KR20090020194A - Wireless control switch device, wireless control lighting device, wireless power control system and wireless power control method by using the same - Google Patents

Abstract

A wireless control switch device, wireless control lighting device, wireless power control system, and wireless power control method using the same are provided to prevent the leakage current due to the power line and the wire waste in proportion to the length of the power line. The wireless control switch device(200) comprises a switch, a switch storage, a controller(240), a switch frequency processor(220), a switch frequency transmitter(210) and a power supply(250). The switch transmits the operating signal. The switch storage stores the second magnetism characteristic value. The switch controller outputs the driving control signal and the first digital signal including the second magnetism characteristic value. The switch frequency processor converts the first digital signal into the first carrier signal. The switch frequency transmitter transmits the first carrier signal. The power supply unit supplies the power source to the controller and the switch frequency processor.

Description

Wireless control switch device, wireless control lighting device, wireless power control system and wireless power control method using same {Wireless Control Switch Device, Wireless Control Lighting Device, Wireless Power Control System and Wireless Power Control Method by using the Same}

The present invention relates to a wireless power control system using a radio frequency (RF) and a wireless power control method using the same, and more particularly, to a wireless control switch device using a radio frequency (RF) and a lighting device controlled wirelessly. .

In the lighting flickering device, in the conventional method of flashing the light through the switch unit provided in the wall, the first power line coming from the distribution panel is connected to the lighting unit, and the second power line is configured to be connected to the lighting unit via the switch unit.

Since the switch unit is generally provided at a position reachable by the user, the switch unit is generally located on the wall of the building. Accordingly, a power line applied to the switch unit is wired inside the wall, and a plurality of switch units corresponding to individual lights are provided. The wiring of the applied power lines should be formed inside the walls of the building.

Accordingly, there is an inconvenience in forming the wiring of the power line inside the wall when constructing the building, and also inconvenient to break down the wall when the power line is relocated by changing the position of the switch unit and renovating the building. .

In addition, there is a problem that a leakage current is generated by the power line connected to the lighting unit through the switch panel from the distribution panel, there is a problem that the waste of the wire proportional to the length of the power line.

As a method for overcoming this, the Korean Utility Model Publication No. 20-1992-0018806 is flashing including a switch unit including an infrared (IR) transmission module and an infrared receiving module that can be operated by the infrared transmission module. A method of omitting a power line formed inside a wall and connected to a switch part is described by configuring as an illumination part.

However, in the case of the infrared (IR) communication method, due to the straightness of the infrared ray used as a signal transmission means and the non-transmissive nature of the obstacle, the wireless switch and the electric / electronic device controlled by the infrared ray should be exposed in a straight line. If there is an obstacle between the modules there is a problem that the light can not blink.

In addition, the Republic of Korea Registered Utility Model Publication No. 20-0300994 and the Republic of Korea Registered Utility Model Registration No. 20-0430386 technology to apply the radio frequency (RF) communication method in order to overcome the problems of the above infrared (IR) communication method This is described.

However, in the above invention, since the power line of the switch unit formed inside the wall is configured as it is, it is inconvenient to form the wiring of the power line inside the wall when constructing the building, and the position of the switch unit is changed and the renovation of the building is performed. It is not overcoming the problem of tearing down the wall when the power line is relocated.

In addition, in the method of controlling a radio communication device using radio frequency (RF), the transmitting module and the receiving module of the radio frequency communication device must synchronize the radio frequency (RF) intrinsic value (ID) with each other. That is, the radio frequency (RF) unique value (ID) of the switch corresponding to the lighting unit should be synchronized with each other. Depending on whether the antenna is attached to the receiver of the radio frequency communication module, the communication radius may be up to several tens of meters.

Accordingly, when the product is installed in a building using a transmission / reception module with initial eigenvalues set, other transmission / reception modules having the same eigenvalues within a communication radius are generated by other transmission / reception modules. There is a problem that can be malfunctioned by the signal.

In addition, in order to overcome the above problems, if any eigenvalues of all transmit / receive modules are assigned by any institution so that the initial eigenvalues do not overlap, unnecessary occupancy of the eigenvalues occurs, and this increases as the quantity of products increases. In order to cope, there is a problem in that the number of bits for the eigenvalue is increased.

An object of the present invention is to solve the inconvenience of forming the wiring of the power line inside the wall when constructing the building, and the inconvenience of having to break down the wall when repositioning the power line by changing the position of the switch unit and renovating the building. It is to.

Another object of the present invention is to solve the problem of a leakage current generated by a power line connected to a lighting unit via a switch unit from a distribution panel and a problem of waste of wires proportional to the length of the power line.

Another object of the present invention is to prevent the occupancy of the device inherent value for unnecessary radio frequency (RF), and to solve the problem that may be malfunctioned by the signal generated by the other transmission / reception module.

Wireless power control method according to an embodiment of the present invention for achieving the above object comprises the steps of receiving a peripheral frequency signal within a predetermined bandwidth; Converting the peripheral frequency signal into a peripheral digital signal; Reading the peripheral digital signal to extract the occupied eigenvalues; Storing at least one of the values that do not overlap with the occupied eigenvalues as a first magnetic eigenvalue in the lighting device storage of the radio controlled lighting device, and a second magnetic eigenvalue in the switch device storage of the wireless control switch device; Storing as; Transmitting a first transmission signal including the second magnetic eigenvalue by the radio control switch device; And reading the second magnetic eigenvalue from the first transmission signal transmitted from the wireless control switch device in the radio control lighting device to determine whether the first magnetic eigenvalue coincides with the first magnetic eigenvalue.

The storing of the second self eigen value in the switch device storage unit of the radio control switch device includes at least one of values not overlapping with the occupied eigen values. It is preferable to proceed after storing as the first magnetic eigenvalue.

The second magnetic eigenvalue is the same as the first magnetic eigenvalue included in the second transmission signal by the wireless control lighting device to transmit a second transmission signal including the first magnetic eigenvalue. It is preferable.

After storing the at least one value of the occupied eigenvalue that does not overlap with the occupied eigenvalue to the lighting device storage of the radio controlled lighting device as the first magnetic eigenvalue, the radio controlled lighting device is configured to store the first magnetic value. It is desirable to continuously transmit the third transmission signal including the eigenvalues.

The peripheral digital signal preferably includes a preamble portion and the occupied eigenvalues.

The extracting the eigenvalues occupied by reading the peripheral digital signal may include determining whether the preamble part is included in the peripheral digital signal.

Preferably, the first transmission signal further includes a drive control signal before or after the second magnetic eigenvalue.

Preferably, the second transmission signal further includes a registration control signal before or after the first magnetic eigenvalue.

Preferably, the third transmission signal further includes an occupation control signal before or after the first magnetic eigenvalue.

Wireless control lighting apparatus according to an embodiment of the present invention for achieving the above object, the lighting device frequency transmitting and receiving unit for receiving a peripheral frequency signal within a predetermined bandwidth; An illumination device frequency processor converting the peripheral frequency signal into a peripheral digital signal; An illumination device controller which reads the surrounding digital signal and extracts an occupied eigenvalue; And an illumination device storage unit which stores at least one of the values that do not overlap with the occupied eigenvalues as a first magnetic eigenvalue.

Wireless control lighting apparatus according to another embodiment of the present invention for achieving the above object, the lighting device frequency transceiver for receiving a first transmission signal or a second transmission signal within a predetermined bandwidth; Illuminator frequency which converts and transmits the first transmission signal received from the illumination device frequency transceiver to a first digital signal or converts the received second digital signal into the second transmission signal and sends it to the illumination device frequency transceiver Processing unit; An illumination device storage unit for storing a first magnetic eigenvalue; A second magnetic eigenvalue included in the first digital signal, read from the first digital signal input from the lighting device frequency processor, and stored in the lighting device storage; A lighting device controller which determines whether or not the first magnetic eigenvalue matches the power control signal to a power control signal line, and transmits the second digital signal including the first magnetic eigenvalue to the lighting device frequency processor; And a power relay switch configured to flash an illumination unit by the power control signal received from the lighting device control unit through the power control signal line.

Wireless control switch device according to an embodiment of the present invention for achieving the above object, the switch unit for transmitting an operation signal; A switch device storage unit storing a second magnetic eigenvalue; A switch device control unit connected to the switch unit and transmitting a first digital signal including a driving control signal generated by the operation signal transmitted from the switch unit and a second magnetic eigenvalue stored in the switch device storage unit; A switch device frequency processor connected to the switch device controller and converting the first digital signal transmitted from the switch device controller into a first transmission signal; A switch device frequency transmitter connected to the switch device frequency processor and transmitting the first transmission signal transmitted from the switch device frequency processor; And a power supply unit for supplying power to the switch device control unit and the switch device frequency processing unit.

Wireless power control system according to an embodiment of the present invention for achieving the above object, a lighting device frequency transceiver for receiving a first transmission signal, or transmits a second transmission signal, the first transmission signal to the first digital signal A lighting device frequency processor for converting and transmitting a second digital signal to the second transmission signal and transmitting the converted second digital signal to the lighting device frequency transceiver, a lighting device storage unit for storing a first magnetic eigenvalue, and the first A first digital signal is read to determine whether a second magnetic eigenvalue included in the first digital signal coincides with the first magnetic eigenvalue stored in the lighting device storage, and includes the first magnetic eigenvalue. A wireless control lighting device including a lighting device control unit for transmitting the second digital signal to the lighting device frequency processing unit; And a switch unit for transmitting an operation signal, a switch device storage unit for storing a second self eigenvalue, a switch device control unit for transmitting the first digital signal including a driving control signal and the second self eigenvalue according to the operation signal. And a switch device frequency processor for converting the first digital signal into the first transmission signal, a switch device frequency transmitter for transmitting the first transmission signal, and the switch device controller and the switch device frequency processor. It includes a wireless control switch device including a power supply.

According to the present invention, it is possible to operate the lighting device wirelessly can omit the wiring of the power line to the inside of the wall when constructing the building, accordingly, it is possible to easily change the position of the switch unit and the renovation of the building It works.

In addition, according to the present invention, it is possible to reduce the leakage current between the switch unit and the lighting unit, there is an effect that can reduce the waste of the wire.

In addition, according to the present invention, there is an effect that can prevent the possession of the device inherent value for the unnecessary radio frequency (RF), and prevent the malfunction by the signal generated by the other transmission / reception module.

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

1 is a configuration diagram of a wireless control power supply system according to an embodiment of the present invention, the wireless control lighting device 100, the wireless control switch device 200, the distribution panel 300 and the power supply line 400 It consists of.

The distribution panel 300 distributes / supplies power supplied from the outside to the plurality of radio control lighting devices 100 through the power supply line 400.

In addition, the wireless control switch device 200 may be configured to be supplied with power by a battery or a fuel cell (detailed in FIG. 5) to be attached to an arbitrary place, or may be used to move freely like a remote controller.

The radio control lighting apparatus 100 is a radio control switch apparatus 200 generated according to a user's operation command input to the radio control switch apparatus 200-a method in which a user manually turns on a switch or a method by a remote controller. Drives the lighting unit included in the wireless control lighting device 100 by the drive control signal generated by.

In this case, each of the radio control switch devices 200-11, 200-12, and 200-13 corresponding to each of the radio control lighting devices 100-11, 100-12, and 100-13 is provided. A pair of the wireless control lighting device 100 and the wireless control switch device 200 has the same magnetic intrinsic value (the wireless magnetic control device has a first magnetic intrinsic value, the wireless control switch device has a second magnetic intrinsic value), respectively. I have it in storage.

The storage unit may be a semiconductor memory device, and may also be configured to be set by switch processing in units of bits.

As an example of the present invention of FIG. 1, the magnetic eigenvalue (the first magnetic eigenvalue of the wireless control lighting device and the second magnetic eigenvalue of the wireless control switch device) is composed of 12 bits, and the first magnetic eigenvalue. Denotes an intrinsic value of the radio control lighting apparatus 100. The radio control lighting apparatus 100 is set to a non-overlapping intrinsic value within a communication radius, and is communicated by a 12-bit magnetic intrinsic value according to an embodiment of the present invention. Within the radius, 4096 independent radio controlled lighting devices 100 are available.

As an example of the present invention of Figure 1, the first radio control lighting device (100-11) and the radio control switch device (200-11) stores "0000 0000 0001" as its own value, the second radio control lighting device 100-12 and the radio control switch device 200-12 store " 0000 0000 0010 " as its own unique value, and the third radio control lighting device 100-13 and the radio control switch device 200-13. Will be described as an example of storing "0000 0000 0011" as an eigenvalue.

In the radio control switch device 200, the radio control switch device 200-11 having a self intrinsic value (second self intrinsic value) of " 0000 0000 0001 " And a first transmission signal including a signal corresponding to an operation command and " 0000 0000 0001 ", and each radio control lighting device 100 receives the first transmission signal and is stored therein. It is determined whether the eigenvalue (first self eigenvalue) and the self eigenvalue (second self eigenvalue) "0000 0000 0001" of the radio control switch device 200-11 included in the first transmission signal match.

Among the radio control lighting apparatuses 100, only the radio control lighting apparatus 100-11 having a self eigen value (first self eigen value) of “0000 0000 0001” is applied to the drive control signal included in the first transmission signal. Accordingly, the lighting unit is driven.

As a result, the wireless power control system may be configured such that the at least one radio control lighting device 100 and the at least one radio control switch device 200 correspond to each other.

However, in order to assign and store the magnetic eigenvalues (0000 0000 0001, 0000 0000 0010, 0000 0000 0011) to each device as described above, the occupied eigenvalues already occupied and in use within the communication radius must be excluded. If the occupied eigenvalue already occupied as the self eigenvalue is used, since the eigenvalues of the devices collide with each other, an unwanted radio controlled illumination device 100 is driven when any radio controlled switch device 200 is driven. Drive problems may arise.

Therefore, in order to construct and use the wireless power control system as described above, the occupied eigenvalue occupied and in use in the communication radius is found, and the eigenvalue (first self eigenvalue) is used as an available eigenvalue excluding the eigenvalue. A self eigenvalue registration step is required.

2 is a flowchart illustrating a process for registering a self eigenvalue according to an embodiment of the present invention. The self eigenvalue setting module for setting / registering a self eigenvalue in a device may include a wireless control switch device 200 and a wireless unit. Control lighting apparatus 100, or may be configured as a separate setting device (not shown), preferably configured in a wireless control lighting device.

The self eigenvalue setting module receives the frequency signal received within the communication radius, converts it into a digital signal, and reads it (step S1010) to determine whether there is already occupied inherent value included in the digital signal (step S1020). )do.

The digital signal is a pulse signal of a predetermined length consisting of a preamble portion of a predetermined length and an information data portion of a predetermined length.

The preamble portion is defined to distinguish the meaningless harmonics received within the communication radius. In the present invention, since the harmonics generally do not have a constant value of "1" of 8 bits or more, 8-bit HIGH ("1") and 8 The LOW ("0") of the bit was configured repeatedly.

The information data unit includes a self-specific value of the device and, if necessary, may include various control signals for controlling between devices.

In one embodiment of the present invention, the information data portion is composed of 16 bits, and has 12 bits of self eigenvalue and 4 bits of control signal within 16 bits.

The 12-bit magnetic eigenvalue allows each wireless power control system with 4096 magnetic eigenvalues to be used within the communication radius, and more magnetic eigenvalues within the communication radius, such as in office dense areas or large apartment complexes. If necessary, it is preferable to increase the number of bits of the intrinsic value or to increase the number of bits of the information data portion.

Referring to the wireless power control system shown in FIG. 1 as an example, if the eigenvalues "0000 0000 1001" and "0000 0000 1010" are in use within the communication radius, the self-eigen value setting module receives the received digital signal from which the wave is removed. The 0000 0000 1001 and 0000 0000 1010 which are occupied eigenvalues already occupied and used in the signal are read (step S1010).

Accordingly, there are 4094 usable eigenvalues excluding the number of two eigenvalues already occupied based on the 12-bit eigenvalue length, and it is determined whether there are such usable eigenvalues (step S1020).

If there are 4096 occupied eigenvalues occupied within the communication radius, the user is informed that there are no eigenvalues available (step S1032), and if there are available eigenvalues, the available eigenvalues are indicated (step S1031).

The user selects one of the available eigenvalues displayed in the self eigenvalue setting module and selects one of the available eigenvalues on either side of the wireless power control system consisting of the wireless control switch device 200 and the wireless control lighting politics 100. Self-intrinsic value) (S1040).

The available eigenvalues can be displayed to the user (step S1031), and the user can select and register (step S1040) the own eigenvalue (first self eigenvalue) to be used by the user. Among them, an eigenvalue that meets a predetermined criterion, for example, the eigenvalue having the fastest value may be automatically registered as the device's own eigenvalue (first self eigenvalue), in which case the available eigenvalue is provided to the user. The display step (step S1031) may be omitted.

3 is a flowchart illustrating a process for synchronizing magnetic intrinsic values between a radio control lighting device and a radio control switch device according to an embodiment of the present invention, and in the description of FIG. After setting and registering an arbitrary eigen value excluding the occupied eigen value as its own eigen value, the method of synchronizing the self eigen value to match the magnetic eigen value with the wireless control switch device 200 to communicate with the wireless control lighting device 100. .

The user switches the wireless control lighting device 100 and the wireless control switch device 200 to the magnetic eigenvalue synchronization mode (steps S2121 and S2111), and the magnetic eigenvalues stored in the wireless control lighting device 100 ( In operation S2122, the second transmission signal including the first magnetic eigenvalue is transmitted. In this case, the second transmission signal may be configured by adding a registration control signal, which is a control signal, in front of or behind the eigenvalue.

The wireless control switch device 200 receives the second transmission signal and reads the magnetic eigenvalue (first magnetic eigenvalue) (step S2113) to read the magnetic eigenvalue (first magnetic eigenvalue) of the wireless control switch device ( 200 is set to the magnetic eigenvalue (second magnetic eigenvalue) (step S2114) and stored in the switch device storage unit.

At this time, before the step of receiving the second transmission signal and reading the self eigenvalue (first self eigenvalue) (step S2113), it may be added to determine whether the registration control signal is included in the second transmission signal (step S2112). It may be.

The wireless control lighting apparatus 100 transmits a second transmission signal including a magnetic eigenvalue (first magnetic eigenvalue) (step S2122), and switches to a standby mode (step S3120) in the magnetic eigenvalue synchronization mode, and wirelessly. The control switch device 200 does not need to receive the frequency signal after setting the self eigenvalue (second self eigenvalue) (step S2114) and transmits a signal to the radio control lighting apparatus 100 by the user's signal. In operation S3110, the operation mode is changed to a standby mode for transmission.

At this time, a test for checking whether the synchronization of the self eigen value is well performed before the operation standby state step (step S3120) of the radio control lighting device 100 and the operation standby state step (step S3110) of the radio control switch device 200. You can also perform more steps.

In the test step, the wireless control switch device 200 switches to the test mode (step S2115) after setting the magnetic eigenvalue (second self eigenvalue) (step S2114), and the magnetic eigenvalue (second self eigenvalue). In step S2211, the fourth transmission signal including the transmission signal is transmitted.

In this case, the fourth transmission signal may add a test control signal, which is a control signal, in front of or behind the magnetic intrinsic value (second magnetic intrinsic value) of the radio control switch device.

The wireless control lighting apparatus 100 receives the fourth transmission signal, and includes the magnetic intrinsic value (second magnetic intrinsic value) included in the fourth transmission signal and the magnetic intrinsic stored in the storage unit of the wireless control lighting apparatus 100. It is determined whether the values (the first magnetic intrinsic value) match, and if there is a match, the lighting unit is driven (step S2221).

The wireless control lighting apparatus 100 transmits a fifth transmission signal including a self-intrinsic value (first self-intrinsic value) and a test completion control signal as a control signal to the wireless control switch apparatus 200 (step S2222), and waits for operation. Switch to the state (step S3120).

The wireless control switch device 200 receives the fifth transmission signal, and includes a magnetic intrinsic value (first magnetic intrinsic value) included in the fifth transmission signal and a magnetic intrinsic value (second magnetic intrinsic value) stored in the switch device storage unit. In step S3110, it is determined whether or not the data is matched, and the operation completion state is switched by the test completion control signal.

When the self-intrinsic value synchronization procedure for the radio control lighting device 100 and the radio control switch device 200 is completed as described above, the operation waiting state is waited for by the user (steps S3110 and S3120).

4 is a flowchart illustrating an operation process between the radio control lighting apparatus 100 and the radio control switch apparatus 200 according to an embodiment of the present invention.

The wireless control lighting device 100 and the wireless control switch device 200 when the operation signal is generated by driving the switch unit configured in the wireless control switch device 200 in the operation standby state (steps S3120, S3110), wireless control The first transmission signal including the magnetic eigenvalue (second magnetic eigenvalue) included in the switch device storage unit of the switch device 200 and the driving control signal as a control signal is transmitted (step S3111), and the state is returned to the operation standby state. (Step S3110).

The radio control lighting apparatus 100 receives and reads the first transmission signal, and the magnetic intrinsic value (second magnetic intrinsic value) included in the first transmission signal is stored in the lighting apparatus storage unit. Value), and the power relay switch 160 for driving the lighting unit is driven by the driving control signal included in the first transmission signal (step S3122), and the operation is switched to the standby state again (step S3121). Step S3120).

5 is a circuit diagram of a wireless control lighting apparatus 100 according to an embodiment of the present invention, the lighting device frequency transceiver 110, the lighting device frequency processing unit 120, the lighting device controller 140 , And the power relay switch 160 are large.

The lighting device frequency transceiver 110 receives a frequency signal within a predetermined bandwidth and transmits the received frequency signal to the lighting device frequency processor 120, or transmits a frequency signal input from the lighting device frequency processor 120 to the air. .

The lighting device frequency processor 120 converts the frequency signal received from the lighting device frequency transceiver 110 into a digital signal and transmits the digital signal to the lighting device controller 140 or transmits the digital signal received from the lighting device controller 140 to the frequency. The signal is converted into a signal and transmitted to the lighting device frequency transceiver 110.

 The lighting device storage unit 130 may be configured in the same physical space as the lighting device control unit 140 or may be configured in a separate space.

In addition, the lighting device storage unit 130 may be composed of a semiconductor memory, it may be configured in a storage method by a physical switch.

In one embodiment of the present invention, the present invention configures the lighting device control unit 140 using the AT89C2051 microcomputer, and configures the lighting device storage unit 130 using a flash memory mounted on the AT89C2051 microcomputer Even when no power is supplied to the lighting device storage unit 130, the registered magnetic eigenvalue (first magnetic eigenvalue) is not lost.

The lighting device controller 140 reads a digital signal received from the lighting device frequency processor 120 and controls the power relay switch 160, or a magnetic eigenvalue (first magnetic eigenvalue) stored in the lighting device storage 130. ) And the control signal are combined to generate a digital signal and transmit the digital signal to the lighting device frequency processor 120.

When the lighting device controller 140 reads the digital signal including the preamble unit and the information data unit received from the lighting unit frequency processor 120, the lighting unit controller 140 determines whether the corresponding digital signal is unnecessary and performs filtering. .

In addition, it is determined whether the function of the radio control lighting apparatus 100 is performed by the information data unit including the eigenvalues and the control signal.

When the eigenvalues included in the received data signal match and compare with the magnetic eigenvalues (first magnetic eigenvalues) stored in the lighting device storage unit 130, the corresponding eigenvalues correspond to the control signals included in the received data signal. Function will be performed.

 The lighting device power supply unit 150 converts AC power supplied from the distribution panel into DC power and supplies power to the lighting device frequency processing unit 120 and the lighting device controller 140, including a ballast.

The power relay switch 160 may use a relay switch which is generally used, and preferably may be a photodiode.

The lighting unit 170 is turned on / off by the power relay switch 160, and may be any fluorescent lamp, incandescent lamp, halogen lamp, or the like.

6 is a circuit diagram of a wireless control switch device 200 according to an embodiment of the present invention. The switch device frequency transmission / reception unit 210, the switch device frequency processor 220, and the switch device controller It is largely composed of 240.

The switch device frequency transmitting / receiving unit 210 receives a frequency signal within a predetermined bandwidth and transmits the received frequency signal to the switch device frequency processing unit 220, or transmits the frequency signal received from the switch device frequency processing unit 220 to the public. Send it out.

The switch device frequency transmitting / receiving unit 210 transmits and receives a frequency in the self-eigen value synchronization step (S2100 and S2200) described with reference to FIG. In the operation state described with reference to FIG. 4 (S3000) after the completion, only the transmission of the frequency is performed, and thus may be referred to as a frequency transmission unit.

The switch device frequency processing unit 220 converts the frequency signal received from the switch device frequency transmission / reception unit 210 into a digital signal and transmits it to the switch device control unit 240 or the digital received from the switch device control unit 240. The signal is converted into a frequency signal and transmitted to the switch device frequency transceiver 210.

 The switch device storage unit 230 may be configured in the same physical space as the switch device control unit 240 or may be configured in a separate space.

In addition, the switch device storage unit 230 may be configured as a semiconductor memory, or may be configured as a storage method by a physical switch.

In one embodiment of the present invention, the present invention configures the switch device control unit 240 using the AT89C2051 microcomputer, and configures the switch device storage unit 230 using a flash memory mounted on the AT89C2051 microcomputer Even if no power is supplied to the switch device storage unit 230, the set registered magnetic eigenvalue (second magnetic eigenvalue) is not lost.

The switch device controller 240 generates a digital signal by combining the magnetic eigenvalue (second magnetic eigenvalue) stored in the switch device storage 230 and the control signal, and transmits the digital signal to the switch device frequency processor 220.

When the switch device control unit 240 reads the digital signal including the preamble unit and the information data unit received from the switch unit frequency processing unit 220, the switch unit control unit 240 determines whether the corresponding digital signal is unnecessary harmonics and performs filtering. .

In addition, it is determined whether the function of the radio control switch device 200 is performed by the information data unit composed of the unique value and the control signal.

When the eigenvalues included in the received data signal match and compare with the magnetic eigenvalues (second self eigenvalues) stored in the switch device storage unit 230, the corresponding eigenvalues correspond to the control signals included in the received data signals. Function will be performed.

 The switch device power supply unit 250 is preferably composed of a battery such as a battery or a fuel cell in order to ensure the mobility of the wireless control switch device 200, the switch device frequency processing unit 220 and the switch device controller 240, Supply power.

According to an embodiment of the present invention, the control signal described above may be configured as 4 bits, and may include a total of eight control signals, which are driving control signals for driving the lighting unit 170 through the power relay switch 160. The first control signal, the second control signal, which is a registration control signal for synchronizing the eigenvalues of the radio control lighting device 100 and the radio control switch device 200, to the eigen value already occupied by the radio control lighting device 100. The third control signal, which is an occupancy control signal for preventing the other radio control lighting device 100 within the communication radius from being used, the unique value synchronization completion test between the radio control lighting device 100 and the radio control switch device 200 are tested. The fourth control signal, which is a test control signal included in the test transmission signal (fourth transmission signal) in the radio control switch device 200 for the test, the radio control switch device 200 in the radio control lighting device 100 is completed The test complete control signal is the fifth control signal, and the other three control signals contained in the test completed, for sending out the transmission signal (the fifth transmission signal) may be configured further sphere.

1 is a block diagram of a wireless control power supply system according to an embodiment of the present invention.

2 is a processing flowchart for registering a self-eigen value according to an embodiment of the present invention.

3 is a flowchart illustrating a process for synchronizing a magnetic eigenvalue between a radio controlled lighting device and a radio controlled switch device according to an embodiment of the present invention.

4 is a flowchart illustrating an operation process between the radio control lighting apparatus and the radio control switch apparatus according to an embodiment of the present invention.

5 is a circuit diagram of a radio control lighting apparatus according to an embodiment of the present invention.

6 is a circuit diagram of a wireless control switch device according to an embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

100: radio control lighting device, 110: lighting device frequency transceiver,

120: lighting device frequency processing unit, 130: lighting device storage unit,

140: lighting device control unit, 150: lighting device power supply,

160: power relay switch, 170: lighting unit,

200: wireless control switch device, 210: switch device frequency transmission and reception unit,

220: switch unit frequency processing unit, 230: switch unit storage unit,

240: switch device control unit, 250: switch device power supply.

300: distribution panel, 400: power wiring.

Claims (13)

Receiving an ambient frequency signal within a predetermined bandwidth; Converting the peripheral frequency signal into a peripheral digital signal; Reading the peripheral digital signal to extract the occupied eigenvalues; Storing at least one of the values that do not overlap with the occupied eigenvalues as a first magnetic eigenvalue in the lighting device storage of the radio controlled lighting device, and a second magnetic eigenvalue in the switch device storage of the wireless control switch device; Storing as; Transmitting a first transmission signal including the second magnetic eigenvalue by the radio control switch device; And And reading the second magnetic eigenvalue from the first transmission signal transmitted from the wireless control switch device in the radio controlled lighting device to determine whether the first magnetic eigenvalue matches the first magnetic eigenvalue. The method according to claim 1, wherein the storing of the second self-eigen value in the switch device storage unit of the radio-controlled switch device comprises at least one of values which do not overlap with the occupied eigenvalues. And storing the first magnetic intrinsic value in the lighting device storage unit. 3. The apparatus of claim 2, wherein the second magnetic eigenvalue is transmitted by the radio control lighting apparatus to transmit a second transmission signal including the first magnetic eigenvalue and is included in the second transmission signal in the radio control switch apparatus. A wireless power supply control method equal to the first magnetic eigenvalue. 3. The wireless control lighting of claim 2, wherein the storing of the at least one value which does not overlap with the occupied eigenvalue is stored as the first self eigenvalue in the lighting unit storage of the wireless control lighting apparatus. 4. And the apparatus continuously transmits a third transmission signal including the first magnetic eigenvalue. 2. The method of claim 1, wherein the peripheral digital signal comprises a preamble portion and the occupied eigenvalues. The method of claim 1, wherein the extracting the eigenvalue occupied by reading the peripheral digital signal comprises determining whether the preamble part is included in the peripheral digital signal. The method of claim 1, wherein the first transmission signal further comprises a drive control signal before or after the second magnetic eigenvalue. 4. The method of claim 3, wherein the second transmission signal further comprises a registration control signal before or after the first magnetic eigenvalue. 5. The method of claim 4, wherein the third transmission signal further comprises an occupancy control signal before or after the first magnetic eigenvalue. An illumination device frequency transceiver for receiving an ambient frequency signal within a predetermined bandwidth; An illumination device frequency processor converting the peripheral frequency signal into a peripheral digital signal; An illumination device controller which reads the surrounding digital signal and extracts an occupied eigenvalue; And And a lighting device storage unit for storing at least one of the values which do not overlap with the occupied eigenvalues as a first magnetic eigenvalue. An illumination device frequency transceiver configured to receive a first transmission signal within a predetermined bandwidth or transmit a second transmission signal; Illuminator frequency which converts and transmits the first transmission signal received from the illumination device frequency transceiver to a first digital signal or converts the received second digital signal into the second transmission signal and sends it to the illumination device frequency transceiver Processing unit; An illumination device storage unit for storing a first magnetic eigenvalue; A second magnetic eigenvalue included in the first digital signal, read from the first digital signal input from the lighting device frequency processor, and stored in the lighting device storage; A lighting device controller which determines whether or not the first magnetic eigenvalue matches the power control signal to a power control signal line, and transmits the second digital signal including the first magnetic eigenvalue to the lighting device frequency processor; And And a power relay switch configured to flash an illumination unit by the power control signal received from the lighting device controller through the power control signal line. A switch unit for transmitting an operation signal; A switch device storage unit storing a second magnetic eigenvalue; A switch device control unit connected to the switch unit and transmitting a first digital signal including a driving control signal generated by the operation signal transmitted from the switch unit and a second magnetic eigenvalue stored in the switch device storage unit; A switch device frequency processor connected to the switch device controller and converting the first digital signal transmitted from the switch device controller into a first transmission signal; A switch device frequency transmitter connected to the switch device frequency processor and transmitting the first transmission signal transmitted from the switch device frequency processor; And And a power supply for supplying power to the switch device control unit and the switch device frequency processing unit. An illumination device frequency transceiver for receiving a first transmission signal or transmitting a second transmission signal, converting the first transmission signal into a first digital signal, and transmitting the first transmission signal or converting the received second digital signal into the second transmission signal. A lighting device frequency processing unit converting and outputting the lighting device frequency transmitting and receiving unit, a lighting device storage unit storing a first magnetic eigenvalue, and a second magnetic eigenvalue included in the first digital signal by reading the first digital signal. And a lighting device controller which determines whether the first magnetic eigenvalue stored in the lighting device storage unit is identical to the first magnetic eigenvalue and transmits the second digital signal including the first magnetic eigenvalue to the lighting device frequency processor. Radio controlled lighting device; And A switch unit for transmitting an operation signal, a switch device storage unit for storing a second self eigenvalue, a switch device control unit for transmitting the first digital signal including the driving control signal and the second self eigenvalue according to the operation signal, A switch device frequency processor for converting the first digital signal into the first transmission signal, a switch device frequency transmitter for transmitting the first transmission signal, and a power supply for supplying power to the switch device controller and the switch device frequency processor Wireless power control system comprising a wireless control switch device including a supply.

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