Semiconductor device having MEMS
First Claim
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1. A method of manufacturing a semiconductor device having a MEMS, comprising the steps of:
- forming an integrated circuit including a processor, a memory, a driving circuit, and a sensor circuit on a semiconductor substrate;
forming an interlayer dielectric layer on the semiconductor substrate;
forming in a plurality of unit regions on the interlayer dielectric layer a plurality of control electrodes and a plurality of sensor electrodes which are insulated from each other;
forming a support member from a conductive material on the interlayer dielectric layer so as to become higher than the control electrode;
preparing a mirror substrate which comprises mirrors in a plurality of opening regions and is formed from a conductive material, the mirrors being pivotally coupled to the mirror substrate via coupling portions; and
connecting and fixing the mirror substrate onto the support member to arrange the mirrors of the mirror substrate at an interval above the control electrodes and the sensor electrodes which are formed for the plurality of units, wherein the control electrodes are electrically connected to the driving circuit so as to receive a signal from the driving circuit, and the sensor electrodes are electrically connected to the sensor circuit so as to output a signal to the sensor circuit.
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Abstract
In a semiconductor device having a MEMS according to this invention, a plurality of units having movable portions for constituting a MEMS are monolithically mounted on a semiconductor substrate on which an integrated circuit including a driving circuit, sensor circuit, memory, and processor is formed. Each unit has a processor, memory, driving circuit, and sensor circuit.
38 Citations
8 Claims
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1. A method of manufacturing a semiconductor device having a MEMS, comprising the steps of:
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forming an integrated circuit including a processor, a memory, a driving circuit, and a sensor circuit on a semiconductor substrate;
forming an interlayer dielectric layer on the semiconductor substrate;
forming in a plurality of unit regions on the interlayer dielectric layer a plurality of control electrodes and a plurality of sensor electrodes which are insulated from each other;
forming a support member from a conductive material on the interlayer dielectric layer so as to become higher than the control electrode;
preparing a mirror substrate which comprises mirrors in a plurality of opening regions and is formed from a conductive material, the mirrors being pivotally coupled to the mirror substrate via coupling portions; and
connecting and fixing the mirror substrate onto the support member to arrange the mirrors of the mirror substrate at an interval above the control electrodes and the sensor electrodes which are formed for the plurality of units, wherein the control electrodes are electrically connected to the driving circuit so as to receive a signal from the driving circuit, and the sensor electrodes are electrically connected to the sensor circuit so as to output a signal to the sensor circuit. - View Dependent Claims (2, 3)
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4. A method of manufacturing a semiconductor device having a MEMS, comprising at least the steps of:
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forming an integrated circuit including processor, a memory, a driving circuit, and a sensor circuit on a semiconductor substrate;
forming an interlayer dielectric layer on the semiconductor substrate;
forming in a plurality of unit regions on the interlayer dielectric layer a plurality of control electrodes and a plurality of sensor electrodes which are insulated from each other;
forming a support member from a conductive material on the semiconductor substrate via an insulating film so as to become higher than the control electrode;
forming a mirror substrate from a conductive material on the support member while holding a space above the control electrodes and the sensor electrodes; and
forming, in the plurality of unit regions, opening regions which pass through the mirror substrate, and forming, in the opening regions, mirrors which are pivotally coupled to the mirror substrate via coupling portions, wherein the mirrors formed on the mirror substrate in the unit regions are arranged at an interval above the control electrodes and the sensor electrodes, the control electrodes are electrically connected to the driving circuit so as to receive a signal from the driving circuit, and the sensor electrodes are electrically connected to the sensor circuit so as to output a signal to the sensor circuit.
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5. A method of manufacturing a semiconductor device having a MEMS, comprising the steps of:
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forming an integrated circuit including a processor, a memory, a driving circuit, and a sensor circuit on a semiconductor substrate;
forming on the semiconductor substrate an interlayer dielectric layer which covers the integrated circuit;
forming a seed layer on the interlayer dielectric layer;
forming on the seed layer a first sacrificial pattern having openings in a first region, a plurality of second regions, and a plurality of third regions;
forming on the seed layer exposed in the first, second, and third regions a first metal pattern substantially equal in film thickness to the first sacrificial pattern by plating, and a second metal pattern and a third metal pattern not larger in film thickness than the first metal pattern;
after forming the first, second, and third metal patterns into predetermined film thicknesses, forming on the first sacrificial pattern and the second and third metal patterns a second sacrificial pattern having an opening in a fourth region on the first metal pattern;
forming a fourth metal pattern substantially equal in film thickness to the second sacrificial pattern by plating on a surface of the first metal pattern that is exposed in the fourth region;
after forming the fourth metal pattern into a predetermined film thickness, removing the first and second sacrificial patterns;
after removing the sacrificial patterns, selectively removing the seed layer by using the first, second, and third metal patterns as a mask, thereby forming a support member from a layered structure of the first and fourth metal patterns, a plurality of control electrodes which are formed from the plurality of second metal patterns and separated from each other on the interlayer dielectric layer, and a plurality of sensor electrodes which are formed from the plurality of third metal patterns and separated from each other on the interlayer dielectric layer;
preparing a mirror substrate which comprises mirrors in a plurality of opening regions and is formed from a conductive material, the mirrors being pivotally coupled to the mirror substrate via coupling portions; and
connecting and fixing the mirror substrate onto the support member to arrange the mirrors of the mirror substrate at an interval above the control electrodes and the sensor electrodes, wherein the control electrodes are electrically connected to the driving circuit so as to receive a signal from the driving circuit, and the sensor electrodes are electrically connected to the sensor circuit so as to output a signal to the sensor circuit. - View Dependent Claims (6, 7)
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8. A method of manufacturing a semiconductor device having a MEMS, comprising the steps of:
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forming an integrated circuit including a processor, a memory, a driving circuit, and a sensor circuit on a semiconductor substrate;
forming on the semiconductor substrate an interlayer dielectric layer which covers the integrated circuit;
forming a seed layer on the interlayer dielectric layer;
forming on the seed layer a first sacrificial pattern having openings in a first region, a plurality of second regions, and a plurality of third regions;
forming on the seed layer exposed in the first, second, and third regions a first metal pattern substantially equal in film thickness to the first sacrificial pattern by plating, and a second metal pattern and a third metal pattern not larger in film thickness than the first metal pattern;
after forming the first, second, and third metal patterns into predetermined film thicknesses, forming on the first sacrificial pattern and the second and third metal patterns a second sacrificial pattern having an opening in a fourth region on the first metal pattern;
forming a fourth metal pattern substantially equal in film thickness to the second sacrificial pattern by plating on a surface of the first metal pattern that is exposed in the fourth region;
after forming the fourth metal pattern into a predetermined film thickness, forming on the second sacrificial pattern a mirror substrate which is electrically connected to the fourth metal pattern and formed from a conductive material;
forming a through hole in the mirror substrate, and forming in a plurality of predetermined regions of the mirror substrate a plurality of mirrors which are pivotally coupled to the mirror substrate via coupling portions;
removing the first and second sacrificial patterns via the through hole formed in the mirror substrate; and
after removing the sacrificial patterns, selectively removing the seed layer via the through hole by using the first, second, and third metal patterns as a mask, thereby forming a support member from a layered structure of the first and fourth metal patterns, a plurality of control electrodes which are formed from the plurality of second metal patterns and separated from each other on the interlayer dielectric layer, and a plurality of sensor electrodes which are formed from the plurality of third metal patterns and separated from each other on the interlayer dielectric layer, wherein the mirrors formed on the mirror substrate are arranged at an interval above the control electrodes and the sensor electrodes, the control electrodes are electrically connected to the driving circuit so as to receive a signal from the driving circuit, and the sensor electrodes are electrically connected to the sensor circuit so as to output a signal to the sensor circuit.
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Specification