JP2017033868A - Lighting supervisory controller - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a highly reliable lighting supervisory controller capable of performing lighting supervisory control, even upon occurrence of phase shift.SOLUTION: A lighting supervisory controller includes a power line 6, a slave station 8 having a light for connection with the power line 6, and a master station 4 connected with the power line 6, and controlling the light L via the power line 6. The slave station 8 has a waveform detector 81 for detecting the power line carrier waveform of the power line 6, an extraction unit 82a for extracting a signal superposed on the positive or negative of the power line carrier waveform based on a reference signal, a signal confirmation unit 83 for determining whether or not an extracted signal includes both a start signal and a command signal, and a phase adjustment unit 82c for leading the phase of the power line carrier waveform by 180 degrees, when a determination is made that the signal extracted by the signal confirmation unit 83 does not include the command signal.SELECTED DRAWING: Figure 5

Description

  Embodiments of the present invention relate to a lamp monitoring device that monitors a lamp such as a guide lamp, which is installed, for example, on an airport runway or taxiway.

  Conventionally, a number of various lights such as guide lights and intrusion lights have been installed on airport runways and taxiways. These lights provide various visual guidance to the aircraft by controlling the arrangement, color, light intensity, and the like of light by a light monitoring and control device. Appropriate visual assistance with this light will ensure safe operation when the aircraft arrives and departs. Therefore, if an abnormality such as disconnection occurs in the lighting, there is a possibility of affecting the operation of the aircraft, which may lead to a very serious accident. For this reason, the lighting monitoring control device includes a processing unit that monitors abnormalities such as lighting disconnection and determines a disconnection location.

  As an example of a light monitoring and control apparatus, an apparatus using a power line carrier having a slave station having a plurality of lights connected to a power line and a master station that controls the slave station via the power line has been proposed. In such a lamp monitoring control device, the slave station on the signal receiving side monitors the lamp for a power waveform on which a predetermined signal supplied from the master station via the power line is superimposed, so that the lamp is disconnected, etc. Detect anomalies.

Japanese Patent No. 3548045 Japanese Patent No. 4987390

  By the way, the lighting monitoring control device includes equipment such as a rubber-covered insulated transformer (hereinafter referred to as a rubber transformer) for supplying power to the lighting and an aerial lighting cable for connecting the rubber transformers. If such a transformer or cable deteriorates, it will be replaced with a new one. However, if an operator who replaces a transformer, a cable, or the like does not have sufficient knowledge about power line conveyance, the rubber transformer may be connected so that the primary side connection has a reverse polarity. As a result, a 180 ° shift occurs in the secondary phase of the rubber transformer.

  A phase shift of 180 degrees also occurs in the slave station connected to the secondary side of the rubber transformer whose phase is shifted. As a result, even if the slave station is operating normally, the signal superimposed on the power waveform cannot be recognized, and there is a case where power cannot be conveyed with the master station. As a result, a response from the slave station where the phase of the rubber transformer is shifted cannot be obtained on the master station side, and this slave station cannot be recognized. In this case, since the master station determines that an abnormality has occurred in the slave station, monitoring control cannot be performed, and the disconnection of the lamp connected to the slave station cannot be detected.

  When the slave station cannot be recognized, the worker must go to the site again and change the slave station's rubber transformer, which has become unrecognizable, and the connection of the aerial lighting cable connected to the rubber transformer. is there. However, facilities such as airports are vast and the length of the cable can reach several kilometers, and there are a plurality of connection points such as cables. For this reason, enormous costs and time are required to find the connection point of the cable that causes the phase shift. The above problems may also occur when a lighting monitoring and control device is replaced or newly introduced at an existing airport, reducing the work efficiency in the process up to the operation of the lighting monitoring and control device. It was.

  The embodiment of the present invention has been proposed in order to solve the above-described problems of the prior art. The purpose is to provide a highly reliable lighting monitoring control apparatus capable of performing lighting monitoring control even when a phase shift occurs.

  The lighting monitoring and control apparatus according to the embodiment for achieving the object as described above includes a power line, a slave station having a lamp connected to the power line, and a slave station connected to the power line and controlling the slave station via the power line. The slave station is configured to detect a waveform detection unit that detects a power line carrier waveform of the power line, and a signal superimposed on the positive and negative of the power line carrier waveform from the positive and negative waveforms of the power line carrier waveform. An extraction unit that extracts based on the extracted reference signal, a signal confirmation unit that determines whether or not the extracted signal includes both a start signal and a command signal, and the signal confirmation unit includes the extracted signal A phase adjustment unit that advances the phase of the power line carrier waveform by 180 degrees when it is determined that the command signal is not included.

It is a connection block diagram which shows an example of a structure of the lighting monitoring control apparatus of 1st Embodiment. It is a block diagram which shows an example of a structure of the main | base station of 1st Embodiment. It is explanatory drawing explaining the example of the signal which a parent station superimposes on a power line carrier waveform. It is a block diagram which shows an example of a structure of the sub_station | mobile_unit of 1st Embodiment. It is a block diagram which shows an example of a structure of the receiving part of 1st Embodiment. It is a figure explaining the signal extraction of an extraction part, (a) shows a power line carrier waveform, (b) shows a reference signal. It is a flowchart which shows an example of the process of the receiving part of 1st Embodiment. It is explanatory drawing which shows the structure of a rubber transformer in (a) and the cable for aerial illumination in (b). It is explanatory drawing which shows the example connected reversely when the connection of a slave station and a rubber transformer is connected normally. It is a figure explaining the signal extraction of the extraction part in the state where the phase of the reference signal was delayed, (a) shows a power line carrier waveform, and (b) shows a reference signal.

[First Embodiment]
[1. Constitution]
(Outline configuration)
A first embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram illustrating an example of a configuration of a lighting monitoring control device according to the present embodiment. The lamp monitoring and control apparatus applies a power line conveyance system that controls a plurality of lamps L using a power line. The lighting monitoring control device includes a central monitoring room 1, an operator console 2, a monitoring control panel 3, a master station 4, a constant current generator 5, a power line 6, a bypass filter 7, a plurality of slave stations 8, and a plurality of rubber transformers 9. . The central management room 1 and the master station 4 are connected via a control LAN. The master station 4 and the plurality of slave stations 8 are connected via a power line 6. A lamp L is connected to each of the plurality of slave stations 8. The lamp L is a light bulb, an LED, or the like that emits light when supplied with electric power.

(Central monitoring room)
The central monitoring room 1 is a place for monitoring and controlling the lamp, and comprehensively manages the lamp and its related facilities, such as backup of the control tower function and output current value management of the constant current generator 5. An operator console 2 and a monitoring control panel 3 are provided in the central monitoring room 1. The central monitoring room 1 functions as a host system.

(Operator console)
The operator console 2 is an operation console that monitors and controls the state of the lamp L and the disconnection in the airport. Via the operator console 2, operations such as operation status display of various facilities such as lights L and sensors in the airport, lighting / extinguishing control of the lights L, operation tests of each slave station 8, and resetting of the slave stations 8 can be performed. Done. A monitoring control board 3 is connected to the operator console 2 via a control LAN, and exchanges information with the monitoring control board 3.

  The operator console 2 includes input means for an operator to perform an operation related to monitoring control of equipment in the airport, and display means for outputting the equipment status in the airport so that the worker can visually recognize the equipment state. As the input means, for example, a touch panel (including those installed on the display means), a mouse, and a keyboard can be used. A CRT display can be used as the display means. In addition, display devices such as a liquid crystal display, a plasma display, and an organic EL display may be used.

(Supervisory control panel)
The supervisory control panel 3 is a control unit that exchanges signals with the operator console 2 and manages various power line circuit information in a concentrated manner. The supervisory control panel 3 is connected to the master station 4 via the control LAN. The supervisory control board 3 has a function of transmitting a control signal input from the operator console 2 to the master station 4. Although FIG. 1 shows one master station 4, a plurality of master stations 4 may be connected via a control LAN. The supervisory control board 3 has a function of sharing power line circuit information related to a circuit managed by one master station 4 with the master station 4.

(master station)
The master station 4 includes a processing unit that transmits a control signal from the supervisory control board 3 that is a host system to the plurality of slave stations 8 via the power line 6. Further, the master station 4 has a processing unit that collects an operation state of the lamp L in the airport and a monitoring signal that is a signal from other sensors and notifies the monitoring control panel 3. As shown in FIG. 2, the master station 4 includes an upper I / F unit 401, a monitoring control unit 402, a transmission unit 403, and a reception unit 404.

  The upper I / F unit 401 is a processing unit that exchanges signals with the monitoring control panel 3. The host I / F unit 401 has a function of transmitting a control signal from the monitoring control panel 3 to the monitoring control unit 402, for example. Further, the host I / F unit 401 has a function of transmitting a monitoring signal from the slave station 8 side received via the monitoring control unit 402 to the monitoring control panel 3. The monitoring control unit 402 performs signal processing on the control signal received from the higher-level I / F unit 401 or the monitoring signal received from the slave station 8 side so as to be suitable for a predetermined transmission format, or modulates the control signal at a predetermined timing. A processing unit for performing transmission processing.

  The transmission unit 403 is a processing unit that superimposes and transmits the control signal received from the monitoring control unit 402 on the power waveform of the power line 6 using a predetermined frequency, for example. The receiving unit 404 is a processing unit that receives a monitoring signal from the slave station 8 side, performs a filtering process, and converts the signal into a signal that can be processed by the monitoring control unit 402.

  An example of a control signal superimposed on the power waveform by the master station 4 will be described with reference to FIG. When superimposing the control signal on the power waveform, the master station 4 first superimposes a start signal indicating the start of the control signal on the power waveform. Here, as shown in the table of FIG. 3B, the start signal is defined as a case where there are signals in both positive and negative of the two cycles of the power line carrier waveform, for example. Therefore, as shown in the table of FIG. 3A, the power waveform on which the start signal is superimposed is output for two cycles in the positive and negative of the power line carrier waveform.

  A command signal which is an actual control signal is superimposed on 3 to 6 cycles following the start signal. Here, as shown in the table of FIG. 3B, the command signal is superimposed only on the positive side of the power supply frequency. A plurality of command signals are defined using the signal on the positive side only. Similarly, in the identification flag in the seventh cycle, it is defined whether only the primary side is used for communication with individual slave stations 8 or communication with all slave stations 8. For example, the slave station 8 replies to the command signal after the eighth cycle.

(Constant current generator)
The constant current generator 5 is a device that generates and generates a constant current from a commercial AC power supply. The constant current generator 5 constitutes a power generator with a step-up transformer (not shown), for example. The constant current generator 5 receives AC power boosted by the step-up transformer, and generates and outputs a constant current having a higher voltage than the input AC power. A power line 6 is connected to the constant current generator 5.

(Power line / Bypass filter)
The power line 6 is a power line derived from the constant current generator 5. In the power line 6, a bypass filter 7 is provided at a position relatively close to the output side of the constant current generator 5. The bypass filter 7 has a resonance circuit in which reactance and a capacitor are connected in series according to the frequency of a signal used for communication. This resonance circuit has a function of causing noise from the constant current generator 5 to flow to the constant current generator 5 side and preventing noise from entering the power line 6 between the master station 4 and the slave station 8.

  The bypass filter 7 has a current extractor 7a. The monitoring controller 402 of the master station 4 is connected to the current extractor 7a. The current extractor 7 a has a function of extracting a current flowing through the resonance circuit and outputting it to the monitoring control unit 402 of the master station 4.

(Slave station / Rubber transformer)
The plurality of slave stations 8 include a processing unit that individually monitors the state of the connected lights L and sensors and transmits them to the master station 4 side. The plurality of slave stations 8 have a processing unit that receives a control signal from the master station 4 side and controls lighting and extinguishing of the lamp L. The plurality of slave stations 8 are connected in series to the power line 6 via rubber transformers 9 respectively. The rubber transformer 9 has a function of preventing the power on the slave station 8 side from entering the power line 6.

  As illustrated in FIG. 4, the slave station 8 includes a lighting control unit 801, a disconnection detection unit 802, a monitoring control unit 803, an optical I / F unit 804, a transmission unit 805, and a reception unit 806. The lamp control unit 801 is a processing unit that controls lighting / extinguishing of the lamp L. The disconnection detection unit 802 is a processing unit that detects an abnormality such as disconnection of the lamp L.

  The monitoring control unit 803 includes a processing unit that analyzes the control signal received from the master station 4 and converts it into a signal related to lighting control. The monitoring control unit 803 includes a processing unit that performs signal processing so that the monitoring signal detected by the disconnection detection unit 802 is suitable for a predetermined transmission format, or performs processing of modulating and transmitting at a predetermined timing.

  The optical I / F unit 804 is a processing unit that captures information related to the state of a sensor or the like in an airport, for example. The transmission unit 805 is a processing unit that superimposes and transmits the monitoring signal received from the monitoring control unit 803 on the power waveform of the power line 6 using a predetermined frequency, for example. The receiving unit 806 is a processing unit that receives a control signal from the master station 4 side, performs a filtering process, and converts the signal into a signal that can be processed by the monitoring control unit 803.

(Receiver)
Next, the receiving unit 806, which is a main part of the present embodiment, will be described in more detail with reference to FIG. The reception unit 806 includes a waveform detection unit 81, a signal extraction unit 82, and a signal confirmation unit 83. The waveform detection unit 81 is a current transformer that extracts a power line carrier waveform flowing on the secondary side of the rubber transformer 9. The waveform detection unit 81 outputs the detected power line carrier waveform to the signal extraction unit 82. In addition, the waveform detection unit 81 performs half-wave rectification on the power line waveform extracted from the rubber transformer 9 and outputs a reference signal to the signal extraction unit 82.

  The signal extraction unit 82 is a processing unit that extracts the signal of the master station 4 from the power line carrier waveform detected by the waveform detection unit 81. The signal extraction unit 82 includes an extraction unit 82a, a storage unit 82b, and a phase adjustment unit 82c. The extraction unit 82a is a filter that extracts the signal of the master station 4 superimposed on the positive / negative of the power line carrier waveform detected by the waveform detector 81 or the power line carrier waveform whose phase is adjusted by the phase adjusting unit 82c described later. The extraction unit 82a detects the presence / absence of a signal superimposed on the power line carrier waveform in the positive / negative order of the reference signal extracted from the positive / negative waveform of the power line carrier waveform (Yes: 1, No: 0).

  The extraction unit 82a is set to start signal extraction when there is a signal on the positive side of the reference signal. That is, if the power line carrier waveform has no signal on the positive side of the first cycle and has a signal on the negative side of the first cycle and the positive side of the second cycle, the positive side of the second cycle The signal is extracted from these signals.

In the present embodiment, the extraction unit 82a extracts whether or not a signal exists in the positive and negative of each cycle. Specifically, if there is a signal on both the positive and negative sides of the first cycle, and if there is a signal on the positive side of the second cycle and no signal on the negative side, the signal is extracted in the following format Is done.
Reference signal cycle Positive 1, negative 1, positive 2, negative 2
Presence or absence of signal 1 1 1 0
The signal extraction unit 82 a outputs the extracted signal to the signal confirmation unit 83.

  The storage unit 82 b is a storage unit that stores the power line carrier waveform detected by the waveform detection unit 81. A semiconductor memory or the like can be used as the storage unit 82b. A storage medium that can be attached to and detached from the slave station 8 may be used. In addition, the storage unit includes a cache memory, a buffer memory, a register, and the like used as a temporary storage area. Note that the storage unit 82b may be configured to store all the detected signals instead of the signals extracted with reference to the positive signal. In that case, the signal extraction unit 82 can be provided with a detection unit that reads all signals superimposed on the power carrier waveform.

The phase adjustment unit 82c is a processing unit that reads the power line carrier waveform stored in the storage unit 82b and advances the phase of the read power line carrier waveform by 180 °. For example, a case where a power line carrier waveform having the following signals is stored in the storage unit 82b will be described as an example. Here, for easy understanding, it is assumed that all signals detected by the extraction unit 82a are stored in the storage unit 82b.
Reference signal cycle Positive 1 Negative 1 Positive 2 Negative 2 Positive 3 Negative 3 Positive 4 Negative 4 Positive 5
Presence or absence of signal 0 1 1 1 1 1 0 1 0

For example, when the phase adjustment unit 82c advances the phase of the power line carrier waveform having the above signal by 180 °, signals included in the power carrier waveform are as follows.
Reference signal cycle Positive 1 Negative 1 Positive 2 Negative 2 Positive 3 Negative 3 Positive 4 Negative 4
Presence or absence of signal 1 1 1 1 1 0 1 0
That is, it can be said that the phase adjustment unit 82c performs a process of inverting the sign of the reference signal. The phase adjustment unit 82c outputs a signal whose phase has been adjusted to the extraction unit 82a.

  The signal confirmation unit 83 is a processing unit that determines whether or not the signal extracted by the extraction unit 82a includes both a start signal and a command signal. The signal confirmation unit 83 includes a start signal detection unit 83a and a command signal detection unit 83b. The start signal detection unit 83a is a processing unit that detects a start signal. The start signal detector 83b determines that the four signals are start signals when there are signals extracted in both positive and negative directions in two cycles.

  The command signal detection unit 83b is a processing unit that detects a command signal following the start signal. The command signal detector 83b determines that the signal following the start signal is a command signal when the signal is superimposed only on the positive side of the power supply waveform and there is no signal on the negative side.

  The signal confirmation unit 83 outputs a series of signals including the start signal and the command signal to the monitoring control unit 803 when the command signal detection unit 83b detects the command signal. On the other hand, when the command signal detection unit 83b determines that the signal extracted by the command signal detection unit 83b does not include the command signal, the command signal detection unit 83b outputs a signal indicating that the phase is adjusted to the phase adjustment unit 82c.

[2. Operation]
The operation of the lighting monitoring control device of the present embodiment will be described with reference to FIGS.
(Outline operation)
First, a general operation of the lighting monitoring control apparatus will be described with reference to FIG. The monitoring control panel 3 receives the light L and sensor monitoring information transmitted from the master station 4 and transmits them to the operator console 2. Based on the received monitoring information, the operator console 1 displays the operation state such as lighting on the display means.

  The operator inputs control information via the input means of the operator console 2. Control information such as input lighting / extinguishing control of the lamp L, operation test of the slave station 8 and reset of the slave station 8 is output to each slave station 8 via the monitoring control panel 3 and the master station 4. The The central monitoring room 1, which is a host system, centrally monitors the response state of the slave station 8 to which the control signal is input, and executes control.

(Signal transmission of master station)
The operation when the master station 4 transmits a control signal to the slave station 8 will be described with reference to FIGS. The host I / F unit 401 of the master station 4 receives the control signal from the monitoring control panel 3 and outputs it to the monitoring control unit 402. The monitoring control unit 402 modulates the control signal at a predetermined timing and outputs the modulated control signal to the transmission unit 403. Transmitter 403 transmits the control signal superimposed on the power waveform of power line 6.

  Here, a power line carrier waveform in which the master station 4 superimposes a signal is shown in FIG. When transmitting a control signal to the slave station 8, the master station 4 superimposes a start signal, which means the start of the control signal, for two periods in the positive and negative of the power line carrier waveform. And the command signal which is an actual control signal is superimposed on the 3-6 period following a start signal.

(Substation signal transmission)
The operation when the slave station 8 receives the control signal superimposed on the power line carrier waveform will be described with reference to FIGS. As shown in the flowchart of FIG. 7, the receiving unit 806 receives the power line carrier waveform from the master station 4 side. The waveform detector 81 detects the power line carrier waveform and stores it in the storage unit 82b (step S01). The waveform detector 81 detects the secondary current waveform of the rubber transformer 9 and outputs it to the signal extractor 82 together with the power line carrier waveform.

The extraction unit 82a uses the secondary current waveform of the rubber transformer 9 shown in FIG. 6B as a reference signal, and extracts the presence / absence of the signal of the power line carrier waveform in the positive / negative order of the reference signal. Here, as an example, description will be made assuming that the following signals are extracted.
(Signal 1)
Reference signal cycle Positive 1 Negative 1 Positive 2 Negative 2 Positive 3 Negative 3 Positive 4 Negative 4
Presence or absence of signal 1 1 1 1 1 0 1 0
The extraction unit 82 a outputs the extracted signal to the signal confirmation unit 83.

  The start signal detection unit 83a of the signal confirmation unit 83 determines whether or not the signal 1 extracted by the extraction unit 82a includes a start signal (step S02). If the extracted signal is not in both positive and negative directions in two cycles, it is determined that the extracted signal is, for example, noise and does not include the start signal (NO in step S02). In this case, the process returns to step S01 to detect the power line carrier waveform.

  On the other hand, in the case of the signal 1, since there are signals extracted in both positive and negative in two cycles, the start signal detecting unit 83a determines that the start signal is included (step S02, YES). Then, the command signal detector 83b determines whether or not the signal following the start signal includes a command signal (step S03). For example, in the case of the signal 1, after the start signal, there is a signal at positive 3 and there is no signal at negative 3. That is, the signal following the start signal is superimposed only on the positive side of the power supply waveform, and there is no signal on the negative side.

  Therefore, the command signal detector 83b determines that these signals are command signals (YES in step S03). When the extracted signal includes both the start signal and the command signal, the signal confirmation unit 83 outputs a series of signals to the monitoring control unit 803. The monitoring control unit 803 analyzes the control signal, converts it into a signal related to lighting control, and outputs the signal to the lighting control unit 801. The lamp control unit 801 controls the lamp L and the like based on the received signal (step S04).

  On the other hand, when the command signal detection unit 83b determines that the command signal is not included (step S03, NO), the following processing is performed. Prior to the description of the specific processing, a phenomenon that can be considered as a cause of the failure to detect the command signal even though the start signal can be detected will be described. As described above, the lighting monitoring control device includes equipment such as the rubber transformer 9 that supplies power to the lighting and the aerial lighting cable 16 that connects the rubber transformers 9.

  FIG. 8A shows the rubber transformer 9 and FIG. 8B is an explanatory view showing the aerial lighting cable 16. As shown in FIGS. 8A and 8B, the rubber transformer 9 has a plug 9a and receptacles 9b and 9c. The aerial lighting cable 16 includes a plug 16a and a receptacle 16b. Therefore, for example, the plug 16 a of the cable 16 for aerial lighting is connected to the receptacle 9 b of the rubber transformer 9. Further, another aerial lighting cable 16 is connected to the plug 9 a of the rubber transformer 9 and connected to the other rubber transformer 9. The receptacle 9c is connected to the plug of the slave station 8.

  Thus, by connecting the rubber transformer 9 and the aerial lighting cable 16 in sequence, the direction of the output current of the constant current generator 5 becomes the same as the reference signal of the rubber transformer 9 and the slave station 8. That is, the output current of the constant current generator 5, that is, the phase of the power line carrier waveform, the internal phase of the master station 4, and the phase of the reference signal of the slave station 8 are all in phase. By performing signal extraction based on this, power line conveyance is established.

  However, since the rubber transformer 9 and the aerial lighting cable 16 are installed outdoors, the rubber that is the outer insulating material may corrode when used for many years, resulting in contact failure or disconnection. In order to prevent such poor contact, etc., the insulation resistance between the power line 6 and the ground is measured periodically. For example, when the insulation resistance is reduced to about 20% or less of the initial value, the abnormal part is identified, Maintenance is performed to replace the rubber transformer 9 and the cable 16 for aerial lighting.

  For example, when the aerial lighting cable 16 is replaced, the cable shown in FIG. 8A may be used. However, in the field, there are cases where a cable composed of a receptacle at both ends is used. In some cases, the rubber transformer 9 and the aerial lighting cable 16 are directly connected without using a plug or a receptacle. In addition, the maintenance contractor does not grasp the phase relationship of each component, and the power line 6 is installed underground for a very long distance. Recovery is the top priority. Therefore, in the configuration described in FIGS. 8A and 8B, the cable is not necessarily connected.

  As a result, as shown in FIG. 9, when the connection of the rubber transformers 9 of the slave stations 1 and 2 is reversed from the case of normal connection, the resulting phase shift on the secondary side of the rubber transformer is 180 degrees. Arise. The slave station 8 detects a signal superimposed on the power carrier waveform using the current waveform flowing on the secondary side of the rubber transformer as a reference signal. Therefore, as shown in FIG. 10, a delay of 180 degrees occurs in the reference signal.

The case where the following signal 2 is detected by the extraction unit 82a when the connection is normal will be specifically described.
(Signal 2)
Reference signal cycle Positive 1 Negative 1 Positive 2 Negative 2 Positive 3 Negative 3 Positive 4 Negative 4
Presence or absence of signal 1 1 1 1 1 0 1 0
When the connection of the rubber transformers 9 of the slave stations 1 and 2 is reversed from that in the normal connection, the signal detected by the extraction unit 82a is as follows.
(Signal 3)
Reference signal cycle Positive 1 Negative 1 Positive 2 Negative 2 Positive 3 Negative 3 Positive 4 Negative 4 Positive 5
Presence or absence of signal 0 1 1 1 1 1 0 1 0

As described above, the extraction unit 82a is set to start signal extraction when there is a signal on the positive side of the reference signal. Therefore, when the signal 3 is input to the extraction unit 82a, the signal extracted by the extraction unit 82a is as follows.
(Signal 4)
Reference signal cycle Positive 2 Negative 2 Positive 3 Negative 3 Positive 4 Negative 4 Positive 5
Presence / absence of signal 1 1 1 1 0 1 0

  In this case, the start signal detection unit 83a of the signal confirmation unit 83 determines whether or not the signal 4 extracted by the extraction unit 82a includes a start signal (step S02). Since the signal 4 includes signals extracted in both positive and negative directions in two cycles, the start signal detection unit 83a determines that it includes a start signal (step S02, YES). Then, the command signal detector 83b determines whether or not the signal following the start signal includes a command signal (step S03).

  In the case of the signal 4, after the start signal, there is no signal at the positive 4, and there is a signal at the negative 3. That is, the signal following the start signal is not superimposed on the positive side of the power supply waveform. Therefore, the command signal detection unit 83b determines that the signal 4 does not include a command signal (step S03, NO). When the signal confirmation unit 83 determines that the signal extracted by the command signal detection unit 83b does not include a command signal, the signal confirmation unit 83 outputs a signal for adjusting the phase to the phase adjustment unit 82c.

  The phase adjustment unit 82c confirms whether or not the phase adjustment has already been performed for the series of signals (step S05). If the phase has already been adjusted for the series of signals (step S05, YES), the process returns to step S01 to detect the power line carrier waveform. On the other hand, when the phase adjustment is not performed on the series of signals (step S05, NO), the phase adjustment unit 82c reads the power line carrier waveform stored in the storage unit 82b, and the read power line carrier waveform is read. The phase is advanced by 180 ° (step S06).

For example, when the phase of the power line carrier waveform shown in signal 3 is advanced by 180 degrees, the extracted signal is as follows.
(Signal 5)
Reference signal cycle Positive 1 Negative 1 Positive 2 Negative 2 Positive 3 Negative 3 Positive 4 Negative 4
Presence or absence of signal 1 1 1 1 1 0 1 0
The extraction unit 82a outputs the extracted signal 5 to the signal confirmation unit 83, and repeats steps S02 to S03.

  As described above, if the signal confirmation unit 83 determines that the extracted signal includes the start signal but does not include the command signal, the signal confirmation unit 83 outputs a signal indicating that the phase is adjusted to the phase adjustment unit 82c ( Step S03). The phase adjustment unit 82c outputs the power line carrier waveform whose phase is advanced by 180 degrees to the extraction unit 82a (step S06), and the extraction unit 82a extracts a signal from the power line carrier waveform. The signal confirmation unit 83 determines whether or not the signal extracted by the extraction unit 82a for the power line carrier waveform whose phase is advanced by 180 degrees by the phase adjustment unit 82c includes both the start signal and the command signal (steps S02 and S03). ). As each processing unit operates in this manner, the deviation of the reference signal caused by the abnormal connection of the rubber transformer 9 and the aerial lighting cable 16 is eliminated, and the signal is correctly extracted.

  In the above description, the reference signal is described as being delayed. However, as is clear from FIG. 10, it can be understood that the power line carrier waveform is delayed by 180 degrees. Therefore, a mode in which the phase of the power line carrier waveform is advanced by 180 degrees includes advancing the phase of the reference signal by 180 degrees. Further, advancing the phase by 180 degrees includes inverting the positive / negative of the reference signal.

[3. Effect]
The operational effects of the present embodiment as described above are as follows.
(1) The lamp monitoring and control device of this embodiment includes a power line 6, a slave station 8 having a lamp L connected to the power line 6, and a master station connected to the power line 6 and controlling the lamp L via the power line 6. 4, the slave station 8 includes a waveform detection unit 81 that detects a power line carrier waveform of the power line 6, and an extraction unit 82 a that extracts a signal superimposed on the positive and negative of the power line carrier waveform based on a reference signal When the extracted signal includes both the start signal and the command signal, the signal confirmation unit 83 determines whether the extracted signal does not include the command signal. And a phase adjustment unit 82c that advances the phase of the power line carrier waveform by 180 degrees.

  As described above, when the phase of the reference signal is shifted due to an abnormal connection of a cable or the like, a phenomenon that the command signal cannot be detected even if the start signal can be detected occurs. In such a case, the phase adjustment unit 82c advances the phase of the power line carrier waveform by 180 degrees, so that even if a phase shift occurs, a highly reliable lamp that can perform the lamp monitoring control. A monitoring control device can be provided.

  Conventionally, when a phase shift occurs in the lighting monitoring and control device, the worker goes to the site again and changes the rubber transformer of the slave station that has become unrecognizable and the connection of the cable for aeronautical lighting connected to the rubber transformer. There was a need to do. However, facilities such as airports are vast, and the length of the cable can reach several kilometers, so enormous costs and time have been required to find the connection point of the cable that causes a phase shift.

  However, in the lighting monitoring control device of the present embodiment in which the phase of the power carrier waveform can be adjusted by the phase adjustment unit 82c, even if the phase is shifted, there is no need for a conventional change operation. Therefore, the work load and cost can be reduced. Similarly, even when a lighting monitoring control device is replaced or newly introduced at an existing airport, there is no problem that the system does not operate due to an abnormal connection of cables or the like. Therefore, work efficiency can be improved in the process up to the operation of the lighting monitoring control device.

(2) The phase adjustment unit 82c inverts the sign of the reference signal. The deviation of the phase of the reference signal caused by an abnormal connection such as a cable is 180 degrees. Therefore, by reversing the sign of the reference signal, it is possible to provide a highly reliable lighting monitoring control device that can perform lighting monitoring control even when a phase shift occurs.

(3) The signal confirmation unit 83 includes a start signal detection unit 83a that detects a start signal, and a command signal detection unit that detects a command signal following the start signal in a series of signals detected by the start signal detection unit 83a. 83b. As described above, when the phase of the reference signal is shifted, a phenomenon occurs in which the command signal following the start signal cannot be detected even when the start signal is detected. Therefore, in the series of signals from which the start signal detection unit 83a has detected the start signal, by providing the command signal detection unit 83b that detects the command signal following the start signal, it is possible to more reliably detect a signal having a phase shift. It becomes possible.

(4) The start signal detector 83a determines that the extracted signal includes a start signal, and the command signal detector 83b determines that the series of signals from which the start signal is detected does not include a command signal. When the determination is made, the command signal detection unit 83b outputs a signal indicating that the phase is adjusted to the phase adjustment unit 82c, and the phase adjustment unit 82c outputs the power line carrier waveform whose phase is advanced by 180 degrees to the extraction unit 82a. The signal confirmation unit 83 determines whether or not the signal extracted by the extraction unit 82a for the power line carrier waveform whose phase is advanced by 180 degrees by the phase adjustment unit 82c includes both the start signal and the command signal.

  That is, if it is determined that the series of signals from which the start signal is detected does not include the command signal, the start signal and the command signal are detected again after the phase is advanced by 180 degrees. With respect to the signal whose phase has been adjusted, the signal confirmation unit 83 detects the start signal and the command signal, so that even if there is a deviation in the phase, for example, a highly reliable lamp monitoring capable of performing the lamp monitoring control. A control device can be provided.

[Other Embodiments]
(1) In the above embodiment, the lighting monitoring control device has been described. However, as another aspect, it can also be understood as a program that causes a computer to execute the functions of the above-described units. That is, the lighting monitoring control device can be realized by controlling the computer with a predetermined program or by a dedicated electronic circuit. The program in this case realizes the processing of each unit as described above by physically utilizing computer hardware. A method for executing the processing of each unit, a program, and a recording medium on which the program is recorded are also one aspect of the embodiment. Moreover, how to set the range processed by hardware and the range processed by software including a program is not limited to a specific mode.

(2) In the above-described embodiment, the start signal is defined as the case where there is a signal in both positive and negative of the two cycles of the power line carrier waveform. Further, the command signal is defined as a signal on the positive side of the power supply frequency only. However, the definitions of the start signal and the command signal are not limited to these. Further, the extraction unit 82a is set to start signal extraction when there is a signal on the positive side of the reference signal, but may be a case where there is a signal on the negative side. That is, the definition of each signal can be set as appropriate, and this embodiment can be applied regardless of the definition of the signal.

(3) Although several embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

L ... Light 1 ... Central monitoring room 2 ... Operator console 3 ... Monitoring control panel 4 ... Master station 401 ... Upper I / F unit 402 ... Monitoring control unit 403 ... Transmitting unit 404 ... Receiving unit 5 ... Constant current generator 6 ... Power line DESCRIPTION OF SYMBOLS 7 ... Bypass filter 7a ... Current extractor 8 ... Slave station 801 ... Light control part 802 ... Core disconnection detection part 803 ... Monitoring control part 804 ... Optical I / F part 805 ... Transmission part 806 ... Reception part 81 ... Waveform detection part 82 ... signal extraction unit 82a ... extraction unit 82b ... storage unit 82c ... phase adjustment unit 83 ... signal confirmation unit 83a ... start signal detection unit 83b ... command signal detection unit 9 ... rubber transformer 9a ... plugs 9b and 9c ... receptacle 16 ... aerial illumination Cable 16a ... plug 16b ... receptacle

Claims (4)

Power lines,
A slave station having a lamp connected to the power line;
A master station connected to the power line and controlling a slave station via the power line,
The slave station is
A waveform detector for detecting a power line carrier waveform of the power line;
An extraction unit that extracts a signal superimposed on the positive and negative of the power line carrier waveform based on a reference signal extracted from the positive and negative waveforms of the power line carrier waveform;
A signal confirmation unit for determining whether or not the extracted signal includes both a start signal and a command signal;
A phase adjustment unit that advances the phase of the power line carrier waveform by 180 degrees when the signal confirmation unit determines that the extracted signal does not include the command signal;
A lighting monitoring control device comprising:   The lighting monitoring control apparatus according to claim 1, wherein the phase adjustment unit reverses the sign of the reference signal. The signal confirmation unit
A start signal detector for detecting the start signal;
The lamp monitoring control device according to claim 1, further comprising: a command signal detection unit that detects the command signal following the start signal when the start signal detection unit detects the start signal. . The start signal detector determines that the extracted signal includes a start signal;
When the command signal detection unit determines that the series of signals from which the start signal is detected does not include a command signal,
The command signal detection unit outputs a signal to adjust the phase to the phase adjustment unit,
The phase adjustment unit outputs a power line carrier waveform having a phase advanced by 180 degrees to the extraction unit,
The signal checking unit determines whether the signal extracted by the extraction unit for the power line carrier waveform whose phase is advanced by 180 degrees includes both a start signal and a command signal;
The lighting monitoring and control device according to claim 3.

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