JP5108913B2 - Electric field communication system - Google Patents

Description

  The present invention relates to an electric field communication system that induces an electric field based on information to be transmitted in an electric field transmission medium, and detects the induced electric field to transmit and receive information.

  Although wearable computers are attracting attention due to the miniaturization and high performance of portable terminals, FIG. 6 shows an example in which such wearable computers are worn and used by humans. As shown in the figure, the wearable computer 7 is mounted on a person's arm, shoulder, torso, etc. via a transceiver 9 to transmit / receive data to / from each other, and is further provided on the wall or floor so that it can be touched by the tip of a limb. Communication is performed with a computer 8 provided outside via the transceivers 9a and 9b and cables.

  Here, the transceiver 9 used for data communication between the wearable computer 7 and between the wearable computer 7 and the computer 8 induces an electric field based on information to be transmitted to a living body that is an electric field transmission medium. Information is transmitted and received using an induced electric field. The transceiver 9 is described in Patent Document 1 and Patent Document 2.

JP 2001-352298 A JP 2006-081111 A

  Now, the electric field induced by the user carrying the wearable computer 7 and the transceiver 9 is coupled (electrostatically coupled) to a nearby third party who does not have the wearable computer 7 or 9, and the third party has the floor or the like. Touching the transceivers 9a and 9b provided in the computer 8 may cause the computer 8 to receive the data transmitted from the wearable computer 7 by mistake.

  In this case, the computer 8 may erroneously recognize that the data is from a user carrying the wearable computer 7 or 9 and perform a malfunction such as opening an automatic door for a third party.

  The present invention has been made to solve the above-described problem, and an object thereof is to prevent erroneous recognition and malfunction due to coupling in an electric field communication system that transmits and receives information via an electric field transmission medium.

  In order to achieve the above object, the present invention according to claim 1 is an electric field communication system, which is a portable terminal that transmits a predetermined communication signal by electric field communication, an interference signal generator that generates an interference signal, A first transceiver for transmitting a jamming signal by electric field communication; a first electrode connected to the first transceiver; a second transceiver for receiving the jamming signal and the communication signal by electric field communication; A second electrode installed in the vicinity of the first electrode and connected to the second transceiver, wherein the electric field of the disturbing signal is from a human body of a first user in contact with the first electrode , Transmitted to the human body of the second user in contact with the second electrode by secondary radiation, transmitted to the second electrode, and the electric field strength due to the secondary radiation of the interference signal is 1 of the communication signal. By secondary radiation The jamming signal that the first transceiver outputs to the first electrode so that the electric field strength due to the primary radiation of the jamming signal is smaller than the electric field strength and larger than the electric field strength due to the primary radiation of the communication signal. The gist of the voltage signal is larger than the voltage signal of the communication signal output from the portable terminal to the electrode of the portable terminal.

  The present invention described in claim 2 is the electric field communication system according to claim 1, wherein the transmission frequency band of the first transceiver is the same as the transmission frequency band of the portable terminal.

  A third aspect of the present invention is the electric field communication system according to the first or second aspect, wherein the area of the first electrode is larger than the area of the electrode of the portable terminal. .

  The present invention described in claim 4 is the electric field communication system according to any one of claims 1 to 3, further comprising a control device connected to the second transceiver, When a user carrying a mobile terminal comes into contact with the second electrode, the second transceiver transmits an ID signal, which is a communication signal transmitted by the mobile terminal, via the user's human body and the second electrode. The control apparatus receives the ID signal, authenticates the ID signal, and performs predetermined control according to the authentication result.

  According to the present invention, in an electric field communication system that transmits / receives information through an electric field transmission medium, an erroneous signal due to coupling is generated by generating an interference signal having an electric field strength larger than the electric field strength of the communication signal output from the mobile terminal. In addition, malfunction can be prevented.

1 is an overall configuration diagram of an electric field communication system according to an embodiment of the present invention. It is a block diagram which shows the structure of a portable terminal. It is a block diagram which shows the structure of a transceiver and a control apparatus. It is a figure which shows the state in which the qualified person who has a portable terminal is contacting each of the 1st electrode and the 2nd electrode. It is a figure which shows the state where the unqualified person contacts the 1st electrode and the qualified person who has a portable terminal is contacting the 2nd electrode. It is a figure which shows the example in the case of mounting | wearing and using a wearable computer for a person via a transceiver.

  Embodiments of the present invention will be described below. The electric field communication system according to this embodiment is carried by a user who is a qualified person in consideration of the effective communication electric field distance when primary radiation (direct radiation) is performed from a mobile terminal and when secondary radiation is performed from a human body. The electric field output from the portable terminal is coupled (electrostatic coupling) to an unqualified person who does not have a nearby portable terminal, and the signal of the portable terminal is transmitted to the control device via the unqualified person who does not have the portable terminal. This prevents the control device from erroneously recognizing and malfunctioning.

  FIG. 1 is an overall configuration diagram of an electric field communication system according to an embodiment of the present invention. The electric field communication system shown in the figure is connected to a portable terminal 1 carried by a qualified person A, a first electrode 2A, a first transceiver 3A connected to the first electrode 2A, and a first transceiver 3A. The interference signal generator 6, the second electrode 2 B, the second transceiver 3 B connected to the second electrode 2 B, the control device 4, and the processing device 5 are included.

  The first transceiver A and the interference signal generator 6, the second transceiver B and the controller 7, and the controller 4 and the processor 5 are connected by a network such as a LAN, for example. The portable terminal 1 is a terminal carried by a qualified person A who is a legitimate user, and is a communication terminal capable of electric field communication with the first and second transceivers 3A and 3B.

  The control device 4 receives a communication signal (in this embodiment, an ID signal) transmitted from the mobile terminal 1 via the second transceiver 3B, and performs predetermined control on the processing device 5. In the present embodiment, the processing device 5 is an automatic door, and the control device 4 will be described below as an example of opening and closing the automatic door in response to a signal from the mobile terminal 1. The processing device 5 is not limited to an automatic door, and may be a gate device such as a ticket gate.

  The first and second transceivers 3A and 3B induce an electric field based on information to be transmitted in a living body that is an electric field transmission medium, and perform transmission and reception of information using the induced electric field. The transmission / reception method of the electric field communication signal may be an electric method, an optical method, or other methods, and is not limited to any one.

  The first electrode 2A is installed in the vicinity of the second electrode 2B. The second electrode 2B is installed in the vicinity of the processing device 5 (in the illustrated example, the floor at a suitable position for the user to wait for the door to open in front of the automatic door 5).

  The jamming signal generator 6 transmits a jamming signal to a user who contacts the first electrode 2A via the first transceiver 3A. The interfering signal generator 6 shown in the figure includes a random number generating unit 61 that generates a pseudo-random number as an interfering signal, and a transmitting unit 62 that transmits the generated pseudo-random number to the transceiver 3B.

  FIG. 2 is a schematic configuration diagram of the mobile terminal 1 of the present embodiment.

  The illustrated mobile terminal 1 includes a computer 11 and a transceiver 12. The computer 11 includes an ID transmission unit 111 and a storage unit 112. It is assumed that the ID transmission unit 111 always transmits an ID signal including an ID stored in advance in the storage unit 112 using the transceiver 12 at a predetermined time interval. The ID stored in the storage unit 112 is identification information such as a user ID or a mobile terminal ID of a qualified person A who carries the mobile terminal 1. In the present embodiment, an ID signal is used as a communication signal transmitted by the mobile terminal 1, but the signal is not limited to the ID signal and may be a signal other than an ID.

  The transceiver 12 induces an electric field based on information to be transmitted in a living body that is an electric field transmission medium, and transmits and receives information using the induced electric field. The transceiver 12 has the configuration shown in FIG. 2, for example. When the transmission data from the computer 11 is received via the input / output (I / O) circuit 901, the transmission data is received via the transmission unit 902 and the electrode 903. And an electric field is induced in the electric field transmission medium through the electrode 903 and the insulating film 904, and this electric field is transmitted to other parts of the electric field transmission medium.

  The transceiver 12 detects an electric field induced and transmitted by the electric field transmission medium by the electrode 903 via the insulating film 904, and couples the electric field to the electric field detection unit 905 to convert it into an electric signal. This electric signal is subjected to signal processing such as amplification and noise removal by the signal processing circuit 906, further subjected to waveform shaping by the waveform shaping circuit 907, and output to the computer 11 via the input / output circuit 901. ing. In addition, the transmission / reception method of the electric field communication signal may be an electric method, an optical method, or other methods, and is not limited to any one.

  Although the illustrated mobile terminal 1 is a transceiver that can transmit and receive, the mobile terminal 1 of the present embodiment may not include the receiving unit 910 and the waveform shaping circuit 907 and may perform only a transmission operation.

  FIG. 3 is a schematic configuration diagram of the control device 4 and the second transceiver 3B.

  The second transceiver 3B has the same configuration as the transceiver 12 of the portable terminal 1, and induces an electric field based on information to be transmitted in a living body that is an electric field transmission medium, and transmits and receives information using the induced electric field. The transceiver to do.

  In the second transceiver 3B of the present embodiment, the second electrode 2B and the insulating film 904 are connected to the transceiver main bodies 901, 902, 905, 906, 907 by cables as shown in FIG. It shall be installed in any possible location (floor, wall, gate, door, etc.). The illustrated second transceiver 3B is a transceiver that can transmit and receive, but may not include the transmission unit 902 and perform only a reception operation.

  The control device 4 receives a communication signal transmitted from the mobile terminal 1 and controls the processing device 5. The illustrated control device 4 includes a control unit 41, an ID storage unit 42, and a log information storage unit 43.

  The control unit 41 receives a communication signal from the mobile terminal 1 and controls the processing device 5. In this embodiment, since the processing device 5 is an automatic door, the control unit 41 authenticates the ID of the received ID signal (communication signal), and controls the automatic door 5 according to the authentication result (unlocking, locking). Etc.). The ID storage unit 42 stores a plurality of IDs of authorized persons or portable terminals 1. The log information storage unit 43 stores electric field communication logs with a plurality of portable terminals 1, control logs such as unlocking / locking of the automatic door 5, and the like.

  The first transceiver 3A has the same configuration as that of the second transceiver 3B shown in FIG. 3, and induces an electric field based on information to be transmitted in a living body that is an electric field transmission medium, and uses the induced electric field for information. It is a transceiver that transmits and receives. In the first transceiver 3A of the present embodiment, as shown in FIG. 1, the first electrode 2A and the insulating film are connected to the transceiver body by a cable, and a predetermined location (floor near the second electrode 2B) Etc.). Note that the transceiver 3B may be a transceiver capable of transmitting and receiving illustrated in FIG. 3 or a transceiver that does not include the receiving unit 910 and the waveform shaping circuit 907 and performs only a transmission operation.

  Note that the computer 11, the control device 4, and the interference signal generation device 6 of the portable terminal 1 are general-purpose devices including at least a CPU, a memory, a storage device, a communication control device, and a bus that connects these devices. A typical computer system can be used. In this computer system, the functions of the computer 11, the control device 4, and the interference signal generator 6 are realized by the CPU executing a predetermined program loaded on the memory.

  Next, the operation of the electric field communication system of this embodiment will be described.

  In the first state shown in FIG. 1, an unqualified person B who does not have the portable terminal 1 stands in contact with the second electrode 2B installed in front of the automatic door 5 or the like. A qualified person A who carries the mobile terminal 1 is in contact with the first electrode 2A in the vicinity of the second electrode 2B.

  When the qualified person A contacts the first electrode 2A, the interfering signal generator 6 and the qualified person A as the electric field transmission medium pass through the first transceiver 3A and the first electrode 2A. A communication path is formed. Thereby, the electric field of the interference signal (pseudorandom number) generated by the interference signal generator 6 is induced (transmitted) to the qualified person A by primary radiation (S11). The interference signal generator 6 always transmits an interference signal, and the first transceiver 3A radiates the electric field of the interference signal from the first electrode 2A.

  The electric field of the disturbing signal induced by this qualified person A is radiated to the atmosphere, and in the situation shown in FIG. 1, it is coupled (electrostatic coupling) to the nearby unqualified person B by secondary radiation (S12). Then, the electric field of the disturbing signal coupled to the unqualified person B is transmitted to the second electrode 2B via the human body of the unqualified person B, which is an electric field transmission medium (S13). That is, a communication path between the interfering signal generator 6 and the second transceiver 3B via the first transceiver 3A, the first electrode 2A, the qualified person A, the unqualified person B, and the second electrode 2B. Is formed.

  On the other hand, from the portable terminal 1 carried by the qualified person A, the electric field of the ID signal transmitted from the computer 11 of the portable terminal 1 is induced in the human body of the qualified person A by primary radiation (S21). The electric field of the ID signal induced by this qualified person A is radiated to the atmosphere, and in the situation shown in FIG. 1, it is coupled (electrostatically coupled) to the nearby unqualified person B by secondary radiation (S22). The electric field of the ID signal coupled to the unqualified person B is transmitted to the first electrode through the human body of the unqualified person B, which is an electric field transmission medium (S23). That is, a communication path is formed between the portable terminal 1 and the second transceiver 3B through the qualified person A, the unqualified person B, and the second electrode 2B.

  Here, the transmission frequency (transmission frequency band) used for transmission by the first transceiver 3A connected to the interference signal generator 6 and the transmission frequency (transmission frequency band) used for transmission by the transceiver 12 of the portable terminal 1 are the same. Things shall be used. Here, both use the frequency (for example, several 10 MHz or less) which can consider the user's human body which is an electric field transmission medium as a conductor.

  When signals are transmitted and received by electric field communication, they are generally easily affected by surrounding electromagnetic noise. In order to make it less susceptible to electromagnetic noise, the reception frequency band is narrowed in the second transceiver 3B. The transceiver 12 of the portable terminal 1 transmits the ID signal to the second transceiver 3B more reliably by using a transmission frequency that matches the reception frequency band of the second transceiver 3B.

  In the present embodiment, by using the same transmission frequency as the transceiver 12 of the mobile terminal 1 as the transmission frequency of the first transceiver 3A, the electric field of the interference signal output from the interference signal generator 6 is It is superimposed on the electric field of the output ID signal. Then, the interference signal is caused to function as a signal that prevents the ID signal transmitted from the portable terminal 1 of the qualified person A who is in contact with the first electrode 2A from being detected by the second transceiver 3B.

  In the present embodiment, the electric field strength of the interference signal transmitted from the first transceiver 3A is made larger than the electric field strength of the ID signal transmitted from the transceiver 12 of the mobile terminal 1. That is, as described above, the electric field of the interference signal and the electric field of the ID signal are superimposed, but since the electric field strength of the interference signal is larger than the electric field strength of the ID signal, when the superimposed electric field is demodulated by the first transceiver 3A, Ensure that the signal is buried in the jamming signal and removed as noise.

  Note that increasing or decreasing the electric field strength output from the transceiver depends on, for example, the size of the electrode area and the size of the modulated voltage signal output from the transceiver (transmitting unit 902) to the electrode.

  Therefore, in this embodiment, the area (size) of the first electrode 2A connected to the first transceiver 3A is made larger than the area of the electrode 903 (see FIG. 2) of the mobile terminal 1. Alternatively, the transmission unit 902 of the first transceiver 3A outputs a voltage signal obtained by modulating the interference signal to the first electrode 2A, and the output level of the voltage signal is set to the transmission unit of the mobile terminal 1 (transceiver 12). The voltage signal of the ID signal modulated by 902 is adjusted and controlled to be larger than the output level to be output to the electrode 903. Alternatively, both the electrode area and the output level of the voltage signal are adjusted. Thus, the electric field strength of the interference signal transmitted from the first transceiver 3A and the first electrode 2A is made larger than the electric field strength of the ID signal transmitted from the mobile terminal 1.

  The electric field in which the electric field of the interference signal and the electric field of the ID signal are thus superimposed is transmitted to the second electrode 2B via the human body of the unqualified person B. The second transceiver 3B detects the superimposed electric field with the second electrode 2B, and couples the electric field to the electric field detector 905 to convert it into an electric signal. This electric signal is subjected to signal processing such as amplification and noise removal by the signal processing circuit 906, further subjected to waveform shaping by the waveform shaping circuit 907, and output to the control device 4 via the input / output circuit 901.

  The electric field detected here is an electric field in which the electric field of the disturbing signal and the electric field of the ID signal are superimposed as described above, and the electric field strength of the interfering signal is larger than the electric field strength of the ID signal. For example, when the difference in electric field strength is several tens of times or more, the signal processing circuit 906 considers a portion corresponding to an ID signal having a small electric field strength in the converted electric signal as noise, and performs ID processing by noise removal signal processing. The part corresponding to the signal is removed. As a result, the waveform shaping circuit 907 performs waveform shaping on the portion corresponding to the interference signal, and is output to the control device 4. Even if the difference in electric field strength is not so large, the portion corresponding to the ID signal is superimposed on the portion corresponding to the interference signal, and the ID signal is not demodulated and output to the control device 4.

  The control unit 41 of the control device 4 determines whether or not the disturbance signal output from the second transceiver 3B is a valid ID stored in the ID storage unit 42. Since the disturbing signal is a pseudorandom number, it does not exist in the ID storage unit 42. Even when the signal output from the second transceiver 3B is a meaningless signal demodulated by superimposing the interference signal and the ID signal, the signal does not exist in the ID storage unit 42.

  Since the signal output from the second transceiver 3B is not stored in the ID storage unit 42, the control unit 41 determines that the signal is an unauthorized signal and outputs an unlocking signal (control signal) for unlocking the automatic door 5. The process ends without transmitting to the automatic door 5. Therefore, in the situation shown in FIG. 1, the automatic door 5 remains locked and does not open, and the control unit 41 does not write log information to the log information storage unit 43.

  Accordingly, even if an unqualified person B who does not carry the mobile terminal 1 stands on the second electrode 2B in front of the automatic door 5, the automatic door 5 does not open, and the security area inside the automatic door 5 Cannot enter the room.

  In the present embodiment, as shown in FIG. 1, when the unqualified person B stands on the second electrode 2B and the qualified person A carrying the mobile terminal 1 is in the vicinity of the unqualified person B, The electric field of the ID signal output from the portable terminal 1 of the person A is transmitted to the nearby unqualified person B by secondary radiation, but the electric field of the ID signal is a disturbance signal transmitted by the disturbance signal generator 6. It is transmitted superimposed on the electric field.

  As a result, even if an unqualified person 2B who does not have the portable terminal 1 contacts the second electrode 2B, the ID signal transmitted from the portable terminal 1 of the qualified person A is detected by the second transceiver 3B. Is not transmitted to the control device 4. For this reason, it is possible to prevent a malfunction that the control device 4 erroneously recognizes that the qualified person A has contacted the second electrode 2B and opens the automatic door 5 by mistake.

  That is, it is possible to prevent erroneous recognition and malfunction such as a qualified person A carrying the portable terminal 1 unintentionally entering the unlicensed person B (third party) who does not have the portable terminal 1 together. can do.

  In addition, when the qualified person A is in contact with the first electrode 2A and neither the qualified person nor the unqualified person is in contact with the second electrode 2B, the interference signal and the ID signal Even if the superimposed electric field is emitted from the qualified person A to the atmosphere and coupled to the first electrode 2A by secondary radiation (electrostatic coupling), the same result as in FIG. 1 is obtained.

  Next, the operation in the second state shown in FIG. 4 will be described.

  In the second state of FIG. 4, the first qualified person A who carries the first portable terminal 1A is in contact with the first electrode 2A. The second qualified person C carrying the second portable terminal 1C is in contact with the second electrode 2B installed in front of the automatic door 5 or the like. Since the first mobile terminal 1A and the second mobile terminal 1C are the same as the mobile terminal 1 described in FIGS. 1 and 2, the description thereof is omitted here.

  Since the first qualified person A is in contact with the first electrode 2A, the first transceiver 3A and the first qualified person A, which is the electric field transmission medium, between the disturbing signal generator 6 and the first qualified person A can be obtained. A communication path through the first electrode 2A is formed, and an electric field of a disturbing signal (pseudorandom number) generated by the disturbing signal generator 6 is induced (transmitted) to the first qualified person A (S31).

  Further, from the first portable terminal 1A carried by the first qualified person A, the electric field of the ID signal (first qualified person A) transmitted from the computer 11 of the portable terminal 1A is the first. It is induced in the human body of qualified person A (S41).

  As described in FIG. 1, the electric field of the interference signal and the electric field of the ID signal induced by the first qualified person A are superimposed by using the same transmission frequency band, and the superimposed electric field is radiated to the atmosphere. In the situation shown in FIG. 4, coupling (electrostatic coupling) is performed to the nearby second qualified person C by secondary radiation (S <b> 32 and S <b> 42). Then, the second qualified person C is secondarily radiated and the superimposed electric field is transmitted to the second electrode 2B through the human body of the second qualified person C that is an electric field transmission medium (S33, S43).

  On the other hand, the electric field of the ID signal (second qualified person C) transmitted from the computer 11 of the second portable terminal 1C is 1 from the second portable terminal 1C carried by the second qualified person C. It is induced in the human body of the second qualified person C by the next radiation, and is transmitted to the second electrode 2B through the human body of the second qualified person C that is an electric field transmission medium (S51).

  Here, the transmission frequency of the first transceiver 3A uses the same transmission frequency as the transceiver 12 of the first portable terminal 1A and the transceiver 12 of the second portable terminal 1C, as described in FIG. As a result, an electric field in which the electric field of the interference signal induced by the second qualified person C by the secondary radiation and the electric field of the ID signal (first qualified person A) are superimposed, and the second radiation by the primary radiation. The electric field of the ID signal (second qualified person C) output from the portable terminal 1C is superimposed and transmitted to the second electrode 2B.

  Further, as described in FIG. 1, the electric field strength of the interference signal transmitted from the first transceiver 3A is equal to the electric field of the ID signal transmitted from the transceiver 12 of the first mobile terminal 1A and the second mobile terminal 1C. Greater than strength. Further, the electric field strength of the ID signal (first qualified person A) transmitted from the transceiver 12 of the first mobile terminal 1A and the ID signal (second output) transmitted from the transceiver 12 of the second mobile terminal 1C The field strength of the qualified person C) is the same.

  In the state shown in FIG. 4, the interference signal and the ID signal of the first portable terminal 1A are transmitted to the second qualified person C by secondary radiation. The electric field strength decreases in inverse proportion to the square of the distance between the first qualified person A and the second qualified person C. For this reason, the interference signal induced by the secondary radiation to the second qualified person C and the electric field strength (S32, S42) of the ID signal are the interference signals induced by the first qualified person A by the primary radiation. And from the electric field strength (S31, S41) of the ID signal, it becomes much smaller.

  On the other hand, the electric field of the ID signal (second qualified person C) transmitted from the second portable terminal 1C is induced in the second qualified person C by primary radiation. Thereby, the electric field intensity of the three signals transmitted by being superimposed on the second electrode 2B through the human body of the second qualified person C is the ID signal (second qualified person C) by primary radiation. It becomes the magnitude | size of the order of the interference signal by secondary radiation, and the ID signal (1st qualified person A) by secondary radiation.

  The second transceiver 3B detects the electric field on which the interference signal and the electric field of the two ID signals are superimposed by the second electrode 2B, and couples the electric field to the electric field detection unit 905 to convert it into an electric signal. This electric signal is subjected to signal processing such as amplification and noise removal by the signal processing circuit 906, further subjected to waveform shaping by the waveform shaping circuit 907, and output to the control device 4 via the input / output circuit 901.

  As described above, the electric field detected here is an electric field obtained by superimposing the electric field of the interference signal and the electric field of the two ID signals, and the electric field strength of the ID signal (second qualified person C) caused by the primary radiation. Is much larger than the electric field strength of the interference signal due to secondary radiation and the ID signal (first qualified person A). Therefore, the signal processing circuit 906 considers and removes the portion corresponding to the interference signal and the ID signal (first qualified person A) having a small electric field strength from the converted electric signal as noise.

  As a result, the portion corresponding to the ID signal (second qualified person C) transmitted from the second portable terminal 1C of the second qualified person C in contact with the second electrode 2B is the waveform shaping circuit 907. The waveform is shaped and output to the control device 4.

  The control unit 41 of the control device 4 determines whether or not the ID signal (second qualified person C) output from the second transceiver 3B is a valid ID stored in the ID storage unit 42. When the ID signal is stored in the ID storage unit 42, the control unit 41 transmits an unlocking signal (control signal) to the automatic door 5 and opens the automatic door 5. As a result, the second qualified person C carrying the second portable terminal 1 </ b> C can enter the automatic door 5.

  Then, the control unit 41 stores log information such as a communication log (ID signal reception time, ID, etc.) with the second portable terminal 1C, a control log (unlock signal transmission time, etc.) in the log information storage unit 43. Store. And the control part 41 will transmit the locking signal (control signal) which locks the automatic door 5, if predetermined time passes after transmitting an unlocking signal, The automatic door 5 will receive the said locking signal, The automatic door 5 is locked from the unlocked state, and the door is closed.

  In the present embodiment, as shown in FIG. 4, even if a qualified person carrying a mobile terminal is in contact with each of the first electrode 2A and the second electrode 2B, secondary radiation ( Since the electric field strength of the interference signal and the ID signal transmitted by the coupling is smaller than the electric field strength of the ID signal due to primary radiation, it is transmitted from a portable terminal of a qualified person in contact with the second electrode 2B. Only the ID signal can be received by the second transceiver 3B. For this reason, erroneous recognition and malfunction of the control device 4 can be prevented.

  In addition, in order to take out the ID signal due to the primary radiation from the superimposed signal transmitted to the second electrode 2B, the electric field strength of the interference signal of the secondary radiation is made higher than the electric field strength of the ID signal of the primary radiation. It needs to be small. The electric field strength of the signal due to secondary radiation also depends on the distance between human bodies. That is, it also depends on the distance between the first electrode 2A and the second electrode 2B. For this reason, the upper limit of the electric field strength of the disturbing signal may be determined according to the distance between the first electrode 2A and the second electrode 2B.

  Next, the operation in the third state shown in FIG. 5 will be described.

  In the third state of FIG. 5, the unqualified person B who does not carry the portable terminal contacts the first electrode 2A, and the portable terminal 1 is placed on the second electrode 2B installed in front of the automatic door 5 or the like. A qualified person A in possession is in contact. The illustrated mobile terminal 1 is the same as the mobile terminal 1 described with reference to FIG. 1 and FIG.

  Since the unqualified person B is in contact with the first electrode 2A, the first transceiver 3A and the first transceiver 3A and the first qualified person A, which is the electric field transmission medium, between the disturbing signal generation device 6 and the first qualified person A are used. A communication path through the electrode 2A is formed, and the electric field of the interference signal (pseudo-random number) generated by the interference signal generator 6 is induced (transmitted) to the unqualified person B (S71).

  The electric field of the disturbing signal induced by the unqualified person B is radiated to the atmosphere, and in the situation shown in FIG. 4, it is coupled (electrostatically coupled) to the nearby qualified person A by secondary radiation (S72). Then, the electric field of the interference signal coupled to the qualified person A is transmitted to the second electrode 2B via the human body of the qualified person A that is an electric field transmission medium (S73).

  On the other hand, from the portable terminal 1 carried by the qualified person A, the electric field of the ID signal transmitted from the computer 11 of the portable terminal 1 is induced in the human body of the second qualified person A by primary radiation, and electric field transmission It is transmitted to the second electrode 2B through the human body of the qualified person A as a medium (S81).

  Here, the transmission frequency of the first transceiver 3A uses the same transmission frequency as that of the transceiver 12 of the mobile terminal 1, as described with reference to FIG. As a result, the electric field of the interference signal induced by the qualified person A by the secondary radiation and the electric field of the ID signal output from the portable terminal 1 by the primary radiation are transmitted to the second electrode 2B in a superimposed manner. The

  Further, as described with reference to FIG. 1, the electric field strength of the interference signal transmitted from the first transceiver 3 </ b> A is larger than the electric field strength of the ID signal transmitted from the transceiver 12 of the mobile terminal 1. However, in the state shown in FIG. 5, the interference signal is transmitted to the qualified person A by secondary radiation, and the electric field strength of the interference signal is inversely proportional to the square of the distance between the unqualified person B and the qualified person A. Get smaller. For this reason, the electric field strength (S73) of the disturbing signal induced by the secondary radiation in the qualified person A is much smaller than the electric field strength (S71) of the disturbing signal induced by the primary radiation in the unqualified person B. Become.

  On the other hand, the electric field of the ID signal transmitted from the portable terminal 1 is induced by the qualified person A by primary radiation. Thereby, the electric field intensity of the signal transmitted superimposed on the second electrode 2B through the human body of the qualified person A is larger in the ID signal due to the primary radiation than the interference signal due to the secondary radiation.

  Thus, the electric field in which the electric field of the interference signal and the electric field of the ID signal are superimposed is transmitted to the second electrode 2B. The second transceiver 3B detects the superimposed electric field with the second electrode 2B, and couples the electric field to the electric field detector 905 to convert it into an electric signal. This electric signal is subjected to signal processing such as amplification and noise removal by the signal processing circuit 906, further subjected to waveform shaping by the waveform shaping circuit 907, and output to the control device 4 via the input / output circuit 901.

  As described above, the electric field detected here is an electric field obtained by superimposing the electric field of the interference signal and the electric field of the ID signal, and the electric field strength of the ID signal due to the primary radiation is the electric field strength of the interference signal due to the secondary radiation. Is much larger than that. For this reason, the signal processing circuit 906 regards a portion corresponding to an interference signal having a small electric field strength in the converted electric signal as noise and removes it.

  As a result, the waveform shaping circuit 907 performs waveform shaping on the portion corresponding to the ID signal transmitted from the portable terminal 1 of the qualified person A in contact with the second electrode 2 </ b> B and is output to the control device 4.

  When the control unit 41 of the control device 4 determines whether or not the ID signal output from the second transceiver 3B is a valid ID stored in the ID storage unit 42, and stored in the ID storage unit 42, An unlock signal is transmitted to the automatic door 5 to open the automatic door 5. Thereby, the qualified person A can enter the interior of the automatic door 5. And the control part 41 memorize | stores log information in the log information storage part 43, and transmits the locking signal which locks the automatic door 5, if predetermined time passes after transmitting an unlocking signal.

  In the present embodiment, as shown in FIG. 5, an unqualified person B who does not have a portable terminal contacts the first electrode 2A, and the electric field of the disturbing signal is transmitted to the qualified person A by secondary radiation (coupling). Even in such a case, since the electric field strength of the interference signal of the secondary radiation is smaller than the electric field strength of the ID signal due to the primary radiation, it is in contact with the second electrode 2B without being affected by the interference signal. The second transceiver 3B can receive only the ID signal transmitted from the portable terminal 1 of the qualified person. For this reason, erroneous recognition and malfunction of the control device 4 can be prevented.

  In addition, when the qualified person A who carries the portable terminal 1 is in contact with the second electrode 2B, and neither the qualified person nor the unqualified person is in contact with the first electrode 2A, The electric field of the interfering signal transmitted from the interfering signal generating device 6 via the first transceiver 3A is radiated from the first electrode 2A to the atmosphere. Even if the electric field of the disturbing signal is coupled (electrostatic coupling) to the qualified person A on the second electrode 2B by secondary radiation, the same result as in the case of FIG. 5 is obtained.

  In the present embodiment described above, an electric field of an interference signal that is greater than the electric field strength of the ID signal transmitted by the mobile terminal 1 is induced on the first electrode 2A by the interference signal generator 6 and the first transceiver 3A. Thereby, a qualified person carrying the portable terminal 1 comes into contact with the first electrode 2A, and an electric field in which the electric field of the ID signal transmitted from the portable terminal 1 and the electric field of the interference signal are superimposed is generated from the body of the qualified person Even when it is emitted to the atmosphere and secondarily radiated by an unqualified person in contact with the adjacent second electrode 2B, the electric field strength of the disturbing signal is larger, so the ID signal is transmitted by the second transceiver 3B. Cannot receive.

  That is, in the present embodiment, an ID that is secondarily radiated from the portable terminal 1 of a qualified person in contact with the first electrode 2 </ b> A to an unqualified person in contact with the second electrode 2 </ b> B in front of the automatic door 5. Even if the electric field of the signal is transmitted, the ID signal cannot be detected by the second transceiver 3B because the electric field of the ID signal is superimposed on the electric field of the interference signal. For this reason, it is possible to prevent a malfunction that the control device 4 erroneously recognizes that a qualified person has contacted the second electrode 2B and opens the automatic door 5 by mistake.

  Therefore, it is possible to prevent erroneous recognition and malfunction such that a qualified person carrying the portable terminal 1 unintentionally (a third party) who does not have the portable terminal 1 unintentionally enter. Can do.

  In the present embodiment, the area of the first electrode 2A connected to the first transceiver 3A is made larger than the area of the electrode of the mobile terminal 1. Alternatively, the first transceiver 3A outputs the output level of the modulated voltage signal of the interference signal to the first electrode 2A, and outputs the voltage signal of the ID signal modulated by the portable terminal 1 (transceiver 12) to the electrode. Adjust and control larger than the level. Alternatively, both the electrode area and the voltage signal are adjusted. Thereby, the electric field strength of the interference signal transmitted from the first transceiver 3A and the first electrode 2A can be made larger than the electric field strength of the ID signal transmitted from the mobile terminal 1.

  Further, the control device 4 of the present embodiment stores log information in the log information storage unit 43 after transmitting an unlocking signal (control signal) to the automatic door 5. Thereby, entrance / exit of the qualified person who opened the automatic door 5 can be managed centrally.

  In the present embodiment, the qualified person carries the portable terminal 1 capable of electric field communication, and the ID signal is transmitted simply by standing on the second electrode 2B in front of the automatic door 5 or the like. An operation load such as an input operation can be reduced.

  In this embodiment, in the situation where an unqualified person stands on the second electrode 2B near the automatic door 5 or the like, the qualified person carrying the portable terminal passes by the unqualified person. However, there is an advantage that the automatic door 5 is not accidentally opened for an unqualified person due to erroneous authentication. Therefore, higher security can be ensured by applying the electric field communication system of the above-described embodiment to a place where traffic is crowded including traffic gates, gates, and the like.

  In addition, this invention is not limited to the said embodiment, Many deformation | transformation are possible within the range of the summary. For example, in the embodiment, the first electrode 2A and the second electrode 2B installed on the floor are used. However, the first electrode 2A and the second electrode 2B may be installed in a place other than the floor as long as the user can touch them.

A, C Qualified person B Unqualified person 1, 1A, 1C Mobile terminal 11 Computer 12 Transceiver 2A 1st electrode 2B 2nd electrode 3A 1st transceiver 3B 2nd transceiver 4 Controller 41 Controller 42 ID storage Unit 43 Log information storage unit
5 Automatic door 6 Interference signal generator 61 Random number generator 62 Transmitter

Claims (4)

An electric field communication system,
A portable terminal that transmits a predetermined communication signal by electric field communication;
An interference signal generating device for generating an interference signal;
A first transceiver for transmitting the jamming signal by electric field communication;
A first electrode connected to the first transceiver;
A second transceiver for receiving the jamming signal and the communication signal by electric field communication;
A second electrode installed in the vicinity of the first electrode and connected to the second transceiver;
The electric field of the disturbing signal is transmitted by secondary radiation from the human body of the first user that contacts the first electrode to the human body of the second user that contacts the second electrode, and the second electrode Communicate to
The electric field strength due to the secondary radiation of the interference signal is smaller than the electric field strength due to the primary radiation of the communication signal, and the electric field strength due to the primary radiation of the interference signal is larger than the electric field strength due to the primary radiation of the communication signal. So that
The electric field communication system, wherein a voltage signal of the interference signal output from the first transceiver to the first electrode is larger than a voltage signal of a communication signal output from the mobile terminal to the electrode of the mobile terminal. The electric field communication system according to claim 1,
The electric field communication system, wherein a transmission frequency band of the first transceiver is the same as a transmission frequency band of the portable terminal. The electric field communication system according to claim 1 or 2,
The area of the first electrode is larger than the area of the electrode of the mobile terminal. The electric field communication system according to any one of claims 1 to 3,
A controller connected to the second transceiver;
When a user carrying the mobile terminal touches the second electrode,
The second transceiver receives an ID signal, which is a communication signal transmitted by the mobile terminal, via the human body of the user and the second electrode, and outputs the received signal to the control device.
When the control device receives the ID signal, the control device authenticates the ID signal and performs predetermined control according to the authentication result.

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