JPH06258394A - Coordinate correcting method for board tester with movable probe - Google Patents

Abstract

PURPOSE:To realize a method for correcting coordinates of a board tester having a movable probe in which various positional deviations including offset, rotation, elongation, contraction of a coordinates shaft can be corrected in X-Y coordinates of the probe. CONSTITUTION:In the case of probing, a position of a hit mark retained on a board to be inspected is measured by an image measuring camera 30. Designated coordinates applied to position control means 81-83 are compared with those of the mark measured by the camera 20, and a coordinate conversion formula [A] between a camera coordinate system and a probe coordinate system is obtained. A position of a position correction mark attached to a known position on the board 1 to be inspected is measured by the camera 20. Known coordinates of the mark are compared with those of the mark measured by the camera, and a coordinated conversion formula [B] between the camera coordinate system and a board coordinated system is obtained. The formulae [A], [B] are coupled to obtain a coordinates conversion formula [C] between the board coordinate system and the probe coordinate system. A position of the probe position to the board coordinates is corrected by using the formula [C].

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for improving the position accuracy of a probe in an in-circuit tester.

[0002]

2. Description of the Related Art An in-circuit tester applies a probe to a board to be inspected, gives a test signal to the board to be inspected through the probe, and is formed on the board to be inspected based on a response signal to the test signal. The quality of the circuit is determined. FIG. 3 shows a configuration example of the in-circuit tester. This in-circuit tester is a stack of two XY tables. The number of XY tables to be stacked may be two or more. In FIG. 3, 1 is a substrate to be inspected, 2 is a table on which the substrate 1 to be inspected is fixed, 3 ₁ and 3 ₂ are X of the table 2.
Guide bars 4 ₁ , 4 ₂ extending in the axial direction are linear motors running along the guide bars 3 ₁ , 3 ₂ and 5 ₁ , 5 ₂ are arms moving in the X-axis direction by the linear motors 4 ₁ , 4 _2. ,
6 _1, 6 ₂ be mounted on the arm 5 _1, 5 _2, drive mechanism (not shown) by head along the arm 5 moves in the Y-axis direction, 7 _1, 7 ₂ heads 6 _1, 6 _The probe is provided in No. ₂ and moves up and down in the Z-axis direction by an elevating mechanism (not shown) to perform probing on the inspection position of the substrate 1 to be inspected. 8 ₁ and 8 ₂ are the X-axis direction of the heads 6 ₁ and 6 ₂ and Y
Position control means for controlling the movement in the axial direction, and 9 ₁ , 9 ₂ for controlling the ascending / descending operation of the probes 7 ₁ , 7 ₂ and a probe control means for exchanging a signal with the substrate 1 to be inspected via the probe, Reference numeral 10 is a C that controls the entire tester by exchanging signals with the position control means 8 ₁ and 8 ₂ and the probe control means 9 ₁ and 9 _2.
It is PU.

In the in-circuit tester having such a structure, the CPU 10 gives the designated coordinates designating the coordinates of the inspection position to the position control means 8 ₁ and 8 ₂ to move the probes 7 ₁ and 7 ₂ to X ,.
By moving in the Y direction, the probes 7 ₁ and 7 ₂ are positioned on the inspection position of the substrate 1 to be inspected. Here, the CPU 10 gives a command to the probe control means 9 ₁ , 9 ₂ to give probes 7 ₁ , 7 _2.
And lower it to the inspection position. In this state, a test signal is applied to the inspected substrate 1, and the quality of the circuit formed on the inspected substrate 1 is determined based on the response signal to the test signal. The two XY tables are used properly according to the inspection position.

In such an in-circuit tester, in order for the coordinates of the tips of the probes 7 ₁ and 7 ₂ provided on the two XY tables to become a common coincident XY coordinate, it is necessary to use each X coordinate.
The machining accuracy and assembly accuracy of the Y table must be improved. In order to achieve a more accurate match, software correction must be performed from the position control means 8 ₁ , 8 ₂ side. Conventionally, the correction for matching the XY coordinates of the two probe tips has been performed by matching the mechanical origins of the two XY tables. As a method for confirming the coincidence, there is a visual method. In addition, there are the following other confirmation methods. That is, a jig substrate having a reference position pattern is prepared, and the reference position pattern is scanned by each probe. Then, the presence or absence of electrical conduction between the pattern and the probe is detected to obtain the edge coordinate of the pattern seen from each probe, and the X and Y coordinate offset between the two probes is calculated from the obtained edge coordinate. However, in such a confirmation method, since the probe is repeatedly applied to the vicinity of the edge of the pattern to obtain the edge coordinates, the vicinity of the edge is missing. As a result, the probe does not hit the pattern accurately, and the edge coordinate detection accuracy deteriorates. Therefore, sufficient correction cannot be performed. Also, with this confirmation method, only the offset of the XY coordinates can be corrected.

[0005]

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and the position of a dent left by a probe on a substrate when probing is measured by an image measuring camera. By indirectly obtaining the relationship between the board coordinate system and the probe coordinate system, and correcting the probe position based on this relationship, the probe position can be corrected with high accuracy, and An object of the present invention is to realize a coordinate correction method for an in-circuit tester that can correct various positional deviations of XY coordinates, including offset, rotation, expansion / contraction of coordinate axes, and the like.

[0006]

The present invention is a coordinate correction method for an in-circuit tester as follows. (1) The substrate to be inspected is mounted on a tester, the probe is moved in a two-dimensional direction along the substrate surface by the position control means, and the probe is lowered when the probe is positioned on the inspection position of the substrate to be inspected. An image of the printed circuit board is taken by the in-circuit tester that contacts the inspection board, sends and receives signals to and from the inspected board via the applied probe for testing, and determines the quality of the circuit formed on the inspection board from the test results. A coordinate correction method for an in-circuit tester, comprising an image measurement camera that measures an image based on a captured image, and correcting the position of the probe according to the following steps. A step of giving designated coordinates to the position control means to determine the position of the probe, and lowering the probe at the determined position to make a dent on the substrate to be inspected. The step of measuring the position of the dent formed in the step of 1. by the image measuring camera. The designated coordinates given to the position control means and the coordinates of the dents measured by the image measuring camera are compared, and from the comparison result, the camera coordinate system for determining the measuring coordinates of the image measuring camera and the designated coordinate of the probe position are determined. A step of obtaining a first coordinate conversion formula for performing coordinate conversion with a defined probe coordinate system. A step of measuring the position of a position correction mark attached to a known position on the inspected substrate with an image measurement camera. The known coordinates of the position correction mark and the coordinates of the position correction mark measured by the image measurement camera are compared,
A step of obtaining a second coordinate conversion formula for performing coordinate conversion between the camera coordinate system and a board coordinate system that defines coordinates on the board to be inspected, from the comparison result. Based on the first coordinate conversion formula and the second coordinate conversion formula,
A step of obtaining a third coordinate conversion formula for performing coordinate conversion between the substrate coordinate system and the probe coordinate system. A step of correcting the position of the probe determined by the position control means with respect to the substrate coordinate system using the third coordinate conversion formula. (2) The method according to (1), wherein a plurality of the probes are provided, a position control unit is provided for each probe, and the position of each probe is corrected in accordance with the steps 1 to 3.

[0007]

According to the present invention as described above, the position of the dent left on the substrate to be inspected by the probe during probing is measured by the image measuring camera. Here, the designated coordinates given to the position control means and the coordinates of the dent measured by the image measurement camera are compared. A coordinate conversion formula [A] between the camera coordinate system and the probe coordinate system is obtained from the comparison result. Next, the position of the position correction mark attached to the known position on the inspected substrate is measured by the image measurement camera. Here, the known coordinates of the position correction mark are compared with the coordinates of the position correction mark measured by the image measurement camera. A coordinate conversion formula [B] between the camera coordinate system and the substrate coordinate system is obtained from the comparison result. The obtained coordinate conversion formulas [A] and [B] are combined to obtain a coordinate conversion formula [C] between the substrate coordinate system and the probe coordinate system. Then, using the coordinate conversion formula [C}, the position of the probe position is corrected with respect to the substrate coordinate system.

[0008]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to the drawings. Figure 1
FIG. 3 is a diagram showing a configuration example of an in-circuit tester used for carrying out the method according to the present invention. 1 that are the same as those in FIG. 3 are given the same reference numerals. The in-circuit tester shown in FIG. 1 is provided with three XY tables. Third X
The components 3 ₃ , 4 ₃ , 5 ₃ , 6 ₃ in the Y table are the components 3 ₁ , 3 ₂ , 4 ₁ , 4 ₂ , 5 ₁ , 5 ₂ , 6 ₁ ,
The same as 6 ₂ respectively. Reference numeral 20 is an image measurement camera attached to the head 6 ₃ . Image measurement camera 2
0 captures an image of the blind substrate 1 and performs image measurement based on the captured image. Reference numeral 21 is a camera control means for controlling the photographing of the image measurement camera 20, and 22 is a position control means 8 _1.
˜8 ₃ , CPU for controlling the entire tester by exchanging signals with the probe control means 9 ₁ , 9 ₂ and the camera control means 21. Reference numeral 23 is a correction means for correcting the position of the probe based on the data from the CPU 22.

A method of correcting the position of the probe using such an in-circuit tester will be described. Probe 7
The position of ₁ is determined by the designated coordinates given to the probe control means 9 ₁ . The coordinate system that defines these designated coordinates is the probe coordinate system. The position of probe 7 ₂ is also defined by another probe coordinate system. The measurement coordinates of the image measurement camera 20 are also determined based on the coordinate axes that are the reference of the measurement coordinates. The coordinate system that defines the measurement coordinates is the camera coordinate system. The position on the substrate 1 to be inspected is also determined by a coordinate system having X and Y coordinate axes on the substrate surface. A coordinate system that defines a position on the substrate 1 to be inspected is a substrate coordinate system. Thus, there are three coordinate systems depending on the viewpoint. In the present invention, these 3
The correction amount of the probe position is calculated by obtaining the coordinate conversion formula between the two coordinate systems.

The outline of the procedure for calculating the coordinate conversion formula will be described below. When the position of the probe is determined by giving designated coordinates to the position control means and the probe is lowered at the determined position to perform probing, a dent is made at the probing position on the substrate to be inspected. The position of the dent thus formed is measured by the image measuring camera 20. Here, the designated coordinates given to the position control means and the coordinates of the dent measured by the image measurement camera 20 are compared. A coordinate conversion formula [A] between the camera coordinate system and the probe coordinate system is obtained from the comparison result. Next, the position of the position correction mark previously attached to the known position on the inspected substrate 1 is measured by the image measurement camera 20.
Here, the known coordinates of the position correction mark are compared with the coordinates of the position correction mark measured by the image measurement camera 20. A coordinate conversion formula [B] between the camera coordinate system and the substrate coordinate system is obtained from the comparison result. The obtained coordinate conversion formulas [A] and [B] are combined to obtain a coordinate conversion formula [C] between the substrate coordinate system and the probe coordinate system. Then, using the coordinate conversion formula [C], the position of the probe position is corrected with respect to the substrate coordinate system. As described above, in the present invention, the coordinate conversion formula [C] between the substrate coordinate system and the probe coordinate system is indirectly obtained through the camera coordinate system, and the probe position of the probe position is calculated using this coordinate conversion formula [C]. Make a correction. The coordinate conversion formula [A] is a characteristic peculiar to the in-circuit tester and is obtained for each in-circuit tester. Since the coordinate conversion formula [B] usually includes the characteristics peculiar to each substrate, it is obtained for each substrate. However, when the difference in characteristics between specific types of substrates can be ignored, it can be represented by the coordinate conversion formula obtained for each standard substrate. Such correction is performed for each probe. As a result, the position of the tip of each probe is corrected with respect to the common coordinate system (board coordinate system).

Next, the procedure for calculating the coordinate conversion formula will be described by taking a concrete formula as an example. First, the necessity of correcting the position of the probe will be described. Even if the substrate to be inspected is mounted on the tester and the designated coordinates of the correct inspection position are given to the position control means, a displacement occurs between the probe position and the inspection position due to the following factors. (1) Distortion of coordinates of XY table of tester (2) Error of reproducibility of probing position of tester (3) Deviation of probing position due to thickness and warpage of inspected board (4) Expansion and contraction of inspected board Misalignment of pattern (5) Deviation from the reference position when mounting the substrate to be inspected Of these factors, (1) is a factor peculiar to the tester and is fixed for a relatively long period of time. Although (2) is a factor peculiar to the tester, the amount of positional deviation is an irregular value and changes every time probing is performed. (3) to (5) are factors that cause little change until the inspection is completed if the substrate to be tested is fixed and fixed to the tester. The positional deviation due to factors other than (2) can be corrected by some method if the characteristics and the amount thereof are known in advance. Among the factors of (3), the thickness of the substrate is known in advance, so it can be corrected. However, the warp of the substrate is generally irregular and cannot be predicted unless the level is measured in advance using two image measurement cameras. The warp of the substrate can be ignored, and the factors (1), (4) and (5) are
If the combination of rotation of the coordinate axes, uniform expansion / contraction of the scale, and offset of the origin can result, the positional deviation can be corrected by linear transformation of the coordinates. If all the work areas of the tester are viewed, even if the coordinate conversion characteristics have non-linear characteristics, if the non-linear changes are gentle, the linearity can be assured in a small area obtained by appropriately dividing all work areas.

A general expression and a conversion constant for linear conversion of coordinates will be described. The general formula for the linear transformation from the xy coordinate system to the XY coordinate system is as follows.

[Equation 1]A to f in the equation (1) are conversion constants. From the XY coordinate system
The coordinates of the origin of the seen xy coordinate system are (X₀, Y₀) And
And X ₀= C, Y₀= F. Conversely, from the xy coordinate system
The coordinates of the origin of the viewed XY coordinate system are (x₀, Y₀) Is
Given by the solution.

[Equation 2] Therefore, the equation (1) can be expressed by the following equation.

[Equation 3] Alternatively, it can be expressed by the following equation.

[Equation 4] Here, the conversion constants a to f are the points (x _i ,
If three sets of points (X _i , Y _i ) in the XY coordinate system corresponding to y _i ) are given, they can be obtained from the simultaneous equations shown below. Since the solution of the simultaneous equations is obtained, the three sets of coordinates are coordinates that are not on a straight line.

[Equation 5] Alternatively, it can be expressed as follows.

[Equation 6] here,

[Equation 7] Is called a transformation matrix.

Next, the coordinate conversion formula in the case where the axes of the Cartesian coordinate system are rotated and the scale is changed will be described. With the origin of the xy coordinate system as the center, the x-axis and the y-axis are rotated counterclockwise by φ radians and η radians respectively, and then the coordinate system in which the scale of each axis is multiplied by α and β is multiplied by X is set. -If the Y coordinate system is used, the conversion constant a-
f is as follows.

[Equation 8] When the rotation angles φ and η are small, the equation (7) can be approximated by the following equation.

[Equation 9] The conversion formula that considers the offset of the coordinate origin in this conversion is
It is given by the equation (3) or the equation (4).

Next, the coordinate conversion between the linear coordinate systems will be described. It is assumed that a conversion formula from one common reference coordinate system xy to the other linear coordinate systems X ₁ -Y ₁ and X ₂ -Y ₂ is given by the following formula.

[Equation 10] (X ₁₀ , y ₁₀ ): Coordinate system X ₁ -Y ₁ viewed from coordinate system xy
Origin coordinates (x ₂₀ , y ₂₀ ): coordinate system X ₂ -Y ₂ viewed from coordinate system xy
At this time, the conversion formula from the coordinate system X ₁ -Y ₁ to the coordinate system X ₂ -Y ₂ is given by the following formula.

[Equation 11] (X ₁₀ , Y ₁₀ ): Coordinate system X ₂ seen from the coordinate system X ₁ − Y ₁ −
Y ₂ origin coordinates (X ₂₀ , Y ₂₀ ): Coordinate system X ₂ − Coordinate system X ₁ seen from Y ₂ −
Origin coordinate of Y ₁ Here, it should be noted that (A) and (B) change if the reference coordinate system xy is different, but (C) and (X ₁₀ , Y
₁₀ ) and (X ₂₀ , Y ₂₀ ) are unchanged. The present invention performs coordinate conversion by applying the above-described theory of coordinate conversion.

The procedure of coordinate conversion according to the present invention will be described.
First, the coordinate conversion formula from the camera coordinate system to the probe coordinate system
The procedure for obtaining is explained. See all tester work areas
If the coordinate conversion characteristics have nonlinear characteristics,
All work areas are suitable if the change in
When n × m (where n and m are integers) is divided into
It has already been mentioned that the coordinate transformation characteristics can be linearized within the area.
It was Now, a board of a size that covers the entire work area
The above area division is applied to the_0,0
The reference board with the coordinate values of the dividing points starting from
Prepare as. FIG. 2 shows an example of a divided area on the reference board.
Shown in. In FIG. 2, S_iIs a divided area, P_i，_j, P_{i + 1, j}, P
_{i + 1, j + 1}Is the dividing point. Divided area S shown in FIG._iAt
Three reference points with known coordinate values are provided.
If you read the position of the point with the image measurement camera and the probe,
Conversion constants from the quasi-board coordinate system to the camera coordinate system, and
And the conversion from the reference board coordinate system to the probe coordinate system.
The number is calculated using the equation (6). Reference board coordinate system
Is x-y, the camera coordinate system is X_C-Y_C, The probe coordinate system
X _p-Y_pAnd Reference board coordinate system to camera coordinate system
The conversion matrix to (C_i), The coordinate system of the reference board
To the probe coordinate system (P_i)age,
The conversion matrix from the camera coordinate system to the probe coordinate system
(M_i), The conversion formula is as follows.

[Equation 12] (X _C0 , y _C0 ): origin coordinates of the camera coordinate system X _C- Y _C viewed from the reference board coordinate system xy (x _p0 , _{yp 0} ): probe viewed from the reference board coordinate system xy origin coordinate of the coordinate system _{X p -Y p (X Cp0,} Y Cp0): camera coordinate system X _C -Y probe coordinate system viewed from _C X _p -Y _p origin coordinates (X _pC0, Y pC0): probe coordinate The origin coordinate transformation matrices (C _i ) and (P _i ) of the camera coordinate system X _C -Y _C viewed from the system X _p -Y _p correct the linear distortion of the XY table of the in-circuit tester based on the reference coordinates. To give a conversion constant for Then, changes in (C _i ) and (P _i ) on the reference board represent a non-linear characteristic of the XY table. It should be noted here that the transformation matrix (M _i ) from the camera coordinate system to the probe coordinate system
The conversion constant included in is the coordinate value obtained by reading the positions of the three reference points provided for each divided area in the camera coordinate system and the probe coordinate system without passing through the coordinate values in the coordinate system of the reference board. That is what is required. That is, three designated coordinates are given to the position control means for each divided area so that the tip of the probe hits the inspected substrate. At this time, the position of the dent formed on the substrate to be inspected is measured by the image measurement camera. Each conversion constant of the conversion matrix (M _i ) is obtained by associating the measured coordinate value with the value of the designated coordinate.

Next, the coordinate from the substrate coordinate system to the camera coordinate system
A procedure for obtaining the standard conversion formula will be described. Known on the board under test
A position correction mark is previously provided at the position. Position correction
The position of the peak is measured with an image measurement camera. This measurement coordinate
The value and the coordinate value of the known position
Corresponding to each positive mark, the coordinates from the board coordinate system
Each conversion constant of the conversion matrix to the mel coordinate system is calculated.
It This will be explained using formulas. PCB coordinate system of position correction mark
The coordinate value at (X_Bm, Y_Bm) (However, m = 1,
2, 3). This coordinate value is known. Image measurement
The coordinate value of the position correction mark measured by the camera_Cm，
Y_Cm). A conversion matrix from the board coordinate system to the camera coordinate system.
Each conversion constant of the trix is obtained from the equation (6). conversion
The matrix (C _B), The conversion formula is
become.

[Equation 13] This conversion formula is also a conversion formula for correction from the substrate coordinate system to the camera coordinate system. The contents that can be corrected by the number of position correction marks are limited as follows. 1 mark: 1) Origin shift of substrate only 2 marks: 2) Origin shift of substrate, uniform expansion and contraction only 3) Origin shift of substrate and expansion / contraction with anisotropy, etc. 3 marks When: 4) General linear distortion In each of the above cases, the transformation matrix (C _B ) is as follows.

[Equation 14] Therefore, the required number of position correction marks are properly arranged,
When the coordinate value of the position correction mark in the substrate coordinate system is known, if the position of the same position correction mark is measured by the image measurement camera, a known coordinate value corresponding to the measured coordinate can be obtained. Each conversion constant of C _B ) is obtained from the solution of equation (6).

Now, a procedure for obtaining a coordinate conversion formula from the substrate coordinate system to the probe coordinate system will be described. By substituting the equation (20) into the equation (16), the transformation matrix (H _i ) from the substrate coordinate system to the probe coordinate system is as follows.

[Equation 15] (X _Bp0 , Y _Bp0 ): Origin coordinates of the probe coordinate system X _p -Y _p viewed from the probe coordinate system X _B -Y _B (X _pB0 , Y _pB0 ): Board viewed from the probe coordinate system X _p -Y _p coordinate system X _B -Y origin coordinate transformation matrix thus determined of _B (H _i) is the transformation matrix for performing an overall conversion from the substrate coordinate system to the probe coordinate system. With this transformation matrix,
The position of the probe can be corrected with respect to the substrate coordinate system of the in-circuit tester. Such correction is performed for each probe. The probe tip position of each XY table is corrected with respect to a common coordinate system (board coordinate system).

[0018]

According to the present invention, the following effects can be obtained. In the present invention, the coordinate conversion formula [A] between the camera coordinate system and the probe coordinate system is obtained by measuring the position of the dent left on the substrate by the probe when performing probing. Further, the coordinate conversion formula [B] between the camera coordinate system and the substrate coordinate system is obtained by measuring the position of the position correction mark attached to the known position on the substrate with the image measurement camera. The two coordinate conversion equations [A] and [B] thus obtained are combined to obtain the coordinate conversion equation [C] between the substrate coordinate system and the probe coordinate system. Then, using the obtained coordinate conversion formula [C], the tip position of the probe is corrected with respect to the substrate coordinate system. The probe may be applied only the number of conversion constants included in the coordinate conversion formula. As a result, since the pattern of the substrate is not chipped by the probe, the probe can be hit accurately and the position can be corrected with high accuracy. Moreover, it is possible to correct various positional deviations of the XY coordinates of the probe, including offset, rotation, expansion / contraction of coordinate axes, and the like. Since the position is measured using the image measurement camera that is not in contact with the substrate, the position can be corrected without causing damage or abrasion of the substrate pattern or the probe tip.

[Brief description of drawings]

FIG. 1 is a configuration diagram showing an embodiment of the present invention.

FIG. 2 is a diagram showing an example of divided areas provided on a reference board.

FIG. 3 is a configuration diagram of a conventional example of an in-circuit tester.

[Explanation of symbols]

1 substrate to be inspected 2 table 3 _{1 to} 3 ₃ guide bar 4 ₁ to 4 ₃ linear motor 5 _{1 to} 5 ₃ arm 6 _{1 to} 6 ₃ head 7 ₁ and 7 ₂ probe 8 ₁ to 8 ₃ position control means 9 ₁ and 9 ₂ probe control means 20 image measurement camera 21 camera control means 22 CPU 23 correction means

─────────────────────────────────────────────────── ───

[Procedure amendment]

[Submission date] April 22, 1993

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction content]

[Document name] Statement

Title: Board tester with movable probe
Coordinate correction method

[Claims]

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention has a movable probe.
The present invention relates to a method for improving the positional accuracy of a probe in a board tester .

[0002]

2. Description of the Related Art A board tester with a movable probe
An example is an in-circuit tester. The in-circuit tester applies a probe to the inspected board, gives a test signal to the inspected board through the applied probe, and determines the quality of the circuit formed on the inspected board based on the response signal to the test signal. To do. FIG. 3 shows a configuration example of the in-circuit tester. This in-circuit tester is a stack of two XY tables. The number of XY tables to be stacked may be two or more. In FIG. 3, 1 is a substrate to be inspected, 2 is a table to which the substrate 1 to be inspected is fixed, 3
₁ , 3 ₂ are guide bars extending in the X-axis direction of the table 2, 4
₁ , 4 ₂ are linear motors that run along the guide bars 3 ₁ , 3 ₂ , 5 ₁ , 5 ₂ are arms that move in the X-axis direction by the linear motors 4 ₁ , 4 ₂ , and 6 ₁ , 6 ₂ are arms 5. _1, 5 ₂ be mounted on the drive mechanism head (not shown) along the arm 5 moves in the Y-axis direction, 7 _1, 7 ₂ heads 6 _1,
6 ₂ and is provided with a lifting mechanism (not shown) for Z
It is a probe that moves up and down in the axial direction to perform probing on the inspection position of the substrate 1 to be inspected. 8 ₁ and 8 ₂ are position control means for controlling the movements of the heads 6 ₁ and 6 _{2 in} the X-axis direction and the Y-axis direction, and 9 ₁ and 9 ₂ control the raising / lowering operation of the probes 7 ₁ and 7 _{2 and} the probes. Probe control means 10 for transmitting and receiving signals to and from the substrate 1 to be inspected via the position control means 8
_1, a ₈₂ and a probe control unit 9 _1, 9 ₂ and CPU which then transfers control of the entire tester signals.

In the in-circuit tester having such a structure, the CPU 10 gives the designated coordinates designating the coordinates of the inspection position to the position control means 8 ₁ and 8 ₂ to move the probes 7 ₁ and 7 ₂ to X ,.
By moving in the Y direction, the probes 7 ₁ and 7 ₂ are positioned on the inspection position of the substrate 1 to be inspected. Here, the CPU 10 gives a command to the probe control means 9 ₁ , 9 ₂ to give probes 7 ₁ , 7 _2.
And lower it to the inspection position. In this state, a test signal is applied to the inspected substrate 1, and the quality of the circuit formed on the inspected substrate 1 is determined based on the response signal to the test signal. The two XY tables are used properly according to the inspection position.

In such an in-circuit tester, in order for the coordinates of the tips of the probes 7 ₁ and 7 ₂ provided on the two XY tables to become a common coincident XY coordinate, it is necessary to use each X coordinate.
The machining accuracy and assembly accuracy of the Y table must be improved. In order to achieve a more accurate match, software correction must be performed from the position control means 8 ₁ , 8 ₂ side. Conventionally, the correction for matching the XY coordinates of the two probe tips has been performed by matching the mechanical origins of the two XY tables. As a method for confirming the coincidence, there is a visual method. In addition, there are the following other confirmation methods. That is, a jig substrate having a reference position pattern is prepared, and the reference position pattern is scanned by each probe. Then, the presence or absence of electrical conduction between the pattern and the probe is detected to obtain the edge coordinate of the pattern seen from each probe, and the X and Y coordinate offset between the two probes is calculated from the obtained edge coordinate. However, in such a confirmation method, since the probe is repeatedly applied to the vicinity of the edge of the pattern to obtain the edge coordinates, the vicinity of the edge is missing. As a result, the probe does not hit the pattern accurately, and the edge coordinate detection accuracy deteriorates. Therefore, sufficient correction cannot be performed. Also, with this confirmation method, only the offset of the XY coordinates can be corrected.

[0005]

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and the position of a dent left by a probe on a substrate when probing is measured by an image measuring camera. By indirectly obtaining the relationship between the board coordinate system and the probe coordinate system, and correcting the probe position based on this relationship, the probe position can be corrected with high accuracy, and A movable probe that can correct various misalignment of XY coordinates, including offset, rotation, expansion / contraction of coordinate axes, etc.
The purpose of the present invention is to realize a coordinate correction method for the board tester .

[0006]

The present invention is the following correction method. (1) The substrate to be inspected is mounted on a tester, the probe is moved in a two-dimensional direction along the substrate surface by the position control means, and the probe is lowered when the probe is positioned on the inspection position of the substrate to be inspected. Apply to the inspection board and inspect
A board tester with a movable probe for testing boards
In the coordinate correction method of (1), a movable probe characterized by having an image measurement camera for taking an image of a printed circuit board and performing image measurement based on the taken image, and correcting the position of the probe according to the following steps. Board tester seat
Standard correction method. A step of giving designated coordinates to the position control means to determine the position of the probe, lowering the probe at the determined position, and making a dent on a predetermined substrate . The step of measuring the position of the dent formed in the step of 1. by the image measuring camera. The designated coordinates given to the position control means and the coordinates of the dents measured by the image measuring camera are compared, and from the comparison result, the camera coordinate system for determining the measuring coordinates of the image measuring camera and the designated coordinate of the probe position are determined. A step of obtaining a first coordinate conversion formula for performing coordinate conversion with a defined probe coordinate system. A step of measuring the position of a position correction mark attached to a known position on the substrate to be inspected with an image measurement camera. Between the known coordinates of the position correction mark, compared with the coordinates of the position correction marks measured by the image measurement camera, the comparison result, and the camera coordinate system, the substrate coordinate system defining the coordinates in the inspected substrate A step of obtaining a second coordinate conversion formula for performing the coordinate conversion of. Based on the first coordinate conversion formula and the second coordinate conversion formula,
A step of obtaining a third coordinate conversion formula for performing coordinate conversion between the substrate coordinate system and the probe coordinate system. A step of correcting the position of the probe determined by the position control means with respect to the substrate coordinate system using the third coordinate conversion formula. (2) The method according to (1), wherein a plurality of the probes are provided, a position control unit is provided for each probe, and the position of each probe is corrected in accordance with the steps 1 to 3.

[0007]

According to the present invention as described above, the position of the dent left on the predetermined substrate by the probe during probing is measured by the image measuring camera. Here, the designated coordinates given to the position control means and the coordinates of the dent measured by the image measurement camera are compared. A coordinate conversion formula [A] between the camera coordinate system and the probe coordinate system is obtained from the comparison result. Next, the position of the position correction mark attached to the known position on the inspected substrate is measured by the image measurement camera. Here, the known coordinates of the position correction mark are compared with the coordinates of the position correction mark measured by the image measurement camera. A coordinate conversion formula [B] between the camera coordinate system and the substrate coordinate system is obtained from the comparison result. The obtained coordinate conversion formulas [A] and [B] are combined to obtain a coordinate conversion formula [C] between the substrate coordinate system and the probe coordinate system. Then, using the coordinate conversion formula [C ] , the position of the probe position is corrected with respect to the substrate coordinate system.

[0008]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to the drawings. Figure 1
FIG. 3 is a diagram showing a configuration example of a port tester used for carrying out the method according to the present invention. Figure 1 shows an example of a port tester
The in-circuit tester is shown. 1 that are the same as those in FIG. 3 are given the same reference numerals. The in-circuit tester shown in FIG. 1 is provided with three XY tables. Three
Elements 3 ₃ , 4 ₃ , 5 ₃ , in the th XY table,
6 ₃ is the above-mentioned constituent elements 3 ₁ , 3 ₂ , 4 ₁ , 4 ₂ , 5 ₁ , 5
_They are the same as ₂ , 6 ₁ and 6 ₂ , respectively. Reference numeral 20 is an image measurement camera attached to the head 6 ₃ . The image measurement camera 20 captures an image of the blind substrate 1 and measures the image based on the captured image. Reference numeral 21 is a camera control means for controlling the photographing of the image measuring camera 20, 22 is a position control means 8 ₁ to 8 ₃ , probe control means 9 ₁ and 9 ₂ and a signal to and from the camera control means 21 to control the entire tester. It is the controlling CPU. Reference numeral 23 is a correction means for correcting the position of the probe based on the data from the CPU 22.

A method of correcting the position of the probe using such an in-circuit tester will be described. Probe 7
The position of ₁ is determined by the designated coordinates given to the probe control means 9 ₁ . The coordinate system that defines these designated coordinates is the probe coordinate system. The position of probe 7 ₂ is also defined by another probe coordinate system. The measurement coordinates of the image measurement camera 20 are also determined based on the coordinate axes that are the reference of the measurement coordinates. The coordinate system that defines the measurement coordinates is the camera coordinate system. The position on the substrate 1 to be inspected is also determined by a coordinate system having X and Y coordinate axes on the substrate surface. A coordinate system that defines a position on the substrate 1 to be inspected is a substrate coordinate system. Thus, there are three coordinate systems depending on the viewpoint. In the present invention, these 3
The correction amount of the probe position is calculated by obtaining the coordinate conversion formula between the two coordinate systems.

The outline of the procedure for calculating the coordinate conversion formula will be described below. When probing is performed by giving the designated coordinates to the position control means to determine the position of the probe and lowering the probe at the determined position, a dent is made at the probing position on a predetermined substrate . Here, the predetermined substrate is an inserter.
The base installed on the tester during the adjustment stage of the kit tester
It is a board, and the board surface covers the work area of the tester.
It is spreading. A given board has the characteristics of a tester
It is a substrate used for. The position of the dent thus formed is measured by the image measuring camera 20. Here, the designated coordinates given to the position control means and the coordinates of the dent measured by the image measurement camera 20 are compared. A coordinate conversion formula [A] between the camera coordinate system and the probe coordinate system is obtained from the comparison result. Next, the position of the position correction mark previously attached to the known position on the inspected substrate 1 is measured by the image measurement camera 20. Here, the known coordinates of the position correction mark are compared with the coordinates of the position correction mark measured by the image measurement camera 20. A coordinate conversion formula [B] between the camera coordinate system and the substrate coordinate system is obtained from the comparison result. The obtained coordinate conversion formulas [A] and [B] are combined to obtain a coordinate conversion formula [C] between the substrate coordinate system and the probe coordinate system. Then, using the coordinate conversion formula [C], the position of the probe position is corrected with respect to the substrate coordinate system. As described above, in the present invention, the coordinate conversion formula [C] between the substrate coordinate system and the probe coordinate system is indirectly obtained through the camera coordinate system, and the probe position of the probe position is calculated using this coordinate conversion formula [C]. Make a correction. The coordinate conversion formula [A] is a characteristic peculiar to the in-circuit tester and is obtained for each in-circuit tester. The coordinate conversion formula [B] is
Usually, since it includes characteristics peculiar to each substrate, it is obtained for each substrate. However, when the difference in characteristics between specific types of substrates can be ignored, it can be represented by the coordinate conversion formula obtained for each standard substrate. Such correction is performed for each probe. As a result, the position of the tip of each probe is corrected with respect to the common coordinate system (board coordinate system).
If the specified board can be used as a substitute,
You may combine these.

Next, the procedure for calculating the coordinate conversion formula will be described by taking a concrete formula as an example. First, the necessity of correcting the position of the probe will be described. Even if the substrate to be inspected is mounted on the tester and the designated coordinates of the correct inspection position are given to the position control means, a displacement occurs between the probe position and the inspection position due to the following factors. (1) Distortion of coordinates of XY table of tester (2) Error of reproducibility of probing position of tester (3) Deviation of probing position due to thickness and warpage of inspected board (4) Expansion and contraction of inspected board Misalignment of pattern (5) Deviation from the reference position when mounting the substrate to be inspected Of these factors, (1) is a factor peculiar to the tester and is fixed for a relatively long period of time. Although (2) is a factor peculiar to the tester, the amount of positional deviation is an irregular value and changes every time probing is performed. (3) to (5) are factors that cause little change until the inspection is completed if the substrate to be tested is fixed and fixed to the tester. The positional deviation due to factors other than (2) can be corrected by some method if the characteristics and the amount thereof are known in advance. Among the factors of (3), the thickness of the substrate is known in advance, so it can be corrected. However, the warp of the substrate is generally irregular and cannot be predicted unless the level is measured in advance using two image measurement cameras. The warp of the substrate can be ignored, and the factors (1), (4) and (5) are
If the combination of rotation of the coordinate axes, uniform expansion / contraction of the scale, and offset of the origin can result, the positional deviation can be corrected by linear transformation of the coordinates. If all the work areas of the tester are viewed, even if the coordinate conversion characteristics have non-linear characteristics, if the non-linear changes are gentle, the linearity can be assured in a small area obtained by appropriately dividing all work areas.

A general expression and a conversion constant for linear conversion of coordinates will be described. The general formula for the linear transformation from the xy coordinate system to the XY coordinate system is as follows.

[Equation 1]A to f in the equation (1) are conversion constants. From the XY coordinate system
The coordinates of the origin of the seen xy coordinate system are (X₀, Y₀) And
And X ₀= C, Y₀= F. Conversely, from the xy coordinate system
The coordinates of the origin of the viewed XY coordinate system (x₀, Y₀) Is the solution of
Given in.The coordinates (X ₀ , Y ₀ ) and (x ₀ , y ₀ ) are
In other words, one coordinate system and the other coordinate system
This is the origin offset of the system.

[Equation 2] Therefore, the equation (1) can be expressed by the following equation.

[Equation 3] Alternatively, it can be expressed by the following equation.

[Equation 4] Here, the conversion constants a to f are the points (x _i ,
If three sets of points (X _i , Y _i ) in the XY coordinate system corresponding to y _i ) are given, they can be obtained from the simultaneous equations shown below. Since the solution of the simultaneous equations is obtained, the three sets of coordinates are coordinates that are not on a straight line.

[Equation 5] Alternatively, it can be expressed as follows.

[Equation 6] (6) Where

[Equation 7] Is called a transformation matrix.

Next, the coordinate conversion formula in the case where the axes of the Cartesian coordinate system are rotated and the scale is changed will be described. With the origin of the xy coordinate system as the center, the x-axis and the y-axis are rotated counterclockwise by φ radians and η radians respectively, and then the coordinate system in which the scale of each axis is multiplied by α and β is multiplied by X is set. -If the Y coordinate system is used, the conversion constant a-
f is as follows.

[Equation 8] (7) When the rotation angles φ and η are small, the equation (7) can be approximated by the following equation.

[Equation 9] (8) The conversion formula that considers the offset of the coordinate origin in this conversion is
It is given by the equation (3) or the equation (4).

Next, the coordinate conversion between the linear coordinate systems will be described. It is assumed that a conversion formula from one common reference coordinate system xy to the other linear coordinate systems X ₁ -Y ₁ and X ₂ -Y ₂ is given by the following formula.

[Equation 10] (X ₁₀ , y ₁₀ ): Coordinate system X ₁ -Y ₁ viewed from coordinate system xy
Origin coordinates (x ₂₀ , y ₂₀ ): coordinate system X ₂ -Y ₂ viewed from coordinate system xy
At this time, the conversion formula from the coordinate system X ₁ -Y ₁ to the coordinate system X ₂ -Y ₂ is given by the following formula.

[Equation 11] (X ₁₀ , Y ₁₀ ): Coordinate system X ₂ seen from the coordinate system X ₁ − Y ₁ −
Y ₂ origin coordinates (X ₂₀ , Y ₂₀ ): Coordinate system X ₂ − Coordinate system X ₁ seen from Y ₂ −
Origin coordinate of Y ₁ Here, it should be noted that (A) and (B) change if the reference coordinate system xy is different, but (C) and (X ₁₀ , Y
₁₀ ) and (X ₂₀ , Y ₂₀ ) are unchanged. The present invention performs coordinate conversion by applying the above-described theory of coordinate conversion.

The procedure of coordinate conversion according to the present invention will be described.
First, the coordinate conversion formula from the camera coordinate system to the probe coordinate system
The procedure for obtaining is explained. See all tester work areas
If the coordinate conversion characteristics have nonlinear characteristics,
All work areas are suitable if the change in
When n × m (where n and m are integers) is divided into
It has already been mentioned that the coordinate transformation characteristics can be linearized within the area.
It was Now, a board of a size that covers the entire work area
The above area division is applied to the_0,0
Is the origin and the coordinates of the division pointPrice in an accurate Cartesian coordinate system
Prepare a reference board.One of the divided areas on the reference board
An example is shown in FIG. In FIG. 2, S_iIs a divided area, P_i，_j, P
_{i + 1, j}, P_{i + 1, j + 1}Is the dividing point. Divided area shown in Figure 2
S_iSet three reference points whose coordinate values have become known.
The positions of these reference points are read with an image measurement camera and probe.
If taken, the coordinate system of the reference board is converted to the camera coordinate system.
From constant and reference board coordinate system to probe coordinate system
The conversion constant of is calculated using equation (6). Reference board
Is the coordinate system of x-y and the camera coordinate system is x_C-Y_C,probe
X coordinate system _p-Y_pAnd Turtle from the reference board coordinate system
The conversion matrix to the La coordinate system is (C_i), On the reference board
The conversion matrix from the coordinate system to the probe coordinate system
(P_i) And change from the camera coordinate system to the probe coordinate system.
Convert matrix to (M_i), The conversion formula is
Become.

[Equation 12](X_C0, Y_C0): The power viewed from the coordinate system xy of the reference board.
Mera coordinate system X_C-Y_COrigin coordinates of (x_p0, Y_p0): Plan viewed from the coordinate system xy of the reference board
Lobe coordinate system X_p-Y_pOrigin coordinates (X_Cp0, Y_Cp0): Camera coordinate system X_C-Y_CProfessional seen from
Curve coordinate system X_p-Y_pOrigin coordinates (X_pC0, Y_pC0): Probe coordinate system X_p-Y_pSeen from
Mera coordinate system X_C-Y_COrigin coordinate transformation matrix (C_i) And (P_i)And origin offset
Is the linear distortion of the XY table of the in-circuit tester.
It also gives a conversion constant for correction based on the reference coordinates.
Of. And on the reference boardi = 1 to n × m
Between areas(C_i) And (P_i)And origin offsetchange of
Represents the non-linear characteristic of the XY table. Be careful here
Kimono is a conversion coordinate from the camera coordinate system to the probe coordinate system.
Trix (M_i)And origin offsetConversion constants included in
The number is based on the positions of the three reference points provided for each divided area.
The camera coordinate system is used instead of the coordinate values of the quasi-board coordinate system.
Calculated based on the coordinate values read in the probe coordinate system
That is. That is, three designated coordinates for each divided area
To the position control means,Predetermined board
To hit. At this timePredetermined boardDents on the
The position of is measured with an image measurement camera. This measurement coordinate value
And the value of the specified coordinates are associated with each other
Rix (M_i)And origin offsetEach conversion constant of
Be done.

Next, the coordinate from the substrate coordinate system to the camera coordinate system
A procedure for obtaining the standard conversion formula will be described. Known on the board under test
A position correction mark is previously provided at the position. Position correction
The position of the peak is measured with an image measurement camera. This measurement coordinate
The value and the coordinate value of the known position
Corresponding to each positive mark, the coordinates from the board coordinate system
Each conversion constant of the conversion formula to the Mera coordinate system is obtained. Expression
It demonstrates using. Position correction mark in the board coordinate system
Set the coordinate value to (X_Bm, Y_Bm) (However, m = 1, 2, 3)
To do. This coordinate value is known. Measure with image measurement camera
Set the coordinate value of the position correction mark (X_Cm, Y_Cm).
Each transformation matrix transformation from the board coordinate system to the camera coordinate system
The conversion constant is obtained from the equation (6). Transform matrix
(C _B), The conversion formula is as follows.

[Equation 13] At the same time, this transformation formula converts the board coordinate system to the camera coordinate system.
It is also a correction formula . The contents that can be corrected by the number of position correction marks are limited as follows. 1 mark: 1) Origin shift of substrate only 2 marks: 2) Origin shift of substrate, uniform expansion and contraction only 3) Origin shift of substrate and expansion / contraction with anisotropy, etc. 3 marks When: 4) General linear distortion In each of the above cases, the transformation matrix (C _B ) is as follows.

[Equation 14] Therefore, the required number of position correction marks are properly arranged,
When the coordinate value of the position correction mark in the substrate coordinate system is known, if the position of the same position correction mark is measured by the image measurement camera, a known coordinate value corresponding to the measured coordinate can be obtained. Each conversion constant of C _B ) is reduced to Eq. (6) or 4 or 2 simultaneous equations.
It can be obtained from the solution of the withdrawn formula .

Now, a procedure for obtaining a coordinate conversion formula from the substrate coordinate system to the probe coordinate system will be described. By substituting the equation (20) into the equation (16), the conversion equation from the substrate coordinate system to the probe coordinate system is as follows.

[Equation 15] ( _Hi ): Comprehensive conversion from the substrate coordinate system to the probe coordinate system
Transformation matrix (X _Bp0 , Y _Bp0 ): origin coordinate of the probe coordinate system X _p −Y _p seen from the probe coordinate system X _B −Y _B (X _pB0 , Y _pB0 ): probe coordinate system X _p − by using origin coordinates the conversion formula of the substrate coordinate system X _B -Y _B as viewed from the Y _p, you are possible to correct the position of the probe relative to the substrate coordinate system of the in-circuit testers.
Such correction is performed for each probe. The probe tip position of each XY table is corrected with respect to a common coordinate system (board coordinate system).

The method according to the present invention is used in the embodiment.
I explained about the case of applying it to the circuit tester.
However, the method according to the present invention is not limited to the in-circuit tester.
Board tester with a movable probe, for example on a board
Test circuit constants, mounting direction, etc. of mounted electrical parts
It may be applied to a board tester or the like.

[0019]

According to the present invention, the following effects can be obtained. In the present invention, the coordinate conversion formula [A] between the camera coordinate system and the probe coordinate system is obtained by measuring the position of the dent left on the substrate by the probe when performing probing. Further, the coordinate conversion formula [B] between the camera coordinate system and the substrate coordinate system is obtained by measuring the position of the position correction mark attached to the known position on the inspected substrate with the image measurement camera. The two coordinate conversion equations [A] and [B] thus obtained are combined to obtain the coordinate conversion equation [C] between the substrate coordinate system and the probe coordinate system. Then, using the obtained coordinate conversion formula [C], the tip position of the probe is corrected with respect to the substrate coordinate system. The probe may be applied only the number of conversion constants included in the coordinate conversion formula. As a result, since the pattern of the substrate is not chipped by the probe, the probe can be hit accurately and the position can be corrected with high accuracy. Moreover, it is possible to correct various positional deviations of the XY coordinates of the probe, including offset, rotation, expansion / contraction of coordinate axes, and the like. Since the position is measured using the image measurement camera that is not in contact with the substrate, the position can be corrected without causing damage or abrasion of the substrate pattern or the probe tip.

[Brief description of drawings]

FIG. 1 is a configuration diagram showing an embodiment of the present invention.

FIG. 2 is a diagram showing an example of divided areas provided on a reference board.

FIG. 3 is a configuration diagram of a conventional example of an in-circuit tester.

[Explanation of reference symbols] 1 board to be inspected 2 table 3 _{1 to} 3 ₃ guide bar 4 ₁ to 4 ₃ linear motor 5 _{1 to} 5 ₃ arm 6 _{1 to} 6 ₃ head 7 ₁ , 7 ₂ probe 8 ₁ to 8 ₃ position control Means 9 ₁ , 9 ₂ Probe control means 20 Image measurement camera 21 Camera control means 22 CPU 23 Correction means

Claims (2)

[Claims] 1. A substrate to be inspected is mounted on a tester, a probe is moved in a two-dimensional direction along a substrate surface by a position control means, and the probe is lowered when the probe is positioned on an inspection position of the substrate to be inspected. Touch the board to be inspected,
The in-circuit tester, which sends and receives signals to and from the inspected board via the applied probe to determine the quality of the circuit formed on the inspected board from the test results, captures an image of the printed circuit board and captures the captured image. A coordinate correction method for an in-circuit tester, which has an image measurement camera for performing image measurement and corrects the position of the probe according to the following steps. A step of giving designated coordinates to the position control means to determine the position of the probe, and lowering the probe at the determined position to make a dent on the substrate to be inspected. The step of measuring the position of the dent formed in the step of 1. by the image measuring camera. The designated coordinates given to the position control means and the coordinates of the dents measured by the image measuring camera are compared, and from the comparison result, the camera coordinate system for determining the measuring coordinates of the image measuring camera and the designated coordinate of the probe position are determined. A step of obtaining a first coordinate conversion formula for performing coordinate conversion with a defined probe coordinate system. A step of measuring the position of a position correction mark attached to a known position on the inspected substrate with an image measurement camera. The known coordinates of the position correction mark and the coordinates of the position correction mark measured by the image measurement camera are compared,
A step of obtaining a second coordinate conversion formula for performing coordinate conversion between the camera coordinate system and a board coordinate system that defines coordinates on the board to be inspected, from the comparison result. Based on the first coordinate conversion formula and the second coordinate conversion formula,
A step of obtaining a third coordinate conversion formula for performing coordinate conversion between the substrate coordinate system and the probe coordinate system. A step of correcting the position of the probe determined by the position control means with respect to the substrate coordinate system using the third coordinate conversion formula. 2. The method according to claim 1, wherein a plurality of the probes are provided, a position control means is provided for each probe, and the position of each probe is corrected according to the steps of to. .