JP7061784B2 - Tactile sensors, tactile measuring devices, trained models, and identification devices - Google Patents

Description

The present invention relates to a tactile sensor, a tactile measuring device, a trained model, and an identification device. More specifically, the present invention relates to a tactile sensor and a tactile measuring device for the purpose of quantifying the tactile sensation felt by humans. The present invention also relates to a trained model and an identification device for identifying the type of an object to be measured.

Various tactile sensors have been developed that imitate human tactile sensations in engineering. Above all, the tactile sensor formed by the semiconductor micromachining technology has the advantage that many sensor signals can be read out with a small number of wirings, so that a large number of sensor units can be arranged at high density and the position resolution is high. ..

Patent Document 1 discloses a tactile sensor having a contact whose tip is minute. By sliding the tactile sensor while pressing it against the object to be measured and detecting the displacement of the contactor, it is possible to detect minute irregularities on the surface of the object to be measured and frictional force in a minute area.

International Publication No. 2015/133113

The shape and properties of the surface of the object to be measured may change depending on whether the object to be measured is patted strongly or weakly, and the feeling of touch may change. Therefore, in evaluating the feel of the object to be measured, the force of pressing the tactile sensor against the object to be measured may be an important factor.

Further, it is required to identify the type of the object to be measured based on the measurement data obtained by the tactile sensor.

In view of the above circumstances, it is an object of the present invention to provide a tactile sensor and a tactile measuring device capable of detecting minute characteristics of the surface of the object to be measured and detecting the pressing force of the tactile sensor against the object to be measured.
Another object of the present invention is to provide a trained model and an identification device capable of identifying the type of an object to be measured.

The tactile sensor of the first invention comprises a large contact having a contact surface in contact with a base and an object to be measured, and a small contact having a contact end having a contact area with the object to be measured smaller than the contact surface. A large contact support that supports the large contact with respect to the base so as to be displaceable at least in a direction perpendicular to the contact surface, and a large contact displacement that detects the displacement of the large contact with respect to the base. A detector, a small contact support that supports the small contact in a displaceable manner with respect to the large contact, and a small contact displacement detector that detects the displacement of the small contact with respect to the large contact. It is characterized by being provided with.
In the first invention, the tactile sensor of the second invention is such that the large contact has a main body portion, a traversing portion including a part or all of the contact surface, and the traversing portion touches the main body portion. It is characterized by including a traversing portion support that supports displaceably in a direction parallel to a surface, and a traversing portion displacement detector that detects displacement of the traversing portion with respect to the main body portion.
In the first invention, the tactile sensor of the third invention has the main body portion, a plurality of traversing portions including a part of the contact surface, and the plurality of traversing portions with respect to the main body portion. A plurality of traversing portion supports that support displaceably in a direction parallel to the contact surface, and a plurality of traversing portion displacement detectors that detect displacement of the plurality of traversing portions with respect to the main body portion. The traversing portion is characterized in that the areas of the contact surfaces are different from each other.
The tactile sensor of the fourth invention is characterized in that, in the first invention, the large contact support supports the large contact with respect to the base so as to be displaceable in a direction parallel to the contact surface. do.
In the first, second, third or fourth aspect of the invention, the tactile sensor of the fifth invention has the large contact surface in the shape of a flat plate having a part of the side surface forming the contact surface, and has two contact surfaces. It has an internal space with an opening to divide, the small contact is arranged in the internal space, and a protective plate is provided on one or both of the front and back surfaces of the large contact, and the protective plate is provided. Is characterized in that it covers the opening of the internal space and a part of the side surface or the side edge is arranged on the extension surface of the contact surface.
The tactile measuring device of the sixth invention is a tactile measuring device provided with the tactile sensor of the first, second, third, fourth or fifth invention, and operates the tactile sensor and / or the measuring object. , A pusher that presses the tactile sensor against the object to be measured, and a scanner that operates the tactile sensor and / or the object to be measured and slides the tactile sensor along the surface of the object to be measured. , Is characterized by the provision of.
In the sixth invention, the tactile measuring device of the seventh invention inputs the pressing force detected by the large contact displacement detector of the tactile sensor, and the pressing force becomes a predetermined value. It is characterized by being provided with a control device for controlling the operation of the device.
The trained model of the eighth invention is measurement data constituting one or more waveforms of unevenness amount, minute region friction force, average friction force, and pressing force with respect to the surface position of the object to be measured, or the measurement thereof. It is a trained model for making a computer function to specify the type of the measurement object based on the tactile data which is the processed data obtained by subjecting the data to a predetermined process, and the measurement object is used. Using the learning data including the tactile data obtained by measurement, a learning device to which machine learning has been performed in advance is configured, and the tactile data obtained by measuring the measurement object is input to the learning device. Then, the computer is made to function so as to output the type information of the measurement object.
The trained model of the ninth invention is characterized in that, in the eighth invention, the processed data is a graph image obtained by graphing the measurement data.
The trained model of the tenth invention is characterized in that, in the eighth invention, the processed data is a displacement image in which the displacement of the waveform composed of the measurement data is represented by the color of the pixel.
The trained model of the eleventh invention is characterized in that, in the eighth invention, the processed data is signal processing data obtained by subjecting the measured data to signal processing.
The trained model of the twelfth invention is characterized in that, in the eighth invention, the processed data is a graph image obtained by graphing the signal processing data obtained by subjecting the measurement data to signal processing.
In the eighth invention, the trained model of the thirteenth invention is a displacement image in which the post-processing data represents the displacement of the waveform composed of the signal processing data obtained by applying signal processing to the measurement data as the pixel color. It is characterized by being.
The identification device of the fourteenth invention comprises a computer in which the trained models of the eighth, ninth, tenth, eleventh, twelfth or thirteenth inventions are installed.

According to the first invention, by detecting the displacement of a small contact having a contact end having a small contact area, it is possible to detect fine characteristics of the surface of the object to be measured. Further, by detecting the displacement in the pushing direction of the large contact having a contact surface having a large contact area, it is possible to detect the pushing force of the tactile sensor against the object to be measured.
According to the second invention, the average frictional force of the object to be measured can be detected by detecting the displacement of the transverse portion in the lateral displacement direction.
According to the third invention, since a plurality of traversing portions having different contact areas are provided, the average frictional force in various measurement ranges can be detected.
According to the fourth invention, the average frictional force of the object to be measured can be detected by detecting the displacement of the large contactor in the lateral displacement direction.
According to the fifth invention, even when measuring an object to be measured composed of fibers, the protective plate can prevent the fibers from entering the inside of the opening of the large contact, and the fibers are caught by the small contacts. Can be prevented. As a result, it is possible to detect fine characteristics of the object to be measured made of fibers.
According to the sixth invention, the tactile sensation of the object to be measured can be measured by sliding the tactile sensor while pressing it against the object to be measured.
According to the seventh invention, since the pressing force of the tactile sensor against the object to be measured can be made constant, the feeling of touch of the object to be measured can be accurately measured.
According to the eighth to fourteenth inventions, the type of the object to be measured can be identified.

It is a top view of the tactile sensor which concerns on 1st Embodiment of this invention. (A) is an explanatory diagram of a strain detecting element when there is no strain on the beam, and (B) is an explanatory diagram of a strain detecting element when there is no strain on the beam. It is a circuit diagram of a distortion detection circuit. It is explanatory drawing of the detection method using a tactile sensor. It is a graph exemplifying various signals obtained from a tactile sensor. It is a top view of the tactile sensor which concerns on 2nd Embodiment of this invention. It is a top view of the tactile sensor which concerns on 3rd Embodiment of this invention. It is a top view of the tactile sensor which concerns on 4th Embodiment of this invention. It is a top view of the tactile sensor which concerns on 5th Embodiment of this invention. It is a top view of the tactile sensor which concerns on 6th Embodiment of this invention. It is a vertical sectional view of the tactile sensor of FIG. It is a top view of the tactile measuring apparatus which concerns on one Embodiment of this invention. It is a top view of the identification apparatus which concerns on one Embodiment of this invention. It is a top view of the tactile sensor used in the test. (A) The figure shows the time change of the signal obtained when the pressing force of the tactile sensor against the milled fabric is weakened. (B) The figure shows the time change of the signal obtained when the pressing force of the tactile sensor against the milled fabric is set to the middle level. (C) The figure shows the time change of the signal obtained when the pressing force of the tactile sensor against the milled fabric is increased. (A) The figure shows the time change of the signal obtained when the pressing force of the tactile sensor against the piqué fabric is weakened. (B) The figure shows the time change of the signal obtained when the pressing force of the tactile sensor against the piqué fabric is set to the middle level. (C) The figure shows the time change of the signal obtained when the pressing force of the tactile sensor against the piqué fabric is increased. (A) The figure shows the time change of the signal during the period when the tactile sensor is scanned in the direction of the tip of the hair. (B) The figure shows the time change of the signal during the period when the tactile sensor is scanned in the fundamental direction. This is an example of a graph image. This is an example of a displacement image.

Next, an embodiment of the present invention will be described with reference to the drawings.
[First Embodiment]
(Construction)
As shown in FIG. 1, the tactile sensor 1 according to the first embodiment of the present invention is formed by processing a semiconductor substrate such as an SOI substrate by a semiconductor micromachining technique. The overall dimensions of the tactile sensor 1 are not particularly limited, but are several mm square to several tens of mm square.

The tactile sensor 1 has a base 10, a large contactor 20, and a small contactor 30. A large contact support 40 that supports the large contact 20 with respect to the base 10 is provided between the base 10 and the large contact 20. A small contact support 50 that supports the small contact 30 with respect to the large contact 20 is provided between the large contact 20 and the small contact 30. These components are formed by etching a semiconductor substrate with a predetermined pattern to remove unnecessary portions. Therefore, the base 10, the large contact 20 and the small contact 30 are all flat plates.

One side surface of the tactile sensor 1 is a sensing surface facing the object to be measured. In the present embodiment, the upper surface of the side surface of the tactile sensor 1 in FIG. 1 is used as the sensing surface.

The base 10 has a substantially U-shape with the sensing surface side open. The large contactor 20 is arranged in the internal space of the base 10. The large contact 20 protrudes from the base 10 toward the sensing surface. Of the side surfaces of the protruding portion of the large contactor 20, the surface that constitutes a part of the sensing surface and comes into contact with the object to be measured is referred to as a contact surface 21. In other words, a part of the side surface of the large contactor 20 forms the contact surface 21.

The contact surface 21 is a flat surface and has a certain contact area with the object to be measured. In the following, the direction perpendicular to the contact surface 21 (x direction in FIG. 1) is referred to as a “pushing direction”. Further, the direction parallel to the contact surface 21 (y direction in FIG. 1) is referred to as a "lateral displacement direction".

The large contact 20 has a circular arc-shaped corner portion located at the end of the contact surface 21. Therefore, when the contact surface 21 is brought into contact with the object to be measured and slid, it is possible to prevent the corner portion of the large contact 20 from being caught by the object to be measured. It is not necessary to form the corners of the large contactor 20 in an arc shape.

The large contact support 40 is composed of a plurality of cross beams 41. Each cross beam 41 is bridged between the base 10 and the large contactor 20. Each cross beam 41 has elasticity and has the same properties as a leaf spring. Further, each cross beam 41 is arranged in parallel with the contact surface 21. Therefore, the cross beam 41 allows the displacement of the large contact 20 with respect to the base 10 in the pushing direction x. In other words, the large contactor 20 is displaceably supported in the pushing direction x with respect to the base 10. The large contact 20 cannot be displaced in the lateral displacement direction y with respect to the base 10.

In the present embodiment, a total of 12 cross beams 41 are provided on both sides of the large contactor 20, but the number and dimensions thereof are not particularly limited. The number and dimensions of the cross beams 41 may be set so that the elasticity required for the large contact support 40 can be obtained.

The large contact 20 has an internal space having an opening on the sensing surface side. The contact surface 21 is divided into two by this internal space. The small contactor 30 and the small contactor support 50 are arranged in the internal space of the large contactor 20.

The small contactor 30 is a rod-shaped member, and its central axis is arranged perpendicular to the contact surface 21. Further, one tip of the small contactor 30 is inserted into the opening on the sensing surface side of the large contactor 20. A contact end 31 is provided at the tip portion. The contact end 31 forms a part of the sensing surface and comes into contact with the object to be measured.

The shape of the contact end 31 is not particularly limited, but may be semi-circular or fan-shaped. The contact area of the contact end 31 with the measurement object is set to be smaller than the contact area of the contact surface 21 with the measurement object.

The contact end 31 may be arranged in an extended surface of the contact surface 21, or may be arranged so as to project outward from the contact surface 21. Further, when the object to be measured is soft and a part of the object to be measured bites between the two contact surfaces 21 and 21, the contact end 31 may be arranged so as to be retracted inward from the contact surface 21.

The small contact support 50 includes a plurality of cross beams 51, a plurality of vertical beams 52, and two island portions 53. In the internal space of the large contactor 20, two island portions 53 are arranged at positions sandwiching the small contactor 30. Each cross beam 51 is bridged between the small contactor 30 and the island portion 53. Each vertical beam 52 is bridged between the island portion 53 and the large contactor 20.

Each cross beam 51 has elasticity and has the same properties as a leaf spring. Further, each cross beam 51 is arranged in parallel with the contact surface 21. Therefore, the cross beam 51 allows the displacement of the small contact 30 with respect to the large contact 20 in the pushing direction x. Each vertical beam 52 has elasticity and has the same properties as a leaf spring. Further, each vertical beam 52 is arranged perpendicular to the contact surface 21. Therefore, the vertical beam 52 allows the displacement of the small contact 30 with respect to the large contact 20 in the lateral displacement direction y. That is, the small contactor 30 is displaceably supported in the pushing direction x and the lateral displacement direction y with respect to the large contactor 20.

In the present embodiment, a total of eight cross beams 51 are provided on both sides of the small contactor 30, but the number and dimensions thereof are not particularly limited. Further, the vertical beams 52 are provided on both sides of each island portion 53, for a total of eight beams, but the number and dimensions thereof are not particularly limited. The number and dimensions of the cross beams 51 and the vertical beams 52 may be set so that the elasticity required for the small contact support 50 can be obtained.

The large contact 20 has a main body portion 22, a traversing portion 23, and a traversing portion support body 24 that supports the traversing portion 23 with respect to the main body portion 22. The traversing portion 23 is a part of the large contactor 20 on the sensing surface side, and includes a part of the contact surface 21. The traversing portion 23 of the present embodiment includes one of the contact surfaces 21 divided into two. The main body portion 22 is a portion other than the traversing portion 23 and the traversing portion support 24 of the large contact 20.

The transverse portion support 24 is composed of a plurality of vertical beams 25. Each vertical beam 25 is bridged between the traverse portion 23 and the main body portion 22. Each vertical beam 25 has elasticity and has the same properties as a leaf spring. Further, each vertical beam 25 is arranged perpendicular to the contact surface 21. Therefore, the vertical beam 25 allows the displacement of the transverse portion 23 with respect to the main body portion 22 in the lateral displacement direction y. In other words, the traversing portion 23 is supported so as to be displaceable in the lateral slip direction y with respect to the main body portion 22. The traversing portion 23 cannot be displaced with respect to the main body portion 22 in the pushing direction x.

When the sensing surface of the tactile sensor 1 is pressed against the object to be measured, the large contactor 20 is displaced in the pushing direction x. In order to detect such a displacement of the large contactor 20, the tactile sensor 1 is provided with a large contactor displacement detector 60.

The large contact displacement detector 60 includes first and second strain detecting elements 63 and 64 that detect the strain of the cross beam 41. The first and second strain detecting elements 63 and 64 are piezo resistance elements, and are formed on the surface of the cross beam 41 by an integrated circuit manufacturing process such as impurity diffusion or ion implantation or a metal wiring forming technique.

As shown in FIG. 2A, a first strain detection element 63 is formed on the surface of one of the plurality of cross beams 41, and a second strain detection element 63 is formed on the surface of the other cross beam 41. The element 64 is formed. The first and second strain detecting elements 63 and 64 are formed in a stepped shape, respectively, and have a shape along one side portion from one end to the center of the cross beam 41 and along the other side portion from the center to the other end. have. Further, the first strain detecting element 63 formed on one cross beam 41 and the second strain detecting element 64 formed on the other cross beam 41 each have a shape that is axisymmetric.

As shown in FIG. 2B, when strain occurs in the cross beam 41, one of the first strain detecting elements 63 has a small resistance due to compressive stress, and the other second strain detecting element 64 has a large resistance due to tensile stress. Become.

As shown in FIG. 3, on the surface of the tactile sensor 1, first and second strain detection elements 63 and 64 are connected in series and a voltage Vdd is applied to both ends to detect the first strain detection element 63 and the second strain. A circuit (not shown in FIGS. 1 and 2) for reading the voltage Vout between the element 64 and the element 64 is formed. Since the voltage Vout changes depending on the differential of the first and second strain detecting elements 63 and 64, the strain amount of the cross beam 41 can be detected by reading the voltage Vout. As a result, the large contactor displacement detector 60 can detect the displacement of the large contactor 20 with respect to the base 10 in the pushing direction x.

When the sensing surface of the tactile sensor 1 is slid while being pressed against the object to be measured, the small contactor 30 is displaced in the pushing direction x and in the lateral displacement direction y. In order to detect such a displacement of the small contactor 30, the tactile sensor 1 is provided with a small contactor displacement detector 70.

As shown in FIG. 1, the small contact displacement detector 70 has a push displacement detector 71 that detects the displacement of the small contact 30 in the push direction x and a lateral displacement that detects the displacement of the small contact 30 in the lateral slip direction y. It has a displacement detector 72. The indentation displacement detector 71 includes first and second strain detection elements 73 and 74 that detect the strain of the cross beam 51. The lateral displacement detector 72 includes first and second strain detecting elements 75 and 76 that detect the strain of the vertical beam 52.

The configuration of the first and second strain detection elements 73 and 74 of the indentation displacement detector 71 and the strain detection circuit are the configuration of the first and second strain detection elements 63 and 64 of the large contact displacement detector 60 and the strain detection circuit. Is similar to. The configuration of the first and second strain detection elements 75 and 76 of the lateral displacement detector 72 and the strain detection circuit are the configuration of the first and second strain detection elements 63 and 64 of the large contactor displacement detector 60 and the strain detection circuit. Is similar to. The small contact displacement detector 70 can detect the displacement of the small contact 30 with respect to the large contact 20 in the pushing direction x and the lateral displacement direction y.

When the sensing surface of the tactile sensor 1 is slid while being pressed against the object to be measured, the transverse portion 23 is displaced in the lateral displacement direction y. In order to detect such a displacement of the traversing portion 23, the tactile sensor 1 is provided with a traversing portion displacement detector 81.

The transverse portion displacement detector 81 includes first and second strain detecting elements 83 and 84 that detect the strain of the vertical beam 25. The configuration of the first and second strain detection elements 83 and 84 of the transverse portion displacement detector 81 and the strain detection circuit include the configuration and strain detection of the first and second strain detection elements 63 and 64 of the large contactor displacement detector 60. Similar to the circuit. The transverse portion displacement detector 81 can detect the displacement of the transverse portion 23 with respect to the main body portion 22 in the lateral displacement direction y.

(Production method)
Next, a method of manufacturing the tactile sensor 1 using the SOI substrate will be described.
Here, the SOI substrate has a three-layer structure of a support substrate (silicon), an oxide film layer (silicon dioxide), and an active layer (silicon), and the thickness thereof is, for example, 300 μm.

First, the substrate is washed and oxidized to form a surface oxide film. Next, the surface oxide film is processed to form a diffusion layer pattern as a circuit portion, and phosphorus is diffused. Next, the chromium thin film is sputtered on the back surface of the substrate, and the chromium thin film is processed into a pattern that releases the movable structure (large contact 20, small contact 30, large contact support 40, and small contact support 50). do. Next, the surface oxide film is removed and etched by ICP-RIE to form a movable structure portion. After filling the periphery of the formed movable structure portion with a resist to protect it, the back surface is etched by ICP-RIE. Finally, the intermediate oxide film and resist are removed to release the movable structure.

(Detection method)
Next, a detection method using the tactile sensor 1 will be described.
As shown in FIG. 4, the sensing surface of the tactile sensor 1 is pressed against the surface of the measurement object O, and the contact surface 21 is brought into contact with the measurement object O. Then, the contact surface 21 is arranged on a plane connecting the peaks of the unevenness on the surface of the object O to be measured. Then, the large contactor 20 is pushed in by the reaction force of the pressing force of the tactile sensor 1 and is displaced in the pushing direction x.

While the sensing surface of the tactile sensor 1 is pressed against the surface of the object to be measured O, the sensor is moved along the surface of the object to be measured O. Then, the small contactor 30 is displaced in the pushing direction x along the unevenness of the surface of the object O to be measured. Further, the small contactor 30 is displaced in the lateral displacement direction y due to the frictional force acting between the contact end 31 and the object O to be measured. Further, the traversing portion 23 is displaced in the lateral slip direction y due to the frictional force acting between the traversing portion 23 and the object to be measured O.

FIG. 5 shows an example of various signals obtained from the tactile sensor 1 by the above detection operation.
In the graph of (1), the horizontal axis is time, and the vertical axis is the displacement of the large contactor 20 detected by the large contactor displacement detector 60 in the pushing direction x. The displacement of the large contact 20 in the pushing direction x means the pushing force of the tactile sensor 1 against the object O to be measured. When the tactile sensor 1 is pleated along the surface of the object O to be measured at a constant speed, the horizontal axis is synonymous with the position coordinates of the surface of the object O to be measured.

In the example shown in FIG. 5, the pressing force is constant over the entire measurement time (all position coordinates). Such a signal can be obtained by performing the detection operation while keeping the pressing force of the tactile sensor 1 against the object O to be measured constant.

In the graph of (2), the horizontal axis is time, and the vertical axis is the displacement of the small contactor 30 detected by the indentation displacement detector 71 in the indentation direction x. The displacement of the small contactor 30 in the pushing direction x means the amount of unevenness on the surface of the object O to be measured. Therefore, the graph in (2) reproduces the surface shape (spatial waveform) of the surface of the object O to be measured.

Here, the small contactor 30 is displaced by following the unevenness of the wavelength band similar to the size of the contact end 31. When the contact end 31 is semi-circular or fan-shaped, the small contactor 30 is displaced following irregularities in a wavelength band similar to the radius of the contact end 31. That is, the smaller the radius of the contact end 31, the smaller the unevenness of the wavelength can be followed, and the finer unevenness on the surface of the object O to be measured can be detected. Further, the larger the radius of the contact end 31, the smaller the unevenness is not followed, and the large unevenness (waviness) having a large wavelength can be detected by removing the fine unevenness on the surface of the object O to be measured. In this way, the surface shape of the object O to be measured can be measured by selecting the wavelength band (frequency band) according to the radius of the contact end 31.

Further, if the contact end 31 is semi-circular or fan-shaped, even if the tactile sensor 1 is slid while being pressed against the measurement object O, the small contactor 30 operates smoothly without being caught by the measurement object O. Therefore, the small contactor 30 is displaced following the unevenness of the surface of the object to be measured, and the surface shape of the object O to be measured can be measured with high accuracy.

In the graph of (3), the horizontal axis is time, and the vertical axis is the displacement of the small contactor 30 detected by the lateral displacement displacement detector 72 in the lateral displacement direction y. The displacement of the small contactor 30 in the lateral displacement direction y means the frictional force acting between the contact end 31 and the object O to be measured. Here, since the contact area of the contact end 31 with the object O to be measured is small, the displacement of the small contactor 30 in the lateral displacement direction y means the frictional force in a minute region.

The dynamic friction coefficient μ of the minute region on the surface of the object O to be measured can be obtained from the displacements of the small contactor 30 in the pushing direction x and the lateral displacement direction y. Since the elastic modulus of the cross beam 51 is known, the reaction force fx applied to the small contactor 30 can be calculated from the displacement of the small contactor 30 in the pushing direction x. Further, since the elastic modulus of the vertical beam 52 is known, the frictional force fy applied to the small contactor 30 can be calculated from the displacement of the small contactor 30 in the lateral displacement direction y. From the calculated reaction force fx and friction force fy, the dynamic friction coefficient μ of the minute region on the surface of the object to be measured O can be calculated according to the following mathematical formula 1.
μ = fx / fy ・ ・ ・ (1)

In the graph of (4), the horizontal axis is time, and the vertical axis is the displacement of the transverse portion 23 detected by the transverse portion displacement detector 81 in the lateral displacement direction y. The displacement of the traversing portion 23 in the lateral displacement direction y means the frictional force acting between the traversing portion 23 and the object O to be measured. Here, since the contact area of the traversing portion 23 with the measurement object O is large, the displacement of the traversing portion 23 in the lateral displacement direction y means an average frictional force that does not depend on the unevenness of the surface of the measuring object O.

The average dynamic friction coefficient <μ> of the surface of the object O to be measured can be obtained from the displacement of the large contactor 20 in the pushing direction x and the displacement of the transverse portion 23 in the lateral displacement direction y. Since the elastic modulus of the cross beam 41 is known, the reaction force Fx applied to the transverse portion 23 can be calculated from the displacement of the large contactor 20 in the pushing direction x. Further, since the elastic modulus of the vertical beam 25 is known, the frictional force Fy applied to the transverse portion 23 can be calculated from the displacement of the transverse portion 23 in the lateral displacement direction y. From the calculated reaction force Fx and friction force Fy, the average dynamic friction coefficient <μ> on the surface of the object to be measured O can be calculated according to the following mathematical formula 2.
<μ> = Fx / Fy ・ ・ ・ (2)

As described above, by detecting the displacement of the small contactor 30 having the contact end 31 having a small contact area in the pushing direction x and the lateral displacement direction y, the fine characteristics (surface shape, minute region) of the surface of the object O to be measured are detected. Friction force) can be detected. Further, by detecting the displacement of the large contactor 20 having the contact surface 21 having a large contact area in the pushing direction x, the pressing force of the tactile sensor 1 against the object O to be measured can be detected. Further, by detecting the displacement of the traversing portion 23 in the lateral displacement direction y, the average frictional force of the object O to be measured can be detected.

The shape and properties of the surface of the object to be measured O may change depending on whether the object O to be measured is strongly stroked or weakly stroked, and the feeling of touch may change. Since the tactile sensor 1 can detect the pressing force of the tactile sensor 1 against the measurement object O, the measurement condition (pressing force) can be quantified, and the touch when the measurement object O is strongly stroked and weakly stroked. You can ask for the difference in feeling.

Further, if the detection operation is performed while keeping the pressing force of the tactile sensor 1 against the object O to be measured constant, the signal does not change depending on the change in the pressing force. Therefore, the characteristics of the object O to be measured can be detected with high accuracy.

When the object O to be measured is paper, cloth, or the like, the distance between the fibers is generally 10 to 100 μm. In order to make the movement of the large contact 20 less likely to be affected by the fiber structure, the width of the contact surface 21 may be larger than the fiber spacing, and is preferably about 1 mm or more.

The maximum width of the large contact 20 depends on the width dimension of the tactile sensor 1. For example, if the width dimension of the tactile sensor 1 is 5 mm, the width of the large contactor 20 is about 5 mm at the maximum. A plurality of large contacts 20 may be provided on one tactile sensor 1. In this case, the width of the large contactor 20 may be set so as to fit in the tactile sensor 1. For example, when two large contacts 20 of the same size are provided in one tactile sensor 1, the width dimension of the large contactor 20 is 1/2 (for example, 2.) of the width dimension (for example, 5 mm) of the tactile sensor 1. 5 mm) or less.

By the way, as cells that contribute to human tactile sensation, Meissner corpuscle, Mercel corpuscle, and Rufini terminal are known. The Meissner corpuscle quickly adapts to pressure and responds well to vibrations and the like. The Mercel tactile adapts slowly to pressure and responds well to persistent skin pressure. The Rufini terminal adapts slowly to pressure and responds to persistent skin deformities and the like. From a functional point of view, the tactile sensor 1 of the present embodiment has a small contact 30 that detects minute characteristics of the surface of the object O to be measured corresponds to a Meissner corpuscle, and a large contact 20 that detects a pressing force is Merkel. The traversing portion 23 corresponding to the tactile panel and detecting the average frictional force corresponds to the end of Rufini. As described above, since the tactile sensor 1 has a function similar to that of cells contributing to human tactile sensation, it is considered that detection close to human tactile sensation can be performed.

From the viewpoint of detecting a human tactile sensation, the contact end 31 preferably has the same shape and dimensions as the cross section of the ridge line constituting the fingerprint. Specifically, it is preferable that the contact end 31 is semicircular and the diameter thereof is 10 to 500 μm. Further, the width dimension of the contact surface 21 is preferably about the same as the thickness of the finger, that is, 1 to 2 cm. If the diameter of the contact end 31 is 10 μm or less, the tactile sensation can be detected with a finer resolution than that of a human.

The object O to be measured is not particularly limited, but the tactile sensor 1 is suitable for measuring the characteristics of a soft object such as paper or cloth. In addition, since the pressing force can be controlled, it is also suitable for measuring the characteristics of things that do not want to be scratched, such as the body of a car.

[Second Embodiment]
Next, the tactile sensor 2 according to the second embodiment of the present invention will be described.
As shown in FIG. 6, the tactile sensor 2 of the present embodiment has a configuration in which the large contact 20 is provided with a plurality of traversing portions 23, 26 in the tactile sensor 1 of the first embodiment. Specifically, the large contact 20 has a main body portion 22, a first traversing portion 23, and a second traversing portion 26. The first and second traversing portions 23 and 26 each include a part of the contact surface 21. The first traversing portion 23 is formed on one of the contact surfaces 21 divided into two, and the second traversing portion 26 is formed on the other. Further, the area of the contact surface 21 of the first traversing portion 23 and the second traversing portion 26 is different from each other. Specifically, the area of the contact surface 21 of the second traversing portion 26 is set to be larger than the area of the contact surface 21 of the first traversing portion 23.

A first traversing portion support 24 that supports the first traversing portion 23 with respect to the main body portion 22 is provided between the first traversing portion 23 and the main body portion 22. The first traversing portion support 24 is composed of a plurality of vertical beams 25. The first traversing portion 23 is supported by the first traversing portion support 24 so as to be displaceable in the lateral displacement direction y with respect to the main body portion 22.

The first traversing portion support 24 is provided with a first traversing portion displacement detector 81 for detecting the displacement of the first traversing portion 23 with respect to the main body portion 22 in the lateral displacement direction y. The first transverse portion displacement detector 81 includes first and second strain detecting elements 83 and 84 that detect the strain of the vertical beam 25. The configuration of the first and second strain detection elements 83 and 84 of the first traverse portion displacement detector 81 and the strain detection circuit include the configuration of the first and second strain detection elements 63 and 64 of the large contactor displacement detector 60 and the configuration of the second strain detection elements 63 and 64. It is the same as the distortion detection circuit.

A second traversing portion support 27 that supports the second traversing portion 26 with respect to the main body portion 22 is provided between the second traversing portion 26 and the main body portion 22. The second traversing portion support 27 is composed of a plurality of vertical beams 28. The second traversing portion 26 is supported by the second traversing portion support 27 so as to be displaceable in the lateral displacement direction y with respect to the main body portion 22.

The second traversing portion support 27 is provided with a second traversing portion displacement detector 82 that detects the displacement of the second traversing portion 26 with respect to the main body portion 22 in the lateral displacement direction y. The second transverse portion displacement detector 82 includes first and second strain detecting elements 85 and 86 that detect the strain of the vertical beam 28. The configuration of the first and second strain detection elements 85 and 86 of the second traverse portion displacement detector 82 and the strain detection circuit include the configuration of the first and second strain detection elements 63 and 64 of the large contactor displacement detector 60 and the configuration of the second strain detection elements 63 and 64. It is the same as the distortion detection circuit.

As described above, the traversing portion 23 detects the average frictional force on the surface of the object O to be measured. Here, the average frictional force means the average frictional force in the area of the contact surface 21 included in the traverse portion 23. Therefore, the measurement range of the average frictional force depends on the contact area of the traversing portion 23. Specifically, the smaller the contact area of the traversing portion 23, the more the average frictional force in a minute region can be detected. The larger the contact area of the traversing portion 23, the more the average frictional force in a wide area can be detected.

Since the tactile sensor 2 of the present embodiment includes two traversing portions 23 and 26 having different contact areas, it is possible to detect the average frictional force in the two measurement ranges.

In the present embodiment, the number of the traversing portions 23 and 26 is two, but it may be three or more. In this case, a traverse portion support and a traverse portion displacement detector are provided for each traverse portion.

[Third Embodiment]
Next, the tactile sensor 3 according to the third embodiment of the present invention will be described.
As shown in FIG. 7, the tactile sensor 3 of the present embodiment has a configuration in which the large contactor 20 can be displaced in the lateral displacement direction y in the tactile sensor 1 of the first embodiment.

The large contact support 40 of the present embodiment includes a plurality of cross beams 41, a plurality of vertical beams 42, and two island portions 43. In the internal space of the base 10, two islands 43 are arranged at positions sandwiching the large contact 20. Each cross beam 41 is bridged between the large contact 20 and the island 43. Each vertical beam 42 is bridged between the island portion 43 and the base portion 10.

Each cross beam 41 has elasticity and has the same properties as a leaf spring. Further, each cross beam 41 is arranged in parallel with the contact surface 21. Therefore, the cross beam 41 allows the displacement of the large contact 20 with respect to the base 10 in the pushing direction x. Each vertical beam 42 has elasticity and has the same properties as a leaf spring. Further, each vertical beam 42 is arranged perpendicular to the contact surface 21. Therefore, the vertical beam 42 allows the displacement of the large contact 20 with respect to the base 10 in the lateral displacement direction y. That is, the large contactor 20 is displaceably supported in the pushing direction x and the lateral displacement direction y with respect to the base 10.

In the present embodiment, a total of eight cross beams 41 are provided on both sides of the large contactor 20, but the number and dimensions thereof are not particularly limited. Further, the vertical beams 42 are provided on both sides of each island portion 43, for a total of eight beams, but the number and dimensions thereof are not particularly limited. The number and dimensions of the cross beams 41 and the vertical beams 42 may be set so that the elasticity required for the large contact support 40 can be obtained.

The large contact displacement detector 60 includes a push displacement detector 61 that detects the displacement of the small contact 30 in the push direction x, and a lateral displacement detector 62 that detects the displacement of the small contact 30 in the lateral displacement direction y. are doing. The indentation displacement detector 61 includes first and second strain detection elements 63 and 64 that detect the strain of the cross beam 41. The lateral displacement detector 62 includes first and second strain detecting elements 65 and 66 that detect the strain of the vertical beam 42.

The configuration of the first and second strain detection elements 63 and 64 of the indentation displacement detector 61 and the strain detection circuit are the first and second strain detection elements 63 and 64 of the large contactor displacement detector 60 in the first embodiment. Similar to the configuration and distortion detection circuit. The configuration of the first and second strain detection elements 65 and 66 of the lateral displacement detector 62 and the strain detection circuit are the first and second strain detection elements 63 and 64 of the large contactor displacement detector 60 in the first embodiment. Similar to the configuration and distortion detection circuit.

The tactile sensor 3 of the present embodiment can detect the average frictional force of the object O to be measured by detecting the displacement of the large contactor 20 in the lateral displacement direction y. In this embodiment, it is not necessary to provide the traversing portion 23 on the large contactor 20.

[Fourth Embodiment]
Next, the tactile sensor 4 according to the fourth embodiment of the present invention will be described.
As shown in FIG. 8, the tactile sensor 4 of the present embodiment has a configuration in which a protective plate 32 is provided on the tactile sensor 1 of the first embodiment.

When a material composed of fibers, particularly a cotton-like material in which the fibers are not so adhered to each other, is measured by the tactile sensor 1, the loop-shaped fibers may be caught by the small contacts 30. Then, since the displacement of the small contactor 30 mainly depends on the strength of the caught fiber, it becomes impossible to detect the desired information (fine characteristics of the surface of the object to be measured). By providing the protective plate 32, it is possible to prevent the fibers from being caught by the small contacts 30, and it is possible to detect fine surface characteristics even with a cotton-like material.

For convenience of explanation, among the surfaces of the flat plate-shaped large contactor 20, a pair of surfaces orthogonal to the contact surface 21 are referred to as "front surface" and "back surface". The tactile sensor 4 of the present embodiment has a configuration in which a protective plate 32 is superposed on the surface side of the large contactor 20.

Two spacers 33 are attached to the surface of the large contactor 20 (main body 22) at intervals. The spacer 33 is a plate material having a predetermined thickness. The protective plate 32 is bridged and attached to two spacers 33. That is, the protective plate 32 is provided on the surface of the large contactor 20 via the spacer 33.

The protective plate 32 has a shape that covers at least the opening of the internal space of the large contactor 20. Therefore, at least the tip of the small contactor 30 is covered with the protective plate 32. Further, a part of the side surface of the protective plate 32 (the portion on the opening side of the large contactor 20) is arranged on the extension surface of the contact surface 21. Therefore, in a plan view, the gap between the two contact surfaces 21 is complemented by the side surface of the protective plate 32.

The side surface of the protective plate 32 does not have to be perpendicular to the front and back surfaces of the protective plate 32, and may be inclined. In this case, a part of the edge (hereinafter referred to as "side edge") located at the intersection of the side surface and the front surface or the back surface of the protective plate 32 is arranged on the extension surface of the contact surface 21.

A gap corresponding to the thickness of the spacer 33 is secured between the protective plate 32 and the small contactor 30 and the small contactor support 50. Moreover, the small contactor 30 is displaced in the same plane as the flat plate-shaped large contactor 20. That is, the displaced surface of the small contactor 30 is parallel to the front and back surfaces of the protective plate 32. Therefore, when the small contactor 30 operates in a normal range, the protective plate 32 does not interfere with the displacement of the small contactor 30. The gap between the protective plate 32 and the small contact 30 is not particularly limited, but is about several μm to several tens of μm.

When measuring the measurement object O made of fibers, the tactile sensor 4 is slid while being pressed against the measurement object O. At this time, the fibers constituting the measurement object O are blocked by the protective plate 32 and cannot enter the inside of the opening of the large contact 20. Therefore, it is possible to prevent the loop-shaped fibers from being caught by the small contactor 30. As a result, even the measurement object O made of fibers can detect fine surface characteristics.

Depending on the shape of the object O to be measured, a force may be applied to the small contactor 30 in a direction perpendicular to the displacement surface in normal operation (direction perpendicular to the paper surface in FIG. 8). However, the displacement of the small contactor 30 in such a direction is limited by the protective plate 32. Therefore, it is possible to prevent the movable structure portion from being damaged due to the small contact 30 being displaced in the above direction.

The protective plate 32 may be provided on the back surface of the large contactor 20. The protective plate 32 may be provided on both the front and back surfaces of the large contact 20. Further, the protective plate 32 may be provided on the tactile sensors 2 and 3 of the second and third embodiments.

[Fifth Embodiment]
Next, the tactile sensor 5 according to the fifth embodiment of the present invention will be described.
As shown in FIG. 9, the tactile sensor 5 of the present embodiment has a configuration in which the base 10 and the large contact support 40 are removed from the tactile sensor 1 of the first embodiment. That is, the tactile sensor 5 has a large contactor 20, a small contactor 30, and a small contactor support 50. The large contact 20 does not have the traverse portion 23 and the traverse portion support 24.

When the tactile sensor 5 is slid while being pressed against the object O to be measured, the small contactor 30 is displaced and fine characteristics on the surface of the object to be measured can be detected. The tactile sensor 5 does not have a function of detecting a pressing force against the object O to be measured.

The tactile sensor 5 is provided with a protective plate 32. The configuration of the protective plate 32 is the same as that of the fourth embodiment. Even when the measurement object O made of fibers is measured by the tactile sensor 5, the protective plate 32 can prevent the fibers from entering the inside of the opening of the large contactor 20. Since the fibers can be prevented from being caught by the small contacts 30, it is possible to detect the fine characteristics of the object O to be measured, which is composed of the fibers.

[Sixth Embodiment]
Next, the tactile sensor 6 according to the sixth embodiment of the present invention will be described.
Although the tactile sensors 1 to 5 of the first to fifth embodiments have a two-dimensional structure, a three-dimensional structure may be used instead. As shown in FIGS. 10 and 11, the tactile sensor 6 of the present embodiment has a three-dimensional structure.

The tactile sensor 6 has a base 10, a large contactor 20, and a small contactor 30. The base 10 has a columnar internal space in the center. The large contact 20 is a cylindrical member and is arranged in the internal space of the base 10. The small contactor 30 is a columnar member and is arranged in the internal space of the large contactor 20. A diaphragm 11 is joined to the lower surfaces of the base 10, the large contact 20 and the small contact 30.

The base 10, the large contact 20 and the small contact 30 are made of a photocurable resin having a thickness of several hundred μm or the like, and have rigidity with little bending due to an external force. The diaphragm 11 is made of silicon or the like having a thickness of several μm to several tens of μm.

The portion of the diaphragm 11 between the base 10 and the large contact 20 has a function as the large contact support 40. Further, the portion of the diaphragm 11 between the large contact 20 and the small contact 30 has a function as a small contact support 50.

The upper surface of the tactile sensor 6 is a sensing surface facing the measurement object O. Therefore, the upper surface of the large contact 20 is the contact surface 21, and the upper surface of the small contact 30 is the contact end 31.

A gap is provided between the base 10 and the large contact 20 so that the large contact 20 can swing. The diaphragm 11 is distorted when the large contact 20 is tilted by an external force or is displaced in the pushing direction. In order to detect such deformation of the diaphragm 11, a large contact displacement detector is formed in a portion between the base 10 of the diaphragm 11 and the large contact 20. The large contact displacement detector comprises, for example, a piezo resistance element.

A gap is provided between the large contact 20 and the small contact 30 so that the small contact 30 can swing. The diaphragm 11 is distorted due to the small contact 30 being tilted by an external force or being displaced in the pushing direction. In order to detect such deformation of the diaphragm 11, a small contact displacement detector is formed in a portion between the large contact 20 and the small contact 30 of the diaphragm 11. The small contact displacement detector comprises, for example, a piezo resistance element.

The sensing surface of the tactile sensor 6 is pressed against the surface of the measurement object O, and the contact surface 21 is brought into contact with the measurement object O. Then, the large contactor 20 is pushed in by the reaction force of the pressing force of the tactile sensor 6 and is displaced in the pushing direction. While the sensing surface of the tactile sensor 6 is pressed against the surface of the object to be measured O, the sensor is moved along the surface of the object to be measured O. Then, the small contactor 30 is displaced in the pushing direction x along the unevenness of the surface of the object O to be measured. Further, the small contactor 30 is tilted by the frictional force acting between the contact end 31 and the object O to be measured. Further, the large contactor 20 is tilted by the frictional force acting between the contact surface 21 and the object O to be measured. By detecting the displacement of the large contactor 20 and the small contactor 30, it is possible to detect the pressing force of the tactile sensor 6, the surface shape of the object O to be measured, the frictional force in a minute region, and the average frictional force.

[Other embodiments]
The large contact support 40, the small contact support 50, and the transverse support 24 may be made of a member other than the beam as long as the desired elasticity can be obtained.

The large contact displacement detector 60, the small contact displacement detector 70, and the transverse portion displacement detector 81 are not limited to the piezo resistance element. For example, the small contact displacement detector 70 is placed between the small contact 30 and the large contact 20 by utilizing the fact that the distance between the small contact 30 and the large contact 20 changes due to the displacement of the small contact 30. It may be configured to detect the capacitance of. Similarly, the large contact displacement detector 60 and the transverse portion displacement detector 81 may also be configured to detect the capacitance.

The contact end 31 of the small contact 30 is not limited to a semicircular shape, and may be formed into another shape. For example, it may have a sharp needle shape, a wavefront shape, or a left-right asymmetric shape. Further, when the feeling of being caught by the object to be measured O is measured as an important parameter, the contact end 31 may be formed in a hook shape so as to be easily caught by the object to be measured O.

The large contact 20 may have a shape having a single undivided contact surface 21. In this case, the traversing portion 23 may include a part of the contact surface 21 or may include the entire contact surface 21. Further, the traversing portion 23 may not be provided and the average frictional force may not be detected.

The manufacturing method of the tactile sensors 1 to 6 is not limited to the semiconductor micromachining technique. For example, modeling technology using a three-dimensional printer can also be adopted.

[Tactile measuring device]
Next, the tactile measuring device 7 provided with the tactile sensor 1 will be described.
As shown in FIG. 12, the tactile measuring device 7 includes a fixture 91, a presser 92, a scanner 93, and a control device 94. The fixture 91 is a member to which the base 10 of the tactile sensor 1 is attached.

The pusher 92 is a mechanism for moving the fixture 91 closer to and further from the object O to be measured. The tactile sensor 1 attached to the fixture 91 can be pressed against the object O to be measured by the operation of the pusher 92. The pusher 92 is not particularly limited, but a ball / nut, a hydraulic cylinder, or the like can be adopted.

The pressing device 92 may be configured to operate the tactile sensor 1 toward the measurement object O as in the present embodiment, or may be configured to operate the measurement object O toward the tactile sensor 1. It may be configured to operate both the tactile sensor 1 and the measurement object O. It suffices if the tactile sensor 1 and the object to be measured O can be relatively close to each other and the tactile sensor 1 can be pressed against the object O to be measured.

The scanner 93 is a mechanism for moving the fixture 91 along the surface of the object O to be measured. The tactile sensor 1 attached to the fixture 91 can be slid along the surface of the object O to be measured by the operation of the scanner 93. The scanner 93 is not particularly limited, but a ball / nut, a hydraulic cylinder, or the like can be adopted. The scanner 93 may be configured to move the entire presser 92.

The scanner 93 may be configured to operate the tactile sensor 1 with respect to the measurement object O as in the present embodiment, or may be configured to operate the measurement object O with respect to the tactile sensor 1. It may be configured to operate both the sensor 1 and the object O to be measured. It suffices if the tactile sensor 1 and the measurement object O can be relatively operated and the tactile sensor 1 can be slid along the surface of the measurement object O.

By using the tactile measuring device 7, it is possible to perform a detection operation in which the tactile sensor 1 is slid while being pressed against the object O to be measured. This makes it possible to measure the feel of the object O to be measured.

The control device 94 has a function of controlling the operation of the presser 92 and the scanner 93. The control device 94 is configured as follows, for example. The pressing force detected by the large contactor displacement detector 60 of the tactile sensor 1 is input to the control device 94. The control device 94 controls the operation of the pressing device 92 so that the input pressing force becomes a predetermined value. That is, the control device 94 performs feedback control using the pressing force detected by the tactile sensor 1 as the operating amount and the pressing amount of the tactile sensor 1 by the pressing device 92 as the control amount.

With such control, the pressing force of the tactile sensor 1 against the object O to be measured can be made constant. Since the signal detected by the tactile sensor 1 does not change depending on the change in the pressing force, the tactile sensation of the object O to be measured can be accurately measured.

[Identification device]
Next, the identification device 8 for identifying the type of the object to be measured will be described.
FIG. 13 is a block diagram showing the configuration of the identification device 8. The identification device 8 is realized by a computer. The computer may be a dedicated machine or a general-purpose machine. A computer is composed of a CPU (Central Processing Unit), a GPU (Graphics Processing Unit), a main storage device, an auxiliary storage device, and the like. When the computer executes various programs, the function as the identification device 8 is realized.

The trained model 201 is stored in the storage device 200 of the identification device 8. The trained model 201 is a program module and is pre-installed in the computer constituting the identification device 8. When the computer executes the trained model 201, the learner 101 is configured on the computer. As the algorithm of the learner 101, an algorithm suitable for dealing with a classification problem, such as a neural network or a support vector machine, is used. Machine learning is performed in advance on the learner 101. The method of machine learning is not particularly limited, and examples thereof include supervised learning, reinforcement learning, and unsupervised learning. When the learner 101 is a neural network, machine learning optimizes the weighting coefficients between neurons.

Machine learning is performed by, for example, the following procedure. This procedure is supervised learning.
First, learning data used for machine learning is prepared. The learning data consists of training data and evaluation data. A plurality of training data and evaluation data are prepared for each type of measurement object. The training data consists of tactile data of the object to be measured and information on the type of the object to be measured. The evaluation data consists of tactile data and is not accompanied by type information. The tactile data is, for example, measurement data obtained by measuring an object to be measured using the tactile sensor 1. The type information is information indicating the type of the object to be measured. Kind information is a teacher signal in supervised learning.

The training data is input to the learning device 101, and the features and patterns for each type of measurement object are learned. Next, the evaluation data is input to the learner 101, and it is evaluated whether the output type information is correct. The above training and evaluation are repeated until the correct type information is output for the evaluation data. As a result, when the learner 101 is a neural network, the weighting coefficient between neurons is optimized.

The measurement data output from the tactile sensor 1 can be used as the tactile data. From the tactile sensor 1, four pieces of information, that is, the amount of unevenness, the minute area frictional force, the average frictional force, and the pressing force of the tactile sensor 1 against the object to be measured with respect to the surface position (positional coordinates of the surface) of the object to be measured. Is output (see FIG. 5). The measurement data may include only one of these four pieces of information, or may include a plurality of any of them. For example, the measurement data may include only the amount of unevenness and the frictional force in a minute region. The pressing force is preferably used in combination with other information.

Various formats of measurement data can be adopted. For example, a data string obtained by converting an analog signal output from the tactile sensor 1 into digital data can be used as measurement data. In this case, the measurement data is a data string constituting a waveform such as the amount of unevenness. For example, when the displacement of the uneven amount is x and the displacement of the minute region frictional force is y, the data sequence is expressed as {(xi, yi)} (i = 1,2, ..., N).

The measurement data is so-called raw data output from the tactile sensor 1. The measured data may be subjected to predetermined processing to obtain post-processed data, and the post-processed data may be used as tactile data. Various processes can be adopted as the processes applied to the measurement data. In addition, various types of post-processing data can be generated depending on the type of processing. An example thereof will be described below.

A waveform such as the amount of unevenness formed by the measurement data can be graphed to generate a graph image, which can be used as the processed data. The graph image is, for example, the image shown in FIG. The graph image shown in FIG. 18 is a graph in which the waveforms of the amount of unevenness and the frictional force in a minute region are color-coded and graphed. The horizontal axis is the surface position of the object to be measured, and the vertical axis is the amount of unevenness or the frictional force in a minute area. Graph images can be generated by converting measurement data using general-purpose spreadsheet software.

The displacement image as shown in FIG. 19 may be used as the processed data. The displacement image is an image obtained by converting a waveform such as the unevenness amount formed by the measurement data, and is an image in which the displacement (value such as the unevenness amount) at each surface position is represented as the color of the pixel corresponding to the surface position. The displacement image can be generated by converting the measurement data.

The displacement image shown in FIG. 19 contains two pieces of information, that is, the amount of unevenness and the frictional force in a minute region. A region on the displacement image is defined for each piece of information. Further, there is a one-to-one correspondence between each pixel constituting each region and the surface position of the object to be measured. Then, the amount of unevenness or the value of the frictional force in a minute region at each surface position is shown as the color of the corresponding pixel.

The color space used for the color of the pixels of the displacement image is not particularly limited, and may be a gray scale or an RGB color system. The displacement image shown in FIG. 19 uses a gray scale.

The measurement data may be subjected to signal processing to obtain signal processing data, and the signal processing data may be used as post-processing data. The signal processing method is not particularly limited, and examples thereof include fast Fourier transform (FFT), chaos analysis, statistical analysis, wavelet analysis, and envelope analysis. The processed data is obtained as a data string.

A graph image obtained by graphing signal processing data may be used as post-processing data. As the graph format, a format suitable for representing signal processing data may be adopted. For example, when signal processing data obtained by Fourier transforming measurement data is used, a graph with frequency on the horizontal axis and intensity on the vertical axis is used. The processed data does not necessarily have to form a waveform. For example, a scatter plot can be obtained from the Lorenz plot, which is a type of chaos analysis. Such a scatter plot may be used as a graph image.

The signal processing data may be converted into a displacement image and used as post-processing data. In this case, the displacement image is an image representing the displacement of the waveform composed of the signal processing data as the color of the pixels.

The learner 101 is preliminarily machine-learned using measurement data or post-processing data of either format as tactile data.

As shown in FIG. 13, the identification device 8 includes a data acquisition unit 102, a data processing unit 103, and a display unit 104 in addition to the learning device 101.

The data acquisition unit 102 has a function of acquiring measurement data output from the tactile sensor 1. If the data acquisition unit 102 is configured by an analog-to-digital conversion circuit, the analog signal output from the tactile sensor 1 can be directly captured and the measurement data can be acquired in the form of a data string. The data acquisition unit 102 may be configured to acquire a data string generated by an external device.

When the measurement data is used as the tactile data, the data acquisition unit 102 inputs the measurement data to the learning device 101. When the processed data is used as the tactile data, the data acquisition unit 102 inputs the measurement data to the data processing unit 103.

The data processing unit 103 has a function of applying predetermined processing to the measurement data and obtaining the processed data. The data processing unit 103 inputs the processed data to the learner 101. When the measurement data is used as the tactile data, the data processing unit 103 may not be provided.

The display unit 104 has a function of displaying the output result of the learning device 101. The display unit 104 is composed of a display or the like.

The identification device 8 is used as follows.
Measurement data can be obtained by measuring an object to be measured using the tactile sensor 1. The measurement data is input to the data acquisition unit 102. The measurement data is input to the learner 101 in the same format or after being converted into data. Here, the format of the data input to the learning device 101 is the same format as the data used for machine learning. Then, the learning device 101 outputs the type information corresponding to the measurement object. The display unit 104 displays the type information output from the learning device 101.

In this way, the type of measurement object can be specified based on the tactile data. If the learning device 101 is made to learn various measurement objects, the types of the various measurement objects can be identified.

(Fabric measurement test)
A fabric measurement test was performed using the tactile sensor shown in FIG. This tactile sensor has the same structure as the tactile sensor 1 according to the first embodiment, but the shape and dimensions of each part are different. The dimensions of the tactile sensor are 9,900 μm in width, 6,000 μm in length, and 50 μm in thickness.

A milled cloth was prepared as an object to be measured. The tactile sensor was slid while being pressed against the milling fabric, and various signals were obtained from the tactile sensor. FIG. 15A shows the time change of the signal obtained when the pressing force of the tactile sensor is weakened. FIG. 15B shows the time change of the signal obtained when the pressing force of the tactile sensor is set to the middle level. FIG. 15C shows the time change of the signal obtained when the pressing force of the tactile sensor is increased.

From FIGS. 15A, 15B, and 15C, it can be seen that as the pressing force of the tactile sensor is increased, the signal of the pressing force detected by the tactile sensor becomes stronger. From this, it was confirmed that the pressing force can be detected by the tactile sensor and the measurement conditions can be quantified. Further, as the pressing force of the tactile sensor is increased, the signal of the amount of unevenness becomes stronger as a whole, and the amplitude becomes larger and the waveform becomes clearer. The waveform of the signal of the minute area frictional force rises strongly, and the influence of the friction of the fiber becomes strong. The signal of the average friction force becomes stronger as a whole. From these changes in the waveform, it is considered that the texture peculiar to the fabric can be identified, such as the feeling of roughness becomes stronger when the fabric is patted strongly.

A piqué cloth was prepared as an object to be measured. To the human touch, piqué fabrics are rougher than piqué fabrics. The tactile sensor was slid while being pressed against the piqué fabric, and various signals were obtained from the tactile sensor. FIG. 16A shows the time change of the signal obtained when the pressing force of the tactile sensor is weakened. FIG. 16B shows the time change of the signal obtained when the pressing force of the tactile sensor is set to the middle level. FIG. 16C shows the time change of the signal obtained when the pressing force of the tactile sensor is increased.

The tendency of the change of each signal with the change of the pressing force is the same as that of the milled fabric. Comparing FIGS. 15 and 16, the signal of the amount of unevenness and the signal of the minute area friction force have a larger amplitude and a clearer waveform in the case of the piqué-knitted fabric than in the case of the milled-knitted fabric. You can see that. It is considered that this is because the piqué fabric is rougher than the piqué fabric. From this, it was confirmed that the difference in the feel of the object to be measured can be measured by the tactile sensor.

(Hair measurement test)
A hair measurement test was performed using a tactile sensor. The hair of the human body was prepared as an object to be measured. The surface of the hair is covered with cuticle. The cuticle is scaly from the root to the tip of the hair. Therefore, if you trace the hair toward the root with your finger, you will feel that it is caught more strongly than if you trace it toward the tip of the hair.

First, the hair was fixed in a straightened state. Next, the tactile sensor was pressed against the hair. In that state, the tactile sensor was scanned in the direction of the tip of the hair for 10 seconds, and then the same portion of the hair was scanned in the direction of the root for 10 seconds.

Various signals obtained from the tactile sensor are shown in FIGS. 17A and 17B. FIG. 17A is a graph showing the time variation of the amount of unevenness and the frictional force in a minute region during the period (16 to 26 seconds) when the tactile sensor is scanned in the direction of the tip of the hair. FIG. 17B is a graph showing the time variation of the amount of unevenness and the frictional force in a minute region during the period (36 to 46 seconds) when the tactile sensor is scanned in the fundamental direction.

The average value of the micro-regional frictional force during the period of scanning in the direction of the hair tips was -0.625 mN. On the other hand, the average value of the minute area frictional force during the period of scanning in the root direction was 1.447 mN. From this, it can be seen that the frictional force is larger when scanning in the root direction.

The standard deviation of the microregional frictional force during the period scanned in the direction of the hair tips was 0.168. In contrast, the standard deviation of the microregional frictional force during the period scanned in the root direction was 0.230. From this, it can be seen that the fluctuation of the frictional force becomes larger when scanning in the root direction.

From the above, it can be seen that when scanning in the fundamental direction, the frictional force becomes large and the fluctuation of the frictional force becomes large. This result is consistent with the sensation of tracing the hair toward the root with a finger. Therefore, it can be said that it was confirmed that the tactile sensation derived from a fine structure such as a cuticle of hair can be detected by using the tactile sensor.

(Cloth identification test 1)
A fabric identification test using artificial intelligence was conducted.
First, a neural network was constructed on a computer. The neural network is a convolutional neural network having a structure in which four convolutional layers and four pooling layers are alternately arranged between an input layer and an output layer.

Next, 10 kinds of fabrics were prepared. Hereinafter, each of the 10 types of fabrics is referred to as fabric A, fabric B, ..., Fabric J. The material of each fabric is as shown in Table 1.

Each fabric was measured using a tactile sensor. The pressing force of the tactile sensor against the fabric was set to 12 mN, and each of the 10 types of fabric was measured 8 times. Further, the pressing force of the tactile sensor against the fabric was set to 24 mN, and each of the 10 types of fabric was measured 7 times. As a result, a total of 150 measurement data were obtained. Each measurement data was converted into a graph image as shown in FIG. The graph image contains waveforms of the amount of unevenness and the frictional force in a minute region, and each is color-coded. The horizontal axis is the surface position of the object to be measured, and the vertical axis is the amount of unevenness or the frictional force in a minute area.

The 150 graph images were divided into training images, evaluation images, and verification images. 100 training images (5 for each fabric measured with a pressing force of 12 mN, 5 for a pressing force of 24 mN) and 30 evaluation images (for each fabric, measured with a pressing force of 12 mN). Two pieces, one piece measured with a pressing force of 24 mN), and 20 verification images (one piece measured with a pressing force of 12 mN and one piece measured with a pressing force of 24 mN for each fabric). ..

The training images were input to the neural network constructed on the computer, and the features and patterns for each type of fabric were learned. At this time, the type information of the cloth (distinguished from the cloths A to J) was used as a teacher signal. Next, an evaluation image was input to the neural network, and it was evaluated whether the output type information was correct. The evaluation was performed by obtaining the discrimination rate from the output of the neural network when the evaluation image was input. Here, the discrimination rate means the ratio of the correct type information output from the neural network.

The above training and evaluation were repeated until there was almost no improvement in the discrimination rate. The final identification rate was 83.3% (25 out of 30 are correct).

Next, a verification image that was not used for the above learning was input to the neural network. If the discrimination result for these unknown data is close to the evaluation result described above, it can be said that the trained model is correctly constructed. The results are shown in Table 2. The ural network outputs the type candidates for the verification image and the certainty (probability) of the candidates.

The discrimination rate was obtained from the output of the neural network. As a result, the identification rate for the verified images was 85.0% (17 out of 20 images are correct). From this, it was confirmed that the type of fabric can be identified from the measurement data obtained from the tactile sensor. It is considered that the discriminating power can be further improved by increasing the number of learning data.

(Cloth identification test 2)
The measurement data used in the fabric identification test 1 was converted into a displacement image as shown in FIG. The displacement image contains information on the amount of unevenness and the frictional force in a minute area. The amount of unevenness and the displacement of the frictional force in a minute region are represented by a gray scale of 256 steps. Machine learning was performed in the same procedure as in the fabric identification test 1 except that the displacement image was used. As a result, the identification rate for the evaluation image was 83.3% (25 out of 30 images are correct).

Table 3 shows the results of inputting the verification image into the neural network.

The discrimination rate was obtained from the output of the neural network. As a result, the identification rate for the verified images was 85.0% (17 out of 20 images are correct). From this, it was confirmed that the type of fabric can be identified from the measurement data obtained from the tactile sensor. It is considered that the discriminating power can be further improved by increasing the number of learning data.

1, 2, 3, 4, 5, 6 Tactile sensor 10 Base 20 Large contact 21 Contact surface 22 Main body 23 Traverse part 24 Traverse part support 30 Small contact 31 Contact end 40 Large contact support 50 Small contact Support 60 Large contactor displacement detector 70 Small contactor displacement detector 81 Traverse displacement detector 7 Tactile measuring device 8 Identification device

Claims (7)

At the base,
A large contactor having a contact surface that comes into contact with the object to be measured,
A small contact with a contact end whose contact area with the measurement object is smaller than that of the contact surface,
A large contact support that supports the large contact so as to be displaceable with respect to the base at least in a direction perpendicular to the contact surface.
A large contactor displacement detector that detects the displacement of the large contactor with respect to the base, and
A small contact support that supports the small contact in a displaceable manner with respect to the large contact,
A tactile sensor comprising a small contactor displacement detector that detects the displacement of the small contactor with respect to the large contactor. The large contact is
With the main body
A traversing portion including a part or all of the contact surface,
A traversing portion support that supports the traversing portion so as to be displaceable in a direction parallel to the contact surface with respect to the main body portion.
The tactile sensor according to claim 1, further comprising a traversing portion displacement detector that detects displacement of the traversing portion with respect to the main body portion. The large contact is
With the main body
A plurality of traversing parts including a part of the contact surface,
A plurality of traversing portions supporting bodies that support the plurality of traversing portions so as to be displaceable in a direction parallel to the contact surface with respect to the main body portion.
A plurality of traversing section displacement detectors for detecting displacement of the plurality of traversing sections with respect to the main body portion are provided.
The tactile sensor according to claim 1, wherein the plurality of traversing portions have different areas of contact surfaces from each other. The tactile sensor according to claim 1, wherein the large contact support supports the large contact with respect to the base so as to be displaceable in a direction parallel to the contact surface. The large contact has a flat plate shape in which a part of the side surface forms the contact surface, and has an internal space having an opening that divides the contact surface into two.
The small contact is arranged in the internal space and
A protective plate is provided on one or both of the front and back surfaces of the large contact.
The tactile sensation according to claim 1, 2, 3 or 4, wherein the protective plate covers an opening of the internal space, and a part of a side surface or a side edge is arranged on an extension surface of the contact surface. Sensor. A tactile measuring device provided with the tactile sensor according to claim 1, 2, 3, 4 or 5.
A pusher that operates the tactile sensor and / or the measurement object and presses the tactile sensor against the measurement object.
A tactile measuring device comprising the tactile sensor and / or a scanner that operates the tactile object and slides the tactile sensor along the surface of the measuring object. It is characterized by comprising a control device that controls the operation of the pressing device so that the pressing force detected by the large contact displacement detector of the tactile sensor is input and the pressing force becomes a predetermined value. 6. The tactile measuring device according to claim 6.

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