RU2125775C1 - Radio electronic assembly - Google Patents

Abstract

FIELD: radio engineering, in particular, design of electronic equipment for receiving and processing signals of satellite navigation systems. SUBSTANCE: device has multilayer printed circuit board, which has N conducting layers (6 or more). First and N-th conducting layers carry contact terminals and radio elements. Ground wires and power supply wires are located on different inner conducting layers and are designed as metal-coated strips which openings around metal-coated holes in connections between layers. Radio elements are grouped into M functional regions, one of which is functional region for analog elements, other functional regions are designed for digital elements. All M functional regions on outer first and N-th conducting layers contain signal wires of these regions. Functional region for analog elements has ground strips for this region on two inner layers of printed circuit board (second and (N-1)-th). Analog power supply strip is located in one of inner conducting layer which is adjacent to second or (N-1)-th layer. In all M-1 functional regions for digital elements, one of inner conducting layers of printed circuit board, which is adjacent to first or N-th outer conducting layer, contains separate ground strip of respective functional regions. One of inner conducting layers of printed circuit board, which is split by at least one conducting layer from layer with ground strips of functional regions of digital elements contains separate isolated strips for digital power supply of these regions. Strips for power supply of analog and digital functional regions do not overlap in vertical direction. Each of M functional regions has contact terminals for connection to external power supply separated according functional regions. Said contact terminals are located on one of external conducting layers of printed circuit board and are connected to corresponding power supply strips of these functional regions. Electrical connections between M functional regions are achieved by means of signal conductors, which are designed as straight line printed conductors, which are located on external conducting layer which is adjacent to inner conducting layer, in which ground strips of all M functional regions are located. Signal conductors are connected to between contact terminals, which are located on edges of respective functional regions. Ground strips of all M functional regions which are located in inner conducting layer, which is adjacent to external conducting layer with signal conductors, are connected by means of straight line ground by-passes, which are located under signal conductors and have width of at least 1mm. EFFECT: decreased parasitic induction and noise in cases when printed circuit board carries functional elements which have different functions, differ in integration level and operating with signals of different frequencies. 8 dwg

Description

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

 A feature of the design of electronic blocks that receive and process signals from the SRNS and CCC is the need to use heterogeneous functional units in them; various analog superhigh-frequency (microwave) and high-frequency (HF) circuits that implement the processes of receiving and converting noise-like radio signals СРСН and ССС, as well as various digital devices - correlators, synthesizers, synchronizers, processors that implement the processes of correlation search, tracking and digital processing of received signals, see, for example, [1, p. 112, fig. 47; p.126, fig. 64]. At the same time, in the practical implementation of such radio-electronic blocks, electro-radio elements having a different degree of integration, for example, discrete electro-radio elements, microcircuits of small, medium and large degree of integration, may be required. In connection with the combination of the indicated heterogeneous functional units and elements within the same design, which also work with signals significantly differing in frequency, the problem arises of ensuring their electromagnetic compatibility, eliminating mutual influence on each other and reducing the level of spurious interference and induced noise.

 One of the known ways of constructing a solution to this problem is the development of a multi-block (multi-board) design, where on separate printed circuit boards are grouped electrical elements related to close (homogeneous) functional groups that use signals that are similar in type and frequency, as, for example, in known designs [1, with. 112, fig. 47], [2]. At the same time, the problems of reducing spurious interference and induced interference are solved by fairly simple technical means, based, in particular, on board to film adaptation. It is obvious, however, that such a path is associated with an increase in the overall dimensions of the structure under development.

 In those cases where weight and size characteristics are important, monoblock designs are developed that combine heterogeneous functional units and elements within a single electronic block, such as in the radio-electronic block of a receiver-processor of SNRS signals described in [1, p. 132, fig. 69]. To solve the problems associated with spurious interference and induced interference, well-known design methods can be used, which include, in particular, installing additional external matching elements connecting the printed circuit board elements to the block body, such as [3], in a special arrangement signal conductors on a printed circuit board, as for example in [4], [5, p. 112 - 115], in a special arrangement of earth conductors and power conductors, as for example in [5, p. 113-114]. The result achieved by reducing spurious interference and induced noise is the higher, the smaller the difference between the frequencies of the signals processed in the block, and the higher the degree of integration of the radio-electronic elements of the block.

 As a prototype of the inventive radio-electronic unit, a well-known radio-electronic unit is described, described in [6, p. 258 - 261, fig. 12.2], which is a single-board design. The electronic block selected as a prototype contains a multilayer printed circuit board with the number of conductive layers N ≥ 6, in which on the outer first and Nth conductive layers of the printed circuit board there are contact pads and radio-electronic elements, and signal printed conductors, power conductors and earth conductors are located in the inner conductive layers of the circuit board. In this case, earth conductors (potential conductors "Earth") and power conductors (conductors of potentials "Power") are located in different internal conductive layers of the printed circuit board, for example, in the fourth and fifth layers, respectively, for the case of a ten-layer (N = 10) printed circuit board. In this case, earth conductors and power conductors are made in the form of metallized earth planes and power planes with windows around metallized holes of interlayer connections not connected with these planes.

 This design of the prototype unit allows you to solve the problem of reducing spurious interference and induced noise in conditions when it uses homogeneous electro-radio elements and close-frequency signals, such as in the case of a digital computer.

 The technical problem to which the claimed invention is directed is to eliminate spurious interference and induced interference under conditions when heterogeneous functional elements of varying degrees of integration are placed on the multilayer printed circuit board of the electronic unit, working with signals of various frequencies, for example, with frequency signals from thousands of megahertz to units as in receiver-processors SRNS and CCC.

 The solution of this problem allows us to design small-sized electronic equipment, including on-board receivers-processors operating on the basis of the GLONASS and NAVSTAR SNRS signals, based on the elemental base represented by electric and radio elements that differ significantly in the degree of integration.

 The essence of the invention lies in the fact that in a radio-electronic unit containing a multilayer printed circuit board with the number of conductive layers N ≥ 6, in which on the outer first and Nth conductive layers are placed contact pads and radio-electronic elements, and ground conductors and power conductors are located in different internal conductive layers of the printed circuit board and are respectively made in the form of metallized earth planes and power planes with windows around the metallized holes of the interlayer connections not electrically connected by these planes, the radio-electronic elements placed on the printed circuit board are grouped according to M functional zones, one of which is the functional zone of the analogue radio-electronic elements, and the remaining M-1 zones are the functional zone of the digital radio-electronic elements, while in all M zones of the functional placement of analogue and digital on the outer first and Nth conductive layers of the printed circuit board are the signal conductors of these fibers, in the area of functional placement of analogues ground radio planes in two internal conductive layers of the printed circuit board - the second and (N-1) -th conductive layers adjacent to the outer first and N-th conductive layers, there are earthen planes of this zone, and the plane of the analogue power supply of the functional placement zone of analogue radio-electronic elements is located in one of the internal conductive layers of the printed circuit board adjacent to the second or (N-1) -th conductive layer in all M-1 zones of the functional placement of digital electro-radio elements in one of the internal conductive layers Separate earthen planes of the respective zones of the functional placement of digital electronic radio elements are located on the printed circuit board adjacent to the first or Nth outer conducting layer, and in one of the inner conducting layers of the printed circuit board, separated by at least one conductive layer from the indicated conducting layer with earth planes zones of the functional placement of digital electro-radio elements, separate, not horizontally touching each other, digital power planes of these zones are located, etc. this, the power planes of the corresponding zones of the functional arrangement of the analog and digital electro-radio elements do not overlap vertically, in each of the M zones of the functional arrangement of the analog and digital electro-radio elements on one of the outer conductive layers of the printed circuit board, contact elements connected to the respective power planes of these zones are made for connection to external sources power supply when the unit is separated by functional zones for power supply, electrical connections between M zones The functional placement of analog and digital radio electronic elements is carried out by means of communication signal conductors made in the form of direct printed conductors located on the outer conductive layer of the printed circuit board adjacent to the inner conductive layer, in which the ground planes of all M zones of the functional placement of analog and digital radio and electronic elements are located, while communication signal conductors are laid between contact points located on the edges of the corresponding functional zones the placement of analog and digital electro-radio elements, and the interconnection of the ground planes of all M zones of the functional placement of analog and digital electro-radio elements located in the inner conductive layer adjacent to the outer conductive layer carrying the communication signal conductors is carried out by means of direct printed earthen wires located under the communication signal conductors jumpers at least 1 mm wide.

 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 of the receiver-processor, designed to determine navigation parameters from the signals GLONASS and NAVSTAR, using a multilayer printed circuit board with six conductive layers (N = 6) . The invention is illustrated by the drawings shown in FIG. 18.

In FIG. Figure 1 shows an example of a grouping of five (M = 5) functional zones of the electric radio elements of the outer first (front) layer of the six-layer printed circuit board of the radio-electronic block of the SNRC receiver-processor (view from the side of the elements of the first layer, printed conductors are not shown conventionally);
in FIG. 2 - an example of grouping of the outer sixth (back) layer of the printed circuit board of the SRNS receiver-processor according to the corresponding functional zones of the electric radio elements (view from the side of the first layer, conditionally transparent layers, printed conductors are not conventionally shown);
in FIG. 3 - view of a six-layer printed circuit board in size (arrangement of conductors and metallized holes of interlayer connections - conditional);
in FIG. 4 - an example of the location of the printed conductors, including signal communication conductors, on the outer first conductive layer of a six-layer printed circuit board of the receiver-processor SNRS;
in FIG. 5 - an example of the location of the printed conductors in the inner second conductive layer of the six-layer printed circuit board of the SNPC receiver-processor (view from the side of the first layer, the layers are conditionally transparent);
in FIG. 6 - an example of the location of the printed conductors in the inner third conductive layer of the six-layer printed circuit board of the CHRS receiver / processor (view from the side of the first layer, the layers are conditionally transparent);
in FIG. 7 - an example of the location of the printed conductors in the inner fourth conductive layer of a six-layer printed circuit board of the SRNS receiver-processor (view from the side of the first layer, conditionally transparent);
in FIG. 8 - an example of the location of the printed conductors in the inner fifth conductive layer of the six-layer printed circuit board of the CHRS receiver / processor (view from the side of the first layer, the layers are conditionally transparent).

 The inventive electronic block in this example implementation contains a multilayer printed circuit board 1 with the number of conductive layers N = 6, the outer first conductive layer 2 of which forms the front side of the circuit board 1, and the outer sixth conductive layer 3 - the back side of the printed circuit board 1. Internal conductive layers of the printed circuit board boards 1, namely, the second conductive layer 4, the third conductive layer 5, the fourth conductive layer 6 and the fifth conductive layer 7 of the circuit board 1 are separated from each other and from the outer conductive layers 2 and 3 by insulating layers and 8. On the outer conductive layers 2 and 3 of the printed circuit board 1, there are external printed circuit board elements - contacting pads 9 and signal conductors 10, as well as electrical radio elements 11. The necessary connections between the printed elements located in the various conductive layers of the circuit board 1 are carried out with using metallized holes 12 interlayer connections.

 In the considered example of the implementation of the radio-electronic unit - the receiver-processor unit of the SRNS, the radio elements 11 located on the printed circuit board 1 are grouped according to M = 5 functional zones 13, 14, 15, 16 and 17. The first of the M functional zones - functional zone 13 is a functional zone placements of analogue electric radio elements, and the remaining M-1 zones - the second, third, fourth and fifth functional zones 14, 15, 16, 17 are zones of the functional placement of digital electronic radio elements. In the first functional zone 13, there are electro-radio elements involved in analogue conversion of SRNS signals, for example, low-integration electro-radio elements similar to MGA-87563 HEWLETT-PACKARD type micro-radio elements, medium-integration electro-radio elements similar to 174XA5 type microcircuits; in the second functional zone 14 there are electro-radio elements performing multichannel correlation signal conversion, for example, ultra-high integration electro-radio elements, similar to microcircuits of the type 1836ВЖ1, 1836ВЖ1-01; in the third functional zone 15 there are electro-radio elements forming a reference generator, for example, medium-integration electro-radio elements similar to Tempus-LVA Motorola type microcircuits, high-integration electro-radio elements similar to Motorola LMX2330ATM microcircuits; in the fourth functional zone 16 there are electro-radio elements forming a digital processor, for example, highly integrated electro-radio elements similar to chips of the type TMC320C203P Texas Instruments; in the fifth functional zone 17, there are interface electro-radio elements, for example electro-radio elements of medium degree of integration, similar to microcircuits of the MAX533ACEE MAXIM type.

 For all zones 13 - 17 of the functional arrangement of analog and digital radio electronic elements, it is common that the signal conductors 10 of these zones are located on the outer first 2 and sixth 3 conductive layers of the circuit board 1.

 Common to all functional zones 13-17 is also the implementation of their earth conductors and power conductors in the form of corresponding metallized earth planes and power planes and their placement in different internal conductive layers of the circuit board 1. Moreover, in terms of the placement of earth and power planes in layers printed circuit board 1 there is a difference between the zone 13 of the functional placement of the analogue radio electronic elements and the zones 14, 15, 16, 17 of the functional location of the digital electronic radioelements. So, in the zone 13 of the functional placement of analogue electro-radio elements in two inner conductive layers of the printed circuit board 1 - in the second conductive layer 4 (Fig. 5) and the fifth conductive layer 7 (Fig. 8) adjacent to the outer first 2 and sixth 3 conductive layers, the corresponding earthen planes 18 and 19 of this zone are located. The plane of the analog power supply of zone 13 can be located in one of the inner conducting layers of the printed circuit board 1 adjacent to one of the above conducting layers, bearing one of the ground planes of this zone. In the considered example of the implementation of the radioelement unit, the analog power supply plane 20 of zone 13 is located in the third conductive layer 5 of the printed circuit board 1 (Fig. 6) adjacent to the second conductive layer 4 carrying the earth plane 18 of the zone 13. The remaining printed conductors 21 of the zone 13 are located in the fourth conductive layer 6 (Fig. 7) of the printed circuit board 1.

 In all areas 14 - 17 of the functional placement of digital electrical components, their earth planes can be located in one of the inner conductive layers of the circuit board 1, adjacent to one of the outer conductive layers. In the considered example of the implementation of the electronic block, the earthen planes 22, 23, 24, 25, respectively, of the zones 14, 15, 16, 17 are located in the second conductive layer 4 of the circuit board 1 (Fig. 5) adjacent to the first outer conductive layer 2. Earth planes 22 - 25 zones 14 - 17 are made separate, their borders do not touch. The digital power planes of zones 14-17 can be located in one of the inner conductive layers of the printed circuit board 1, separated by at least one conductive layer from the specified conductive layer with the ground planes of these zones. In this example, the implementation of the electronic block of the digital plane 26, 27, 28, 29, respectively, zones 14, 15, 16, 17 are located in the fourth conductive layer 6 of the circuit board 1 (Fig. 7), separated by a third conductive layer 5 from the second conductive layer 4 with earth planes 22 - 25 of these zones. The planes 26 - 29 of the digital power supply of zones 14 - 17 are made separate, their boundaries do not touch. The remaining printed conductors 30 zones 14 - 17 are located in the third 5 (Fig. 6) and fifth 7 (Fig. 8) conductive layers of the printed circuit board 1.

 The analog power plane 20 and the digital power planes 26, 27, 28, and 29 do not overlap vertically.

 Electrical connections between the functional areas 13-17 of the printed circuit board 1 are carried out by signal communication conductors 31, 32, 33, 34 located on the first outer conducting layer 2 of the printed circuit board 1 adjacent to the second conducting layer 4, in which the ground planes 18, 22 are located , 23, 24, 25 of all M = 5 functional zones 13, 14, 15, 16, 17. In the considered example of the implementation of the electronic unit, the electrical connection between the functional areas 13 and 14 is carried out by signal communication wires 31, the connection between zones 14 and 15 isosredstvom conductor 32, the connection between the zones 14 and 16 - by means of conductors 33, communication between the zones 16 and 17 - by means of conductors 34 (figure 4.). The number and arrangement of communication signal conductors 31 to 34 shown in FIG. 4 - conditional.

 The communication signal conductors 31 to 34 are made in the form of direct printed conductors laid between the contact points 35 (Fig. 4) located on the edges of the respective functional arrangement zones 13-17 of the analog and digital radio electronic elements.

 Earth planes 18, 22, 23, 24, 25 of all M = 5 functional zones 13, 14, 15, 16, 17, located in the second inner conductive layer 4 of the circuit board 1 (Fig. 5), are not directly (by borders) between themselves in contact, and their electrical connection is carried out by means of printed jumpers 36, 37, 38, 39 (earthed printed jumpers), laid between the contact points 35 under the corresponding signal signal conductors 31, 32, 33, 34 (Fig. 4) located on the outer conductive layer 2 of the printed circuit board 1. The position of the contact points 35 in the inner layer 4 fully corresponds to the position of similar points 35 on the first outer layer 2.

 The earthen printed lintels 36 - 39 are made straight, their width is set at least 1 mm.

 In the inventive electronic unit uses the principle of separate (functional zones 13 - 17) power supply. To accomplish this, in each of the functional zones 13-17 on one of the outer conductive layers of the printed circuit board 1, in the considered example of implementation, on the first outer conductive layer 2, contact elements connected to the respective planes 20, 26, 27, 29, 29 of these zones are made 40, 41, 42, 43, 44 for connecting to external power sources. The position of the contact elements 40, 41, 42, 43, 44 on the first conductive layer 2 and their connection points 45, 46, 47, 48, 49 with the supply planes 20, 26, 27, 28, 29 of the corresponding functional zones 13, 14, 15 , 16, 17 are shown in FIG. 1, 6, 7.

 In the inventive radio-electronic unit to eliminate unwanted short circuits between the metallized holes 12 of the interlayer connections and the metallized earth planes 18, 19, 22 - 25, as well as the metallized power planes 20, 26 - 29, windows 50 are deprived of metallization in the corresponding places of these planes (Fig. 3) through which the indicated metallized holes 12 of the interlayer connections pass.

 To connect the inventive electronic unit with external devices, a low-frequency connector (connector) 51 is used, mounted on the front side of the circuit board 1 (Fig. 1), one of the terminals of which is connected to the contact element 44.

 To connect to the input source, a high-frequency connector (connector) 52 is used, mounted on the front side of the printed circuit board 1 (figure 1).

 To enable the operation of the inventive radio electronic unit - receiver-processor SRNS to its contact elements 40, 41, 42, 43, as well as through the connector 51 - to the contact element 44 are connected to the appropriate power sources (Fig. 1 - 8 are not shown), to the connector 51 also connects the corresponding external devices - control panel, data recording means, etc. (not shown in FIGS. 1–8), and to the connector 52, an input signal source, for example, a receiving antenna cable (not shown in FIGS. 1–8).

 The input signals of the electronic unit, in this example, which are analog pseudo-noise (broadband) SRNS signals with frequencies in the range from 1200 to 1700 MHz, pass through connector 52 to the first functional area 13 of circuit board 1, where they are subjected to the necessary amplification, filtering from interference, and frequency conversion with decreasing frequency to tens of megahertz.

 The signals converted in this way in the first functional area 13 of the printed circuit board 1 are then subjected to multichannel correlation processing in the second functional area 14, then processed in a digital processor of the fourth functional area 16, and then processed in the interface elements of the fifth functional area 17 of the printed circuit board 1 . The necessary signals of the supporting parts come from the third functional area 15 of the printed circuit board 1.

 Thus, in the inventive radio-electronic unit, the signals in the process of processing are sequentially transferred from one functional area of the printed circuit board 1 to another, while undergoing changes in frequency from thousands of megahertz at the input of the first functional area 13 (the area of placement of analogue radio electronic elements) to units of hertz at the output the fifth functional zone 17 (zone placement of interface electro-radio elements).

 In this case, the transition of signals from one functional zone to another is carried out along strictly defined paths formed by parallel communication signal conductors 31 - 34 and earthing printed bridges 36 - 39. The width of the earthed printed jumpers (at least 1 mm) is chosen from the minimization condition losses in the return circuits of the signal paths and reduce their susceptibility to radiation and crosstalk by eliminating non-optimal current paths that have an additional inductance Stu.

 To minimize losses in the return circuits of the signal paths, as well as the power distribution circuits, the proposed implementation and arrangement of the metallized elements of the planes 18, 19, 22 - 25 and the metallized power planes 20, 26 - 29 of each of the functional zones 13 - 17 are positively affected by which in the inventive electronic block provides the formation of the most optimal return circuits corresponding to the signal circuits, the formation of spurious current circuits, characterized by spurious and inductance and susceptibility to interference, and reached the lowest possible DC resistance and virtually eliminates the falling DC voltage at any place of the PCB.

 The combination of these design measures in combination with the use of a separate power supply for the functional zones allows us to solve the technical problem in the inventive radio electronic block to eliminate spurious interference and induced interference under given conditions, when heterogeneous electrical radio elements of varying degrees of integration are placed on a multilayer printed circuit board that work with signals in the range frequencies from thousands of megahertz to units of hertz.

 The experiments conducted on the electronic blocks of the claimed design showed that the elimination of spurious interference and induced noise, required from the conditions for ensuring the operability of the blocks, is observed when processing the GLONASS and NAVSTAR SRNS signals in their various combinations and in all operating frequency ranges. This allows, in particular, to use the claimed design as a base when developing on-board equipment of SRNS consumers of various classes and purposes.

 Thus, it can be seen from the above that the claimed radio-electronic unit is technically feasible, industrially feasible, solves the technical problem posed by eliminating spurious interference and induced interference under the given conditions for the placement on the single multilayer printed circuit board of radio-electronic elements of varying degrees of integration working with frequency signals from thousands of megahertz to units of hertz, and promising in the design of consumer equipment SRNS and CCC of various classes and purposes.

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

 2. Certificate of the Russian Federation for utility model N 2157, G 06 T 11/20, publ. 05/16/96.

 3. Copyright certificate of the USSR N 1823853, H 05 K 5/00, publ. 11/20/96.

 4. RF patent N 2047947, H 05 K 1/02, publ. 11/10/95.

 5. Lund P. Precision printed circuit boards. Design and production. -M .: Energoatomizdat, 1983.

 6. Mayorov S.A. and other electronic computers. / Design Guide Ed. S.V. Mayorova. -M .: Sov. Radio, 1975 (p. 258 - 261, Fig. 12.2 - prototype).

Claims (1)

 A radio electronic unit containing a multilayer printed circuit board with a number of conductive layers N ≥ 6, in which on the outer first and Nth conductive layers there are contact pads and radio-electronic elements, and earth conductors and power conductors are located in different internal conductive layers of the printed circuit board and are respectively made in in the form of metallized earth planes and power planes with windows around the metallized holes of interlayer connections not electrically connected to these planes, characterized in that The radio-electronic elements placed on the printed circuit board are grouped according to M functional zones, one of which is the functional placement area of analogue electrical radio elements, and the remaining M - 1 zones are the functional arrangement areas of digital radio-electronic elements, while in all M zones of functional placement of analogue and digital electronic-radio elements on the outdoor the first and Nth conductive layers of the printed circuit board are the signal conductors of these zones, in the functional placement area of the analogue electrical radio element in two internal conductive layers of the printed circuit board - the second and (N - 1) -th conductive layers adjacent to the outer first and N-th conductive layers, there are earthen planes of this zone, and the plane of the analogue power supply of the functional placement area of the analogue radio-electronic elements is located in one from the internal conductive layers of the printed circuit board adjacent to the second or (N - 1) -th conductive layer, in all M - 1 zones of the functional placement of digital electronic radio elements in one of the internal conductive layers of the printed circuit board, with adjacent to the first or Nth outer conductive layer, there are separate earth planes of the respective zones of the functional location of the digital radio electronic elements, and in one of the inner conductive layers of the printed circuit board, separated by at least one conductive layer from the said conductive layer with the earth planes of the zones of the functional location of the digital of radio-electronic elements, there are separate, not horizontally touching, digital power planes of these zones, while the pit planes vertices do not overlap the corresponding functional zones of the analog and digital radio electronic elements vertically; each of the M zones of the analog and digital electronic radio elements functional location on one of the outer conductive layers of the printed circuit board has contact elements connected to adjacent power planes of these zones for connecting to external power sources for implementation of a separate power supply unit for functional zones, electrical connections between M zones of the functional location analogue and digital radio-electronic elements are carried out by means of communication signal conductors made in the form of direct printed conductors located on the outer conductive layer of the printed circuit board adjacent to the inner conductive layer, in which the ground planes of all M zones of the functional arrangement of analog and digital radio-electronic elements are located, while the signal communication conductors are laid between the contacts by points located on the edges of the corresponding zones of the functional placement of analogues x and digital electro-radio elements, and the interconnection of the ground planes of all M zones of the functional arrangement of analog and digital electro-radio elements located in the inner conductive layer adjacent to the outer conductive layer carrying the communication signal conductors is carried out by means of direct printed earth jumpers with a width located under the communication signal conductors not less than 1 mm.

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