RU10887U1 - DEVICE FOR MEASURING RESISTANCE OF CONDUCTORS OF MULTILAYER PRINTED CIRCUIT BOARDS - Google Patents

Abstract

A device for measuring the resistance of conductors of multilayer printed circuit boards containing a stabilized current source, a voltage meter, an operational amplifier that acts as a zero-voltage generator, a four-wire communication line, two wires of which are connected through the current and potential contacts to the first connection point (metallized hole) of the measured section of the circuit of the controlled circuit board, and the other two wires are connected through the current and potential contacts to the second point along The connections of this section of the circuit, the direct input of the operational amplifier and the input of the stabilized current source are connected to a common bus, characterized in that the stabilized current source, voltage meter, and operational amplifier are combined into a measuring and switching module, which is connected through two-wire communication line to two metallized holes ( connection points) of the measured section of the circuit, the first and second outputs of the measuring and switching module are connected respectively through the current and potential to contacts with the first connection point of the measured circuit section, and the third and fourth outputs are connected respectively through current and potential contacts with the second connection point of the measured circuit section, N - 1 measuring and switching modules, N - 1 four-wire communication lines, where N = 1, 2, 3, ..., and also introduced an adapter, an interface and a microcomputer, N measuring and switching modules are connected to N groups of metallized holes (connection points) into which a controlled multilayer furnace is arbitrarily divided

Description

The utility model relates to the field of control and measuring equipment and can find application in non-destructive testing of printed circuit boards of multilayer printed circuit boards.

Closest to the proposed device is a resistance meter of a resistive sensor containing a current source, a voltage meter, an inverting amplifier and a four-wire communication line, two wires of which connect the first output (connection point) of the resistive sensor to the first terminals of the current source and voltage meter, and the inverting input and the amplifier output is connected by the other two wires of the communication line to the second output of the resistive sensor, the direct input of the amplifier and the second terminals of the current source and measure I connected to a common voltage bus 1.

A disadvantage of the known device is the low speed measurement of the resistance of the printed circuit conductors of the MPP due to the measurement of the resistance of only one controlled circuit per measurement cycle, as well as the low accuracy of the measurement in the field of low resistance values due to the influence on the measurement result of the bias voltage and input operating voltage amplifier.

The device solves the problem of increasing the speed of measuring the resistance of the MPP conductors by simultaneously measuring the L + M of controlled sections of the circuits in one measurement cycle.

The solution is achieved by the fact that in the device for measuring the resistances of the MPP conductors containing a stabilized current source, the input of which is connected to a common bus, a voltage meter, an operational amplifier for generating a voltage equal to zero, the direct input of which is connected to a common bus, a four-wire communication line, two wires of which are connected to current and potential contacts for connection to the first metallized hole (connection point) of the controlled multilayer printed circuit board, and two other wires are connected to current and potential contacts for connecting to the second metallized hole of this board, the first, second, third and fourth connection nodes, the first, second, third, fourth and fifth analog multiplexers, an adapter, an interface and a microcomputer are introduced, in addition to that, the source stabilized current, voltage meter, operational amplifier, the first, second, third and fourth nodes of connection, the first, second, third, fourth and fifth analog multiplexers are combined into measuring and switching module, N - 1 measuring and switching modules were additionally introduced for connecting to N groups of metallized holes (connection points) into which the controlled multilayer printed circuit board is arbitrarily divided, N - 1 four-wire communication lines, where

N 1, 2, 3, ..., while N four-wire communication lines

provide the ability to connect to the N measuring switching modules L + M the measured sections of the circuits of the controlled multilayer printed circuit board, and in the case when each of the L measured sections of the circuits, where L 0,1, ..., N, has two connection points located inside the corresponding group of metallized holes, two wires of a four-wire communication line provide the connection of the first and second outputs of each of the L measuring and switching modules, respectively, with current and potential contacts for connection to the first the second connection point of the corresponding measured circuit section, and two other wires of the same four-wire communication lines provide the connection of the third and fourth outputs of each of the L measuring and switching modules, respectively, with current and potential circuits for connecting to the second connection point of the corresponding measured circuit section, and the case when each of the M measured sections of the chains, where M 0,1, ..., (N - L) / 2, has connection points located between groups of metallized holes, namely, If each point M of the measured sections of the circuit, respectively, belongs to the group L + 2M -1, and the second point belongs to the group L + 2M, then two wires of the four-wire communication line provide the connection of the first and second or third and fourth outputs of each of L + 2M - 1 measuring and switching modules, respectively, with current and potential contacts for connecting to the first connection point of the corresponding M measured section of the circuit, and two wires of another four-wire communication line provide the connection of the first and second or three the fourth and fourth outputs of each of the L + 2M measuring and switching modules, respectively, with current and potential contacts for connecting to the second connection point the corresponding M measured section of the circuit, in N measuring and switching modules the first, second, third, fourth, fifth, sixth and seventh inputs are combined into the control signal bus and connected to the adapter outputs, the inputs of which are connected to the fifth outputs of N measuring and switching modules, and the inputs of the adapter outputs are connected to the interface, the inputs are you the moves of which are connected to a microcomputer, in each of the N measuring and switching modules, the output of the current source is connected to the first input of the first analog multiplexer and the second input of the second analog multiplexer, the output of the operational amplifier is connected to the first input of the second analog multiplexer and the second input of the first analog multiplexer, the output of the third analog multiplexer is connected to the inverse input of the operational amplifier, the outputs of the first and second analog multiplexers are connected respectively with the first outputs of the first and second connection nodes, the first output of the third connection node is connected to the first and second inputs of the fourth analog multiplexer, as well as to the second input of the third analog multiplexer, the first output of the fourth connection node is connected to the first input of the fifth analog multiplexer and the third input of the fourth analog multiplexer, as well as with the first input of the third analog multiplexer, the second and third inputs of the fifth analog multiplexer are connected to a common bus, in orye terminals of the first, second, third and fourth connection nodes are

respectively, the first, second, third and fourth outputs of the measuring and switching module, the outputs of the fourth and fifth analog multiplexers are connected respectively to the first and second inputs of the voltage meter, the output of which is the fifth output of the measuring and switching module, the combined control inputs of the first, second and third analog multiplexers , control outputs of the first, second, third and fourth connection nodes, combined control inputs of the fourth and fifth analog mules multiplexers, the control input of the voltage meter are respectively the first, second, third, fourth, fifth, sixth and seventh inputs of the measuring switching module.

The proposed device for measuring the resistances of the MPP conductors differs from the prototype in that the first, second, third and fourth connection nodes, the first, second, third, fourth and fifth analog multiplexers, an adapter, an interface and a microcomputer are introduced, in addition, a stabilized current source voltage meter, operational amplifier, first, second, third and fourth connection nodes, first, second, third, fourth and fifth analog multiplexers are combined into a measuring and switching module, additionally N - 1 measuring and switching modules for connecting to N groups of metallized holes (connection points), into which the controlled multilayer printed circuit board is arbitrarily divided, N - 1 four-wire communication lines, where N 1, 2, 3, ..., N four-wire communication lines provide the ability to connect to the N measuring and switching modules L + M the measured sections of the circuits of the controlled multilayer printed circuit board, and in the case when each of the L measured sections of the circuits, where L 0,1, ..., N, has two connection points placed inside the corresponding group of metallized holes, two wires of the four-wire communication line provide the connection of the first and second outputs of each of the L measuring and switching modules, respectively, with current and potential contacts for connecting to the first connection point of the corresponding measured section of the circuit, and two other wires of the same four-wire lines communications provide the connection of the third and fourth outputs of each of the L measuring - switching modules, respectively, with the current and potential contacts for connecting to the second connection point of the corresponding measured circuit section, and in the case when each of the M measured circuit sections, where M 0,1, ..., (N - L) / 2, has connection points located between groups of metallized holes, namely, the first point of each of the M measured sections of the chains, respectively, belongs to the group L + 2M -1, and the second point to the group L + 2M, then two wires of the four-wire communication line provide the connection of the first and second or third and the fourth release of each and L + 2M - 1 measuring and switching modules, respectively, with current and potential contacts for connecting to the first connection point the corresponding M measured section of the circuit, and two wires of the other four-wire communication line provide the connection of the first and second or third and fourth outputs of each of L + 2M measuring - switching modules respectively with current and potential contacts for connection

TO the second connection point of the corresponding M measured section of the circuit, in N measuring and switching modules the first, second, third, fourth, fifth, sixth and seventh inputs are combined into the control signal bus and connected to the outputs of the adapter, the inputs of which are connected to the fifth outputs of N measuring - switching modules, and the inputs and outputs of the adapter are connected to the interface, the inputs and outputs of which are connected to the microcomputer, in each of the N measuring switching modules the output of the current source is connected to the first input of the first analog of the first multiplexer and the second input of the second analog multiplexer, the output of the operational amplifier is connected to the first input of the second analog multiplexer and the second input of the first analog multiplexer, the output of the third analog multiplexer is connected to the inverse input of the operational amplifier, the outputs of the first and second analog multiplexers are connected respectively to the first outputs of the first and the second connection nodes, the first output of the third connection node is connected to the first and second inputs of the fourth ana OG multiplexer, as well as with the second input of the third analog multiplexer, the first output of the fourth connection node is connected to the first input of the fifth analog multiplexer and the third input of the fourth analog multiplexer, as well as the first input of the third analog multiplexer, the second and third inputs of the fifth analog multiplexer are connected to a common bus, the second conclusions of the first, second, third and fourth connection nodes are respectively the first, second, third and fourth outputs of the measuring o - switching module, the outputs of the fourth and fifth analog multiplexers are connected respectively to the first and second inputs of the voltage meter, the output of which is the fifth output of the measuring and switching module, the combined control inputs of the first, second and third analog multiplexers, the control outputs of the first, second, third and the fourth connection nodes, the combined control inputs of the fourth and fifth analog multiplexers, the control input of the voltage meter are respectively by exactly the first, second, third, fourth, fifth, sixth and seventh inputs of the measuring switching module, which provides increased device performance when measuring the resistances of MPP conductors by simultaneously measuring L + M of controlled sections of circuits in one measurement cycle, and also solves the problem of increasing the measurement accuracy due to the compensation of the bias voltage and the input voltage of the operational amplifier, which is part of the voltage follower equal to zero, as well as reducing the influence of common mode noise.

Comparison of the claimed technical solution with the prototype made it possible to identify a set of essential (in relation to the technical result perceived by the applicant) distinctive features in the claimed object set forth in the utility model formula.

Therefore, the claimed technical solution meets the requirement of "novelty under applicable law.

metallized holes and the formation of arrays L and M of measured sections of the chains before each cycle of simultaneous measurement of the resistances of these sections of the chains.

A device for measuring the resistance of printed conductors MPP contains N measuring - switching modules 1, N

four-wire communication lines 2, adapter 3, interface 4, microcomputer 5, controlled by MPP 6.

The measuring and switching module 1 contains a stabilized current source 7, a voltage meter 8, an operational amplifier 9 that performs the function of a voltage equalizer equal to zero, the first, second, third and fourth connection nodes 10, 11, 12, 13, the first, second, third, fourth and fifth analog multiplexers 14, 15, 16, 17.

The direct input of the operational amplifier 9 and the input of the stabilized current source 7 are connected to a common bus, the output of the current source 7 is connected to the first input of the first analog multiplexer 14 and the second input of the second analog multiplexer 15, the output of the operational amplifier 9 is connected to the first input of the second analog multiplexer 15 and the second the input of the first analog multiplexer 14, the output of the third analog multiplexer 16 is connected to the inverse input of the operational amplifier 9, the outputs of the first and second analog multiplexes Ksorov 14, 15 are connected respectively to the first outputs of the first and second connection nodes 10, 11, the first output of the third connection node 12 is connected to the first and second inputs of the fourth analog multiplexer 17, as well as to the second input of the third analog multiplexer 16, the first output of the fourth node 13 the connection is connected to the first input of the fifth analog multiplexer 18 and the third input of the fourth analog multiplexer 17, as well as to the first input of the third analog multiplexer 16, the second and third inputs of the fifth analog the second multiplexer 18 connected to a common bus, the second outputs of the first, second, third and fourth nodes 10, 11, 12, 13 connections are respectively the first, second, third and fourth outputs of the measuring and switching module 1, the outputs of the fourth and fifth analog multiplexers 17, 18 are connected respectively to the first and second inputs of the voltage meter 8, the output of which is the fifth output of the measuring and switching module 1, the combined control inputs of the first, second and third analog multiplexers 14. 1 5, 16, the control outputs of the first, second, third and fourth nodes 10, 11, 12, 13 of the connection, the combined control inputs of the fourth and fifth analog multiplexers 17, 18, the control input of the voltage meter 8 are respectively the first, second, third, fourth, fifth, sixth and seventh inputs of the measuring switching module 1.

The four-wire communication line 2 provides the connection of the first, second, third and fourth outputs of the measuring and switching module 1 to two metallized holes (connection points) of a group of metallized holes of a controlled multilayer printed circuit board 6.

connection), which are arbitrarily broken controlled

multilayer printed circuit board 6.

1,2, ..., N four-wire communication lines 2 provide connection to 1,2, ..., N measuring and switching modules 1 L + M of the measured sections of the circuits of the controlled multilayer printed circuit board 6, in this case, when each of 1,2, ..., L of the measured sections of the chains, where L 0,1, ..., N, has two connection points located inside the corresponding group of metallized holes, the first connection point of each of 1,2, ..., L measured circuits connected through current 2.1 and potential

2.2 contacts respectively with the first and third outputs of the corresponding measuring and switching module 1, and the second connection point of each of these sections of the circuits is connected through the current

2.3 and potential 2.4 contacts, respectively, with the second and fourth outputs of the same measuring and switching module 1, and in the case when each of the 1,2, ..., M is measured sections of the circuits, where M 0,1, ..., (N - L) / 2, has connection points located between groups of metallized holes, namely, the first connection point of each of the 1,2, ..., M measured sections of the chains, respectively, belongs to L + 1, L + 3 ,. .., L + 2M-1 group of metallized holes, and the second connection point - to L + 2, L + 4, ..., L + 2M group of metallized holes, then the first point and the connections of each of the 1,2, ..., M measured sections of the circuits are connected through the current (2.1 or 2.3) and potential (2.2 or 2.4) contacts, respectively, with the first and third or with the second and fourth outputs of the corresponding L + 1, L + 3, ..., L + 2M - 1 measuring and switching module 1, and the second point of each of these sections of the circuits is connected via current (2.1 or 2.3) and potential (2.2 or 2.4) contacts respectively with the first and third or with the second and the fourth outputs of the corresponding L + 2, L + 4, ..., L + 2M measuring and switching module 1.

The first, second, third, fourth, fifth, sixth and seventh inputs 1,2, ..., N of the measuring and switching modules 1 are combined in the control signal bus and connected to the outputs of the adapter 3, the inputs of which are connected to the fifth outputs 1,2, ..., N of the measuring and switching modules 1, and the inputs and outputs of the adapter 3 are connected to interface 4, the inputs and outputs of which are connected to the microcomputer 5.

In the measuring and switching module 1, the stabilized current source 7 is designed to generate a test effect (test current) on the first point of connection of the measured section of the circuit of the controlled multilayer printed circuit board 6. The stabilized current source 7 can be performed similarly 2. The voltage meter 8 is designed to measure and convert voltage to binary code equivalent to the parameter of the measured circuit. The voltage meter 8 can be performed on the basis of the analog digital converter AD7892 of ANALOG DEVICES 3 or can be performed similarly to 4.

The adapter 3 is intended for transmitting control data from the micro - computer 5 to the measuring and switching modules 1 and transmitting measurement data from the measuring and switching modules 1 to the micro - computer 5 through the interface 4.

control, 1,2, ..., N buffers 23, signal bus 24, data bus 25, address bus 26, 1,2, ..., N input buses 27, 1,2, ..., N buses 28 output.

The data bus 25 through the reception - transmitters 19 is connected to the inputs of the registers 22/1, ..., 22 / N control and to the outputs of the buffers 23/1, ..., 23 / N. The address bus 26 is connected to the inputs of the sample decoder 20 and the output decoder 21. The outputs of the sample decoder 20 are connected respectively to the clock inputs of the control registers 22/1, ..., 22 / N. The outputs of the output decoder 21 are connected to the high resolution impedance enable inputs of the buffers 23/1, ..., 23 / N. The IOR signal (Input) of the signal bus 24 is connected to the resolution input of the sample decoder 20. The IOW signal (Output) of the signal bus 24 is connected to the enable input of the output decoder 21 and to the control input of the transmitters 19. Bus 27 of the input data is connected to

the corresponding information inputs of the buffers 23/1, ..., 23 / N. The outputs of the control registers 22/1, ..., 22 / N are combined in the output bus 28. Interface 4 is designed to ensure information and electrical compatibility of N measuring and switching modules 1 with microcomputer 5 via adapter 3. As an interface, the ASI 5 system bus can be used.

Micro - computer 5 is a standard micro - computer (PC) with external memory for storing data on the value of the resistance of the measured circuits.

The controlled multilayer printed circuit board 6 is arbitrarily divided into N groups of metallized holes (connection points) and is presented in the form of an approximate section of a printed circuit board, which most closely approximates a real circuit board with possible connections between metallized holes. An exemplary multilayer printed circuit board 6 contains L groups of metallized holes (connection points), inside each of which two connection points of the corresponding measured circuit section are located, and also contains 2M groups of metallized holes (connection points), inside each of which there is one connection point corresponding to one of the M measured section of the circuit, namely, the first point of each of the M measured chains, respectively, belongs to the group L + 2M - 1, and the second point to the group L + 2M, with the total number about the measured circuits of the multilayer printed circuit board 6 is determined by the expression: L + M, and the total number of groups of metallized holes (connection points) into which the multilayer printed circuit board 6 is arbitrarily divided is determined by the expression: N L + 2M.

An arbitrary breakdown of the controlled MPP into N groups of metallized holes and the formation of L and M measured sections of the chains is carried out according to the following algorithm.

Controlled MPP are randomly divided into N groups

metallized holes (connection points), each of which can contain any number of connection points, form an array of all elementary sections of MPP chains to be controlled, for which each MPP chain is divided into separate elementary sections of the circuit, which are connections only between two metallized holes, they form arrays L and M of measured sections of chains for the first cycle of simultaneous measurement

the resistances of these sections of the chains, with each elementary section of the chain included in the array L of measured sections of the chains, where L 0.1 ... N, has connection points inside the corresponding group of metallized holes, and each elementary section of the chain included in the array M of measured sections of chains, where M 0,1, ..., (NL) / 2, has connection points in different groups of metallized holes, namely, the first point of each elementary section of a chain of M measured sections of chains, respectively, belongs to the group L + 2M -1, and the second point is to the group ne L + 2M, at the beginning of the formation of arrays of L and M of measured sections of chains, for the first cycle of simultaneous measurement of the resistances of these sections of chains, any group of metallized holes (connection points) is selected, and inside this group an arbitrary metallized hole is selected, which is the first connection point of the measured elementary section of the circuit, to select the second connection point of this section of the circuit from the array of all elementary sections of the MPP chains to be controlled, any elementary section is selected the circuit connecting the selected first connection point of the measured elementary chain section (metallized hole) with another metallized hole, which is the second connection point, in this case, if the connection points of the selected elementary chain section belong to the same group of metallized holes, then this elementary chain section refers to the array L of measured sections of chains, and if these connection points belong to different groups of metallized holes, then this elementary the drain of the circuit is assigned to the array M of measured sections of the chains, with the further formation of arrays L and M of measured sections of the chains, the first connection points of the measured elementary sections of the chains are selected from the groups of metallized holes (connection points), the connection points of which do not belong to the elementary sections of the chains included in the arrays L and M of the measured sections of the chains, and in this case, all metallized holes belonging to chains whose elementary sections are already inlet should be excluded from consideration within these groups jat into the arrays L and M of the measured sections of the chains, at the end of the formation of the L and M arrays, a stabilized current is supplied to the first points of each of the L + M measured elementary sections of the circuits, and zero potential is supplied to the second points of the measured elementary sections of the chains from the corresponding L + M formers voltage equal to zero, exercise

simultaneous determination of voltage drops on L + M measured elementary sections of circuits by measuring voltage drops between the first and second connection points on each of L measured elementary circuits and by subtracting the results of simultaneously measured voltage drops on the first and second connection points of each of M measured elementary sections of chains relative to the common bus when forming new arrays of L and M measured sections of chains for the next cycle simultaneously a complete measurement of the resistances of these sections of the circuits from the array of all elementary sections of the MPP circuits to be controlled exclude all previously measured elementary sections of the chains, and when choosing the first points of connection

connections) that do not belong to the elementary sections of the chains included in the array of all elementary sections of the MPP chains subject to control.

Fig. 3 shows an example of the performance of a controlled MPP, which is randomly divided into four groups of metallized holes according to the principle of equal areas of sections of MPP occupied by each group, or can be divided into groups according to the principle of an equal number of metallized holes in each group, or it can be divided into groups on some other principle. To form an array of all elementary sections of the MPP chains subject to control, through numbering of all metallized holes is carried out. Next, the arrays L and M of the measured sections of the chains are formed for the first cycle of simultaneous measurement of the resistances of these sections of the chains, for which any connection point inside any group of metallized holes is selected, for example, t.1, after which the second connection point of the measured section is found by choosing from the array of all elementary sections of MPP chains subject to control of any section of the circuit connecting the selected first connection point t.1 with another metallized hole, which is the second The first connection point is the connection point t. 2. Since the selected connection points of the measured section of chain 1-2 belong to groups 1 and 2, this section of the chain is assigned to array M. During the subsequent formation of arrays L and M, the groups of metallized holes 1 and 2 are excluded from further consideration, since connection points 1 and 2 of the selected chain section, respectively, belong to these groups, and in the group of metallized holes 3, point T.6 is excluded from consideration, since it belongs to the chain of the selected section. Then they proceed to the choice of the second measured section of the chain, for which any permitted connection point is selected from the groups of metallized holes 3 and 4, for example, point 4. Then they find the second connection point of the measured section by selecting from the array of all elementary sections of the MPP circuits to be controlled any section of the circuit connecting the selected first connection point t.4 with another metallized hole, which is the second connection point - this is the connection point t.5. Since the selected connection points of the measured section of the chain 4-5 belong to one group 3, this section of the chain is assigned to the array L. During the subsequent formation of the arrays L and M, the groups of metallized holes 1,2iZ are excluded from further consideration, since the connection points 1, 2, 4, and 5 selected sections of the chains belong to these groups. Then go to the selection of the third measured section of the circuit, for which any permitted connection point is selected from the group of metallized holes 4, for example, point 7. Then they find the second connection point of the measured section by selecting from the array of all elementary sections of the MPP chains to be controlled any section of the circuit connecting the selected first connection point t.7 with another metallized hole, which is the second connection point - this is the connection point t8. Since the selected connection points of the measured section of the circuit 7-8 belong to the same group 4, this section of the chain is assigned to the array L. As a result of the actions taken, all groups of metallized holes of the controlled MPP include the connection points of the selected

sections of chains, therefore the formation of arrays L and M

the measured sections of the circuit for the first cycle of simultaneous measurement of the resistances of these sections of the circuit is considered complete.

When forming arrays L and M of measured sections of chains for conducting a second cycle of simultaneous measurement of the resistances of these sections of chains, previously measured sections of chains, namely sections of chains 1-2, 4-5, 7-8 and as a consequence of this, the connection points t.1, t.4, t.5 and t8 are excluded from further consideration during the formation of arrays L and M. Next, the arrays L and M of the measured sections of the chains are formed, for which any connection point connected to the selection inside any group of metallized holes, for example, vol. 2, after which they find the second connection point of the measured section by selecting from the array of all elementary sections of the MPP chains to be controlled any section of the circuit connecting the selected first connection point of vol. 2 to another metallized hole, being the second connection point, this is the connection point t. Since the selected connection points of the measured section of the circuit 2-3 belong to the same group 2, this section of the chain is assigned to the array L. When after The formation of L and M arrays excludes from further consideration the group of metallized holes 2, since the connection points 2 and 3 of the selected sections of the chains belong to this group, and the point t.6 is excluded from the consideration of the group of metallized holes 3, since it belongs to the chain selected area 2-3. Then they proceed to the choice of the second measured section of the circuit, for which any allowed connection point is selected from the groups of metallized holes 3 and 4, for example, point 7. Then they find the second connection point of the measured section by selecting from the array of all elementary sections of the MPP chains to be controlled any section of the circuit connecting the selected first connection point t.7 with another metallized hole, which is the second connection point - this is the connection point t.9. Since the selected connection points of the measured section of the circuit 7-9 belong to one group 4, this section of the circuit is assigned to the array L.

As a result of the actions taken, all groups of metallized holes of the controlled MPP include connection points for selected sections of the chains, therefore the formation of arrays L and M of measured sections of chains for the second cycle of simultaneous measurement of the resistances of these sections of chains is considered completed.

During the formation of arrays L and M of measured sections of chains for the third cycle of simultaneous measurement of the resistances of these sections of chains, previously measured sections of chains, namely sections of chains 2-Zi 7-9, are excluded from the array of all elementary sections of MPP chains to be controlled the connections of T.2 and T.7 are excluded from further consideration when forming the L and M arrays. Next, the L and M arrays of the measured sections of the circuits are formed, for which any connection point is selected from the allowed optionally within any group of metallized holes, e.g. TZ, whereupon the second connection point are measured by selecting a portion of an array of

elementary sections of MPP chains to be controlled

any part of the circuit connecting the selected first connection point t.Z with another metallized hole, which is the second connection point, is the connection point t.6. Since the selected connection points of the measured section of the chain 3-6 belong to groups 2 and 3, this section of the chain is assigned to the array M. During the subsequent formation of the arrays L and M, the groups of metallized holes 2 and 3 are excluded from further consideration, since the connection points 3 and 6 selected sections of the chain respectively belong to these groups. Then go to the selection of the second measured section of the circuit, for which any permitted connection point is selected from the group of metallized holes 4, for example, point 9. Then they find the second connection point of the measured section by selecting from the array of all elementary sections of the MPP chains to be controlled any section of the circuit connecting the selected first connection point t. 9 with another metallized hole, which is the second connection point - this is the connection point t. 10. Since the selected connection points of the measured section of the circuit 9-10 belong to one group 4, then this section of the chain is assigned to the array L.

As a result of the actions taken, all groups of metallized holes of the controlled MPP incorporate connection points for selected sections of the chains, therefore the formation of arrays L and M of measured sections of chains for the third cycle of simultaneous measurement of the resistances of these sections of chains is considered completed.

After excluding from the array of all elementary sections of MPP chains that are subject to control the previously measured sections of chains, namely, sections of 3-bi 9-10 chains, in the array of all measured elementary sections of MPP chains for the next measurement cycle, not a single unmeasured elementary chain section remained in as a result, subsequent measurement cycles are not carried out.

The device operates as follows.

The device simultaneously measures the resistances L + M of the printed conductors of the controlled multilayer printed circuit board 6 for one measurement cycle by connecting N measuring and switching modules 1 to N groups of metallized holes (connection points) into which the controlled multilayer printed circuit board 6 is arbitrarily divided, thus that at the first connection points of each of the L + M of the measured section of the circuits fed a stabilized current generated by the corresponding stabilized current source 7 and measuring and switching module 1, and to the second connection points of the measured sections of the circuits, zero potential is applied from the corresponding voltage generator equal to zero, which is part of the measuring and switching module 1, and executed on the operational amplifier 9 operating in the voltage follower mode equal to zero. The voltage drops are measured and converted into binary code simultaneously on the L + M measured sections of the circuits using the corresponding voltage meters 8, the measurement results are sent to the microcomputer 5, they are processed and the measurement results of the resistance of the conductors of the controlled multilayer printed circuit board 6 are displayed.

The first, second, third and fourth nodes of the connection

measuring and switching modules 1 provide the appropriate inclusion of the first, second, third and fourth outputs of the measuring switching modules 1.

The choice of the operation mode of each of the N measuring and switching modules 1 and the synchronization of measurements is carried out by supplying a code combination that is sent via the control bus to the N measuring and switching modules 1 from the micro-computer 5 via interface 4 and adapter 3. Reading N results of measurements of printed resistances conductors of a controlled multilayer printed circuit board 6 is carried out by supplying a code combination that is transmitted via a control signal bus to voltage meters 8 corresponding to N measuring - switching ion modules 1 from the microcomputer 5 through interface 4 and adapter 3.

When measuring the resistances L of controlled circuits connected through four-wire communication lines 2.1, 2.2, 2.3, 2.4 to the corresponding measuring and switching modules 1, in each of the 1 / L measuring switching modules, the analog multiplexers 14, 15, 16 provide respectively the connection of a stabilized current source 7 through the connection unit 10 and the current contact 2.1 to the first connection point of the corresponding section of the circuit, the output of the operational amplifier 9 through the connection unit 11 and the current contact 2.3 to the second connection point of that section of the circuit, the inverse input of the operational amplifier 9 through the connection node 13 and the potential contact 2.4 to the second connection point, and analog multiplexers 17 and 18 respectively provide the connection of the first input of the voltage meter 8 through the connection nodes 12 and potential contact 2.2 to the first connection point of the measured section the circuit, and connecting the second input of the voltage meter 8 through the connection unit 13 and the potential contact 2.2 to the second connection point of the same section of the circuit, while determining the drop voltage on the measured section of the circuit is carried out by subtracting the voltage drops coming to the first and second input of the voltage meter 8 and converting the received voltage into a binary code. In this case, the final determination of the resistance value of the conductor of each of the L measured sections of the MPP circuits is carried out by sending the received code from the corresponding 1 / L measuring and switching module via adapter 3 and interface 4 to the microcomputer and calculating the resistance of the MPP conductor from the formula:

UR 1 X RL and 1T.P. - U 2t.p, (1)

wherein:

UiT.n. UR + UcM + ivh.ou + Uccn; (2)

U2T.n. UCM + ivh.ou + Uccn; (3)

ivh.ow ob - live.ow / key, (4)

the connections of which are connected to the L measuring switching module;

UiT.n. - voltage drop at the first point of connection of the measured section of the circuit L MPP;

U2T.n. - voltage drop at the second connection point of the measured section of the circuit L MPP;

UcM is the bias voltage of the operational amplifier 9;

ivh.ou - input voltage of the operational amplifier 9;

Uvyh.ou - the output voltage of the operational amplifier 9;

Uccn is the common mode component voltage;

Ki is the gain of the operational amplifier 9. As can be seen from formulas (1), (2), (3), in them, in contrast to the method of measuring the resistances of printed conductors MPP 2, the dependence of the results of the output voltages of each of the L voltage meters 8 on voltage drops is eliminated on the resistances of the lead wires of a four-wire communication line 2.3 and 2.4, connection nodes 11.13 and analog multiplexers 15 and 16 by connecting them to the negative feedback circuit of operational amplifier 9 operating in a voltage follower mode equal to n Liu. Due to the properties of the operational amplifier 9 (low input current and high gain), this connection makes it possible to apply the potential ОВ + UCM + ив.о. to the second connection points of each of the L measured sections of the circuits. At the same time, as can be seen from formulas (1), (2), (3), the bias voltage UCM, the input voltage of the operational amplifier 9 uh.ow and the common-mode noise component Uccn are not affected by the voltage drop of the measured conductor resistance due to the full compensation of all these constituent values of the measurement results.

When measuring the resistances M of the monitored sections of the circuits connected through four-wire communication lines to different measuring and switching modules 1, the first point of each of the M measured sections of the circuits is respectively connected to the measuring switching module 1 / L + 2M-1, and the second point to the measuring switching module 1 / L + 2M. In each 1 / L + 2M-1 measuring switching module, in which the first connection point of the measured circuit section is connected via current 2.1 and potential 2.2 contacts respectively to the first and second outputs of the measuring switching module, the analog multiplexer 14 provides the connection of a stabilized current source 7 through connection unit 10 and current contact 2.1 to the first connection point of the measured circuit section, and multiplexers 17 and 18 respectively provide the connection of the first input of voltage meter 8 Erez connection node 12 and a potential contact 2.2 in the same measured point along the chain connecting portion, and connecting the second input voltage meter 8 to the common bus. In each 1 / L + 2M-1 measuring switching module, in which the first connection point of the measured circuit section is connected via current 2.3 and potential 2.4 contacts respectively to the third and fourth outputs of the measuring switching module, the analog multiplexer 15 provides the connection of a stabilized current source 7 through connection unit 11 and current contact 2.3 to the first connection point of the measured circuit section, and analog multiplexers 17 and 18

respectively, provide the connection of the first input of the voltage meter 8 through the connection unit 13 and the potential contact 2.4 to the same connection point of the measured section of the circuit, and the connection of the second input of the voltage meter 8 to the common bus. In each of the 1 / L + 2M measuring and switching modules, in which the second connection point of the measured section of the circuit is connected via current 2.1 and potential 2.2 contacts respectively to the first and second outputs of the measuring and switching module, analog multiplexers 14 and 16 respectively provide connection to the second the connection point of the measured portion of the output circuit of the operational amplifier 9 through the connection node 10 and the current contact 2.1 and the inverse input of the operational amplifier 9 through the connection node 12 and are potential 2.2 contact, and analog multiplexers 17 and 18 provide respectively connecting the first input voltage meter 8 via connecting node 12 and a potential contact point 2.2 second circuit connecting the measuring portion and the second input connection of the voltage measuring instrument 8 to the common bus. In each 1 / L + 2M measuring switching module, in which the second connection point of the measured circuit section is connected via current 2.3 and potential 2.4 contacts respectively to the third and fourth outputs of the measuring switching module, analog multiplexers 15 and 16 respectively provide connection to the second connection point the measured output circuit of the operational amplifier 9 through the connection unit 11 and the current contact 2.3 and the inverse input of the operational amplifier 9 through the connection unit 13 and the potential circuit 2.4 m, and the multiplexers 17 and 18 provide respectively connecting the first input voltage meter 8 via the connection node 13 and a potential contact to the 2.4 second point along the chain connecting the measuring portion and the second input connection of the voltage measuring instrument 8 to the common bus. In each of the 1 / L + 2M-1 measuring and switching modules, the voltage drop is measured at the first point of the measured section of the circuit relative to the common bus by subtracting the voltage drops coming to the first and second input of the voltage meter 8 and converting it to binary code. In each of the 1 / L + 2M metering and switching modules, the voltage drop is measured at the second point of the measured section of the circuit relative to the common bus by subtracting the voltage drops coming to the first and second input of the voltage meter 8 and converting it to binary code. In this case, the final determination of the value of the conductor resistance of each of the M measured circuit sections is carried out by sending the received codes from the corresponding 1 / L + 2M -1 and 1 / L + 2M measuring switching modules 1 through adapter 3 and interface 4 to the microcomputer 5 and calculation of the resistance of the MPP conductor from the formula:

UR 1 X R and L + 2M-1 - and L + 2M, (5)

wherein:

and L + 2M-1 UR + UcM + ivh.ou + Uccn; (6)

UR is the voltage drop across the measured resistance of the MPP conductor;

1 tbsp. - test current generated by a stabilized current source in L + 2M-1 measuring and switching module;

R is the measured resistance of the MPP conductor, the first and second connection points of which are connected respectively to L + 2M-1 and L + 2M measuring and switching modules;

UcM - bias voltage of the operational amplifier;

ivh.ou - input voltage of the operational amplifier;

ivyh.ow - output voltage of the operational amplifier;

Uccn is the common mode component voltage;

Ki is the gain of the operational amplifier. As can be seen from formulas (5), (6), (7), unlike the resistance meter of the resistive sensor 3, the voltage drop of the measured resistance of the conductor is not affected by the bias voltage UCM, the input voltage of the operational amplifier is 9 volts and the common-mode component voltage of the interference Uccn thanks to the full compensation of all these component values of the measurement results.

Due to the fact that the second connection points of each of the M measured sections of the circuits supply zero potential by switching on the resistance of the contacts and lead wires of the four-wire communication line (2.1 and 2.2 or 2.3 and 2.4), the nodes (10 and 12 or 11 and 13) of the connection and analog multiplexers (14 or 15 and 16) in the feedback circuit of the operational amplifier 9 operating in the voltage follower mode equal to zero and included in the corresponding 1 / L + 2M measuring switching module, the influence of voltage drops on these resistances is excluded ia on the results of measurements of voltage drops on the measured resistances of the MPP conductors by each of 1 / L + 2M -1 and 1 / L + 2M measuring and switching modules 1 (6) and (7).

Analog multiplexers and switches of the 590 series can be used as analog multiplexers and connection nodes in the measuring and switching modules.

The proposed device for measuring the resistances of the conductors of multilayer printed circuit boards provides simultaneous measurement of L + M controlled sections of circuits for one measurement cycle, which significantly increases the speed of measuring the resistances of the conductors of the MPP, and also improves the accuracy of measuring the resistances of the conductors of multilayer printed circuit boards by compensating for the effects of bias voltage and input the voltage of the operational amplifier, as well as the voltage of the common-mode component of the interference to the measurement result in each ohm from 1/1 + 2M measuring and switching module.

Sources of information taken into account when conducting a patent information search:

1.Putnikov V.S. and Lopatin V.V. Resistance sensor resistance meter, A. p. USSR No. 463931, class G 01 R 27/16 claimed 01/12/1973, publ. 03/15/1975, Bull. No. 10 is a prototype device.

2. Putnikov V. S. Interactive electronics in measuring devices. 2nd ed., Revised. and add. - L .: Energoatomizdat. Leningrad Department, 1988, pp. 70-74.

3. Reference book “Integrated circuits: Integrated circuits for analog-to-digital conversion and multimedia. Issue 1-M. DODEKA, 1996, pp. 166-175.

4.Digital ohmmeter, A.S. USSR No. 1167529, cl. G01 R 27/00, publ. 07/15/1985, Bull. No. 26.

5. Petrukhin V. S., Stepchenkov Yu. A., Filin A. V. Personal computers based on Intel 80386 architecture. In two books. - Obninsk: “INVESKO, 1993, - Prince. 2, pp. 7-40.

Claims (1)

A device for measuring the resistance of conductors of multilayer printed circuit boards containing a stabilized current source, a voltage meter, an operational amplifier that performs the function of a zero-voltage generator, a four-wire communication line, two wires of which are connected through the current and potential contacts to the first connection point (metallized hole) of the measured section of the circuit of the controlled circuit board, and the other two wires are connected through the current and potential contacts to the second point along The connections of this section of the circuit, the direct input of the operational amplifier and the input of the stabilized current source are connected to a common bus, characterized in that the stabilized current source, voltage meter, and operational amplifier are combined into a measuring and switching module, which is connected through two-wire communication line to two metallized holes ( connection points) of the measured section of the circuit, the first and second outputs of the measuring and switching module are connected respectively through the current and potential to contacts with the first connection point of the measured circuit section, and the third and fourth outputs are connected respectively via current and potential contacts to the second connection point of the measured circuit section, N - 1 measuring-switching modules, N - 1 four-wire communication lines, where N = 1, 2, 3, ..., as well as an adapter, an interface, and a microcomputer, N measuring and switching modules are connected to N groups of metallized holes (connection points) into which a controlled multilayer furnace is arbitrarily divided n board, N four-wire communication lines provide connection to N measuring and switching modules L + M of the measured sections of the circuits of the controlled multilayer printed circuit board, in the case when each of the L measured sections of the circuits, where L = 0,1, ..., N, has two connection points located inside the corresponding group of metallized holes, the first connection point of each of the L measured sections of the circuit is connected through current and potential contacts, respectively, with the first and second outputs of the corresponding flax-switching module, and the second connection point of each of these sections of the circuits is connected through the current and potential contacts, respectively, with the third and fourth outputs of the same measuring and switching module, and in the case when each of the M measured sections of the circuits, where M = 0 , 1, ..., (N - L) / 2, has connection points located between groups of metallized holes, namely, the first point of each of the M measured sections of the chains respectively belongs to the group L + 2M - 1, and the second point to the group L + 2M, then the first point The voltage of each of the M measured sections of the circuits is connected through the current and potential contacts, respectively, to the first and second or third and fourth outputs L + 2M - 1 of the measuring and switching module, and the second point of each of these sections of the circuits is connected through the current and potential contacts, respectively the first and second or with the third and fourth outputs of the L + 2M measuring and switching module, and in all cases the current contacts are connected on one side of the metallized junctions of the contacted printed circuit board, and potential contacts - on the other hand of the same metallized junctions, the first, second, third and fourth connection nodes, the first, second, third, fourth and fifth analog multiplexers are introduced in each of the N measuring and switching modules, the current source output is connected to the first input of the first analog multiplexer and the second input of the second analog multiplexer, the output of the operational amplifier is connected to the first input of the second analog multiplexer and the second input of the first analog multiplexer, output q the third analog multiplexer is connected to the inverse input of the operational amplifier, the outputs of the first and second analog multiplexers are connected respectively to the first outputs of the first and second connection nodes, the first output of the third connection node is connected to the first and second inputs of the fourth analog multiplexer, as well as to the second input of the third analog multiplexer, the first output of the fourth connection node is connected to the first input of the fifth analog multiplexer and the third input of the fourth analog new multiplexer, as well as with the first input of the third analog multiplexer, the second and third inputs of the fifth analog multiplexer are connected to the common bus, the second outputs of the first, second, third and fourth connection nodes are the first, second, third and fourth outputs of the measuring and switching module, the outputs of the fourth and fifth analog multiplexers are connected respectively to the first and second inputs of the voltage meter, the output of which is the fifth output of the measuring and switching module, the combined control inputs of the first, second and third analog multiplexers, the control outputs of the first, second, third and fourth connection nodes, the combined control inputs of the fourth and fifth analog multiplexers, the control input of the voltage meter are respectively the first, second, third, fourth, fifth , the sixth and seventh inputs of the measuring and switching module, which are combined in the control signal bus and connected to the outputs of the adapter, the inputs of which are connected to the fifth in the outputs of N measuring and switching modules, and the inputs and outputs of the adapter are connected to an interface whose inputs and outputs are connected to the microcomputer.