JP2012238940A - Communication system and communication device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable controlling to suppress solar cell power generation more reliably.SOLUTION: A communication system comprises: a conversion device for converting the power generation output of a power generation device to a predetermined voltage; and a communication device for receiving control information to control the power generation output. The communication device receives a signal on which the control information is broadcast at a first frequency, and converts the frequency of the received signal from the first frequency to a second frequency. The communication device superposes the signal on which the frequency is converted to the second frequency on the power generation output and supplies the resultant to the conversion device. The conversion device separates the signal on which the frequency is converted to the second frequency superposed on the power generation output from the power generation output supplied by the communication device, and extracts control information from the separated signal.

Description

  Embodiments described herein relate generally to a communication system and a communication apparatus.

  In recent years, a photovoltaic power generation system that distributes the output of a solar cell panel installed in each home and efficiently uses electric power has become widespread. In such a solar power generation system, it is necessary to suppress the generation of surplus power due to the fact that the power generated by solar power generation exceeds the demand power.

  As an output suppression method in a solar power generation system, output suppression utilizing bidirectional communication has been proposed together with an output suppression function based on calendar information by a power conditioner (PCS). That is, communication is performed between the control center and the control device of each solar cell panel, and output suppression of each solar cell panel is controlled from the control center.

For example, the following four methods have been proposed as communication methods at this time.
(1) A wireless communication device is mounted on the PCS, and communication is performed directly from the control center to the wireless communication device.
(2) A new communication device is introduced to each solar cell panel, and communication with the control center is performed via this communication device.
(3) Communicating with the control center via a power visualization system for visualizing the power used and a communication system using a smart meter applied to automatic metering of power usage.
(4) Communicate with the control center via the Internet.

Agency for Natural Resources and Energy, Electricity and Gas Division, “Next Generation Transmission and Distribution System System Study Group 1st Working Group 7th Secretariat Document”, online, December 17, 2010, Agency for Natural Resources and Energy, Electricity and Gas Division, Heisei Search on April 13, 2011, Internet (http://www.meti.go.jp/committee/summary/0004671/007_03_00.pdf)

  In the above-described method (1) using the wireless communication device mounted on the PCS, the state of wireless communication greatly depends on the installation location of the PCS. Therefore, there is a problem that the reliability of wireless communication depends on the installation location of the PCS, thereby determining whether or not the output control of the solar cell panel is possible.

  In the method (2) for introducing a new communication device, the possibility of output control of the solar cell panel may depend on the installation location of the communication device, as in the method (1) described above. In addition, this method has a problem that it is necessary to separately prepare communication means from the communication device to the PCS, which increases the introduction cost.

  In the method (3) of using a smart meter, it is necessary to introduce both the PCS and the smart meter, and there is a problem that the introduction cost increases. Further, in the method (4) using the Internet, there is a problem that the Internet line is not always prepared for the use environment of the solar cell panel, and there is a possibility that the introduction cost may increase.

  According to the embodiment of the present invention, it is an object to make it possible to control output suppression of solar cell power generation with higher reliability.

  An embodiment communication system includes a conversion device that converts a power generation output of a power generation device into a predetermined voltage, and a communication device that receives control information for controlling the power generation output. The communication device receives a signal whose control information is broadcast at the first frequency, and converts the frequency of the received signal from the first frequency to the second frequency. The communication device superimposes a signal, the frequency of which has been converted to the second frequency, on the power generation output, and supplies the signal to the conversion device. The conversion device separates the signal converted to the second frequency superimposed on the power generation output from the power generation output supplied from the communication device, and extracts control information from the separated signal.

1 is a schematic diagram of a configuration of a communication system according to a first embodiment. The block diagram of the communication apparatus of the transmission system which concerns on 1st Embodiment. 1 is a block diagram of a receiving system according to a first embodiment. The detailed block diagram of the communication apparatus which concerns on 1st Embodiment. The more detailed block diagram of the conversion apparatus which concerns on 1st Embodiment. The block diagram for demonstrating the acquisition method of the power supply of a communication apparatus. The block diagram of the radio | wireless processing part which concerns on each modification of 1st Embodiment. The block diagram of the analog process part which concerns on each modification of 1st Embodiment. The basic diagram which shows one information period of the time code | cord | chord at the normal time in a standard radio wave. The basic diagram of the output suppression notification format which concerns on the modification of 2nd Embodiment. Schematic of the communication system which concerns on 3rd Embodiment. The basic diagram for demonstrating alerting | reporting information. The block diagram of the communication apparatus by the side of the transmission system applicable to 4th Embodiment.

(First embodiment)
FIG. 1 schematically shows a configuration of an example of a communication system according to the first embodiment. The communication system includes a transmission system 1 and a reception system 2. The communication system may include a plurality of receiving systems 2, 2,... As shown in FIG. The transmission system 1 includes a control device 10 and a communication device 12 that are connected to each other via a network 11. The control device 10 generates an output suppression notification indicating whether to suppress the power generation output for the photovoltaic power generation system including the plurality of receiving systems 2, 2,..., And communicates with the communication device 12 via the network 11. Send to. The communication device 12 includes the received output suppression notification in the broadcast signal of the existing system and broadcasts it from the antenna 13 by wireless transmission.

  The control device 10 controls the amount of power generated by the photovoltaic power generation system and another large-scale power generation system such as thermal power generation. For example, the control apparatus 10 produces | generates the output suppression notification which shows performing suppression of an electric power generation output with respect to a solar power generation system, when surplus electric power generate | occur | produces by the electric power generation of a solar power generation system.

  In the transmission system 1, the control device 10 and the communication device 12 are not limited to those connected via the network 11. For example, the control device 10 and the communication device 12 can be configured integrally. The network 11 may be wired or wireless.

  The reception system 2 includes a communication device 22, a conversion device 23, and a power generation device 24. The communication device 22 receives the broadcast radio wave broadcast by the communication device 12 of the transmission system 1 through the antenna 21. The communication device 22 extracts the output suppression notification from the received broadcast radio wave and supplies it to the conversion device 23. The power generation device 24 generates electric power and sends the power generation output to the conversion device 23. The power generation device 24 is, for example, a solar cell panel that generates power according to the irradiated light.

  The conversion device 23 converts the power generation output sent from the power generation device 24 from direct current to alternating current, adjusts it to a predetermined voltage, and outputs it to the outside. The output of the conversion device 23 is supplied to various electrical devices as a power source, for example. Further, the conversion device 23 suppresses the output of the power generation output to the outside in accordance with the output suppression notification supplied from the communication device 22. As an example, the conversion device 23 stops the output of the power generation output to the outside when the output suppression notification indicates that the output is suppressed. On the other hand, when the output suppression notification indicates that the output suppression is not performed, the power generation output converted into alternating current is output to the outside.

  FIG. 2 shows an exemplary configuration of the communication apparatus 12 in the transmission system 1 shown in FIG. In FIG. 2, the same reference numerals are given to the portions common to FIG. 1 described above, and detailed description thereof is omitted. The communication device 12 includes an output suppression control unit 100, a data generation unit 101, a signal processing unit 102, and a wireless processing unit 103.

  The data generation unit 101 generates transmission data according to a broadcasting method applied to this communication system, based on data supplied from another device (not shown). The signal processing unit 102 performs predetermined signal processing necessary for broadcasting on the transmission data generated by the data generation unit 101. For example, the signal processing unit 102 performs signal processing such as addition of an error detection code, error correction coding, reference signal insertion, and modulation on the transmission data.

  The radio processing unit 103 performs radio signal processing on the transmission data subjected to these processes by the signal processing unit 102 in accordance with a broadcasting method applied to this communication system. For example, the wireless processing unit 103 performs wireless signal processing such as D / A conversion, orthogonal conversion, frequency conversion (up-conversion), band limitation, and power amplification on the transmission data. A transmission signal obtained by performing wireless signal processing on transmission data by the wireless processing unit 103 is broadcast as a radio wave by the antenna 13.

  In the communication device 12, the output suppression control unit 100 receives the output suppression notification transmitted from the control device 10 via the network 11, and includes it in the transmission data or transmission signal. For example, the output suppression control unit 100 supplies the output suppression notification to, for example, the data generation unit 101 and inserts it into the transmission data. Not only this but the output suppression control part 100 can supply the output suppression notification to the signal processing part 12, and can also superimpose it on a transmission signal.

  In the first embodiment, the broadcasting system of the existing system can be used as the broadcasting system. The output suppression notification can be inserted, for example, in an empty area defined in the data format in the broadcasting system of the existing system. It is also possible to modulate the output suppression notification and superimpose it on the broadcast signal of the existing system.

  FIG. 3 shows an exemplary configuration of the receiving system 2. In FIG. 3, the same reference numerals are given to the portions common to FIG. 1 described above, and detailed description thereof is omitted. In FIG. 3, the solid arrow indicates the flow of data (information), and the dotted arrow indicates the flow of power generation output (electric power). In the reception system 2, the communication device 22 includes a wireless processing unit 220 and a superimposing unit 221. The conversion device 23 includes a separation unit 230, a conversion unit 231, a signal processing unit 232, and a control unit 233.

  The power generation output by the DC voltage generated by the power generation device 24 is input to the communication device 22 via the electric wire and supplied to the superimposing unit 221.

  In the communication device 22, the radio processing unit 220 performs predetermined radio signal processing such as band limitation, power amplification, and frequency conversion (down-conversion) on a signal generated when radio waves are received by the antenna 21. To generate a reception signal. The superimposing unit 221 superimposes the reception signal generated by the wireless processing unit 220 on the power generation output supplied from the power generation device 24. The power generation output on which the reception signal is superimposed is supplied to the conversion device 23 via an electric wire.

  In the conversion device 23, the power generation output on which the reception signal is superimposed supplied from the communication device 22 is input and supplied to the separation unit 230. The separation unit 230 separates the received signal superimposed on the generated power output from the supplied power generation output and supplies it to the signal processing unit 232. Further, the separation unit 230 supplies the power generation output from which the reception signal is separated to the conversion unit 231.

  The signal processing unit 232 performs predetermined demodulation processing, error correction code decoding processing, and the like on the reception signal supplied from the separation unit 230 and supplies the result to the control unit 233. The control unit 233 extracts the output suppression notification from the signal supplied from the signal processing unit 232. And the control part 233 controls the conversion part 231 according to the extracted output suppression notification, and performs output suppression of electric power generation output.

  FIG. 4 shows an exemplary configuration of the communication device 22 in more detail. The reception signal generated when the antenna 21 receives radio waves is subjected to band limitation by a band pass filter (BPF) 222, and power is amplified by an amplifier 223. The reception signal output from the amplifier 223 is mixed with a signal of a predetermined frequency output from the oscillator 225 by the mixer 224, and then the high frequency component is limited by the low pass filter (LPF) 226, and the frequency is converted.

As an example, the frequency of the reception signal output from the antenna 21 is the frequency f ₁ , the frequency of the signal output from the oscillator 225 is the frequency f _2, and f ₁ > f ₂ . The received signal having the frequency f ₁ amplified by the amplifier 223 is mixed with the signal having the frequency f _{2 by} the mixer 224, and the high frequency component is further limited by the LPF 226, so that the signal having the frequency f ₃ = f ₁ −f ₂ is obtained. Is obtained. As an example, if the frequency f ₁ = 2.5 GHz and the frequency f ₂ = 2.48 GHz, the frequency-converted received signal has a frequency f ₃ = 20 MHz.

The reception signal changed to the frequency f ₃ is amplified by the amplifier 227 and supplied to the superimposing unit 221. The superimposing unit 221 superimposes the received signal, which is supplied from the wireless processing unit 220 and frequency-converted to the frequency f ₃ , on the power generation output by the DC voltage supplied from the power generation device 24. In the example of FIG. 4, the superimposing unit 221 uses the transformer 228 to superimpose the reception signal on the power generation output. The power generation output on which the reception signal is superimposed is supplied to the conversion device 23 via an electric wire.

  FIG. 5 shows an exemplary configuration of the conversion device 23 in more detail. The power generation output on which the reception signal is superimposed supplied from the superimposing unit 221 is input to the separation unit 230. The separation unit 230 separates the reception signal from the power generation output and supplies it to the signal processing unit 232. In the example of FIG. 5, the separation unit 230 separates the received signal from the power generation output using the transformer 240.

Note that the frequency of the received signal separated from the power generation output is the frequency f ₃ as described above. Here, it is conceivable that the signal quality of the power generation output on which the reception signal is superimposed changes depending on the installation environment of the communication device 22 and the conversion device 23. Therefore, for example, it is preferable to determine the frequency f _{3 of the} reception signal to be superimposed on the power generation output, that is, the frequency f ₂ in the oscillator 225 so that the separation unit 230 can separate the reception signal with good quality.

In the signal processing unit 232, the reception signal having the frequency f ₃ supplied from the separation unit 230 is input to the BPF 241, band-limited, and power amplified by the amplifier 242. The reception signal output from the amplifier 242 is mixed with the signal of the frequency f ₃ output from the oscillator 244 by the mixer 243, and then the high frequency component is limited by the low pass filter (LPF) 245, so that the baseband signal is Generated.

  The baseband signal is amplified by the amplifier 246, converted to a digital signal by the A / D converter 247, and supplied to the digital unit 248. The digital unit 248 subjects the digital signal converted from the baseband signal to demodulation processing corresponding to the processing performed by the signal processing unit 102 on the transmission system 1 side, decoding processing of an error correction code, and the like. Restore digital data. The digital unit 248 further extracts an output suppression notification from the restored digital data.

  As described above, according to the first embodiment, in the transmission system 1, the output suppression notification for controlling the power generation output of the power generation device 24 is included in the broadcast signal from the existing system and broadcast. On the receiving system 2 side, the broadcast radio wave broadcast including the output suppression notification is received, and the received signal is subjected to frequency conversion. Then, the reception signal whose frequency has been converted is superimposed on the power generation output of the power generation device 24 and supplied to the conversion device 23 via an electric wire.

  As described above, in the first embodiment, on the reception system 2 side, the communication device 22 that receives the broadcast radio wave including the output suppression notification and the conversion device 23 that performs conversion processing on the power generation output of the power generation device 24 are provided. It is separated. Therefore, by applying the first embodiment, the output suppression notification can be stably transmitted to the conversion device 23 on the reception system 2 side regardless of the installation environment of the power generation device 24 and the conversion device 23. Is possible. For example, the communication device 22 can be installed on a roof together with the power generation device 24, and the conversion device 23 can be installed indoors. Further, since the output suppression notification is broadcast using the existing system, the output suppression of the generated power can be controlled with a simple system.

  The communication device 22 is operated when power is supplied. The power supply for supplying to the communication device 22 is not limited to that obtained from the commercial power supply, and for example, the power generation output generated by the power generation device 24 can be used as the power supply. By using the power generation output of the power generation device 24 as a power source for the communication device 22, it is possible to suppress power consumption when the communication device 22 is installed.

  FIG. 6A and FIG. 6B show an example of a configuration when the power source of the communication device 22 is acquired from the power generation output of the power generation device 24. 6 (a) and 6 (b), the same reference numerals are given to the portions common to FIG. 3 described above, and detailed description thereof is omitted.

  FIG. 6A illustrates an example in which the power supply unit 260 generates power to be supplied to the wireless processing unit 220 from the power extracted from the power transmission path of the power generation output by the superimposing unit 221 in the communication device 22a. Note that, when the power generation amount of the power generation device 24 is small, the power supply unit 260 can determine that reception of the output suppression notification is unnecessary and can perform control so that power supply to the wireless processing unit 220 is not performed.

  FIG. 6B illustrates an example of a configuration in which the power supply unit 261 stores a part of the power extracted from the power transmission path of the power generation output in the power storage unit 262 in the communication unit 22b. Show. The power supply unit 261 generates power to be supplied to the wireless processing unit 220 using at least one of the power extracted from the power transmission path of the power generation output and the power stored in the power storage unit 262. In this case, when the power generation amount of the power generation device 24 is small, the power supply unit 261 may determine that reception of the output suppression notification is unnecessary and may perform control so that power supply to the wireless processing unit 220 is not performed.

(First modification of the first embodiment)
Next, a first modification of the first embodiment will be described. FIG. 7A shows an exemplary configuration of the wireless processing unit 220a according to the first modification. The wireless processing unit 220a includes an analog processing unit 300, an A / D conversion unit 301, an equalization unit 302, a D / A conversion unit 303, and an analog processing unit 304.

FIG. 8 shows an exemplary configuration of the analog processing unit 300. In FIG. 8, the same reference numerals are given to the portions common to FIG. 4 described above, and detailed description thereof is omitted. As illustrated in FIG. 8, the analog processing unit 300 mixes the frequency f ₁ signal output from the oscillator 250 by the mixing unit 224 with the reception signal of the frequency f ₁ output from the amplifier 223. A baseband signal is generated by limiting the high frequency component to the output of the mixing unit 224 by the LPF 226. The baseband signal is amplified by an amplifier 227 and output.

Returning to the description of FIG. 7A, the baseband signal output from the analog processing unit 300 is converted into a digital signal by the A / D conversion unit 301, and the equalization unit 302 equalizes distortion caused by wireless transmission. Then, it is converted again into an analog signal by the D / A converter 303. The baseband signal output from the D / A conversion unit 303 is converted into a frequency f ₃ by the analog processing unit 304 and subjected to predetermined analog signal processing such as band limitation and power amplification. The output of the analog processing unit 304 is supplied to the superimposing unit 221 and superimposed on the power generation output.

  In the first embodiment described above, the radio processing unit 220 performs only frequency conversion on the reception signal output from the antenna 21 and supplies the received signal to the superposition unit 221. On the other hand, in the first modified example, as described above, a baseband signal is once generated from the reception signal output from the antenna 21, and this baseband signal is A / D converted and equalized. D / A conversion is performed again to return to an analog signal and superimposed on the power generation output. Therefore, the reliability of the signal superimposed on the power generation output can be improved.

(Second modification of the first embodiment)
Next, a second modification of the first embodiment will be described. FIG. 7B shows an exemplary configuration of the wireless processing unit 220b according to the second modification. In FIG. 7B, the same reference numerals are given to the portions common to FIG. 7A described above, and detailed description thereof is omitted. As shown in FIG. 7B, the radio processing unit 220b according to the second modification is different from the radio processing unit 220a according to the first modification described above in place of the equalization unit 302. 310 and a modulator 311 are provided.

That is, the baseband signal output from the analog processing unit 300 is converted into a digital signal by the A / D conversion unit 301, and the demodulation unit 310 performs demodulation processing corresponding to the modulation processing by the signal processing unit 102. The digital signal demodulated by the demodulator 310 is subjected to transmission coding processing in the modulator 311 and is modulated again. The signal modulated by the modulation unit 311 is converted into an analog signal by the D / A conversion unit 303. This analog signal is converted into a signal of frequency f ₃ in the analog processing unit 304, subjected to predetermined analog signal processing such as band limitation and power amplification, and supplied to the superimposing unit 221.

  As described above, in the second modification example, as described above, a baseband signal is once generated from the reception signal output from the antenna 21, and this baseband signal is A / D converted and demodulated. The demodulated signal is subjected to transmission encoding processing, modulated again, D / A converted, converted back to an analog signal, and superimposed on the power generation output. Therefore, the reliability of the signal superimposed on the power generation output can be improved.

(Third Modification of First Embodiment)
Next, a third modification of the first embodiment will be described. FIG. 7C illustrates an exemplary configuration of the wireless processing unit 220c according to the third modification. In FIG. 7C, parts common to those in FIG. 7B described above are denoted by the same reference numerals, and detailed description thereof is omitted. As illustrated in FIG. 7C, the wireless processing unit 220c according to the third modification example is provided between the demodulation unit 310 and the modulation unit 311 with respect to the wireless processing unit 220b according to the second modification example described above. In addition, a decoding unit 320 is added.

That is, the baseband signal output from the analog processing unit 300 is converted into a digital signal by the A / D conversion unit 301, and the demodulation unit 310 performs demodulation processing corresponding to the modulation processing by the signal processing unit 102. The digital signal demodulated by the demodulation unit 310 is subjected to error correction by decoding the error correction code encoded by the signal processing unit 102 by the decoding unit 320. The error-corrected digital signal is modulated again by the modulation unit 311 using a predetermined method, and converted to an analog signal by the D / A conversion unit 303. This analog signal is converted into a signal of frequency f ₃ in the analog processing unit 304, subjected to predetermined analog signal processing such as band limitation and power amplification, and supplied to the superimposing unit 221.

  As described above, in the third modification, error correction processing is performed on the digital signal based on the reception signal output from the antenna 21, and then modulation processing is performed again to superimpose it on the power generation output. Yes. Therefore, the reliability of the signal superimposed on the power generation output can be further improved.

(Fourth modification of the first embodiment)
Next, a fourth modification of the first embodiment will be described. FIG. 7D shows an exemplary configuration of the wireless processing unit 220d according to the fourth modification of the first embodiment. In FIG. 7D, parts common to those in FIG. 7C described above are denoted by the same reference numerals, and detailed description thereof is omitted. As illustrated in FIG. 7D, the wireless processing unit 220d according to the third modification example is provided between the decoding unit 320 and the modulation unit 311 with respect to the wireless processing unit 220c according to the third modification example described above. In addition, a protocol processing unit 330 is added.

  That is, the baseband signal output from the analog processing unit 300 is converted into a digital signal by the A / D conversion unit 301, and the demodulation unit 310 performs demodulation processing corresponding to the modulation processing by the signal processing unit 102. The digital signal demodulated by the demodulation unit 310 is subjected to error correction by decoding the error correction code encoded by the signal processing unit 102 by the decoding unit 320.

  The protocol processing unit 330 generates transmission data according to a predetermined protocol based on the digital signal error-corrected by the decoding unit 320. At this time, the protocol processing unit 330 may generate transmission data based on a protocol different from a protocol applied to broadcasting between the transmission system 1 and the reception system 2. By converting the protocol, the processing in the conversion device 23 can be performed more flexibly.

The transmission data generated by the protocol processing unit 330 is modulated again by the modulation unit 311 using a predetermined method, and converted to an analog signal by the D / A conversion unit 303. This analog signal is converted into a signal of frequency f ₃ in the analog processing unit 304, subjected to predetermined analog signal processing such as band limitation and power amplification, and supplied to the superimposing unit 221.

  As described above, in the fourth modification example, error correction processing is performed on the digital signal based on the reception signal output from the antenna 21, and then transmission data is generated according to a predetermined protocol by the protocol processing unit 330, The transmission data is again subjected to modulation processing and the like so as to be superimposed on the power generation output. Therefore, the reliability of the signal superimposed on the power generation output can be improved, and the processing on the signal separated from the power generation output can be performed more flexibly.

(Second Embodiment)
Next, a communication system according to the second embodiment will be described. In the second embodiment, the configurations of the transmission system 1 and the reception system 2 included in the communication system can be applied almost as they are the configurations of the transmission system 1 and the reception system 2 according to the first embodiment described above. A detailed description of the parts that are common to the processing is omitted here.

  In the second embodiment, the output suppression notification is broadcast by transmitting the output suppression notification using an existing super-wide area broadcast type radio system. For example, when there is a free area in which information to be stored is not defined in one information cycle of the broadcast wireless system, an output suppression notification is inserted into the free area.

  As an ultra-wide area broadcast type radio system, a standard radio wave system that broadcasts standard time information at a predetermined cycle can be applied. The standard radio wave system is a system that broadcasts accurate time information at an accurate frequency using an atomic clock.

  In Japan, the standard radio wave broadcast by the standard radio wave system uses long-wave radio waves (frequency of 40 kHz and 60 kHz, respectively) from two locations in the Tohoku and Kyushu regions, and constantly transmits time codes as time-related information. ing. The time code transmitted by the standard radio wave includes a normal time code (other than 15 minutes per hour and 45 minutes) and a time code when a call code is transmitted (15 minutes per hour and 45 minutes). In the second embodiment, the output suppression notification is broadcast using a normal time code provided with a spare bit in which information to be stored for future expandability is not defined.

  FIG. 9 shows an example of one information period of a normal time code in a standard radio wave. The time code is expressed by encoding the time of the first marker M in one cycle using a binary number. The position marker P0 normally corresponds to the rise of 59 seconds, and the position markers P1 to P5 correspond to the rise of 9 seconds, 19 seconds, 29 seconds, 39 seconds, and 49 seconds, respectively. The time information is transmitted immediately after the head marker M in the order of minute, hour, day since January 1, year (last two digits of the year), day of the week, and leap second. The markers M, P0 to P5, and binary numbers “0” and “1” are identified by the pulse width. FIG. 9 shows an example of “no leap second within one month on Thursday, April 92, 2004 at 17:25 Thursday”.

  In the normal time code, 1 bit before and after the position marker P4, 2 bits in total, are reserved bits. Since the output suppression notification is a notification for controlling whether or not the power generation output by the power generation device 24 is suppressed, it can be expressed as long as there is at least one bit. Therefore, at least one of the two spare bits is assigned to a bit indicating an output suppression notification.

  As an example, the communication device 12 shown in FIGS. 1 and 2 can be made to correspond to a transmission device in a standard radio wave transmitting station. For example, in the communication device 12, the output of the atomic clock is supplied to the data generation unit 101. The data generator 101 generates the time code shown in FIG. 9 based on the supplied atomic clock output. At that time, the data generation unit 101 inserts the output suppression notification transmitted from the control device 10 via the network 11 into the spare bit position under the control of the output suppression control unit 100. The output suppression notification is inserted for each period with respect to the time code.

  The reception of the standard radio wave and the analysis of the time code can be executed by a module for a radio clock used in general homes and the like, and acquisition and use are easy. For example, the control unit 233 in the conversion device 23 shown in FIG. 3 has the function of a radio clock module, analyzes the signal supplied from the signal processing unit 232, and reserves the time code in the normal time code. Extract the value of the bit position. The control unit 233 controls the conversion unit 231 according to the extracted value, and suppresses the output of the power generation output.

As described above, the standard radio wave is transmitted using a long wave band having a frequency of several tens of kHz. On the other hand, in the receiving system 2, the frequency of the signal to be superimposed on the electric wire that transmits the power generation output from the communication device 22 to the conversion device 23 is considered to be several tens of kHz to several tens of MHz. Therefore, referring to FIG. 4, frequency conversion by the mixer 224, the oscillator 225, and the low-pass filter (LPF) 226 may not be performed in the wireless processing unit 220, and the frequency f _{2 of the} signal output from the oscillator 225 is not necessary. May be several tens of MHz, and the generated signal of the frequency f ₃ may be superimposed on the power generation output by the superimposing unit 221.

  Thus, according to the second embodiment, the output suppression notification can be broadcast over a wide range using the existing system, and the configuration on the receiving side can also use the configuration based on the existing system. The suppression control of the power generation output can be realized at a lower cost.

(Modification of the second embodiment)
Next, a modification of the above-described second embodiment will be described. In the second embodiment described above, the output suppression notification is inserted for each information period with respect to the time code of the standard radio wave, but this is not limited to this example. In the modification of the second embodiment, a format for transmitting an output suppression notification (referred to as an output suppression notification format) is defined using spare bits for a plurality of information periods, and the output suppression notification format is used. Send output suppression notification. Here, it is assumed that the output suppression notification includes information indicating whether or not the power generation output can be suppressed and information related to the information.

An example of the output suppression notification format will be described with reference to FIG. As illustrated in FIG. 10A, it is assumed that two spare bits 50 ₀ and 50 ₁ are included in one information period. As shown in FIG. 10 (b), M spare bits 50 ₀ , 50 ₁ , 50 ₂ ,..., 50 _M−1 included in the M / 2 information period (M is an integer of 1 or more) Thus, a frame of one control cycle is formed (FIG. 10C). A field is assigned to this frame every predetermined number of bits, and each piece of information constituting the output suppression notification is stored for each field.

  In the example of FIG. 10D, an HDLC (High-Level Data Link Control) frame structure is applied as an output suppression notification format. In this way, the system development cost can be reduced by using the existing frame structure. Of course, the present invention is not limited to this, and an original format may be used.

  Referring to FIG. 10 (d), “flag”, “address”, “control” and “company ID” are arranged 8 bits at a time from the head, with a frame of 30 information periods and a bit length of 60 bits as one control period. Then, the “region ID” is arranged in the next 10 bits. The next 2 bits of “area ID” are assigned a “suppression instruction” by output suppression notification. Finally, an error detection code is arranged with a bit length of 16 bits. As the error detection code, a CRC (Cyclic Redundancy Check), a checksum, or the like can be used.

  The “flag” is a synchronization bit indicating the head of one control cycle, and a specific bit pattern is used. “Address” indicates a destination address. “Control” can be used to control a specific function. “Company ID” is, for example, identification information for identifying a transmission power company. The “region ID” is identification information for identifying a region that is a notification target of the output suppression notification. The “suppression instruction” is information for performing suppression control of the power generation output of the power generation device 24, and indicates whether to suppress the power generation output. Of these, “address” and “control” can be omitted in the modification of the second embodiment.

  These pieces of information are generated by the control device 10 in the transmission system 1, input to the communication device 12 via the network 11, and supplied to the output suppression control unit 100. The output suppression control unit 100 generates an output suppression notification from each piece of information supplied from the control device 10 according to the output suppression notification format described above. On the other hand, the data generation unit 101 generates the time code shown in FIG. 9 based on the supplied output of the atomic clock. At this time, the output suppression control unit 100 takes out the generated output suppression notification two bits at a time from the head and passes it to the data generation unit 101. The data generation unit 101 inserts the passed 2-bit data at the spare bit position of the time code.

  As described above, by transmitting the output suppression notification using a large number of spare bits, it is possible to perform the suppression control of the power generation output in finer units such as each electric power company and each region. By further using “address” and “control”, an output suppression notification can be transmitted to each receiving system 2.

  In the above example of the standard radio wave system, since one information cycle is one minute, for example, on the receiving system 2 side, the control unit 233 extracts a spare bit from the time code and holds it in a register or the like. ”Is detected. Error detection is performed using an error detection code when spare bits of a predetermined number of bits (52 bits in the example of FIG. 10D) are extracted from the detected synchronization bits and stored in the register.

  If no error is detected, the control unit 233 determines whether or not the receiving system 2 including itself is an output suppression target based on the “company ID” and the “area ID”. It is assumed that the receiving system 2 stores and holds its own “company ID” and “area ID” in a ROM (Read Only Memory) or the like in advance. When the control unit 233 determines that the reception system 2 is an output suppression target based on the received signal, the control unit 233 controls the conversion unit 231 in accordance with the suppression instruction, and performs the generation output suppression control.

(Third embodiment)
Next, a third embodiment will be described. In the third embodiment, the configurations of the transmission system 1 and the reception system 2 included in the communication system can be applied almost as they are the configurations of the transmission system 1 and the reception system 2 according to the first embodiment described above. A detailed description of the parts that are common to the processing is omitted here.

  In the third embodiment, the output suppression notification is broadcast by transmitting the output suppression notification using an existing wide area wireless system. For example, when there is a free area in which information to be stored is not defined in one information cycle of the broadcast wireless system, an output suppression notification is inserted into the free area.

  As an existing wide area wireless system, a communication system (hereinafter referred to as a mobile communication system) used for wireless communication by a mobile terminal such as a mobile phone can be used. In such a mobile communication system, wireless communication is performed between a base station having a predetermined range as a communication area and a communication terminal existing in the communication area. Therefore, referring to FIG. 1 described above, the base station can be considered as the communication device 12 in the transmission system 1, and the communication terminal can be considered as the communication device 22 in the reception system 2.

  FIG. 11 schematically shows an example of a communication system using a mobile communication system according to the third embodiment. In FIG. 11, the same reference numerals are given to the portions common to FIG. 1 described above, and detailed description thereof is omitted. In the transmission system 1 (not shown), the control device 10 and the communication devices 12, 12,... Are connected via the network 11 (in FIG. 11, only a part of routes are shown to avoid complexity). . The communication devices 12, 12,... Are base stations having predetermined communication areas 30a, 30b,. In each communication area 30a, 30b,..., There is a receiving system 2, 2,... That includes a communication device 22, a conversion device 23, and a power generation device 24. In FIG. 11, communication areas 30a and 30b are communication area group A, and communication areas 30c and 30d are communication area group B.

  In such a mobile communication system, on the assumption that each terminal device is a mobile terminal, each base station obtains location information indicating the location of the base station. It goes periodically. Each terminal device can receive broadcast information transmitted from the nearest base station, acquire position information of the base station, and know a communication area including the terminal device. In the third embodiment, an output suppression notification is inserted into the broadcast information, and the output suppression notification is broadcast to each receiving system 2.

  FIG. 12 (a) shows an example of a signal when multicarrier communication such as OFDM (Orthogonal Frequency Division Multiplex) is used as a communication method in a mobile communication system. The vertical axis represents frequency and the horizontal axis represents time. Information is broadcast periodically in units of frames divided in the time axis direction. The broadcast information 40 is transmitted at a predetermined frequency and a predetermined time in each frame. The output suppression notification includes, for example, 1-bit information indicating that output suppression is performed with a value “1” and that output suppression is not performed with a value “0”. As illustrated in FIG. 12B, this output suppression notification is inserted into an area where information to be stored in the notification information 40 is not defined.

  For example, the communication device 12 generates the notification information 40 based on data from a control unit (not shown). At this time, the data generation unit 101 inserts the output suppression notification transmitted from the control device 10 via the network 11 into a predetermined position of the notification information 40 under the control of the output suppression control unit 100. The output suppression notification is inserted for each frame of transmission data. Further, the output suppression notification is not limited to the notification information 40, and may be inserted into paging information called paging, for example.

  As an example, the processing on the reception system 2 side causes the wireless processing unit 220 of the communication device 22 to have the function of a module of an existing mobile phone terminal. Then, the received signal obtained by receiving the radio wave from the base station (communication device 12) by the antenna 13 is subjected to processing such as demodulation and decoding by the module function of the mobile phone terminal to obtain a digital signal. This digital signal is modulated into a signal having a frequency suitable for being superimposed on the power generation output, supplied to the superimposing unit 221, superimposed on the power generation output from the power generation device 24, and transmitted to the conversion device 23. Not limited to this, the notification information 40 may be extracted from the digital signal, and only the extracted notification information 40 may be subjected to a predetermined process such as modulation and superimposed on the power generation output by the superimposing unit 221.

  In the conversion device 23, the separation unit 230 extracts a signal superimposed on the power generation output and supplies the signal to the signal processing unit 232. The signal processing unit 232 performs a predetermined process such as demodulation on the supplied signal to generate a digital signal, and supplies the digital signal to the control unit 233. The control unit 233 extracts the notification information 40 from the digital signal supplied from the signal processing unit 232, and further extracts an output suppression notification from the notification information 40. Then, the converter 231 is controlled in accordance with the output suppression notification that has been taken out, and the output of the power generation output is suppressed.

  The control device 10 can control output suppression for each communication area 30a, 30b,... Of each communication device 12 (base station). For example, the control device 10 transmits identification information for identifying each communication device 12, 12,... To the network 11 together with the output suppression notification. Each of the communication devices 12, 12,... Receives only the output suppression notification whose identification information corresponds to itself among the output suppression notifications transmitted via the network 11, and generates the notification information 40.

  Further, as described above, the control device 10 controls output suppression for each communication area of the plurality of communication devices 12 (base stations), not for each communication area 30a, 30b,... Of each communication device 12 (base station). May be. In the example of FIG. 11, output suppression control is performed on a communication area group A including two communication areas 30a and 30b and a communication area group B including two different communication areas 30c and 30d.

  Thus, according to the third embodiment, the output suppression notification can be broadcast over a wide range using the existing system, and the configuration on the receiving side can also use the configuration of the existing system. The suppression control of the power generation output can be realized at a lower cost.

(Fourth embodiment)
Next, a fourth embodiment will be described. In the fourth embodiment, the configurations of the transmission system 1 and the reception system 2 included in the communication system can be applied almost as they are the configurations of the transmission system 1 and the reception system 2 according to the first embodiment described above. A detailed description of the parts that are common to the processing is omitted here.

  In the fourth embodiment, the output suppression notification is broadcast by transmitting the output suppression notification using an existing digital broadcasting system. For example, the output suppression notification is modulated by a predetermined method and superimposed on the broadcast radio wave by the digital broadcasting system and broadcast. At this time, the signal power of the signal obtained by modulating the output suppression notification is set to a predetermined ratio or less with respect to the signal power of the existing broadcast radio wave so as not to hinder the reception process of the broadcast radio wave by the existing system.

  As an existing digital broadcasting system applicable to the fourth embodiment, there is terrestrial digital broadcasting. Digital terrestrial broadcasting uses broadcast and radio waves that are modulated and multiplexed using OFDM (Orthogonal Frequency Division Multiplexing) video and audio data that has been compression-encoded in a prescribed format, and data that accompanies the program. Send. At this time, the output suppression notification is modulated and transmitted by being superimposed on the broadcast radio wave by terrestrial digital broadcasting.

  FIG. 13 shows an exemplary configuration of the communication apparatus 12 on the transmission system 1 side that can be applied to the fourth embodiment. Note that, in FIG. 13, the same reference numerals are given to portions common to FIG. 2 described above, and detailed description thereof is omitted. In the communication device 12, the signal processing unit 102 includes a first modulation unit 200, a second modulation unit 201, and an adder 202. For example, the communication device 12 can be configured as part of a transmission facility (not shown) in terrestrial digital broadcasting.

  In a broadcasting station (not shown), video data and image data of a program are compressed and encoded by a predetermined method, and multiplexed with accompanying data related to the program to generate a program stream. This program stream is packed into TS packets by a transport stream (TS) for each predetermined unit, and multiplexed with program streams of other channels to generate a transport stream. This transport stream is input to the communication device 12.

  The transport stream input to the communication device 12 is supplied as transmission data to the first modulation unit 200 via the data generation unit 101. The first modulation unit 200 performs predetermined signal processing such as error correction coding, reference signal insertion, and modulation on the supplied transmission data to generate a transmission signal 210. In the case of terrestrial digital broadcasting, OFDM, which is one of multicarrier modulations, is applied as a modulation method. The transmission signal 210 is input to the adder 202.

  In FIG. 13, a transmission signal 210, and a broadcast signal 211 and an output suppression signal 212, which will be described later, each have a signal intensity P on the vertical axis and a frequency f on the horizontal axis.

  On the other hand, the control device 10 generates an output suppression notification and transmits it to the communication device 12 via the network 11. The output suppression notification received by the communication device 12 is supplied to the second modulation unit 201 via the output suppression control unit 100. The second modulation unit 201 performs predetermined signal processing such as error correction coding, reference signal insertion, and modulation on the supplied output suppression notification to generate an output suppression signal 212. The output suppression signal 212 is input to the adder 202 and superimposed on the transmission signal 210. The broadcast signal 211 in which the output suppression signal 212 is superimposed on the transmission signal 210 by the adder 202 is subjected to predetermined processing by the wireless processing unit 103 and transmitted from the antenna 13 as a broadcast radio wave.

  Here, as illustrated in FIG. 13, the second modulation unit 201 outputs the output suppression signal 212, the signal power per unit frequency is a signal per unit frequency of the transmission signal 210 generated by the first modulation unit 200. It produces | generates so that it may become below a predetermined ratio with respect to electric power. For example, the signal power of the output suppression signal 212 is set to a signal power that does not hinder the processing such as demodulation and decoding on the broadcast signal 211 in a television receiver that receives terrestrial digital broadcasting.

  The predetermined modulation method in the second modulation unit 201 is preferably a spread spectrum method represented by a direct spread method. In the communication device 22 of the reception system 2, the radio processing unit 220 despreads the output suppression signal 212 spread in the frequency band by spectrum spreading. By despreading the output suppression signal 212, the signal power per unit time of the output suppression signal 212 can be made larger than the signal power per unit time of the transmission signal 210 modulated by the first modulation unit 200. it can. Therefore, when the second modulation unit 201 performs modulation, the signal power per unit time of the output suppression signal 212 is predetermined with respect to the signal power per unit time of the transmission signal 210 modulated by the first modulation unit 200. Even when the ratio is less than or equal to the ratio, the output suppression signal 212 can be correctly extracted.

  Thus, according to the fourth embodiment, the output suppression notification can be broadcast over a wide range using the existing system, and the configuration on the receiving side can also use the configuration of the existing system. The suppression control of the power generation output can be realized at a lower cost.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 1 Transmission system 2 Reception system 10 Control apparatus 11 Network 12, 22 Communication apparatus 13, 21 Antenna 23 Converter 24 Electric power generation apparatus 40 Notification information 100 Output suppression control part 101 Data generation part 102 Signal processing part 103,220 Wireless processing part 221 Superimposition Unit 230 separation unit 231 conversion unit 232 signal processing unit 233 control unit

Claims (6)

A conversion device that converts the power generation output of the power generation device into a predetermined voltage;
The control information for controlling the power generation output is received by a signal broadcast at a first frequency, the frequency of the received signal is converted from the first frequency to a second frequency, and the frequency is the second frequency. A communication device that superimposes the signal converted into the frequency of the power on the power generation output and supplies the power generation output on which the signal is superimposed to the conversion device,
The converter is
A communication system that separates a signal converted to the second frequency superimposed on the power generation output from the power generation output supplied from the communication device, and extracts the control information from the signal. . The communication system according to claim 1, wherein the control information is broadcast by being inserted at a position of a spare bit defined in a standard radio wave. The control information is broadcast by being inserted into broadcast information for broadcasting position information indicating the position of the base station in a mobile communication system that performs wireless communication between the mobile terminal and the base station. The communication system according to claim 1. The control information is modulated such that the signal power per unit frequency is equal to or less than a predetermined ratio with respect to the signal power per unit frequency of the digital broadcast signal by the digital broadcast system, and is superimposed on the digital broadcast signal. The communication system according to claim 1, wherein the communication system is broadcast. A radio processing unit that converts a frequency of a received signal received by an antenna from a signal on which control information for controlling the power generation output of the power generation apparatus is broadcast at the first frequency, from the first frequency to the second frequency When,
The wireless processing unit superimposes the reception signal converted to the second frequency on the power generation output of the power generation device, and converts the power generation output on which the reception signal is superimposed into the power generation output of the power generation device to a predetermined voltage. A communication apparatus comprising: a superimposing unit that outputs to a conversion apparatus that performs conversion. The wireless processing unit
The frequency of the received signal is converted to a third frequency lower than the second frequency, the signal of the third frequency is converted to a digital signal and demodulated, and the demodulated digital signal is modulated to Converting to a signal of a third frequency, converting the frequency of the signal from the third frequency to the second frequency;
The superimposing unit is
6. The communication apparatus according to claim 5, wherein a signal whose frequency is converted from the third frequency to the second frequency by the wireless processing unit is superimposed on the power generation output.

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