GB2385207A - Laser trimming of chip resistors - Google Patents

Abstract

A chip resistor is formed with an elongated resistor (2) connecting a pair of electrodes (3) on a substrate (1) and grooves (4) are formed on the surface of the resistor in a characteristic pattern having a longer branch (4a) and a shorter branch (4b). The longer branch is arc-shaped, extending between a selected point on a side edge of the resistor and an end point which is nearer towards one of the electrodes. The shorter branch extends between another point on the side edge of the resistor and an intermediate point on the longer branch other than the end point. To form the grooves in such a pattern, the longer branch is formed first by laser-trimming from the side edge of the resistor to the end point. The laser is then switched off and is moved to the intermediate branching point. The shorter branch is then formed by switching on the laser and moving it from the branching point to the other end.

Description

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CHIP RESISTORS AND LASER-TRIMMING OF SAME Background of the Invention This invention relates to chip resistors for mounting to a chip and also to methods of adjusting their resistance by a laser-trimming process.

Fig. 5 shows a prior art chip resistor of this kind, characterized as comprising a ceramic substrate 1, a resistor 2, a pair of electrodes 3 and a glass coating layer 5. Such a chip resistor may be produced first by using a silver paste or the like to form the electrodes 3 on the ceramic substrate 1 and then by using a resistor paste or the like to form the resistor 2 so as to connect the pair of electrodes 3. After the glass coating layer 5 is formed over the resistor 2, a laser beam is used for a laser-trimming process to form a cross-sectionally wedgeshaped groove 4 in the resistor 2 through the glass coating layer 5, reaching the top surface of the ceramic substrate 1, so as to adjust the resistance value of the resistor 2. A protective layer may be formed thereafter over the glass coating layer 5.

If the groove 4 is thus formed, the resistance of the resistor 2 increases because the current which can flow therethrough is necessarily reduced. Thus, when the resistor 2 is initially formed. it is formed such that its resistance will be smaller than the desired resistance of the chip resistor to be obtained and the laser-trimming is effected so as to appropriately increase the resistance of the resistor 2 to the required target value.

Although Fig. 5 shows an example with an L-shaped groove 4, the groove 4 may be cut in other forms. Fig. 6A shows an example of a Cshaped groove 4, Fig. 6B shows another example with a J-shaped groove 4 and Figs. 6C and 6D show still other examples with I-shaped grooves 4.

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Fig. 7 shows equipotential lines 6 in the resistor 2 of Fig. 5 when a potential difference is applied across its electrodes 3. If the applied potential difference is 200V, a potential difference of about 150V will result between positions A and B on the resistor 2 shown in Fig. 7 which are on the opposite sides of the groove 4. If the gap across the groove 4 is 50um, the field intensity between these two points A and B is about 3000V/mm, and it is approximately equal to the voltage at which an atmospheric discharge will start. Thus, a discharge may well take place across the groove 4, depending on the condition of the glass coating layer 5 over the resistor 2. In summary, a leak current is likely to flow through such a prior art chip resistor when it is subjected to a high potential difference. In other words, prior art chip resistors are not satisfactorily resistant against high potential differences.

Figs. 8A, 8B, 8C and 8D show equipotential lines inside the chip resistors of Figs. 6A, 6B, 6C and 6D. When a same potential difference is applied across the pair of electrodes 3, the field intensity is about 635V/mm between positions A and B of Fig. 8A, about 3730V/mm between positions A and B of Fig. 8B, about 1570V/mm and 1590V/mm respectively between positions A and B and positions A'and B'of Fig. 8C, and about 2090V/mm and 1800V/mm respectively between positions A and B and between A'and B'of Fig. 8D. In summary, the possibility of atmospheric discharge is equally high in the case of a J-shaped groove as in the case of an L-shaped groove. The field intensity is also fairly high in the cases of I-shaped grooves.

If the groove is C-shaped, by contrast, the field intensity across the groove is relatively small. As a practical problem, however, a C-shaped groove (as shown in Figs. 6A and 8A) is difficult to make with a satisfactorily high precision. When such a groove is cut by a laser-trimming method, the trimming is started at an edge point of the glass coating layer (not shown in Fig.

6A or 8A) to first produce an L-shaped groove, and the resistance is adjusted then to a specified target value. The direction of movement of the laser is then changed by 90 degrees, while the laser light continues to be emitted, and the groove is formed to reach the same edge of the glass coating to complete a C-

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shape. When it is desired to change the direction of movement of the laser after the groove has been formed in an L-shape, however, the galvanometer which is disposed inside the laser-assisted manufacturing apparatus tends to fluctuate due to inertia. As a result, the L-shaped groove tends to become longer than desired, or it is difficult to form the groove in the desired shape with a high degree of precision. This means that the resultant resistance of the chip resistor tends to be higher than the target value.

Summary of the Invention It is therefore an object of this invention in view of the above to provide a chip resistor having a high accurate resistance value.

It is another object of this invention to provide such a chip resistor having a high resistant against application of a high potential difference.

It is still another object of this invention to provide a method of carrying out laser-trimming in making such a chip resistor.

In a first aspect, the present invention provides a chip resistor according to claim 1.

A chip resistor embodying this invention, with which the above and other objects can be accomplished, may be characterized as having grooves formed in a different pattern having a longer branch and a shorter branch, the longer branch extending between a selected point on a side edge of the resistor which is longitudinally elongated between a pair of electrodes and an end point which is longitudinally displaced from the selected point towards one of the electrodes and a shorter branch extending between another point on the side edge of the resistor and an intermediate point on the longer branch other than its end point. The longer branch, for example, may be in an L-shape with a part perpendicular to the longitudinal direction of the resistor and another part which is substantially in the longitudinal direction. To form the grooves in such a pattern, the longer branch is formed first by laser-trimming from its selected point to the end point. The laser is then switched off and is moved to the intermediate branching point. The shorter branch is then formed by switching on the laser and moving it from the branching point to the other end thereof on the same side edge of the resistor.

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With a chip resistor thus formed, the area of the resistor surrounded by the longer and shorter branches of the grooves is not affected by the potential difference applied across the electrodes. As a result, the distance between the high-potential area and the low-potential area of the resistor is effectively increased and the likelihood of a leak current is reduced. With a method of laser-trimming according to this invention, the dimensions of the grooves can be controlled more dependably and accurately.

Brief Description of the Drawings : The accompanying drawings, which are incorporated in and form a part of this specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention. In the drawings: Figs. 1 A, IB, 1 C are examples of chip resistors for comparison and Fig. 1 D is a plan view of a chip resistor embodying the invention; Fig. 2 shows equipotential lines inside the resistor of Fig. 1A when a potential difference has been applied to its electrodes; Fig. 3 is a drawing for showing the sequence of steps in the laser- trimming according to this invention; Fig. 4 is a graph for showing the distributions of differences between measured and target resistance values for prior art resistors and resistors embodying this invention; Fig. 5 is a schematic plan view of a prior art chip resistor; Figs. 6A, 6B, 6C and 6D are schematic plan views of other prior art chip resistors; Fig. 7 shows equipotential lines inside the chip resistor of Fig. 5; and Figs. 8A, 8B, 8C and 8D show equipotential lines inside the resistors of Figs. 6A, 6B, 6C and 6D.

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Throughout herein, corresponding or like components are indicated by the same numerals and may not necessarily be explained repetitiously.

Detailed Description of Invention Fig. ID shows a chip resistor embodying this invention. Figs. I A, I Band 1 C show other examples for comparison. Since they are similar not only among themselves but also to the prior art chip resistor described above with reference to Fig. 5, like components such as the ceramic substrate 1, the rectangular resistor 2, the pair of electrodes 3 and the glass coating layer 5 are indicated by the same numerals as used in Fig. 5 and are not described repetitiously. For the convenience of description, the direction, in which a current will generally flow through the rectangular resistor 2 when a potential difference is applied across the pair of electrodes 3 and in which the resistor 2 connecting the electrodes 3 together is generally elongated, will be herein referred to as"the longitudinal direction"of the resistor 2.

The chip resistor embodying this invention and shown in Fig. 10 is different from the prior art chip resistor of Figs. 5,6A, 6B, 6C and 6D in that grooves 4 formed in the resistor 2 through the glass coating layer 5, reaching the ceramic substrate 1, have a different pattern with branches joined at"a branching point."There is a longer branch 4a extending from one edge point of the glass coating layer 5, passing over a longitudinally extending side edge of the resistor 2, to an end point which is longitudinally displaced from the crossing point at which the side edge of the resistor 2 is crossed. A shorter branch 4b is formed, extending from another edge point of the glass coating layer 5, passing over the same side edge of the resistor 2 as does the longer branch 4a but at a longitudinally displaced different position, and ending at an intermediate point (or"the branching point") on the longer branch 4a other than its end point.

The examples shown in Figs. I A, I B and 1 C are characterized wherein the longer branch 4a of the grooves 4 is L-

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shaped, having a perpendicular part and a longitudinal part which are both substantially straight and linear. The perpendicular part extends from an edge point of the glass coating layer 5 substantially perpendicularly to the aforementioned longitudinal direction, passing a side edge of the resistor 2 and reaching a point nearly in the middle of the resistor 2 in the direction of its width (perpendicular to its longitudinal direction). The longitudinal part extends longitudinally from the end point of the perpendicular part of the longer branch 4a such that an L-shape is formed together with the perpendicular part.

In Fig. I A, the shorter branch 4b is formed parallel to the perpendicular part of the longer branch 4a, extending between an edge point of the glass coating layer 5, passing over the same side edge of the resistor 2 as does the longer branch 4a and ending at an intermediate point (or"the branching point") on the longitudinal part of the longer branch 4a approximately at its middle.

Figs. 1B and 1C, are similar to Fig. 1 A except the shorter branch 4b is straight but not parallel to the perpendicular part of the longer branch 4a. According to the second embodiment, the separation in the longitudinal direction between the perpendicular part of the longer branch 4a and the shorter branch 4b decreases as one moves away from the branching point, at which the two branches 4a and 4b of the grooves 4 meet. towards the side edge of the resistor 2. In Fig. 1 C, this separation increases as one moves similarly from the branching point towards the side edge of the resistor 2. It is to be noted, however, that the separation in the longitudinal direction between the perpendicular part of the longer branch 4a and the shorter branch 4b, along the side edge of the resistor 2 crossed by them, is less than the length of the longitudinal part of the longer branch 4a.

Explained in another way, the point (indicated by letter P in Figs. 1B and 1 C) on the side edge which will be crossed by a line drawn perpendicularly from the end point of the longitudinal part of the longer branch 4a should be on the

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opposite side of the shorter branch 4b from the perpendicular part of the longer branch 4a.

The embodiment of the invention shown in Fig. 1 D is characterized wherein the longer branch 4a of the grooves 4 is not L-shaped but is curved, extending from an edge point of the glass coating layer 5, passing over a side edge of the resistor 2 (at"the crossing point"), to an end point which is displaced longitudinally from the aforementioned crossing point. The shorter branch 4b is straight, substantially perpendicular to the longitudinal direction, extending from another edge point of the glass coating layer 5 and reaching an intermediate point on the longer branch 4a away from its end point.

Fig. 2 shows equipotential lines inside the resistor 2 of the chip resistor according to the first embodiment of the invention shown above in Fig.

1 A when a potential difference has been applied across its electrodes 3. Since the application of the potential difference does not affect the area 2a completely surrounded by the grooves 4, it is between points A and B indicated in Fig. 2 on opposite sides of the grooves 4 that a high potential difference appears as a load.

Let us assume that the load potential difference between points A and B is about 150V, that the width LI of the grooves 4 is 50Jlm and that the width L2 of the area 2a surrounded by the grooves 4 is 160pm. In such a realistic situation, the voltage per unit charge (or the electric field intensity) between points A and B is about 577V/mm. Since this field intensity is sufficiently smaller than the threshold field intensity of3000V/mm for starting a discharge in air, there is no danger of occurrence of a discharge with this chip resistor and this means that an even higher potential difference can be applied.

Next, the method of carrying out laser-trimming according to this invention will be described with reference to Fig. 3. To produce the grooves 4 of the chip resistor shown in Fig. 1A the laser-trimming is started from the edge point of the glass coating layer 5 (as shown in Fig. 1A) at one end of the longer branch 4a and the laser is kept moving perpendicularly to the longitudinal direction to form the perpendicular part of the longer branch 4a, as indicated by circled numeral ! in Fig. 3. After reaching the comer point of the L-shaped

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longer branch 4a, the laser is moved in the longitudinal direction until it reaches the end point of the longer branch 4a as indicated by circled numeral 2. The length of the longitudinal part of the longer branch 4a is adjusted such that the resistor 2 has the resistance value desired for the chip resistor.

The laser emission is stopped when the longer part 4a of the grooves 4 has thus been completed, and the galvanometer (not shown) is returned in the longitudinal direction as indicated by circled numeral 3. When it reaches the aforementioned branching point between the longer and shorter branches 4a and 4b, the laser is switched on again and the trimming is effected perpendicularly to the longitudinal direction, as indicated by circled numeral 4 in Fig. 3.

The method of laser-trimming according to this invention is advantageous in that the laser can be aimed more accurately and the grooves can be formed more accurately, say, than in the production of prior art C-shaped grooves described above. Fig. 4 compares the distributions (averages and deviations) of the differences between measured and target resistance values between prior art chip resistor samples with L-shaped and C-shaped grooves and samples embodying this invention. For each shape of the grooves, thirty samples were tested. The target resistance was 900kQ. Symbols R indicate samples obtained by carrying out the laser-trimming after the resistor 2 has been formed and symbols G indicate those obtained by carrying out the laser-trimming after the glass coating layer 5 has been formed over the resistor 2. Resistance values were measured for all these samples, the difference of each from the target resistance value was calculated, and their averages and deviations are shown in Fig. 4.

Fig. 4 shows clearly that the differences from the target value (their average as well as the deviations) for samples embodying this invention are about the same as for those with an L-shaped groove and much better than those with a C-shaped groove produced by the prior art method.

The invention has been described above with reference to only a limited number of examples, but these examples are not intended to limit the

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scope of the invention. Many modifications and variations are possible within the scope of the invention. For example, the laser-trimming need not be carried out after the glass coating layer 5 is formed on the surface of the resistor 2.

Alternatively, the laser-trimming according to this invention may be carried out directly on the resistor 2 without forming the glass coating layer 5. As for the pattern of the grooves 4, Figs. I A, IB, I C and ID are not intended to limit the scope of the invention. Neither the longer part nor the shorter part of the grooves 4 is required to be straight or exactly perpendicular to the longitudinal direction. The longer part 4a may even be straight and oblique to the longitudinal direction although it is preferable, from the point of view of accuracy in adjusting the resistance value, that it be longitudinally oriented near the end point.

In summary, chip resistors according to this invention do not easily generate a leak current due to an atmospheric discharge because no large load potential difference is generated over a very short distance (as was the case with prior art resistors with an L-shaped groove as shown in Fig. 5). Moreover, dimensionally accurate grooves can be produced according to the method of this invention, as compared to the prior art resistors with a C-shaped groove.

Claims (5)

1. A chip resistor comprising: a substrate; a pair of electrodes on said substrate; and a resistor which is elongated in a longitudinal direction between and connected to said electrodes, laser-trimmed grooves being formed on said resistor according to a pattern, said pattern including a longer branch and a shorter branch, said longer branch extending so as to draw an arc from a selected point on a side edge, which is parallel to the longitudinal direction, of said resistor to a connection point located away longitudinally and orthogonally to the longitudinal direction from the selected point, and extending further from the connection point substantially in parallel to the longitudinal direction to an end point which is longitudinally closer to one of said electrodes than said selected point, said shorter branch extending from the connection point straight in perpendicular to the longitudinal direction to another point on said side edge of said resistor.

2. A method of laser-trimming a resistor of a chip resistor to form grooves thereon, said resistor being elongated in a longitudinal direction between and connected to a pair of electrodes on a substrate, said method comprising steps of : forming a first part of a longer branch of said grooves by switching on and moving a laser so as to draw an arc starting from a selected point on a side edge, which is parallel to the longitudinal direction, of said resistance, to a connection point which is longitudinally closer to one of said electrodes than the selected point is and closer to another side edge of the resistance than the selected point is; forming a second part of the longer branch, while keeping the laser switched on, by moving the laser from the connection point in a direction substantially parallel to the longitudinal direction to an end point which is longitudinally closer to one of said electrodes than said connection point is ; switching off said laser at said end point; moving said switched-off laser backward along said second part of the longer branch to the connection point; and switching on said laser and forming a shorter branch of said grooves by moving said laser from said connection point to another point on said side edge so as to form a line perpendicular to the second part of the longer branch.

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3. The method of claim 2, wherein the step of forming said longer branch includes the step of thereby adjusting resistance of said resistor.

4. A chip resistor substantially as any one embodiment herein described with reference to Fig. 1 D of the accompanying drawings.

5. A method of laser trimming a resistor of a chip resistor to form grooves thereon substantially as any one embodiment herein described with reference to Fig. 1 D of the accompanying drawings.