KR101756757B1 - Data transfer method and device using control communication phase angle of volts alternating current - Google Patents

Abstract

According to the present invention, there is provided a data communication method and apparatus using phase angle control of an AC power source, the method comprising: (a) receiving a transmission object data packet and an AC power source having a binary number of 1 bits and a binary number of 0 bits from the outside; (b) receiving a first alternating current power from the first positive voltage point detection unit in the transmitter and detecting a first alternating voltage point of the input alternating current power; (c) a first switching signal to be turned on from the off state to the first control unit in the transmitter, a second switching signal to be turned on in the on state, and a third switching signal to be turned off in the on state, And the binary zero 0 bit, and the first zero voltage point is detected from the first zero voltage detector, and when the first zero voltage point is detected at the start of communication, the switching signal matched with the start bit is applied to the switching unit Sequentially applying a corresponding switching signal matched with a bit value of a data packet to be transmitted to the switching unit every time the first zero voltage point is detected; (d) when the switching unit in the transmitter receives the AC power, receives the first to third switching signals from the first control unit, and when the first to third switching signals are on, And outputting the generated modified AC power when the AC power is off; (e) the second zero voltage detector in the receiver receives the modified AC power outputted from the switching unit and sequentially detects the second zero voltage point and transmits it to the second controller; And (f) the second control unit sequentially receives the second zero voltage point, and when the second zero voltage point is detected, the second second voltage point signal during the half period is maintained in the on-state In the case of continuously maintaining the off state, the bit is read with the bit value matched in advance to the second switching signal. When the off state is maintained, Reading a bit with a bit value matched in advance to the first switching signal and outputting a received data packet in which the read bit values are sequentially collected; To a data communication method and apparatus using phase angle control of an AC power source. According to the present invention, in controlling the phase angle of the AC power supply for transmitting data, a leading-edge control waveform, a trailing-edge control waveform, and a waveform not controlled are combined, It is possible to provide a method and an apparatus for data communication using phase angle control of an AC power source capable of effectively communicating by ensuring the stability of the phase angle control.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data communication method and apparatus using phase angle control of an AC power source,

The present invention relates to a data communication method and apparatus using phase angle control of an AC power source, and more particularly, to a method and apparatus for generating a permutation in which a phase angle of an AC power source is adjusted and a non- And transmitting the same.

As a background of the present invention, as disclosed in Korean Patent Laid-Open Publication No. 10-2011-0107879, in order to control a device remotely by using a communication, a wired / wireless communication network or an analog communication signal It is common to use power line communication in which data is superimposed and transmitted.

In the case of using a wired line, a cost for installing a separate communication line increases. In the case of using wireless, installation is simple, but a communication device having a relatively high price compared to a wired line should be used and there is a possibility of data loss due to crosstalk.

In the case of power line communication, although communication is possible by using a power supply line without a separate communication network, it has a problem that it is difficult to use generally because it is vulnerable to disturbance caused by other electric devices.

Conventional power line communication includes a coupling circuit, a frequency conversion circuit, an SS diffusion, a PN code, a control circuit, and a power supply circuit.

In the case of power line communication, which is widely used in wireless communication, in the case of power line communication which is widely used in the spread spectrum, there is a problem in that there is a restriction on the electric power network configuration because the communication device can not communicate when the power equipment generating the noise in the carrier frequency band exists on the line .

In order to reduce the power by adjusting the output amount of electric heaters and lighting devices using AC power, the phase angle of electric power to be supplied is generally controlled by a SCR (Silicon controlled rectifier) or a transistor, Transformer) is used to control the voltage to control the amount of RMS power supplied. In the case of a power saver that controls the amount of reactive power supplied by controlling the voltage or phase angle, there is a period in which the voltage of the supplied power is lowered or power is not supplied, so that the load device may operate abnormally There is a problem.

It is an object of the present invention, which is devised to solve the problems described above, to combine leading-edge control waveforms, trailing-edge control waveforms, and uncontrolled waveforms in controlling the phase angle of an AC power supply for transmitting data, And to provide a data communication method and apparatus using phase angle control of an AC power source capable of efficiently communicating with the stability of data communication by displaying the starting point of data.

Another object of the present invention is to provide a method and apparatus for controlling a phase angle of an AC power source by controlling an apparatus so that data can be transmitted using only a power line without any other communication line, And a data communication method and apparatus using the phase angle control of the power supply.

It is still another object of the present invention to provide a method of controlling a phase angle of an alternating current power source that can be used singly by data input from an external operating unit or built-in data, or by receiving data remotely through a wired / And to provide a data communication method and apparatus using control.

It is another object of the present invention to provide a method of controlling a phase angle of an AC power source in order to transmit data by controlling a trailing-edge control of a half period of a half- And to provide a data communication method and apparatus using phase angle control of an AC power source capable of transmitting information faster by inserting it into a waveform.

It is still another object of the present invention to provide a method and apparatus for controlling the phase angle of an AC power source to transmit data by grasping the number of times the AC power is turned off in a waveform corresponding to a half period, The present invention is to provide a data communication method and apparatus using phase angle control of an AC power source capable of transmitting information by inserting a bit value into a trailing edge control waveform of a half period.

According to a first preferred embodiment of the present invention, there is provided a data communication method using phase angle control of an AC power source according to the present invention, the method comprising the steps of: (a) transmitting a data signal having a binary number of 1 bit and a binary number of 0 Receiving a data packet to be transmitted and an AC power source; (b) receiving a first alternating current power from the first positive voltage point detection unit in the transmitter and detecting a first alternating voltage point of the input alternating current power; (c) a first switching signal to be turned on from the off state to the first control unit in the transmitter, a second switching signal to be turned on in the on state, and a third switching signal to be turned off in the on state, And the binary zero 0 bit, and the first zero voltage point is detected from the first zero voltage detector, and when the first zero voltage point is detected at the start of communication, the switching signal matched with the start bit is applied to the switching unit Sequentially applying a corresponding switching signal matched with a bit value of a data packet to be transmitted to the switching unit every time the first zero voltage point is detected; (d) when the switching unit in the transmitter receives the AC power, receives the first to third switching signals from the first control unit, and when the first to third switching signals are on, And outputting the generated modified AC power when the AC power is off; (e) the second zero voltage detector in the receiver receives the modified AC power outputted from the switching unit and sequentially detects the second zero voltage point and transmits it to the second controller; And (f) the second control unit sequentially receives the second zero voltage point, and when the second zero voltage point is detected, the second second voltage point signal during the half period is maintained in the on-state In the case of continuously maintaining the off state, the bit is read with the bit value matched in advance to the second switching signal. When the off state is maintained, Reading a bit with a bit value matched in advance to the first switching signal and outputting a received data packet in which the read bit values are sequentially collected; .

According to a second aspect of the present invention, there is provided a data communication method using phase angle control of an AC power source, the method comprising the steps of: (a) transmitting a data signal having a binary number of 1 bits and a binary number of 0 bits Comprising: receiving a transmission object data packet and AC power source comprising at least one bit value; (b) receiving a first alternating current power from the first positive voltage point detection unit in the transmitter and detecting a first alternating voltage point of the input alternating current power; (c) Time Ne from the ON state to the OFF state, where N is an integer equal to or greater than 0, and e is an off state. N + 1 pieces of fourth switching signals respectively matched with N + 1 bit values are stored in correspondence with the reference time from the first zero voltage detection unit to the first zero voltage detection unit, A first switching signal is applied to the switching unit when a first zero voltage point is detected at the start of communication, and then each fourth zero voltage point is detected, Sequentially applying a switching signal to the switching unit; (d) when the switching unit in the transmitter receives the AC power, receives the first switching signal and the at least one fourth switching signal from the first control unit, and when the first switching signal and the fourth switching signal are on, Passing the alternating current power and outputting the generated deformed alternating current power by shutting off the alternating current power in the off state; (e) the second zero voltage detector in the receiver receives the modified AC power outputted from the switching unit and sequentially detects the second zero voltage point and transmits it to the second controller; And (f) the second control unit sequentially receives the second zero voltage point, and when the second zero voltage point is detected, the second second zero voltage point signal for half a period is turned on The first switching signal is read out with the starting bit matched in advance and the bit is read out as a bit value previously matched to the fourth switching signal corresponding to the time Ne from the on state to the off state while maintaining the on state in the off state, And outputting a received data packet in which the read bit values are sequentially collected; .

개의 제 6스위칭신호가 각각

개의 비트값과 매칭되어 저장되어 있고, 제1 영전압 검출부로부터 제1 영전압점을 파악하고, 통신 개시시 제1 영전압점이 검출되면 검출된 제1영전압점의 오프상태에서 온상태까지의 시간 Ne에 매칭된 제5스위칭신호를 스위칭부에 인가하고, 그 다음 제1 영전압점이 검출될 때마다 송신대상 데이터 패킷을 이루는 하나 이상의 비트값 각각에 매칭된 각 제6스위칭 신호를 순차적으로 스위칭부에 인가하는 단계; (d) 송신기 내 스위칭부가 상기 교류전원을 입력받고, 상기 제1 제어부로부터 제1영전압점의 오프상태에서 온상태까지의 시간 Ne에 매칭된 제5 스위칭 신호, 하나 이상의 제6스위칭 신호를 인가받아 상기 제5 스위칭 신호 및 제6 스위칭 신호가 온 상태일 경우에는 상기 교류전원을 통과시키고, 오프 상태일 경우에는 상기 교류전원을 차단시켜 생성된 변형 교류전원을 출력하는 단계; (e) 수신기 내 제2 영전압 검출부가 상기 스위칭부로부터 출력된 변형 교류전원을 수신하여 제2 영전압점을 순차적으로 검출하여 제2 제어부에 전송하는 단계; 및 (f) 제2 제어부가 상기 제2 영전압점을 순차적으로 수신하고, 상기 제2 영전압점이 검출될 때마다 그 시점을 기준으로 반주기 동안의 제2 영전압점 신호가 제1영전압점의 오프상태에서 온상태까지의 시간 Ne 동안 유지되는 경우 상기 제5 스위칭 신호에 미리 매칭된 개시비트로 판독하고, 온 상태에서 Ne시간 동안 하나 이상의 오프 상태로 되되 상기 오프상태의 개수 및 Ne시간 내에서 위치하는 위치에 따라 각각 매칭된

개의 제 6스위칭신호에 미리 매칭된 비트값으로 판독하여 각 판독된 비트값을 순차적으로 취합한 수신 데이터패킷을 출력하는 단계; 를 포함한다.
According to a third aspect of the present invention, there is provided a data communication method using phase angle control of an AC power source, the method comprising the steps of: (a) Comprising: receiving a transmission object data packet and AC power source comprising at least one bit value; (b) receiving a first alternating current power from the first positive voltage point detection unit in the transmitter and detecting a first alternating voltage point of the input alternating current power; (c) a time N (N is an integer of 1 or more, e is a reference time from the OFF state to an ON state) from the OFF state to the ON state, Each of which is matched to the number of the off state and the position in the Ne time,

The sixth switching signals are

And detects the first zero voltage point from the first zero voltage detector and detects the time Ne from the OFF state to the ON state of the first zero voltage point detected when the first zero voltage point is detected at the start of communication, Each of the sixth switching signals matched with one or more bit values constituting a transmission object data packet is sequentially applied to the switching unit every time the first zero voltage point is detected, ; (d) receiving a fifth switching signal and one or more sixth switching signals matched with a time Ne from the first control unit to the on state to the first on-state voltage point of the switching unit, Passing the AC power when the fifth switching signal and the sixth switching signal are on and outputting a modified AC power generated by shutting off the AC power when the fifth switching signal and the sixth switching signal are in an off state; (e) the second zero voltage detector in the receiver receives the modified AC power outputted from the switching unit and sequentially detects the second zero voltage point and transmits it to the second controller; And (f) the second control unit sequentially receives the second zero voltage point, and when the second zero voltage point is detected, the second second zero voltage point during the half period is detected as an off state of the first zero voltage point To the off-state, and when it is held for a time Ne from the on-state to the on-state, the read-out bit is pre-matched with the fifth switching signal, Respectively.

And outputting a received data packet in which the read bit values are sequentially summed up; .

In order to achieve the above object, according to a first preferred embodiment of the present invention, a data communication apparatus using the phase angle control of an AC power supply according to the present invention is a data communication apparatus that receives an AC power, A first zero voltage detecting unit for detecting the first zero voltage; A first switching signal to be turned on in an off state, a second switching signal to be turned on in an on state, a third switching signal to be turned off in an on state, Signal is arbitrarily pre-matched and stored in the start bit, the binary number 1 bit, and the binary 0 bit, and the first zero voltage point is detected from the first zero voltage detector. When the first zero voltage point is detected at the start of communication, A first control unit for applying a matching switching signal to the switching unit and sequentially applying a corresponding switching signal matched to a bit value of a data packet to be transmitted each time a first zero voltage point is detected; And receives the AC power, receives the first switching signal to the third switching signal from the first controller, passes the AC power when the first to third switching signals are on, And a switching unit for outputting the generated modified AC power by shutting off the AC power when the AC power is off. A second zero voltage detection unit for receiving the modified AC power outputted from the switching unit and sequentially detecting a second zero voltage point; And when the second zero voltage point is detected and the second last zero voltage point signal during the half period is maintained on from the off state to the third switching point based on the detected second zero voltage point, In the case where the off state is continuously maintained, the bit is read with the bit value matched in advance to the second switching signal. When the off state is maintained in the on state, And a second control unit for reading out the received data with a matched bit value and outputting a received data packet in which the read bit values are sequentially collected; .

According to another aspect of the present invention, there is provided a data communication apparatus using phase angle control of an AC power supply, the apparatus comprising: an AC power supply for receiving an AC power, A first zero voltage detecting unit for detecting the first zero voltage; A first switching signal which is turned on in an off state is stored by being matched with a start bit and is stored in an off state from an on state N + 1 fourth switching signals respectively matched according to a time Ne (N is an integer equal to or larger than 0, and e is a reference time from the off state to the on state) from the off state to the on state are N + 1 bit values And detects a first zero voltage point from the first zero voltage detector and applies a first switching signal to the switching unit when a first zero voltage point is detected at the start of communication and then a first zero voltage point is detected A first controller sequentially applying each fourth switching signal matched to one or more bit values constituting a data packet to be transmitted to the switching unit every time the data packet is transmitted; And receiving the AC power and receiving the first switching signal and the at least one fourth switching signal from the first control unit to pass the AC power when the first switching signal and the fourth switching signal are on, And a switching unit for outputting the generated modified AC power by shutting off the AC power in the off state. A second zero voltage detection unit for receiving the modified AC power outputted from the switching unit and sequentially detecting a second zero voltage point; And when the second zero voltage point is detected and the second second zero voltage point signal during the half period is maintained in the off state with respect to the time point when the second zero voltage point is detected, Read out with the start bit matched in advance to the signal, reading the bit with a bit value matched in advance to the fourth switching signal corresponding to the time Ne from the on state to the off state while maintaining the on state in the off state, And a second controller for outputting sequentially received reception data packets; .

개의 제 6스위칭신호가 각각

개의 비트값과 매칭되어 저장되어 있고, 제1 영전압 검출부로부터 제1 영전압점을 파악하고, 통신 개시시 제1 영전압점이 검출되면 검출된 제1영전압점의 오프상태에서 온상태까지의 시간 Ne에 매칭된 제5스위칭신호를 스위칭부에 인가하고, 그 다음 제1 영전압점이 검출될 때마다 송신대상 데이터 패킷을 이루는 하나 이상의 비트값 각각에 매칭된 각 제6스위칭 신호를 순차적으로 스위칭부에 인가하는 제1 제어부; 및 상기 교류전원을 입력받고, 상기 제1 제어부로부터 제1영전압점의 오프상태에서 온상태까지의 시간 Ne에 매칭된 제5 스위칭 신호, 하나 이상의 제6스위칭 신호를 인가받아 상기 제5 스위칭 신호 및 제6 스위칭 신호가 온 상태일 경우에는 상기 교류전원을 통과시키고, 오프 상태일 경우에는 상기 교류전원을 차단시켜 생성된 변형 교류전원을 출력하는 스위칭부;를 포함하는 송신기; 상기 스위칭부로부터 출력된 변형 교류전원을 수신하여 제2 영전압점을 순차적으로 검출하는 제2 영전압 검출부; 및 상기 제2 영전압점을 순차적으로 수신하고, 상기 제2 영전압점이 검출될 때마다 그 시점을 기준으로 반주기 동안의 제2 영전압점 신호가 제1영전압점의 오프상태에서 온상태까지의 시간 Ne 동안 유지되는 경우 상기 제5 스위칭 신호에 미리 매칭된 개시비트로 판독하고, 온 상태에서 Ne시간 동안 하나 이상의 오프 상태로 되되 상기 오프상태의 개수 및 Ne시간 내에서 위치하는 위치에 따라 각각 매칭된

개의 제 6스위칭신호에 미리 매칭된 비트값으로 판독하여 각 판독된 비트값을 순차적으로 취합한 수신 데이터패킷을 출력하는 제2 제어부;를 포함하는 수신기; 를 포함한다.
According to a third aspect of the present invention, there is provided a data communication apparatus using phase angle control of an AC power supply according to the present invention, which receives an AC power supply and receives a first, A first zero voltage detecting unit for detecting the first zero voltage; (N is an integer of 1 or more, e is an integer of 1 or more from the off state to the on state, while the transmission data packet is composed of one or more bit values composed of one bit of binary number and 0 bit of binary number from the outside. The first switching signal is stored in the ON state, and the first switching signal is set to one or more OFF states during the Ne time, and the number of the OFF states and the Ne time Lt; RTI ID = 0.0 >

The sixth switching signals are

And detects the first zero voltage point from the first zero voltage detector and detects the time Ne from the OFF state to the ON state of the first zero voltage point detected when the first zero voltage point is detected at the start of communication, Each of the sixth switching signals matched with one or more bit values constituting a transmission object data packet is sequentially applied to the switching unit every time the first zero voltage point is detected, A first control unit for applying the first control signal; And a fifth switching signal received from the first control unit and matched with a time Ne from a first point-to-point of the first voltage point to an on-state, and receives the fifth switching signal and the fifth switching signal, And a switching unit for passing the AC power when the sixth switching signal is on and outputting a modified AC power generated by shutting off the AC power when the sixth switching signal is in an off state. A second zero voltage detection unit for receiving the modified AC power outputted from the switching unit and sequentially detecting a second zero voltage point; And the second zero voltage point, and when the second zero voltage point is detected, a time period from the off-state of the first zero voltage point to the on-state of the second zero-voltage point during the half- Is read out with the start bit matched in advance to the fifth switching signal, and is turned into one or more OFF states during the Ne time in the ON state, and is matched to the number of the OFF state and the Ne position in the Ne time

And a second controller for reading out the received data packet with a bit value matched in advance to the sixth switching signal and outputting a received data packet in which the read bit values are sequentially collected. .

As described above, according to the present invention, in controlling the phase angle of the AC power supply for transmitting data, the leading-edge control waveform, the trailing-edge control waveform, and the uncontrolled waveform are combined, It is possible to provide a data communication method and apparatus using the phase angle control of an AC power source capable of ensuring the stability of data communication and displaying the data communication effectively.

According to the present invention, there is provided a method of controlling a phase angle of an AC power source, the apparatus being controlled to transmit data using only a power line without using any other communication line, A data communication method and apparatus using phase angle control can be provided.

In addition, according to the present invention, it is possible to use phase angle control of an AC power source that can be used alone by data input from an external operating unit or built-in data, or by receiving data remotely through a wired / A data communication method and apparatus can be provided.

According to the present invention, in controlling the phase angle of the AC power source to transmit data, a bit value of one or more binary numbers is converted into a trailing-edge control waveform of a half cycle through a time when the AC power is off in a waveform corresponding to a half- It is possible to provide a method and an apparatus for data communication using phase angle control of an AC power source capable of transmitting information more quickly.

According to the present invention, in controlling the phase angle of the AC power for transmitting data, the number of times the AC power is turned off in the waveform corresponding to the half period is grasped, The present invention can provide a data communication method and an apparatus using phase angle control of an AC power source capable of transmitting information faster by inserting it into a trailing edge control waveform of a half period.

1 is a diagram illustrating a control method used in a data communication method and apparatus using phase angle control of an AC power source according to a first preferred embodiment of the present invention.
2 is a detailed block diagram of a data communication apparatus using phase angle control of an AC power source according to a first preferred embodiment of the present invention.
FIG. 3 is a diagram illustrating a data communication method using phase angle control of an AC power source according to a first preferred embodiment of the present invention.
4 is a circuit diagram of a transmitter used in a data communication method and apparatus using phase angle control of an AC power source according to a first preferred embodiment of the present invention.
5 is a diagram illustrating waveforms detected in a data communication method and apparatus using phase angle control of an AC power source according to a first preferred embodiment of the present invention.
FIG. 6 is a diagram illustrating a waveform read by a data communication method and apparatus using phase angle control of an AC power source according to a first preferred embodiment of the present invention.
FIG. 7 is a diagram illustrating a first embodiment of a data communication method using phase angle control of an AC power source according to a first embodiment of the present invention and a modified AC power source output to a receiver of the apparatus.
FIG. 8 is a diagram illustrating a control method used in a data communication method and apparatus using phase angle control of an AC power source according to a second preferred embodiment of the present invention.
9 is a diagram illustrating a waveform read by a data communication method and apparatus using phase angle control of an AC power source according to a second preferred embodiment of the present invention.
10 is a view showing a second embodiment of a data communication method using phase angle control of an AC power source according to a second embodiment of the present invention and a modified AC power source output to a receiver of the apparatus.
11 is a diagram illustrating a control method used in a data communication method and apparatus using phase angle control of an AC power source according to a third preferred embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention and the manner of achieving them will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings.

The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described with reference to the accompanying drawings which illustrate a data communication method and apparatus using phase angle control of an AC power source according to embodiments of the present invention.

The present invention relates to an apparatus and method for receiving a data packet 10 and an AC power source 20 to be transmitted through an external communication network 30 having a wired or wireless network, The receiver 350 receives the deformed alternating current power from the transmitter 200 and controls the phase of the second alternating current power of the deformed alternating current power And a phase angle control of an AC power source for detecting and storing a received data packet by generating a bit value according to the ON / OFF state of the second ground voltage signal.

1 is a diagram illustrating a control method used in a data communication method and apparatus using phase angle control of an AC power source according to a first preferred embodiment of the present invention.

Referring to FIG. 1, the AC power supply has a characteristic in which a sine function type power is supplied with an opposite polarity every 1/2 period in a cycle of 60 Hz or 50 Hz.

As a method of controlling the phase angle of the AC power source, there are a leading edge cutting method of controlling the phase of the beginning of the waveform based on the permanent voltage point existing at 0 degree and 180 degree, There is a trailing edge control method for controlling the trailing edge. At this time, only the leading edge control method or the trailing edge control method may be used in the phase angle control method, or the leading edge control method and the trailing edge control method may be used in combination.

The communication method of the present invention communicates data by substituting start bit or binary data into leading edge control waveform, trailing edge control waveform, and uncontrolled waveform in a method of controlling phase angle.

The present invention combines a waveform in which the leading edge is adjusted by the ac power source 20 and the data packet 10 input to the transmitter 200, a waveform in which the trailing edge is adjusted and a waveform in which the phase angle is not adjusted, (350) to transmit the received data packet.

The starting point of the communication corresponds to the leading edge control waveform or the trailing edge control waveform, the data to be transmitted is converted into binary numbers so that the remaining phase angle control waveform corresponds to binary number 1 or binary number 0, The waveform is sequentially supplied so as to correspond to the complement of the binary value of the waveform whose phase angle is adjusted, and the received data packet is serially transmitted.

2 is a detailed block diagram of a data communication apparatus using phase angle control of an AC power source according to a first preferred embodiment of the present invention.

Referring to FIG. 2, the present invention includes a transmitter 200 and a receiver 350.

The transmitter 200 includes a first zero voltage detector 230, a switching unit 240, a first control unit 250, and a communication unit 210.

The communication unit 210 receives the data packet 10 from the external terminal through the wire / wireless communication network, and outputs the data packet to the first controller 250.

The first zero voltage detector 230 detects a first zero voltage at which the voltage of the AC power source 20 becomes zero voltage and outputs a first Zener voltage signal to the first controller 250.

The first controller 250 receives the first null voltage signal from the first zero voltage detector 230 and receives the data packet 10 through the communication unit 210 and outputs a data packet 10 to the first null voltage point I cover it.

At this time, a first switching signal, a second switching signal, and a third switching signal, which are converted from the on state to the off state, are stored in advance in the first controller 250.

When the first zero voltage point is detected at the start of communication, the first zero voltage detector 230 detects the first zero voltage point, and applies the switching signal matched with the start bit to the switching unit 240, And sequentially applies a corresponding switching signal matched with a bit value constituting a transmission target data packet to the switching unit 240 whenever a point is detected.

At this time, the first switching signal or the third switching signal is matched with the start bit, and the remaining two switching signals except for the switching signal matched with the start bit are arbitrarily matched to the binary 1 bit and the binary 0 bit.

That is, the first control unit 250 outputs a first switching signal, a second switching signal, or a third switching signal corresponding to the data packet 10 to the corresponding switching unit, (240).

The switching unit 240 receives the AC power source 20 and receives the first to third switching signals from the first control unit 250. When the first to third switching signals are on The AC power source 20 is turned off, and in the off state, the AC power source 20 is cut off to output the generated modified AC power.

At this time, the switching unit 240 may be implemented as a semiconductor switching device such as an FET, a transistor, or an IGBT.

The receiver 350 of the present invention includes a second zero voltage detector 330 and a second controller 320.

The second zero voltage detector 330 receives the modified AC power outputted from the switching unit 240 to detect a second zero voltage and a second zero voltage, And outputs it to the control unit 320.

When the second zero voltage point of the modified AC power source is detected, the second control unit 320 sequentially receives the second last voltage point signal and turns off the second second voltage point signal for half a period When the state is maintained, when the off state is continuously maintained, it is determined which of the cases where the state is maintained from the off state to the on state. Accordingly, when the second positive voltage signal is maintained in the off state and the on state is maintained, the bit is read with the bit value previously matched to the third switching signal. When the off state is continuously maintained, Bit value. When the on-state is maintained in the on-state, the read data is read with a bit value matched with the first switching signal in advance, and the received data packet in which the read bit values are sequentially collected is output. At this time, the second controller 320 stores the generated received data packet.

In addition, the data communication method and apparatus using the phase angle control of the AC power source of the present invention may be configured such that the transmitter and the receiver are configured at a ratio of 1: 1, and the data and the data are transmitted by transmitting the data packet to the receiver, A plurality of receivers may be configured in one transmitter so that the transmitter may transmit data to each receiver in such a manner that a unique code of the receiver and a data packet to be transmitted are transmitted.

Hereinafter, the operation of the first embodiment of the data communication method using the phase angle control of the AC power source of the present invention will be described in detail with reference to FIG.

FIG. 3 is a diagram illustrating a data communication method using phase angle control of an AC power source according to a first preferred embodiment of the present invention.

First, the transmitter 200 receives a transmission object data packet and an AC power source 20, which are composed of 1 bit of binary number and 0 bit of binary number, from the outside (step S210).

Then, the first ground voltage detection unit in the transmitter 200 receives the AC power supply 20 and detects the first ground voltage point of the input AC power supply 20 (step S220).

Then, a first switching signal to be turned on in the off state, a second switching signal to stay on, and a third switching signal to be turned off in the on state are supplied to the first controller 250 in the transmitter 200, respectively A start bit, a 1-bit binary number, and a 0-bit binary number. The first zero voltage detector 230 detects the first zero voltage point, and when the first zero voltage point is detected at the start of communication, The switching signal applied to the switching unit 240 is applied to the switching unit 240. Then, each time the first zero voltage point is detected, the corresponding switching signal matched to the bit value of the data packet to be transmitted is sequentially applied to the switching unit 240 (Step S230).

Then, the switching unit 240 in the transmitter receives the AC power source 20, receives the first to third switching signals from the first controller 250, and receives the first to third switching signals If the signal is in the ON state, the AC power source 20 is passed. If the signal is in the OFF state, the AC power source 20 is cut off to output the generated modified AC power (step S240).

Next, the second zero voltage detector 330 in the receiver receives the modified AC power outputted from the switching unit 240 and sequentially detects the second zero voltage point and transmits it to the second controller 320 (step S310 ).

Then, the second control unit 320 sequentially receives the second zero voltage point, and whenever the second zero voltage point is detected, the second second voltage point signal for half a period is turned on from the off state The bit is read with a bit value matched in advance to the third switching signal. When the off state is maintained, the bit is read with a bit value matched in advance to the second switching signal, and the off state is maintained (Step S320). In step S320, the first switching signal is read with a bit value matched in advance, and the received data packet obtained by sequentially combining the read bit values is outputted.

At this time, each time the second zero voltage point is detected, the second control unit 320 determines a second last voltage point signal for half a period based on that point, and when the second near point voltage signal is a signal corresponding to the start bit , And generates a received data packet from that point onward.

Then, the received data packet is stored in the receiver's internal storage 310 (step S330).

4 is a circuit diagram of a transmitter used in a data communication method and apparatus using phase angle control of an AC power source according to a first preferred embodiment of the present invention.

First, the first zero voltage detector 230 will be described.

The general AC power supply 20 changes the size and direction of the voltage at a cycle of 50 or 60 Hz. The applied AC power supply 20 drops through the resistor distribution circuits R1, R2, R3 to a voltage recognizable in the circuit. The capacitor C1 connected to the bridge circuits D1, D2, D3 and D4 is charged by a voltage which varies with time, and is discharged through D5 when the voltage is lowered. The photocoupler (OP2) is activated by the voltage charged in C1, and the isolated low signal is input by the voltage point signal input. When the voltage of the AC power source 20 reaches 0 voltage according to the period, C1 is discharged, and the operation of the photocoupler OP2 is stopped and the High signal isolated at the voltage terminal of the voltage point is inputted. Since the zero voltage occurs twice in one period of the AC power source 20, the voltage point signal occurs at a cycle twice the frequency of the AC power source 20.

Since the circuit principle of the zero voltage detecting unit is commonly used, a further detailed description thereof will be omitted.

The switching unit 240 includes a first FET Q1, a second FET Q2, a photocoupler OP1, a zener diode, and a capacitor.

The first FET Q1 is an N-channel transistor having a drain terminal electrically connected to the AC power source, a source terminal electrically connected to the first ground terminal, and a gate terminal electrically connected to the first node.

The second FET Q2 is an N-channel transistor having a source terminal electrically connected to the first ground terminal, a gate terminal electrically connected to the first node, and a degenerated ac power source outputting a drain terminal.

The photocoupler OP1 has a first end electrically connected to a first resistor connected to the first DC power supply Vcc, a second end electrically connected to a switching signal output terminal of the first control unit, Is electrically connected to a second resistor connected to the second DC power supply (Vdd), the fourth terminal is electrically connected to the second ground terminal, and when a current flows from the first terminal to the second terminal, Current is conducted.

A zener diode is electrically connected between the first node and the second ground terminal.

A capacitor is also electrically connected between the first node and the second ground terminal.

The first to third switching signals output from the switching signal output terminal of the first control unit have the same voltage level as the first DC power supply Vcc (for example, 3.3 V) The voltage magnitude of the first node is preset to be equal to the voltage magnitude of the first ground terminal. The magnitude of the off state voltage of the first to third switching signals will be close to 0 V as the Low voltage.

That is, if the voltage applied to the switching signal output terminal of the first control unit is equal to the Vcc voltage of the first DC power source, there is no voltage difference between the first and second ends of the photocoupler, The current does not flow between the first stage and the fourth stage, and a voltage is applied to the first node at which the second DC power supply (Vdd) is distributed at a constant rate. Therefore, in this case, the voltage across the first node is higher than the voltage at the first ground terminal, so that the first FET flows from the drain to the source and the second FET flows from the source to the drain , So that the input AC power passes through the drain terminal of the second FET as it is.

If the voltage applied to the switching signal output terminal of the first control unit is the above-described Low voltage, a voltage difference occurs between the first and second ends of the photocoupler to cause a current to flow, so that a current also flows between the third and fourth ends of the photocoupler The voltage of the third stage will drop to the voltage level of the second ground terminal, and the voltage of the first node is also dropped to a voltage of the same magnitude as that of the second ground stage. Therefore, in this case, the voltage applied to the first node becomes equal to the voltage magnitude of the first ground terminal, so that the first node voltage applied to the gate terminal of the first FET and the second FET becomes equal to the first ground terminal, Both the first FET and the second FET are prevented from flowing a current, and finally, the input AC power is cut off.

The phase angle control is operated on the basis of the first positive voltage point signal and the phase angle control circuit is maintained in the ON state until the next first positive voltage point signal is input based on the first positive voltage point signal in a period in which the phase angle is not controlled .

During the control period of the leading edge, the phase angle control circuit is kept in the OFF state during the phase angle control time based on the point of time of the voltage point of the electric potential, and then the phase angle control circuit is kept ON until the next voltage point is inputted.

If the trailing edge is controlled, the phase angle control circuit is turned ON during the trailing edge control delay time based on the voltage point signal, and then the phase angle control circuit is kept OFF during the phase angle control time.

In the present invention, since the combination of the leading edge control waveform, the trailing edge control waveform, and the waveform not controlling the phase angle is generated, the start point of data can be displayed in addition to the data representing the binary data. It is easy to implement general serial communication configured to allow data communication to operate smoothly by displaying the start point of data using the start signal by the start bit.

FIG. 5 is a waveform diagram of a first positive voltage point detected by a data communication method and apparatus using phase angle control of an AC power source according to a first preferred embodiment of the present invention. FIG. FIG. 6 is a diagram showing a waveform read by a data communication method and apparatus using phase angle control of an AC power source according to an example.

5 and 6, the first controller 250 stores the first to third switching signals, and the first to third switching signals are supplied to the AC power source 20 through the communication unit 210 A binary number 1 or 0, and a switching signal corresponding to the input data is applied to the switching unit 240 with each switching signal corresponding to the start bit, the binary number 1 or 0 .

The first switching signal is a signal which is in an off state and is converted into an on-state, the second switching signal is a signal which is kept on continuously, and the third switching signal is a signal which is converted from an on state to an off state.

At this time, the first switching signal is a state in which the switching signal is in the OFF state and the ON state in the non-cutoff state only for the cut period by cutting the phase of the start portion based on the first solar power voltage point of the AC power source 20, Leading edge control waveform.

The second switching signal is a state in which the switching signal is continuously turned on since there is no phase change with reference to the first solar charging point of the AC power supply 20. [

The third switching signal is on until the section of the AC power source 20 is cut off at the first zero voltage point since the switching signal is off only during the cut period by cutting the phase at the end of the AC power source 20 The trailing edge control waveform is the trailing edge control waveform.

When the AC power source 20 is input to the transmitter 200, the first zero voltage point of the AC power source 20 detected by the first zero voltage detector 230 is input to the first controller 250.

At this time, the first switching signal to be switched from the off state to the on state, the second switching signal to be maintained in the on state, and the third switching signal to be switched from the on state to the off state are stored in the first controller 250, The switching signal, the second switching signal, and the third switching signal are each set to match the start bit or the binary number 1 or the binary number 0, respectively.

For example, when it is assumed that the first switching signal is matched to the binary number 1, the second switching signal is matched to the binary 0, and the third switching signal is matched to the start bit, the first controller 250 controls the communication unit 210 And outputs a first switching signal corresponding to the binary number 1 to the switching unit 240. [

According to the first switching signal, the switching unit 240 cuts off the AC power source 20 during the OFF period, passes the AC power source 20 during the ON period, and applies the binary number 1 to the AC power source 20 And outputs the generated modified AC power to the receiver 350.

The second zero voltage detector 330 in the receiver detects the second zero voltage point of the deformed AC power source and transmits the second zero point voltage signal to the second controller 320.

At this time, the second control unit 320 is preset with a half period to be determined based on the second zero voltage point.

For example, when the second control unit 320 is instructed to judge based on the half cycle of the modified AC power, the second control unit 320 detects the second nearest power point when the modified AC power is input, At the time when the half period ends.

That is, the second control unit 320 reads the ON / OFF state every time the modified AC power is input and the second local voltage signal is detected, reads the ON / OFF state at the time when the half period ends, Off state or off state, and derives each received data packet accordingly.

Also, the second controller 320 operates only when the switching signal matched with the start bit is input based on the second positive voltage point of the modified AC power source.

For example, in the case of the deformed alternating current power supply, when the second last power voltage point is in the off state and the on state is the second local power point, the time point when the off state is switched to the on state is the data start point.

FIG. 7 is a diagram illustrating a first embodiment of a modified AC power source output to a receiver 350 of a data communication method and apparatus using phase angle control of an AC power source according to a first preferred embodiment of the present invention.

Hereinafter, the AC power source 20 is input to the transmitter 200, the data packet 10100101 is input from the external terminal, the first and third switching signals are matched with the binary number 1 in the first controller 250, The switching signal is set to match the binary number 0 and the second control unit 320 is set to read the half period with reference to the second solar charging point.

 Referring to FIG. 7, the second control unit 320 recognizes the start bit S as being started. Here, the start bit is set to the off-state from the second on-state voltage point during the half- And is switched to a switching signal in which the second positive voltage point signal is switched from the off state to the on state. That is, the start bit corresponds to the trailing edge control waveform or the leading edge control waveform.

Then, when the second positive voltage signal for half a period is switched from the OFF state to the ON state based on the second positive voltage point, the bit value binary number 1 matched with the first switching signal is detected.

Then, when the second positive voltage point signal for half a period is maintained in the off state with reference to the second positive voltage point, the bit value binary 0 matched with the second switching signal is detected.

Then, when the second positive voltage signal for half a period is switched from the OFF state to the ON state based on the second positive voltage point, the bit value binary number 1 matched with the first switching signal is detected.

Then, when the second positive voltage point signal for half a period is maintained in the off state with reference to the second positive voltage point, the bit value binary 0 matched with the second switching signal is detected. The next binary 0 is also the bit value due to the same process.

Then, when the second positive voltage signal for half a period is switched from the on state to the off state based on the second positive voltage point, the bit value binary number 1 matched with the third switching signal is detected.

Then, when the second positive voltage point signal for half a period is maintained in the off state with reference to the second positive voltage point, the bit value binary 0 matched with the second switching signal is detected.

Then, when the second positive voltage signal for half a period is switched from the on state to the off state based on the second positive voltage point, the bit value binary number 1 matched with the third switching signal is detected.

As described above, the binary number 1 is a bit value matched with the first switching signal or the third switching signal, and the second positive voltage signal during the half period is switched from the ON state to the OFF state or from the OFF state to the ON state Is output. The binary number 0 is output when the second positive voltage point signal during the half period is maintained in the off state based on the second negative voltage point, which is matched with the second switching signal.

That is, the start bit corresponds to the leading edge control waveform or the trailing edge control waveform, and the data to be transmitted is converted into binary numbers so that the remaining phase angle control waveform corresponds to binary number 1 or binary number 0, The waveform is serially supplied so as to correspond to the complement (01011010) of the binary number (10100101) of the waveform whose phase angle is adjusted, and the received data packet is serially transmitted.

FIG. 8 is a diagram illustrating a control method used in a data communication method and apparatus using phase angle control of an AC power source according to a second preferred embodiment of the present invention. FIG. 10 is a diagram illustrating a data communication method using phase angle control of an AC power source according to a second preferred embodiment of the present invention, and FIG. Fig. 6 is a view showing a second embodiment of a deformed ac power source output to a receiver of the apparatus; Fig.

Referring to Figs. 8 to 10, the second embodiment includes a transmitter 200 and a receiver 350. Fig.

The transmitter 200 includes a first zero voltage detector 230, a switching unit 240, a first control unit 250, and a communication unit 210.

Since the first zero voltage detector 230, the switching unit 240, and the communication unit 210 of the configuration described in the second embodiment are described in detail in the first embodiment, the detailed description is omitted here.

The first control unit 250 receives a transmission target data packet composed of one or more bit values composed of 1 bit of binary number and 0 bits of binary number and outputs a first switching signal that is turned on in the off state to match the start bit (N + 1) th fourth switching signals (N + 1), which are matched in accordance with a time Ne (N is an integer equal to or larger than 0, and e is a reference time from the OFF state to the ON state) from the ON state to the OFF state, And detects a first zero voltage point from the first zero voltage detector 230. When a first zero voltage point is detected at the start of communication, the first switching signal is input to the switching unit 240, and then sequentially applies each fourth switching signal matched to each of the one or more bit values constituting the data packet to be transmitted to the switching unit 240 every time the first zero voltage point is detected.

That is, if the fourth switching signal has N times, N + 1 switching signals are formed, and N + 1 bit values are matched with N corresponding bit values.

For example, supposing that N is 4, it is possible to form five binary bit values from binary 0 to binary 100, so that the fourth switching signal has five binary numbers from 0 to 100 and one to one Five fourth switching signals are matched with respective bit values so as to be matched.

Here, assuming that the time from the ON state to the OFF state and the time from the OFF state to the ON state is 4e, it is preferable that the binary bit value is 100 and the fourth switching signal is the fourth switching signal corresponding to 4e.

The switching unit 240 receives the AC power and receives the first switching signal and the at least one fourth switching signal from the first control unit 250 to receive the first switching signal and the fourth switching signal, , The AC power is passed, and in the off-state, the AC power is cut off to output the generated modified AC power.

The receiver 350 includes a second zero voltage detector 330 and a second controller 320.

The second zero voltage detector 330 receives the modified AC power outputted from the switching unit 240 and sequentially detects the second zero voltage point.

Since the second zero voltage detector 330 in the second embodiment is described in detail in the first embodiment, a detailed description thereof will be omitted.

The second control unit 320 sequentially receives the second zero voltage point, and when the second zero voltage point is detected, the second second voltage point signal for half a period is turned on The first switching signal is read out with the starting bit matched in advance and the bit is read out as a bit value previously matched to the fourth switching signal corresponding to the time Ne from the on state to the off state while maintaining the on state in the off state, And outputs the received data packet in which the read bit values are sequentially collected.

11 is a diagram illustrating a control method used in a data communication method and apparatus using phase angle control of an AC power source according to a third preferred embodiment of the present invention.

Referring to Fig. 11, the third embodiment includes a transmitter 200 and a receiver 350. Fig.

The transmitter 200 includes a first zero voltage detector 230, a switching unit 240, a first control unit 250, and a communication unit 210.

Since the first zero voltage detector 230 and the communication unit 210 of the third embodiment are described in detail in the first embodiment, the detailed description is omitted here.

개의 제 6스위칭신호가 각각

개의 비트값과 매칭되어 저장되어 있고, 제1 영전압 검출부(230)로부터 제1 영전압점을 파악하고, 통신 개시시 제1 영전압점이 검출되면 검출된 제1영전압점의 오프상태에서 온상태까지의 시간 Ne에 매칭된 제5스위칭신호를 스위칭부(240)에 인가하고, 그 다음 제1 영전압점이 검출될 때마다 송신대상 데이터 패킷을 이루는 하나 이상의 비트값 각각에 매칭된 각 제6스위칭 신호를 순차적으로 스위칭부(240)에 인가한다.The first control unit 250 receives a transmission object data packet composed of one or more bit values composed of 1 bit binary and 0 binary bits from the outside and outputs a time Ne (N (N)) from the off state to the on state And e is a reference time from an OFF state to an ON state) is stored, and the fifth switching signal, in which each of the N start bits matched with the N start bits, is stored, The number of the off states and the position in the Ne time,

The sixth switching signals are

And detects the first zero voltage point from the first zero voltage detector 230. When the first zero voltage point is detected at the start of communication, the first zero voltage point is detected from the OFF state to the ON state of the detected first zero voltage point The switching unit 240 applies the fifth switching signal matched with the time Ne of the first switching signal to the switching unit 240. Then, each time the first zero voltage point is detected, To the switching unit 240 in sequence.

개의 스위칭신호가 형성되고, 각각

개의 비트값과 매칭되어 각 비트값에 매칭되게 된다.That is, according to the fifth switching signal, the sixth switching signal is switched to the Nm off state and the m on state for the Ne time according to the number of the off states and the positions where the respective off states are located within the Ne time

Lt; RTI ID = 0.0 >

Lt; RTI ID = 0.0 > bit < / RTI > values.

For example, assuming that N is 2, it is possible to form four binary bit values from binary 1 to binary 100, so that the fifth switching signal has four binary digits from binary 0 to binary 100 and one to one Four sixth switching signals are matched with each bit value so as to be matched.

The switching unit 240 receives the AC power and receives the fifth switching signal and one or more sixth switching signals matched with the time Ne from the first control unit to the first power voltage point from the off state to the on state When the fifth switching signal and the sixth switching signal are in an ON state, the AC power is passed. When the fifth switching signal and the sixth switching signal are in an OFF state, the AC power is turned off to output a generated AC power.

Since the method of outputting the deformed alternating current power is described in detail in the first embodiment, detailed description will be omitted.

The receiver 350 includes a second zero voltage detector 330 and a second controller 320.

Since the second zero voltage detector 330 in the third embodiment is described in detail in the first embodiment, a detailed description thereof will be omitted.

개의 제 6스위칭신호에 미리 매칭된 비트값으로 판독하여 각 판독된 비트값을 순차적으로 취합한 수신 데이터패킷을 출력한다.When the second zero voltage point is detected, the second control unit 320 sequentially receives the second zero voltage point, and when the second zero voltage point is detected, To the off-state, and when it is held for a time Ne from the on-state to the on-state, the read-out bit is pre-matched with the fifth switching signal, Respectively.

And outputs the received data packet in which the read bit values are sequentially collected.

Since the method of outputting the received data packet is described in detail in the first embodiment, detailed description will be omitted.

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the appended claims rather than the foregoing detailed description, and all changes or modifications derived from the meaning and scope of the claims and the equivalents thereof are included in the scope of the present invention Should be interpreted.

100: Data transmission method 200: Transmitter
210: communication unit 230: first zero voltage detecting unit
240: switching unit 250: first control unit
350: receiver 310:
320: second control unit 330: second zero voltage detecting unit
10: Data packet 20: AC power source
30: External communication network

Claims (6)

delete delete (a) receiving a transmission object data packet and an AC power source in which the transmitter has at least one bit value composed of one bit of binary number and zero bits of binary number from the outside;
(b) receiving a first alternating current power from the first positive voltage point detection unit in the transmitter and detecting a first alternating voltage point of the input alternating current power;
(c) a time N (N is an integer of 1 or more, e is a reference time from the OFF state to an ON state) from the OFF state to the ON state, Each of which is matched to the number of the off state and the position in the Ne time,

The sixth switching signals are

And detects the first zero voltage point from the first zero voltage detector and detects the time Ne from the OFF state to the ON state of the first zero voltage point detected when the first zero voltage point is detected at the start of communication, Each of the sixth switching signals matched with one or more bit values constituting a transmission object data packet is sequentially applied to the switching unit every time the first zero voltage point is detected, ;
(d) receiving a fifth switching signal and one or more sixth switching signals matched with a time Ne from the first control unit to the on state to the first on-state voltage point of the switching unit, Passing the AC power when the fifth switching signal and the sixth switching signal are on and outputting a modified AC power generated by shutting off the AC power when the fifth switching signal and the sixth switching signal are in an off state;
(e) the second zero voltage detector in the receiver receives the modified AC power outputted from the switching unit and sequentially detects the second zero voltage point and transmits it to the second controller; And
(f) the second control unit sequentially receives the second zero voltage point, and when the second zero voltage point is detected, the second zero voltage point during the half period is detected from the point of time when the second zero voltage point is detected, And if it is held for the time Ne until the ON state, the start bit is pre-matched with the fifth switching signal, and the ON state is set to one or more OFF states during the Ne time, Respectively,

And outputting a received data packet in which the read bit values are sequentially summed up; And a phase angle control of the AC power source.
delete delete A first zero voltage detector for receiving an AC power source and detecting a first zero voltage point of the input AC power; (N is an integer of 1 or more, e is an integer of 1 or more from the off state to the on state, while the transmission data packet is composed of one or more bit values composed of one bit of binary number and 0 bit of binary number from the outside. The first switching signal is stored in the ON state, and the first switching signal is set to one or more OFF states during the Ne time, and the number of the OFF states and the Ne time Lt; RTI ID = 0.0 >

The sixth switching signals are

And detects the first zero voltage point from the first zero voltage detector and detects the time Ne from the OFF state to the ON state of the first zero voltage point detected when the first zero voltage point is detected at the start of communication, Each of the sixth switching signals matched with one or more bit values constituting a transmission object data packet is sequentially applied to the switching unit every time the first zero voltage point is detected, A first control unit for applying the first control signal; And a fifth switching signal received from the first control unit and matched with a time Ne from a first point-to-point of the first voltage point to an on-state, and receives the fifth switching signal and the fifth switching signal, And a switching unit for passing the AC power when the sixth switching signal is on and outputting a modified AC power generated by shutting off the AC power when the sixth switching signal is in an off state.
A second zero voltage detection unit for receiving the modified AC power outputted from the switching unit and sequentially detecting a second zero voltage point; And the second zero voltage point, and when the second zero voltage point is detected, a time period from the off-state of the first zero voltage point to the on-state of the second zero-voltage point during the half- Is read out with the start bit matched in advance to the fifth switching signal, and is turned into one or more OFF states during the Ne time in the ON state, and is matched to the number of the OFF state and the Ne position in the Ne time

And a second controller for reading out the received data packet with a bit value matched in advance to the sixth switching signal and outputting a received data packet in which the read bit values are sequentially collected. The phase angle control of the AC power source.

Images