JP2015142328A - Learning remote control device, self-traveling electronic apparatus with the same, and remote control learning method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a learning remote control device for preventing erroneous learning from being generated by receiving ambient infrared noise.SOLUTION: A learning remote control device includes: an input part for receiving a command from a user; an infrared receiving part for receiving an infrared signal; a signal learning part for analyzing the infrared signal and learning the signal pattern thereof; a signal storage part for holding the signal pattern; a notification part for notifying the user of predetermined information; and a control part for controlling the input part, the infrared receiving part, the signal learning part, the signal storage part and the notification part. When the input part receives a learning command of a remote controller, the controls part makes the infrared receiving part attempt the reception of an ambient infrared signal and when the infrared receiving part receives the infrared signal, the notification part notifies the user about the presence of infrared noise. If the infrared receiving part does not receive the infrared signal, the notification part notifies the user about transmission of a remote control signal desired to be learnt toward the infrared receiving part.

Description

  The present invention relates to a learning remote control device, a self-propelled electronic device including the same, and a remote control learning method.

  Conventionally, a learning remote control device is known that can receive an infrared signal transmitted from a remote control device, analyze a signal pattern of the received infrared signal, perform learning, and transmit the same infrared signal as the learned signal. Yes. In addition, since the learning remote control device can learn the infrared signals of the remote control devices of a plurality of devices such as an air conditioner and a television, the plurality of devices can also be operated with one learning remote control device.

  As an invention of such a learning remote control device, for example, it is possible to learn an infrared signal emitted from the remote control device, so that an infrared remote control for other companies and other uses can be obtained without preparing an infrared remote control for this portable information processing device. An invention of a portable information processing apparatus capable of remotely operating the portable information processing apparatus with a remote controller is known (see, for example, Patent Document 1).

  In addition to a portable learning remote control device, a stationary learning remote control device and a self-propelled learning remote control device are also known. Since the stationary learning remote control device can operate indoor home appliances from the learning remote control device via a communication terminal device such as a smartphone or a tablet terminal, the home appliances can be operated from a location outside the home via the communication terminal device. In addition, the self-propelled learning remote control device is known to have the learning remote control device mounted on the self-propelled electronic device, even if there are obstacles such as walls between the home appliances to be operated, The home appliance can be operated by running the self-propelled electronic device to a desired place in the room via the communication terminal device.

JP-A-2005-150878

  Here, as a remote control learning method of the portable learning remote control device, the infrared receiving unit of the learning remote control device and the infrared transmission unit of the remote control device to be learned are brought close to each other and the learning start button of the learning remote control device is In general, the infrared signal of the remote control device is learned by pressing a button of the remote control device to be learned after pressing.

However, as a remote control learning method for stationary and self-propelled learning remote control devices, a remote control learning method is used to bring the infrared receiver of the learning remote control device close to the remote control device to be learned, like a portable learning remote control device. Then, when the learning remote control device is on the floor surface, the user needs to approach the learning remote control device and bend down, which causes a heavy burden on the user.
On the other hand, if the infrared signal of the remote control device that the user wants to learn from a location remote from the learning remote control device is transmitted, there is a risk that infrared noise generated by sunlight, fluorescent lights, or other home appliances may be received by mistake . Although such infrared noise is difficult to be recognized by the user, it has been a problem because it causes erroneous learning of the learning remote controller.

  The present invention has been made in view of the above circumstances, and it is an object of the present invention to provide a learning remote control device and a remote control learning method that prevent in advance occurrence of erroneous learning due to reception of ambient infrared noise.

The present invention includes an input unit that receives a command from a user, an infrared receiving unit that receives an infrared signal, a signal learning unit that analyzes the infrared signal to learn its signal pattern, and a signal storage that holds the signal pattern And a control unit for controlling the input unit, the infrared receiving unit, the signal learning unit, the signal storage unit, and the notification unit, and a control unit that notifies a user of predetermined information. When the input unit receives a remote control learning command, the unit causes the infrared receiving unit to try to receive a surrounding infrared signal, and when the infrared receiving unit receives the infrared signal, the user has infrared noise. A remote control signal to be learned toward the infrared receiving unit when the infrared receiving unit has not received the infrared signal. There is provided a learning remote control device for notifying the notification unit to transmit to the user.
In addition, when receiving a remote control learning instruction, the present invention attempts to receive an ambient infrared signal, and when the ambient infrared signal is received, informs the user that infrared noise exists, If a remote control signal is not received, a remote control learning method for notifying a user to transmit a remote control signal to be learned is provided.

  According to this invention, the control unit causes the infrared receiving unit to try to receive a surrounding infrared signal when the input unit receives a remote control learning command, and the infrared receiving unit receives the infrared signal. In this case, a learning remote controller and a self-propelled electronic device including the learning remote controller that prevent the occurrence of erroneous learning due to reception of ambient infrared noise in advance by letting the user notify that the infrared noise is present to the user it can.

It is a block diagram which shows schematic structure of one Example of the control system of the self-propelled electronic device of this invention. (Embodiment 1) It is a perspective view of one Example of the self-propelled electronic device shown in FIG. (Embodiment 1) It is the top view and side view seen from 3 directions of one Example of the self-propelled electronic device shown in FIG. (Embodiment 1) It is sectional drawing of one Example of the self-propelled electronic device shown in FIG. (Embodiment 1) It is a top view of the bottom face of the self-propelled electronic device shown in FIG. (Embodiment 1) It is a perspective view of one Example of the infrared transmission / reception part of this invention. (Embodiment 1) It is a perspective view of one Example of the infrared transmission / reception part of this invention. (Embodiment 1) It is a flowchart of the remote control learning procedure of the conventional learning remote control apparatus. (Conventional technology) It is a flowchart of the remote control learning procedure of the learning remote control apparatus mounted in the self-propelled electronic device of this invention. (Embodiment 1) It is explanatory drawing of the remote control learning procedure of the conventional learning remote control apparatus. (Conventional technology) It is explanatory drawing of one Example of the remote control learning procedure of the learning remote control apparatus mounted in the self-propelled electronic device of this invention. (Embodiment 1) It is a flowchart of the remote control learning procedure of the learning remote control apparatus mounted in the self-propelled electronic device which concerns on Embodiment 2 of this invention. (Embodiment 2) It is explanatory drawing of one Example of the remote control learning procedure of the learning remote control apparatus mounted in the self-propelled electronic device of this invention. (Embodiment 2) It is a flowchart of the remote control learning procedure of the learning remote control device mounted in the self-propelled electronic device according to Embodiment 3 of the present invention. (Embodiment 3) It is explanatory drawing of one Example of the remote control learning procedure of the learning remote control apparatus mounted in the self-propelled electronic device of this invention. (Embodiment 3) It is explanatory drawing of one Example of the display part of the communication terminal device of this invention. (Embodiment 1) It is explanatory drawing of one Example of the message at the time of the detection of the infrared noise of the learning remote controller of this invention, and its solution method. (Embodiment 4) It is explanatory drawing of one Example of the learning remote control apparatus attached to the self-propelled electronic device of this invention so that attachment or detachment was possible. (Embodiment 6)

  Hereinafter, the present invention will be described in more detail with reference to the drawings. In addition, the following description is an illustration in all the points, Comprising: It should not be interpreted as limiting this invention.

(Embodiment 1)
<Overall Configuration of Control System 100 for Self-Propelled Electronic Equipment>
Next, a control system 100 that controls the self-propelled electronic device 20 will be described below as an example of the self-propelled electronic device including the learning remote control device of the present invention. This case is merely an example, and is not limited to the learning remote control device mounted on the self-propelled electronic device 20.
Hereinafter, the learning remote controller of the present invention having a function of preventing the occurrence of erroneous learning due to the reception of ambient infrared noise in advance will be referred to as a learning remote controller 1, and a conventional learning remote controller that does not have such a function is a learning remote controller. The apparatus 2 will be described.
The learning remote control device 1 may be incorporated in the self-propelled electronic device 20 or may be detachably provided in the self-propelled electronic device 20.
The learning remote controller 1 is not limited to the one mounted on the self-propelled electronic device 20, and may be a stationary or portable learning remote controller 1.

FIG. 1 is a block diagram showing a schematic configuration of an embodiment of a control system 100 for a self-propelled electronic device 20 according to the present invention.
As shown in FIG. 1, the control system 100 includes a communication terminal device 10 and a self-propelled electronic device (abbreviated as “electronic device” in the figure) 20, and these devices can communicate via a communication network 90. It is connected to the.

  In the first embodiment, the “input unit” of the present invention is realized by the operation unit 23. The “infrared receiver” of the present invention is realized by an infrared transmitter / receiver 36 (infrared light receiving element 36R (described later)). Further, the “signal storage unit” of the present invention is realized by the storage unit 24. Further, the “notification unit” of the present invention is realized by the audio output unit 43. Further, the “traveling part” of the present invention is realized by the movement driving part 61 (drive wheel 32). The “running control unit” of the present invention is realized by the control unit 21. Further, the “charging connection portion” of the present invention is realized by the charging terminal 49.

Further, the communication terminal device 10 and the self-propelled electronic device 20 may have a function of performing direct communication between these two devices without using the communication network 90.
The number of self-propelled electronic devices 20 provided in the control system 100 is not limited to one, and a plurality of self-propelled electronic devices 20 may be provided.
Similarly, the number of communication terminal devices 10 is not limited to one, and a plurality of communication terminal devices 10 may be provided.

  The communication terminal device 10 and the self-propelled electronic device 20 communicate with a server device (not shown) via the communication network 90, respectively, and the communication terminal device 10 communicates with the self-propelled electronic device via the server device. The operation of the device 20 may be controlled.

<Configuration of communication terminal device 10>
As illustrated in FIG. 1, the communication terminal device 10 includes a control unit 11, a communication unit 12, an operation unit 14, and a storage unit 15.
The communication terminal device 10 may include a display unit.
The configuration of the communication terminal device 10 is not particularly limited as long as it is a communication terminal device having the functions of the above-described units. For example, a smartphone, a tablet terminal, a mobile phone, a PDA (Personal Digital Assistance), a personal computer, a portable game A machine can be used.
Further, as the communication terminal device 10, a remote control device for controlling the self-propelled electronic device 20 configured to have the functions of the above-described units can be used.

  The control unit 11 is a control unit of the communication terminal device 10 that controls the operation of each unit of the communication terminal device 10. The control unit 11 includes, for example, an arithmetic processing unit such as a CPU and a dedicated processor, and a storage unit such as a RAM (Random Access Memory), a ROM (Read Only Memory), and an HDD (Hard Disk Drive) (not shown). And the like, and controls the operation of each unit of the communication terminal device 10 by reading and executing various information stored in the storage unit and a program for performing various controls.

The communication unit 12 communicates with other devices that exist in remote locations via the communication network 90 (far-distance communication function), and other devices that exist within a communicable range (for example, within the same facility). It is a communication means provided with the function (short-distance communication function) which performs communication between apparatuses.
When the user inputs an instruction for remote operation through the operation unit 14, the communication unit 12 controls the operation of the control target device to the communication unit 22 of the self-propelled electronic device 20. Send instruction information.

  Examples of the communication network 90 used for the above-described long-distance communication function include the Internet, a telephone line network, a mobile communication network, a CATV communication network, a satellite communication network, and the like.

In addition, as the short-range communication function, for example, WiFi (registered trademark) that interconnects wireless devices using IEEE802.11 (IEEE802.11a or IEEE802.11b), which is one of the wireless LAN standards, is used. Use a communication function of a device, a communication function based on a wireless LAN standard other than IEEE 802.11, a communication function using a short-range wireless communication standard such as Bluetooth (registered trademark) or ZigBee (registered trademark), an infrared communication function, etc. it can.
Note that the communication network 90 of the present application includes both the long-range communication function and the short-range communication function.

The operation unit 14 receives an operation input from the user and transmits it to the control unit 11.
The configuration of the operation unit 14 is not particularly limited, and various conventionally known operation input means such as a keyboard, a mouse, a pen, a touch panel, and other pointing devices can be used.

The storage unit 15 is a storage unit that stores various types of information used in the communication terminal device 10.
The structure of the memory | storage part 15 is not specifically limited, A conventionally well-known memory | storage means can be used.

<Configuration of self-propelled electronic device 20>
The self-propelled electronic device 20 has a function of performing an operation according to an instruction from the user to the operation unit 23 provided in the own device and an operation according to a control command (instruction information) sent from the communication terminal device 10. Equipment.
In the following embodiments, the case where the self-propelled electronic device 20 is a self-propelled cleaner will be mainly described.
However, the configuration of the self-propelled electronic device 20 is not limited to this, and a self-propelled electronic device having a function of performing an operation according to a control command from the communication terminal device 10, that is, an electronic device having a moving function. As long as it corresponds to.
Examples of the self-propelled electronic device 20 of the present invention include air cleaning devices, photographing devices, AV devices, various robot devices (for example, housework support robots, animal type robots, etc.).

  As shown in FIG. 1, the self-propelled electronic device 20 includes a control unit 21, a communication unit 22, an operation unit 23, a storage unit 24, a device function unit 25, and a remote control unit 26.

The control unit 21 is a control unit of the self-propelled electronic device 20 that controls the operation of each part of the self-propelled electronic device 20.
The control unit 21 includes, for example, a computer device including an arithmetic processing unit such as a CPU and a dedicated processor, and a storage unit (not shown) such as a RAM, a ROM, and an HDD, and is stored in an upper storage unit The various information and programs for performing various controls are read out and executed to control the operation of each part of the self-propelled electronic device 20.

The communication unit 22 is configured to communicate with other devices that exist at remote locations via the communication network 90 (far-distance communication function) and other devices that exist within a communicable range (for example, within the same facility). It is a communication means provided with the function (short-distance communication function) which performs communication between apparatuses.
As the communication part 22, the thing similar to the communication part 12 with which the communication terminal device 10 is equipped can be used, for example.
In the present invention, the communication unit 22 mainly receives instruction information for controlling the operation of the control target device from the communication terminal device 10, and transmits the image captured by the imaging unit 40 to the communication terminal device 10.

The operation unit 23 is a part that receives an instruction input from the user and transmits the instruction input to the control unit 21.
The configuration of the operation unit 23 is not particularly limited. For example, the operation unit 23 may be configured by key operation buttons, a touch panel, or a combination thereof.

The storage unit 24 is a storage unit that stores various information used in the self-propelled electronic device 20.
The configuration of the storage unit 24 is not particularly limited, and various types of RAM, ROM, HDD, and the like can be used, for example.

The device function unit 25 is a part that executes the device function of the self-propelled electronic device 20 in accordance with an instruction from the control unit 21.
For example, when the self-propelled electronic device 20 is a self-propelled cleaner, the device function unit 25 executes a traveling function (moving function), a cleaning function (dust collecting function), an imaging function, and the like.
In addition, when the self-propelled electronic device 20 is an air cleaning device, a photographing device, an AV device, various robots, or the like, the device function unit 25 includes device functions (for example, a traveling function, an air cleaning function) provided in each device. , Shooting function, moving function, etc.).

The remote control unit 26 is a control unit that controls the remote control operation of the home appliance using the infrared transmission / reception unit 36.
The remote control unit 26 has, for example, the same configuration as the control unit 21, and stores various information stored in a storage unit (not shown) such as a RAM, a ROM, and an HDD and a program for performing various controls. Execute remote control of home appliances read and registered.
Note that the self-propelled electronic device 20 is not limited to the configuration including the remote control unit 26, and may be a configuration in which the control unit 21 executes a remote control operation.

  FIG. 1 shows a configuration block of an embodiment of a self-propelled cleaner that is a self-propelled electronic device 20. The apparatus function unit 25 mainly includes a movement drive unit 61, a brush drive unit 62, an audio output. Unit 43, fan drive unit 63, imaging unit 40, drive wheel 32, rotating brush 44, side brush 45, suction fan 58, ultrasonic sensor 41, infrared transmission / reception unit 36, voltage detection unit 64, battery 31, charging terminal 49, An infrared sensor 35 and an energization detection unit 65 are provided.

2 is a perspective view of an embodiment of a self-propelled cleaner that is the self-propelled electronic device 20 of the present invention, and FIG. 3 is a plan view and a side view of the self-propelled cleaner. These are sectional drawings of a self-propelled cleaner, and Drawing 5 is a top view of the bottom (floor side) of a self-propelled cleaner.
In FIG. 4, C is a vertical center line passing vertically through the center of the housing 30.

As shown in the figure, a self-propelled cleaner, which is a self-propelled electronic device 20, uses a self-propelled electronic device main body formed of a substantially disc-shaped housing 30 and a battery (rechargeable battery) 31 as a power supply source. It has a drive wheel 32 to be driven, and has a function of collecting (cleaning) dust while self-propelled.
The movement drive unit 61 is a part that moves the housing 30, and performs traveling control by driving the drive wheels 32.

On the upper surface of the housing 30, a lid 34, an operation unit 23, and an infrared transmission / reception unit 36 are provided.
In FIG. 2, the housing 30 has a shape in which the upper surface and the bottom surface are circular, but the shape of the housing 30 is not particularly limited.

  The lid portion 34 can be opened and closed with respect to the housing 30, and by opening the lid portion 34, a dust collection container 38 that is accommodated in the dust collection portion 37 in the housing 30 and accumulates dust can be attached and detached. The dust in the dust collecting container 38 can be discarded.

The operation unit 23 may be provided with an operation switch that receives input of various instructions from the user, data such as characters and numbers, and may further be provided with a display (display unit) that displays various information presented to the user.
Moreover, as the operation part 23, you may provide the touchscreen integrally formed with the display part.

  The infrared sensor 35 is a part that detects a return infrared induction signal transmitted from the charging stand 70.

The infrared transmission / reception unit 36 is a part that receives an infrared signal (infrared light) transmitted from the remote control device 3 of the home appliance to be controlled. This is the part that transmits signals (infrared light). The infrared transmission / reception unit 36 corresponds to a control signal transmission unit that transmits a control signal of the above-described control target device.
The infrared transmission / reception unit 36 differs from the infrared light receiving element arranged so as to be able to receive the infrared signal transmitted from the remote control device 3, and the principal axis directions of the emitted light are different from each other so that infrared light is emitted in different directions. And a plurality of infrared light sources (also referred to as infrared light LEDs) arranged in this manner.
An infrared signal can be output from the infrared LED in a relatively wide angle range in the horizontal direction and the vertical direction of the casing 30 of the self-propelled electronic device 20. The infrared signal is a signal corresponding to the instruction information transmitted from the communication terminal device 10 and is a signal for controlling the control target device.
The configuration of the infrared transmitting / receiving unit 36 is not particularly limited, and the number of installed infrared light receiving elements, the infrared light receiving angle range, the number of installed infrared light sources, and the infrared signal emitting angle range may be set as appropriate. A specific configuration example of the infrared transmitting / receiving unit 36 will be described later.

A bumper 39 is provided on the side surface of the housing 30 to reduce the impact on the housing 30 when the housing 30 collides with a wall or the like.
In addition, an infrared sensor 35 and an imaging unit 40 are provided in a hole provided in a part of the bumper 39, for example, a hole provided in a front surface in a normal traveling direction, and provided in a part of the bumper 39. An ultrasonic sensor 41 is provided in the other hole.

The imaging unit 40 is a camera that captures an image, and mainly captures an image around the self-propelled electronic device 20 to generate imaging data. The captured image may be either a moving image or a still image, but in order for a user at a remote location to check the current state of the room in detail with his mobile terminal, in addition to the still image, It is preferable that a moving image can be captured.
The configuration of the imaging unit 40 is not particularly limited, and conventionally known imaging means can be used. For example, an imaging unit including an optical lens, a color filter, a CCD (Charge Coupled Device) that is a receiving element, and the like may be used.
In addition to the imaging unit 40, a sound acquisition unit (not shown) that acquires the sound around the self-propelled electronic device 20 may be provided.

The ultrasonic sensor 41 outputs an ultrasonic wave toward the periphery of the self-propelled electronic device 20 and receives an ultrasonic wave reflected by the obstacle, thereby causing an obstacle present around the self-propelled electronic device 20. Detect the position of an object.
It is preferable to provide a plurality of ultrasonic sensors 41 at an appropriate distance on the outer surface of the housing 30 instead of one.

The voice output unit 43 is a part that outputs a voice for reproducing a message predetermined to the user and a notification sound such as a buzzer or an alarm. For example, a speaker is used.
The audio output unit 43 is provided at a position on the side of the housing 30 of the self-propelled electronic device 20 (not shown). This is merely an example and can be provided at an arbitrary position.

  As shown in FIG. 5, the driving wheel 32, the rear wheel 48, the rotating brush 44, the side brush 45, and the suction port 46 are provided on the bottom surface of the housing 30.

The drive wheels 32 are respectively provided on both ends of a center line 32a of a circle formed by the bottom surface of the bottom surface of the housing 30.
Each of the drive wheels 32 is attached to a rotation shaft (not shown) parallel to the center line 32 a in a state where a part of the drive wheel 32 protrudes from the bottom surface of the housing 30.
Each of these rotating shafts is rotationally driven by driving a motor, gear, or the like (not shown), which is the movement drive unit 61 (see FIG. 1), using electric power supplied from the battery 31.
Thereby, each drive wheel 32 rotates and the self-propelled electronic device 20 self-propels on the floor surface F.

Each drive wheel 32 is individually driven to rotate. When these drive wheels 32 are driven to rotate in the same direction, the self-propelled electronic device 20 corresponds to the rotation direction of each drive wheel 32. Move forward or backward.
When these drive wheels 32 are driven to rotate in opposite directions, the self-propelled electronic device 20 rotates (turns) in a direction parallel to the bottom surface on the spot according to the rotation direction of each drive wheel 32. To do.
Thereby, the advancing direction of the self-propelled electronic device 20 can be changed.
The self-propelled electronic device 20 is provided with a sensor (not shown) that detects when the bumper 39 collides with a wall or the like, and proceeds when the self-propelled electronic device 20 collides with the wall or the like during movement. The movement may be continued by changing the direction.
Also, obstacles such as walls and furniture are detected according to the detection result of the ultrasonic sensor 41 and the imaging result of the imaging unit 40, and the self-propelled electronic device 20 automatically moves while avoiding the obstacle. May be.

In addition, a rectangular suction port 46 formed of a recess recessed inside the housing 30 is provided on the bottom surface of the housing 30, and external air is introduced into the housing 30 from the suction port 46. A rotating brush 44 that rotates along a rotation axis parallel to the bottom surface of the housing 30 is provided in the recess of the suction port 46.
Further, side brushes 45 that rotate along a rotation axis perpendicular to the bottom surface of the housing 30 are provided at positions close to both ends in the longitudinal direction of the suction port 46 with respect to the suction port 46.
In the rotating brush 44 and the side brush 45, the brush driving unit 62 (see FIG. 1) rotates and rotates the rotating shafts of the rotating brush 44 and the side brush 45 by the electric power supplied from the battery 31 in response to an instruction from the control unit 21. Rotate by

A rear wheel 48 made up of a free wheel is provided near the rear end (rear end) of the bottom surface of the housing 30.
When the self-propelled electronic device 20 is disposed on the flat floor surface F, the rotating brush 44, the drive wheel 32, and the rear wheel 48 are grounded to the floor surface F.

At the rear end of the peripheral surface (side surface) of the housing 30, a charging terminal 49 used when charging the battery 31 is provided so as to be exposed from the housing 30 to the outside.
In the first embodiment, at the rear end of the peripheral surface of the housing 30, two charging terminals 49 extending in a substantially horizontal direction with respect to the floor surface F are arranged at a predetermined interval in the vertical direction. However, the installation position and the number of the charging terminals 49 are not limited to this.

When charging the battery 31, as shown in FIG. 4, the self-propelled electronic device 20 is returned to the charging base (home position) 70, and the charging terminal 49 is connected to the power supply terminal 71 provided on the charging base 70. To charge the battery 31.
The charging stand 70 is usually installed so that the back side (the side opposite to the side where the power supply terminal 71 is provided) faces the indoor side wall S, and power supplied from a commercial power source is supplied via the power supply terminal 71. To the self-propelled electronic device 20.
The charging stand 70 is arranged at a predetermined position on the floor so as not to move.

The battery (rechargeable battery) 31 is a power supply source for the entire self-propelled electronic device 20, and supplies power to the above-described movement drive unit 61, imaging unit 40, dust collection unit 37, infrared transmission / reception unit 36, and the like.
The configuration of the battery 31 is not particularly limited. For example, a lead battery, a nickel metal hydride battery, a lithium ion battery, or a capacitor can be used. The battery 31 is preferably a large capacity rechargeable battery that can be repeatedly charged and discharged.

  The voltage detector 64 detects the voltage of the battery 31 and calculates the charge amount of the battery 31 from the detected voltage.

  The energization detection unit 65 supplies the energization amount from the power feeding terminal 71 to the charging terminal 49 (the current value of the current supplied from the power feeding terminal 71 to the battery 31 via the charging terminal 49 and / or the charging terminal 49 by the power feeding terminal 71. The voltage value applied to is detected.

As shown in FIG. 4, a dust collecting portion 37 that collects dust is disposed in the housing 30.
The dust collection unit 37 is housed in a dust collection chamber 50 provided inside the housing 30, and collects the dust sucked together with the air introduced from the suction port 46 in the dust collection container 38.
The dust collection chamber 50 is composed of an isolation chamber whose four circumferential surfaces and bottom are covered, and is formed by extending in the axial direction of the rotary brush 44 so as to partition the inside of the housing 30.
Each wall surface of the dust collection chamber 50 is closed except for the front wall extending in the axial direction of the rotating brush 44.
A first intake passage 51 communicating with the suction port 46 is provided on the front wall of the dust collection chamber 50.
The air introduced from the suction port 46 is discharged from the exhaust port 59 to the outside through the internal path.

The dust collector 37 is opened to the outside of the housing 30 by opening the lid portion 34 of the housing 30.
The dust collecting portion 37 is formed by attaching an upper cover 53 having a filter 52 to an upper portion of a dust collecting container 38 having a bottom.
The upper cover 53 is locked to the dust collecting container 38 by a movable locking part (not shown), and the upper surface of the dust collecting container 38 is opened and closed by operating the locking part.
Thereby, the dust accumulated in the dust collecting container 38 can be discarded.

An inflow passage 54 communicating with the first intake passage 51 is provided on the peripheral surface of the dust collecting container 38.
In addition, an inflow portion 54 b is provided in the dust collection container 38 so as to guide the airflow downward by bending the inflow passage 54.
On the peripheral surface of the upper cover 53, an outflow passage 55 that connects the inside of the dust collecting container 38 and the second intake passage 56 is provided.
The second intake path 56 is disposed so as to allow the motor unit 57 and the outflow path 55 to communicate with each other.

A gasket (not shown) that is in close contact with the front wall of the dust collecting chamber 50 is provided around the openings in the inflow path 54 and the outflow path 55.
Thereby, the inside of the dust collection chamber 50 which accommodated the dust collection part 37 is sealed.

A control board 42 is disposed on the upper rear side of the dust collection chamber 50 in the housing 30.
The control board 42 is provided with a control unit 21 that controls each unit of the self-propelled electronic device 20 and a storage unit 24 that stores various data.
A battery 31 is disposed at the lower rear of the dust collection chamber 50.
The battery 31 is charged by the electric power supplied from the charging stand 70 via the charging terminal 49, and in addition to the above-described components, the control board 42, the drive wheel 32, the rotating brush 44, which are the components constituting the dust collecting unit 37, Power is also supplied to the side brush 45, the suction fan 58, and the like.

In the self-propelled electronic device 20, when the cleaning operation is instructed, the suction fan 58, the drive wheel 32, the rotating brush 44, and the side brush 45 are driven by the power supplied from the battery 31.
The suction fan 58 is driven by driving a motor unit 57 by a fan driving unit 63 (see FIG. 1).
As a result, the self-propelled electronic device 20 causes the rotating brush 44, the drive wheel 32, and the rear wheel 48 to contact the floor surface F and self-propelled in a predetermined cleaning region, and dust on the floor surface F from the suction port 46. Airflow including is sucked.
At this time, the dust on the floor surface F is scraped up by the rotation of the rotating brush 44 and guided into the suction port 46. Further, the dust on the side of the suction port 46 is guided to the suction port 46 by the rotation of the side brush 45.

The airflow sucked from the suction port 46 flows into the dust collecting portion 37 through the first intake passage 51 as shown by an arrow A1 in FIG.
The airflow that has flowed into the dust collecting portion 37 collects dust by the filter 52 and flows out from the dust collecting portion 37 through the outflow passage 55.
As a result, dust is collected and accumulated in the dust container 38.
The airflow flowing out from the dust collecting portion 37 flows into the suction fan 58 of the motor unit 57 through the second intake passage 56 as indicated by an arrow A2.

  The airflow that has passed through the suction fan 58 is exhausted upward and rearward of the self-propelled electronic device 20 from an exhaust port 59 provided on the upper surface of the housing 30 as indicated by an arrow A3.

<Configuration of Infrared Transmitter / Receiver 36>
6 and 7 are perspective views of an embodiment of the infrared transmission / reception unit 36 of the present invention.
FIG. 6 shows a part of the housing 30 including the infrared transmission / reception unit 36 of the self-propelled electronic device 20 shown in FIG.
The infrared transmission / reception unit 36 shown in FIG. 6 shows a state where a lid is attached. Inside the lid, there is one infrared light receiving element that receives infrared light and a plurality of infrared light receiving elements that transmit infrared light. An infrared LED is provided.
The infrared light transmitted from the remote control device 3 passes through this lid and is received by the infrared light receiving element 36R.
The infrared light transmitted from the infrared light LED passes through this lid and is emitted outside the housing.
An infrared sensor 35 and an imaging unit 40 are provided in the vicinity of the infrared transmission / reception unit 36, and both are arranged near the outer surface of the housing 30.

FIG. 7 shows the infrared transmitting / receiving unit 36 with the lid removed.
In the embodiment shown in FIG. 7, the infrared transmitter / receiver 36 includes one infrared light receiving element 36R and six infrared LEDs (36 (a) to (f)).

<Configuration of Infrared Light Receiving Element 36R>
In FIG. 7, the infrared light receiving element 36 </ b> R is fixedly installed such that the central axis in the infrared light receiving direction is above the horizontal plane.
For example, it is attached so that the central axis of the received infrared light is inclined by about 45 degrees in the front-rear direction of the main body and above the horizontal plane.
However, the number of infrared light receiving elements is not limited to one, and a plurality of infrared light receiving elements may be provided.

<Configuration of Infrared Light LEDs 36 (a) to (f)>
The six infrared LEDs are arranged so that the emission directions of the infrared light are different from each other.
In FIG. 7, the two outer infrared LEDs (36 (a), 36 (f)) are fixedly installed so that the central axis of the infrared light emission direction is above the horizontal plane.
For example, it is attached so that the central axis of the emitted infrared light is inclined about 75 degrees above the horizontal plane.
The infrared light LED 36 (a) has a center axis in the infrared light emitting direction inclined 15 degrees to the right from the vertical plane in the longitudinal direction of the main body, and the infrared light LED 36 (f) is inclined about 15 degrees to the left. It is attached so that it is in the direction.

  The two infrared LEDs (36 (b), 36 (e)) have an infrared light emission direction upward from the horizontal plane, but the two infrared LEDs (36 (a), 36 (e), 36 (f)) is fixedly installed so as to be emitted at an angle lower than that (for example, the central axis of the emitted infrared light is 45 degrees above the horizontal plane). As with the infrared LEDs 36 (a) and (f), the infrared LEDs 36 (b) and 36 (e) have a central axis in the emission direction of 15 degrees to the right and 15 to the left from the vertical plane in the front-rear direction of the main body. It is attached so that it is in a direction inclined about a degree.

The innermost two infrared LEDs (36 (c), 36 (d)) have an emission direction of infrared light higher than the horizontal plane, and the two infrared LEDs (36 (b) , 36 (e)) is fixedly installed so that it is emitted at an angle lower than that (for example, the central axis of the emitted infrared light is 15 degrees above the horizontal plane).
As with the infrared LEDs 36 (a) and (f), the infrared LEDs 36 (c) and 36 (d) each have a central axis in the emission direction of 15 degrees to the right and 15 to the left from the vertical plane in the longitudinal direction of the main body. It is attached so that it is in a direction inclined about a degree.
However, the number of infrared LEDs is not limited to six and may be any of 2 to 5. A smaller number is preferable for reducing power consumption.
Infrared light emitted from one infrared LED spreads in a conical shape and travels through space. For example, the infrared light travels with a spread of about ± 15 degrees from the central axis in the traveling direction.
Thereby, infrared light which is a control signal can be emitted in a wide range.

<Flow of Remote Learning Procedure of Conventional Learning Remote Controller 2>
Next, before the description of the learning remote controller 1 of the present invention, the flow of the remote learning procedure of the conventional learning remote controller 2 will be described based on FIG.
FIG. 8 is a flowchart of a remote control learning procedure of the conventional learning remote control device 2.

  When the user operates the conventional learning remote control device 2 and starts remote control learning, the learning remote control device 2 follows the procedure shown in the following steps.

  In step S1 of FIG. 8, the learning remote controller 2 determines whether or not a remote control learning command from the user has been received (step S1).

  Here, the remote control learning command is a setting for learning remote control of the learning remote control device 2. For example, registration settings such as selection of a registered device such as an air conditioner, television, or lighting, selection of a remote control signal type such as a power source, volume or intensity, and selection of a button type. The learning remote controller 2 determines that the remote control learning command has been accepted when these settings are completed. Alternatively, it may be determined that a remote control learning command has been received when an operation of the remote control learning start button is received.

In step S1, when the remote control learning command is received (when the determination in step S1 is Yes), the learning remote control device 2 performs the process of step S2 (step S2).
On the other hand, when the remote control learning command is not received (when the determination in step S1 is No), the learning remote control device 2 waits until the remote control learning command is received (step S1).

Next, in step S2, the learning remote controller 2 notifies the user of the start of remote control learning (step S2).
Specifically, the message “Ready for remote control learning” or “Start remote control learning. Press the button on the remote control device you want to learn toward the receiver of the learning remote control device” appears on the display. Display or output from the speaker to inform the user. Moreover, you may alert | report by alerting sounds, such as a buzzer and an alarm, and you may alert | report by the flashing signal of a lamp | ramp etc.
Thereafter, the user presses the button of the remote control device to be learned after the receiving unit of the learning remote control device 2 and the transmission unit of the remote control device to be learned are brought close to each other so as to face each other.

Subsequently, in step S3, the learning remote controller 2 determines whether or not an infrared signal has been received within a predetermined time (for example, 1 minute) (step S3).
When the learning remote control device 2 receives an infrared signal within a predetermined time (when the determination in step S3 is Yes), the learning remote control device 2 analyzes the signal pattern of the received infrared signal in step S4, After storing the obtained learning data (step S4), the learning is terminated.

  On the other hand, when the learning remote controller 2 cannot receive the infrared signal within a predetermined time (when the determination in step S3 is No), the learning remote controller 2 returns error information at the time of learning failure in step S5. The user is notified (step S5), and learning is terminated.

  Here, the error information notification content includes, for example, a message such as “Reception of remote control signal failed”.

<Specific Example of Remote Control Learning Procedure of Learning Remote Control Device 1 Mounted on Self-Propelled Electronic Device 20 of the Present Invention>
Next, a specific example of the remote control learning procedure of the learning remote controller 1 mounted on the self-propelled electronic device 20 of the present invention will be described with reference to FIG.
FIG. 9 is a flowchart of the remote control learning procedure of the learning remote control device 1 mounted on the self-propelled electronic device 20 of the present invention.

Here, steps S11 and S15 to S18 in FIG. 9 correspond to steps S1 to S5 in FIG.
Here, the processes of steps S12 to S14 that are not in the prior art will be described.

  In step S11 of FIG. 9, when the control unit 21 receives a remote control learning command (when the determination in step S11 is Yes), the remote control unit 26 transmits and receives infrared information around the housing 30 by infrared transmission / reception in step S12. The unit 36 is checked (step S12).

  As a specific checking method, for example, as shown in FIG. 11, the infrared transmission / reception unit 36 receives ambient infrared signals while changing the direction of the casing 30 360 degrees on the spot (see FIG. 11).

Next, in step S13, the control unit 21 determines whether or not the infrared transmission / reception unit 36 has received an infrared signal (step S13).
When the infrared transmission / reception unit 36 receives an infrared signal (when the determination in step S13 is Yes), in step S14, the control unit 21 notifies the user of detection of infrared noise (step S14), and ends the learning.

  Specific notification contents include, for example, a predetermined message such as “An infrared noise has been detected. Please move the main body to a place where infrared noise does not reach”. The notification method may be a method of causing the audio output unit 43 to reproduce a predetermined message. When the communication terminal device 10 includes a display unit, the communication terminal via wireless communication is used. A method of displaying a predetermined message on the display unit of the apparatus 10 may also be used.

  On the other hand, when the infrared transmission / reception unit 36 does not receive the infrared signal in step S13 (when the determination in step S13 is No), the control unit 21 performs the process of step S15 (step S15).

<Comparison Example of Remote Learning Method of Conventional Learning Remote Control Device 2 and Learning Remote Control Device 1 of the Present Invention>
Next, based on FIG. 10 and FIG. 11, the remote learning method of the conventional learning remote controller 2 and the learning remote controller 1 of the present invention will be compared.
FIG. 10 is an explanatory diagram of a remote control learning procedure of the conventional learning remote control device 2.
FIG. 11 is an explanatory diagram of an embodiment of a remote control learning procedure of the learning remote control device 1 mounted on the self-propelled electronic device 20 of the present invention.

As shown in FIG. 10, it is assumed that the self-propelled electronic device 20 is present in the infrared noise generated by the lighting device at the start of remote control learning. It is known that lighting devices such as fluorescent lamps may generate strong infrared noise. In FIG. 10, the area affected by the infrared noise generated from the lighting device is indicated by an area surrounded by a broken line.
Here, when the conventional learning remote control device 2 is mounted on the self-propelled electronic device 20, the conventional learning remote control device 2 receives not the infrared signal transmitted from the remote control device 3 but the infrared noise generated by the lighting device. This may cause mislearning.

  On the other hand, when the learning remote control device 1 of the present invention is mounted on the self-propelled electronic device 20, the self-propelled electronic device 20 has a housing 30 before starting remote control learning, as indicated by an arrow MP1 in FIG. The surrounding infrared information is checked while changing the direction of 360 degrees. If infrared noise is detected as a result of the check, a predetermined voice message “IR noise detected” is output. Therefore, the user can know the presence of infrared noise and prevent erroneous learning due to reception of infrared noise.

  In this way, the remote infrared learning is checked at the start of remote control learning, and when there is infrared noise, a predetermined message is notified to the user, thereby preventing erroneous learning of the remote control signal due to the infrared noise. be able to.

(Embodiment 2)
<Specific example of remote control learning procedure of learning remote controller 1 mounted on self-propelled electronic device 20 according to Embodiment 2 of the present invention>
Next, a specific example of the remote control learning procedure of the learning remote controller 1 mounted on the self-propelled electronic device 20 according to the second embodiment of the present invention will be described with reference to FIGS.
FIG. 12 is a flowchart of a remote control learning procedure of the learning remote controller 1 mounted on the self-propelled electronic device 20 according to the second embodiment of the present invention.
FIG. 13 is an explanatory diagram of an embodiment of a remote control learning procedure of the learning remote control device 1 mounted on the self-propelled electronic device 20 of the present invention.

Here, the processes in steps S21 to S23 and S25 to S28 in FIG. 12 correspond to the processes in steps S11 to S13 and S15 to S18 in FIG.
Here, the process of step S24 that is not in the first embodiment will be described.

When the self-propelled electronic device 20 receives an infrared signal in step S23 of FIG. 12 (when the determination in step S23 is Yes), the self-propelled electronic device 20 performs a charging stand feedback process in step S24 ( Step S24).
Note that the user may be notified that infrared noise has been detected before performing the charging stand feedback process.

As shown in FIG. 13A, when the self-propelled electronic device 20 is not connected, the charging stand 70 has an infrared induction signal (infrared induction signal for guiding the return of the self-propelled electronic device 20 to the charging stand 70). A beacon is emitted indoors at a predetermined radiation angle.
Here, when the conventional learning remote control device 2 is mounted on the self-propelled electronic device 20, the conventional learning remote control device 2 may erroneously receive an infrared signal transmitted from the charging stand 70, and erroneous learning occurs. Cause.

  On the other hand, in the case of the self-propelled electronic device 20 equipped with the learning remote control device 1 according to the second embodiment of the invention, when the infrared signal transmitted from the charging stand 70 is received, the self-propelled electronic device 20 is indicated by an arrow MP2. The charging stand return process is performed through the route, and the charging stand 70 is connected. At this time, an infrared induction signal for return is not transmitted from the charging stand 70, so that erroneous learning due to reception of the infrared induction signal can be prevented.

  Thus, when detecting the infrared noise, the self-propelled electronic device 20 performs the charging stand feedback process and connects to the charging stand 70, so that the influence of the infrared induction signal for feedback can be removed.

(Embodiment 3)
<Specific example of remote control learning procedure of learning remote control device 1 mounted on self-propelled electronic device 20 according to Embodiment 3 of the present invention>
Next, a specific example of the remote control learning procedure of the learning remote control device 1 mounted on the self-propelled electronic device 20 according to Embodiment 3 of the present invention will be described with reference to FIGS.
FIG. 14 is a flowchart of a remote control learning procedure of the learning remote controller 1 mounted on the self-propelled electronic device 20 according to the third embodiment of the present invention.
FIG. 15 is an explanatory diagram of an embodiment of a remote control learning procedure of the learning remote control device 1 mounted on the self-propelled electronic device 20 of the present invention.

Here, steps S31, S33, S34 and S38 to S41 in FIG. 14 correspond to steps S11 to S13 and S15 to S18 in FIG.
Here, the processes of steps S32, S35, and S36 that are not in the first embodiment will be described.

  In step S31 in FIG. 14, when the control unit 21 receives a remote control learning command (when the determination in step S31 is Yes), in step S32, the control unit 21 sets a timer (step S32).

Next, when the infrared transmission / reception unit 36 receives an infrared signal in step S34 (when the determination in step S34 is Yes), in step S35, the control unit 21 performs a random running process of the self-propelled electronic device 20. (Step S35).
Note that the user may be notified that infrared noise has been detected before the random running process is performed.

Subsequently, in step S36, the control unit 21 determines whether or not a set timer setting time (for example, 5 minutes) has elapsed (step S36).
When the set time of the set timer has elapsed (when the determination in step S36 is Yes), the control unit 21 notifies the user that infrared noise has been detected in step S37 (step S37).
On the other hand, when the set time of the set timer has not elapsed (when the determination in step S36 is No), the remote controller control unit 26 repeats the process of step S33 (step S33).

  In this way, when infrared noise is received, by performing a random run for a predetermined timer setting time and checking the surrounding infrared information again, there is no infrared noise (or infrared rays) Remote control learning is possible in places where noise is weak.

Next, as shown in FIG. 15, it is assumed that the self-propelled electronic device 20 exists in the infrared noise of sunlight radiated from the window at the start of remote control learning. In FIG. 15, a region affected by infrared noise due to sunlight incident through a window is indicated by a region surrounded by a broken line.
When the infrared transmission / reception unit 36 detects infrared noise, the self-propelled electronic device 20 checks the surrounding infrared information every predetermined time (for example, 1 minute) after starting random running.

  In FIG. 15, the self-propelled electronic device 20 starts random traveling after detecting infrared noise. And after moving the path | route shown by arrow MP3, infrared information is checked again. However, since the infrared noise is detected again, the random running is started again, and this time, after moving the arrow MP4, the infrared information is checked. As a result, since no infrared noise was detected, a normal remote control learning procedure is started.

On the other hand, when a predetermined timer set time has elapsed during random running, the self-propelled cleaner 20 notifies the user of a message that infrared noise has been detected.
For example, it is assumed that the set time of the timer is 5 minutes, the time required for checking the surrounding infrared information is 30 seconds, and the random running time per time is 30 seconds. At this time, if a place where there is no infrared noise is not found even after performing ambient infrared information five times, the self-propelled electronic device 20 notifies the user of a message indicating that infrared noise has been detected.

  Thus, even when infrared noise is detected at the start of remote control learning, the self-propelled electronic device 20 that searches for a place where infrared noise does not exist can be realized by random running.

(Other embodiments)
1. In the first embodiment, when the communication terminal device 10 includes a display unit, when notifying the user of the detection of infrared noise, the display unit of the communication terminal device 10 is not limited to a voice message and is displayed on the display unit of the communication terminal device 10 via wireless communication. A message may be displayed. (Embodiment 4)
In this way, detailed error information can be notified to the user via the communication terminal device 10.

FIG. 16 is an explanatory diagram of an embodiment of the display unit of the communication terminal device 10 according to the present invention.
As shown in FIG. 16, when infrared noise is detected, a predetermined message is displayed on the display unit of the communication terminal device 10. Here, a hint for solving the problem may be obtained by touching a “display solution” button displayed on the display unit.

  FIG. 17 is an explanatory diagram of an embodiment of a message when detecting the infrared noise of the learning remote controller 1 of the present invention and a solution method thereof.

2. In step S24 of the second embodiment, when the self-propelled electronic device 20 has a function of controlling the power source of the fluorescent lamp, a process of turning off the power source of the corresponding fluorescent lamp may be performed. (Embodiment 5)
In this way, the influence of infrared noise caused by the fluorescent lamp can be removed without the user having to switch off the fluorescent lamp himself.

3. As shown in FIG. 18, the learning remote controller 1 may be detachably provided on the self-propelled electronic device 20. (Embodiment 6)
This example is merely an example and is not limited to the form shown in FIG.

As mentioned above,
(I) A learning remote controller of the present invention includes an input unit that receives a command from a user, an infrared receiving unit that receives an infrared signal, a signal learning unit that analyzes the infrared signal and learns a signal pattern thereof, A signal storage unit that holds a signal pattern, a notification unit that notifies a user of predetermined information, and a control that controls the input unit, the infrared reception unit, the signal learning unit, the signal storage unit, and the notification unit And when the input unit receives a remote control learning command, the control unit causes the infrared receiving unit to try to receive a surrounding infrared signal, and the infrared receiving unit receives the infrared signal. If the user is informed of the presence of infrared noise by the user and the infrared receiver does not receive the infrared signal, the user learns toward the infrared receiver. The notification unit is informed to transmit a remote control signal to be learned to the user.
In addition, the remote control learning method of the present invention, when receiving a remote control learning instruction, causes the surrounding infrared signal to be received, and when the surrounding infrared signal is received, informs the user that infrared noise exists, When the surrounding infrared signal is not received, the user is notified to transmit a remote control signal to be learned.

In this invention, the “learning remote control device” receives an infrared signal transmitted from the remote control device, analyzes a signal pattern of the received infrared signal, performs learning, and transmits the same infrared signal as the learned signal. It is a device that can.
As types of learning remote control devices, stationary learning remote control devices and self-propelled learning remote control devices are also known in addition to portable learning remote control devices. The stationary learning remote control device can operate indoor household appliances from the learning remote control device via a communication terminal device such as a smartphone or a tablet terminal, so that the home appliances can be operated from the outside via the communication terminal device. it can. In addition, the self-propelled learning remote control device is known to have the learning remote control device mounted on the self-propelled electronic device, even if there are obstacles such as walls between the home appliances to be operated, The home appliance can be operated by running the self-propelled electronic device to a desired place in the room via the communication terminal device.
The “self-propelled electronic device” performs operations such as cleaning, air cleaning, and ion generation while traveling. As an example of the specific aspect, a self-propelled electronic device is mentioned, for example. In the above-described embodiment, the self-propelled electronic device corresponds to the self-propelled electronic device.
This self-propelled electronic device includes a housing having an air inlet on the bottom and a dust collecting portion inside, a driving wheel for running the housing, a control unit for controlling rotation, stopping, and rotating direction of the driving wheel, etc. And an autonomous cleaning operation, and an example is shown by the embodiment using the above-mentioned drawings.
In addition, the self-propelled electronic device of the present invention includes not only a self-propelled electronic device, but also a self-propelled air purifier that performs air suction and exhausts purified air, and an ion generator that generates ions. It includes those that run on their own, those that present necessary information to the user, and those that run on a robot that can satisfy the user's desires.
“Infrared noise” is an infrared signal other than the remote control signal transmitted by the remote control device that the user wants to learn. Therefore, the remote control signal transmitted by the remote control device that is not the user's operation target also becomes infrared noise.
In the present invention, since all infrared signals received before the start of remote control learning are determined as infrared noise, no special analysis for determining infrared noise is required.

Furthermore, the preferable aspect of this invention is demonstrated.
(Ii) A self-propelled electronic device according to the present invention controls the traveling unit while cooperating with the learning remote controller according to claim 1, a casing having a traveling unit for self-propelling, and the control unit. The travel control unit, and when the input unit receives a remote control learning command, the travel control unit controls the travel unit to change the direction of the housing while the infrared receiver receives ambient infrared rays. Try to receive a signal.

  In this way, when checking the surrounding infrared information, it is possible to detect infrared noise more efficiently by changing the direction by utilizing the self-propelled function of the self-propelled electronic device. .

  “While cooperating with the control unit” means that the self-propelled electronic device is self-propelled in accordance with the operation of the learning remote control device mounted on the self-propelled electronic device.

  (Iii) In the self-propelled electronic device according to the present invention, the traveling control unit controls the traveling unit when the infrared receiving unit receives an ambient infrared signal, and controls the traveling unit for a predetermined time, You may make the said infrared receiving part try reception of a surrounding infrared signal, making it drive | work.

  In this way, when infrared noise is received during remote control learning, by checking the surrounding infrared information while running for a predetermined time, the infrared noise does not exist (or the infrared noise is weak) Enables remote learning.

  (Iv) In the self-propelled electronic device according to the present invention, the housing includes a charging connection unit for connecting to a charging base that emits an infrared signal for return, and the traveling control unit includes the infrared receiving unit. When a surrounding infrared signal is received, the traveling unit may be controlled to move the housing, and the charging connection unit may be connected to the charging stand.

  In this way, when infrared noise is detected, the self-propelled electronic device is connected to the charging stand, thereby removing the influence of infrared rays emitted from the charging stand.

  The “infrared signal for return” is an induction signal for guiding the self-propelled electronic device and returning it to the charging stand. In general, the transmission of an infrared signal from the charging stand stops when the charging connection of the self-propelled electronic device is connected to the charging stand.

Preferred embodiments of the present invention include combinations of any of the above-described plurality of embodiments.
In addition to the above-described embodiments, there can be various modifications of the present invention. These modifications should not be construed as not belonging to the scope of the present invention. The present invention should include the meaning equivalent to the scope of the claims and all modifications within the scope.

1: Learning remote control device 2: Conventional learning remote control device 3: Remote control device 10: Communication terminal device 11, 21: Control unit 12, 22: Communication unit 14, 23: Operation unit 15, 24: Storage unit, 20: Self-propelled electronic device, 25: Device function unit, 26: Remote control unit, 30: Housing, 31: Battery, 32: Drive wheel, 32a: Center line, 34: Lid unit, 35: Infrared ray Sensor: 36: Infrared transmission / reception unit, 36 (a) to (f): Infrared light LED, 36R: Infrared light receiving element, 37: Dust collection unit, 38: Dust collection container, 39: Bumper, 40: Imaging unit 41: Ultrasonic sensor, 42: Control board, 43: Audio output unit, 44: Rotating brush, 45: Side brush, 46: Suction port, 48: Rear wheel, 49: Charging terminal, 50: dust collecting chamber, 51: first intake passage, 52: filter, 53: upper cover, 54: inflow passage, 54b: inflow portion, 55: outflow passage, 56: second intake passage, 57: motor Unit: 58: suction fan, 59: exhaust port, 61: movement drive unit, 62: brush drive unit, 63: fan drive unit, 64: voltage detection unit, 65: energization detection unit, 70: charging stand, 71: power supply Terminal 90: communication network 100: control system A1 to A3: arrow C: vertical center line F: floor surface MP1-4: arrow S: side wall

Claims (5)

An input unit that receives a command from a user, an infrared receiving unit that receives an infrared signal, a signal learning unit that analyzes the infrared signal and learns its signal pattern, a signal storage unit that holds the signal pattern, A notification unit for notifying a user of defined information, and a control unit for controlling the input unit, the infrared reception unit, the signal learning unit, the signal storage unit, and the notification unit,
The control unit causes the infrared receiving unit to try to receive a surrounding infrared signal when the input unit receives a remote control learning command, and when the infrared receiving unit receives the infrared signal, the control unit causes the user to detect infrared noise. If the infrared receiving unit does not receive the infrared signal, the notification unit notifies the user to transmit a remote control signal to be learned toward the infrared receiving unit. Learning remote control device. A learning remote controller according to claim 1, a housing having a traveling unit for self-running, and a traveling control unit that controls the traveling unit in cooperation with the control unit,
When the input unit receives a remote control learning command, the traveling control unit controls the traveling unit to change the direction of the housing and causes the infrared receiving unit to try to receive surrounding infrared signals. Electronic equipment.   When the infrared receiving unit receives an ambient infrared signal, the traveling control unit controls the traveling unit to cause the casing to travel for a predetermined time while the infrared receiving unit transmits an ambient infrared signal to the infrared receiving unit. The self-propelled electronic device according to claim 2, wherein the electronic device is caused to try to receive the signal. The housing includes a charging connection for connecting to a charging stand that emits an infrared signal for return,
The travel control unit controls the travel unit to move the housing and connect the charging connection unit to the charging stand when the infrared receiving unit receives an ambient infrared signal. Or the self-propelled electronic device of 3.   When the remote control learning command is received, it tries to receive the surrounding infrared signal, and when the surrounding infrared signal is received, the user is notified that infrared noise exists, and the surrounding infrared signal is not received A remote control learning method for informing a user to transmit a remote control signal to be learned.