JP6345377B1 - Control system and remote control device - Google Patents

Abstract

A remote control device (1) that outputs identification information indicating a surface in which a normal direction toward the outside of the casing (11) corresponds to a set direction among a plurality of surfaces in the polyhedron is provided, and a control device (2 ) Stores the control contents of the plurality of control target devices (5-n) corresponding to the respective faces in the polyhedron, and the plurality of control target devices (5-n) corresponding to the respective stored faces. ) Based on the control contents of the plurality of control target devices (5-n) corresponding to the surface indicated by the identification information output from the remote operation device (1). n) is controlled.

Description

  The present invention relates to a control system including a remote control device having a polyhedral casing and a remote control device having a polyhedral casing.

For example, Patent Literature 1 below discloses a control system including a sensing unit that controls home appliances.
“ON” is written as a function name on the first surface of the casing of the sensing unit, and “OFF” is written as a function name on the second surface facing the first surface. Yes.
This sensing unit includes a measurement unit for determining which of the first surface and the second surface of the housing is arranged as a front surface.
This sensing unit transmits the function ID corresponding to “ON” to the function execution device if the surface arranged in the table is the first surface, and the surface arranged in the table is the second surface. If it is a screen, the function ID corresponding to “OFF” is transmitted to the function execution device.
The function execution device executes “ON” or “OFF” of the home appliance according to the function ID transmitted from the sensing unit.

JP 2014-199643 A

  Since the conventional control system is configured as described above, it is possible to execute “ON” or “OFF” of one home appliance. However, it is impossible to control a plurality of control target devices at once according to various life scenes such as “sleeping”, “getting up”, and “relaxing”. For this reason, in order to collectively control a plurality of control target devices, there is a problem that a sensing unit must be prepared for each control target device and the plurality of sensing units must be operated.

  The present invention has been made to solve the above-described problems, and obtains a control system and a remote operation device capable of collectively controlling a plurality of control target devices without preparing a plurality of sensing units. For the purpose.

The control system according to the present invention includes a polyhedral housing having a plurality of surfaces, and a normal direction toward the outside of the housing among the plurality of surfaces in the polyhedron is detected by detecting the inclination of the housing. Corresponding to each surface in the polyhedron, and a remote control device including a surface detection unit that detects a surface corresponding to the surface detection unit, and an identification information output unit that outputs identification information indicating the surface detected by the surface detection unit Identification information output from the identification information output unit of the remote control device among the control details of the plurality of control target devices corresponding to each of the stored surfaces, storing the control details of the plurality of control target devices. And a control device that controls the plurality of control target devices based on the control contents of the plurality of control target devices corresponding to the surface indicated by the control device, the control device of the plurality of control target devices corresponding to each surface in the polyhedron Control the contents of it The control target corresponding to the surface indicated by the identification information output from the identification information output unit of the remote operation device from the control contents of the server stored and the plurality of control target devices stored by the server A server that acquires the control content of the device, and the server controls a plurality of control target devices based on the control content acquired by the terminal .

  According to this invention, among the plurality of surfaces in the polyhedron, the remote control device that outputs identification information indicating the surface in which the normal direction toward the outside of the housing corresponds to the setting direction is provided, and the control device includes: The control contents of a plurality of control target devices corresponding to each surface in the polyhedron are stored, respectively, and the control contents of the plurality of control target devices corresponding to the respective stored surfaces are output from the remote operation device. Since the plurality of control target devices are controlled based on the control contents of the plurality of control target devices corresponding to the surface indicated by the identification information, a plurality of control target devices are prepared without preparing a plurality of sensing units. There is an effect that can be controlled collectively.

It is a block diagram which shows the control system by Embodiment 1 of this invention. It is a hardware block diagram which shows the control system by Embodiment 1 of this invention. It is a perspective view which shows the remote control apparatus 1 by Embodiment 1 of this invention. 4A is a perspective view illustrating an example in which the polyhedron is a regular octahedron, FIG. 4B is a perspective view illustrating an example in which the polyhedron is a regular dodecahedron, and FIG. 4C is a perspective view illustrating an example in which the polyhedron is a regular icosahedron. FIG. It is a hardware block diagram of a computer in case a control system is implement | achieved by software or firmware. It is a flowchart which shows the process sequence in case a control system is implement | achieved by software or firmware. It is explanatory drawing which shows setting direction (theta) _est for selecting one surface from six surfaces 11a-11f which the housing | casing 11 has. FIG. 8A is an explanatory diagram showing a “wake” life scene, FIG. 8B is an explanatory diagram showing a “sleep” life scene, and FIG. 8C is an explanatory diagram showing a “relax” life scene. It is explanatory drawing which shows an example of the control content of the some control object apparatus 5-n corresponding to the six surfaces 11a-11f which the housing | casing 11 has. It is explanatory drawing which shows an example of the setting screen of the control content by the setting reception part 17 of the portable terminal. It is explanatory drawing which shows a mode that the user lifts the remote control apparatus 1 in order to switch a life scene. It is explanatory drawing which shows the state which is lighting only the surface corresponding to normal line direction (theta) _near . It is a block diagram which shows the control system by Embodiment 2 of this invention. It is a block diagram which shows the remote control apparatus 1 by Embodiment 3 of this invention. It is a hardware block diagram which shows the remote control apparatus 1 by Embodiment 3 of this invention. It is a flowchart which shows the process sequence in case the remote control apparatus 1 is implement | achieved by software or firmware.

  Hereinafter, in order to explain the present invention in more detail, modes for carrying out the present invention will be described with reference to the accompanying drawings.

Embodiment 1 FIG.
1 is a block diagram showing a control system according to Embodiment 1 of the present invention. FIG. 2 is a hardware configuration diagram showing the control system according to the first embodiment of the present invention.
FIG. 3 is a perspective view showing a remote control device according to Embodiment 1 of the present invention.
1 to 3, the remote operation device 1 outputs a remote controller that outputs identification information indicating a surface in which a normal direction toward the outside of the housing 11 corresponds to a setting direction among a plurality of surfaces in a polyhedron. It is.
As shown in FIG. 3, the casing 11 of the remote operation device 1 is a polyhedron having a plurality of surfaces.
In the example of FIG. 3, since the polyhedron is a cube, the housing 11 has six surfaces 11a to 11f. Note that the surface 11a and the surface 11f face each other, the surface 11b and the surface 11d face each other, and the surface 11c and the surface 11e face each other.
Although FIG. 3 shows an example in which the polyhedron is a cube, the present invention is not limited to this. For example, as shown in FIG. 4, a polyhedron other than a cube may be used.
4A is a perspective view showing an example in which the polyhedron is a regular octahedron, FIG. 4B is a perspective view showing an example in which the polyhedron is a regular dodecahedron, and FIG. 4C is a polyhedron that is a regular icosahedron. It is a perspective view which shows an example.

The surface detection unit 12 includes an inclination detection unit 13 and a surface detection processing unit 14.
The inclination detection unit 13 of the surface detection unit 12 is realized by an inclination detection sensor 31 including a triaxial gyroscope and a triaxial acceleration sensor, for example.
The tilt detection unit 13 detects the tilt of the housing 11 from the measurement result of the triaxial gyroscope and the measurement result of the triaxial acceleration sensor in the tilt detection sensor 31.
The surface detection processing unit 14 of the surface detection unit 12 is realized by, for example, the surface detection processing circuit 32 illustrated in FIG.
The surface detection processing unit 14 is a surface in which the normal direction toward the outside of the housing 11 corresponds to the setting direction among the plurality of surfaces in the polyhedron from the tilt of the housing 11 detected by the tilt detection unit 13. Execute the process to detect.
In the first embodiment, for example, a vertical direction facing upward with respect to a horizontal surface such as a table on which the housing 11 is placed is set in advance in the surface detection processing unit 14 as a setting direction. To do.

The identification information output unit 15 is realized by, for example, the identification information output circuit 33 shown in FIG.
The identification information output unit 15 performs a process of outputting identification information indicating the surface detected by the surface detection processing unit 14 of the surface detection unit 12 to the control device 2.
The display processing unit 16 is realized by, for example, the display processing circuit 34 illustrated in FIG.
When the inclination detection unit 13 of the surface detection unit 12 detects that the inclination of the housing 11 has changed, the display processing unit 16 lights all the surfaces in the polyhedron.
After the display processing unit 16 turns on all the surfaces in the polyhedron and the surface detection processing unit 14 detects a surface whose normal direction corresponds to the setting direction, only the surface corresponding to the setting direction is displayed. Continue lighting and turn off the surface that does not correspond to the set direction.

The control device 2 includes a mobile terminal 3 and a server 4.
The mobile terminal 3 corresponds to a terminal such as a smartphone, a tablet terminal, or a mobile computer.
The mobile terminal 3 includes a setting reception unit 17 and a control processing unit 19.
The setting reception unit 17 of the mobile terminal 3 is realized by, for example, a setting reception circuit 35 illustrated in FIG.
The setting accepting unit 17 performs a process of accepting settings of control contents of a plurality of control target devices 5-n (n = 1, 2,..., N) corresponding to each surface in the polyhedron, and sets each of them. Are stored in the control content storage unit 18 of the server 4.

The server 4 includes a control content storage unit 18, a control signal transmission unit 20, and an interface unit 21.
The control content storage unit 18 of the server 4 is realized by, for example, the storage circuit 36 shown in FIG.
The control content storage unit 18 stores the control content of the plurality of control target devices 5-n corresponding to each surface in the polyhedron as the control content whose setting is received by the setting reception unit 17, respectively.

The control processing unit 19 of the portable terminal 3 is realized by, for example, the control processing circuit 37 illustrated in FIG.
The control processing unit 19 includes identification information output from the identification information output unit 15 of the remote operation device 1 from among the control contents of the plurality of control target devices 5-n stored in the control content storage unit 18 of the server 4. The control content of the plurality of control target devices 5-n corresponding to the surface indicated by “” is acquired, and the process of outputting the acquired control content to the control signal transmission unit 20 of the server 4 is performed.
The control signal transmission unit 20 of the server 4 is realized by, for example, the control signal transmission circuit 38 illustrated in FIG.
The control signal transmission unit 20 performs a process of outputting, to the interface unit 21, a control signal for realizing the control content of the plurality of control target devices 5-n output from the control processing unit 19 of the mobile terminal 3.

The interface unit 21 of the server 4 is realized by, for example, an interface circuit 39 shown in FIG.
For example, when the server 4 and the plurality of devices to be controlled 5-n are connected by a wireless LAN (Local Area Network), the interface unit 21 is realized by an interface circuit for the wireless LAN.
When the server 4 and the plurality of devices to be controlled 5-n are connected by Bluetooth (Bluetooth / registered trademark, hereinafter omitted), which is one of short-range wireless communication standards for digital devices, the interface unit 21 It is realized with an interface circuit for Bluetooth.
The interface unit 21 transmits the control signal output from the control signal transmission unit 20 to the plurality of control target devices 5-n.
The plurality of control target devices 5-n are devices controlled by the control system, and correspond to, for example, an air conditioner, a lighting fixture, an aroma diffuser, and a music player.

In FIG. 1, the tilt detection unit 13, the surface detection processing unit 14, the identification information output unit 15, the display processing unit 16, the setting reception unit 17, the control content storage unit 18, the control processing unit 19, the control, which are components of the control system. It is assumed that each of the signal transmission unit 20 and the interface unit 21 is realized by dedicated hardware as shown in FIG.
That is, it is realized by the tilt detection sensor 31, the surface detection processing circuit 32, the identification information output circuit 33, the display processing circuit 34, the setting reception circuit 35, the storage circuit 36, the control processing circuit 37, the control signal transmission circuit 38, and the interface circuit 39. Is assumed.

Here, the memory circuit 36 includes a RAM (Random Access Memory), a ROM (Read Only Memory), a flash memory, an EPROM (Erasable Programmable Read Only Memory), an EEPROM (Electrically Erasable Programmable Memory), and the like. And a semiconductor memory, a magnetic disk, a flexible disk, an optical disk, a compact disk, a mini disk, or a DVD (Digital Versatile Disc).
The surface detection processing circuit 32, the identification information output circuit 33, the display processing circuit 34, the setting reception circuit 35, the control processing circuit 37, the control signal transmission circuit 38, and the interface circuit 39 are, for example, a single circuit, a composite circuit, a program An integrated processor, a parallel-programmed processor, an ASIC (Application Specific Integrated Circuit), an FPGA (Field-Programmable Gate Array), or a combination of these is applicable.

The components of the control system are not limited to those realized by dedicated hardware, and the control system may be realized by software, firmware, or a combination of software and firmware.
Software or firmware is stored as a program in the memory of a computer. The computer means hardware that executes a program, for example, a CPU (Central Processing Unit), a central processing unit, a processing unit, a processing unit, a microprocessor, a microcomputer, a processor, or a DSP (Digital Signal Processor) To do.

FIG. 5 is a hardware configuration diagram of a computer when the control system is realized by software or firmware.
When the control system is realized by software or firmware, the control content storage unit 18 is configured on the memory 41 of the computer, and the tilt detection unit 13, the surface detection processing unit 14, the identification information output unit 15, and the display processing unit 16. , A program for causing the computer to execute processing procedures of the setting reception unit 17, the control processing unit 19, the control signal transmission unit 20, and the interface unit 21 is stored in the memory 41, and the processor 42 of the computer is stored in the memory 41. The program should be executed.
FIG. 6 is a flowchart showing a processing procedure when the control system is realized by software or firmware.

  2 shows an example in which each component of the control system is realized by dedicated hardware, and FIG. 5 shows an example in which the control system is realized by software or firmware. Some components may be realized by dedicated hardware, and the remaining components may be realized by software or firmware.

Next, the operation will be described.
First, the surface detection processing unit 14 of the surface detection unit 12 is given a setting direction θ _est for selecting one of the six surfaces 11 a to 11 f of the housing 11.
FIG. 7 is an explanatory diagram showing a setting direction θ _est for selecting one surface from the six surfaces 11a to 11f of the housing 11.
In the example of FIG. 7, the + z direction that is perpendicular to the horizontal plane of the table or the like on which the housing 11 is placed is set as the setting direction θ _est .
When the + z direction is set as the setting direction θ _est , the details will be described later. For example, if the casing 11 is placed on the table in the orientation shown in FIG. 3, the six surfaces 11 a to 11 f The surface 11a whose normal direction is the + z direction is selected from the inside.
In the example of FIG. 3, the normal direction theta _b with respect to the normal direction theta _a is + z direction, surface 11b relative to the surface 11a of the housing 11 -x direction, the normal direction theta _c with respect to the surface 11c is -y direction.
The normal direction θ _d with respect to the surface 11 _d is the + x direction, the normal direction θ _e with respect to the surface 11 _e is the + y direction, and the normal direction θ _{f with} respect to the surface 11 _f is the −z direction.

For example, a life scene is assigned to the six surfaces 11a to 11f of the housing 11.
In the example of FIG. 3, “wake” is assigned to the face 11a as a life scene, “sleep” is assigned to the face 11b, and “relax” is assigned to the face 11c as a life scene. It has been.
Although not shown in FIG. 3, for example, “energize” is assigned to the face 11d as a life scene, “away” is assigned to the face 11e as a life scene, and the life scene is assigned to the face 11f. “Custom” is assigned.
FIG. 8 is an explanatory diagram showing an example of a life scene.
8A shows a life scene of “wake”, FIG. 8B shows a life scene of “sleep”, and FIG. 8C shows a life scene of “relax”.

Further, in the control content storage unit 18 of the server 4, a plurality of control contents whose settings are received by the setting reception unit 17 of the mobile terminal 3, corresponding to the six surfaces 11 a to 11 f of the housing 11. The control contents of the control target device 5-n are stored.
FIG. 9 is an explanatory diagram illustrating an example of control contents of the plurality of control target devices 5-n corresponding to the six surfaces 11a to 11f of the housing 11. As illustrated in FIG.
FIG. 9 shows an example in which five control target devices are controlled. The control target device 5-1 is an air conditioner, the control target device 5-2 is a bedroom lighting fixture, and the control target device 5-3 is a living room lighting. The appliance, the control target device 5-4 is an aroma diffuser, and the control target device 5-5 is a music player.

In FIG. 9, “ON” indicates that the control target device operates, and “OFF” indicates that the control target device does not operate.
In addition to the operation mode suitable for a good sleep, the operation mode of the air conditioner includes an operation mode in which wind is sent in the direction in which a human is present, but in FIG. , C, D.
Further, when the music player is ON, it is possible to reproduce “bird chirping” suitable for waking up, “healing” suitable for relaxing, etc. In FIG. 9, for ease of explanation, music reproduction E , F, and G.
“-” Indicates that the operation of the control target device is not set, and is handled in the same manner as “OFF”, for example.

FIG. 10 is an explanatory diagram illustrating an example of a control content setting screen by the setting reception unit 17 of the mobile terminal 3.
FIG. 10 shows a control content setting screen when the life scene is “wake”, and this setting screen is displayed on the display of the mobile terminal 3.
The user can set the control contents of the plurality of control target devices 5-n on the setting screen.
The setting receiving unit 17 receives the setting of the control contents of the plurality of control target devices 5-n and stores the control contents of the plurality of control target devices 5-n in the control content storage unit 18 of the server 4.
Since the process itself for receiving the setting of the control content by the setting receiving unit 17 is a known technique, detailed description thereof is omitted.

Hereinafter, the operation of the control system will be described with reference to FIG.
The inclination detection unit 13 of the surface detection unit 12 incorporates an inclination detection sensor 31, and the inclination detection sensor 31 detects the inclination of the housing 11 (step ST1 in FIG. 6).
As a format of data indicating the tilt of the housing 11 detected by the tilt detection sensor 31, various formats are conceivable.
In the first embodiment, a case will be described in which, for example, data indicating the normal directions θ _{a to} θ f with respect to the surfaces 11 a to 11 _f are obtained as data indicating the inclination of the housing 11.
Since the shape of the housing 11 is known, for example, as long obtain data indicating normal direction theta _a relative surface 11a, it is possible to specify the normal direction theta _b through? _F with respect to the plane 11B～11f. Therefore, it may be assumed that only the data indicating the normal direction theta _a to the surface 11a is obtained.

FIG. 11 is an explanatory diagram showing a state in which the user lifts the remote control device 1 in order to switch the life scene.
For example, the remote operation device 1 placed on the table is lifted by the user, whereby the inclination of the casing 11 in the remote operation device 1 changes.
Each time the tilt detection sensor 31 detects the tilt of the casing 11, the tilt detection unit 13 uses the normal direction to the surfaces 11 a to 11 f as the latest data indicating the tilt of the casing 11 detected by the tilt detection sensor 31. The latest data indicating θ _{a to} θ _f is output to the surface detection processing unit 14.
If the inclination of the casing 11 detected this time by the inclination detection sensor 31 is different from the inclination of the casing 11 detected last time by the inclination detection sensor 31 (step ST2 in FIG. 6: YES). ), The surface detection processing unit 14 and the display processing unit 16 are notified that the inclination of the housing 11 has changed.
If the inclination of the casing 11 detected this time by the inclination detection sensor 31 is the same as the inclination of the casing 11 previously detected by the inclination detection sensor 31 (step ST2 in FIG. 6: NO). ), A notification that the inclination of the housing 11 has changed is not output to the surface detection processing unit 14 and the display processing unit 16. The tilt detection unit 13 continues the process of detecting the tilt of the housing 11 (step ST1 in FIG. 6).

When the display processing unit 16 receives notification from the tilt detection unit 13 that the tilt of the housing 11 has changed, as shown in FIG. 11, all of the six surfaces 11 a to 11 f of the housing 11 are displayed. Lights up (step ST3 in FIG. 6).
When the surface detection processing unit 14 receives notification from the tilt detection unit 13 that the tilt of the housing 11 has changed, the tilt detection unit 13 displays the latest data indicating the normal directions θ _{a to} θ f with respect to the surfaces 11 a to 11 _f. Is output, the latest data output from the inclination detector 13 is acquired (step ST4 in FIG. 6).
The surface detection processing unit 14 compares the normal direction θa at _a plurality of times with respect to the surface 11a output from the tilt detection unit 13 to determine whether or not the tilt of the housing 11 is stable (see FIG. 6 step ST5). If the normal direction θa at _a plurality of times becomes the same, the surface detection processing unit 14 determines that the inclination of the housing 11 is stable.
If the user lifts the remote control device 1 and places the remote control device 1 on the table, the inclination of the housing 11 is stabilized.
Here, the surface detection processing unit 14 determines whether or not the inclination of the housing 11 is stable by comparing the normal direction θa at _a plurality of times with respect to the surface 11a. by comparing the normal direction theta _b at a plurality of times for 11b, the inclination of the housing 11 may determine whether the stable.

If the surface detection processing unit 14 determines that the inclination of the housing 11 is stable (step ST5 in FIG. 6: YES), the surface detection processing unit 14 applies to the surfaces 11a to 11f indicated by the latest data output from the inclination detection unit 13. by comparing respectively the normal direction θ _a ~θ _f, and a setting direction theta _est, in the normal direction theta _a through? _f with respect to the surface 11a to 11f, nearest the normal direction to the setting direction theta _est θ _near is specified (step ST6 in FIG. 6).
If the surface detection processing unit 14 determines that the inclination of the housing 11 is not stable (step ST5 in FIG. 6: NO), the surface detection processing unit 14 returns to the processing of step ST4, and normal direction θ _a to the surfaces 11a to 11f. The latest data indicating θ _f is re-acquired, and the processes of steps ST4 to ST5 are repeated.

Face detection processing unit 14 has determined the closest normal direction theta _near the setting direction theta _est, the direction deviation Δθ of the specified normal direction theta _near the setting direction _{θ est (= θ near -θ est} ), It is determined whether or not it is within a preset allowable range Δθ _th (step ST7 in FIG. 6).
As the allowable range Δθ _th , 10 degrees, 15 degrees, 20 degrees, 25 degrees, 30 degrees, or the like is set.

If the direction deviation Δθ is larger than the allowable range Δθ _th (step ST7: NO in FIG. 6), the surface detection processing unit 14 returns to the process of step ST4, and normal directions θ _{a to} θ with respect to the surfaces 11a to 11f. _The latest data indicating _f is re-acquired, and the processes of steps ST4 to ST7 are repeated.
If the direction deviation Δθ is within the allowable range Δθ _th (step ST7 in FIG. 6: YES), the surface detection processing unit 14 has a surface corresponding to the specified normal direction θ _near different from the previously selected surface. It is determined whether it is a surface (step ST8 in FIG. 6).
The casing 11 of the remote operation device 1 is a cube, and the setting direction θ _est is the + z direction. For example, when the remote operation device 1 is placed on a table before being lifted by the user, the surface selected last time Is the upper surface of the housing 11.
For example, if the surface corresponding to the specified normal direction θ _near is the surface 11b and the previously selected surface is the surface 11a, the surface corresponding to the specified normal direction θ _near is determined by the surface detection processing unit 14. It is determined that the surface is different from the previously selected surface.
If the surface corresponding to the specified normal direction θ _near is the surface 11a, and the previously selected surface is the surface 11a, the surface corresponding to the specified normal direction θ _near is determined by the surface detection processing unit 14. It is determined that the surface is the same as the previously selected surface.

If the surface detection processing unit 14 determines that the surface corresponding to the specified normal direction θ _near is a surface different from the previously selected surface (in the case of YES in step ST8 in FIG. 6), the surface detection processing unit 14 corresponds to the setting direction θ _est. The surface corresponding to the specified normal direction θ _near is notified to each of the identification information output unit 15 and the display processing unit 16.
When the display processing unit 16 receives the notification of the surface corresponding to the specified normal direction θ _near from the surface detection processing unit 14, as shown in FIG. 12, only the surface corresponding to the normal direction θ _near is turned on. _Subsequently , the surface not corresponding to the normal direction θ _near is turned off (step ST9 in FIG. 6).
FIG. 12 is an explanatory diagram showing a state where only the surface corresponding to the normal direction θ _near is lit.
In the example of FIG. 12, the surface corresponding to the normal direction θ _near is the surface 11c, and only the surface 11c to which “relax” is assigned as the life scene is lit. Surfaces 11a, 11b, and 11d to 11f other than the surface 11c are turned off.

When receiving the notification of the surface corresponding to the normal direction θ _near from the surface detection processing unit 14, the identification information output unit 15 sends the identification information indicating the surface corresponding to the normal direction θ _near to the mobile terminal 3 of the control device 2. Output (step ST10 in FIG. 6).
The control processing unit 19 of the mobile terminal 3 outputs from the identification information output unit 15 of the remote operation device 1 from among the control contents of the plurality of control target devices 5-n stored in the control content storage unit 18 of the server 4. The control content of the plurality of control target devices 5-n corresponding to the surface indicated by the identification information thus obtained is acquired (step ST11 in FIG. 6).

When the control content of the plurality of control target devices 5-n stored in the control content storage unit 18 is the control content as shown in FIG. 9, for example, the surface corresponding to the normal direction θ _near may be the surface 11c. For example, the control processing unit 19 acquires the following control content as the control content of the plurality of control target devices 5-n.
Control target device 5-1 → ON (operation mode C)
Control target device 5-2 →-
Control target device 5-3 → ON
Control target device 5-4 → ON
Control target device 5-5 → ON (audio playback F)

The control processing unit 19 outputs the acquired control content to the control signal transmission unit 20 of the server 4.
The control signal transmission unit 20 of the server 4 outputs to the interface unit 21 a control signal for realizing the control contents of the plurality of control target devices 5-n output from the control processing unit 19.
The interface unit 21 of the server 4 transmits the control signal output from the control signal transmission unit 20 to the plurality of control target devices 5-n (step ST12 in FIG. 6).
The plurality of control target devices 5-n receive a control signal transmitted from the interface unit 21 of the server 4 and operate according to the received control signal.

If the surface detection processing unit 14 determines that the surface corresponding to the specified normal direction θ _near is the same surface as the previously selected surface (in the case of step ST8: NO in FIG. 6), the same surface as the previous one is selected. This is notified to the display processing unit 16.
Upon receiving notification from the surface detection processing unit 14 that the same surface as the previous one has been selected, the display processing unit 16 turns off all the six surfaces 11a to 11f (step ST13 in FIG. 6).
In the first embodiment, when the surface corresponding to the specified normal direction θ _near is the same surface as the previously selected surface, the display processing unit 16 turns off all the six surfaces 11a to 11f. Although shown, it is not limited to this. For example, similarly to the case where the surface is different from the previously selected surface, the processes of steps ST9 to ST12 may be performed.

As apparent from the above, according to the first embodiment, among the plurality of faces in the polyhedron, the identification information indicating the face in which the normal direction toward the outside of the housing 11 corresponds to the set direction is output. Remote control device 1 is provided, and the control device 2 stores the control contents of a plurality of control target devices 5-n corresponding to each surface in the polyhedron, and a plurality corresponding to each stored surface. Of the control target devices 5-n, based on the control details of the plurality of control target devices 5-n corresponding to the surface indicated by the identification information output from the remote operation device 1. Since it is configured to control -n, there is an effect that a plurality of control target devices 5-n can be controlled collectively without preparing a plurality of sensing units.
In the first embodiment, since a plurality of control target devices 5-n can be controlled collectively, the number of operations can be reduced and operability is improved as compared with the case of operating each control target device. .
Further, since it is not necessary to arrange a switch such as a button on the surface of the housing 11 of the remote operation device 1, the remote operation device 1 having a simple design can be constructed.

In the first embodiment, when the direction deviation Δθ is larger than the allowable range Δθ _th (in the case of step ST7: NO in FIG. 6), the example returns to the process of step ST4.
Before returning to the process of step ST4, the surface detection processing unit 14 has reached a preset lighting time after the display processing unit 16 has lit all six surfaces 11a to 11f. Only when the elapsed time has not reached the lighting time, the process may return to step ST4.
When the surface detection processing unit 14 determines that the elapsed time has reached the lighting time, the display processing unit 16 turns off all the six surfaces 11a to 11f. Further, the control system ends the process shown in FIG.

Embodiment 2. FIG.
In the said Embodiment 1, the server 4 has shown the example which mounts the control content memory | storage part 18 which has memorize | stored the control content of several control object apparatus 5-n.
The device in which the control content storage unit 18 is mounted is not limited to the server 4, and the mobile terminal 3 may be a device in which the control content storage unit 18 is mounted as shown in FIG. 13.
FIG. 13 is a block diagram showing a control system according to Embodiment 2 of the present invention. 13, the same reference numerals as those in FIG. 1 denote the same or corresponding parts.
The operation of the control system itself is the same as that of the first embodiment except that the apparatus in which the control content storage unit 18 is mounted is different from that of the first embodiment.

Embodiment 3 FIG.
In the said Embodiment 1, the example which the control apparatus 2 controls several control object apparatus 5-n is shown.
In the third embodiment, an example in which the remote operation device 1 controls a plurality of control target devices 5-n will be described.
FIG. 14 is a block diagram showing a remote control device 1 according to Embodiment 3 of the present invention. FIG. 15 is a hardware configuration diagram showing the remote control device 1 according to the third embodiment of the present invention.
14 and 15, the same reference numerals as those in FIGS. 1 and 2 indicate the same or corresponding parts, and thus description thereof is omitted.

The setting reception unit 51 is realized by, for example, a setting reception circuit 61 illustrated in FIG.
The setting receiving unit 51 performs a process of receiving setting of control contents of a plurality of control target devices 5-n (n = 1, 2,..., N) corresponding to each surface in the polyhedron, and sets each of them. The control contents of the plurality of control target devices 5-n corresponding to the respective surfaces that have been received are stored in the control content storage unit 52.
The control content storage unit 52 is realized by, for example, the storage circuit 62 shown in FIG.
The control content storage unit 52 stores the control content of the plurality of control target devices 5-n corresponding to each surface in the polyhedron as the control content whose setting is received by the setting reception unit 51, respectively.

The device control unit 53 includes a control processing unit 54, a control signal transmission unit 55, and an interface unit 56.
The device control unit 53 includes a plurality of control contents corresponding to the surfaces detected by the surface detection processing unit 14 of the surface detection unit 12 among the control contents of the plurality of control target devices 5-n stored in the control content storage unit 52. A plurality of control target devices 5-n are controlled based on the control content of the control target device 5-n.

The control processing unit 54 of the device control unit 53 is realized by, for example, a control processing circuit 63 illustrated in FIG.
The control processing unit 54 includes a plurality of control contents corresponding to the surfaces detected by the surface detection processing unit 14 of the surface detection unit 12 among the control contents of the plurality of control target devices 5-n stored in the control content storage unit 52. The control content of the control target device 5-n is acquired, and the process of outputting the acquired control content to the control signal transmission unit 55 is performed.
The control signal transmission unit 55 is realized by, for example, a control signal transmission circuit 64 illustrated in FIG.
The control signal transmission unit 55 performs a process of outputting, to the interface unit 56, a control signal for realizing the control contents of the plurality of control target devices 5-n output from the control processing unit 54.

The interface unit 56 is realized by, for example, an interface circuit 65 shown in FIG.
For example, when the remote operation device 1 and the plurality of control target devices 5-n are connected by a wireless LAN, the interface unit 56 is realized by an interface circuit for the wireless LAN.
When the remote operation device 1 and the plurality of control target devices 5-n are connected via Bluetooth, the interface unit 56 is realized by an interface circuit for Bluetooth.
The interface unit 56 transmits the control signal output from the control signal transmission unit 55 to the plurality of control target devices 5-n.

In FIG. 14, the tilt detection unit 13, the surface detection processing unit 14, the display processing unit 16, the setting reception unit 51, the control content storage unit 52, the control processing unit 54, and the control signal transmission unit 55 that are components of the remote operation device 1. Each of the interface unit 56 is assumed to be realized by dedicated hardware as shown in FIG.
That is, it is realized by the tilt detection sensor 31, the surface detection processing circuit 32, the identification information output circuit 33, the display processing circuit 34, the setting reception circuit 61, the storage circuit 62, the control processing circuit 63, the control signal transmission circuit 64, and the interface circuit 65. Is assumed.

Here, the storage circuit 62 corresponds to a nonvolatile or volatile semiconductor memory such as RAM, ROM, flash memory, EPROM, or EEPROM, a magnetic disk, a flexible disk, an optical disk, a compact disk, a mini disk, or a DVD.
The surface detection processing circuit 32, the identification information output circuit 33, the display processing circuit 34, the setting reception circuit 61, the control processing circuit 63, the control signal transmission circuit 64, and the interface circuit 65 are, for example, a single circuit, a composite circuit, a program An integrated processor, a parallel-programmed processor, an ASIC, an FPGA, or a combination thereof is applicable.

The components of the remote operation device 1 are not limited to those realized by dedicated hardware, and the remote operation device 1 may be realized by software, firmware, or a combination of software and firmware. Good.
When the remote operation device 1 is realized by software or firmware, the control content storage unit 52 is configured on the memory 41 of the computer shown in FIG. 5, and the tilt detection unit 13, the surface detection processing unit 14, and the display processing unit 16. , A program for causing the computer to execute processing procedures of the setting reception unit 51, the control processing unit 54, the control signal transmission unit 55, and the interface unit 56 is stored in the memory 41, and the processor 42 of the computer is stored in the memory 41. The program should be executed.
FIG. 16 is a flowchart showing a processing procedure when the remote operation device 1 is realized by software, firmware, or the like.

  FIG. 15 shows an example in which each component of the remote operation device 1 is realized by dedicated hardware, and FIG. 5 shows an example in which the remote operation device 1 is realized by software or firmware. However, some components in the remote operation device 1 may be realized by dedicated hardware, and the remaining components may be realized by software or firmware.

Next, the operation will be described.
First, the surface detection processing unit 14 of the surface detection unit 12 is for selecting one surface from the six surfaces 11a to 11f of the housing 11 as in the first embodiment. A set direction θ _est is given.

Similarly to the setting receiving unit 17 illustrated in FIG. 1, the setting receiving unit 51 receives the setting of the control content of the plurality of control target devices 5-n, and the control content of the plurality of control target devices 5-n. Store in the storage unit 52.
As a result, the control content storage unit 52 has the casing 11 as the control content whose settings are received by the setting reception unit 51, similarly to the control content storage unit 18 of the server 4 shown in FIG. The control contents of the plurality of control target devices 5-n corresponding to the six surfaces 11a to 11f are stored.

Hereinafter, the operation of the remote control device 1 will be described with reference to FIG.
The inclination detection unit 13 of the surface detection unit 12 incorporates an inclination detection sensor 31, and the inclination detection sensor 31 detects the inclination of the housing 11 (step ST21 in FIG. 16).
As a format of data indicating the tilt of the housing 11 detected by the tilt detection sensor 31, various formats are conceivable.
In the third embodiment, as in the first embodiment, as data indicating the inclination of the housing 11, for example, the case where data indicating the normal direction theta _a through? _F with respect to the surface 11a~11f obtain respectively explain.

As in the first embodiment, the tilt detection unit 13 is the latest data indicating the tilt of the casing 11 detected by the tilt detection sensor 31 every time the tilt detection sensor 31 detects the tilt of the casing 11. The latest data indicating the normal directions θ _{a to} θ f with respect to the surfaces 11 _{a to} 11 _f are output to the surface detection processing unit 14.
If the inclination of the casing 11 detected this time by the inclination detection sensor 31 is different from the inclination of the casing 11 detected last time by the inclination detection sensor 31 (step ST22 in FIG. 16: YES). ), The surface detection processing unit 14 and the display processing unit 16 are notified that the inclination of the housing 11 has changed.
If the inclination of the casing 11 detected this time by the inclination detection sensor 31 is the same as the inclination of the casing 11 detected last time by the inclination detection sensor 31 (step ST22: NO in FIG. 16). ), A notification that the inclination of the housing 11 has changed is not output to the surface detection processing unit 14 and the display processing unit 16. The tilt detection unit 13 continues the process of detecting the tilt of the housing 11 (step ST21 in FIG. 16).

When the display processing unit 16 receives a notification from the tilt detection unit 13 that the tilt of the housing 11 has changed, the display processing unit 16 displays the six surfaces 11a to 11f of the housing 11 as in the first embodiment. All are turned on (step ST23 in FIG. 16).
When the surface detection processing unit 14 receives a notification that the tilt of the housing 11 has changed from the tilt detection unit 13, the tilt detection unit 13 performs the normal direction θ with respect to the surfaces 11 a to 11 f as in the first embodiment. each for outputting the latest data indicating _a through? _f, to get the latest data output from the inclination detecting unit 13 (step ST24 in FIG. 16).
Similar to the first embodiment, the surface detection processing unit 14 compares the normal directions θa at _a plurality of times with respect to the surface 11a output from the tilt detection unit 13, thereby stabilizing the tilt of the housing 11. It is determined whether or not (step ST25 in FIG. 16).

If the surface detection processing unit 14 determines that the inclination of the housing 11 is stable (in the case of step ST25: YES in FIG. 16), the latest output from the inclination detection unit 13 as in the first embodiment. By comparing each of the normal directions θ _{a to} θ f with respect to the surfaces 11 _{a to} 11 _f indicated by the data, and the set direction θ _est , the normal directions θ _{a to} θ f with respect to the surfaces 11 _{a to} 11 _f are set. The normal direction θ _near closest to the direction θ _est is specified (step ST26 in FIG. 16).
If the surface detection processing unit 14 determines that the inclination of the housing 11 is not stable (step ST25 in FIG. 16: NO), the surface detection processing unit 14 returns to the processing of step ST24 and normal direction θ _a to the surfaces 11a to 11f. The latest data indicating θ _f is obtained again, and the processes of steps ST24 to ST25 are repeated.

Face detection processing unit 14 has determined the closest normal direction theta _near the setting direction theta _est, the direction deviation Δθ of the specified normal direction theta _near the setting direction _{θ est (= θ near -θ est} ), It is determined whether it is within the preset allowable range Δθ _th (step ST27 in FIG. 16).
If the direction deviation Δθ is larger than the allowable range Δθ _th (step ST27 in FIG. 16: NO), the surface detection processing unit 14 returns to the process of step ST24, and normal directions θ _{a to} θ with respect to the surfaces 11a to 11f. _The latest data indicating _f is re-acquired, and the processes of steps ST24 to ST27 are repeated.

If the direction deviation Δθ is within the allowable range Δθ _th (step ST27 in FIG. 16: YES), the surface detection processing unit 14 has a surface corresponding to the specified normal direction θ _near different from the previously selected surface. It is determined whether or not it is a surface (step ST28 in FIG. 16).
For example, if the surface corresponding to the specified normal direction θ _near is the surface 11b and the previously selected surface is the surface 11a, the surface corresponding to the specified normal direction θ _near is determined by the surface detection processing unit 14. It is determined that the surface is different from the previously selected surface.
If the surface corresponding to the specified normal direction θ _near is the surface 11a, and the previously selected surface is the surface 11a, the surface corresponding to the specified normal direction θ _near is determined by the surface detection processing unit 14. It is determined that the surface is the same as the previously selected surface.

When the surface detection processing unit 14 determines that the surface corresponding to the specified normal direction θ _near is a surface different from the previously selected surface (in the case of YES in step ST28 in FIG. 16), the surface detection processing unit 14 corresponds to the setting direction θ _est. The surface corresponding to the specified normal direction θ _near is notified to each of the control processing unit 54 and the display processing unit 16 of the device control unit 53.
When the display processing unit 16 receives a notification of the surface corresponding to the specified normal direction θ _near from the surface detection processing unit 14, as in the first embodiment, only the surface corresponding to the normal direction θ _near is displayed. The lighting is continued and the surface not corresponding to the normal direction θ _near is extinguished (step ST29 in FIG. 16).

When the control processing unit 54 of the device control unit 53 receives a notification of the surface corresponding to the normal direction θ _near from the surface detection processing unit 14, the control processing unit 54 stores a plurality of control target devices 5-stored in the control content storage unit 52. The control details of a plurality of control target devices 5-n corresponding to the notified surface are acquired from the control details of n (step ST30 in FIG. 16).

When the control content of the plurality of control target devices 5-n stored in the control content storage unit 52 is the control content as shown in FIG. 9, for example, the surface corresponding to the normal direction θ _near may be the surface 11b. For example, the control processing unit 54 acquires the following control contents as the control contents of the plurality of control target devices 5-n.
Control target device 5-1 → ON (operation mode B)
Control target device 5-2 → OFF
Control target device 5-3 → OFF
Control target device 5-4 →-
Control target device 5-5 → OFF

The control processing unit 54 outputs the acquired control content to the control signal transmission unit 55.
The control signal transmission unit 55 outputs a control signal for realizing the control contents of the plurality of control target devices 5-n output from the control processing unit 54 to the interface unit 56.
The interface unit 56 transmits the control signal output from the control signal transmission unit 55 to the plurality of control target devices 5-n (step ST31 in FIG. 16).
The plurality of control target devices 5-n receive the control signal transmitted from the interface unit 56 of the remote operation device 1, and operate according to the received control signal.

If the surface detection processing unit 14 determines that the surface corresponding to the specified normal direction θ _near is the same surface as the previously selected surface (in the case of step ST28 in FIG. 16: NO), the same surface as the previous one is selected. This is notified to the display processing unit 16.
Upon receiving notification from the surface detection processing unit 14 that the same surface as the previous one has been selected, the display processing unit 16 turns off all the six surfaces 11a to 11f (step ST32 in FIG. 16).
In the third embodiment, when the surface corresponding to the specified normal direction θ _near is the same surface as the previously selected surface, the display processing unit 16 turns off all the six surfaces 11a to 11f. Although shown, it is not limited to this. For example, similarly to the case where the surface is different from the previously selected surface, the processes of steps ST29 to ST31 may be performed.

As is apparent from the above, according to the third embodiment, the casing 11 of a polyhedron having a plurality of faces and the casing of the plurality of faces in the polyhedron are detected by detecting the inclination of the casing 11. 11 includes a surface detection unit 12 that detects a surface corresponding to a normal direction toward the outside of the control unit 11, and a control content that stores control content of a plurality of control target devices 5-n that correspond to each surface in the polyhedron. A storage unit 52 is provided, and the device control unit 53 corresponds to the surface detected by the surface detection unit 12 among the control contents of the plurality of control target devices 5-n stored in the control content storage unit 52. Since the plurality of control target devices 5-n are controlled based on the control content of the control target device 5-n, the plurality of control target devices 5-n are prepared without preparing a plurality of sensing units. It can be controlled collectively It achieves the effect that.
In the third embodiment, since a plurality of control target devices 5-n can be controlled collectively, the number of operations can be reduced and operability is improved as compared with the case of operating each control target device. .
Further, since it is not necessary to arrange a switch such as a button on the surface of the housing 11 of the remote operation device 1, the remote operation device 1 having a simple design can be constructed.

The third embodiment shows an example in which the process returns to step ST24 when the direction deviation Δθ is larger than the allowable range Δθ _th (step ST27: NO in FIG. 16).
Before returning to the process of step ST24, the surface detection processing unit 14 has reached a preset lighting time after the display processing unit 16 has lit all six surfaces 11a to 11f. Only when the elapsed time has not reached the lighting time, the process may return to step ST24.
When the surface detection processing unit 14 determines that the elapsed time has reached the lighting time, the display processing unit 16 turns off all the six surfaces 11a to 11f. Further, the control system ends the process shown in FIG.

  In the present invention, within the scope of the invention, any combination of the embodiments, or any modification of any component in each embodiment, or omission of any component in each embodiment is possible. .

  The present invention is suitable for a control system including a remote control device having a polyhedral casing and a remote control device having a polyhedral casing.

  DESCRIPTION OF SYMBOLS 1 Remote operation apparatus, 2 Control apparatus, 3 Portable terminal, 4 Server, 5-n Control object apparatus, 11 housing | casing, 11a-11f surface, 12 surface detection part, 13 Tilt detection part, 14 surface detection process part, 15 identification Information output unit, 16 Display processing unit, 17 Setting reception unit, 18 Control content storage unit, 19 Control processing unit, 20 Control signal transmission unit, 21 Interface unit, 31 Tilt detection sensor, 32 Surface detection processing circuit, 33 Identification information output Circuit, 34 Display processing circuit, 35 Setting reception circuit, 36 Storage circuit, 37 Control processing circuit, 38 Control signal transmission circuit, 39 Interface circuit, 41 Memory, 42 Processor, 51 Setting reception unit, 52 Control content storage unit, 53 Device Control unit, 54 control processing unit, 55 control signal transmission unit, 56 interface unit, 61 setting reception circuit, 62 memory times , 63 control processing circuit, 64 a control signal transmission circuit, 65 an interface circuit.

Claims (2)

A polyhedral housing having a plurality of surfaces;
By detecting the inclination of the housing, a surface detection unit that detects a surface in which a normal direction toward the outside of the housing corresponds to a setting direction among a plurality of surfaces in the polyhedron,
A remote control device including an identification information output unit that outputs identification information indicating the surface detected by the surface detection unit;
The control contents of a plurality of control target devices corresponding to each surface in the polyhedron are stored, and among the control details of the plurality of control target devices corresponding to each of the stored surfaces, the remote operation device A control device that controls the plurality of control target devices based on the control contents of the plurality of control target devices corresponding to the surface indicated by the identification information output from the identification information output unit;
With
The controller is
A server storing the control contents of a plurality of control target devices corresponding to the respective faces of the polyhedron;
Among the control contents of the plurality of control target devices stored by the server, the control details of the plurality of control target devices corresponding to the surface indicated by the identification information output from the identification information output unit of the remote operation device and an end the end you get,
Wherein the server, before SL based on the control content acquired by the terminus, control system system shall be the controls said plurality of control target device. Before SL end end is provided with a setting receiving unit that receives the setting of the control contents of a plurality of control target devices corresponding to each face in the polyhedron, respectively,
The server control system according to claim 1, characterized in that each stores control contents of a plurality of control target device setting is accepted respectively by the setting accepting section before Symbol edge end.

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