (view "on the gap" from the side of the outer first conductive layer, the layers are conditionally transparent);
in FIG. 5 is an example of a print pattern of the inner third conductive layer (view of the “transparency” from the side of the outer first conductive layer, the layers are conditionally transparent);
Fig.6 is an example of a print pattern of the inner fourth conductive layer (view "on the gap" from the side of the outer first conductive layer, the layers are conditionally transparent);
in FIG. 7 is an example of a print pattern of the inner fifth conductive layer (view of the "transparency" from the side of the outer first conductive layer, the layers are conditionally transparent);
in FIG. 8 is a fragment of the print pattern of the outer first conductive layer, explaining in this example the location of the contact elements "Power" and "Earth" from an external power source (radio elements conventionally not shown);
in FIG. 9 is a fragment of a functional electrical circuit explaining the principle of power wiring in the considered example of the implementation of the electronic unit.

 The inventive electronic block contains a printed circuit board 1 (in this example, a six-layer) with the outer first 2 and sixth 3 conductive layers, with an inner second 4, third 5, fourth 6 and fifth 7 conductive layers. The inner conductive layers 4, 5, 6 and 7 are separated from each other and from the outer conductive layers 2 and 3 by insulating layers 8 (Fig. 1).

 In the outer conductive layers 2 and 3 are placed (FIGS. 1, 2, 3) pads 9, printed conductors 10 and electro-radio elements 11, as well as high-frequency 12 and low-frequency 13 connectors for external connections, which are structural elements of the receiving electrical circuit, the frequency signal conversion and digital processing - in this case, the GLONASS and GPS GPS signals. In the inner conductive layers 4, 5, 6, and 7, printed conductors are placed (FIGS. 4-7). Interlayer connections of the printed conductors are carried out by means of the corresponding metallized holes 14 of the interlayer connections (in Fig. 1, the performance of the metallized holes 14 of the interlayer connections is shown conditionally). In the case when the metallized holes of the interlayer connections must pass through the printed conductors without electrical contact with them, the corresponding windows are deprived of metallization in these conductors.

 The electro-radio elements 11 located on the printed circuit board 1 are grouped into two zones 15 and 16 (Figs. 2, 3, 8), while the first zone 15 is a zone for the placement of electro-radio elements intended for receiving and frequency conversion of signals, and the second zone 16 is a zone placement of electronic components intended for digital signal processing. In the first zone 15 is also placed high-frequency connector 12 (for example, type SMA or SMB), designed to connect a receiving antenna. In the second zone 16 is also placed a low-frequency connector 13 (for example, plug 828430 AMP), designed to connect external devices, including an external power source.

 The first zone 15 is a zone in which the reception and frequency conversion of input signals is carried out - broadband analog microwave signals SRNS "GLONASS" and "GPS", as well as their analog-to-digital conversion. In the first zone 15, with the help of electro-radio elements, as well as due to the corresponding topology, strip lines, microwave bandpass filters, low-noise microwave amplifiers, mixers, bandpass filters based on surface acoustic waves, frequency synthesizers, a reference oscillator, and analog-to-digital comparators. The radio elements of the first zone 15 are mainly capacitors, resistors, microcircuits. Typical microcircuits of the first zone 15 are, for example, microchips of the type MGA-87563 from HEWLETT-PACKARD (USA) or MAAM 12021 M / A COM of the company MOTOROLA (USA) (low-noise microwave amplifiers), microcircuits of the type LMX2330ATM from MOTOROLA (USA) (synthesizers frequencies), chips of the UEC2753 type from NEC (USA) (signal converters and amplifiers), chips from the type MC13142D from Motorola (USA) (mixers), chips from the TXO255AR type 10.00 MHz, 3V from RAKON (USA) (reference generator), chips type MAX962ESA company MAXIM (USA) (comparators). With the exception of the high-frequency connector 12, the radio-electronic elements located in the first zone 15, including microcircuits, belong to the V generation elemental base intended for surface mounting. Technique (technology) of surface mounting [9, p. 107-110], used in the inventive electronic unit, allows you to realize the maximum density of the layout with the minimum dimensions of the printed circuit board 1.

 The second zone 16 is a zone where multichannel correlation processing of signals coming from the first zone 15, the calculation of navigation data and the conversion of the interface. The electro-radio elements of the second zone 16 are mainly capacitors, resistors, microcircuits. Typical microchips of the second zone 16 are, for example, microchips of the type 1836VZh1, 1836VZh1-01 (Russia) or ASIC (Korea "SAMSUNG" - Russia "KOTLIN") (correlator), microchips of the type TMS320LC203PZA or TMS320VC5410PGE from TEXAS INSTRUMENTS (USA) , chips like KM616V1002ATI-15 of SAMSUNG firm (Korea) (memory), chips like MAXIM 3223EAR firm MAXIM (USA) (interface converters). With the exception of the low-frequency connector 13, the electric radio elements located in zone 16, including microcircuits, belong to the fifth-generation elemental base intended for surface mounting.

 In this example, the implementation of the inventive electronic block of the first zone 15 corresponds to the first 17 and second 18 shielding earth planes made in the inner second 4 and penultimate (fifth) 7 conductive layers adjacent to the outer first 2 and last (sixth) 3 conductive layers. The first 17 and second 18 shielding earthen planes (Fig. 4, 7) are interconnected by the corresponding metallized holes of the interlayer connections, located, in particular, along their perimeter.

 The second zone 16 corresponds to the supply plane 19 and the third shielding earthen plane 20, each made in its own inner conductive layer. In this example, the supply plane 19 is made in the inner second conductive layer 4 (FIG. 4), and the third shielding ground plane 20 is made in the inner fifth conductive layer 7, i.e. in the same inner conductive layer as the second shielding earth plane 18 (Fig. 7).

Power conductors 21, which serve to power the electro-radio elements of the first zone 15, are concentrated in the inner ith conductive layer, where 2 <i <N-1, that is, between the inner second and penultimate (fifth) conductive layers 4 and 7. In the considered As an example, the power conductors 21 are made in the inner third (i = 3) conductive layer 5 (Fig. 5). The power conductors 21 are made in the form of printed conductors, diverging rays from the branching unit 22, located within the boundaries of the first zone 15 and representing an equipotential area. On the areas of the area remaining in the inner third conductive layer 5 within the boundaries of the first zone 15 free from the location of the branching unit 22, the power conductors 21 and the metallized holes of the interlayer connections not subject to grounding, earthen sections 23 _{1 are made} (Fig. 5). On the areas of the area remaining in the inner fourth conductive layer 6 within the boundaries of the first zone 15 free from the placement of printed conductors and metallized holes of the interlayer connections not subject to grounding, earthen sections 23 _{2 are made} (Fig. 6). Earthen sections 23 ₁ and 23 ₂ are connected through the corresponding metallized holes of the interlayer connections to the first 17 and second 18 shielding earthen planes - at least in the places where the earth terminals of the corresponding electro-radio elements of the first zone 15 are connected to them.

 The center of the branching assembly 22 (FIG. 5) is connected by means of a corresponding metallized hole of the interlayer connections to the output terminal 24 of the first power filter 25 (FIGS. 2, 9).

 In this example, the first power filter 25 is located on the outer first conductive layer 2 (Fig. 2) and is made in the form of a pass-through noise suppression filter - an electro-radio element consisting of a tubular ceramic capacitor and a coilless inductor [10, p.236-240, Fig.5.9] that implements the function of a U-shaped or T-shaped LC filter with an inductive component in the longitudinal arm (in this example, the function of a T-shaped LC filter). In practice, the NFM61T series pass-through filter MURATA (USA), designed for surface mounting and realizing the function of a T-shaped LC filter, can be used as the first power filter 25.

 In this example, an additional capacitive component 27 is made parallel to the output terminal 24 and the ground terminal 26 of the first power filter 25, made in the form of two capacitors connected in parallel (Fig. 2, 9), one of which is a high-frequency filter capacitor, for example, ceramic type X7R- 16V-0,1μF, s.0603 ... s.1206, and the other is a low-frequency electrolytic capacitor, for example, tantalum type B45196-N-2227-K509-10V-220μF or oxide-semiconductor type K-53-22.

 The ground terminal 26 of the first power filter 25 is connected through the corresponding metallized holes of the interlayer connections with the first 17 and second 18 shielding earth planes (Figs. 4, 7, 9).

 The input terminal 28 of the first power filter 25 is connected to the output terminal 30 of the second power filter 31 by means of the corresponding metallized hole of the interlayer connections and a separate printed conductor 29 made in the example in the inner second conductive layer 4 (Fig. 4). , 9).

 With the output terminal 30 of the second power filter 31 is also connected to the power plane 19 (Fig.4, 9).

 The second power filter 31, like the first power filter 25, is located on the outer first conductive layer 2 (FIG. 2). In this example, the second power filter 31 is made in the form of a pass-through noise suppression capacitor. The design of the pass-through noise-suppressing capacitor (one lining is connected to the current-carrying wire between the input and output terminals, and the second to the ground terminal) ensures the constant capacitance in a wide frequency band [10, p.238-239, Fig. 5.8]. In practice, in the inventive radio-electronic unit, a NFM41R series pass-through noise suppression capacitor manufactured by MURATA (USA) intended for surface mounting can be used as the second power filter 31.

 The input 32 and ground 33 conclusions of the second power filter 31 are connected respectively to the contact elements 34 and 35 "Power" and "Earth", designed to supply voltage to the printed circuit board from an external power source (Fig.9). In this example, the contact elements 34 and 35 "Power" and "Earth" are the contact pads with metallized holes of the interlayer connections, which solder the corresponding pin terminals of the low-frequency connector 13, designed to connect an external power source (Fig.7, 8). The connection of the input terminal 32 of the second power filter 31 with the contact element 34 "Power" is carried out in the outer first conductive layer 2 by a short and wide printed conductor 36 (Fig, 9). The connection of the ground terminal 33 of the second power filter 31 with the contact element 35 "Earth" is carried out through the corresponding holes of the interlayer connections connected in the inner fifth conductive layer 7 with the third shielding earth plane 20 in the area 37 near the junction of it with the contact element 35 "Earth" (Fig .7, 9).

 In addition to the indicated connection of the third shielding earth plane 20 with the contact element 35 "Earth", the first 17 and the second 18 shielding earth planes are also electrically connected to it. The connection of the contact element 35 "Earth" with the first 17 and second 18 shielding earth planes is carried out through the third shielding earth plane 20 as follows. The first shielding earth plane 17 is connected to the second shielding earth plane 18 by means of metallized holes of the interlayer connections, and the second shielding earth plane 18 is connected to the third fifth shielding earth plane 20 located in the same inner conducting layer 7 by means of the earth bridge 38 (Fig. 7) .

 To include the inventive radio-electronic unit, which in the example under consideration, performs the function of a navigation receiver-processor of the GLONASS and GPS signals, a receiving antenna is connected to the high-frequency connector 12, and an external power source and other necessary for the electronic work to the low-frequency connector 13 external devices, for example, registration and control means (not shown in the figures).

 The voltage supplied from an external power source to the contact elements 34 and 35 "Power" and "Earth", at the very beginning of its distribution in zones 15 and 16 is filtered from high-frequency components and interference using a second power filter 31. The second power filter 31 carries out short-circuiting of the high-frequency components of the input supply voltage to the ground of the power source, thereby preventing the propagation of high-frequency pickups to the functional units and radio-electronic components of the electronic unit. The supply voltage thus filtered is supplied to the second 16 and first 15 zones.

 In the second zone 16, the supply voltage is supplied using the supply plane 19 and the third screening ground plane 20. In this case, the supply voltage of the potential "Power" comes to the supply plane 19 from the output terminal 30 of the second power filter 31, and the supply voltage to the third screening ground plane 20 potential "Earth" comes from the contact element 35 "Earth".

 In the first zone 15, the supply voltage is supplied as follows. From the output terminal 30 of the second power filter 31, the voltage supply of the potential "Power" is supplied to the center of the branch node 22 of the power wires 21 - first, through a separate printed wire 29, which is not structurally connected to the power plane 19, and then through the first power filter 25. The power voltage of the potential “Earth” enters the second screening earth plane 18 from the third screening earth plane 20 through the earth bridge 38. The voltage of the potential of the “Earth” potential arrives at the first screening earth plane 17 emit from the second shielding earth plane 18 - through the corresponding metallized holes of the interlayer connections. From the power conductors 21 and the interconnected first 17 and second 18 shielding earth planes, the voltage supply potentials "Power" and "Earth" is supplied to the electrical elements of the first zone 15 through the corresponding metallized holes of the interlayer connections. In this case, the first power filter 25 filters the high-frequency components of the supply voltage propagating along the printed conductor 29 from the side of the second zone 16, and also filters the high-frequency components propagating inside the first zone 15 along the power conductors 21 to the ground.

Thus, in the inventive radio-electronic unit, an effective high-frequency isolation of the power supply circuits of the first 15 and second 16 zones is provided, and within the first zone 15 the power supply circuits of electro-radio elements, which minimizes the mutual influence of electro-radio elements of both zones on each other along the power supply circuits. The screening effect of the ground planes 17, 18, 20 and the ground sections 23 ₁ , 23 ₂ also contributes to minimizing the mutual influence of electro-radio elements on each other (along with the high-frequency isolation of the power supply circuits of the first 15 and second 16 zones). The positive role of the shielding earth planes 17, 18, 20 and the earth sections 23 ₁ , 23 ₂ in addition to the effect of plane shielding is also to provide optimal current paths that meet the requirements of minimum inductance, which eliminates losses in the return circuits of the signal paths and reduces their susceptibility to exposure emissions and crosstalk. All this ensures the elimination of spurious interference and induced interference under the considered conditions of using one external power source and a dense arrangement of electrical radio elements and printed conductors, when it is not possible to fully realize the principles of linear placement of electronic radio elements, functional units and printed circuit conductors in accordance with the sequence of processing .

 Powered in the manner described above, the radio elements of the first 15 and second 16 zones carry out the required operations for receiving, frequency converting and digitally processing the GLONASS and GPS signals, generating output signals that carry navigation information to the consumer. In this case, the input signals, which are broadband microwave signals - the GLONASS and GPS signals with frequencies in the range from 1200 MHz to 1700 MHz, pass through the high-frequency connector 12 to the first zone 15, where they are amplified, filtered from interference , frequency conversion with lowering the carrier frequency to tens of megahertz and analog-to-digital conversion. When converting signals, heterodyne and clock signals generated by synthesizers and frequency shapers located in the first zone 15 are used. Next, the signals are sent to the second zone 16, where multichannel correlation processing, processing in a digital processor and interface elements with the formation of output low-frequency signals carrying navigation consumer information. The output low-frequency signals are removed from the corresponding terminals of the low-frequency connector 13.

 Thus, the totality of the proposed design measures allows us to solve the technical problem in the inventive radio electronic unit to eliminate spurious interference and induced noise in the given conditions of a dense arrangement of different types of radio electronic elements and printed conductors on a printed circuit board that uses one external power source for its power.

 The experiments conducted on the electronic blocks of the claimed design with the above-considered elemental base showed that the elimination of spurious pickups and induced interference required from the conditions for ensuring operability in processing the GLONASS and GPS GPS signals can be realized when the electronic block is printed boards with overall dimensions (width and length) 45 • 95 mm and less.

 From the above it follows that the claimed radio-electronic unit is technically feasible, industrially feasible, solves the stated technical problem and has prospects for widespread practical use, including in the construction of small-sized ("pocket") equipment for SRNS signal consumers.

Sources of information
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 10. A. D. Knyazev. Elements of the theory and practice of ensuring electromagnetic compatibility of electronic equipment. M., Radio and Communications, 1984.

Claims (4)

 1. A radio electronic unit comprising a printed circuit board with a number of conductive layers N≥6, in which printed conductors, contact pads, radio electronic elements and connectors for external connections are placed in the outer first and Nth conductive layers, and the remaining printed conductors in the inner conductive layers an electrical circuit for receiving, frequency converting and digitally processing signals, the interlayer connections of the printed conductors being made through the metallized holes of the interlayer soy voltages, radio-electronic elements placed on a printed circuit board are grouped into zones, the first of which is a zone for placing radio-electronic elements used for receiving and frequency conversion of signals, and the second is a zone for placing radio-electronic elements serving for digital signal processing, the first zone is connected to each other by metallized holes of interlayer connections, the first and second shielding earth planes, made respectively in the inner second and (N-1) th conductive with oyah adjacent to the outer first and Nth conductive layers, and the second zone corresponds to the power plane and the third shielding earth plane, each made in its own inner conductive layer, characterized in that in the first zone the power conductors concentrated in the inner i-th conductive the layer where 2 <i <N-1 is made in the form of printed conductors diverging by rays from a branching unit located within the boundaries of the first zone and representing an equipotential area, the center of the branching unit is connected by by means of the corresponding metallized hole of the interlayer connections with the output terminal of the first power filter, the ground terminal of which is connected to the first and second screening ground planes, and the input terminal is connected via a separate printing conductor to the output terminal of the second power filter, the input and ground terminals of which are connected respectively to contact elements "Power" and "Earth", designed to supply voltage to the circuit board from an external power source, and with all the indicated shielding earthen planes are connected with the actuation element "Earth", and with the output terminal of the second power filter - also the power plane belonging to the second zone, while in the inner from the third to (N-2) -th conductive layers in the areas, remaining within the boundaries of the first zone free from the placement of printed conductors, metallized holes of interlayer connections not subject to grounding, and the specified branching unit made earthen sections connected by means of appropriate metal ized holes feedthroughs having first and second shielding earthen planes at least in places connecting thereto electronic components corresponding earth terminals of the first zone.  2. The electronic unit according to claim 1, characterized in that the connection of the contact element "Earth" with the first and second shielding earth planes is carried out through the third shielding earth plane, which is made in one inner conducting layer with the first or second shielding earth plane and connected to her through an earthen jumper.  3. The radio-electronic unit according to claim 1, characterized in that the first power filter is made in the form of a pass-through noise suppression filter.  4. The radio-electronic unit according to claim 1, characterized in that the second power filter is made in the form of a pass-through noise suppressing capacitor.

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