JP2001298425A - Communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a communication system, that can makes stable communication independently of the relation between a transmission medium and earth grounding and an installation interval between a transmitter and a receiver, by directly detecting the electric field induced in the transmission medium, so as to eliminate a feedback electrode which was required in the conventional systems. SOLUTION: A micro controller MPU 1 in a communication unit TRX 1 generates a signal D1 corresponding to data to be sent to a communication unit TRX 2, modulates this signal D and outputs the modulated signal to a human body HB. The electric filed, given to the human body HB in the communication unit TRX 2, is transmitted to an optoelectronic crystal EO 2 via an electrode ER 2 to change the refractive index of the optoelectronic crystal EO 2. A refractive index detector DT 2 detects a change in the refractive index to acquire a modulation signal D1'. Then the modulation signal D1' acquired by the refractive index detector DT 2 is demodulated, and the demodulated signal is outputted to a micro controller MPU 2.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a communication system for transmitting a signal through a medium such as a human body.

[0002]

2. Description of the Related Art In conventional communication, wired communication by connecting communication lines and wireless communication using radio waves and the like have been common. However, with the recent technological development, a communication method using an electric field guided to a human body or the like has been proposed as a completely new communication method. Such a communication method using an induced electric field is described in “Personal Area N” by TGZimmerman.
etworks: Near-Field intrabody Communication. ”(I
BM System Journal Vol.35, No3 & 4, 1996-MIT Media La
boratory) (hereinafter referred to as “PA
N ”).

FIG. 11 is a schematic diagram of a communication system using the PAN. This is based on the above-mentioned document (IBM Syst.
em Journal Vol.35, No3 & 4, 1996-MIT Media Laborator
y) Excerpt from In general, the human body
It shows good conductivity for frequencies from Hz to several MHz. Therefore, depending on the carrier frequency, a human body can be used as a transmission path. Therefore, in this PAN,
A human body can be used as a signal transmission path by modulating a carrier wave showing good conductivity by a human body according to a signal to be transmitted from the transmitter and outputting the modulated carrier wave from the transmitter to generate an electric field in the human body.

[0004]

By the way, as shown in FIG. 11, a PAN uses an earth ground as a feedback transmission line. For this reason, it is necessary that the electrostatic coupling is established between the transmitter and the receiver via the earth ground. Therefore, if the transmitter or the receiver is installed at a position distant from the ground, the electrostatic coupling with the ground is weakened, and stable communication cannot be performed. As a result, it is necessary to install the transmitter and the receiver at a position that can be electrostatically coupled via the earth ground, and there is a problem that many restrictions are imposed on the method of installing the transmitter and the receiver. .

[0005] This PAN has another problem that "communication is not possible when a human body contacts the earth". In a PAN, a human body and a ground are used as a pair of signal transmission lines. Therefore, when the human body comes into contact with the earth ground, there is a problem that the circuit is short-circuited and communication cannot be performed. Considering the case of actually wearing a device and living, it is often the case that a person touches a desk or wall with bare hands. These objects, such as desks and wall surfaces, are usually considered as earth ground. Therefore, in a PAN where a short circuit occurs at the time of contact with the earth ground, a portable (wearable) that can be used in daily life.
It is difficult at present to realize portable communication devices.

On the other hand, Japanese Patent Application Laid-Open No. Hei 10-229357 discloses that a return electrode on the transmitter side and a return electrode on the receiver side are opposed to each other so that the ground electrode is replaced with a return electrode between the two return electrodes. Techniques have been proposed to ensure direct connection via air as a path. According to the invention described in the publication, at first glance, it seems that the problem in the PAN has been solved. However, in order to make a direct coupling between the transmitter and the return electrode of the receiver via air, it is inevitable to take a long distance between the return electrode provided in the transmitter and the return electrode provided in the receiver. There was a problem that was possible. Therefore, for example, it has been virtually impossible to perform communication between a transmitter installed on the head and a receiver installed on the waist. Further, according to the method described in the publication, when the size of the feedback electrodes of the transmitter and the receiver is reduced, the direct coupling between the return electrodes of the transmitter and the receiver via air becomes weaker. It is practically difficult to reduce the size of the object. Therefore, there is a problem that the size of the device cannot be reduced. The problem is P
This is common to ANs, and it is practically impossible to perform communication in a PAN if the feedback electrode is reduced.

The present invention has been made in view of such circumstances, and directly detects an electric field induced in a transmission medium, thereby eliminating the need for a feedback electrode in the conventional method, and eliminating the need for a transmission medium and ground. It is an object of the present invention to provide a communication system capable of performing stable communication irrespective of the relationship with the ground and the installation intervals of the transmitter and the receiver.

[0008]

According to a first aspect of the present invention, there is provided a communication system for applying a transmission medium and an electric field modulated by a transmission signal to the transmission medium. It is characterized by comprising a transmitter and a receiver that detects a part of the electric field via the transmission medium and generates a demodulated signal corresponding to the transmission signal. The communication system according to claim 2, in addition to the features described in claim 1, wherein the transmitter includes a housing that houses the transmitter,
An insulator that covers the housing, a modulator that generates a modulation signal from the transmission signal, an amplifier that generates a voltage obtained by amplifying the modulation signal between a signal output terminal and a reference terminal, and the housing that includes the insulator. And an electrode connected to the signal output terminal of the amplifier.

In a communication system according to a third aspect of the present invention, in addition to the features of the second aspect, the transmission medium is made of a dielectric material having conductivity with respect to a predetermined frequency, and the modulation medium in the transmitter is provided. The modulator modulates a carrier whose dielectric is conductive by the transmission signal to generate the modulated signal. The communication system according to claim 4,
In addition to the features according to claim 3, a human body is used as the dielectric, and the modulator in the transmitter is configured to transmit the transmission signal so that the human body is conductive.
The modulated signal is generated by modulating a carrier having a frequency of

In a communication system according to a fifth aspect of the present invention, in addition to the features of the third aspect, the earth is used as the dielectric, and the modulator in the transmitter transmits the earth by the transmission signal. The modulation signal is generated by modulating a carrier having a frequency of The communication system according to claim 6, in addition to the features according to any one of claims 1 to 5, the receiver includes:
A housing for housing the receiver, an insulator covering the housing, an electrode provided on a surface of the insulator, an electro-optic crystal provided inside the housing, and connected to the electrode; And a demodulation signal generating means for generating the demodulation signal according to a change in the refractive index of the electro-optic crystal.

[0011] A communication system according to claim 7 is a communication system including a transmission medium, a plurality of transmitters, and a plurality of receivers, wherein the plurality of transmitters are connected to the plurality of receivers. Specify a receiver to be a transmission destination, generate a transmission signal containing information indicating the specified destination, and apply an electric field modulated by the transmission signal to the transmission medium,
The plurality of receivers detect a part of the electric field via the transmission medium, and generate a demodulated signal corresponding to the transmission signal addressed to the receiver based on a result of the detection. The communication system according to claim 8, wherein the communication system includes a transmission medium, a plurality of transmitters, and a plurality of receivers, wherein the plurality of transmitters have different receptions for the plurality of receivers. Of the frequencies, an electric field modulated by a transmission signal with a carrier of a reception frequency corresponding to a receiver serving as a transmission destination is applied to the transmission medium, and the plurality of receivers are
A part of the electric field is detected through the transmission medium, and a demodulated signal corresponding to the transmission signal addressed to the receiver is generated based on the detection result.

A communication system according to a ninth aspect is a communication system comprising a transmission medium, at least two or more computers, and a communication device connected to each computer and serving as an interface of the connected computer. The transmission source computer in the plurality of computers generates a transmission signal including information to be transmitted to the transmission destination computer in the plurality of computers, sends the transmission signal to a communication device connected to the computers, A communication device connected to a computer serving as a transmission source applies an electric field modulated by a transmission signal transmitted from the computer to the transmission medium,
A communication device connected to the transmission destination computer detects a part of the electric field via the transmission medium, generates a demodulated signal corresponding to the transmission signal, and sets the decoded signal as the transmission destination. It is sent to a computer. The communication system according to claim 10 is a communication system according to claim 9, wherein the computer serving as the transmission source includes:
The transmission signal is generated in a format conforming to Ethernet.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, such embodiments do not specify the present invention and can be arbitrarily changed within the scope of the present invention.

[1] First Embodiment [1.1] Configuration of First Embodiment FIG. 1 is a block diagram showing an example of a communication system according to the present embodiment. As shown in FIG. 1, the communication system according to the present embodiment includes a communication device TRX near a human body HB.
1 and TRX2 (hereinafter, referred to as a “communication device TRX” unless otherwise specified). Then, in this communication system, communication is performed between the communication devices TRX1 and TRX2 using the human body HB as a transmission path.

The communication device TRX transmits and receives data via the human body HB. This communication device TRX
It has a function of modulating a carrier wave of several tens kHz to several MHz with a signal corresponding to data to be transmitted to another communication device TRX and outputting the modulated carrier wave to the human body HB. In addition, the communication device TRX
Has a function of receiving data transmitted from another communication device TRX via the human body HB by measuring a change in an electric field generated in the human body HB.

FIG. 2 is a perspective view showing an example of the appearance of the communication device TRX. As shown in FIG. 2, the communication device TRX according to the present embodiment includes a box-shaped casing CS covered with an insulator IS. Further, an electrode ER is provided on the lower surface side of the housing CS via an insulator IS. As a result, the communication device T according to this embodiment
In the RX, the casing CS is configured to be completely insulated from other parts and the human body HB. The case C
The reason why S is insulated from other parts will be described later in detail. Here, the electrode ER is for applying an electric field to the human body HB or detecting a change in the electric field generated on the human body HB. Therefore, when transmitting and receiving signals using the communication device TRX, the electrode ER is connected to the human body HB.
It is necessary to be placed in direct contact with, or to be installed on clothes or with some space. For example, the electrode ER may be attached to a waist or a wrist by a belt so as to come to the human body HB side, or may be gripped so that the electrode ER comes into direct contact with the hand. The appearance of the communication device TRX shown in FIG. 2 is merely an example, and the case CS is a human body H.
Any configuration may be used as long as it is completely insulated from B and the electrode ER. Therefore, the communication device TRX arranges the electrode ER on the bottom surface of the housing CS as shown in FIG.
A part of the insulator IS has a thickness, and the casing CS is made of a human body HB.
The housing CS may be insulated from the human body HB and the electrodes ER by keeping the housing CS away from the body.

FIG. 4 is a block diagram showing the internal configuration of the communication device TRX. As shown in FIG. 4, the communication device TRX according to the present embodiment includes a microcontroller MPU, a modulation device EC, and a transmission amplifier A in a housing CS.
P, a refractive index detector DT, an electro-optic crystal EO, and a demodulation device DC. Although omitted from FIG. 4 because it is not related to the gist of the present invention, this communication device TRX includes, in addition to these components, a battery for supplying operating power and a work area for the microcontroller MPU. Memory, a display device and a speaker for outputting the processing result of the received data.

The microcomputer MPU is a means for controlling transmission and reception of data D to and from another communication device TRX. More specifically, the microcomputer M
The PU sends a signal D corresponding to data to be transmitted to another communication device TRX to the modulation device EC. Also, the microcontroller MPU transmits the human body HB from another communication device TRX.
Performs a process corresponding to the signal D received via the. For example, when the received signal D is a signal corresponding to image data, the microcontroller MPU displays an image corresponding to the data on a display device (not shown),
The sound corresponding to the data is reproduced from a speaker (not shown).

The modulator EC is a microcontroller M
This is a device that modulates a carrier wave (a carrier wave of several tens of kHz to several MHz) of a frequency at which the human body HB exhibits good conductivity into a modulation signal D ′ using the signal D output from the PU. At this time, if the frequency of the carrier is selected to be a frequency at which noise from the surroundings is unlikely to enter, communication quality can be stabilized. Note that any method may be used as the modulation method in the modulation device EC.

The transmission amplifier AP is a differential amplifier, amplifies the modulation signal D 'sent from the modulation device EC, and
This is a device that occurs between Q and Q. The terminal P of the transmission amplifier AP is connected to the electrode ER. Therefore, when the modulation signal D 'is sent to the transmission amplifier AP, an electric field corresponding to the output voltage from the terminal P is generated on the human body HB. here,
The terminal Q is a terminal for supplying a reference potential of the transmission amplifier AP. Therefore, if the terminal Q is connected to the ground potential and the ground potential is connected to the casing CS, it is possible to stabilize the output signal from the terminal P and obtain the shielding effect of the internal circuit. . In this case, since the case CS has the reference potential, the case CS is short-circuited with the terminal Q unless the case CS is insulated from the human body HB or the electrode ER. For this reason, in this embodiment,
As described above, the surface of the casing CS is covered with the insulator, and the casing CS is completely insulated from the human body HB and the electrodes ER. Note that when the terminal Q cannot be connected to a stable potential, the terminal Q may not be connected to any of them, and the reference potential may be set to the atmosphere.

Electro-optic crystal EO and refractive index detector DT
Are constituent elements of the electric field sensor. This electric field sensor is a sensor for detecting an extremely weak electric field. Here, the electro-optic crystal EO is, for example, BSO (Bi
₁₂ SiO ₂₀ ), BTO (Bi ₁₂ TiO ₂₀ ), CdTi,
It is a crystal such as CdTe, DAST (dimethylaminosulfibazolium-tosylate) or the like, in which the refractive index of the crystal changes according to an applied electric field according to the so-called Pockels effect. For this reason, when an electric field is generated on the human body HB by the output of the modulation signal D ′ from another communication device TRX and an electric field is induced in the electrode ER, the electro-optic crystal EO is induced in the electrode ER. And changes the refractive index.

The refractive index detector DT has a light source for irradiating the electro-optic crystal EO with a laser beam, and a light receiving section (not shown) for receiving the laser beam emitted from the light source. ing. This light receiving unit receives the reflected light when the laser beam passes through the electro-optic crystal EO and the transmitted light is reflected, for example, in a state where the laser beam is irradiated to the electro-optic crystal EO from the light source. It is provided at a position where it can be operated.
Therefore, when a change occurs in the refractive index of the electro-optic crystal EO, the amount of light received in the light receiving unit changes with the change in the refractive index. As a result, the refractive index detector DT can detect a change in the refractive index of the electro-optic crystal EO based on the change in the amount of received light. For example, another communication device TR
The output of the modulation signal D ′ from X causes the electrodes E
An electric field corresponding to the modulation signal D ′ is induced on R, and the refractive index of the electro-optic crystal EO may change. In such a case, the refractive index detector DT detects a change in the refractive index of the electro-optic crystal EO, and acquires a modulation signal D ′ output from another communication device TRX based on the detection result. The electric field sensor composed of the electro-optic crystal EO and the refractive index detector DT is a known electric field sensor.
The detailed description is omitted because it is the same as that disclosed in -262117 and the like.

The demodulation device DC is a device for extracting the signal D from the modulation signal D 'sent from the refractive index detector DT. When demodulation is performed in this demodulation device DC, the same signal as when modulated in another communication device TRX is used.

[1.2] Operation of First Embodiment Hereinafter, the operation of the present embodiment will be described with reference to an example in which the signal D1 is transmitted from the communication device TRX1 to the communication device TRX2. I do. In the following description, the components of the communication device TRX1 are used to specify each code obtained by adding "1" to each code used in FIG. 4, and the components of the communication device TRX2 are not shown in FIG. The code obtained by adding “2” to each code used in 4 is used to specify each code.

<Operation Example 1> An operation example of this embodiment will be described below with reference to FIG. First, the transmitter TRX1
In, the microcontroller MPU1 generates a signal D1 corresponding to data to be transmitted to the communication device TRX2, and outputs the signal D1 to the modulation device EC1. In the modulation device EC1, by using this signal D1, a carrier having a frequency (several tens of kHz to several MHz) at which the human body exhibits conductivity is modulated into a modulation signal D1 '. Next, the modulation device EC1
The modulated signal D1 'obtained in
, Is converted into a change in voltage between the terminals P and Q, and is output to the electrode ER1. As a result, the human body HB
Is applied with an electric field corresponding to the modulation signal D1 ′.

On the other hand, in the communication device TRX2, the electric field applied to the human body HB is transmitted to the electro-optic crystal EO2 via the electrode ER2, and the refractive index of the electro-optic crystal EO2 changes. As a result, in the light receiving portion of the refractive index detector DT2, the amount of received light changes with a change in the refractive index of the electro-optic crystal EO2. The refractive index detector DT2 acquires the modulation signal D1 'output from the communication device TRX1, based on the change in the amount of received light. And the refractive index detector D
The modulated signal D1 'obtained at T2 is a demodulation device DC2
Is output to.

Next, the demodulation device DC2 includes a refractive index detector D
The modulated signal D1 'output from T2 is demodulated to extract a signal D1 corresponding to the modulated signal D1'. At this time, the same signal as the carrier in the modulation device EC1 is used in the demodulation device DC2. And the demodulation device DC2
Outputs the signal D1 extracted from the modulation signal D1 ′ to the microcontroller MPU2. As a result, in the microcontroller MPU2, processing corresponding to the signal D1 sent from the demodulation device DC2 is executed.

Here, the difference between the communication method according to the present embodiment and the PAN will be described with reference to FIGS. In FIG. 5, in order to avoid complicating the drawing, each unit shown in FIG.
Only the portions necessary to explain the difference from N are shown. In the PAN, as shown in FIG. 11, each of the transmitter and the receiver is provided with a return electrode for establishing electrostatic coupling by grounding. Also, Japanese Patent Application Laid-Open
In the invention described in Japanese Patent Application Laid-Open No. 0-229357, a feedback electrode for establishing direct coupling via air is provided in the same manner (not shown). On the other hand, in the communication system according to the present embodiment, for example, when an electric field is applied to the human body HB by the modulation signal D ′ output from the communication device TRX1, the electric field sensor (the electro-optic crystal EO2) of the communication device TRX2 And the refractive index detector DT2) directly detect a part of the electric field applied to the human body HB and obtain the modulation signal D1 '. As a result, as shown in FIG. 5, the communication system according to the present embodiment does not need to particularly provide a feedback electrode for receiving feedback from the communication device TRX that is the transmission destination.
Further, as shown in FIG. 5, in the communication system according to the present embodiment, no electrostatic coupling is established between the communication devices TRX1 and TRX2 by grounding.

<Operation Example 2> A second operation example of the present embodiment will be described below with reference to FIG. In this operation example, the signal D is transmitted from the communication device TRX1 possessed by the user a to the communication device TRX2 possessed by the user b.

First, an electric field is applied to the body of the user a (hereinafter referred to as "human body HBa") by the modulation signal D1 'output from the electrode ER1 of the communication device TRX1. At this time, the human body HBa and the body of the user b (hereinafter, “human body HB
b ") is in contact (eg, shaking hands) or in a state in which the human body HBa and the human body HBb are very close to each other, the electric field applied to the human body HBa changes the electric field applied to the human body HBb. Is transmitted to

On the other hand, in the communication device TRX2, the electro-optic crystal E according to the electric field transmitted to the human body HBb.
The refractive index of O2 changes. As a result, the communication device TRX1
Is obtained by the communication apparatus TRX2. Note that the process of outputting the modulation signal D1 ′ from the communication device TRX1 to the human body HB and the operation of obtaining the modulation signal D1 ′ in the communication device TRX2 are completely the same as those in the first operation example, and thus will be described. Omitted.

<Operation Example 3> A third operation example of the present embodiment will be described below with reference to FIG. In this operation example, when the user has the communication device TRX1, the data D1 is transmitted to the communication device TRX2 installed on a wall surface of a building or the like.

First, when the user is in contact with the communication device TRX2, the communication device T
When the modulation signal D1 'is output from the electrode ER1 of the RX1, an electric field corresponding to the modulation signal D1' is applied to the human body HB. On the other hand, in the communication device TRX2, the refractive index of the electro-optic crystal EO2 changes due to the electric field applied to the human body HB. As a result, the modulation signal D1 'output from the communication device TRX1 is obtained by the communication device TRX2.

As described above, the communication system according to the present embodiment is not configured to use the earth ground as the return transmission path. Therefore, it is not necessary to establish the electrostatic coupling between the communication device and the ground as in the PAN. Therefore, many restrictions are not imposed on the installation method, and even when the human body comes into contact with the earth ground, a short circuit does not occur and communication becomes impossible. Further, according to the communication device of the present embodiment, when an electric field is applied to the human body by the modulation signal output from the communication device of the transmission source, the electric field sensor of the communication device of the transmission destination transmits the electric field applied to the human body HB. Can be directly detected to obtain a modulated signal. As a result, communication can be performed even when the distance between the source communication device and the destination communication device is increased. Further, the communication system according to the present embodiment includes:
There is no need to provide a feedback electrode for receiving feedback from the communication device TRX that is the transmission destination. Therefore, there is no adverse effect that the size of the communication device is increased due to the increase in the size of the feedback electrode.

[1.3] Modifications <Modification 1> In the first embodiment, one-to-one communication is performed by using only one frequency carrier between transmission and reception. . However, it is also possible to perform one-to-N or N-to-N communication by using a plurality of carrier frequencies. Also, CS
By using the MA (Carrier Sence Multiple Access) method or equivalent means, a plurality of transceivers can configure a bus-like network using a carrier of one frequency. However, when the CSMA method is used, unlike the case where a plurality of carrier frequencies are used, only one communication device TRX can be transmitted on the bus.

<Modification 2> In the first embodiment, an electric field is applied to the human body HB by the communication device TRX1 of the transmission source, and the human body HB is used as a transmission path. However, any dielectric material having conductivity at a predetermined frequency such as a human body may be used as the transmission line. For example, other animals and plants may be used as the transmission path. The earth can also be used as a transmission path. In this case, by improving the detection sensitivity of the electric field sensor, the communication device TR placed in a distant place of the building
Communication between X1 and TRX2 and communication between a plurality of buildings are also possible. In theory, communication with the other side of the earth is also possible as shown in FIG.

[2] Second Embodiment [2.1] Configuration of Second Embodiment FIG. 9 is a diagram showing a configuration of a communication system according to the present embodiment. As shown in FIG. 9, the communication system according to the present embodiment includes small computers PC1 and PC2 (hereinafter referred to as “small computer P
C ") and the network cards TRXC1 and T
RXC2 (hereinafter, referred to as “network card TRXC” unless otherwise specified) and a human body HB. Here, in the communication system according to the present embodiment, the human body HB (the human body HB in the present embodiment) is used.
Is a bus) and the small computer PC
An AN (Local Area Network) is configured. This LAN conforms to Ethernet.

In FIG. 9, a small computer PC is
For example, a notebook computer or PDA (Personal Digital
Assistant), and has a PC card slot PCCS on one side thereof. A female connector for a PC card is provided inside the PC card slot PCCS. The driver software for the network card TRXC is installed in the small computer PC.
It has a function of driving the XC. That is, when there is data to be transmitted to another small computer PC, the small computer PC has a function of converting the data into a signal D in a format compatible with Ethernet and transmitting the signal D to the network card TRXC. When the signal D transmitted from another small computer PC is received by the network card TRXC, the small computer P
C receives the signal D from the network card TRXC and performs a corresponding process. Here, IEEE80
In 2.3, 10BASE-5, 10BASE-2, 10BASE-
There are four standards, T and 100 BASE-TX, and all of these standards employ the baseband system (however, the encoding system differs depending on each standard). Therefore, in the following description, all signals D transmitted and received between the small computer PC and the network card TRXC are of the baseband type.

The network card TRXC includes a small computer PC and an LA as well as a conventional Ethernet card.
In addition to the function as an interface with the N, as well as the first embodiment, it has a function of transmitting and receiving the signal D via the human body HB. That is, the network card TRXC
Is a small computer P from another small computer P
When a signal D corresponding to data to be transmitted to C is transmitted, a carrier wave of several tens of kHz to several MHz is frequency-converted using this signal D, and a signal after the frequency conversion (hereinafter, referred to as “ The conversion signal D ") is output to the human body HB. Further, the network card TRXC detects the electric field generated in the human body HB, and thereby detects the human body HB.
B has a function of acquiring the converted signal D ″ transmitted from another network card TRXC via B.

The network card TRXC
Has a casing CS having a shape defined by the PCMCIA / JEIDA standard. The surface of the housing CS is covered with an insulator, and a male connector PCCIM for a PC card is provided on one side. Therefore, the network card TRXC is the PC of the small computer PC.
It can be inserted into the card slot PCCS and connected to a female connector for a PC card. In addition, case C
In S, an antenna ANT is connected via a cable to the opposite side surface on which the male connector PCCIM is provided. Here, the antenna ANT is for applying an electric field to the human body HB or detecting a change in the electric field generated on the human body HB. Therefore, when communication is performed using the communication system according to the present embodiment, the antenna ANT
Must be placed in direct contact with the human body HB, or installed on clothes or with some space. Alternatively, the antenna ANT may be attached to the body of the small computer PC and the user may hold the small computer PC so that the antenna ANT is installed near the human body.

Next, FIG. 10 shows a network card TR.
It is the block diagram which showed the internal configuration of XC. FIG.
The same reference numerals as in FIG. 4 denote parts corresponding to those in FIG. As shown in FIG. 10, the network card TRXC according to the present embodiment includes a PC card connector PCCIM and an Ethernet transceiver module E
TM, transmission module TXM, reception module RX
M and an antenna ANT.

Ethernet transceiver module ET
M is a physical layer interface compatible with Ethernet. More specifically, this Ethernet transceiver ETM converts the frequency of a carrier wave of several tens of kHz to several MHz into a converted signal D "using a signal D output from a small computer PC, and then sends the converted signal to a transmission module TXM. Also, Ethernet transceiver module ET
M receives the converted signal D "from the receiving module RXM, converts the frequency of the converted signal D" to a predetermined frequency, and sends it to the small computer PC via the PC card connector PCCIM. . This Ethernet transceiver module ETM is 10BA
Depending on whether you use SE-5, 10BASE-2, 10BASE-T, or 100BASE-TX, you must use a different one. However, even when an Ethernet transceiver module conforming to any of the standards is used, it is exactly the same as a conventional Ethernet transceiver module, and therefore, detailed description is omitted.

The transmission module TXM is a device that outputs the converted signal D ″ sent from the Ethernet transceiver module ETM to the human body HB via the antenna ANT. The transmission module TXM is a transmission amplifier AP
And the Ethernet transceiver module E
It has a function of amplifying the converted signal D ″ sent from the TM and generating the converted signal between the terminals P and Q. The terminal P of the transmission amplifier AP is connected to the antenna ANT.
The transmission amplifier AP can send the output from the terminal P to the human body HB via the antenna ANT.

The receiving module RXM includes an electro-optic crystal E
This is a device that has an O and a refractive index detector DT and obtains a converted signal D ″ output from another small computer PC by detecting an electric field of the human body HB.

[2.2] Operation of the Second Embodiment In the following, in FIG. 9, the small computers PC1 through PCX are connected via the network cards TRXC1 and TRXC2.
The operation of the present embodiment will be described by taking, as an example, a case where a signal D1 corresponding to data to be transmitted to address 2 is transmitted. In the following description, the components of the network card TRXC1 are used to identify each of the symbols used in FIG. 10 with “1” added thereto, and the components of the network card TRXC2 are illustrated in FIG. Codes obtained by adding “2” to each code used in 9 are used to specify each code.

First, in the small computer PC1,
By performing the predetermined processing, a signal D1 corresponding to data to be transmitted to the small computer PC2 is generated. This signal D1 is transmitted to the network card T
RXC1 Ethernet Transceiver Module ETM
Sent to 1. Next, the Ethernet transceiver module ETM1 uses this signal D1 to
The frequency of a carrier of up to several MHz is converted. Thus, the converted signal D1 ″ obtained in the Ethernet transceiver module ETM1 is transmitted to the transmission module TX
In the transmission amplifier AP1 of M1, the voltage is converted into a change in voltage between the terminal Q and the terminal P and output to the human body HB via the antenna ANT1. As a result, an electric field corresponding to the conversion signal D1 "is applied to the human body HB.

On the other hand, in the network card TRXC2, the electric field applied to the human body HB is generated by the antenna ANT2.
Via the electro-optic crystal EO of the receiving module TXM2
2, and the refractive index of the electro-optic crystal EO2 changes. As a result, in the light receiving section of the refractive index detector DT2 of the receiving module TXM2, the amount of received light changes with a change in the refractive index of the electro-optic crystal EO2. Refractive index detector D
T2 acquires the converted signal D1 "output from the network card TRXC1 based on the change in the amount of received light. The converted signal D1" acquired by the refractive index detector DT2 is converted to the Ethernet transceiver module ET.
Output to M2.

Next, the Ethernet transceiver module ETM2 demodulates the converted signal D1 "output from the refractive index detector DT2 and extracts a signal D1 corresponding to the converted signal D1". Then, the signal D1 is sent from the Ethernet transceiver module ETM2 to the small computer PC2.

As described above, according to the network card of the present embodiment, communication between small computers can be performed via a human body. In addition, the network card according to the present embodiment operates in the same manner as a conventional Ethernet card from the viewpoint of a small computer, so that data communication can be performed without making any special changes on the small computer side. Further, since the same Ethernet transceiver module as a conventional Ethernet card can be used, manufacturing costs can be reduced.

In the present embodiment, the small computer PC and the network card TRXC are configured as separate devices. However, the network card TRXC may have all of these functions.

<Modification 1> In the second embodiment, the Ethernet transceiver module ETM is configured to convert the frequency of the baseband signal D. However, Ethernet transceiver module E
In TM, for example, FM (Frequency Modulatio)
n), PWM (Pulse Width Modulation), QAM (Qua
Modulation and demodulation may be performed using a modulation method such as drature amplitude modulation (Drature Amplitude Modulation). In this case, the Ethernet transceiver module ETM uses the signal D sent from the small computer PC to modulate a carrier of several tens of kHz to several MHz, which shows good conductivity of the human body HB.
As described above, if the signal D of the baseband system is modulated and transmitted / received by another modulation system, it is possible to reduce a transmission error in a transmission process and to improve a transmission distance.

[0052]

As described above, according to the present invention, by directly detecting an electric field induced in a transmission medium,
No feedback electrode is required, and stable communication can be performed irrespective of the relationship between the transmission medium and the earth ground and the installation intervals of the transmitter and the receiver.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating an example of a communication system according to an embodiment.

FIG. 2 is a perspective view showing an example of an appearance of a communication device TRX.

FIG. 3 is a perspective view showing an example of another appearance of the communication device TRX.

FIG. 4 is a block diagram illustrating an internal configuration of a communication device TRX.

FIG. 5 is an equivalent circuit diagram of the communication system according to the first embodiment.

FIG. 6 is a diagram showing a state in which communication is performed using a plurality of human bodies as transmission paths using the communication devices TRX1 and TRX2 according to the first embodiment.

FIG. 7 is a diagram illustrating a state where a communication device TRX1 is installed on a wall surface and communication is performed between a communication device TRX2 owned by a user and the communication device TRX1.

FIG. 8 illustrates the communication devices TRX1 and TR according to the present embodiment.
It is the figure which showed the state which communicates via the earth using X2.

FIG. 9 is a diagram illustrating a configuration of a communication system according to a second embodiment.

FIG. 10 is a diagram showing a configuration of a network card according to a second embodiment.

FIG. 11 is a schematic diagram showing a communication system using a conventional PAN.

[Explanation of symbols]

TRX: Communication device CS: Housing ER: Electrode HB: Human body MPU: Microcontroller EC: Modulator AP: Transmission amplifier EO: Electro-optic crystal DT: Refractive index detector D
C: Demodulator TRXC: Network card PC: Small computer ETM: Ethernet transceiver module A
NT ... Antenna

Claims (10)

[Claims] 1. A transmission medium, a transmitter for applying an electric field modulated by a transmission signal to the transmission medium, and a part of the electric field detected through the transmission medium, the transmission medium corresponding to the transmission signal. A receiver for generating a demodulated signal. 2. The transmitter, a housing for housing the transmitter, an insulator covering the housing, a modulator for generating a modulation signal from the transmission signal, and a voltage obtained by amplifying the modulation signal. An amplifier generated between a signal output terminal and a reference terminal, and an electrode isolated from the inside of the housing by the insulator and connected to a signal output terminal of the amplifier. 2. The communication system according to 1. 3. The transmission medium is made of a dielectric material having conductivity with respect to a predetermined frequency. The modulator in the transmitter modulates a carrier having the dielectric material with conductivity by the transmission signal. The communication system according to claim 2, wherein the modulated signal is generated by performing the modulation. 4. A human body as the dielectric, wherein the modulator in the transmitter is tens of kHz at which the human body becomes conductive by the transmission signal.
The communication system according to claim 3, wherein the modulated signal is generated by modulating a carrier having a frequency of up to several MHz. 5. The apparatus according to claim 1, wherein the earth is used as the dielectric, and the modulator in the transmitter generates the modulation signal by modulating a carrier having a frequency at which the earth is conductive by the transmission signal. The communication system according to claim 3, wherein 6. The receiver, wherein a housing for housing the receiver, an insulator covering the housing, an electrode provided on a surface of the insulator, and provided inside the housing, 6. An electro-optic crystal connected to the electrode, and a demodulation signal generating means for generating the demodulation signal in accordance with a change in the refractive index of the electro-optic crystal. The communication system according to any one of the above. 7. A communication system comprising a transmission medium, a plurality of transmitters, and a plurality of receivers, wherein the plurality of transmitters designate a receiver to be a transmission destination in the plurality of receivers. Then, a transmission signal including information indicating the designated destination is generated, and an electric field modulated by the transmission signal is applied to the transmission medium. The plurality of receivers transmit the electric field through the transmission medium. A communication system comprising: detecting a part of the signal; and generating a demodulated signal corresponding to the transmission signal addressed to the receiver based on a result of the detection. 8. A communication system comprising: a transmission medium; a plurality of transmitters; and a plurality of receivers, wherein the plurality of transmitters transmit, among different reception frequencies for each of the plurality of receivers, An electric field obtained by modulating a carrier having a reception frequency corresponding to a receiver at the destination by a transmission signal is applied to the transmission medium, and the plurality of receivers detect a part of the electric field via the transmission medium. A communication system for generating a demodulated signal corresponding to the transmission signal addressed to the receiver based on a detection result. 9. A communication system comprising: a transmission medium; at least two or more computers; and a communication device connected to each computer and serving as an interface of the connected computer. The computer generates a transmission signal including information to be transmitted to a destination computer in the plurality of computers, sends the transmission signal to a communication device connected to the computer, and is connected to the source computer. The communication device provides an electric field modulated by a transmission signal transmitted from the computer to the transmission medium, and a communication device connected to the transmission destination computer transmits the electric field of the electric field through the transmission medium. A part is detected, and a demodulated signal corresponding to the transmission signal is generated. Communication system, characterized by sending a signal to the computer to be the destination. 10. The communication system according to claim 9, wherein the transmission source computer generates the transmission signal in a format conforming to Ethernet (registered trademark).