JP5328924B2 - Sensor device and method for manufacturing sensor device - Google Patents

Description

  The present invention relates to a sensor device and a method for manufacturing the sensor device.

In recent years, humanoid robots have been developed.
Humanoid robots are required to perform advanced operations such as touching people, autonomously avoiding obstacles, and grasping and moving objects.
Since such an operation requires a tactile sensation, research has been progressing to provide a tactile sensor on the robot hand or the entire surface (for example, Patent Document 1 to Patent Document 6).

Conventional tactile sensor systems mainly employ a mesh structure.
For example, a plurality of electrode wirings are formed on each of two electrode sheets.
The mesh-like wiring is formed by arranging the electrode sheets so that the electrode wirings are orthogonal to each other.
A pressure-sensitive conductive member is sandwiched between two electrode sheets, or a tactile sensor element is disposed at each intersection of electrode wiring.
Each tactile sensor element converts a pressure change or a temperature change due to contact with an object into an electric signal change corresponding to the change amount.

The control unit is connected to each electrode wiring and centrally manages a plurality of tactile sensor elements. That is, the control unit sequentially selects each tactile sensor element and samples the sensor value of each sensor. In the control unit, electrical signals from the tactile sensor elements are integrated and processed.
By periodically repeating such sampling operation, it is detected whether the robot is in contact with the object and which sensor is in contact.
Thereby, it is possible to sense at what position the robot is in contact with the object at what level.

JP 2006-337315 A JP 2007-10482 JP 2007-285784 A JP 2007-78382 A JP 2006-287520 A JP 2006-281347 A Japanese Patent No. 03621093

The conventional tactile sensor system has the following problems.
In the technologies disclosed in Patent Document 1 to Patent Document 6, a control unit serves as a host to centrally manage a large number of tactile sensor elements, select each tactile sensor element in order, and sample the sensor value of each sensor. I will do it.
In the case of such a configuration, there is a problem that the processing load on the control unit becomes very large as the number of sensors increases.
Also, the sampling interval becomes longer as the number of sensors increases. Then, it is inevitable that the response speed becomes low and the response becomes slow, but this is a fatal problem as a tactile sensor system for a robot.

Further, considering the arrangement of a large number of tactile sensors on the entire body surface of the robot, the wiring between the tactile sensors and the control unit becomes enormous.
Therefore, in practice, it is considerably difficult to mount a large number of tactile sensors at desired positions, and it is very difficult to maintain or repair the failure.
In addition, since the wiring between the tactile sensor and the control unit becomes a long distance, there is a high risk that the sensor signal is deteriorated by noise.

Here, it is conceivable to incorporate a sensor structure unit and a signal processing unit into each tactile sensor.
Then, it is considered that the sensor signal from the sensor structure unit may be sense-amplified by the signal processing unit, and further digital processing may be performed.

For this purpose, a technique for integrating the sensor structure unit and the signal processing unit is required.
For example, Japanese Patent No. 03621093 (Patent Document 7) discloses a packaging technique called a shell case.
In this Japanese Patent No. 03621093, the upper and lower sides of the device chip are sandwiched between glass plates, and the side surfaces are surrounded by resin.
With this structure, a plurality of wafers can be bonded together, and the device chip is firmly protected by the glass plate.
However, in the technique of Japanese Patent No. 03621093, the upper and lower sides of the device chip must be bonded to glass. Then, for example, there arises a problem that it cannot be applied to a tactile sensor that requires contact with a detection target such as a pressure sensor or a temperature sensor.

  Under such circumstances, a technology for packaging a sensor structure portion having a contact sensing surface and a signal processing LSI portion for processing the sensor signal is desired.

The sensor device of the present invention comprises:
In addition to having a contact sensing surface that directly contacts the detection target on one surface exposed to the outside, a sensor electrode that outputs an analog sensor signal in response to a change in the contact sensing surface is opposite to the contact sensing surface A sensor structure on the surface side;
A semiconductor substrate on which an integrated circuit for signal processing for processing the analog sensor signal is formed;
An adhesive layer disposed between the other surface of the sensor structure portion and the semiconductor substrate, and bonding the sensor structure and the semiconductor substrate;
A sensor device in which the sensor structure and the semiconductor substrate are laminated to form a one-chip with the sensor electrode and the integrated circuit facing each other with the adhesive layer in between,
The sensor electrode and the integrated circuit are sealed inside a sensor device,
The external terminal of at least one of the sensor electrode and the signal processing integrated circuit is drawn out to the back surface of the semiconductor substrate via a side surface of the semiconductor substrate.

The manufacturing method of the sensor device of the present invention includes:
A sensor electrode is provided on the back surface of the wafer to be the sensor structure,
Create a semiconductor substrate incorporating an integrated circuit for signal processing,
Bonding the sensor structure and the semiconductor substrate with an adhesive layer in a state where the sensor electrode and the integrated circuit face each other,
Etching the back surface of the semiconductor substrate, and further exposing the wiring extraction portion of the sensor electrode and the electrode extraction portion of the integrated circuit to the back side of the semiconductor substrate by half dicing from the back surface of the semiconductor substrate,
A lead wiring is provided from the slope of the semiconductor substrate formed by the etching and the half dicing to the back surface of the semiconductor substrate,
The external terminals of the sensor electrode and the signal processing integrated circuit are drawn out to the back surface of the semiconductor substrate through the side surface of the semiconductor substrate.

The figure which shows a mode that the tactile sensor system was applied to the hand of the robot. The figure which shows a mode that the several sensor apparatus has been arrange | positioned to the bus | bath. The perspective view which looked at the sensor apparatus from the surface side. The perspective view which looked at the sensor apparatus from the back side. Sectional drawing of a sensor apparatus. The figure which shows the manufacturing process of a sensor apparatus in 1st Embodiment. The figure which shows the manufacturing process of a sensor apparatus in 1st Embodiment. The figure which shows the manufacturing process of a sensor apparatus in 1st Embodiment. The figure which shows the manufacturing process of a sensor apparatus in 1st Embodiment. The figure which shows the manufacturing process of a sensor apparatus in 1st Embodiment. The figure which shows the manufacturing process of a sensor apparatus in 1st Embodiment. 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The figure which shows the manufacturing process of a sensor apparatus in 1st Embodiment. The figure which shows the manufacturing process of a sensor apparatus in 1st Embodiment. The figure which shows the manufacturing process of a sensor apparatus in 1st Embodiment. The figure which shows the manufacturing process of a sensor apparatus in 1st Embodiment. The figure which shows the manufacturing process of a sensor apparatus in 1st Embodiment. The figure which shows the manufacturing process of a sensor apparatus in 1st Embodiment. The figure which shows the manufacturing process of a sensor apparatus in 1st Embodiment. The figure which shows the structure of 2nd Embodiment in the state decomposed | disassembled. The figure which shows the manufacturing process of 2nd Embodiment. The figure which shows the manufacturing process of 2nd Embodiment. The figure which shows the manufacturing process of 2nd Embodiment. The figure which shows the manufacturing process of 2nd Embodiment. 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The figure which shows the manufacturing process of 3rd Embodiment. The figure which shows the manufacturing process of 3rd Embodiment. The figure which shows the structure of 3rd Embodiment. The figure for demonstrating the procedure which converts a sensor signal into a digital signal. The figure for demonstrating the procedure which converts a sensor signal into a digital signal. The figure which represents the structure of this invention most simply. FIG. 6 is a cross-sectional view of a sensor device according to a fourth embodiment. FIG. 6 is a perspective view of a sensor device according to a fourth embodiment viewed from the back side. FIG. 10 is a diagram showing a manufacturing process of a fourth embodiment. FIG. 10 is a diagram showing a manufacturing process of a fourth embodiment. FIG. 10 is a diagram showing a manufacturing process of a fourth embodiment. FIG. 10 is a diagram showing a manufacturing process of a fourth embodiment. FIG. 10 is a diagram showing a manufacturing process of a fourth embodiment. FIG. 10 is a diagram showing a manufacturing process of a fourth embodiment. FIG. 10 is a diagram showing a manufacturing process of a fourth embodiment. FIG. 10 is a diagram showing a manufacturing process of a fourth embodiment. FIG. 10 is a diagram showing a manufacturing process of a fourth embodiment. FIG. 10 is a diagram showing a manufacturing process of a fifth embodiment. FIG. 10 is a diagram showing a manufacturing process of a fifth embodiment. FIG. 10 is a diagram showing a manufacturing process of a fifth embodiment. FIG. 10 is a diagram showing a manufacturing process of a fifth embodiment.

Embodiments of the present invention will be illustrated and described with reference to reference numerals attached to respective elements in the drawings.
(First embodiment)
A first embodiment according to the sensor device of the present invention will be described.
FIG. 1 is a diagram showing a state in which a tactile sensor system in which a large number of sensor devices are arranged is applied to a robot hand.
FIG. 2 is a diagram illustrating a state in which a plurality of sensor devices 200 are arranged on the bus 110. FIG.

As shown in FIG. 1, the sensor device according to the present embodiment is arranged on the hand 11 of the robot 10 or the entire body surface of the robot, and constitutes the tactile sensor system 100 as a whole.
Each bus 110 is provided with a plurality of tactile sensor devices 200.
In the present embodiment, four lines 112, 112, 113, 113 are provided as wiring lines of the bus 110.
Two of the four are power lines 112 and 112, and two are signal lines 113 and 113 for differential serial transmission.
All buses 110 are connected to the information integration device 140 via the information relay device 120 and the concentrator 130.

For example, when the surface of the robot 10 comes into contact with the object by the hand 11 of the robot 10 grasping the object (not shown), each sensor device 200 detects the contact pressure.
Furthermore, each sensor device 200 executes digital signal processing of the sensor signal.
Then, the sensor signal that has undergone the digital signal processing is transmitted from each sensor device 200 to the information integration device 140.
The information integration device 140 integrates information from the sensor device 200 and detects how much force is applied to which position.

Next, the configuration of the sensor device will be described.
FIG. 3 is a perspective view of the sensor device as viewed from the front side.
FIG. 4 is a perspective view of the sensor device as seen from the back side.
FIG. 5 is a cross-sectional view of the sensor device.

As shown in FIG. 5, the sensor device 200 has a structure in which a sensor structure 300 and a semiconductor substrate 400 are bonded together with an adhesive layer 500.
The sensor structure 300 includes a structure body 310, a first sensor electrode 320, and a second sensor electrode 330.
The structure main body 310 is made of Si.

When viewed from the front side, a convex force transmission portion 311 that contacts the object is provided at the center of the structure main body 310, and the periphery of the force transmission portion 311 is a concave thin portion 312.
Since the thin-walled portion 312 has elasticity, the structure main body portion 310 functions as an operating membrane. That is, when a force is applied to the force transmitting portion 311, the structure main body 310 is bent.

  Here, a contact sensing surface is configured by the force transmission unit 311.

A peripheral portion around the thin portion 312 is a support frame portion 313 that supports the working membrane.
Further, a recess 314 is formed on the back surface of the structure main body 310.

The first sensor electrode 320 is provided in a recess 314 formed on the back surface of the structure main body 310.
At least one end of the first sensor electrode 320 is extended to a position reaching the side surface 316 of the structure main body 310 via the back surface of the support frame portion 313.
The first sensor electrode 320 becomes a movable electrode that is displaced together with the working membrane.

The second sensor electrode 330 is provided immediately above the adhesive layer 500.
The distance between the first sensor electrode 320 and the second sensor electrode 330 is defined by the depth of the recess 314.
The second sensor electrode 330 is a fixed electrode, and the first sensor electrode 320 and the second sensor electrode 330 that are arranged to face each other constitute a capacitance element.
The second sensor electrode 330 is connected to the rewiring layer 410 of the semiconductor substrate 400 through a via 510 formed in the adhesive layer 500.

An integrated circuit 420 for signal processing is formed on the semiconductor substrate 400, and the surface thereof is protected by a passivation film 430.
Further, a rewiring layer 410 is formed on the passivation film 430.
The adhesive layer 500 is provided immediately above the semiconductor substrate 400, and the second sensor electrode 330 and the integrated circuit 420 are opposed to each other with the adhesive layer 500 in between.
Further, the first and second sensor electrodes 320 and 330 and the integrated circuit 420 are sealed inside the sensor device 200.

The adhesive layer 500 preferably has a thickness of 10 μm or more in order to reduce the parasitic capacitance between the integrated circuit 420 and the sensor electrode 330.
Although the upper limit of the thickness is not particularly limited, for example, an upper limit of, for example, about 100 μm is taken into account in consideration of the manufacturing convenience of the semiconductor chip.

When the sensor device 200 is viewed from the back side, an inclined surface 211 is formed at the center on each side end surface in the left-right direction in FIG.
Metal lead wires 212 and 213 are formed on the inclined surface 211, and the lead wires 212 and 213 are drawn to the back surface 240.
One of the lead wires 212 is connected to one end of the first sensor electrode, and the other lead wire 213 is connected to the second sensor electrode 330 via the rewiring layer 410 (see FIG. 5).

Further, the side end surfaces 220 and 220 in the vertical direction in FIG. 4 are formed as inclined surfaces 221 and 221 as a whole, and eight lead wires 230 are provided on each side end surface 220 and 220 up to the back surface 240. It is provided to reach.
These lead wires 230 are drawn from the rewiring layer 410 and become power supply lines or signal lines of the integrated circuit 420.

External connection terminals are provided on the back surface 240 of the sensor device 200 shown in FIG.
In the present embodiment, four external terminals 241 to 244 are provided on the back surface of the sensor device 200 in correspondence with the four wiring lines 112 and 113 of the bus 110.
In FIG. 4, the first external terminal 241, the second external terminal 242, the third external terminal 243, and the fourth external terminal 244 are sequentially arranged from the left.

The first external terminal 241 is an external terminal connected to the GND of the bus 110, for example, and the lead wire 212 from the left side 210 and the leftmost lead wire 231 on the lower side 220 are connected to the first external terminal 241. Has been.
The leftmost lead wire 232 on the upper side surface 220 is connected to the second external terminal 242, and the rightmost lead wire 234 on the lower side surface 220 is connected to the third external terminal 243.
The fourth external terminal 244 is connected to the lead wiring 213 from the right side 210 and the rightmost lead wiring 234 on the upper side 220.

  The number of external terminals 241 to 244 is appropriately changed according to the number of signal lines of the bus 110. Of course, it can be done.

Next, a method for manufacturing the sensor device will be described.
6 to 21 are diagrams showing a manufacturing procedure of the sensor device.
First, a wafer 315 to be the structure main body 310 of the sensor structure 300 is created.
That is, as shown in FIG. 6, a wafer 315 made of Si is prepared, and the back surface thereof is etched with TMAH (Tetramethyl ammonium hydroxide) to form a recess 314 having a depth of about 10 μm. Then, as shown in FIG. 7, the first sensor electrode 320 is formed in the recess 314. Further, a mask 317 is formed on the surface of the Si wafer 315 so that a region excluding the force transmission part 311 and the support frame part 313 becomes a thin part 312.
This mask 317 can be formed of a thermal oxide film.

On the other hand, as shown in FIG. 8, a wafer in which an integrated circuit 420 for signal processing is incorporated in a semiconductor substrate 400 is prepared.
Then, the surface is protected by a passivation film 430, and a rewiring layer 410 is provided on the passivation film 430.
The rewiring layer 410 is connected to the electrode pad 421 of the integrated circuit 420.

Next, as shown in FIG. 9, an organic insulating film as an adhesive layer 500 is provided on the upper surface of the semiconductor substrate 400, and a second sensor electrode 330 is provided on the adhesive layer 500.
This process will be described with reference to FIGS.
As described above, the semiconductor substrate 400 incorporating the integrated circuit 420 is prepared.
A BCB (benzocyclobutene) resin film having a thickness of about 10 μm is formed thereon by spin coating (FIG. 10A).
This BCB (benzocyclobutene) resin film becomes the adhesive layer 500.
This is precured for 1 hour in a furnace purged with nitrogen at 220 ° C.

A resist 520 is applied on the BCB film and exposed (FIG. 10B).
The resist 520 is cured by post-exposure baking (FIG. 10C), and then etched.
As a result, a via (hole) 510 is formed immediately above the rewiring layer 410 (FIG. 10D).
Next, the semiconductor substrate 400 and the adhesive layer 500 are hard baked.

Subsequently, aluminum (Al) is deposited on the patterned adhesive layer 500 by sputtering (FIG. 10E).
This aluminum thin film becomes the second sensor electrode 330.
A resist 520 is applied on the aluminum thin film and patterned (FIGS. 10F and 10G).
Then, the aluminum is etched (FIG. 10H).
As a result, the second sensor electrode 330 is formed in the central portion excluding the peripheral portion, and the second sensor electrode 330 is connected to the rewiring layer 410 of the integrated circuit 420 through the via 510.

Next, as shown in FIG. 11, a wafer 315 (FIG. 7) to be the structure main body 310 and a wafer (FIG. 9) to be the semiconductor substrate 400 are bonded.
In joining, for example, a load of 1000 N is applied at 250 ° C. for 1 hour.

A protective film 250 for TMAH etching is formed on the back surface of the semiconductor substrate 400 (FIG. 12).
Here, the protective film 250 is preferably formed by laminating a photosensitive alkali-resistant organic protective film (ProTEK PSB) on a low-temperature oxide film deposited by PECVD or sputtering.
As a mask material that can withstand long-time etching of a Si substrate, a silicon thermal oxide film or a silicon nitride film is generally used, but these require high temperature processing (800 ° C. or higher).
Such a high temperature treatment cannot be applied to the semiconductor substrate 400 in which the integrated circuit 420 is already incorporated.
Further, there is a problem that pinholes are formed only by the low temperature oxide film, and there is a problem that side etching occurs when only the photosensitive alkali-resistant organic protective film is used.

After forming the protective film 250, both surfaces of the bonded wafer are etched (FIG. 13).
Thereby, the thin portion 312 of the sensor structure 300 is formed at the same time as the semiconductor substrate 400 is etched.

Note that the opening pattern of the protective film 250 is preferably a hole shape 251 or a single groove shape 252 as shown in FIG. 14A.
For example, as shown in FIG. 14B, when the grooves 252 and 252 cross each other, the erosion of the corner 254 is fast due to the crystal anisotropic etching of Si using an alkali solution (TMAH), and the internal integration Circuit 420 may be damaged.

Etching is stopped leaving a thickness of about 10 μm from the electrode pad, and the photosensitive alkali-resistant organic protective film 250 is removed (FIG. 15).
After that, isotropic etching by gas etching of XeF ₂ is performed to completely remove the Si substrate (FIG. 16).
Next, a BCB resin is formed as the base insulating film 255 (FIG. 17).
After applying the insulating film, half dicing is performed from the back surface of the semiconductor substrate using a V-shaped blade (FIG. 18).

Here, FIG. 18 shows a cross section taken along line XVIII-XVIII of FIG. 4, and in this direction, the sensor electrodes 320 and 330 need to be pulled out from the side surface of the sensor device 200.
Therefore, in the half dicing, it is necessary to cut up to the upper surface of the adhesive layer 500 so as to reach the first sensor electrode 320.
Thereby, one end of the first sensor electrode 320 and the rewiring layer 410 are exposed to the back side 240 from the left and right side surfaces.

  On the other hand, in the direction of the XIX-XIX line cross section of FIG. 4, only the electrode pad 421 of the integrated circuit 420 needs to be pulled out, so shallow half dicing that reaches the electrode pad 421 or the rewiring layer 410 as shown in FIG. It's okay.

Next, wiring is formed by a shadow mask method (FIG. 20).
As an example of the metal material, Ti / Cu is used.
Ti functions as an intermediate layer for improving adhesion to the insulating film.
Thereafter, electroless Au plating is applied on the wiring to improve wire bonding.
Finally, the wafer is separated by dicing, and the individual sensor devices 200 are cut out (FIG. 21).

According to such a first embodiment, there are the following effects.
(1) By the manufacturing method of this embodiment, the tactile sensor device 200 can be integrated at the wafer level.
That is, the tactile sensor device 200 can be configured as MEMS (Micro Electro Mechanical Systems) integrally including the sensor structure 300 and the integrated circuit 420.
Further, the size of the tactile sensor device 200 can be extremely reduced by integration, and for example, one tactile sensor device can be reduced to about 3 mm square.
Thus, by using MEMS that integrally includes the sensor structure 300 and the integrated circuit 420 and achieving a reduction in size, the sensor system can be suitably used as a sensor system mounted on the body surface of the robot 10, for example.

(2) The accumulated charge amount is taken out from the sensor electrodes 320 and 330 as an analog sensor signal to the integrated circuit 420. However, such an analog sensor signal has a problem that input impedance is high and noise is easily mixed.
In this regard, in this embodiment, the sensor electrodes 320 and 330 and the integrated circuit 420 can be sealed inside the sensor to completely protect them.
Furthermore, since the second sensor electrode 330 and the integrated circuit 420 are disposed in close proximity within the sensor with the adhesive layer 500 interposed therebetween, the wiring length between the second sensor electrode 330 and the integrated circuit 420 is extremely short. can do. Therefore, it is difficult for noise to enter the analog sensor signals from the sensor electrodes 320 and 330, and the detection accuracy can be greatly improved.

(3) In the manufacturing method of the present embodiment, the sensor structure 300 and the semiconductor substrate 400 are joined by the adhesive layer 500, and therefore the structure of the integrated circuit 420 incorporated in the semiconductor substrate 400 is not limited.
For example, a semiconductor substrate 400 incorporating an existing sense amplifier and signal processing circuit can be applied to this embodiment.

(4) In this embodiment, since the sensor electrodes 320 and 330 and the integrated circuit 420 are sealed inside the sensor, it is necessary to take out these electrodes to the outside.
Here, in the case where an electrode is taken out from the chip sealed inside the package, it may be possible to form through silicon vias (silicon through wiring). However, it is a process to provide as many through silicon vias as necessary. The number is greatly increased and processing is also difficult.
In this regard, in this embodiment, the sensor electrode and the electrode of the integrated circuit are taken out from the back surface of the semiconductor substrate by etching and half dicing.
Therefore, the number of steps can be reduced and the external terminals can be provided easily.

(5) Due to the diaphragm structure including the force transmitting portion 311 and the thin portion 312, the force applied to the structure main body 310 is accurately reflected in the deformation of the structure main body 310.
In addition, since the first sensor electrode 320 is directly formed on the back surface of the structure main body 310, the deformation of the structure main body 310 due to an external force received by the force transmission unit 311 is used as the displacement of the first sensor electrode 320. Therefore, it is possible to accurately detect the applied force as a change in capacitance of the capacitive element formed by the second sensor electrode 330.

(6) Since at least one end of the first electrode 320 extends to a position reaching the side surface 316 of the structure main body 310 via the back surface of the support frame portion 313, it can be directly connected to an external power source or a circuit. it can.
For example, if the first electrode 320 is connected to the ground electrode of the external power source to have the same potential, the electrode closest to the outside serves as ground, shields noise from the outside, and improves measurement accuracy.
Further, if the first electrode 320 and the structure main body 310 are formed so as to be electrically connected, the structure main body 310 becomes a ground potential, the shielding ability against external noise is further improved, and the S / N ratio is increased. It will be extremely improved.

(7) Since the first and second sensor electrodes 320 and 330 and the integrated circuit 420 are sealed inside the sensor device 200, the electrodes and wiring of the sensor electrodes 320 and 330 and the integrated circuit 420, The pn junction can be prevented from being corroded or oxidized due to the penetration of water, acid, alkali, organic solvent, oil or the like from the outside, gas intrusion, alteration, conductive coating, etc., and stable operation can be realized for a long time.
Therefore, the apparatus can be coated with an organic substance dissolved in an organic solvent, or can be attached to a robot's limbs to operate under adverse conditions such as muddy water.

(8) The adhesive layer 500 is formed on the passivation film 430 on the surface of the integrated circuit 420 for signal processing built in the semiconductor substrate 400, and the second sensor electrode 330 is formed on the adhesive layer 500. As a result, the wiring distance between the integrated circuit 420 and the capacitive element composed of the first sensor electrode 320 and the second sensor electrode 330 is short.
Therefore, parasitic capacitance, which is an important factor that affects the sensitivity and accuracy of the sensor, can be reduced, and detection sensitivity is improved.
Because the wiring length is short, it is difficult for noise to enter.
By setting the thickness of the adhesive layer 500 to be large, the parasitic capacitance between the integrated circuit 420 and the sensor electrode 330 can be further reduced, so that higher sensitivity can be achieved.

(9) An inclined surface 211 is provided at the center of each side end surface in the left-right direction, and an inclined surface 221 is provided on the entire side end surface 220 in the up-down direction. Metal lead wires 212, 213, 230 is formed. By arranging the wirings 212, 213, and 230 on the slope, the manufacturing is easy, the film thickness of the wiring is secured, and instability such as disconnection is eliminated.
These shapes and structures increase stability against temperature and durability against repeated temperature changes, and the reliability of wiring when mounting a device or in use is greatly improved.
Unlike the inclined surface on each side end surface 220 in the up-down direction, the inclined surface 211 on each side end surface in the left-right direction is a slope having a shape limited to the center portion of each side end surface in the left-right direction.
This is to solve the manufacturing problem of the inclined surface, but the reliability of the wiring can be improved by using the inclined surface 211 having a structure slightly recessed from the inclined surface 211.

(10) The wirings for the sensor electrodes 320 and 330 are the lead-out wirings 212 and 213 formed on the inclined surfaces 211 on the side end surfaces in the left-right direction, and the electrodes for the integrated circuit 420 are the side end surfaces in the vertical direction. The lead wires 230, 231, 232, and 234 are formed on the inclined surface 221 at 220.
Here, the depth of the wedge-shaped cut for taking out the wiring for the sensor electrode is deeper than the wedge-like cut-out for taking out the wiring for the integrated circuit.
As a result, it is possible to stably take out wirings in two different directions.

(11) In the present embodiment, the adhesive layer 500 serves as both an insulating film and an adhesive.
Therefore, the adhesive layer 500 is required to have stability as an insulating film and flexibility and adhesiveness as an adhesive.
In this regard, in the present embodiment, a BCB (benzocyclobutene) resin film is used for the adhesive layer, and after pre-curing at 220 ° C., the sensor electrode is patterned.
The sensor structure 300 and the semiconductor substrate 400 are bonded at 250 ° C.
At this time, when the pre-cure temperature is lowered, flexibility and adhesiveness are increased, but a problem arises in stability.
In addition, when the pre-cure temperature is raised, the stability increases, but the adhesiveness and flexibility cannot be maintained. If the temperature at the time of joining is increased to compensate for this, the problem of damaging the sensor electrode arises.
In this embodiment, these problems can be solved, and optimal stability, flexibility, and adhesiveness can be realized.

(Second embodiment)
A second embodiment will be described.
In the first embodiment, the case where the structure main body 310 and the semiconductor substrate 400 are bonded together after the second sensor electrode 330 is formed immediately above the adhesive layer 500 formed on the semiconductor substrate 400 has been exemplified.
In contrast, in the second embodiment, first, the glass substrate 600 on which the second electrode 320 is formed is bonded to the back surface of the structure body 310, and the electrodes 320 and 330 of the sensor structure 300 are sealed. (Figure 22).
Thereafter, the semiconductor substrate 400 and the wafer of the sensor structure unit 300 are bonded by the adhesive layer 500.

FIG. 23A to FIG. 23I are views showing a manufacturing procedure of the second embodiment.
As shown in FIG. 23A, the wafer (FIG. 7) to be the structure main body 310 and the glass substrate 600 are bonded together.
At this time, the second sensor electrode 330 is formed on the glass substrate 600.
Thereby, the first sensor electrode 320 and the second sensor electrode 330 are sealed between the structure main body 310 and the glass substrate 600.

In FIG. 23A, a groove 318 is formed by etching at a dicing planned position on the side where the lead wiring of the second sensor electrode 330 is provided in the wafer serving as the structure main body.
This prevents the dicing blade from cutting into the Si structure main body 310 during half dicing.

  Then, an adhesive layer 500 is formed on the back surface of the glass substrate 600, and the glass substrate 600 and the semiconductor substrate 400 are bonded.

In FIG. 23G, half dicing for exposing the sensor electrodes 320 and 330 is performed.
At this time, it is necessary to cut to the upper surface of the glass substrate 600.

  Other steps are the same as those described in the first embodiment, and the sensor device shown in FIG. 24 is finally obtained.

In this configuration, the wafer (FIG. 7) to be the structure main body 310 and the glass substrate 600 are bonded together, and the second sensor electrode 330 is formed on the glass substrate 600, and the first sensor electrode 320 and the second sensor electrode 320 are formed. Since the sensor electrode 330 is sealed between the structural body 310 and the glass substrate 600, the shape, gap, and relative position of the first sensor electrode 320 and the second sensor electrode 330 can be set more accurately. it can.
Thereby, more accurate sensor performance can be realized.

(Third embodiment)
A third embodiment will be described.
In the second embodiment, the glass substrate 600 on which the second electrode 330 is formed is bonded to the back surface of the structure main body 310 to seal the electrodes 320 and 330 of the sensor structure 300, and then the semiconductor substrate 400 And the case where the wafer of the sensor structure 300 is bonded by the adhesive layer 500.
In this regard, the third embodiment is characterized in that instead of the glass substrate 600, an LTCC (Low Temperature Co-fired Ceramics) substrate 700 is used.
In FIG. 25, the second sensor electrode 330 is formed on the upper surface of the LTCC substrate 700.
Further, the wiring layer 710 is formed on the LTCC substrate 700, and the wiring layer 710 and the second sensor electrode 330 are connected via the via 720.
Therefore, the lead line of the second sensor electrode 330 may be drawn from the wiring layer 710 of the LTCC substrate 700.

FIG. 26 is a diagram showing a manufacturing procedure according to the third embodiment.
As shown in FIG. 26A, the wafer (FIG. 7) to be the structure main body 310 and the LTCC substrate 700 are bonded together.
At this time, the wiring layer 710 is formed in the LTCC substrate 700, and the second sensor electrode 330 formed on the upper surface of the LTCC substrate 700 is connected to the wiring layer 710.
26A, the first sensor electrode 320 and the second sensor electrode 330 are sealed between the structure main body 310 and the LTCC substrate 700.

  Then, an adhesive layer 500 is formed on the back surface of the LTCC substrate 700, and the LTCC substrate 700 and the semiconductor substrate 400 are joined.

In FIG. 26G, half dicing for exposing the sensor electrodes 320 and 330 is performed.
At this time, it is necessary to cut the top surface of the LTCC substrate 700.

  Other steps are the same as those described in the first embodiment, and the sensor device shown in FIG. 27 is finally obtained.

For example, since the second sensor electrode 330 is formed on a ceramic substrate such as an LTCC substrate, the shape, gap, and relative position of the first sensor electrode 320 and the second sensor electrode 330 can be more accurately the same as the glass substrate 600. Can be set to
Furthermore, it becomes possible to form multilayer wiring, resistors, capacitors, coils, interlayer electrodes, interlayer dielectric films on the ceramic substrate 700, and to incorporate active electronic components such as passive electronic components, diodes, and transistors between the layers, The sensitivity and S / N ratio of the sensor can be effectively improved in analog by analog signal processing before digitization.
As a result, the function, type, and application range of the sensor are greatly expanded.

(Fourth embodiment)
In the first to third embodiments, half dicing is performed to expose the first and second sensor electrodes 320 and 330. However, in the fourth embodiment, after etching with TMAH, a passivation film ( The first and second sensor electrodes 320 and 330 are exposed by etching a TEOS film (SiN film, etc.) 430 using a fast atom beam, accelerated ions, or mechanical etching such as sandblasting.
FIG. 31 is a cross-sectional view of the sensor device according to the fourth embodiment. As shown in FIG. 31, in the adhesive layer 500, the via 510 that electrically connects the second sensor electrode 330 and the rewiring layer 410 of the semiconductor substrate 400, and the first sensor electrode 320 and the back surface 240 are electrically connected. And vias 520 connected to.
FIG. 32 is a perspective view of the sensor device according to the fourth embodiment viewed from the back side. As shown in FIG. 32, the first sensor electrode 320 on the back surface of the structure main body 310 is exposed through the via 520, and is drawn out to the back surface 240 by the lead-out wiring 212 connected to the via 520.
33A to 33I are views showing manufacturing steps of the fourth embodiment. As shown in FIG. 32A, first, the wafer to be the structure main body 310 and the semiconductor substrate 400 on which the adhesive layer 500 provided with the via 520 is formed are bonded and thinned (FIG. 32B).
Next, the passivation film 430 is exposed by wet etching with TMAH and dry etching with XeF ₂ (FIG. 33C). Thereafter, as shown in FIG. 33D, etching is performed to remove the passivation film 430. Accordingly, the first and second sensor electrodes 320 and 330 are simultaneously exposed due to the presence of the via 520.
Further, a photosensitive BCB is formed on the back surface 420 of the semiconductor substrate to form an insulating film (FIG. 33E). The formed BCB is etched by RIE (Reactive Ion Etching) to expose the first and second sensor electrodes 320 and 330 again (FIG. 33F).
In the manufacturing process of the fourth embodiment, other processes are substantially the same as the manufacturing process of the first embodiment, and a detailed description thereof will be omitted.
Further, in the first to fourth embodiments, the sensor structure and the semiconductor substrate are integrated (one-chip).
According to such a configuration, the sensor signal from the sensor structure unit 300 can be signal-processed by the integrated circuit 420 incorporated in the semiconductor substrate 400.
Thus, if signal processing can be executed by each tactile sensor device 200, the signal processing load on the information integration device 140 can be reduced.
Even if a large number of tactile sensor devices 200 are arranged in the tactile sensor system 100, the increase in processing load of the information integration device 140 can be reduced, so that a high-speed response is possible even though it is a large system having many tactile sensor devices 200. It can be set as a revolutionary tactile sensor system.

  Here, an example in the case of converting the sensor signal from the sensor structure portion into a digital signal will be exemplified.

  In this example, the diaphragm type sensor structure unit 300 and the LSI integrated with the signal processing unit are bonded together by the adhesive layer 500, so that the whole is an integrated one package.

The sensor structure unit 300 includes two electrode plates 320 and 330 arranged to face each other.
The upper surface of the sensor structure unit 300 is a force transmission unit (sensor surface) 311 that comes into contact with an object. When the force transmission unit 311 is pressed, the distance d between the two electrode plates 320 and 330 changes. To do.
The change in capacitance due to the change in the electrode plate interval d becomes an analog sensor signal.

For example, as shown in FIG. 28, it is assumed that a strong force is applied to the force transmission unit 311 from time T1 to time T2, and a weak force is applied to the force transmission unit 311 from time T3 to time T4.
Then, the distance d between the electrode plates changes according to the applied force.
The amount of charge Q accumulated between the plates changes according to the change in the distance d between the plates.
An inter-electrode charge amount Q that changes in accordance with the applied force is sent to the integrated circuit 420 as an analog sensor signal.
Specifically, the electric charge accumulated in the second sensor electrode 330 is detected by the integrated circuit 420 via the rewiring layer 410 and the electrode pad 421.

The integrated circuit 420 digitally converts the analog sensor signal from the sensor structure 300.
A manner of digitally converting the capacitance change into the frequency change will be described with reference to FIG.
The integrated circuit 420 outputs the selection signal Sct and the reset signal Rst at a constant period when taking out the sensor signal from the sensor structure 300.
The selection signal Sct is an ON signal of a switch (not shown) disposed between the electrode plate 330 and the integrated circuit 420.
The reset signal Rst is a signal for resetting the charge of the electrode plate 330 once to GND.

By the selection signal Sct, the inter-electrode charge amount Q is taken out at a constant period.
The inter-electrode charge amount Q thus taken out is converted into a voltage V _Q via a predetermined resistance.
Contrasting this V _Q with a predetermined reference voltage Vref.
A pulse signal Vout having a time width in which V _Q exceeds Vref is generated.
At this time, if the withdrawal rate of the charge is constant, the pulse width of the high and Vout of V _Q has a positive correlation.
Vout is converted into a pulse signal having a predetermined frequency by a pulse generator (not shown).
By counting the number of pulses per unit time, the force applied to the sensor structure 300 can be measured as a digital quantity.
The sensor signal digitized by frequency conversion in this manner is used as a digital sensor signal.

The digital sensor signal generated in this way is transmitted from each tactile sensor device 200 to the information integration device 140.
In signal transmission, the signal may be transmitted by differential serial transmission through two signal lines 113 and 113 of the bus.
In this way, by transmitting a digital signal from the touch sensor device 200 to the information integration device 140, even if the wiring length between the touch sensor device 200 and the information integration device 140 is long, it is less susceptible to noise.
For example, if the tactile sensor device 200 is provided on the entire body surface of the robot, the entire wiring length becomes considerably long, so noise resistance becomes important.
Compared to the case where the analog signal is transmitted as it is, the configuration of the present embodiment is suitable for a sensor system including a large number of tactile sensor devices 200.
(Fifth embodiment)
In the first to fourth embodiments, the heights of the support frame portion 313 and the force transmission portion 311 are the same. However, in order to effectively detect the shearing force, the force transmission portion 311 is provided on the support frame. It is preferable that the height be higher than that of the portion 313.
Therefore, in the fifth embodiment, at the stage of separating the sensor device 200 from the wafer state, the support frame portion 313 is cut by half dicing, so that the force transmission portion 311 is made more than the support frame portion 313 as described above. Set high.
34A to 34D are views showing the manufacturing process of the fifth embodiment. Note that the manufacturing process of the fifth embodiment can be applied to the first to fourth embodiments.
As shown in FIG. 34A, after the electrode pads 212 and 213 are formed, half dicing is performed from the semiconductor substrate 400 side. At this time, the cut depth is set to a depth that sufficiently reaches the structure main body 310 (FIG. 34B).
Next, the support frame portion 313 is cut from the front side by half dicing (FIG. 34C), and element isolation is naturally performed (FIG. 34D). Here, in the half dicing, it is preferable to cut to a thickness that does not change the diaphragm performance.
As described above, simultaneously with the element separation, the force transmission part 311 can be made higher than the support frame part 313, the sensitivity of the shear force can be increased, and the shear force can be detected effectively.

  Note that the present invention is not limited to the above-described embodiment, and can be changed as appropriate without departing from the spirit of the present invention.

In the above, the diaphragm structure composed of the convex force transmission part 311 and the thin part 312 facilitates the application of force to the structure main body 310, accurately deforms the structure main body 310, and is formed inside. The structure which detects force as a capacitance change of the electrostatic capacitance part which consists of 1 sensor electrode 320 and 2nd sensor electrode 330 was illustrated.
Pressure is applied to the diaphragm structure composed of the convex force transmission part 311 and the thin part 312 to cause deformation of the structure main body part 310, and the electrostatic force composed of the first sensor electrode 320 and the second sensor electrode 330 formed inside. You may use as an apparatus which detects a pressure as a capacity | capacitance change of a capacity | capacitance part.
Since there is a convex part in the center of the diaphragm, the deformation of the diaphragm is not concentrated in the center. Thereby, a diaphragm deform | transforms comparatively equally and a big pressure change can be detected accurately.

External heat, that is, the movement of heat due to the temperature difference is transmitted to the diaphragm shape composed of the convex heat transfer portion and the thin portion 312, and the shape change due to the thermal expansion of the structure main body portion 310 occurs, and the first formed inside It can be configured as a device that detects a change in heat or temperature as a change in the capacitance of the electrostatic capacitance portion composed of the first sensor electrode 320 and the second sensor electrode 320.
Here, although it has been described as a change in capacitance due to heat, a change in resistance due to temperature and a change in temperature characteristics of the pn junction may be detected by an electrode inside the sensor and a signal processing circuit.

Here, FIG. 30 is a diagram that most simply represents the configuration of the present invention.
As shown in FIG. 30, the sensor structure having the sensor electrode and the semiconductor substrate are joined by an adhesive layer, and the external terminal of the sensor electrode and the integrated circuit is drawn out to the back surface of the semiconductor substrate via the side surface of the semiconductor substrate. Yes.
The sensor structure only needs to be able to detect a physical quantity such as pressure or heat transmitted to the contact sensing surface on the surface with an internal sensor electrode.
In this case, it is needless to say that the contact sensing surface does not have to be a diaphragm type.

  Of course, materials such as the adhesive layer 500 and the protective film 250 may be appropriately changed.

  10 ... Robot, 11 ... Hand, 100 ... Tactile sensor system, 110 ... Bus, 112 ... Power line, 113 ... Signal line, 120 ... Information relay device, 130 ... Concentrator, 140 ... Information integration device, 200 ... Sensor device, 211: Inclined surface, 212, 213 ... Drawer wiring, 220 ... Side end surface, 221 ... Inclined surface, 230, 231, 232, 233, 234 ... Drawer wiring, 240 ... Back surface, 241, 242, 243, 244 ... External terminal, 250 ... Protective film, 251 ... Hole, 252 ... Groove, 254 ... Square, 255 ... Underlying insulating film, 300 ... Sensor structure, 310 ... Structure main body, 311 ... Force transmission part, 312 ... Thin part, 313 ... Support frame 314 ... recess, 315 ... wafer, 316 ... side, 317 ... mask, 317 ... groove, 320 ... sensor electrode, 330 ... sensor electrode, 400 ... semiconductor substrate, 410 ... redistribution layer, 420 ... integrated circuit, 421 ... Electrode pad, 430 ... passivation film, 500 ... adhesive layer, 510 ... via, 520 ... resist, 600 ... glass substrate, 700 ... LTCC substrate, 710 ... wiring layer, 720 ... via.

Claims (22)

In addition to having a contact sensing surface that directly contacts the detection target on one surface exposed to the outside, a sensor electrode that outputs an analog sensor signal in response to a change in the contact sensing surface is opposite to the contact sensing surface A sensor structure on the surface side;
A semiconductor substrate on which an integrated circuit for signal processing for processing the analog sensor signal is formed;
An adhesive layer disposed between the other surface of the sensor structure portion and the semiconductor substrate, and bonding the sensor structure and the semiconductor substrate;
A sensor device in which the sensor structure and the semiconductor substrate are laminated to form a one-chip with the sensor electrode and the integrated circuit facing each other with the adhesive layer in between,
The sensor electrode and the integrated circuit are sealed inside a sensor device,
At least one of the external terminals of the sensor electrode and the signal processing integrated circuit is connected to a wiring lead-out portion of the sensor electrode formed on the back surface of the semiconductor substrate by way of a side slope of the semiconductor substrate and wiring. A sensor device, wherein the sensor device is pulled out to at least one of electrode extraction portions of the integrated circuit. The sensor device according to claim 1,
The adhesive layer is BCB (benzocyclobutene, benzocyclobutene). The sensor device according to claim 1 or 2,
External terminals of the sensor electrode and the signal processing integrated circuit are drawn out to the back surface of the semiconductor substrate via the side surface of the semiconductor substrate,
The sensor device is characterized in that the notch for taking out the wiring of the sensor electrode has a greater depth of cut than the notch for taking out the electrode of the integrated circuit. The sensor device according to claim 3,
In the back surface of the semiconductor substrate, the direction of taking out the wiring of the sensor electrode and the direction of taking out the electrode of the integrated circuit are orthogonal to each other. The sensor device according to any one of claims 1 to 4,
One sensor electrode provided on the back surface of the sensor structure,
The other sensor electrode provided on the adhesive layer,
The sensor device, wherein the sensor structure and the semiconductor substrate are bonded together by the adhesive layer in a state where two sensor electrodes face each other. The sensor device according to claim 5,
Vias are provided in the adhesive layer,
The other sensor electrode is connected to the electrode of the integrated circuit through the via. The sensor device according to any one of claims 1 to 6,
One sensor electrode provided on the back surface of the sensor structure,
The other sensor electrode provided on one surface of the glass substrate,
The sensor structure portion and the glass substrate are bonded in a state where two sensor electrodes face each other,
The sensor device, wherein the glass substrate and the semiconductor substrate are bonded by an adhesive layer provided on the other surface of the glass substrate. The sensor device according to claim 7,
A sensor device comprising a ceramic substrate instead of the glass substrate. The sensor device according to any one of claims 1 to 8,
The sensor electrode wiring extraction portion and the integrated circuit electrode extraction portion are formed in holes formed discontinuously on the side surface of the semiconductor substrate or on the side surface of the semiconductor substrate when the semiconductor substrate is viewed from the back surface. A sensor device characterized in that the sensor device is provided in a hollow. The sensor device according to any one of claims 1 to 9,
The sensor device is characterized in that the connection between the sensor electrode and the integrated circuit is made by a lead-out wiring or an external terminal on the side end surface of the semiconductor substrate. The sensor device according to any one of claims 1 to 10,
As a means for reducing parasitic capacitance between the sensor electrode and the integrated circuit, the thickness of the adhesive layer is 10 μm or more. The sensor device according to any one of claims 1 to 11,
The contact sensing surface is in contact with a detection target and transmits contact pressure or heat to the sensor electrode,
The sensor structure unit detects force, contact force, contact pressure, or heat. A sensor electrode is provided on the back surface of the wafer to be the sensor structure,
Create a semiconductor substrate incorporating an integrated circuit for signal processing,
Bonding the sensor structure and the semiconductor substrate with an adhesive layer in a state where the sensor electrode and the integrated circuit face each other,
Etching the back surface of the semiconductor substrate, and further exposing the wiring extraction portion of the sensor electrode and the electrode extraction portion of the integrated circuit to the back side of the semiconductor substrate by half dicing from the back surface of the semiconductor substrate,
A lead wiring is provided from the slope of the semiconductor substrate formed by the etching and the half dicing to the back surface of the semiconductor substrate,
A method of manufacturing a sensor device, wherein the external terminals of the sensor electrode and the signal processing integrated circuit are drawn out to a back surface of the semiconductor substrate through a side surface of the semiconductor substrate. In the manufacturing method of the sensor apparatus according to claim 13,
The etching is alkali wet etching,
A method of manufacturing a sensor device, comprising using a low-temperature oxide film overlaid with a photosensitive resistant alkali organic protective film as an etching mask. In the manufacturing method of the sensor apparatus according to claim 13 or 14,
For the adhesive layer, BCB (benzocyclobutene, benzocyclobutene) is used,
A method for manufacturing a sensor device, comprising: applying BCB, performing pre-cure at 220 ° C., and performing bonding at 250 ° C. In the manufacturing method of the sensor apparatus according to any one of claims 13 to 15,
In the half dicing,
The method for manufacturing a sensor device, wherein the half dicing for extracting the wiring of the sensor electrode has a greater depth of cut than the half dicing for extracting the electrode of the integrated circuit. A method of manufacturing a sensor device according to any one of claims 13 to 16,
The sensor device has two sensor electrodes,
One of the sensor electrodes is provided on the back surface of the sensor structure,
Providing an adhesive layer on the semiconductor substrate;
Provide the other of the sensor electrodes on the adhesive layer,
A sensor device manufacturing method, wherein the sensor structure and the semiconductor substrate are joined by the adhesive layer so that two sensor electrodes face each other. In the manufacturing method of the sensor apparatus according to claim 17,
After providing an adhesive layer on the semiconductor substrate, patterning vias in the adhesive layer,
The other of the sensor electrodes is connected to the electrode of the integrated circuit through a via provided in an adhesive layer. A method of manufacturing a sensor device according to any one of claims 13 to 16,
The sensor device has two sensor electrodes,
One of the sensor electrodes is provided on the back surface of the sensor structure,
The other side of the sensor electrode is provided on one surface of the glass substrate,
Bonding the sensor structure and the glass substrate so that the two sensor electrodes face each other,
An adhesive layer is formed on the other surface of the glass substrate to bond the glass substrate and the semiconductor substrate. In the manufacturing method of the sensor apparatus according to claim 19,
A method of manufacturing a sensor device, wherein a ceramic substrate is used instead of the glass substrate. A sensor electrode is provided on the back surface of the wafer to be the sensor structure,
Create a semiconductor substrate incorporating an integrated circuit for signal processing,
Bonding the sensor structure and the semiconductor substrate with an adhesive layer in a state where the sensor electrode and the integrated circuit face each other,
Etching the back surface of the semiconductor substrate, forming an insulating film on the back surface, and etching the insulating film so that the wiring extraction portion of the sensor electrode and the electrode extraction portion of the integrated circuit are on the back surface side of the semiconductor substrate. To expose
A lead wiring is provided from the slope of the semiconductor substrate formed by the etching to the back surface of the semiconductor substrate,
A method of manufacturing a sensor device, wherein the external terminals of the sensor electrode and the signal processing integrated circuit are drawn out to a back surface of the semiconductor substrate through a side surface of the semiconductor substrate. In the manufacturing method of the sensor apparatus according to any one of claims 13 to 21,
Half-dicing is performed from the sensor structure part side, and the support frame part outside the force transmission part is cut lower than the force transmission part of the sensor structure part that comes into contact with the object, and element separation is performed. A method for manufacturing a sensor device.

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