JP2002525907A - Apparatus and method for forming an integrated signal, apparatus and method for forming a current signal and a first communication signal, and communication system and method for transmitting a first integrated signal and a second integrated signal - Google Patents

Abstract

(57) [Abstract] A first frequency region is provided when forming an integrated signal for a first communication signal, and a second communication signal that can be modulated on a current signal is provided. Is provided with a second frequency region. In this case, the first frequency domain at least partially has a higher frequency domain than the second frequency domain.

Description

DETAILED DESCRIPTION OF THE INVENTION

The present invention relates to an apparatus and a method for forming an integrated signal from a current signal and a communication signal, an apparatus and a method for forming a current signal and a first communication signal from an integrated signal, and a first integrated signal and a second signal. And a method of transmitting a first integrated signal and a second integrated signal within the communication system.

[0002] Such mechanisms and devices and systems of this kind are known from document [1]. This type of device has a terminal from which an integrated electrical signal can be extracted. The integrated signal includes a current signal (carrier frequency signal) and an electric signal that modulates the current signal. The electric signal to be modulated is a communication signal.

[0003] Here, the communication signal is an electric signal that enables transmission of electronic data, for example, an electric signal that enables transmission of text data, image data, or video data.

[0004] Basically, any modulation method can be used for modulation, for example, amplitude modulation, frequency modulation, or phase modulation can be used.

[0005] In this way, electronic data (communication signals) for communication is provided using an ordinary energy supply network, that is, a power supply network for supplying a three-phase AC voltage having a frequency of, for example, 50 Hz to an arbitrary number of consumers. Can also be transmitted, which makes the energy supply network available in the field of data transmission.

The device known from document [1] has a coupling element that is coupled to an energy supply network. A communication signal is obtained in the coupling element from the integrated signal in a first mode of operation. Also, in the second mode of operation, the current signal is modulated by the communication signal, thereby forming an integrated signal.

Further, a second terminal connected to the coupling element is provided. At the second terminal, a communication signal can be extracted or supplied according to the operation mode of the coupling element.

[0008] Therefore, a communication signal representing the communication data and to be modulated is produced at the second terminal or supplied thereto.

[0009] Furthermore, it is known from document [2] to apply such a device to the scenario depicted in FIG. FIG. 2 illustrates an energy supply network, that is, a power supply network 201, to which a house 202 is connected. Further, a base station 203 known from document [3] is connected to a power supply network 201 via an interface 204. The base station 203 is connected to a communication network 206 via a network interface 205.

The base station 203 has a processor 207, which is connected via a bus 208 to a data conversion card 209, also known from document [3], which itself is connected via a coaxial line 210. It is connected to the interface 204. Further, the power supply network 201 is provided with a transformer 211 for medium voltage / low voltage. In the following, it is assumed that the medium voltage is a voltage of several kilovolts (KV), typically 10 KV, and the low voltage is a normal operating voltage of the order of 230 V.
The house 202 is connected to the power supply network 201 via a house interface 212. The house interface 212 is connected to the above-mentioned known device denoted by reference numeral 213 in FIG.

The base station 203 modulates a low-voltage signal transmitted via the power line 214 of the power supply network 201 with a communication signal (hereinafter, referred to as a modulation signal). Further, the low voltage signal is hereinafter referred to as a carrier frequency signal. The carrier frequency signal is typically 220V and the frequency is 50Hz.

In this manner, the first signal 215 is provided to the house 202 via line 214,
This first signal comprises a carrier frequency signal 220 and a communication signal 221 generated by the base station 203 and modulating the carrier frequency signal.

Then, the first signal is supplied to the above-described device 213 via the house interface 212.

In the device 213, as is well known, the carrier frequency signal 220 is
6 and demodulated from the carrier frequency, the modulated signal 221 is supplied to the first computer and the second computer 219 via the coaxial line 217.

A disadvantage of such a scenario is that coaxial cable 217 must be laid from house 213 to each computer unit 218, 219 in house 202. In other words, in order to realize data communication via the power supply line 201, a new line must be laid in each room where a computer is provided in the house 202. As a result, much extra work is required when planning the house, and considerable flexibility is lost in planning and mounting the house 202.

Further, it is known that communication signals modulate current signals in a frequency range of several MHz, generally in a range of 1 MHz to about 8 MHz.

Such a restriction on the frequency range results from the attenuation characteristic of the transmission medium used. In the vicinity of about 8 MHz, the communication signal is greatly attenuated, making it impossible to transmit a relatively long communication signal. To transmit signals requiring a relatively large bandwidth, a specific transmission medium, such as a coaxial cable, is used.

Accordingly, it is an object of the present invention to provide a method and apparatus for forming an integrated signal comprising a current signal and a first communication signal and a method for forming a current signal and a first communication signal from the integrated signal. The goal is to increase flexibility in implementation and to improve bandwidth utilization.

It is a further object of the present invention to provide a method for transmitting a first integrated signal and a second integrated signal in a communication system and in a communication system with increased flexibility in planning and implementation of a house, and furthermore on the utilization of bandwidth. Is to be able to improve.

This object is achieved by a method and a device according to the features of the independent claims.

An apparatus for forming an integrated signal from a current signal and a first communication signal has the following features. A) a first terminal to which a current signal is supplied; b) a second terminal to which a first communication signal is supplied; c) an integrated terminal from which an integrated signal is taken out; A coupling element for forming an integrated signal from the first communication signal, the coupling element being connected to the first terminal, the second terminal, and the integrated terminal; e) the coupling element In signal formation, a first frequency region is provided for a first communication signal, and a second frequency region is provided for a second communication signal that can be modulated on a current signal, The first frequency domain at least partially has a higher frequency domain than the second frequency domain.

An apparatus for forming a current signal and a first communication signal from an integrated signal has the following features. A) a first terminal from which the current signal is derived; b) a second terminal from which the first communication signal is derived; c) an integrated terminal from which the integrated signal is supplied; and d) a current signal from the integrated signal. And a coupling element for forming a first communication signal, the coupling element being connected to a first terminal, a second terminal and an integrated terminal; e) the coupling element comprising: a first communication signal; In forming the signal, a first frequency region is provided and a second frequency region is provided for a second communication signal modulatable on a current signal, wherein the first frequency region is at least partially provided. It has a higher frequency range than the second frequency range.

In the case of a method of forming an integrated signal from a current signal and a first communication signal, a first frequency region is provided for forming an integrated signal for the first communication signal, and modulation is performed on the current signal. A second frequency range is provided for a possible second communication signal. In this case, the first frequency domain at least partially has a higher frequency domain than the second frequency domain.

A method for transmitting a first integrated signal and a second integrated signal in a communication system including a first communication unit, a second communication unit, and a power supply network for supplying a current signal includes the following. Has steps. -Forming a first communication signal by the first communication unit, adding the first communication signal to the current signal to form a first integrated signal, and-forming a first integrated signal in the first integrated signal. Providing a first frequency domain for one communication signal; transmitting a first integrated signal to a second communication unit; forming a second communication signal by the second communication unit; Adding a second integrated signal to the current signal to form a second integrated signal; providing a second frequency domain for the second communication signal within the second integrated signal; To the first communication unit, causing the first frequency domain to have a frequency domain that is at least partially higher in frequency than the second frequency domain.

Specifically, according to the present invention, the current signal is modulated by the communication signal in a frequency domain at least partially having a frequency higher than that of the frequency domain in which the communication signal has been transmitted. It is recognized that the distance from the individual terminals of the dwelling units to the power supply network within each dwelling unit must be tied to the computer, especially in relatively large houses with a large number of dwelling units. Nevertheless, this is small enough that the attenuation is not yet strong enough to make transmission of the communication signal impossible. In this way, flexibility in planning and implementation of a house can be increased, and optimal use of bandwidth can be realized.

[0027] Advantageous embodiments of the invention are set forth in the dependent claims.

Advantageously, the current signal is modulated by the second communication signal in a second frequency range.

Further, in the device configuration according to one embodiment, a modulation / demodulation unit is provided, and this unit is connected to the integrated terminal. With this unit, the current signal can be modulated with the first and / or second communication signal, thereby forming an integrated signal or by means of this unit with the first and / or second communication signal. Alternatively, the second communication signal can be demodulated from the current signal.

The modulation and demodulation unit is preferably connected to electrical equipment, which can be a computer (computing unit).

Next, an embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a schematic diagram of a conversion unit according to an embodiment.

FIG. 2 is a schematic diagram of a power supply network with a base station and a house connected to the power supply network using prior art devices.

FIG. 3 is a schematic diagram of a power supply network with a base station and a house connected to the power supply network using the device according to the embodiment.

FIG. 4 is a diagram showing attenuation progress characteristics regarding frequencies used for modulating the second communication signal 401 and the first communication signal 402.

In FIG. 3, the same reference numbers are used for the same components as in FIG. 2, in which a base station 203 is shown, which is connected via an interface 204 to the energy supply or power supply 201. It is connected.

FIG. 3 further shows a house 202 having a first dwelling unit 301 and a second dwelling unit 310. The first housing unit 301 is provided with a first computer 302, and the second housing unit 310 is provided with a second computer 311.

The first computer 302 is connected via a communication cable 303 to a first modulation / demodulation unit 304 described later. Further, the second current cable 305
, The first modulation / demodulation unit 304 is connected to a first conversion unit 306 which will also be described later.

The second computer 311 is connected to a second current cable 312 through a second
Is connected to the second modulation / demodulation unit 312 in this case.
13 is configured in the same manner as the first modulation / demodulation unit 304. Further, the second modulation / demodulation unit 313 is connected via a fourth current cable 314 to a second conversion unit 315 which will also be described later. In this case, the second conversion unit 315 is connected to the first conversion unit 315. 306 is configured in the same manner.

The structure of the first conversion units 306 and 100 is depicted in FIG. The first conversion units 306, 100 have a first terminal 101, to which a current signal 102 can be supplied or taken out, depending on the operating mode. In the first operation mode, the current signal 102 as a carrier signal is modulated by the second communication signal.

Further, in the first operation mode, communication directed from the first computer 302 to the power supply network 201 or the communication network 206 is performed as described later.

In the second operation mode, communication from the power supply network 201 or the communication network 206 to the first computer 302 is performed as described later.

Further, the first conversion units 306 and 100 have the second terminal 103,
A communication signal 104 can be supplied to this terminal 103 or extracted therefrom depending on the operation mode.

The first conversion units 306 and 100 have an integrated terminal 105, and can supply or take out the integrated signal 106 to the integrated terminal depending on the operation mode.

In the first operation mode, the integrated signal 106 includes the current signal 102 as a carrier frequency signal and the second communication signal superimposed on the current signal 102 by modulation. The second communication signal modulates the current signal 102 in a second frequency range of about 1 to about 4 to 8 MHz.

FIG. 4 shows a diagram 400 that illustrates the decay characteristic 403 of the modulation frequency of the second communication signal 401 and the first communication signal 402 as the frequency 404 increases. Here, the attenuation is shown in the unit of decibel (dB).

The transmission characteristics of the power supply networks 201, 305, and 314 are shown in the frequency domain in the diagram 400. In this case, since the distance in the power supply network 201 is relatively long, the attenuation of the second communication signal 401 is reduced. Due to this, only a modulation frequency of about 1 to 8 MHz can be used, and the transmission of the second communication signal is no longer possible. From the first conversion unit 306 or the second conversion unit 315 to the first computer 30
In the context of this embodiment with respect to the path to the second or second computer 311, a modulation frequency of up to about 20-30 MHz can be used over a fairly short distance, so that for the first communication signal 402 More bandwidth can be used. This is represented by the attenuation characteristic of the first communication signal 402. In this case, the attenuation increases only in the region from about 10 MHz to 20 MHz, and becomes strong only at around 20 MHz so that transmission of the modulation frequency of the first communication signal 401 is no longer possible. In addition, about 10-20 Mbps
The region of (Megabit per second) is hereinafter referred to as a first frequency region.

Based on such recognition, the first conversion unit 306 makes the integrated signal 106
During the operation mode, the current signal 102 as the carrier frequency signal and the current signal
2 is implemented to have first communication signals 402 and 104 modulating 2.

The first communication signals 402, 104 are superimposed on the current signal 102 in a first frequency domain, ie, within one dwelling unit for transmission of the first communication signal 402, respectively.
A frequency domain that includes frequencies higher than the frequency of the second frequency domain is used.

In this way, an optimal use of the available bandwidth is realized.

Further, the first conversion unit 306 has a coupling element 107 connected to the first terminal 101, the second terminal 103, and the integrated terminal 105. This coupling element 1
07 comprises a circuit 108, during which a first communication signal 104, 402 is carried on the current signal 102 in a first frequency domain during a first mode of operation, thereby forming an integrated signal 106. Has been implemented to be.

In addition, the coupling element 107 connects the second communication signal carried on the current signal 102 in the second frequency range to the conversion / demodulation unit 203 connected to the central connection terminal 320 during the second operation mode. Has been implemented to be supplied via. At a central connection terminal 320, a first communication signal 402 and a second communication signal 401 are guided together, as is known per se, to a communication network 206.
Supplied to

Next, the cooperation of the individual components will be described. Here, the transport control protocol / internet protocol (TCP / IP)
), The first computer 302 sends a request message 330. The request message 330 requests information from the Internet, in which case the communication network 206 is configured as the Internet. The request message 330 is supplied to the first modulation / demodulation unit 304. In the first modulation and demodulation unit 304, the request message 330 modulates the current signal 102 as a second communication signal 401, thus forming an integrated signal 506. The modulation is performed in the second frequency domain.

The integrated signal 506 is transmitted from the first modulation / demodulation unit 304 to the second current cable 305.
Is supplied to the integration terminal 105 of the first conversion units 306 and 100 via the.
During the first mode of operation, the integrated signal 10
6 is transmitted to the first connection cable 340 via the first terminal 101 together with the second communication signal 401 loaded by modulation. The first transmission cable 340 is connected to a power supply network as shown in FIG. 2, in which the current signal is modulated and transmitted as a second communication signal carried thereon. . A device 203 is disposed in the power supply network, and the device 203 demodulates the second communication signal carried on the current signal and supplies a request message 330 to the central connection terminal 320.

The central connection terminal 320 can be provided at any point in the power supply network, where the request message 330 is supplied to the communication network 206. Further, the communication network 206 further includes other computers 360, 361,
362, 363,. . . Is connected.

The request message 330 is sent to another computer 360, 362, 363. The request message is sent to those computers according to a unique Internet address (IP address), and in this embodiment, to a first other computer 360, which is implemented as an Internet server.

After receiving the request message 330, the first other computer 360 forms a reply message 370, which includes the information requested by the first computer 302. First another computer 360
Supplies a reply message 370 to the central connection terminal 320.

During the second mode of operation, the reply message 370 is sent to the central connection terminal 320
Through the second connection cable 350, and also through the second connection cable 350.
Is supplied as a first communication signal 402 to a first conversion unit 306 connected to the first conversion unit 306.

In the first conversion unit 306, the first communication signal is superimposed on the current signal 102 and modulation is performed, thereby forming the integrated signal 106. Modulation by the first communication signal 402 is performed in a first frequency domain. The integrated signal 106 is the first
Are supplied to the modulation / demodulation unit 304. The reply message 370 is demodulated from the integrated signal 106 as the first communication signal 402 in the first modulation / demodulation unit 304, and is supplied to the first computer 302.

In the following, an alternative to the above embodiment is shown. In this case, any communication protocol can be used as the communication protocol for digital data transmission, that is, the method and the device according to the present invention are not restricted to a communication protocol conforming to the TCP-IP standard.

The following publications are cited in this specification: [1] GB 2 272 350 B [2] D. Clark, Powerline Communications: Finally ready for prime time ?, IEEE Internet Computing 1998 January
Mon., Feb., pp. 10-11 [3] Brochure of Northern Telekom and Norweb Digital Powerline:
a major new business opportunity for power utilities worldwide, Commnica
tions Digital Power Line March 18, 1998

[Brief description of the drawings]

FIG. 1 is a schematic diagram of a conversion unit according to an embodiment.

FIG. 2 is a schematic diagram of a power supply network with a base station and a house connected to the power supply network using devices according to the prior art.

FIG. 3 is a schematic diagram of a power supply network with a base station and a house connected to the power supply network using an apparatus according to an embodiment.

FIG. 4 is a diagram showing attenuation progress characteristics regarding frequencies used for modulating a second communication signal 401 and a first communication signal 402.

[Procedural Amendment] Submission of translation of Article 34 Amendment of the Patent Cooperation Treaty

[Submission date] December 7, 2000 (2000.12.7)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Claims

[Correction method] Change

[Correction contents]

[Claims]

Claims (14)

[Claims] 1. An apparatus for forming an integrated signal from a current signal and a first communication signal, comprising: a) a first terminal to which a current signal is supplied; and b) a second terminal to which a first communication signal is supplied. And c) an integrated terminal from which the integrated signal is taken out; and d) a coupling element for forming an integrated signal from the current signal and the first communication signal, wherein the coupling element is the first terminal, E) the coupling element is provided with a first frequency range for a first communication signal in forming an integrated signal, the second frequency element being capable of being modulated on a current signal. A second frequency range configured for a communication signal, wherein the first frequency range has a frequency range at least partially higher than the second frequency range. Characteristic, current signal and first communication A device that forms an integrated signal from a signal. 2. a) a current signal is extracted from the first terminal; b) a first communication signal is extracted from the second terminal; c) an integrated signal is supplied to the integrated terminal. Item 1. The apparatus according to Item 1. 3. An apparatus for forming a current signal and a first communication signal from an integrated signal, comprising: a) a first terminal from which the current signal is extracted; and b) a second terminal from which the first communication signal is extracted. C) an integrated terminal to which an integrated signal is supplied; and d) a coupling element for forming a current signal and a first communication signal from the integrated signal, the coupling element comprising a first terminal and a second terminal. And e) the coupling element is provided with a first frequency range for forming the first communication signal, and is provided with a second frequency signal for modulating the second communication signal on the current signal. Wherein the first frequency domain has a frequency domain of a frequency higher than that of the second frequency domain at least partially. A device for forming one communication signal. 4. The device according to claim 1, wherein a modulation is performed by placing a second communication signal on the current signal in a second frequency range. 5. A modulation / demodulation unit connected to an integration terminal, wherein the modulation / demodulation unit places a first communication signal and / or a second communication signal on a current signal and modulates the current signal to perform integration. 5. The device according to claim 1, wherein a signal is formed or a first communication signal and / or a second communication signal is demodulated from the current signal by the modem unit. 6. The modulation / demodulation unit is connected to an electric device.
The described device. 7. The apparatus according to claim 6, wherein the electric device is a computer. 8. A communication system comprising a first communication unit, a second communication unit, and an energy supply network for supplying a current signal, comprising: a) a first communication unit formed by the first communication unit and added to the current signal; A first frequency domain is provided for one communication signal to form a first integrated signal; and b) a second communication signal formed by the second communication unit and added to the current signal. On the other hand, a second frequency domain is provided for forming a second integrated signal; c) the first frequency domain has at least partially a frequency domain of a higher frequency than the second frequency domain. A communication system comprising: a first communication unit, a second communication unit, and an energy supply network that supplies a current signal. 9. A method for forming an integrated signal from a current signal and a first communication signal, wherein a first frequency region is provided for the first communication signal when forming the integrated signal, A second frequency region is provided for a second communication signal on which modulation is performed, wherein the first frequency region has a frequency region of a frequency higher than the second frequency region at least partially. A method for forming an integrated signal from a current signal and a first communication signal. 10. A method for forming a current signal and a first communication signal from an integrated signal, wherein a first frequency region is provided for forming the first communication signal, and modulation is performed on the current signal. Providing a second frequency domain for the signal, wherein the first frequency domain is at least partially provided with a frequency domain having a higher frequency than the second frequency domain. To form a communication signal. 11. The method according to claim 9, wherein the modulation is performed by placing the second communication signal on the current signal in the second frequency domain. 12. The method according to claim 9, wherein the first communication signal and / or the second communication signal are modulated on the current signal to form an integrated signal. 13. The method according to claim 9, wherein the communication signal and / or the second communication signal are demodulated from the current signal. 14. A first integrated signal and a second integrated signal in a communication system comprising a first communication unit, a second communication unit, and an energy supply network for providing a current signal.
A) forming a first communication signal by a first communication unit and adding the first communication signal to a current signal to form a first integrated signal; b) Providing a first frequency domain for a first communication signal within the first integrated signal; c) transmitting the first integrated signal to a second communication unit; and d) transmitting the first integrated signal to the second communication unit. Forming a second communication signal and adding the second communication signal to the current signal to form a second integrated signal; e) a second integrated signal within the second integrated signal for the second communication signal; F) transmitting the second integrated signal to the first communication unit; and g) causing the first frequency region to have a frequency region at least partially higher in frequency than the second frequency region. A first communication unit, a second communication unit, and a current signal Method for transmitting a first integrated signal and the second integrated signal in a communications system having a supply energy supply network.