KR102166431B1 - Apparatus and method for controlling devices in a network - Google Patents

Abstract

The present invention relates to an apparatus and method for efficient operation control for devices constituting a network. The apparatus according to the present invention is an apparatus for controlling N target devices on a network, storing different control sequences for the N target devices, and controlling the operation of at least one of the N target devices. A user terminal that generates a control signal and transmits it to the network, and stores its own control sequence number that is the same as one of the control sequence numbers stored in the user terminal, receives the motion control signal, and stores the user terminal stored in the motion control signal. A control sequence number field comprising a target device that detects the content of information corresponding to the control sequence and executes an action command included in the action control signal according to the detection content, wherein the action control signal comprises the same number of bits as the N number of bits. And the target device executes the operation command when a bit at the same position as its control order in the bit arrangement order of the control order field has operation activation information. Here, N means a natural number of 2 or more.

Description

Efficient operation control apparatus and method for devices constituting a network {Apparatus and method for controlling devices in a network}

The present invention relates to an apparatus and method for efficient operation control for devices constituting a network. In more detail, the present invention relates to an apparatus and method for controlling the operation of target devices constituting a node of a MESH network while improving the efficiency of the data amount of the operation control signal.

Each of the target devices constituting the network, such as IoT devices, has its own address, and the method of setting and using the address is different depending on the wireless method. For example, WiFi uses IP address and Port, while Bluetooth uses BT address and UUID. As a recent technology using the Bluetooth method, the BLE-MESH network technology assigns a device unique ID to a random BT address for registration and control.

The operation control of the target devices is usually classified by the device unique ID, and the transmission of the operation control signal including the device unique ID and the operation command to a large number of target devices is a low power, low data rate target device. Not suitable for

As an example of a simple BLE-MESH network, each target device is connected to different devices in a mesh form, and each target device communicates with a unique device ID, and each target device controls its involvement. It executes the command of the signal and retransmits/transmits the control signal irrelevant to itself to the nearby target device. For example, assuming that there are 100 LED lamps as the target device, if the data amount for the unique ID of each target device needs 2 bytes, the control signal for controlling each target device at the same time is 100 * 2 = 200 bytes. The amount of data is required to distinguish the device to be controlled, and this excessive amount of data is inefficient for target devices with low power and low data rate, and 200 bytes must be divided several times for one operation control. There is a problem in that a parallax occurs between target devices during operation control. For example, in the case of BLE-MESH, a maximum of 30 bytes or less can be transmitted at a time, so about 7 times are divided and transmitted for one operation control.

An object of the present invention is to provide an apparatus and method for a user to conveniently and efficiently control the operation of target devices constituting a node of a MESH network using a mobile terminal while improving the efficiency of the amount of data of a motion control signal. .

According to an aspect of the present invention for achieving the object of the present invention, an apparatus for controlling N target devices on a network stores different control sequence numbers for the N target devices, and among the N target devices Stores a user terminal that generates an operation control signal for controlling at least one operation and transmits it to the network, and its own control order equal to one of the control order stored in the user terminal, and receives the operation control signal, And a target device that detects contents of information corresponding to the own control sequence stored among the operation control signals, and executes an operation command included in the operation control signal according to the detected contents.

The operation control signal includes a control sequence number field composed of the same number of bits as the N, and the target device has operation activation information in a bit at the same position as its control sequence in the bit arrangement order of the control sequence number field. To perform the above operation instruction. Here, N means a natural number of 2 or more.

According to an embodiment of the present invention, the control sequence number stored in the user terminal is characterized in that it consists of a series of consecutive natural numbers from 1 to N.

According to an embodiment of the present invention, the user terminal is characterized in that the device stores unique IDs for each of the N target devices and the control sequence number matched thereto.

According to an embodiment of the present invention, the user terminal provides a GUI for registering a target device through a display to a user, and when a device unique ID for a specific target device is input through the GUI, the device unique ID is It is characterized in that the corresponding control sequence numbers are sequentially allocated according to the input order.

According to an embodiment of the present invention, when the user terminal receives a selection of a device registration button through a GUI for registering the target device, the registration control including the N device unique IDs and a control sequence matching thereto A signal is generated and transmitted to the network, and the target device receives the registration control signal and detects and stores a control sequence number matched with a unique device ID of the registration control signal.

According to an embodiment of the present invention, the user terminal provides a GUI for deleting a target device through a display to the user, and when at least one of the registered target devices is selected through the GUI, the selected target device is It is characterized in that the unique ID information and the control sequence number information are deleted, and the control sequence numbers for the remaining target devices are re-allocated in a sequence numbering manner.

According to an embodiment of the present invention, when the user terminal receives a selection of a device registration button through a GUI for deleting the target device, the control sequence corresponding to the control sequence of the target device selected to be deleted in the control sequence number field A deletion control signal including information indicating that the order bit is activated is generated and transmitted to the network, and the target device controls its own control when the control order bit corresponding to its own control order is activated to be deleted. If the sequence number is deleted and the control sequence bit corresponding to the own control sequence number is not activated, it is detected whether the control sequence bit having a priority higher than the own control sequence number is deleted and activated, and the control sequence number of the priority that is activated to be deleted It is characterized in that the control sequence number is updated and stored in the order of the number of bits.

According to an embodiment of the present invention, the user terminal provides a user with a GUI for controlling operation of a target device through a display, and when a target device for operation control is selected from among target devices registered through the GUI. The operation control signal including information indicating that the control sequence bit corresponding to the control sequence number of the selected target device is activated is generated and transmitted to the network.

According to another aspect of the present invention, an apparatus for controlling N target devices on a network allocates and stores different control sequence numbers for the N target devices, and stores the control sequence numbers for the N target devices. A user terminal that generates a registration control signal to be used and transmits it to the network, and a target device that receives the registration control signal and detects and stores a control sequence number matching its own device ID among the registration control signals. do.

The registration control signal includes device unique IDs for the N target devices and N control sequence numbers matched thereto. Here, N means a natural number of 2 or more.

According to an embodiment of the present invention, the control sequence number is characterized in that it consists of a continuous series of natural numbers from 1 to N.

According to an embodiment of the present invention, the user terminal provides a GUI for registering a target device through a display to a user, and when a device unique ID for a specific target device is input through the GUI, the device unique ID is It is characterized in that the corresponding control sequence numbers are sequentially allocated according to the input order.

According to an embodiment of the present invention, when the user terminal receives a selection of a device registration button through a GUI for registering the target device, the registration control including the N device unique IDs and a control sequence matching thereto It is characterized in that the signal is generated and transmitted to the network.

According to the present invention, a user can conveniently and efficiently control the operation of target devices constituting a node of a MESH network while improving the efficiency of the data amount of the operation control signal using a mobile terminal.

1 is a schematic configuration diagram of an apparatus according to an embodiment of the present invention.
2 is a schematic configuration diagram of a user terminal according to an embodiment of the present invention.
3 is a schematic configuration diagram of an object device according to an embodiment of the present invention.
4 is a flowchart illustrating a method of registering and deleting a target device according to an embodiment of the present invention.
5 is a flowchart illustrating a detailed method of registering and deleting a target device in a user terminal according to an embodiment of the present invention.
6 and 7 are diagrams illustrating a process of registering a target device through a GUI according to an embodiment of the present invention.
8 is a diagram illustrating a process of deleting a target device through a GUI according to an embodiment of the present invention.
9 is a view for explaining information included in a registration control signal according to an embodiment of the present invention.
10 is a diagram for describing information included in a deletion control signal according to an embodiment of the present invention.
11 is a flowchart illustrating a method of controlling an operation of a target device according to an embodiment of the present invention.
12 is a diagram for explaining controlling an operation of a target device through a GUI according to an embodiment of the present invention.
13 is a diagram for describing a configuration of a motion control signal according to an embodiment of the present invention.
14 is a diagram for explaining a process of registering a target device through a GUI according to another embodiment of the present invention.
15 is a diagram for explaining controlling an operation of a target device through a GUI according to another embodiment of the present invention.
16 is a diagram illustrating control of a unit cluster consisting of a hierarchical classification system according to another embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic configuration diagram of an apparatus according to an embodiment of the present invention.

Referring to FIG. 1, the apparatus of the present invention may include a user terminal 100 and a network 200 comprising a plurality of target devices 210.

The user terminal 100 is a mobile terminal, and may include a device capable of performing communication with a network using wireless communication such as a smartphone, a tablet PC, and a notebook. The user terminal may transmit a registration control signal, an operation control signal, and the like to target devices on the network 200 using wireless communication.

The network 200 may include a MESH network, and a target device 210 is located at each node of the MESH network. The MESH network may be configured by a communication method such as Bluetooth or WiFi, and the target device of each node performs wireless communication with nearby devices. The number of target devices is 2 or more.

2 is a schematic configuration diagram of a user terminal according to an embodiment of the present invention.

1 and 2, the user terminal 100 may include a control unit 110, a communication unit 120, a memory 130, and a display 140.

The controller 110 controls each component of the user terminal. In particular, by executing the dedicated app 132 stored in the memory 130, the GUI (Graphical User Interface) of the dedicated app 132 is controlled to be displayed on the display 140, and the control sequence of the target devices 210 Is assigned, and generates a registration control signal, a deletion control signal, and an operation control signal to the target devices, and transmits them to the network 200 through the communication unit 130.

The communication unit 120 may communicate with the target device 210 on the network 200 using wireless communication. The communication unit 120 may perform short-range wireless communication such as Bluetooth and WiFi, and modify a registration control signal, a deletion control signal, and an operation control signal transmitted from the control unit 110 according to a prescribed wireless communication method, and the target device ( 210).

The memory 130 may store various types of information and programs necessary for controlling the operation of the user terminal 100. In particular, in the memory 130, a dedicated app 132 for registering a control sequence of target devices and executing operation control according to an embodiment of the present invention is stored in the form of a program. In the present description, for convenience of explanation, as an example is described that the user terminal is a smart phone, the term “app” is only used, but is not limited to an app for a smart phone.

The display 140 displays a GUI generated according to the execution of the dedicated app 132 and provides it to the user.

3 is a schematic configuration diagram of an object device according to an embodiment of the present invention.

1 and 3, the target device 210 may include a control unit 212, a communication unit 214, a memory 216, and a driving unit 218.

The control unit 212 controls each configuration of the target device. In particular, by processing the registration control signal, the deletion control signal, and the operation control signal received through the communication unit 214, the control sequence number detected from the registration control signal is stored in the memory 216, or the The control sequence number of is deleted or updated and stored, or the operation command detected by the operation control signal is controlled to be executed through the driving unit 218, and the registration control signal, the deletion control signal, and the operation control signal are transmitted to the surrounding area through the communication unit 214. Make it delivered to the target device.

The communication unit 214 may communicate with the target device 210 on the network 200 using wireless communication. The communication unit 214 may perform short-range wireless communication such as Bluetooth, WiFi, etc., and transform the received registration control signal, deletion control signal, and operation control signal according to a prescribed wireless communication method to the surrounding target device 210 I can deliver.

The memory 216 may store various types of information and programs necessary for controlling the operation of the target device 210. In particular, it is possible to store its own device ID and store its own control sequence number detected in the registration control signal. The memory may be a nonvolatile memory.

The driver 210 may perform an operation command detected from the operation control signal. For example, when the target device is an LED lamp, ON/OFF control and/or illuminance control, when a locking device is a lock/unlock control, and when a curtain is an open/close control, it is possible. In the present description, for convenience of explanation, the target device is an LED lamp.

4 is a flowchart illustrating a method of registering and deleting a target device according to an embodiment of the present invention.

1 to 4, when the dedicated app 132 is executed in the user terminal 100, a GUI is displayed on the display 140 (S402).

In the user terminal 100, a target device for registration or deletion is registered and deleted through a GUI (S404).

5 is a flowchart illustrating a detailed method of registering and deleting a target device in a user terminal according to an embodiment of the present invention.

Referring to FIG. 5, it is determined whether the process of registering the target device or deleting the target device (S4042).

In the process of registering a target device, information of a specific target device is input through the GUI, a corresponding control sequence number is assigned (S4044), and step S4044 is repeated until all desired number of target devices are registered (S4045).

6 and 7 are diagrams illustrating a process of registering a target device through a GUI according to an embodiment of the present invention.

6 and 7 show an example of registering three LED lamps at once.

When the dedicated app 132 is first executed by the user touching the dedicated app icon on the touch screen of the user terminal, the registration processing screen 600 is displayed in an initial state (a). The registration processing screen 600 in the initial state may include a classification system display field 602 indicating that the registration processing screen is a registration processing screen, an add button 604, and a device registration button 608.

When the add button 604 is selected in the above (a), the device information input screen 700 is displayed (b). The device information input screen 700 includes a registration display field 702 indicating that it is a device information input screen, and a device unique ID input field through which a user can input a device unique ID (eg, 1001) through a keyboard on the GUI. 704), a password input field 706 for inputting a password as needed, a name input field 708 for inputting a registration name (e.g., lighting 1) of the target device, and a self registration button 710 Can be included. Here, the device unique ID is to be able to identify itself from other devices, and may be a unique Product ID allocated during the production process.

When the self-registration button 710 is selected in the above (b), the first registration processing screen including the illumination 1 to which the control sequence is assigned is displayed (c). The registration processing screen 600 may further include a select all button 603 for selecting all target devices of the unit cluster, and a first target device button 605 corresponding to the registration name illumination 1.

In addition, information on the registration status is stored in the memory 130 of the user terminal in the form of a registration status table shown on the right side of the figure. That is, the target device of assigned control sequence #1 has the registration name of lighting 1, the device unique ID is 1001, the current state of the target device is OFF, and the total number of registered devices constituting the unit cluster is 1. do.

When the add button 604 is selected in (c) above, the device information input screen 700 is displayed (d). Hereinafter, descriptions of the same buttons and the same fields on the GUI will be omitted. A user can input a device unique ID of 1002 through a keyboard or the like on the GUI, and can input a registration name of lighting 2.

When the self-registration button is selected in (d) above, a registration processing screen that further includes illumination 2 to which the control sequence number is assigned is displayed (e). The registration processing screen 600 may further include a second target device button 606 corresponding to the registration name illumination 2.

In addition, information on the registration status is stored in the memory 130 of the user terminal in the form of a registration status table shown on the right side of the figure. In other words, the target device of assigned control sequence #2 has the registration name of lighting 2, the device unique ID is 1002, the current state of the target device is OFF, and the total number of registered devices constituting the unit cluster is 2. do.

When the add button is selected in (e) above, the device information input screen 700 is displayed (f). The user can input the device unique ID of 1003 through the keyboard on the GUI, and can input the registration name of Lighting 3.

When the self-registration button is selected in (f) above, the thirdly, the registration processing screen including the illumination 3 to which the control sequence is assigned is displayed (g). The registration processing screen 600 may further include a third destination device button 607 corresponding to the registration name illumination 3.

In addition, information on the registration status is stored in the memory 130 of the user terminal in the form of a registration status table shown on the right side of the figure. That is, the target device of assigned control sequence #3 has the registration name of lighting 3, the device unique ID is 1003, the current state of the target device is OFF, and the total number of registered devices constituting the unit cluster is 3. do.

Here, as for the control sequence, the sequence numbers are automatically assigned in the order of natural numbers in sequence according to the registration sequence. In the registration processing screen 600, it can be seen that the arrangement order from the upper side corresponds to the control order number.

The above (g) shows that 3 target devices are arranged on the registration processing screen, but if there are a larger number of target devices, the registered target device goes over the partitioned screen, so the user scrolls up and down the screen. You can check the registration of the target device with.

Returning to FIG. 5 again, the process of deleting the target device from the user terminal includes selecting a target device to be deleted from among target devices registered through the GUI (S4048), deleting the selected target device, and then deleting the deleted target device. The control sequence numbers for the other registered target devices are reassigned (S4049).

8 is a diagram illustrating a process of deleting a target device through a GUI according to an embodiment of the present invention.

When described by reflecting the description in FIG. 7, when the dedicated app 132 is executed in the user terminal, the registration processing screen 600 is displayed as shown in FIG. 8(a), and the registration processing screen 600 is 3 It shows that two target devices are registered, and when the user touches the add button 604 with a finger (902) and drags it to the right, in FIG.8(b), the add button 604 is a delete button 904 When the property is converted to and, in Fig. 8(c), when you select the first illumination 1 605, which is the first among the three registered target devices, and select the delete button 904, in Fig. 8(d), After the illumination 1 is deleted from the registration processing screen 600, the remaining registration devices, illumination 2 606 and illumination 3 607, are rearranged in a push-up manner, and an additional button is rearranged.

In this case, information on the registration status is updated and stored in the memory 130 of the user terminal in the form of a registration status table shown on the right side of the figure. The control sequence number is reassigned in a sequence numbering manner to fill the control sequence number of the deleted device. That is, the target device of reassigned control sequence #1 has the registered name of lighting 2, the device unique ID is 1002, the current state of the target device is OFF, and the target device of the reassigned control sequence #2 is lighting. It is stored that it has a registration name of 3, the device unique ID is 1003, the current state of the target device is OFF, and the total number of registered devices constituting the unit cluster is 2.

Depending on the embodiment, a unit having a control sequence number of 1 (unique ID 01), 2 (unique ID 02), 3 (unique ID 03), 4 (unique ID 04), and 5 (unique ID 05) If the 2nd and 4th sequence numbers are deleted from the cluster at the same time, the device with the unique ID 03 that was the 3rd sequence will be reassigned to the 2nd sequence, and the device with the unique ID 05 that was the 5th sequence will be reassigned to the 3rd sequence. It can be seen that the total number of registered devices to be configured can be adjusted to 3.

Returning to FIG. 4, the user terminal 100 transmits a registration control signal or a deletion control signal to the network 200 to which the target devices belong (S406).

9 is a view for explaining information included in a registration control signal according to an embodiment of the present invention.

When the device registration button 608 is selected in FIG. 7(g), the total number of registered devices in the unit cluster for controlling the sequence registration operation is 3, the device ID 1001 is the control sequence number #1, and the device ID 1002 A registration control signal indicating that the control sequence number is #2 and the device ID 1003 is the control sequence number is #3, and is transmitted to the network 200.

10 is a diagram for describing information included in a deletion control signal according to an embodiment of the present invention.

When the device registration button 608 is selected in (d) of FIG. 8, the information field includes the total number of registered devices as 3, the command field includes the command DEL (i.e., delete command), and the control sequence number consisting of 3 bits Deletion control in which the control sequence bit corresponding to the control sequence device to be deleted in the field is activated as 1 (i.e., the control sequence bit 1 corresponding to the control sequence number 1, which is the control sequence before deletion for lighting 1 is activated as 1) The signal is generated and transmitted to the network 200.

According to an exemplary embodiment, if all of the lights 1, 2, and 3 are selected to be deleted in FIG. 8, all of the 1st, 2nd, and 3rd control sequence bits will be activated as 1 in the control sequence field in the deletion control signal.

Returning to FIG. 4, the destination device 210 on the network 200 receives a registration control signal or a deletion control signal (S408).

The target device 210 detects its own control sequence number from the received registration control signal and stores it in the memory 216, or deletes its own control sequence number stored in the memory 216 according to the received deletion control signal, or The control sequence number is updated and stored, and a registration control signal or a deletion control signal is transmitted to the surrounding target device 210 (S410).

Upon receiving the registration control signal, the target device 210 detects a control sequence number matching its own device ID in the registration control signal, and stores the detected control sequence in the memory 216.

The target device 210 receiving the deletion control signal detects whether a control sequence bit corresponding to the control sequence stored in the control sequence field of the deletion control signal is activated, and If the corresponding control sequence bit is activated, the control sequence number stored in the memory 216 is deleted.

If the control sequence bit corresponding to the own control sequence number is not activated, the position of the control sequence bit that is activated to be deleted from the other control sequence bit in the control sequence field and the control sequence bit higher than the own control sequence number are deleted. It detects the number of control sequence bits and updates and stores its own control sequence number in a sequence numbering method.

For example, in the example of FIG. 10, since only the 1st control sequence bit is activated to be deleted, the 1st control sequence, illumination 1 (unique ID 1001), deletes its own control sequence from the memory, and the 2nd control sequence In lighting 2 (unique ID 1002) deletes one bit in the priority order than itself, so its own control sequence is updated and stored in the control sequence number 1, up from 2 times, and lighting 3 is the control sequence number 3 (Unique ID 1003) has one bit higher than its own and is activated to delete it, so its own control sequence is updated and saved from 3 to 1, up to 2 control sequence.

Depending on the example, if 6 target devices are registered in the unit cluster and control sequence number 2 and control sequence number 5 are deleted, the control sequence bits 2 and 5 in the control sequence field have deletion activation information. The operation of each target device that has received the deletion control signal will be as follows.

In other words, since the control sequence device No. 1 maintains its own control sequence, the control sequence device No. 2 deletes its control sequence, and the control sequence device No. 3 deletes 1 from its priority (i.e., delete control signal Since one bit is deleted from the bit higher than its own in the control sequence field of (i.e., 1 bit is deleted from the bit higher than itself), it is updated and stored with the control sequence number 2, which is raised 1 times, and the device of the control sequence number 4 has deleted 1 bit from the priority level than itself (i.e. In the control sequence number field of the delete control signal, one bit is deleted from the bit higher than its own.) It is updated and stored in the control sequence number 3, which is raised 1 times, and the control sequence device number 5 deletes its own control sequence number. The 6th control sequence device is updated to the 4th control sequence, which is raised 2 times because 2 bits have been deleted from the priority of the device (that is, 2 bits are deleted from the bit of the priority higher than itself in the control sequence field of the deletion control signal). Save it.

The target device whose control sequence has been deleted does not perform any other special operation even if it receives an operation control signal according to an embodiment of the present invention, but only transmits the signal to other nearby target devices.

11 is a flowchart illustrating a method of controlling an operation of a target device according to an embodiment of the present invention.

12 is a diagram for explaining controlling an operation of a target device through a GUI according to an embodiment of the present invention.

Referring to FIGS. 11 and 12, when the dedicated app 132 is executed in the user terminal 100, a registration processing screen 600 is displayed as in FIG. 12A (S1102).

When the target device buttons 605 and 607 for operation control are selected on the registration processing screen 600 (S1104), the buttons are displayed brightly.

When the device registration button 608 is selected on the registration processing screen 600, the control unit 110 of the user terminal 100 generates an operation control signal and transmits it to the network including the target devices (S1106). At this time, in the registration status table for the unit cluster stored in the memory 130, as shown in FIG. 12(b), the states of target devices with control order #1 and #3 are changed to ON and registered.

13 is a diagram for describing a configuration of a motion control signal according to an embodiment of the present invention.

The information field contains information on the total number of devices registered in the unit cluster, the command field contains the corresponding operation command (lamp ON), and the control sequence field contains the same number of control sequence bits as the total number of registered devices. . The control sequence bits can represent digital signals 1 and 0, and the arrangement order of the control sequence bits means the control sequence number. That is, the first control sequence bit corresponds to the control sequence #1, the second control sequence bit corresponds to the control sequence #2, and the third control sequence bit corresponds to the control sequence #3.

In the example of FIG. 13, the target device corresponding to control sequence #1 and #3 (i.e., the target device having unique IDs 1001 and 1003) in which the corresponding control sequence bit is activated as 1 turns on the lamp, and the control sequence number The target device corresponding to #2 (ie, unique ID 1002) means that the corresponding control sequence bit is inactive, so that the operation command should not be executed.

By doing so, the amount of data for discriminating the target device for which operation control is desired is significantly reduced compared to using the unique ID of the target device. For example, if 8 bits of information are required for one unique ID, 80 bits of data amount is required for a unit cluster including 10 target devices, but only 10 bits are sufficient in the case of the present invention.

Returning to FIG. 11, the target device 210 receives an operation control signal (S1108).

The target device 210 detects information of a control sequence bit corresponding to its own control sequence number stored in the memory from the received motion control signal, and executes an operation command included in the motion control signal according to the information of the detected control sequence bit. Then, the operation control signal is transmitted to another target device in the vicinity (S1110).

12 and 13, the target device with device ID 1001 turns on the lamp, and the target device with device ID 1002 does not execute an operation command (i.e., ignores the operation command), and device ID 1003 The intent device is to perform the lamp ON.

14 is a diagram for explaining a process of registering a target device through a GUI according to another embodiment of the present invention.

1 to 13 illustrate examples of a single unit cluster in which a target device is distinguished by its own control order. 14 is for explaining a case of having a hierarchical classification system having a control sequence number of a higher concept for distinguishing a bundle of a plurality of target devices. In the present embodiment, a hierarchical classification system in which the control order is composed of a main group order, a subgroup order, and an end order is described.

For example, this is the case when a target device installed in a building consisting of several floors is divided into floors, rooms, etc. and controlled.

In (a) of FIG. 14, when the dedicated app 132 is first executed in the user terminal, the group display screen 500 in an initial state is displayed. The group display screen 500 includes a group display field 502 indicating that it is a screen for creating a group, a create button 503 for creating an individual group, and a next button 504 for moving to the next step. can do.

In FIG. 14B, when the next button 504 in the above (a) is selected, the operation control method for a single unit cluster described in FIGS. 1 to 13 is applied as it is.

In (c) of FIG. 14, when the create button 503 in the above (a) is selected, a group name input field 505 for inputting a group name (eg, the first floor) for the main group order #1 is opened. The included group display screen 500 is displayed.

In (d) of FIG. 14, when the group name input field 505 is selected in the above (c) and the next button 504 is selected, the registration processing screen where "first floor" is displayed in the classification system display field 602 ( 600) is displayed. Subsequently, the registration process of the target device is the same as described in FIGS. 6 and 7.

In (e) of Fig. 14, when the group name input field 505 is selected in the above (c) and the create button 503 is selected, "first floor" is displayed in the group display field 502, and the subgroup order A group display screen 500 including a subgroup name input field 506 for inputting a subgroup name for #1 (eg, office 1) is displayed.

Although not shown in the drawing, if the create button 503 is selected while the group name input field 505 is not selected in the above (c), a group for entering a group name (eg, second floor) for group order #2 A group display screen 500 including a name input field 505 will be displayed.

In (f) of FIG. 14, when the subgroup name input field 506 is selected in the above (e) and the next button 504 is selected, registration with "1st floor office 1" displayed in the classification system display field 602 The processing screen 600 is displayed. Subsequently, the registration process of the target device is the same as described in FIGS. 6 and 7.

In (g) of FIG. 14, when the create button 503 is selected while the subgroup name input field 506 is not selected in the above (e), "first floor" is displayed in the group display field, and the subgroup order number A group display screen 500 including a subgroup name input field 506 for inputting a subgroup name for #2 (eg, office 2) is displayed. Here, although not shown in the drawing, when the subgroup name input field 506 is selected and the next button 504 is selected, the registration processing screen in which "1st floor office 2" is displayed in the classification system display field similar to (f) above. Will be displayed.

15 is a diagram for explaining controlling an operation of a target device through a GUI according to another embodiment of the present invention.

In FIG. 15, operation control of a target device in a classification system having a total of five unit clusters consisting of two main groups and five subgroups is described.

In (a) of FIG. 15, when the dedicated app 132 is executed on the user terminal, a first main group button 507 for two main groups (1st and 2nd floor) and a second main group button ( A group display screen 500 including 508 is displayed. In addition, it is displayed that the first floor of the main group with main group order #1 includes two subgroups, and the second floor of the main group with main group order #2 includes three subgroups.

Although not shown in the drawing, if the create button 503 is selected without any of the main group buttons selected in (a), the group name for the main group order #3 (for example, similar to FIG. 14(c)) A group display screen 500 including a group name input field 505 for inputting (3rd floor) will be displayed.

Although not shown in the drawing, if the first group button 507 is selected in (a) and the create button 503 is selected, a group name for subgroup order #3 (for example, A group display screen 500 including a subgroup name input field 506 for inputting the office 3) will be displayed.

In Figure 15 (b), in Figure 15 (a) above, when the first group button 507 corresponding to the first floor of the main group is selected and the next button 504 is selected, "first floor" is displayed. A classification system display field 802 is included, and a first subgroup button 805 indicating office 1 with subgroup order #1 and a second subgroup button 806 indicating office 2 with subgroup order #2. The subgroup display screen 800 is displayed.

In Fig. 15(c), in Fig. 15(b) above, when the first subgroup button 805, which is office 1 with subgroup order #1, is selected, the classification system is displayed with "1st floor office 1" A registration processing screen 600 including a field 602 and including two target device buttons 605 and 606 is displayed.

Thereafter, using the registration processing screen 600, refer to Figs. 6, 7, 8, and 12 above for operation control, registration, and deletion of the target device for the unit cluster (i.e., 1st floor office 1 total number of registered devices 2). As described above, it is the same as described above, so it will be omitted.

16 is a diagram illustrating control of a unit cluster consisting of a hierarchical classification system according to another embodiment of the present invention.

Here, the hierarchical classification system described in FIG. 15 will be described as an example. In other words, in a hierarchical classification system in which there are two main groups, two subgroups are included on the first floor with main group order #1, and three subgroups are included on the second floor with main group order #2, the main group The control of the first unit cluster of order #1 and subgroup order #1 will be described.

16A is a registration status table for a first unit cluster. It can be seen that the main group information and subgroup information are further included in the registration status table described in (e) of FIG. 7.

FIG. 16B is a diagram for explaining a registration control signal transmitted to a target device included in a first unit cluster.

In the registration control signal, the number of main groups is 2, the number of subgroups is 2, the total number of registered devices in the unit cluster is 2, the main group sequence number is 1 (#1), and the subgroup sequence number is 1 (#1). , Information that the end sequence number of the device with the unique ID 1001 is 1 (#1) and the end sequence number of the device with the unique ID 1002 is 2 (#2) is included.

The target device with a unique ID of 1001, which has received the registration control signal, stores in its memory that the main group sequence number is 1, the subgroup sequence number is 1, and the end sequence number is 1, and receives the registration control signal. The target device with ID 1002 stores that the main group sequence number is 1, the subgroup sequence number is 1, and the end sequence number is 2 in its memory.

FIG. 16C is a diagram illustrating an operation control signal transmitted to a target device included in a first unit cluster.

The information field contains information indicating that the number of main groups is 2, the number of subgroups is 2, and the number of registered devices is 2, the command field contains the corresponding command information, and the control sequence number field can express digital information 1 or 0. It consists of N bits (here, N=6). 2 main group bits (main group order #1 bit, main group order #2 bit), 2 subgroup bits (subgroup order #1 bit, subgroup order #2 bit), ( N-number of main groups-number of subgroups) end bits (end #1 bit, end #2 bit) may be included.

The target device that has received the motion control signal compares the main group order, subgroup order, and end order stored in its memory with the bit arrangement order of the control order field, and the bit in the control order field corresponding to the stored control order is set to 1. After determining whether it is activated, the command is executed.

Referring to (b) and (c) of FIG. 16, a target device having a unique ID of 1001, which has received an operation control signal, has a main group sequence bit, a subgroup sequence bit, and an end bit corresponding to its own control sequence number. The target device with a unique ID of 1002, which has received the operation control signal, has the main group sequence bit and the subgroup sequence bit corresponding to its own control sequence as 1, but it will turn on the lamp. Since the bit is deactivated to 0, no action command will be executed.

Although not shown in the drawing, if the fourth unit cluster with main group order #2 and subgroup order #2 is composed of a total of 4 devices, the registration status table includes main group order #2, subgroup order #2, and terminal order # Information on 1 to #4, the total number of registered devices 4 will be registered.

The registration control signal for this includes the number of main groups 2, the number of subgroups 3, the total number of registered devices 4, the main group sequence number #2, the subgroup sequence number #2, the unique ID for the corresponding 4 target devices, and the matching terminal sequence number information. Will be included.

The operation control signal for this includes the number of main groups 2, the number of subgroups 3, and the total number of registered devices 4, main group order #2 bit among the two main group bits, subgroup order #2 bit among the three subgroup bits Is activated as 1, and the last bit corresponding to the end sequence number of the target device for controlling the operation among the four end bits will be activated as 1.

In the above, the embodiments of the present invention have been described in detail. The scope of protection of the present invention is not limited to the above-described embodiments, and anyone of ordinary skill in the art can easily see that various modifications and variations are possible within the limits not departing from the spirit and scope of the invention indicated by the claims. will be.

100: user terminal 200: network
110: control unit 120: communication unit
130: memory 132: dedicated app
140: display
210: target device
212: control unit 214: communication unit
216: memory 218: driver
500: Group display screen
600: Registration processing screen
700: Device information input screen
800: Subgroup display screen

Claims (12)

An apparatus for controlling N target devices on a network,
A user terminal that stores different control order numbers for the N target devices, generates a single motion control signal for selectively controlling at least one of the N target devices, and transmits it to the network,
It stores its own control sequence which is the same as one of the control sequence numbers stored in the user terminal and is different from each other, receives the motion control signal, and detects the contents of information corresponding to the own control sequence stored in the motion control signal, , Each N target devices for performing an operation command included in the operation control signal according to the detected content,
The operation control signal includes a control sequence number field consisting of the same number of bits as the N,
Each of the N target devices executes the operation command when a bit at the same position as its control order in the bit arrangement order of the control order field has operation activation information.
Here, N means a natural number of 2 or more. The method of claim 1,
The apparatus according to claim 1, wherein the control sequence number stored in the user terminal consists of a series of consecutive natural numbers from 1 to N. The method of claim 2,
And the user terminal stores device unique IDs for the N target devices and the control sequence number matching thereto. The method of claim 3,
The user terminal,
Provides a user with a GUI for registering a target device through a display,
When a device unique ID for a specific target device is input through the GUI, corresponding control sequence numbers are sequentially allocated according to the input order of the device unique ID. The method of claim 4,
When the user terminal receives a selection of a device registration button through a GUI for registering the target device, the user terminal generates a registration control signal including the N device unique IDs and a control sequence number matching thereto and transmits it to the network. ,
And the target device receives the registration control signal and detects and stores a control sequence number matched with a unique device ID of the registration control signal. The method of claim 3,
The user terminal,
Provide the user with a GUI for deleting the target device through the display,
When at least one of the target devices registered through the GUI is selected, the unique ID information and the control sequence number information for the selected target device are deleted, and the control sequence numbers for the remaining target devices are reassigned in a sequential order. Device. The method of claim 6,
When the user terminal receives the selection of the device registration button through the GUI for deleting the target device, the user terminal provides information indicating that the control sequence bit corresponding to the control sequence number of the target device selected to be deleted in the control sequence number field is activated. Generating a deletion control signal containing and transmitting it to the network,
The target device,
When the control sequence bit corresponding to the own control sequence number is activated to be deleted, the own control sequence number is deleted,
If the control sequence bit corresponding to the own control sequence number is not activated, it is detected whether the control sequence bit having a higher priority than the own control sequence number is activated, and the number of control sequence bits of the priority activated to be deleted is activated. An apparatus, characterized in that for updating and storing its own control sequence in a rolling manner. The method of claim 3,
The user terminal,
Provides a user with a GUI for controlling the operation of a target device through a display,
When a target device for operation control is selected among target devices registered through the GUI, a motion control signal including information indicating that the control sequence bit corresponding to the control sequence number of the selected target device is activated is generated and transmitted to the network. Device, characterized in that. delete delete delete delete

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