Source: https://patents.google.com/patent/KR101222802B1/en
Timestamp: 2020-04-02 23:13:01
Document Index: 271851259

Matched Legal Cases: ['art 4', 'art 5', 'art 3', 'art 3', 'art 3', 'art 22', 'art 23', 'art 21', 'art 21', 'art 22', 'art 22', 'art 22', 'art 23', 'art 23', 'art 21', 'art 23', 'art 23', 'art 22']

KR101222802B1 - Circuit board inspection apparatus and method - Google Patents
KR101222802B1
KR101222802B1 KR1020070117760A KR20070117760A KR101222802B1 KR 101222802 B1 KR101222802 B1 KR 101222802B1 KR 1020070117760 A KR1020070117760 A KR 1020070117760A KR 20070117760 A KR20070117760 A KR 20070117760A KR 101222802 B1 KR101222802 B1 KR 101222802B1
KR1020070117760A
KR20080049624A (en
무네히로 야마시타
니혼덴산리드가부시키가이샤
2006-11-30 Priority to JPJP-P-2006-00322850 priority Critical
2006-11-30 Priority to JP2006322850A priority patent/JP4918339B2/en
2007-11-19 Application filed by 니혼덴산리드가부시키가이샤 filed Critical 니혼덴산리드가부시키가이샤
2008-06-04 Publication of KR20080049624A publication Critical patent/KR20080049624A/en
2013-01-15 Publication of KR101222802B1 publication Critical patent/KR101222802B1/en
Provided is a substrate inspection apparatus which can be inspected without causing damage to a pseudo short section between adjacent wiring patterns.
Substrate inspection apparatus which produces | generates a potential difference between inspection points 12a and 12b on the test | inspection board | substrate 11, and examines the electrical characteristic of the wiring pattern 13 between inspection points by extracting a test signal from an inspection point. A plurality of probes 2a and 2b which are directly or indirectly connected to the inspection point, an output unit 3 for generating a potential difference between the inspection points via the probe, and from the inspection point through the probe at the time of applying the potential difference. The detection part 4 which detects a signal is provided, and the output part examines the potential difference so that the pseudo short part which the pseudo short-circuit between adjacent wiring patterns conducts and is not destroyed by the electric current which flows through this pseudo short part is provided. Occurs between points.
Substrate inspection device and substrate inspection method {CIRCUIT BOARD INSPECTION APPARATUS AND METHOD}
The present invention relates to a substrate inspection apparatus and a method for generating an electric potential difference between inspection points on a test target board and inspecting electrical characteristics of wiring patterns between the inspection points by extracting a signal for inspection from the inspection point. will be.
In addition, this invention is not limited to a printed wiring board, For example, in various board | substrates, such as a flexible board | substrate, a multilayer wiring board, the electrode board for liquid crystal displays or a plasma display, and a package board | substrate and a film carrier for semiconductor packages, for example. It is applicable to the inspection of the electrical wiring, and in this specification, these various wiring boards are collectively called "substrate."
In the case where there is a minute short circuit portion between the wiring patterns to be inspected, if a general potential difference is generated between the inspection points of the wiring pattern, the minute short circuit portion is burned out by overcurrent, which causes problems such as poor insulation. Problems such as incorrect determination of the test target substrate may occur.
A conventional board inspection apparatus in this regard is to change the voltage value or current value given to a wiring pattern step by step, thereby performing inspection while preventing the defective insulation part of the wiring pattern from being burned out by overcurrent. (Patent Document 1).
However, the problem caused by the burnout of the inspection target board is still in the present state until it is completely solved.
Patent Document 1: Japanese Patent Application Laid-Open No. 6-230058
In view of such a situation, the inventors of the present application have investigated the cause of the burnout of the inspected substrate generated at the time of inspection, and as a result, an unresolved burnout is caused by a pseudo short circuit between adjacent wiring patterns. It was found that a physician section was included.
Then, the problem to be solved of this invention is providing the board | substrate inspection apparatus which can test | inspect without damaging about the pseudo short part which the pseudo wiring shorted between adjacent wiring patterns.
MEANS TO SOLVE THE PROBLEM In order to solve the said subject, in invention of Claim 1, a potential difference is produced between the test points set on the some wiring pattern on a to-be-tested board | substrate, and the said wiring is carried out by taking out the test signal from the said test point. A substrate inspection apparatus for inspecting electrical characteristics between patterns, comprising: a plurality of probes in conductive contact with the inspection point, an output portion for generating a potential difference between the inspection points through the probe, and the probe at the time of applying the potential difference A detection section for detecting a signal from the inspection point through the output section, wherein the output section has a pseudo short section conducting pseudo short-circuited between adjacent wiring patterns and is not burned out by a current flowing through the pseudo short section. A potential difference is generated between the check points.
Furthermore, in the invention of claim 2, in the substrate inspection apparatus according to the invention of claim 1, the potential difference generated between the inspection points by the output unit is intermittently interposed so as to bridge between adjacent wiring patterns. The pseudo short circuit formed in this manner is brought into a conducting state from a non-conductive state, and the pseudo short circuit is set to a level which does not burn out by a current.
Further, in the invention of claim 3, in the substrate inspection apparatus according to the invention of claim 1, the potential difference generated between the inspection points by the output unit is intermittently interposed so as to bridge between adjacent wiring patterns. The pseudo short-circuit formed of one or a plurality of fine conductor grains or fine conductor pieces, which are formed in succession, is brought into a conducting state from a non-conductive state, and the pseudo short-circuit is not damaged by current. It is set to the level.
Further, in the invention of claim 4, in the substrate inspection apparatus according to any one of claims 1 to 3, the output section changes the potential difference generated between the inspection points so as to increase in stages, At any level of the plurality of potential difference levels that are varied in stages, the potential difference in which the pseudo short portion is conducted and does not burn out is substantial.
Further, in the invention of claim 5, in the substrate inspection apparatus according to the invention of claim 4, the pseudo short circuit portion is not burned to the plurality of potential difference levels generated between the inspection points by the output unit. The potential difference smaller than the potential difference, and the minute short circuit portion continuously formed to bridge between the adjacent wiring patterns does not burn out by the current flowing through the minute short circuit portion, and the potential difference in which the pseudo short portion is conductive and does not burn out. It is large and the potential difference for detecting a current leak by the spark between the said wiring patterns is included.
Further, in the invention of claim 6, an electric potential between the wiring patterns is obtained by generating a potential difference between inspection points set on the plurality of wiring patterns of the inspection target board, and extracting a signal for inspection from the inspection points. A substrate inspection apparatus for inspecting, comprising: a plurality of probes in conductive contact with the inspection point, an output unit for generating a potential difference between the inspection points through the probe, and a current value flowing between the inspection points when the potential difference is applied. While controlling the detection unit and the output unit, a resistance value between the inspection points is derived based on the potential difference applied between the inspection points and the detection current value of the detection unit, and the derived resistance value is compared with a predetermined determination reference resistance value. The control part which makes a determination regarding the presence or absence of insulation defect of the said wiring pattern is provided, The fisherman is able to set the magnitude of the potential difference generated by the output section between the inspection points according to the defect of the substrate under test, and set the magnitude of the determination reference resistance value according to the magnitude of the potential difference. Board inspection apparatus enabled.
Furthermore, in the invention of claim 7, in the substrate inspection apparatus according to the invention of claim 6, the potential difference includes a first potential difference value, a second potential difference value larger than the first potential difference value, and the first potential difference value. It is set so that switching to the third potential difference value larger than 2 potential difference values, The said determination reference resistance value is provided with respect to the 1st reference resistance value provided with respect to the said 1st potential difference value, and the said 2nd potential difference values, A second reference resistance value larger than the first reference resistance value and a third reference resistance value provided for the third potential difference value and larger than the first reference resistance value and smaller than the second reference resistance value. It is set to be switchable.
Furthermore, in the invention of claim 8, a potential difference is generated between inspection points set on the plurality of wiring patterns on the inspection target board, and the electrical signals between the wiring patterns are detected by detecting a test signal from the inspection points. A substrate inspection method for inspecting characteristics, wherein the potential difference is set to a range of three levels of small, medium, and large so as to gradually increase the potential difference according to a defect of the inspected substrate. In response to the range of the three stages of medium and large, the reference electrical characteristics serving as a standard for determining the defectiveness of the inspected substrate are set to three stages of small, large and medium.
According to the invention of claims 1 to 5, the inspection is performed by setting the potential difference given to the wiring pattern to a potential difference in which a pseudo short circuit part electrically shorted between adjacent wiring patterns is conducting and does not burn out. Therefore, the inspection can be performed without damaging the pseudo short circuit.
According to the invention as claimed in claim 4, the inspection can be performed without causing damage to various insulation failure points and the like including the pseudo short section.
According to the invention as claimed in claim 5, the minute short circuit portion, the pseudo short circuit portion, and the spark between the wiring pattern are inspected without causing damage due to overcurrent of the micro short circuit portion and the pseudo short circuit portion. Can be done.
According to the invention as claimed in claim 6, since the potential difference applied according to the defect of the substrate is adjusted to detect the defect, accurate defect inspection can be performed.
According to the invention as claimed in claim 7, the output unit changes the order of the potential difference between the inspection points in the order of small, medium, and large, and in response to the determination criterion resistance value for the insulation failure in the small, large, and medium order. In order to prevent the burnout caused by overcurrent, various damages such as minute short circuits between the wiring patterns, pseudo short circuits, and current leakage due to sparks between the wiring patterns can be prevented. Inspections corresponding to other causes of poor insulation can be performed individually.
According to the invention of claim 8, the output unit changes the potential difference between the inspection points in the order of small, medium, and large, and in response to the determination criterion resistance value for the insulation failure, the small, large, and medium changes. In order to prevent the burnout caused by overcurrent, various damages such as minute short circuits between the wiring patterns, pseudo short circuits, and current leakage due to sparks between the wiring patterns can be prevented. Inspections corresponding to other causes of poor insulation can be performed individually.
1 is a block diagram of a substrate inspection apparatus according to an embodiment of the present invention. As shown in FIG. 1, the substrate inspection apparatus 1 includes a plurality of probes 2a and 2b, an output unit 3 for supplying a current or voltage for inspection, and probes 2a and 2b. The detection unit 4 which detects the voltage value or the current value of the signal imparted through the control unit, the control unit 5, and the plurality of switches 6a and 6b are provided, and the inspection points 12a, The electrical potential of the wiring pattern 13 between the inspection points 12a and 12b is examined by generating a potential difference between the inspection points 12a and 12b.
The output unit 3 supplies a current or voltage of a predetermined level for inspection between the inspection points 12a and 12b through the probes 2a and 2b under the control of the control unit 5.
The inspection unit 4 controls the inspection point through the probes 2a and 2b when a current or voltage is supplied to the inspection points 12a and 12b by the output unit 3 under the control of the control unit 5. The potential difference between 12a and 12b or the current value flowing between check points 12a and 12b is detected.
The switches 6a and 6b are retrofitted on the wirings 7a and 7b connecting the output unit 3 and the detection unit 4 and the probes 2a and 2b to control the control unit 5. As a result, the connection between the output unit 3 and the detection unit 4 and the probes 2a and 2b is switched.
The control part 5 controls the output part 3, the test | inspection part 3, and switches 6a and 6b, and test | inspects the electrical characteristic of the wiring pattern 13 of the board | substrate 11 to be tested. The inspection contents include the conduction inspection and the short circuit inspection.
In the conduction inspection, it is checked whether or not each wiring pattern 13 in the inspection target board 11 is electrically conducting without a problem. More specifically, the detection unit 4 inspects the output unit 3 while supplying a current having a predetermined current value (for example, 20 mA) between the inspection points 12a and 12b through the probes 2a and 2b. The potential difference between the points 12a and 12b is detected. Then, the resistance value of the wiring pattern 13 between the inspection points 12a and 12b is calculated based on the supply current value and the detected potential difference value at that time, and the derived resistance value and the predetermined determination reference value (for example, By comparing about 30 ?, the conduction characteristics (whether or not normally conducting, etc.) of the wiring pattern 13 are examined.
In the short-circuit inspection, the wiring pattern 13 to be insulated substantially is checked for insulation failure such as short circuit. More specifically, between the two inspection points 12a and 12b electrically connected to the two wiring patterns 13 which should be insulated from each other, the predetermined voltage value set in multiple steps through the probes 2a and 2b. The voltages are sequentially applied, and the detection unit 4 detects the current value flowing between the inspection points 12a and 12b through the probes 2a and 2b in each state where the voltage value of each step is applied. Then, the resistance value between the inspection points 12a and 12b is derived based on the applied voltage value and the detection current value between the inspection points 12a and 12b of each stage, and the derived resistance value and the voltage of each stage are derived. By comparing a plurality of determination reference resistance values set in advance in response to the values, the presence or absence of insulation failure between the wiring patterns 13 to be inspected is inspected. More specifically, when the resistance value derived at the time of applying the voltage in all the steps is larger than the determination reference resistance value set corresponding to the step, it is determined that the insulation is defective, and the resistance value derived in any one or more steps is equal to or less than the determination reference resistance value. Is determined to be poor insulation.
More specifically, in this embodiment, the output voltage value of the output part 3 changes so that it may become large in three steps, and a short circuit test | inspection is performed. That is, the short-circuit test is performed in three stages of the first to the third. The first reference resistance value is used in the first short-circuit inspection, and the second reference resistance value larger than the first reference resistance value is used in the second short-circuit inspection as the determination reference resistance value for the insulation failure determination. In the third short-circuit test, a third reference resistance value larger than the first reference resistance value and smaller than the second reference resistance value is used.
Such conduction inspection and the 1st-3rd short circuit inspection are performed in order (S1-S4) as shown in FIG. 2 mentioned later.
Next, the significance of each of the first to third short circuit inspections according to the present embodiment will be described.
As a result of investigating and examining the cause of the insulation failure of the wiring pattern 13, the inventors of the present invention show that the cause of the insulation failure is a fine short circuit portion 21 as shown in Figs. 3 (a) and 3 (b). And it turned out that the pseudo short part 22 as shown in FIG. 4 and the pattern access part 23 as shown in FIG. 5 are included.
Here, the fine short circuit part 21 shown to FIG. 3 (a) and FIG. 3 (b) relates to the fine short circuit part continuously formed so that the bridge | wire between adjacent wiring patterns 13a and 13b may be bridge | crosslinked. Such fine short circuit portion 21 is caused by, for example, etching residue left without completely removing the unnecessary wiring material to be removed when etching the wiring patterns 13a and 13b. Since such a fine short circuit section 21 is a fine thickness such as a micron order, for example, when a large potential is applied to the wiring pattern 13 during the short circuit inspection, it is destroyed by the current flowing through the fine short circuit section 21. I may throw it away. The resistance value of such a fine short circuit part 21 is about 100 ohms or less in many cases.
In addition, the pseudo short circuit part 22 shown in FIG. 4 pseudo-short-circuits the adjacent wiring patterns 13a and 13b, and causes insulation failure, and bridges between adjacent wiring patterns 13a and 13b. It is formed intermittently so that it may change from a non-conduction state to a conduction state with the increase of the voltage applied to the pseudo short part 22. FIG. Such pseudo short-circuit part 22 is one or a plurality of fine conductor grains or fine conductor pieces (for example, formed intermittently so as to bridge between adjacent wiring patterns 13a and 13b). Fine conductor powder or fine conductor piece made of the material of the wiring patterns 13a and 13b). Also, in the case of such a pseudo short circuit 22, if a large potential is applied to the wiring pattern 13 during a short circuit inspection, the pseudo short circuit 22 may be damaged by the current flowing through the pseudo short circuit 22. FIG. The resistance of the pseudo short section 22 is often about 10 MΩ to about 100 MΩ.
In addition, the pattern access part 23 shown in FIG. 5 arises from the pattern defect at the time of formation of the wiring patterns 13a, 13b, etc., and the adjacent wiring patterns 13a, 13b mutually approached abnormally. It is a part and causes insulation failure by a spark. The resistance value of this pattern access part 23 is substantially infinite before a spark generate | occur | produces, and when a spark generate | occur | produces, it becomes a finite value according to the clearance dimension etc., for example, about 1 MΩ.
Further, as a result of further investigation and examination by the inventors of the present invention, for these insulation failure causes 21 to 23, a short circuit test is performed by applying a test voltage according to the type of the insulation failure cause to the wiring pattern 13. I knew I needed to do it.
FIG. 6 is a diagram showing a relationship between various other causes of insulation failure and a test voltage range in which the insulation failure can be found. The range R1 in FIG. 6 is a range suitable for finding the fine short circuit 21, the range R2 is a range suitable for discovering the pseudo short circuit 22, and the range R3 is a pattern access section 23. It is a suitable range to find.
As shown in FIG. 6, the range R1 is larger than 0V and is about 1.2V or less, More preferably, it is 0.1-1.0V. The upper limit of this R1 is about 1.2 V because there is a risk that the fine short circuit 21 will burn out due to overcurrent when a voltage larger than this is applied.
In addition, the range R2 is in the range of about 0.2V to about 20V, more preferably 1 to 10V. The lower limit of the range R2 is set at about 0.2 V in this manner because the pseudo short section 22 is a discontinuous configuration when viewed minutely, and therefore the pseudo short section 22 does not conduct at an applied voltage below that. to be. The upper limit of the range R2 is about 20 V because the risk that the pseudo short-circuit 22 may be burned out due to overcurrent when a voltage larger than this is applied.
In addition, the range R3 is in a range of about 10 V or more, more preferably 100 V or more. The lower limit of this range R3 is about 10 V because sparks do not occur at a voltage smaller than this and insulation failure cannot be found.
In this way, the range R1 and the range R2 are partly overlapped with each other so that the range of the range R2 is distributed in a region of higher voltage. In addition, in the range R2 and the range R3, the portions of the range R3 are distributed in a region of higher voltage so that a part thereof overlaps each other. In addition, the graphs L1 to L3 in FIG. 6 show the distribution of resistance values (the vertical axis values correspond to the resistance values) in the fine short circuit section 21, the pseudo short circuit section 22, and the pattern access section 23. .
Therefore, in the present embodiment, in response to these various other poor insulation causes 21 to 23, by switching the voltage applied to the wiring pattern 13 at the time of the short-circuit inspection in three stages, various other poor insulation causes 21 To 23) is accurately performed.
That is, in the 1st short circuit test S2 performed at the beginning of the short circuit test S2-S4 shown in FIG. 2, it is larger than 0V suitable for the discovery of the fine short circuit part 21, and is about 1.2V or less (more preferable) Preferably, the first voltage value (for example, about 1 V), which is any value in the first range of 0.1 to 1.0 V (that is, the range in which the fine short circuit portion 21 does not burn out), is selected as the test point ( It is applied between 12a and 12b) to perform a short circuit inspection. At this time, the first reference resistance value used for the insulation failure determination is set to about 50 to 200 k? (For example, 100 k?).
In the subsequent second short-circuit test S3, a second range (ie, pseudo short section 22) of about 0.2 V to about 20 V (more preferably 1 to 10 V) suitable for the discovery of the pseudo short section 22 is provided. Is a value of any one of the ranges of conducting and not being burned out, and applying a voltage value (for example, 10 V) larger than the first voltage value between the check points 12a and 12b to perform a short-circuit test. It is supposed to be done. At this time, the second reference resistance value used for the insulation failure determination is set to about 10 to 200 MΩ (for example, 100 MΩ).
In the subsequent third short-circuit test S4, a spark in the third range (i.e., 100 V or more) of about 10 V or more (more preferably, 100 V or more) suitable for the discovery of the pattern access part 23 (i.e., the spark in the pattern access part 23). The third voltage value (for example, about 250V) which is a value of any one of the ranges which can effectively generate a current leak by the said 2nd voltage value, is between the test points 12a and 12b. It is applied to and performs a short circuit test. At this time, the third reference resistance value used for the insulation failure determination is set to about 1 to 5 MΩ (for example, 2 MΩ).
In this order, the conduction inspection S1 and the first to third short-circuit inspections S2 to S4 subsequent to it are performed, and the inspected substrate 11 determined to have no abnormality in all the inspections S1 to S4 is provided. If it is determined that it is normal and is abnormal in any of the inspections S1 to S4, the inspection is finished without performing any subsequent inspection at that time.
As described above, according to the present embodiment, the short circuit inspection S2 to S4 sets the voltage applied to the wiring pattern 13 to a value such that the pseudo short circuit section 22 conducts and does not burn out. Since the process (S3) which carries out the process is included, the inspection can be performed, without damaging the pseudo short circuit part 22. FIG.
In addition, the voltage applied for the short-circuit inspection is formed between the wiring patterns 13 and set in response to the fine short circuit 21, the pseudo short circuit 22, and the pattern access section 23, which cause insulation failure. First to third short-circuit checks (S2 to S4) are provided, and the first to third short-circuit checks (S2 to S4) are performed in order so that the applied voltage at the time of the test is first performed first. Therefore, the micro short section 21, the pseudo short section 22, and the pattern access section 23 are inspected without causing damage due to overcurrent of the micro short section 21 and the pseudo short section 22. Can be done.
In addition, it is preferable that the inspection method described in the present invention be carried out via the three steps as described above, but using an inspection step (second short inspection S3) in which a pseudo short section can be found. Short-circuit inspection of the first short-circuit inspection S2 and the second short-circuit inspection S3, short-circuit inspection of the second short-circuit inspection S3 and the third short-circuit inspection S4, or first and second short-circuit inspection 2 of the short circuit inspection performed by the potential which can be performed simultaneously, the 2 short circuit inspection of the 3rd short circuit inspection, and the 1st short circuit inspection, and the short circuit inspection performed by the electric potential which can perform a 2nd short circuit inspection and a 3rd short circuit inspection simultaneously. The number of short circuit inspections, such as a meeting short circuit inspection, can also be adjusted.
BRIEF DESCRIPTION OF THE DRAWINGS The block diagram of the board | substrate inspection apparatus which concerns on one Embodiment of this invention.
2 is a flow chart showing an inspection procedure.
Fig. 3A is a plan view schematically showing a state of a minute short circuit portion in a substrate to be inspected, and Fig. 3B is a sectional view of an essential part of Fig. 3A.
4 is a plan view schematically showing a state of a pseudo short circuit portion in an inspection target board;
FIG. 5 is a plan view schematically showing a pattern access part in which a wiring pattern in a test target board has approached abnormally. FIG.
6 is a diagram showing a relationship between various other causes of insulation failure and a test voltage range in which insulation failure can be found.
1: substrate inspection device
2a, 2b: probe
3: output unit
6a, 6b: switch
7a, 7b: wiring
11: test target substrate
12a, 12b: checkpoint
13, 13a, 13b: wiring pattern
21: fine short circuit
22: doctor section
23: pattern access unit
A substrate inspection apparatus that generates a potential difference between inspection points set on a plurality of wiring patterns on a test target board, and inspects electrical characteristics between the wiring patterns by extracting a signal for inspection from the inspection point.
A plurality of probes in conductive contact with the inspection point;
An output unit for generating a potential difference between the inspection points through the probe;
A detection section for detecting a signal from the inspection point through the probe at the time of applying the potential difference,
The output unit changes the potential difference generated between the inspection points to increase in stages,
In the plurality of potential difference levels that are changed in stages,
A potential difference in which a pseudo short section is electrically shorted between adjacent wiring patterns and is not burned by a current flowing through the pseudo short section,
A potential difference that is smaller than the potential difference at which the pseudo short portion is not burned out, and the minute short circuit part continuously formed to bridge the adjacent wiring patterns is not burned out by a current flowing through the minute short circuit part,
And a potential difference for detecting a current leak due to a spark between the wiring patterns, wherein the pseudo short portion is larger than the potential difference that is conductive and does not burn out.
The potential difference generated between the inspection points by the output unit is
The said board | substrate inspection part formed intermittently so that the bridge | crosslinking of the adjacent wiring patterns may become a conduction state from a non-conduction state, and the board | substrate inspection apparatus characterized by setting it at the level which does not burn out by an electric current. .
The pseudo short circuit portion formed of one or a plurality of fine conductor grains or fine conductor pieces which are intermittently formed so as to bridge between the adjacent wiring patterns is brought into a conductive state from a non-conductive state, and the pseudo short portion is connected to a current. The board | substrate test | inspection apparatus characterized by being set to the level which does not burn out.
A substrate inspection apparatus that generates a potential difference between inspection points set on a plurality of wiring patterns of a test target board, and inspects electrical characteristics between the wiring patterns by extracting a signal for inspection from the inspection point.
A detection section for detecting a current value flowing between the inspection points when the potential difference is applied;
While controlling the output unit, the resistance value between the inspection points is derived based on the potential difference applied between the inspection points and the detected current value of the detection unit, and the derived resistance value is compared with a predetermined determination reference resistance value. It is provided with the control part which makes a determination about the presence or absence of insulation failure of a pattern,
The magnitude of the potential difference generated by the output section between the inspection points can be set in accordance with the defect of the inspection target board, and the magnitude of the determination reference resistance value can be set in accordance with the magnitude of the potential difference. There is,
The potential difference is,
The first potential difference value,
A second potential value greater than the first potential value,
Is set to be switchable to a third potential difference value larger than the second potential difference value,
The determination criterion resistance value,
A first reference resistance value provided with respect to said first potential difference value,
A second reference resistance value provided for the second potential difference value and larger than the first reference resistance value;
And a third reference resistance value which is provided for the third potential difference value and which is larger than the first reference resistance value and smaller than the second reference resistance value.
KR1020070117760A 2006-11-30 2007-11-19 Circuit board inspection apparatus and method KR101222802B1 (en)
JPJP-P-2006-00322850 2006-11-30
JP2006322850A JP4918339B2 (en) 2006-11-30 2006-11-30 Board inspection equipment
KR20080049624A KR20080049624A (en) 2008-06-04
KR101222802B1 true KR101222802B1 (en) 2013-01-15
ID=39486937
KR1020070117760A KR101222802B1 (en) 2006-11-30 2007-11-19 Circuit board inspection apparatus and method
JP (1) JP4918339B2 (en)
KR (1) KR101222802B1 (en)
CN (1) CN101191811B (en)
TW (1) TWI412765B (en)
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