EP3769593A1 - Coupon and method for checking a printed circuit board - Google Patents

Abstract

The invention relates to a coupon (110) for a panel (100) with at least one printed circuit board (101). The printed circuit board (101) has M layers (121), where M is greater than or equal to 2, said layers being electrically insulated from one another by a respective substrate (122, 123). The coupon (110) comprises M test layers (241) for the corresponding M layers (121) of the printed circuit board (101). Each of the M test layers (241) has an electrically conductive reference surface (212) and a test line (211, 213) which is electrically insulated from the reference surface. The reference surface (212) of one test layer (241) is designed as a reference layer for the test line (212, 213) of a directly adjacent test layer (241).

Description

 Test coupon and method for checking a printed circuit board

The invention relates to a test coupon, which makes it possible to check the construction of a printed circuit board in a reliable and non-destructive manner. Furthermore, the invention relates to a method for checking a printed circuit board based on the test coupon described in this document.

Circuit boards today may have a plurality (e.g., M = 4, 6, 8, 10 or more) electrically conductive layers. In the manufacture of printed circuit boards, it may happen that inaccurate materials (e.g., materials with incorrect dielectric constant) and / or materials of incorrect thickness are used. In addition, it can happen that positions are reversed, which can lead to malfunction of an electronic circuit based on the printed circuit board.

Such manufacturing errors can typically only be detected within the framework of an examination method in which a printed circuit board is destroyed. For example, one or more micrographs of a printed circuit board can be made and measured under a microscope to detect a manufacturing error.

The present document deals with the technical task to enable an efficient and non-destructive quality assurance of a printed circuit board production.

The object is solved by the subject matter of the independent patent claims. Advantageous embodiments are defined in particular in the dependent claims, described in the following description or illustrated in the accompanying drawing.

In accordance with one aspect of the invention, a test coupon for use with at least one printed circuit board is described. The printed circuit board and the test coupon are manufactured on a common use and therefore typically have the same layer structure. The circuit board or the utility may have M layers, with M equal to 2 or more (typically M = 4, 6, 8, 10 or more), each electrically isolated from each other by a substrate (eg, a fiber composite) are. In particular, the printed circuit board or the utility typically have M-1 substrates.

To make a circuit board, M masks can be provided for the M layers of utility. In this case, a mask has the design or the layout of a respective desired position of the printed circuit board and the design or the layout of a test layer of the test coupon. The layer designs or layouts can each be applied in pairs to a two-ply benefit. Subsequently, N-finished two-layered benefits can be combined via one substrate each (in particular a Pre Preg substrate) to produce the M = 2N-layered benefit. During manufacture, dual-layered benefits may be mismatched (for example, in the wrong order) and / or false substrates may be used to merge the two-ply benefits (e.g., with a defective thickness and / or a defective dielectric property). As a result, the printed circuit board produced may be defective. Based on the test coupon described in this document, a manufacturing defect of a printed circuit board can be detected in an efficient and non-destructive manner.

As already stated above, the test coupon M includes test layers for the corresponding M layers of the printed circuit board. The M test layers may each have an electrically conductive reference surface and a test lead electrically insulated therefrom. For this purpose, an isolation region can be created around the test lead of a test layer (by removing the electrically conductive material of the layer). The reference surfaces of the M test layers preferably cover in each case 70%, 80% or more of the total area of the respective test layer.

The reference surfaces of the M test layers are designed such that the reference surface of a test layer is designed as a reference layer or as an electrical reference for the test line of at least one directly adjacent test layer. In particular, the M test layers can be designed such that, for all M test layers, the reference surfaces of the one or more directly adjacent test layers form a reference layer or an electrical reference for the test line of the respective test layer. For this purpose, the reference surfaces of the M test layers may be over one or more vias be electrically connected to each other. In particular, the reference surfaces of the M test layers can each be connected to ground and / or ground.

Thus, a test coupon with M test plots is provided, wherein the M test plots each have at least one (possibly exactly one) test lead. The test leads each have reference layers in one or more directly adjacent test layers, and thus can be reliably used to measure one or more electrical properties of the test layers, and based thereon, to identify the different test layers. Due to the one-to-one relationship between test layers of the test coupon and layers of the printed circuit board can thus be concluded by measuring one or more electrical properties of the test layers on a manufacturing error of the printed circuit board.

The circuit board to be checked may have M set positions each having a target design (i.e., a target layout of the conductor pattern) in a target state (in particular, a healthy state). Alternatively or additionally, the one or more, in particular the M-1, substrates of the printed circuit board in the target state in each case setpoints with respect to the substrate thickness and / or with respect to a dielectric property (in particular the dielectric constant of the material of the substrate).

The M test layers of the test coupon may be designed to deliver different reference values in the target state (i.e., in a defect-free production of the benefit) in a nondestructive measurement of at least one electrically relevant property of the M test layers. In particular, at least one reference value can be provided for each measured property. In this case, the reference values of the measured property for the different test layers may at least partially differ. The at least M different reference values for at least one electrically relevant property can then be used to distinguish the M test positions of the test coupon from one another.

Possibly. Several different electrically relevant properties (eg the length of the test lead of a test layer and the impedance of the test lead of a test layer) can be measured. For each property, then (at least) a separate reference value can be provided. For example, considering Q different electrically relevant properties (with Q = 1, 2, 3 or more) if necessary exactly or at least Q reference values for the Q properties are provided (for each property at least one reference value). In this case, Q reference values can be provided for each of the M test positions (at least or exactly), and thus in total (at least or exactly) QM reference values for the test coupon. By considering several different electrically relevant properties, the reliability of distinguishing the different test layers of a test coupon can be further increased.

The M test layers may be associated with the M target layers in a one-to-one relationship so that a manufacturing defect of the printed circuit board may be detected by performing the nondestructive measurement on the test coupon. In this case, a manufacturing error may include in particular: a faulty order of the M target positions; at least one layer of the printed circuit board which does not correspond to the required nominal position; and / or at least one substrate with a defective thickness and / or a faulty dielectric property.

The M test layers of a test coupon can thus be assigned as reference test layers to the different desired positions of the printed circuit board. The M test layers, in particular the test lines of the M test layers, can have a different design or layout. In this case, the designs or layouts differ in such a way that the different test layers can be distinguished from one another by the non-destructive measurement of at least one electrically relevant characteristic of the test layers. If the measurement shows that the actual values measured for the test layers correspond to the reference values for the reference test positions, a manufacturing error can be ruled out. On the other hand, if the actual values at least partially deviate from the reference values, the presence of a manufacturing error can be detected. Possibly. Also, a particular manufacturing defect (e.g., a faulty location or an erroneous order of locations) may be identified.

The test coupon may have a longitudinal direction and a transverse direction, wherein the test coupon is greater in the longitudinal direction than in the transverse direction (eg by a factor of 2, 3, 4 or more). The test leads of the M test layers can then each extend for the most part along the longitudinal direction (for example to 80%, 90% or more). It can be a Test line have a length which is substantially greater than the width of the test line, for example by a factor of 10, 20, 50 or more. Through test lines formed in this way, large-area and spatially defined reference areas can be provided for the test lines in the adjacent test plots. This in turn allows a precise adjustment of the electrically relevant properties of the test layers, which allows a reliable detection of the different test layers and thus a reliable detection of manufacturing errors.

The test coupon may have a centerline along the length of the test coupon that divides the test coupon into a first half and a second half. The test leads of the M test layers can then be arranged alternately in the first half and in the second half. Furthermore, the reference surfaces of the M test layers may be arranged alternately at least for the most part (possibly also completely) in the second half and in the first half, in a complementary manner to the test lines. Thus, one or more reference layers for the test leads of the different test layers can be efficiently provided.

The test leads of the M test layers can each have a contact point via which the test leads can each be electrically contacted individually. The measurement of the at least one electrically relevant characteristic of a test layer can take place via the contact point of the test line of this test layer. For example, a time domain reflectometer can be connected to the contact point of a test line in order to carry out the measurement of the at least one electrically relevant property. Thus, an identification of the individual test layers can be carried out by means of a nondestructive measurement in an efficient manner.

The M test layers, in particular the test lines of the M test layers, may differ from one another such that the M test layers can be distinguished from one another on the basis of current and / or voltage measurements on the M test lines (in particular at the contact points of the M test lines). In particular, the M test layers may differ from one another in such a way that it is possible to distinguish the M test layers by means of the measurements of a time domain reflectometer. For example, the test lines of the M test layers may at least partially have different lengths. Alternatively or additionally, the test lines of the M test layers may have at least partially different impedances. Alternatively or additionally, the test lines of the M test layers can at least partially have a separate reflection point from the end (remote from the contact point) of the respective test line, at which an electrical pulse is at least partially reflected. Alternatively or additionally, the test leads of the M test layers may at least partially have reflection sites which differ from each other with respect to the position and / or with respect to the shape. The M test layers, in particular the test lines of the M test layers, can thus each have a different design or layout, which makes it possible to distinguish the M test layers by means of a current and / or voltage measurement, in particular by means of a time domain reflectometer measurement. Thus, a particularly efficient detection of a manufacturing error of a printed circuit board is made possible.

In another aspect, a benefit is described for at least one printed circuit card comprising the test coupon described in this document.

According to a further aspect of the invention, a method for checking a printed circuit board is described. The printed circuit board was produced in a utility together with a test coupon, the test coupon preferably being designed as described in this document.

The printed circuit board has M layers, with M equal to 2 or more, the layers being electrically isolated from each other by a substrate or a laminate. The test coupon has corresponding M test layers, the M layers of the printed circuit board being assigned in a desired state (ie the M desired positions) to M reference test layers of the test coupon. The M reference test layers provide M reference values for the measurement of at least one electrically relevant property. Alternatively or additionally, the one or more, in particular the M-1, substrates of the printed circuit board in the nominal state can each have reference values with respect to a substrate thickness and / or with respect to a dielectric property. The method comprises capturing sensor data for the M test layers of the test coupon by measuring the at least one electrically relevant property. In particular, sensor data can be detected by means of a time domain reflectometer. For this purpose, the time domain reflectometer can be connected to the individual contact points of test leads of the M test layers.

In addition, the method includes detecting a manufacturing error of the printed board based on the sensor data and based on the reference values. The detected sensor data may include an actual value corresponding to the reference value for each test position. Alternatively or additionally, the sensor data may be such that an actual value corresponding to the reference value can be determined on the basis of the sensor data for each test position. The method may then include (possibly in pairs) comparing the actual values with the corresponding reference values. It can then be detected based on the comparison, a manufacturing error of the printed circuit board. Furthermore, based on the comparison, if necessary, an order of the M reference test positions and the positions of the printed circuit board assigned to the M reference test positions can be determined.

Thus, a method is described which enables efficient and non-destructive monitoring of the production of printed circuit boards. In this case, due to the high efficiency of the described method, if necessary, each produced benefit (and the one or more printed circuit boards contained thereon) can be checked.

The electrically relevant property used to detect the different reference test locations may include one or more of: the impedance of a test lead or a test pad; a property of a test line or a test location determined by time domain reflectometry; the length of a test line; the presence of a reflection point separate from the end of a respective test line on a test line at which an electrical pulse is at least partially reflected; and / or the position and / or the shape of a reflection point on a test line. Thus, different reference test layers can be identified in an efficient and reliable manner in order to detect manufacturing errors of a printed circuit board.

The method may include determining, on the basis of the sensor data, actual impedance values of the respective impedance of the M test layers, in particular the Test leads of the M test layers. The reference values can indicate reference impedance values for the M test positions, in particular for the M test lines. On the basis of the actual impedance values (and on the basis of the reference impedance values), a defective thickness and / or a faulty dielectric property of at least one substrate of the printed circuit board can then be detected.

Alternatively or additionally, an actual length of at least one of the test lines of the M test layers, and / or an actual position and / or an actual shape of a reflection point on at least one of the test lines of the M test layers can be determined on the basis of the sensor data. The reference values may include a reference length of the at least one test line, a reference position of the reflection point and / or a reference shape of the reflection point of the at least one test line. It can then be detected on the basis of the actual length, the actual position and / or the actual shape (and on the basis of the reference length, the reference position and / or the reference shape) a faulty position of the printed circuit board.

It should be noted that any aspects of the test coupon described in this document and the method described in this document may be combined in a variety of ways. In particular, the features of the claims can be combined in a variety of ways.

Furthermore, the invention will be described with reference to embodiments illustrated in the accompanying drawings. Show

 FIG. 1 a shows an exemplary benefit with a multiplicity of printed circuit boards and a test coupon in a plan view;

 FIG. 1b shows an exemplary multi-layer printed circuit board or an exemplary multi-layered benefit in a side view;

 FIG. 2a shows an exemplary layer structure of a test coupon;

 FIGS. 2b to 2d show exemplary test layers of a test coupon; and

 FIG. 3 shows a flow diagram of an exemplary method for checking a printed circuit board on the basis of a test coupon.

As stated above, this document deals with quality assurance in printed circuit board manufacturing. In this connection, FIG. 1 a shows a utility 100 (ie, a total circuit board) that has multiple (possibly identical) circuit boards or circuit boards 101 in the illustrated example. The utility 100 is manufactured in a single manufacturing process, thus making it possible to produce multiple circuit boards 101 in a single manufacturing process. A patch of the benefit 100 may be used to make at least one test coupon 110. A test coupon 110 may be used, for example, to check the impedance values of the lines of individual layers of the printed circuit boards 101.

1 b shows the layer structure of an exemplary four-ply benefit 100. To produce a benefit 100, a laminate or substrate 122 can be coated from both sides with a conductive layer or layer 121 (in particular a layer of copper). As part of an etching process, conductor tracks can then be produced in the layers 121. Thus, a two-layer printed circuit board with electrical leads on both sides of a substrate 122 can be manufactured. In other words, two-layer printed circuit boards can be produced with layers 121 having a specific design or layout.

Two of these two-layer circuit boards can then be connected to one another via another substrate 123 (in particular a so-called "pre-preg") in order to produce a four-layered utility 100. By stacking N two-ply circuit boards, thus, utility 100 and circuit boards 101 having a total of M = 2N layers 121 can be made (e.g., N = 2, 3, 4, 5, or more).

When producing a benefit 100, manufacturing errors can occur. Exemplary manufacturing defects are:

 Defective properties (e.g., thickness, material, dielectric constant, etc.) of a

Substrate 122, 123; and or

 A swapping of the layers 121 (for example, several two-ply

Circuit boards are assembled in the wrong order to produce a utility 100 and a printed circuit board 101, respectively.

The test coupon 110 of a benefit 100 is produced in the same manufacturing process as the leader cards 101 on the benefit 100. As a result, manufacturing errors in the production of a benefit 100 also affect a test coupon 110 io

of benefit 100 off. The test coupon 110 of a benefit 100 can thus be used to detect manufacturing errors.

2a shows the layer structure of an exemplary test coupon 110. The test coupon 110 has a reference surface 212 and at least one test line 211, 213 in each layer 241 (also referred to as test layer in this document). In this case, the test power 211 may be formed in an outer layer 241 as a microstrip and the test line 213 of an intermediate layer 241 as a stripline. The reference surface 212 of a layer 241 can be formed by the largely continuous electrically conductive layer (in particular the copper layer) of the layer 241. In one or more localized isolation regions 215, the electrically conductive layer of the layer 241 may be removed to form a test line 211 electrically isolated from the reference surface 212.

As shown in FIG. 2 a, reference surfaces 212 and test lines 21 1, 213 can alternate in directly successive layers 24, so that the test line 213 of an intermediate layer 241 is surrounded by the reference surfaces 212 of the two directly adjacent layers 241. Furthermore, the test line 211 of an outer layer 241 has a reference surface 212 in exactly one directly adjacent layer 241. Fig. 2a further illustrates vias (vias) 214 through which the reference surfaces 212 of the different layers 241 may be electrically conductively connected (particularly grounded).

Such a layer construction may provide a test coupon 110 comprising for each layer 241 at least one test line 211, 213 having a unique relationship with at least one reference surface 212 and / or at least one reference potential (e.g., GND). This allows a reliable setting of at least one electrically measurable property of the layers 241 of a test coupon 110, which enables efficient and reliable identification of different layers 241 of a test coupon 110.

FIGS. 2b to 2d show exemplary layers 241 of a test coupon 110 in a top view (ie along the surface of a test coupon 110). As can be seen in FIGS. 2b to 2d, the layers 241 each have an electrically conductive reference surface 212 which can cover much of the total area of a layer 241 (eg 70%, 80% or more). Furthermore, the layers 241 each have a test line 21 1, 213, which is electrically insulated from the reference surface 212 by an insulating region 215. The insulating region 215 may be formed by removing the conductor material of a layer 241.

As already stated above, the test leads 21 1, 213 may be arranged alternately on a first side (see FIG. 2 b) or on a second side (see FIG. 2 c) of the test coupon 110 (with respect to a transverse direction 232 of the test coupon 110 ). Furthermore, the test leads 21 1, 213 may extend along a longitudinal direction 231 of the test coupon 110. The test line 211, 213 of a layer 241 is preferably designed such that the test line 21 1, 213 can be electrically contacted via a contact point or via a contact point 220. Thus, the test coupon 110 may be constructed such that the individual test leads 21 1, 213 of the individual layers 241 can each be contacted electrically individually via a contact point 220.

The test lines 21 1, 213 in the different layers 241 can be constructed differently. In other words, the test lines 21 1, 213 may have different property values for one or more measurable characteristics. The one or more properties may be such that they can be detected by means of an electrical measuring method (in particular by means of a time domain reflectometer). For example, properties are

 The length 221 of the test line 211, 213 along the longitudinal direction 231 of the test coupon 110;

 The width 222 of the test line 21 1, 213 along the transverse direction 232 of the test coupon 110; and or

 An impurity or reflection point 223 on the test line 21 1, 213; whereby e.g. the width 225 and / or the position 224 and / or the length 226 of the defect 223 on the test line 21 1, 213 can be varied.

By varying one or more properties of the one or more test leads 211, 213, different layers or test layers 241 with different properties can thus be provided. For a printed circuit board 101 with M layers (eg M = 2, 4, 6, 8, 10 or more), M test lines 21 1, 213 or M test layers can be defined, each of which has a uniquely identifiable combination of property values of one or more properties exhibit. The different layers 121 of a printed circuit board 101 to be produced can then each be assigned one of the different test layers 241 as reference test layers. The properties of the test layers 241 and the test lines 21 1, 213 can then be used to check whether or not there is a manufacturing error of the printed circuit board 101.

In one example, the layers 121m = 1, ..., M of a printed circuit board 101 are assigned the reference test layers m = 1, ..., M, i. the layer 121 m = 1 is produced together with the test layer 241 m = 1, the layer 121 m = 2 together with the test layer 241 m = 2, etc. In this case, the assignment preferably takes place in such a way that, in the case of a defect-free production 100, the alternating structure of test line 211, 213 and reference surface 212 shown in FIG. 2b results.

After producing a benefit 100, the properties of the different test layers 241 of the test coupon 110 can be measured. For this purpose, e.g. A Time Domain Reflectometer may be used to detect sensor data related to the length 221 of a test line 21 1, 213 and / or to an impurity 223 on a test line 21 1, 213. Thus, sensor data relating to the individual test layers 241 of a test coupon 110 can be detected. The sensor data can then be compared with reference data for the reference test positions m = 1,..., M of the test coupons 110. From the comparison, it can then be determined whether there is a manufacturing error or not.

In a test coupon 110, a test line 211, 213 (in each case a microstrip 21 1 in the outer layers 241, in each case one stripline 213 in the one or more inner layers 241) can thus be applied in each layer 241. The test lines 21 1, 213 can each be measured with a Time Domain Reflectometer. In particular, the test lines 21 1, 213 can be measured with regard to their impedance and / or their length 221. In a defect-free manufactured use 100 or test coupon 110, a typical impedance results for each layer 121, 241 of the utility 100. If this impedance is exceeded or undershot for at least one layer 241 of a test coupon 110, then it can be concluded that false dielectrics or dielectrics with a different layer thickness have been used as substrates 122, 123.

The lengths 221 of the individual test lines 21 1, 213 of a test coupon 110 can be different and it can be determined by measuring the lengths 221 (position assignment over the length 221 of the individual test lines 21 1, 213), whether layers 121, 241 in the layer structure of the benefit 100 were reversed. The test leads 211, 213 in the individual layers 241 of a test coupon 110 can also be at least partially the same length. In these cases, test lines 211, 213 (typically short) (reflection) locations 223 may have different impedance (e.g., line widening or line thinning). These impurities 223 may be in any position 241 of the test coupon 110 at a different position 224 to ensure a unique location assignment. It can thus be a position assignment on the position 224 of interference or reflection points 223 done. Alternatively or additionally, the interference or reflection points 223 in the individual layers 241 may have different lengths 226.

3 shows a flowchart of an exemplary method 300 for testing a multilayer printed circuit board 101. The printed circuit board 101 has been produced in a utility 100 together with a test coupon 110. Further, the circuit board 101 has M layers 121, with M equal to 2 or more, each electrically isolated from each other by a substrate 122, 123. The test coupon 110 has corresponding M test plies 241.

The M layers 121 of the printed circuit board 101 are assigned in a desired state M reference test layers 241 of the test coupon 1 10. In particular, the printed circuit board 101 in a desired state M may have target positions 121 with a specific desired design. The different desired positions 121 are assigned M different reference test positions 241 of the test coupon 110. This can be achieved, for example, by virtue of the fact that the masks for producing the different layers 121 of the utility 100 each have the design a desired position 121 and the design of the respectively assigned reference test layer 241 have.

It can then be checked whether the test coupon 110 has the M reference test plies 241 (in the correct order). If this is the case, it can be concluded that also the circuit board 101 manufactured in the same utility 100 has the M target layers 121 (in the correct order). On the other hand, it can be concluded that a manufacturing error of the printed circuit board 101. Furthermore, if necessary, a specific manufacturing defect can be identified.

The M reference test plies 241 are designed in such a way that the M reference test plies 241 deliver at least one electrically relevant property (at least) M (different) reference values during (non-destructive) measurement. If necessary, values for Q different electrically relevant properties can be defined (with Q = 1, 2, 3, or more). For each property and for each test layer 241, at least one reference value can then be provided in each case. The different reference test plies 241 can thus be identified by measuring one or more electrically relevant properties based on the reference values for the one or more electrically relevant properties. The measurement of values of the one or more electrically relevant properties can take place on the basis of a time domain reflectometry of the M reference test plies 214, in particular of the test leads 211, 213 of the M reference test plies 214.

The method 300 includes detecting 301 sensor data for the M test layers 241 of the test coupon by measuring the at least one electrically relevant property. In particular, sensor data relating to the M test plies 241 can be detected by means of a time domain reflectometer. In addition, the method 300 includes detecting 302 a manufacturing error of the printed board 101 based on the sensor data and based on the reference values.

The measures described in this document enable efficient quality assurance in the production of printed circuit boards 101. In this case, it can be checked in particular whether the correct dielectrics have been used for the substrates 122, 123 of a printed circuit board 101. Alternatively or additionally, the layer structure of a printed circuit board 101 are checked. It can do the verification without using a destructive

Measurement, which leads to a reduction in the cost of quality assurance. In addition, a production-accompanying test per benefit 100 and / or per production lot is made possible by the measures described. Furthermore, the identification of manufacturing problems can be facilitated by the measures described.

The present invention is not limited to the embodiments shown. In particular, it should be noted that the description and the figures are only intended to illustrate the principle of the proposed test coupon and the proposed method.

Claims

A test coupon (10) for use (100) with at least one printed circuit board (101); wherein the circuit board (101) has M layers (121), with M equal to 2 or more, each electrically isolated from each other by a substrate (122, 123); in which

the test coupon (110) comprises M test plies (241) for the respective M plies (121) of the printed circuit board (101);

 - the M test layers (241) each have an electrically conductive reference surface (212) and one of them electrically insulated test line (211, 213); and

 - The reference surface (212) of a test layer (241) as a reference position for the test line (212, 213) of a directly adjacent test layer (241) is formed.

2. test coupon (110) according to claim 1, wherein

 the test coupon (110) has a center line extending along a longitudinal direction (231) of the test coupon (110) which divides the test coupon into a first half and a second half;

 - The test lines (211, 213) of the M test layers (241) are arranged alternately in the first half and in the second half; and

 - The reference surfaces (212) of the M test layers (241) in a complementary manner to the test lines (21 1, 213) are arranged alternately at least for the most part in the second half and in the first half.

3. test coupon (110) according to any one of the preceding claims, wherein

 the test coupon (110) has a longitudinal direction (231) and a transverse direction (232);

 - The test Coupon (1 10) in the longitudinal direction (231) is greater than in the transverse direction (232); and

 - The test lines (211, 213) of the M test layers each extend largely along the longitudinal direction (231).

4. test coupon (110) according to any one of the preceding claims, wherein - The reference surfaces (212) of the M test layers (110) via one or more vias (214) are electrically conductively connected to each other; and or

 - Cover the reference surfaces (212) of the M test layers (1 10) each 70%, 80% or more of a total area of the respective test layer (241); and or

 - The reference surfaces (212) of the M test layers (110) are each connected to ground and / or ground.

5. test coupon (1 10) according to any one of the preceding claims, wherein the test lines (211, 213) of the M test layers (110) each have a contact point (220) via which the test leads (211, 213) can each be electrically contacted individually ,

6. test coupon (110) according to one of the preceding claims, wherein the M test layers (110), in particular the test lines (21 1, 213) of the M test layers (1 10), differ from each other such that the M test layers (110) Based on current and / or voltage measurements on the M test lines (211, 213) can be distinguished from each other.

7. test coupon (1 10) according to one of the preceding claims, wherein the test leads (21 1, 213) of the M test layers (1 10)

 - have at least partially different lengths (221); and or

 - have at least partially different impedances; and or

 at least partially have a reflection point (223) separate from one end of the respective test line (211, 213), at which an electrical pulse is at least partially reflected; and or

 at least partially have reflection sites (223) which differ from each other with respect to a position (223) and / or with respect to a shape.

8. test coupon (110) according to any one of the preceding claims, wherein

- The circuit board (101) in a desired state M target positions (121), each having a desired design; - The one or more substrates (122, 123) of the printed circuit board (101) in the desired state each have set values with respect to a thickness and / or a dielectric property;

 the M test plies (241) of the test coupon (1 10) are designed to deliver different reference values in the desired state in the non-destructive measurement of at least one electrically relevant property of the M test plies (241);

 the M test plies (241) are associated with the M set plies (121) in a one-to-one relationship so that a manufacturing defect of the printed circuit board (101) can be detected by performing the non-destructive measurement on the test coupon (110) ; and

 - the manufacturing defect includes in particular:

 an erroneous order of the M target positions (121);

 - At least one layer (121) which does not correspond to the required target position (121); and or

 - At least one substrate (122, 123) with a defective thickness and / or a faulty dielectric property.

A method (300) of inspecting a printed circuit board (101) produced in a utility (100) together with a test coupon (110); wherein the circuit board (101) has M layers (121), with M equal to 2 or more, each electrically isolated from each other by a substrate (122, 123); wherein the test coupon (110) has corresponding M test plies (241); wherein the M layers (121) of the printed circuit board (101) are assigned in a desired state M reference test plies (241) of the test coupon (110) which supply at least M reference values when measuring at least one electrically relevant property; the method (300) comprising

 - detecting (301) sensor data for the M test layers (241) of the test coupon by measuring the at least one electrically relevant property; and

 - Detecting (302) a manufacturing error of the printed circuit board (101) on the basis of the sensor data and based on the reference values.

10. The method (300) according to claim 9, wherein - The sensor data for each test layer (241) comprise an actual value corresponding to the reference value;

 the method (300) comprises pairwise comparing the actual values with the corresponding reference values; and

 - Based on the comparison, a manufacturing error of the printed circuit board (101) is detected.

The method (300) of claim 10, wherein the method (300) comprises, based on the comparison, determining an order of the M reference test plies (241) and the plies associated with the M reference test plies (121) (121 ) of the printed circuit board (101).

12. The method according to claim 9, wherein the electrically relevant property comprises

 - An impedance of a test line (211, 213) of a test layer (241);

 a property of a test line (21 1, 213) determined by time domain reflectometry;

 a length (221) of a test line (211, 213);

 the presence of a reflection point (223) separate from one end of a respective test line (211, 213) on a test line (211, 213) at which an electrical pulse is at least partially reflected; and or

 - A position (224) and / or a shape (226) of a reflection point (223) on a test line (211, 213).

13. The method (300) of claim 9, wherein the method comprises (300)

 Determining, based on the sensor data, actual impedance values of a respective impedance of test lines (21 1, 213) of the M test plies (241); wherein the reference values indicate reference impedance values for the M test leads (21 1, 213); and

- Detecting (302) a defective thickness and / or a defective dielectric property of at least one substrate (122, 123) of the printed circuit board (101) on the basis of the actual impedance values.

14. Method (300) according to one of claims 9 to 13, wherein the method comprises (300)

 Determining, on the basis of the sensor data, an actual length (221) of at least one of the M test lines (211, 213), and / or an actual position (224) and / or an actual shape (226) of a reflection point (223 ) on at least one test line (21 1, 213) of the M

Test locations (241); wherein the reference values comprise a reference length (221), a reference position (224) of the reflection site (223), and / or a reference shape (226) of the reflection site (223) of the at least one test line (211, 213); and

 Detecting (302) a faulty position (121) of the printed circuit board (101) on the basis of

Actual length (221), the actual position (224) and / or the actual shape (226).

15. Method (300) according to claim 9, wherein the one or more, in particular the M-1, substrates (122, 123) of the printed circuit board (101) in the nominal state respectively have reference values with respect to a substrate thickness and / or with respect to a dielectric property.