JP2011083035A - Transmission device and communication system employing the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a transmission device flexibly coping with a change in a characteristic value to be set without the need for revising the circuit configuration of the transmission device even when the characteristic value to be set for a transmission signal is changed and to provide a communication system employing the transmission device. <P>SOLUTION: A characteristic value information obtaining part 9 obtains characteristic value information FD2 to be newly set to the transmission signal SS and denoting other characteristic values, and a characteristic value revision setting control part 9 controls a characteristic value setting part 8 to revise and set the set characteristic values to the other characteristic values denoted by the obtained characteristic value information FD2. Since the characteristic values are revised into the other characteristic values in this way, the characteristic values of the transmission signal SS can easily be revised without the need for revising the circuit configuration of the transmission device. Even when the characteristic values to be set are revised due to revision of regulated contents attended with the amendments of the law or revision of an operating area of the transmission device, for example, the transmission device can flexibly cope with the revision. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a transmission apparatus that outputs input data as a transmission signal. In particular, even when a characteristic value to be set for a transmission signal changes, the transmission apparatus should be set without changing the circuit configuration of the transmission apparatus. The present invention relates to a transmission apparatus and a communication system using the same that can flexibly cope with changes in characteristic values.

  In recent years, various communication methods such as a wireless LAN (Local Area Network) have been used, and besides this, power line carrier communication that can use a power line as a network transmission path has been proposed (for example, Patent Document 1). . In such a communication method, a characteristic value indicating a physical characteristic (for example, a frequency band and a power level) of a transmission signal output from the transmission device is regulated by various laws (for example, “Radio Law”). The restriction contents differ depending on the region such as “country”, and the transmission apparatus is set in advance so that the characteristic value of the transmission signal matches the restriction contents according to the use region.

JP 2000-165304 A

  However, the characteristic values to be set are not always constant, and there are cases in which the characteristic values change due to changes in the regulations according to the revision of the law or changes in the region where the transmitter is used. For this reason, for example, when the frequency band to be set changes, it may be necessary to change the circuit configuration of the transmission device, such as when a new band rejection filter needs to be added. There was an inconvenience that could not be done.

  Particularly in power line carrier communications, for example, there is a possibility of using frequency bands used by existing communication systems such as amateur radio and short wave broadcasting, so it is necessary to avoid interference with these existing communication systems. Various restrictions were added to the regulations. For this reason, there has been a demand for a transmission apparatus that can flexibly cope with changes in characteristic values to be set even when various restrictions are added to the contents of regulation.

  The problem to be solved is that when the characteristic value to be set for the transmission signal changes, it is necessary to change the circuit configuration of the transmission device, so that it is possible to flexibly cope with the change in the characteristic value to be set. There is no point.

  In the present invention, the characteristic value information acquisition unit acquires characteristic value information indicating other characteristic values to be newly set for the transmission signal, and the characteristic value change setting control unit determines the set characteristic value as described above. The main feature is that the characteristic value setting unit is controlled so as to be changed and set to another characteristic value indicated by the acquired characteristic value information.

  In the transmission apparatus of the present invention, by acquiring the characteristic value information of the characteristic value to be newly set for the transmission signal, the characteristic value of the set transmission signal is changed and set to the characteristic value to be newly set. Therefore, even if the characteristic value to be set changes, the characteristic value of the transmission signal can be easily changed without changing the circuit configuration of the transmission apparatus. Thereby, for example, even when the regulation content is changed in accordance with the revision of the law or when the use area of the transmission device is changed, it is possible to flexibly cope with the change of the characteristic value to be set.

Block diagram showing an example of a communication device The figure which shows an example of the contents of a frequency band table It is explanatory drawing which shows an example of transmission operation, (a) The figure which shows the flow of transmission data, (b) The block diagram which shows an example of a wavelet inverse transformer, (c) The figure which shows an example of a subcarrier Explanatory drawing which shows an example of the control which selects a subcarrier The figure which shows an example of the frequency spectrum when the frequency band is changed and set The figure which shows an example of the frequency spectrum at the time of changing and setting a frequency band and output power Block diagram showing an example of a communication system Block diagram showing an example of a server Block diagram showing an example of a communication system when a gateway is connected

A first invention made to solve the above-described problem is a transmission apparatus (1) that outputs input data (SD) as a transmission signal (SS).
A characteristic value setting unit (8) for setting a characteristic value indicating a physical characteristic (for example, frequency band) of the transmission signal (SS) (for example, Δf1);
A transmission signal generation output unit (5) for generating a transmission signal (SS) of the characteristic value (Δf1) set by the characteristic value setting unit (8) from the input data (SD) and outputting the generated transmission signal (SS) When,
A characteristic value information acquisition unit (9) for acquiring characteristic value information (for example, FD2) indicating other characteristic values (for example, Δf2);
The characteristic value (Δf1) set by the characteristic value setting unit (8) is changed and set to another characteristic value (Δf2) indicated by the characteristic value information (FD2) acquired by the characteristic value information acquisition unit (9). And a characteristic value change setting control unit (9) for controlling the characteristic value setting unit (8).

  With this configuration, by acquiring the characteristic value information of the characteristic value to be newly set for the transmission signal, the characteristic value of the set transmission signal is changed and set to the characteristic value to be newly set. Even when the characteristic value to be changed is changed, the characteristic value of the transmission signal can be easily changed without changing the circuit configuration of the transmission apparatus. Thereby, for example, even when the regulation content is changed in accordance with the revision of the law or when the use area of the transmission device is changed, it is possible to flexibly cope with the change of the characteristic value to be set.

In a second invention made to solve the above problem, the characteristic value setting unit (8) sets the frequency band of the transmission signal (SS) (for example, Δf1),
The transmission signal generation output unit (5)
A subcarrier selection unit (51) for selecting subcarriers (for example, SC2, SC3) within the frequency band (Δf1) set by the characteristic value setting unit (8);
A bit data generation unit (51) for generating a plurality of bit data (BL) from input data (SD);
A signal point mapping unit (51) that maps the bit data (BL) generated by the bit data generation unit (51) to signal points of digital modulation (for example, PAM: Pulse Amplitude Modulation),
Only the subcarriers (SC2, SC3) selected by the subcarrier selection unit (51) are mapped with the signal point data (PD) mapped by the signal point mapping unit (51) to generate a transmission signal (SS). And output the generated transmission signal (SS),
The characteristic value information acquisition unit (9) acquires characteristic value information (FD2) indicating another frequency band (for example, Δf2),
The characteristic value change setting control unit (9) indicates the frequency band (Δf1) set by the characteristic value setting unit (8) by the characteristic value information (FD2) acquired by the characteristic value information acquisition unit (9). The characteristic value setting unit (8) is controlled so as to be changed and set to the frequency band (Δf2).

  With this configuration, the frequency band of the transmission signal is changed and set by acquiring characteristic value information of the frequency band to be newly set, so the frequency band to be set can be changed without adding a band rejection filter. It can respond flexibly. As a result, even if the transmission device is configured to be used in a plurality of regions, it is not necessary to prepare a band rejection filter having a different filter coefficient for each region (for example, country). Can be prevented from increasing. Further, when the transmission apparatus is operated at a high speed, it is possible to prevent an increase in power consumption accompanying the addition of a band rejection filter.

According to a third aspect of the invention made to solve the above problem, the transmission signal generation output unit (5) further includes:
Wavelet inverse transform for generating time waveform series data (TD) by wavelet transforming the signal point data (PD) mapped only to the subcarriers selected by the subcarrier selection unit (51) (for example, SC2, SC3) Part (52),
A transmission signal (SS) is generated from the time waveform series data (TD) generated by the wavelet inverse transform unit (52), and the generated transmission signal (SS) is output.

  With this configuration, the frequency band of the transmission signal is changed and set using an OFDM (Orthogonal Frequency Division Multiplex) modulation scheme using wavelet inverse transform, so that computation processing that requires complex computation by Fourier inverse transform is performed. The calculation can be performed only by the real part calculation, and the amount of calculation processing can be reduced as compared with the OFDM modulation method using inverse Fourier transform. Thereby, the circuit scale in the transmission apparatus can be reduced.

4th invention made | formed in order to solve the said subject, the characteristic value setting part (8) sets the power level of a transmission signal (SS),
The transmission signal generation output unit (5)
A power level control unit (54) for controlling the power level of the transmission signal (SS) to the power level set by the characteristic value setting unit (8);
A transmission signal (SS) having a power level controlled by the power level control unit (54) is generated from the input data (SD), and the generated transmission signal (SS) is output.
The characteristic value information acquisition unit (9) acquires characteristic value information indicating other power levels,
The characteristic value change setting control unit (9) changes and sets the power level set by the characteristic value setting unit (8) to another power level indicated by the characteristic value information acquired by the characteristic value information acquisition unit (9). Thus, the characteristic value setting unit (8) is controlled.

  With this configuration, by acquiring the characteristic value information of the power level to be newly set, the power level of the transmission signal is changed and set. It can respond flexibly.

  A fifth invention made to solve the above problem is characterized in that the transmission signal generation output unit (5) outputs the generated transmission signal (SS) via a power supply line (for example, 2). .

  With this configuration, the characteristic value of the transmission signal output via the power line can be easily changed, so various restrictions have been added to the restriction contents, such as frequency band and allowable electric field strength. Even if it is a case, it can respond flexibly to these restrictions. Thereby, for example, even when a frequency band used by an existing communication system for amateur radio or shortwave broadcasting is used, it is possible to reliably avoid interference with these existing systems.

A sixth invention made to solve the above-described problem has a transmitter memory (10) for storing a characteristic value information table (FDT) in which characteristic value information (for example, FD) is associated with an area (AR). ,
The characteristic value information acquisition unit (9) acquires characteristic value information (FD2) corresponding to the use area (for example, AR2) of the transmission apparatus from the characteristic value information table (FDT).

  With this configuration, the characteristic value information corresponding to the area where the transmission apparatus is used is acquired from the characteristic value information table, so it is not necessary to check the characteristic value to be set in each area, and the labor of the user of the transmission apparatus is reduced. I can do it.

7th invention made | formed in order to solve the said subject has a signal input part (11) which receives the signal which designates the use area (for example, AR2) of a transmitter (1),
The characteristic value information acquisition unit (9) acquires characteristic value information (FD2) corresponding to the area (AR2) designated via the signal input unit (11) from the characteristic value information table (FDT). And

  With this configuration, the user of the transmission device can specify the region of the characteristic value information acquired from the characteristic value information table by operating the signal input unit, so that the degree of freedom in changing the characteristic value can be set. It can be provided and can flexibly respond to user requests.

The 8th invention made in order to solve the above-mentioned subject has an area information monitoring part (9) which monitors area information (for example, IPA) which shows a use area (for example, AR2) of transmitting device (1),
When the area information (IPA) of the transmitting apparatus monitored by the area information monitoring unit (9) is updated (for example, IPA2), the characteristic value information acquisition unit (9) For example, characteristic value information (FD2) corresponding to AR2) is obtained from a characteristic value information table (FDT).

  With this configuration, when the area information (for example, IP address) indicating the area where the transmission signal is used is updated, the characteristic value of the transmission signal is changed and set. The value can be changed and set automatically.

A ninth invention made to solve the above-mentioned problems is a communication system comprising the transmission device (1) and the server (30) according to any one of claims 1 to 5, which is connectable to a network (21). In (20)
Server (30)
A server memory (32) for storing a characteristic value information table (FDT) in which characteristic value information (for example, FD) is associated with an area (AR);
The characteristic value information (FD2) corresponding to the use area (for example, AR2) of the transmission device (1) is read from the characteristic value information table (FDT), and the read characteristic value information (FD2) is the characteristic value of the transmission device (1). It has a characteristic value information transmission part (33) which transmits to an information acquisition part (9).

  With this configuration, the server stores the characteristic value information table and transmits characteristic value information corresponding to the use area of the transmission device to the transmission device, so that the server can manage the characteristic value information for each region. . Thereby, for example, by preparing the latest characteristic value information in each region, even if the regulation content is changed in accordance with the revision of the law, it is possible to change and set the appropriate characteristic value.

In a tenth aspect of the invention made to solve the above problems, the transmission device (1) can be freely connected to the network (21) via the gateway (22),
The server (30) has a gateway area information monitoring unit (34) for monitoring area information (for example, IPA) set in the gateway (22),
When the regional information (IPA) of the gateway (22) monitored by the gateway regional information monitoring unit (34) is updated (for example, to IPA2), the characteristic value information transmission unit (33) of the server (30) is updated. The characteristic value information (FD2) corresponding to the area (AR2) of the area information (IPA2) is read from the characteristic value table (FDT) as characteristic value information corresponding to the use area of the transmission device (1), and the read characteristic value Information (FD2) is transmitted to the characteristic value information acquisition unit (9) of the transmission device (1).

  With this configuration, since the characteristic value of the transmission signal is changed and set using the area information set in the gateway, the area information indicating the area where the transmission apparatus is used needs to be monitored with respect to the transmission apparatus. The degree of freedom of monitoring can be expanded.

  The numbers in parentheses indicate the corresponding elements in the drawings for the sake of convenience in order to help understanding of the present invention. Therefore, the present description is not limited to the description on the drawings, and the present invention should not be construed by the description of the reference numerals.

  Hereinafter, embodiments of the present invention will be described with reference to FIGS.

(Embodiment 1)
FIG. 1 is a block diagram illustrating an example of a communication device. A communication apparatus to which the present invention is applied is, for example, a PLC (Power Line Communication) adapter 1 as indicated by a broken line in FIG. The PLC adapter 1 relays the power line 2 and the electric device 3. The power line 2 is a parallel cable that transmits a commercial power supply (for example, AC 100V), and the electric device 3 is, for example, a home appliance. In addition to the electric device 3, a plurality of electric devices (not shown) are connected to the power line 2 via PLC adapters (not shown). That is, these electrical devices connected to the PLC adapter constitute a home communication network by power line carrier communication via the power line 2. The power line 2 used for the power line carrier communication is not necessarily a commercial power line, and may be a DC power line transformed with AC 100V, for example.

  The PLC adapter 1 includes a transmission unit 5, a reception unit 6, a power line coupling unit 7, a control unit 8, a controller 9, a setting information unit 10, and a setting switch 11. The transmitter 5 includes a signal point mapper 51, a wavelet inverse transformer 52, a D / A converter 53, a transmission amplifier 54, and a band pass filter 55, as shown in the broken line frame at the top of FIG. Yes. The receiving unit 6 includes a band-pass filter 61, an amplification degree controller 62, an A / D converter 63, a wavelet transformer 64, and a symbol determiner 65, as shown in the broken line frame at the bottom of FIG. . In FIG. 1, the transmission path of the commercial power source from the power line coupling unit 7 to the electric device 3 is omitted.

  In the above configuration, a communication operation by the PLC adapter 1 will be described.

  The setting information unit 10 of the PLC adapter 1 stores a frequency band table FDT shown in FIG. 2 in advance. FIG. 2 is a diagram illustrating an example of the contents of the frequency band table FDT. The frequency band table FDT stores frequency band data FD corresponding to each area AR. The frequency band data FD indicates a frequency band Δf (for example, 0.1 to 0.2 krad / s [= 0.1π to 0.2π kHz]).

  Specifically, the frequency band data FD1, FD2, FD3,... Respectively indicate the frequency bands Δf1, Δf2, Δf3,..., And the frequency bands Δf1, Δf2, Δf3,. It corresponds to the areas AR1, AR2, AR3,. Further, the area AR indicates, for example, “country”, that is, the frequency band table FDT indicates a frequency band that can be used in power line carrier communication according to the laws and regulations of each country. The area AR does not necessarily have to be a “country”, and may be a “state” in the United States, for example, as long as the usable frequency band is different.

  The setting information unit 10 stores use area data ARD indicating an area in which the PLC adapter 1 is used (hereinafter simply referred to as “use area”). Here, it is assumed that the PLC adapter 1 is used in, for example, the area AR1, and used area data ARD indicating the area AR1 is stored as a default.

  In the communication operation (for example, when the PLC adapter 1 is activated), the control unit 8 reads the use region data ARD stored in the setting information unit 10 and the frequency band data FD corresponding to the region AR1 indicated by the use region data ARD. Is acquired from the setting information unit 10. Since the frequency band data FD corresponding to the area AR1 is FD1 as shown in FIG. 2, the control unit 8 acquires the frequency band data FD1 from the setting information unit 10 as shown in FIG. The acquired frequency band data FD1 indicates the frequency band Δf1 as shown in the figure, so that the control unit 8 selects a subcarrier SC corresponding to the frequency band Δf1 from a plurality of subcarriers SC described later. Commands to the signal point mapper 51 of the transmitter 5. That is, the frequency band Δf is set to Δf1.

  Next, the PLC adapter 1 performs a communication operation based on the set frequency band Δf1. Hereinafter, the communication operation of the PLC adapter 1 will be described with reference to FIGS. 1 and 3. 3A and 3B are explanatory diagrams showing an example of the transmission operation. FIG. 3A is a diagram showing the flow of transmission data SD, FIG. 3B is a block diagram showing an example of the wavelet inverse transformer 52, and FIG. 3C is a subcarrier SC. It is a figure which shows an example.

  When performing the transmission operation, the electrical device 3 outputs the transmission data SD to the PLC adapter 1 as shown in FIG. The transmission data SD is indicated by “00011111010110100”, for example, as shown in the upper part of FIG. When the transmission data SD is input to the PLC adapter 1, the transmission data SD is input to the signal point mapper 51 of the transmission unit 5 via the controller 9 of the PLC adapter 1.

  The signal point mapper 51 generates a plurality of bit strings BL having an appropriate length from the input transmission data SD. For example, as shown in the upper part of FIG. 3A, the transmission data SD “00011111010110100” is converted into “00”, “01”, “11”, “10”, “10”, “11”, “01”, “ The bit string BL is generated by dividing into two bits of “00”. Then, the generated bit string BL is mapped to each signal point of PAM (Pulse Amplitude Modulation) to generate signal point data PD.

  In the PAM, as shown on the right side of FIG. 3A, the bit strings BL of “11”, “10”, “00”, “01” are respectively “−3”, “−1”, “+1”, Since it corresponds to the signal point of “+3”, the signal point mapper 51 generates the generated bit strings BL “00”, “01”, “11”, “10”, “10”, “11”, “01”. , “00” to “+1”, “+3”, “−3”, “−1”, “−1”, “−3”, “+3”, “+1” signal points, Generate point data PD. When the signal point data PD is generated, the signal point mapper 51 inputs the generated signal point data PD to the wavelet inverse transformer 52. The digital modulation is not particularly limited to PAM, and may be, for example, BPSK (Binary Phase Shift Keying), QPSK (Quadrature Phase Shift Keying), or QAM (Quadrature Amplitude Modulation).

  As shown in FIG. 3B, the wavelet inverse transformer 52 includes an input device 52A and an inverse transformation processor 52B. The input device 52A includes the same number of input devices 52A1, 52A2,... As the number of subcarriers SC. In the wavelet transform process, the number of subcarriers SC can be freely set in the range of a power of 2. However, in the first embodiment, a wavelet that divides the frequency band Δf into four for simplicity of explanation. As shown in FIG. 3C, the number of subcarriers SC is assumed to be four (SC1, SC2, SC3, SC4). That is, the input device 52A of the wavelet inverse transformer 52 is composed of four input devices 52A1, 52A2, 52A3, and 52A4 corresponding to the subcarriers SC1, SC2, SC3, and SC4, respectively, as shown in FIG. Has been.

  The filter length may be an integral multiple of the number of subcarriers SC, and can be freely set within this range, similar to the number of subcarriers SC, but the filter length is twice the number of subcarriers SC. It is assumed that conversion is performed using two signal point data PD.

  The generated signal point data PD is input to these four input devices 52A1, 52A2, 52A3, 52A4. More specifically, for example, as shown in the table T1 in FIG. 3A, each of the subcarriers SC1, SC2, SC3, and SC4 is a preceding stage of the signal point data PD (see the left side of FIG. 3A). ) “+1”, “+3”, “−3”, “−1” are assigned, and “−1”, “−3”, “+3”, “+” in the subsequent stage (on the right side of FIG. 3A) +1 ”is assigned. Accordingly, as shown in FIG. 3B, the signal point mapper 51 receives the signal point data PD “+1” and “−1” as the input unit 52A1 and the signal point data PD “+3” and “−3” as shown in FIG. The signal point data PD “−3” and “+3” are input to the input unit 52A3, and the signal point data PD “−1” and “+1” are input to the input unit 52A4. That is, each signal point data PD is mapped to subcarriers SC1, SC2, SC3, and SC4.

  The input unit 52A outputs the input signal point data PD to the inverse transformation processor 52B, and the inverse transformation processor 52B outputs the signal point data PD mapped to the subcarriers SC1, SC2, SC3, and SC4 to the wavelet. Inverse conversion is performed to generate time sample values of the transmission waveform on the time axis in one symbol period, and time waveform series data TD “0.7034”, “0.6356”, “0” shown in the lower part of FIG. . 9474 ”,“ 2.5523 ”,. The D / A converter 53 converts the time waveform series data TD into an analog signal and outputs it as an analog signal at a fixed sampling time.

  The transmission amplifier 54 amplifies the output transmission waveform to the transmission signal level, and the band pass filter 55 removes unnecessary frequency components and outputs the transmission signal SS as shown in FIG. The power line coupling unit 7 outputs the transmission signal SS whose waveform has been shaped by the band pass filter 55 to the power line 2.

  On the other hand, when performing a receiving operation, for example, if another electrical device (not shown) transmits a reception signal RS to the electrical device 3 via the power line 2, the power line coupling unit 7 receives the reception signal RS from the power line 2. Extracted and output to the receiver 6 as shown in FIG. The band pass filter 61 of the reception unit 6 removes an out-of-band noise signal from the input / output transmission signal RS. The amplification degree controller 62 is set with a conversion gain, and adjusts the signal level of the reception signal RS so as to be within the dynamic range of the A / D converter 63 based on the conversion gain. The A / D converter 63 samples and digitizes the signal waveform of the reception signal RS whose signal level has been adjusted at the same timing as the sampling timing on the transmission side.

  The wavelet transformer 64 wavelet transforms the digitized waveform data of the received signal RS to obtain the signal point data PD of the subcarriers SC1, SC2, SC3, and SC4. The symbol determiner 65 performs inverse mapping of these signal point data PD, restores the bit string BL that seems to be closest, and obtains received data RD. Then, as shown in FIG. 1, the reception data RD is output to the electric device 3 and the communication operation by the PLC adapter 1 is performed. Note that the PLC adapter 1 does not necessarily perform a reception operation, and may simply be a transmission device.

  Next, the change setting process of the frequency band Δf will be described with reference to FIGS. 1, 2, 4, and 5. FIG. 4 is an explanatory diagram showing an example of control for selecting a subcarrier SC, and FIG. 5 is a diagram showing an example of a frequency spectrum when the frequency band Δf is changed and set.

  Here, the PLC adapter 1 is moved from, for example, the area AR1 to the area AR2, and the use area is changed from AR1 to AR2, and the home communication network using the power line carrier communication shown in FIG. Assume again. The PLC adapter 1 is provided with the setting switch 11 as described above, and the user of the PLC adapter 1 can specify the area where the PLC adapter 1 is used by operating the setting switch 11. ing.

  That is, when the user of the PLC adapter 1 inputs a signal indicating that the area AR2 that is the use area to the PLC adapter 1 via the setting switch 11, the controller 9 is stored in the setting information unit 10. The use area data ARD is updated and stored in the area AR2 indicated by the input signal from the area AR1.

  When the use region data ARD is updated and stored in the region AR2, the control unit 8 reads the use region data ARD stored in the setting information unit 10, and the frequency band data corresponding to the region AR2 indicated by the use region data ARD. The FD is acquired from the setting information unit 10. Since the frequency band data FD corresponding to the area AR2 is FD2 as shown in FIG. 2, the control unit 8 acquires the frequency band data FD2 from the setting information unit 10 as shown in FIG. Since the acquired frequency band data FD2 indicates the frequency band Δf2 as shown in the figure, the control unit 8 selects the subcarrier SC corresponding to the frequency band Δf2 from the four subcarriers SC1, SC2, SC3, SC4. The signal point mapper 51 of the transmission unit 5 is instructed to select. Here, the subcarriers corresponding to the frequency band Δf2 are SC2 and SC3. That is, the subcarriers SC2 and SC3 are selected.

  Specifically, the case where the signal point data PD “+1”, “+3”, “−3”, “−1”,... Is generated will be described with reference to FIG. When the signal point mapper 51 outputs the signal point data PD in the order of “+1”, “+3”, “−3”, “−1”,..., The control unit 8 is as shown in FIG. Then, zero is input to the signal point mapper 51 so that the signal point data PD is not input to the input units 52A1 and 52A4 corresponding to the unselected subcarriers SC1 and SC4. Accordingly, as shown in FIG. 4, the signal point mapper 51 receives the signal point data PD “+1”, “−3”,... As input to the input unit 52A2, and the signal point data PD “+3”, “−1”. ,... Are input to the input unit 52A3. That is, the signal point data PD is mapped only to the selected subcarriers SC2 and SC3.

  In FIG. 4, among the input signal point data PD, the signal point data PD “+1” and “−3” input to the input unit 52A2, and the signal point data PD “+3” input to the input unit 52A3. Only “−1” is shown. In addition, high-speed communication can be achieved by sequentially assigning signal point data PD to a plurality of subcarriers SC, but the same signal point data PD is simultaneously assigned to different subcarriers SC and transmitted. It is also possible. By doing so, more reliable data communication can be realized.

  The inverse transform processor 52B performs wavelet inverse transform on each signal point data PD mapped only to the subcarriers SC2 and SC3, and the transmission unit 5 transmits the transmission signal SS subjected to the same processing as described above to the power line 2. Output. Thus, since SC2 and SC3 corresponding to Δf2 are selected as the subcarrier SC, the frequency band Δf of the output transmission signal SS is changed from Δf1 to Δf2.

Thus, when the frequency band Δf is changed to Δf2, the frequency spectrum of the transmission signal SS is controlled within the range of the frequency spectrum that can be used in the area AR2. More specifically, for example, when the frequency spectrum SP _AR (broken line) that can be used in the area AR2 has the regulation areas LA1 and LA2 at 0.02 to 0.35 krad / s as shown in FIG. In the frequency spectrum SP _SS (solid line) of the transmission signal SS, the output power is controlled within the range of the frequency spectrum SP _AR . In order to simplify the explanation, Having described the number of sub-carrier SC as four, the sub-carrier SC2, SC3, and the frequency spectrum SP _SS shown in FIG. 5, it does not match.

As described above, even if the use area of the PLC adapter 1 is changed from the area AR2 to another area AR (for example, AR3), the change setting process of the frequency band Δf is performed as described above, and the frequency spectrum of the transmission signal SS is obtained. The SP _SS is controlled within the range of the frequency spectrum SP _{AR that} can be used in each area AR.

  As described above, in the present invention in Embodiment 1, by acquiring the frequency band data FD, the frequency band Δf of the set transmission signal SS is changed and set to the frequency band Δf to be newly set. Therefore, even when the frequency band Δf to be set changes, the frequency band Δf of the transmission signal SS is easily changed without adding a band rejection filter, that is, without changing the circuit configuration of the communication device. I can do it. Thereby, for example, even when the regulation content is changed due to a revision of the law or when the use area of the communication device is changed, it is possible to flexibly cope with the change of the frequency band Δf to be set. .

  Further, since it is possible to flexibly cope with changes in the frequency band Δf to be set without adding a band rejection filter, each communication apparatus can be used in a plurality of regional ARs. It is not necessary to prepare a band rejection filter having different filter coefficients for each area AR (for example, country), and an increase in circuit scale in the communication apparatus can be prevented. Further, when the communication device is operated at high speed, it is possible to prevent an increase in power consumption accompanying the addition of the band rejection filter.

  Further, since the frequency band Δf of the transmission signal SS output via the power line 2 can be easily changed, various restrictions on the restriction contents such as the frequency band and the allowable electric field strength are added to the restriction contents. Even if it is a case, it can respond flexibly to these restrictions. Thereby, for example, even when a frequency band used by an existing communication system for amateur radio or shortwave broadcasting is used, it is possible to reliably avoid interference with these existing systems.

  In addition, since the frequency band Δf of the transmission signal SS is changed and set using an OFDM (Orthogonal Frequency Division Multiplex) modulation method using wavelet inverse transformation, computation processing that requires complex computation by Fourier inverse transformation is performed. The calculation can be performed only by the real part calculation, and the amount of calculation processing can be reduced as compared with the OFDM modulation method using inverse Fourier transform. Thereby, the circuit scale in a communication apparatus can be reduced.

  Note that the conversion method between the time domain and the frequency domain is not limited to the wavelet conversion method, and for example, a Fourier transform method may be used. Further, although the OFDM modulation method is shown as the modulation method, it is not particularly limited to this, and for example, a spread spectrum modulation method may be used.

  In the first embodiment described above, the case where the frequency band Δf is changed has been described. However, the present invention is not limited to this as long as the characteristic value indicating the physical characteristic of the transmission signal SS is changed. For example, the transmission signal SS The power level may be changed. In this case, in the frequency band table FDT shown in FIG. 2, data indicating the power level is stored together with the frequency band Δf, and when the use area data ARD is updated and stored, the control unit 8 uses the use area data ARD. The data indicating the power level corresponding to is acquired, and the transmission amplifier 54 of the transmission unit 5 is commanded to change the power level of the transmission signal SS to the power level. In response to the command, the transmission amplifier 54 controls the output transmission waveform to the changed power level.

For example, the frequency spectrum available, and has been changed to SP _AR (dashed line) from the SP _AR '(dashed line) as shown in FIG. Frequency spectrum SP _AR ', a new regulatory region LA3 is with provided SP _AR, is obtained 10dB reduces the output power in the entire SP _AR. As described above, the power level is changed together with the frequency band Δf as described above even when the output power is changed as well as the frequency spectrum as the usable characteristic value. The frequency spectrum SP _SS (solid line) is controlled within the range of the frequency spectrum SP _AR ′ as shown in FIG.

  In the first embodiment described above, the case where the frequency band Δf is changed based on the frequency band table FDT shown in FIG. 2 has been described. However, the frequency band table FDT need not be stored in advance. For example, the user of the PLC adapter 1 can input the frequency band data FD from an input means (for example, a numeric keypad) provided in the PLC adapter 1. In this case, the setting switch 11 is not particularly necessary. Further, the input means does not necessarily have to be provided in the PLC adapter 1, and may be input from, for example, an input means (for example, a keyboard) provided in the electric device 3.

In the first embodiment described above, the PLC adapter is shown as an example of the communication device. However, any configuration may be used as long as the device has a transmission function. For example, it may be a semiconductor element having a transmission function, or may be an electric device having a transmission function (such as a personal computer, a printer, a copier, a telephone, or a facsimile). Such electric appliances include home appliances (TV, DVD [Digital Versatile] having a transmission function.
Also included are so-called Internet home appliances such as Disk] recorders. By using such various configuration modes, it is possible to provide a product that is easy to use.

(Embodiment 2)
Next, the communication system will be described. FIG. 7 is a block diagram illustrating an example of the communication system 20. As shown in FIG. 7, the communication system 20 includes a server 30 and a home gateway 22 connected to a network 21 such as an Internet connection network, and a communication device 1 connected to the home gateway 22. The configuration of the communication device 1 is the same as that of the PLC adapter 1 shown in FIG. In FIG. 1, the power line 2 and the electric device 3 are omitted.

  FIG. 8 is a block diagram illustrating an example of the server 30. The server 30 has a main control unit 31 as shown in a broken line frame in FIG. 8, and the main control unit 31 receives a setting information unit 32, a frequency band data transmission unit 33, and an IP via a bus line 35. It is connected to the address monitoring unit 34. The frequency band data transmission unit 33 is connected to the network 21. In the second embodiment, unlike the first embodiment, the frequency band table FDT shown in FIG. 2 is not stored in the setting information unit 10 of the PLC adapter 1 but is stored in the setting information unit 32 of the server 30. .

  In the above configuration, the change setting process of the frequency band Δf by the communication system 20 will be described with reference to FIGS. 1, 2, 7 and 8.

  The communication device 1 is used in the area AR1 as in the first embodiment, and “IPA1” is set as the IP address IPA of the electrical equipment 3 (for example, a personal computer) connected to the communication device 1. . The IP address IPA is an address defined by, for example, IPv4 (Internet Protocol Version 4). Since such an IP address IPA consists of a 32-bit number sequence, there are about 4.3 billion combinations of all number sequences, and a specific range of IP addresses is assigned by an organization such as IANA (Internet Assigned Numbers Authority). For example, an IP address “194.0.0.0” to “195.255.255.255” is assigned to each area AR such as a country.

  Here, as in the first embodiment, it is assumed that the communication device 1 is moved from the area AR1 to the area AR2, and the home communication network using the power line carrier communication shown in FIG. 1 is configured again in the area AR2. In this case, since the electrical device 3 has been moved to the area AR2, a DHCP (Dynamic Host Configuration Protocol) server (not shown) is different from “IPA1” among the IP addresses IPA assigned to the area AR2. Is changed to the electric device 3.

  The IP address monitoring unit 34 of the server 30 monitors the IP address IPA set for the electrical device 3, and when the IP address IPA is changed and set, the IP address of the electrical device 3 is transmitted via the network 21. The IPA is referred to, and the use area of the communication device 1 is set to be read out. Further, the server 30 stores an address table (not shown) indicating the range of the IP address IPA corresponding to each of the areas AR1, AR2, AR3,.

  That is, since the IP address IPA of the electrical device 3 is changed and set to IPA2 as described above, the IP address monitoring unit 34 refers to the address table stored in the server 30 and includes the IP address including the IP address IPA2. AR2 is read out as the area AR corresponding to the range of (that is, as the use area). When the area AR2 is read, the frequency band data FD corresponding to the area AR2 is read from the frequency band table FDT (see FIG. 2) stored in the setting information unit 32. The frequency band data FD corresponding to the area AR2 is FD2, and the frequency band data transmission unit 33 transmits the read frequency band data FD2 via the network 21 and the home gateway 22 as shown in FIG. To the controller 9.

  The controller 9 illustrated in FIG. 1 stores the transmitted frequency band data FD2 in the setting information unit 10 of the communication device 1. When the frequency band data FD2 is stored, the control unit 8 acquires the frequency band data FD2 from the setting information unit 10. Since the acquired frequency band data FD2 indicates the frequency band Δf2, the control unit 8 performs subcarriers corresponding to the frequency band Δf2 from, for example, four subcarriers SC1, SC2, SC3, and SC4 as in the first embodiment. The signal point mapper 51 of the transmission unit 5 is instructed to select SC2 and SC3, whereby the frequency band Δf of the transmission signal SS is changed from Δf1 to Δf2 as in the first embodiment. Will be. Note that the communication operation is the same as that in the first embodiment, and a description thereof will be omitted.

  As described above, in the present invention in the second embodiment, when the server 30 is updated with the IP address IPA indicating the use area of the communication device 1, the frequency band Δf of the transmission signal SS is changed and set. Unlike the first embodiment, the frequency band Δf can be automatically changed and set without taking time and effort for the user of the communication apparatus 1.

  Further, since the server 30 stores the frequency band table FDT and transmits the frequency band data FD corresponding to the use area of the communication device 1 to the communication device 1, the server 30 manages the frequency band Δf for each region AR. I can do it. Thereby, for example, by preparing the latest frequency band Δf in each area AR, even if the regulation content is changed in accordance with the revision of the law, the change setting can be made to an appropriate frequency band Δf.

  In the second embodiment, the IP address IPA is shown as an example of the area information indicating the area where the communication device 1 is used. However, it is not necessarily limited to the IP address IPA. Further, the IP address is not particularly limited to an address defined by IPv4, and may be an address defined by IPv6 (Internet Protocol Version 6), for example.

  In the second embodiment, the case where the server 30 monitors the IP address IPA of the electric device 3 has been described. However, the present invention is not limited to this, and for example, the communication device 1 monitors the IP address IPA of the electric device 3. You may do it. In this case, if the frequency band table FDT and the address table are stored in the communication device 1, the server 30 is not particularly required. Further, the server 30 does not directly monitor the IP address IPA of the electrical device 3, but monitors the IP address IPA of another communication device (for example, gateway) in which the IP address IPA corresponding to the use area of the communication device 1 is set. Thus, it is possible to monitor the IP address IPA of the electric device 3.

  FIG. 9 is a block diagram showing an example of the communication system 20 when monitoring the IP address of the gateway. In the communication system 20, unlike the communication system 20 shown in FIG. 7, the home gateway 22 is connected to the network 21 via the gateway 23, and the IP address monitoring unit 34 of the server 30 is set to the gateway 23. IP address IPA is monitored.

  At this time, when the communication apparatus 1 is moved from the area AR1 to the area AR2 and the home communication network by the power line carrier communication shown in FIG. 1 is reconfigured in the area AR2 as in the second embodiment. Assume that the gateway that relays the communication apparatus 1 to the network 21 is the gateway 23. Since the gateway 23 belongs to the area AR2, the IP address IPA of the gateway is changed from IPA1 to IPA2 similarly to the IP address IPA of the electrical device 3.

  The IP address monitoring unit 34 of the server 30 refers to the IP address IPA2 set in the gateway 23 via the network 21, and reads the area AR2 as the use area of the communication device 1 as described above. Accordingly, as described above, the frequency band data FD2 is acquired, and the frequency band data transmission unit 33 of the server 30 transmits the acquired frequency band data FD2 via the network 21, the gateway 23, and the home gateway 22 to the communication device 1. To the controller 9. As a result, the frequency band Δf of the transmission signal SS is changed from Δf1 to Δf2 as described above. By doing so, it is not necessary to monitor the area information indicating the area where the communication apparatus 1 is used with respect to the communication apparatus 1, and the degree of freedom of monitoring can be expanded.

  In the second embodiment described above, the case where the frequency band Δf is changed has been described. However, as long as the characteristic value indicating the physical characteristic of the transmission signal SS is changed, this is the same as in the first embodiment. Not limited. Moreover, although the PLC adapter was shown as an example of a communication apparatus, as long as it is an apparatus which has a transmission function, any structure aspect may be sufficient like Embodiment 1.

  In the second embodiment described above, the configuration of FIGS. 7 and 9 is shown as an example of the communication system 20, but it is not particularly limited to this. In addition, the network is not particularly limited to the Internet connection network as long as the communication device 1 can be connected. For example, an integrated digital communication network such as ISDN (Integrated Services Digital Network), an international public network, a cable modem network, DSL It may be a (Digital Subscriber Line) modem network, FTTH (Fiber to the Home), or an intranet network uniquely constructed in the enterprise. Further, as long as the Internet connection network can provide an IP (Internet Protocol) layer in OSI (Open Systems Interconnection), it may be an open wide area network or an intranet network uniquely constructed in the company. Further, no special limitation is required for the physical layer, the data link layer, and the network layer.

  In the communication system 20, the connection means between the communication device 1 and the network 21 is at least one or more of power lines, copper wires, twist lines, coaxial cables, wireless, Ethernet (registered trademark), telephone lines, and the like. Any connection means may be used as long as they are connected by means, and the type and number of physical layers of the interface are not limited.

  The present invention can be applied to a transmission device, a transmission method, and a communication system that output input data as a transmission signal. For example, when the regulations are changed due to a revision of the law, Even if it is changed, it is possible to flexibly cope with a change in the characteristic value to be set without changing the circuit configuration of the transmission apparatus.

1 PLC adapter, communication device (transmitting device)
2 Power line 5 Transmitter (Transmission signal generation output unit)
8 Control part (characteristic value setting part)
9 Controller (characteristic value information acquisition unit, characteristic value change setting control unit, regional information monitoring unit)
10 PLC adapter setting information section (transmitting device memory)
11 Setting switch (signal input section)
20 communication system 21 network 22 gateway 30 server 32 server setting information section (server memory)
33 Frequency band data transmitter (characteristic value information transmitter)
34 IP address monitoring unit (gateway area information monitoring unit)
51 Signal point mapper (subcarrier selection unit, bit data generation unit, signal point mapping unit)
52 Wavelet inverse transformer (wavelet inverse transformer)
54 Transmitter Amplifier (Power Level Control Unit)
AR region BL bit string (bit data)
FD2 frequency band data (characteristic value information)
FDT frequency band table (characteristic value information table)
IPA IP address (regional information)
PD signal point data (signal point data)
SC2, SC3 Subcarrier SD transmission data (input data)
SS Transmission signal TD Time waveform series data Δf1 characteristic value, frequency band Δf2 Other characteristic value, other frequency band

Claims (12)

In a transmission device that outputs input data as a transmission signal,
A storage unit for storing a plurality of characteristic values indicating physical characteristics of the transmission signal;
A characteristic value setting unit for setting one characteristic value among the plurality of characteristic values;
A transmission signal generation output unit that generates a transmission signal of the characteristic value set by the characteristic value setting unit from the input data, and outputs the generated transmission signal;
An area information monitoring unit that monitors area information corresponding to the use area of the transmission device;
A characteristic value information acquisition unit that acquires characteristic value information indicating other characteristic values stored in the storage unit based on the area information;
A characteristic value change that controls the characteristic value setting unit so that the characteristic value set by the characteristic value setting unit is changed to another characteristic value indicated by the characteristic value information acquired by the characteristic value information acquisition unit. A setting control unit;
A transmission apparatus characterized by the above. The characteristic value setting unit sets a frequency band of the transmission signal;
The transmission signal generation output unit
A subcarrier selection unit that selects subcarriers in the frequency band set by the characteristic value setting unit;
A bit data generation unit for generating a plurality of bit data from the input data;
A signal point mapping unit that maps the bit data generated by the bit data generation unit to a digital modulation signal point, and
Mapping the signal point data mapped by the signal point mapping unit only to the subcarriers selected by the subcarrier selection unit to generate the transmission signal, and outputting the generated transmission signal,
The characteristic value information acquisition unit acquires characteristic value information indicating another frequency band,
The characteristic value change setting control unit changes the frequency band set by the characteristic value setting unit to another frequency band indicated by the characteristic value information acquired by the characteristic value information acquisition unit. Control the value setting section,
The transmission apparatus according to claim 1. The transmission signal generation output unit further includes:
A wavelet inverse transform unit that generates time waveform series data by wavelet transforming data of signal points mapped only to the subcarriers selected by the subcarrier selection unit;
Generating the transmission signal from the time waveform series data generated by the wavelet inverse transform unit, and outputting the generated transmission signal;
The transmission apparatus according to claim 2, wherein: The characteristic value setting unit sets a power level of the transmission signal;
The transmission signal generation output unit
A power level control unit that controls the power level of the transmission signal to the power level set by the characteristic value setting unit;
Generating a transmission signal of a power level controlled by the power level control unit from the input data, and outputting the generated transmission signal;
The characteristic value information acquisition unit acquires characteristic value information indicating another power level,
The characteristic value change setting control unit changes the power level set by the characteristic value setting unit to another power level indicated by the characteristic value information acquired by the characteristic value information acquisition unit. Control the value setting section,
The transmission apparatus according to claim 1. The transmission signal generation output unit outputs the generated transmission signal via a power line.
The transmission apparatus according to claim 1. A transmission device memory for storing a characteristic value information table in which the characteristic value information corresponds to an area;
The characteristic value information acquisition unit acquires characteristic value information corresponding to a use region of the transmission device from the characteristic value information table;
The transmission apparatus according to claim 1. A signal input unit for receiving a signal indicating that the transmission device is used;
The characteristic value information acquisition unit acquires characteristic value information corresponding to an area designated via the signal input unit from the characteristic value information table.
The transmitter according to claim 6. A communication system comprising the transmission device and server according to claim 1, which is connectable to a network.
The server
A server memory for storing a characteristic value information table in which the characteristic value information corresponds to a region;
A characteristic value information transmitting unit that reads characteristic value information corresponding to a use area of the transmission device from the characteristic value table, and transmits the read characteristic value information to a characteristic value information acquisition unit of the transmission device.
A communication system characterized by the above. The transmission device is freely connectable to the network via a gateway,
The server has a gateway area information monitoring unit that monitors area information set in the gateway;
When the regional information of the gateway monitored by the gateway regional information monitoring unit is updated, the characteristic value information transmission unit of the server uses the characteristic value information corresponding to the region of the regional information to use the transmission device. Read out from the characteristic value table as characteristic value information corresponding to the region, and transmit the read characteristic value information to the characteristic value information acquisition unit of the transmission device,
The communication system according to claim 8. An area information monitoring unit that monitors area information indicating a use area of a communication apparatus that communicates with the transmission apparatus;
The characteristic value change control unit is configured to change and set the characteristic value corresponding to the region of the updated region information when the region information monitored by the region information monitoring unit is updated. The transmission device according to claim 1, wherein the value setting unit is controlled. A transmission device that communicates with a server that is connectable to a network and that transmits information corresponding to the area information acquired by monitoring the area information used in the network,
2. The transmission apparatus according to claim 1, wherein the characteristic change control unit controls the characteristic value setting unit to change and set the characteristic value based on information transmitted from the server. A transmission method used in a transmission device that outputs input data as a transmission signal,
Storing a plurality of characteristic values indicating physical characteristics of the transmission signal;
Setting one of the plurality of characteristic values;
A transmission signal having a characteristic value set by the characteristic value setting unit is generated from the input data, and the generated transmission signal is output.
Monitor regional information corresponding to the area where the transmitter is used,
Based on the area information, obtain characteristic value information indicating other characteristic values stored in the storage unit,
Controlling the characteristic value setting unit to change and set the set characteristic value to another characteristic value indicated by the characteristic value information;
A transmission method characterized by the above.

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