JP2019088915A - Robot device - Google Patents

Abstract

To provide a robot device that can realize more attractive movements.SOLUTION: A robot device comprises a main body, a first operating body and a second operating body provided operatively in the main body, and a control unit for controlling operations of the first operating body and the second operating body. The control unit can control the first operating body so as to cause it to operate in a first direction, and can control the second operating body so as to cause it to operate in a second direction different to the first direction.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a robot apparatus.

  As a robot apparatus having the shape of a sphere, there is one described in Patent Document 1.

JP, 2005-046387, A

  The present invention provides a robotic device that can exhibit more interesting movements compared to the prior art.

The present invention for solving the above problems is a robot device, and
Body and
A first operating body and a second operating body operatively provided in the main body;
A control unit that controls the operation of the first operating body and the second operating body;
Have
The control unit can control the first operating body to move in a first direction, and can control the second operating body to operate in a second direction different from the first direction. It is.

  According to the present invention, it is possible to provide a robot apparatus that exhibits more interesting movements.

The figure which shows an example of the external appearance of the robot apparatus 100 corresponding to embodiment of invention. The figure which shows an example of the internal structure of the robot apparatus 100 corresponding to embodiment of invention. FIG. 2 is a view showing an example of the configuration of an operating body in the robot apparatus 100 corresponding to the embodiment of the invention. BRIEF DESCRIPTION OF THE DRAWINGS Sectional drawing which shows an example of the internal structure of the robot apparatus 100 corresponding to embodiment of invention. FIG. 7 is a view for explaining the operation of the robot apparatus 100 according to the rotation of the operating body in the robot apparatus 100 corresponding to the embodiment of the invention. The figure which shows another example of the internal structure of the robot apparatus 100 corresponding to embodiment of invention. The figure which shows an example of the hardware constitutions of the robot apparatus 100 corresponding to embodiment of invention.

  Hereinafter, exemplary embodiments of the invention will be described with reference to the accompanying drawings. In the drawings, the same reference numerals indicate the same elements.

  FIG. 1 is an overall view showing one embodiment of a robot apparatus according to the present invention. The robot apparatus 100 is configured as an apparatus having a spherical shape, and an outer shell thereof is a first outer shell body including a spherical upper main body 101 and a spherical lower main body 111, and a second outer surface grounded to the ground (grounding surface). And a shell 121. In the present embodiment, the robot apparatus 100 is configured to be swingable in a predetermined direction along the outer surface of the spherical lower main body 111 of the first outer shell and the second outer shell 121, and the outer shell It is configured to be capable of turning around 121.

  Two lid members 102 are attached to the spherical upper body 101. Each lid member 102 is openably and closably attached to the spherical upper main body 101, and forms a spherical surface with the spherical upper main body 101 in the closed state. Further, a weight (not shown) is connected to the lid member 102 via an arm in the spherical upper main body 101. With this configuration, while the robot apparatus 100 is swinging, the lid member 102 moves up and down in the direction indicated by the arrow 106 centering on the connection portion with the spherical upper main body 101 by the swinging of the weight portion. Furthermore, inside the respective lid members 102, hand-shaped members 103 are accommodated. The bill member 103 can be connected to an arm member (not shown) and can protrude like an arm from the spherical upper main body 101. The opening 104 corresponds to the eye of the robot apparatus 100, and a light emitting element such as an LED is embedded therein. The bonding portion 105 is a bonding portion between the spherical upper main body 101 and the spherical lower main body 111, and a light emitting element such as an LED is embedded.

  The main body of the robot apparatus 100 is divided into a spherical upper main body 101 and a spherical lower main body 111 by a joint portion 105. The user of the robot apparatus 100 further attaches the attachment to the robot apparatus 100 to the user by grasping the lid member 102, the opening 104 and the joint 105 as the ears, eyes, and mouth forming the face of the robot apparatus 100. It can make you feel. The joint portion 105 may be a separate transparent or semi-transparent member, and may be attached to the spherical upper main body 101 and the spherical lower main body 111. In addition, a gap may be formed between the spherical upper main body 101 and the spherical lower main body 111. Furthermore, since the bonding portion is formed in a wave shape, bonding in different directions can be suppressed when bonding the spherical upper main body 101 and the spherical lower main body 111.

  Two lid members 112 are attached to the spherical lower main body 111. Each lid member 112 is detachably attached to the spherical lower main body 111, and forms a spherical surface with the spherical lower main body 111 in the mounted state. Further, the inside of each lid member 112 is connected to a leg member (not shown) so that the lid member 112 can be projected like a leg from the spherical lower main body 111. The lid member 112 protruding from the spherical lower main body 111 can be in contact with the ground surface of the robot apparatus 100. In the present embodiment, as shown in the lower side of FIG. 1, the direction of the robot apparatus 100 is identified front to back, right to left, top to bottom with the side with the eye 104 as the front (front side).

  Next, the internal mechanism of the robot apparatus 100 will be described with reference to FIGS. 2 to 4. FIG. 2 is a view showing an example of the internal structure of the robot apparatus 100 corresponding to the present embodiment. FIG. 3 is a view showing a configuration example of an operating body in the robot apparatus 100 excluding the spherical lower main body 111 from the internal mechanism shown in FIG. FIG. 4 is a cross-sectional view showing the internal structure of the robot apparatus 100. As shown in FIG. FIG. 4 is a cross-sectional view taken along line A-A of FIG. However, for the sake of simplicity, the lid member 102 is closed.

  In the robot apparatus 100, a mechanism is provided for swinging the sphere in the front-rear direction (pitch axis) and the left-right direction (roll axis) with respect to the front of the robot apparatus 100. The mechanisms are arranged to intersect each other in the spherical lower body 111. The crossing angle may be a predetermined value (for example, 90 degrees) determined in advance.

  First, a mechanism for swinging in the front-rear direction includes an arm member 201, a power supply unit 202, a bearing unit 203, and a counterweight 204. The arm member 201 is an operating body that rotates around a predetermined rotation axis in a predetermined angle range according to the power transmitted from the power supply unit 202. The power supply unit 202 includes a motor and can rotate the arm member 201. The bearing portion 203 supports the rotation shaft of the arm member 201 to enable the rotation of the arm member 201 and has a role of positioning the arm member 201 with respect to the spherical lower main body 111. The bearing portion 203 is disposed on the inner circumferential surface of the robot apparatus 100 at a position where the contour of the spherical lower main body 111 is substantially equally divided in the front-rear direction. The arm member 201 includes a connection portion connected to the power supply portion 202 and the one bearing portion 203, a connection portion connected to the other bearing portion 203, and an arm for connecting the connection portion and integrating it as the arm member 201. It is composed of parts.

  The counterweight 204 is a weight held at a position in the vicinity of the bearing portion 203 of the arm member 201 or in the vicinity of an end portion of the arm member 201 in a suspended state by a support member 205 extending downward. In the present embodiment, two counterweights 204 are provided for one arm member 201, but the number of counterweights is not limited to two, and may be more than two or one. However, in the case where the number of counter weights is one, the arrangement position is determined from the relationship with the position of the counter weights provided to the other arm members 211. The counterweight 204 is disposed relative to the arm member 201 so that the robot apparatus 100 does not roll and rest without tilting in a state in which it rests in the lowermost position.

  By arranging the counter weight 204 from the arm member 201 via the support member 205 in this manner, the center of gravity of the robot apparatus 100 can be easily changed by the rotation of the arm member 201, and the robot apparatus 100 can be A rocking motion can be realized. A more detailed description will be given with reference to FIG.

  Similarly, a mechanism for swinging in the left-right direction includes an arm member 211, a power supply unit 212, a bearing unit 213, and a counterweight 214. The arm member 211 is an operating body that rotates around a predetermined rotation axis in a predetermined angle range according to the power transmitted from the power supply unit 212. The power supply unit 212 includes a motor and can rotate the arm member. The bearing portion 213 supports the pivot shaft of the arm member 211 to enable pivoting of the arm member 211 and has a role of positioning the arm member 211 with respect to the spherical lower main body 111. The bearing portion 213 is disposed on the inner peripheral surface of the robot apparatus 100 at a position where the contour of the spherical lower main body 111 is substantially equally divided in the front-rear direction. The arm member 211 is a connection portion connected to the power supply portion 212 and the one bearing portion 213, a connection portion connected to the other bearing portion 213, and an arm for connecting the connection portion and integrating it as the arm member 211. It is composed of parts.

  The counterweight 214 is a weight held at a position in the vicinity of the bearing portion 213 of the arm member 211 or in the vicinity of the end portion of the arm member 201 in a suspended state by the support member 215 extending downward. In the present embodiment, two counterweights 214 are provided for one arm member 211, but the number of counterweights is not limited to two, and may be more than two or one. However, when the number of counterweights is one, the arrangement position is determined from the relationship with the positions of the counterweights provided to the other arm members 201. The counterweight 214 is also arranged with respect to the arm member 211 so that the robot apparatus 100 does not roll and rest without tilting in a state in which it is stationary at the lowermost position.

  By arranging the counterweight 214 from the arm member 211 through the support member 215 in this manner, the center of gravity of the robot apparatus 100 can be easily changed by the rotation of the arm member 211, and A rocking motion can be realized. A more detailed description will be given with reference to FIG.

  The arm members 201 and 211 are a first portion (connection portion) extending downward along the bearing portions 203 and 213, and a second portion extending horizontally connecting the first portions. (Arm part) and. Here, as indicated by the one-dot chain line 401 in FIG. 4, the bearing portions 203 and 213 are arranged at substantially the same height in the vertical direction with respect to the spherical lower main body 111. Accordingly, the height of the drive shaft when driving the arm member 201 and the position of the drive shaft when driving the arm member 211 are the same. Therefore, the lengths of the first portion of the arm member 201 and the first portion of the arm member 211 are made different so that the arm members 201 and 211 are not in contact with each other. In the present embodiment, the length of the first portion of the arm member 211 is longer. Accordingly, the arm member 201 lengthens the length of the support member 205, and the arm member 211 shortens the support member 215. Thus, as shown by the alternate long and short dash line 402, the positions of the counter weight 204 and the counter weight 214 are the same.

  As described above, since the distance from the rotation shaft 401 for rotating the arm members 201 and 211 to the position 402 of the counterweight is equal between the arm member 201 and the arm member 211, the arm member 201 or the arm member 211 is used. The amount of displacement of the center of gravity in the case of swinging is the same, and the motion of the robot apparatus 100 can be made similar in the front-rear direction (pitch axis) and the left-right direction (roll axis).

  Next, the swinging operation of the robot apparatus 100 by the rotation of the arm member will be described. FIG. 5 is a diagram for explaining the operation of the robot apparatus 100 according to the rotation of the operating body in the robot apparatus 100. In FIG. 5, the robot apparatus 100 is located on the ground 500 which is a ground contact surface. At this time, in the arm member 211, the counter weight 214 is at the lowest position in the initial state. The position of the center of gravity of the robot apparatus 100 is on the alternate long and short dash line 501 passing through the center of the robot apparatus 100, and the position of the center of gravity does not change. Therefore, the robot apparatus 100 can be stably positioned with respect to the ground 500 in a stationary state.

  On the other hand, when the arm member 211 is rotated in the direction of the arrow 502, the position of the counterweight 214 moves in the upper right direction, so the center of gravity of the robot apparatus 100 deviates from the alternate long and short dash line 501 in the right direction. Move to At this time, since the main body of the robot device 100 has a spherical shape, the robot device 100 rolls on the ground 500 in the direction of the arrow 503 so as to offset the displacement of the center of gravity. In other words, the installation positions of the robot apparatus 100 and the ground 500 move in the direction of the arrow 503. As a result, the raised position of the counterweight 214 is lowered by an amount corresponding to the rolling of the robot apparatus 100, and the change of the center of gravity can be relatively reduced.

  At this time, the rotation angle of the arm member 211 can be made within a predetermined value (for example, 90 degrees) determined in advance. By limiting the rotation angle of the arm member 211 to a predetermined value or less, even when the space in the robot apparatus 100 is narrow, the robot apparatus 100 can perform a desired operation by combining with the rotation operation of the other arm members. be able to. Further, the rotation angle of the arm member 211 can be set to a size according to the degree to which the robot apparatus 100 is swung. When it is desired to make the rocking smaller, the turning angle may be made smaller, and when making the rocking larger, the turning angle may be made larger. In addition, the degree of swing can be controlled by the weight or the number of the counterweights 214. If it is desired to swing the gear more greatly, it may be changed to a heavier counterweight 214, and the number of counterweights 214 may be increased. Further, the degree of swinging can be controlled by the number of times the arm member 211 is turned. If it is desired to make the swing larger, the rotation angle may be increased and the number of times may be increased. In addition, even when the degree of rocking is reduced, the rocking operation state can be continued by increasing the number of times.

  Next, when the arm member 211 is rotated in the direction of the arrow 504 in the opposite direction to the arrow 502, the position of the counter weight 214 moves in the lower left direction. As you go back, move downward. At this time, the robot apparatus 100 has already rotated in the direction of the arrow 503. Therefore, in order to offset the change in the position of the center of gravity again, the robot device 100 pivots on the ground 500 in the direction of the arrow 505 this time. In other words, the installation positions of the robot device 100 and the ground 500 move in the direction of the arrow 505.

  By repeating the above pivoting operation of the arm member 211, the robot apparatus 100 pivots so as to cancel the change in the center of gravity position due to the pivoting operation of the arm member 211, so that the pivoting motion can be realized as a result. it can.

  Although the arm member 211 has been described above, the operation principle of the rocking operation is the same as in the case of the arm member 201. However, in the arm member 201 and the arm member 211, since the direction of rotation is different between the front and rear direction and the left and right direction, the rocking direction is different.

  In addition, although the operation of the arm member in the case of starting the swinging operation has been described above, the operation of the arm member in the case of ending the swinging operation will be described below. A weight may be provided on the lower side of the robot apparatus 100 as shown in FIG. 6 as shown in FIG. 6. If the pivoting operation of the arm member is stopped, the swing width of the robot apparatus 100 itself becomes naturally smaller. Finally, the oscillation stops at the original position even when the oscillation converges.

  In addition to such a natural stop, the swing can be forcibly stopped by rotating the arm member. The principle of the rocking movement of the robot apparatus 100 is the cancellation of the change in the center of gravity position based on the rotation of the arm member and the movement of the counterweight. According to this principle, the robot device 100 rolls in the direction in which the position of the center of gravity changes, so turning the arm member in the direction opposite to the direction in which the robot device 100 is turning interferes with the turning force of the robot device 100 itself. Since the position of the center of gravity changes, the rocking speed can be forcibly reduced.

  For example, when the robot apparatus 100 is rotated in the direction indicated by the arrow 505, if the arm member 211 is rotated in the direction of the arrow 502, the change of the center of gravity turns the robot apparatus 100 in the direction of the arrow 503. As it acts to move, it prevents rotation in the direction of the arrow 505 and as a result, the rocking movement is impeded. As described above, by operating the arm member in the phase opposite to the swinging motion of the robot apparatus 100, the stop time can be shortened. The state of the rocking motion in the robot apparatus 100 can be detected by, for example, an acceleration sensor or the like.

  Next, the bottom structure of the robot apparatus 100 will be described with reference to FIG. FIG. 6 is a view showing another example of the internal structure of the robot apparatus 100. As shown in FIG. The bottom surface of the robot apparatus 100 is pivotable about a pivot shaft 600. The rotation direction is not limited to one direction.

  A power supply unit 601 is disposed on the bottom surface of the robot apparatus 100, and the power supply unit 601 is fixed to the spherical lower main body 111 by a holding plate 602. In addition, the rotational force of the power supply unit 601 is transmitted to the bottom surface member 604, and the other portion of the robot apparatus 100 is configured to turn relative to the bottom surface member 604. Here, the bottom surface member 604 corresponds to the second outer shell 121 of FIG. At least a part of the contact surface of the bottom member 604 with the ground 500 is made of a member having a predetermined friction (for example, rubber etc.) or is surface finished to have a high coefficient of friction, When the rotational force of the supply portion 601 is transmitted to the bottom surface member 604, the bottom surface member 604 is maintained substantially stationary without rotating with respect to the ground 500 by the frictional force. Also, in order to increase the contact area between the bottom member 604 and the ground 500, the bottom member 604 can be configured to have a flatter ground surface side. Thereby, the curvature radius R1 of the outer surface of the bottom surface member 604 becomes a value different from the curvature radius R2 of the surface of the spherical lower main body 111, and R1> R2.

  In the present embodiment, the robot device 100 turns by the rotational force supplied from the power supply unit 601. At this time, the member 603 in contact with the bottom member 604 is fixed to the spherical lower main body 111 so that the rotational force of the power supply unit 601 can be reliably transmitted to the main body of the robot apparatus 100. Further, by providing a plurality of air gaps 605 and the like in the bottom surface member 604, the contact area with the member 603 is reduced and the friction is reduced so that the main body of the robot apparatus 100 can easily turn relative to the bottom surface member 604. .

  Further, on the bottom side of the robot apparatus 100, a predetermined weight 606 is disposed in the vicinity of the bottom surface member 604, for example, on the inner peripheral surface of the robot apparatus 100 and around the bottom surface member 604. The weight 606 is disposed to lower the center of gravity of the robot apparatus 100.

  Next, with reference to FIG. 7, the hardware configuration corresponding to the embodiment of the invention will be described. The robot apparatus 100 can have a control unit 701, a detection unit 702, a rocking motor 703, a turning motor 704, and an output unit 705 as its configuration. These are described as the configuration for describing the embodiment of the above-mentioned invention, and may have a further configuration.

  The control unit 701 controls the entire operation of the robot apparatus 100. The control unit 701 controls the rocking motor 703 and the turning motor 704 according to the detection result of the detection unit 702. The rocking motor 703 corresponds to the power supply units 202 and 212 in FIG. The control unit 701 controls the operation of the rocking motor 703 to realize the rocking operation and the rocking stop operation of the robot apparatus 100. Further, the turning motor 704 corresponds to the power supply unit 601 of FIG. The control unit 701 implements the swing operation and the swing stop operation of the robot apparatus 100 by controlling the operation of the swing motor 704.

  In the present embodiment, the control unit 701 does not drive a plurality of motors simultaneously. That is, when driving the swing motor 703, the swing motor 704 is not driven. At the same time, when driving the turning motor 704, the swinging motor 703 is not driven. Further, the power supply unit 212 is not driven when the power supply unit 202 of the rocking motor 703 is driven, and the power supply unit 202 is not driven when the power supply unit 212 is driven. Note that simultaneously driving the plurality of motors, for example, simultaneously driving the two rocking motors 703 causes the robot apparatus 100 to rock in an oblique direction (right front left back rear direction, left front right rear direction). By driving the rocking motor 703 and the turning motor 704 at the same time, more complicated rocking motion can be achieved.

  The control unit 701 further controls the operation of the output unit 705. The output unit 705 can include, for example, a light emitting unit such as a light emitting element such as an LED embedded in the opening 104 in FIG. 1 or a light emitting element such as an LED embedded in the junction unit 105. Furthermore, the output unit 705 can also function as a sound output unit and can include a speaker for performing sound output. The control unit 701 can control the light emission of these light emitting elements in accordance with the detection result of the detection unit 702, the swinging operation and the turning operation of the robot apparatus 100. Also, at that time, a predetermined sound output can be performed.

  The detection unit 702 may include a sensor that detects an operation of the robot apparatus 100, such as an acceleration sensor. The control unit 701 can realize the swing operation and the swing stop operation by determining the swing state of the robot apparatus 100 based on the output signal from the acceleration sensor and controlling the swing motor 703. . When the swing operation is performed, the control unit 701 determines whether the swing of the robot apparatus 100 is completely stopped based on the detection result of the detection unit 702, and determines that the swing is completely stopped after the swing is completely stopped. The operation can be started.

  The detection unit 702 may also include sound detection means such as a microphone for detecting an external sound input. In this case, the control unit 701 can analyze the content of the sound detected by the microphone and output the sound corresponding to the analysis result through the speaker of the output unit 705. At that time, the light emission form of the light emitting element may be changed to be a pattern in accordance with the sound content to be output. Also, the detection unit 702 may include a plurality of microphones. The control unit 701 can specify the direction of the sound generation source based on the information such as the size of the sound detected by the plurality of microphones. When the control unit 701 can identify the direction of the sound generation source, the control unit 701 operates the turning motor 704 to turn the robot apparatus 100 so that the front of the robot apparatus 100 can be controlled to face the direction. .

Claims (25)

A robotic device,
Body and
A first operating body and a second operating body operatively provided in the main body;
A control unit that controls the operation of the first operating body and the second operating body;
Have
The control unit can control the first operating body to move in a first direction, and can control the second operating body to operate in a second direction different from the first direction. Robotic equipment that is. The first operating body is further operable in a third direction, which is the direction opposite to the first direction,
The robot apparatus according to claim 1, wherein the second motion body is further operable in a fourth direction which is a direction opposite to the second direction. The first operating body is operable within a first angle in the first direction,
The robot apparatus according to claim 1, wherein the second motion body is operable within the first angle in the second direction. The first operating body includes a first weight and a first arm supporting the first weight,
The robot apparatus according to any one of claims 1 to 3, wherein the second moving body includes a second weight and a second arm supporting the second weight. The first operating body includes a plurality of the first weights,
At least one first weight in the vicinity of one end of the first arm and in the vicinity of the other end of the first arm in a hanging state with respect to the first arm. Department is provided,
The second operating body includes a plurality of the second weights,
At least one second weight in the vicinity of one end of the second arm and in the vicinity of the other end of the first arm in a hanging state with respect to the second arm. The robot apparatus according to claim 4, wherein a unit is provided.   The said 1st operation body and the said 2nd operation body are provided so that the said 1st arm part and the said 2nd arm part may be crossed in the said main body. Robot equipment.   The robot apparatus according to claim 6, wherein in the main body, the first arm portion crosses above the second arm portion.   The said 1st weight part and the said 2nd weight part are provided in the same height position with respect to the earthing | grounding surface of the said main body in the said main body in any one of Claim 4 to 7 Robot equipment.   The robot apparatus according to any one of claims 4 to 8, wherein the first arm portion and the second arm portion are provided swingably inside the main body. A first power supply unit for supplying a first power to the first operating body;
And a second power supply unit for supplying a second power to the second operating body.
The first operating body further includes a first connection portion connecting the first power supply portion and the first arm portion,
The robot apparatus according to any one of claims 4 to 9, wherein the second operating body further includes a second connection portion connecting the second power supply portion and the second arm portion. The first arm portion is configured to be swingable by the first power supplied from the first power supply portion via the first connection portion,
The robot apparatus according to claim 10, wherein the second arm unit is configured to be swingable by the second power supplied from the second power supply unit via the second connection unit. The control unit
Controlling the operation of the first operating body and the second operating body by controlling the first power supply unit and the second power supply unit;
The second power supply unit is controlled not to operate the second operating body while controlling the first power supply unit to operate the first operating body.
11. The first power supply unit according to claim 10, wherein the first power supply unit is controlled not to operate the first operation body while the second operation body is operated by controlling the second power supply unit. The robot apparatus according to 11. The body is configured to be swingable by the operation of the first operating body or the second operating body.
The control unit controls the first operating body or the second operating body to operate in the opposite phase to the oscillating motion of the main body during the oscillating motion of the main body. The robot apparatus according to any one of 12.   The control unit operates in the opposite phase by operating the first operating body or the second operating body in the opposite phase to the oscillating operation of the main body during the oscillating operation of the main body. The robot apparatus according to claim 13, wherein control is performed such that the time until the rocking of the main body stops is short as compared with the case where it is not performed. The body includes a first shell and a second shell,
The apparatus is configured to be swingable along the outer surface of at least one of the first outer shell and the second outer shell by the operation of the first operating body or the second operating body. Item 15. The robot device according to any one of items 1 to 14.   The robot apparatus according to claim 15, wherein the curvature radius of the outer surface of the first outer shell and the curvature radius of the outer surface of the second outer shell are different.   At least a part of the second outer shell is grounded to the ground plane by the operation of the first or second operation body, and the first outer shell is the ground plane To transition to a second operation state in which at least a portion of the first outer shell and the second outer shell are grounded to the ground plane from a first operation state not grounded to the ground. The robot apparatus according to claim 15 or 16, which is   The robot apparatus according to any one of claims 15 to 17, wherein at least a part of the outer surface of the second outer shell is configured by a member that reduces slippage with respect to the ground surface.   The robot apparatus according to any one of claims 15 to 18, further comprising a third weight in the vicinity of the second outer shell in the main body.   20. The apparatus according to any one of claims 15 to 19, further comprising a third power supply for supplying a third power for rotating the first outer shell relative to the second outer shell. Robot equipment.   The control unit is configured to prevent the first outer shell from rotating relative to the second outer shell when the first operating body or the second operating body is operated. The robot apparatus according to claim 20, which controls the third power supply unit. It further has a sound detection unit that detects sound input,
The control unit
From the sound detected by the sound detection unit, the direction of the source of the sound is determined;
22. The robot apparatus according to claim 20, wherein the third power supply unit is controlled such that the robot apparatus faces the determined direction.   The spherical body shape is comprised by said 1st outer shell body and a 2nd outer shell body, A face part is formed in said 1st outer shell body, It is described in any one of Claim 15 to 22 Robot equipment. The first outer shell has a light emitting portion,
In the first outer shell, one outer shell and the other outer shell are separably joined,
The light emitting portion is visible through a joint that joins the one outer shell and the other outer shell, or a gap formed between the one outer shell and the other outer shell. The robot apparatus according to any one of claims 15 to 23, which emits light as follows. Sound output unit,
And a sound detection unit for detecting a sound input,
The robot apparatus according to any one of claims 1 to 24, wherein the control unit controls the sound output unit to output a sound according to the sound detected by the sound detection unit.

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