KR20190118443A - Human body communication system including security filter device - Google Patents

Abstract

The present invention relates to a human body communication system including a security filter device. According to an embodiment of the present invention, the human body communication system includes a transmitting device, a security filter device, and a receiving device. The transmitting device outputs a transmission signal to a living body. The security filter device includes a distortion filter that transforms the transmission signal received through the living body into a distortion signal. The receiving device converts a signal received from the security filter device into data information corresponding to the transmission signal. According to the present invention, the convenience, security, and reliability of human body communication can be secured.

Description

HUMAN BODY COMMUNICATION SYSTEM INCLUDING SECURITY FILTER DEVICE}

The present invention relates to a communication system using a human body as a medium, and more particularly to a human communication system including a security filter device.

BACKGROUND ART A human body communication system and a human body communication method for transmitting signals or information from a transmitting apparatus to a receiving apparatus using a human body as a medium have emerged. The human body communication system has an advantage in that a signal exchange between a user and the system is possible without requiring a separate wired signal transmission medium. In addition, since the human body communication system uses the human body as a medium, it has an advantage that it can have a binding force to the radiation of the signal as compared to the wireless communication system. The human body communication system may be applied in various fields such as medical, security, retail, and smart management. The conventional research on human body communication has focused on a contact-based human body communication system that transmits a signal through a human body in contact with a transceiver.

A contact-based human body communication system may cause inconvenience that a user and a transmitting device or a receiving device must maintain a contact state. In order to secure the convenience of the human body communication system, there is a demand for a non-contact based human body communication system in which a certain distance (for example, a distance of several cm) is spaced between the user and the human body communication system. Since the non-contact based human body communication system may be spaced apart from the user with clothing or shoes interposed therebetween, convenience of system utilization may be secured. However, in order to transmit a signal to a human body in a non-contact based human body communication system, the strength of a transmission signal may be increased.

As the strength of a transmission signal increases in a non-contact based human body communication system, an unintended transmission signal may arrive at another neighbor. In this case, security and reliability of the human body communication system may be weak. Accordingly, there is a need for a method for securing convenience and security and reliability of a human body communication system.

The present invention can provide a human body communication system including a security filter device in order to ensure the convenience, security, and reliability of human body communication.

A human body communication system according to an embodiment of the present invention includes a transmitting device, a security filter device, and a receiving device. The transmission device may output the transmission signal to the living body. The security filter device may modify a part of a transmission signal transmitted through a living body among transmission signals output to the outside. The receiving device may restore data information corresponding to the transmission signal based on the modified transmission signal.

For example, the security filter device may include a first electrode that receives a transmission signal from a living body, a distortion filter that transforms a transmission signal received through the living body into a distortion signal, and a second electrode that outputs the distortion signal. The security filter device is separate from the transmitting device and the receiving device. The security filter device is configured to be in contact with the living body, but may be arranged such that the distance between the receiving device and the security filter device is closer than the distance between the transmitting device and the security filter device.

For example, the receiving apparatus may include a receiving electrode for receiving the distortion signal, a correction filter for transforming the received distortion signal into a correction signal, and a receiving circuit for converting the correction signal into data information. The product of the distortion function's transfer function and the correction filter's transfer function may maintain a reference value. Alternatively, the receiving apparatus may include a receiving electrode for receiving the distortion signal, and a receiving circuit for converting the received distortion signal into a digital signal, converting the converted digital signal into a correction signal, and converting the correction signal into data information. have.

In one example, the security filter device may further include a correction filter for transforming the distortion signal into a correction signal. In this case, the security filter device may further include a third electrode for transmitting the distortion signal received from the living body to the correction filter, and a fourth electrode for outputting the correction signal received from the correction filter to the receiving device. The receiving device may restore the data information based on the correction signal.

The human body communication system including the security filter device according to the embodiment of the present invention may be implemented in a non-contact manner, thereby ensuring convenience of human body communication. In addition, the human body communication system according to the embodiment of the present invention can prevent the degradation of the security and reliability of signal transmission caused by the non-contact method by using a security filter device for modifying the transmission signal.

1 is a block diagram of a human body communication system according to an embodiment of the present invention.
FIG. 2 is a block diagram specifically illustrating an embodiment of the human body communication system of FIG. 1.
FIG. 3 is a graph illustrating a relationship between the distortion filter and the correction filter of FIG. 2.
4 is a block diagram illustrating an embodiment of a receiving apparatus that may be replaced in the human body communication system of FIG. 2.
5 and 6 are diagrams illustrating an actual application example of the human body communication system of FIG. 2.
7 and 8 are block diagrams illustrating in detail an embodiment of the human body communication system of FIG. 1.

In the following, embodiments of the present invention are described clearly and in detail so that those skilled in the art can easily practice the present invention.

1 is a block diagram of a human body communication system according to an embodiment of the present invention. Referring to FIG. 1, the human body communication system 100 includes a transmitting device 110, a security filter device 120, and a receiving device 130. The human body communication system 100 transmits a signal or information using a human body as a medium. However, the transmission medium of the signal or information is not limited to the human body, and may be various living bodies such as animals and plants. In addition, the signal transmitted from the human body communication system 100 may be via a conductive material or the like based on the presence of the security filter device 120 as well as the human body. That is, it will be understood that the human body communication system 100 described below uses the human body (living body) as at least some signal transmission path.

The transmission device 110 generates a transmission signal and transmits the generated transmission signal to the reception device 130 through the security filter device 120. The transmission device 110 may output a transmission signal to a human body. The transmitting device 110 may be spaced apart from the human body at small intervals to radiate the transmission signal to the outside. Here, the small interval means a reference distance at which the transmission signal can reach the human body at an intensity identifiable by the receiving device 130. For example, the small gap may be a distance between the transmitting device and the human body in the pants pocket or the thickness of the shoe sole. This small interval may be determined according to the application method of the human body communication system 100 or the strength of the transmission signal. As described above, the transmitting device 110 may output the transmission signal in a non-contact manner, but is not limited thereto. For example, the transmission device 110 may be in contact with the human body, and may output the transmission signal in a contact manner.

When the transmission device 110 outputs a transmission signal to the outside in a non-contact manner, it is required to output a transmission signal having a stronger strength than the contact method. Some of the transmission signal will be transmitted to the human body, but the transmission signal that is not output to the human body may be radiated into the air around the human body. In this case, the transmission signal may be transmitted to another electronic device adjacent to the human body. In addition, when the transmitting device 110 transmits a transmission signal to the receiving device 130 through the user, if there is a person in contact with the user, the transmission signal may be transmitted through the other person. That is, the transmission signal can be transmitted to another person or another electronic device, security and reliability can be reduced. Human body communication system according to an embodiment of the present invention can secure the security and reliability by using the security filter device 120.

The security filter device 120 may transform the transmission signal into a signal that can be processed by the reception device 130. The security filter device 120 may modify the transmission signal transmitted from the transmission device 110 through the human body. To this end, the security filter device 120 may be configured to be in contact with the human body. For example, the security filter device 120 may be a device detachable to a human body, such as a ring, a necklace, a bracelet, a thimble, or a sticker. The security filter device 120 may be disposed in a signal transmission path between the transmitting device 110 and the receiving device 130. The security filter device 120 may be a separate device separate from the transmitting device 110 and the receiving device 130.

By the security filter device 120, the transmission signal radiated around the user or transmitted through another person may be different from the signal transmitted through the user. For example, a signal input to the receiving device 130 may be different from a signal provided to another person or another electronic device (receiving device). Therefore, hacking by others can be prevented and security can be ensured. Also, by the security filter device 120, a signal transmitted through a user and a signal transmitted through another person may be distinguished. Therefore, the reception device 130 may not identify the transmission signal transmitted through the other person. That is, the human body communication system 100 using the security filter device 120 may be used as an authentication system or a personal identification system. Specific embodiments of the security filter device 120 will be described later.

The receiving device 130 receives the signal modified by the security filter device 120. The reception device 130 may restore data information corresponding to the transmission signal based on the signal received from the security filter device 120. For example, the data information corresponding to the transmission signal may be a digital signal generated by the transmission device 110 to output a transmission signal which is an analog signal. Alternatively, the data information may be an analog signal having the same waveform as the transmission signal. The reception device 130 may receive a signal modified in a contact manner or a noncontact manner through a human body. Alternatively, the reception device 130 may directly contact the security filter device 120 to receive the modified signal. In this case, the security filter device 120 and the reception device 130 may perform signal transmission through a conductive material such as an electrode.

FIG. 2 is a block diagram specifically illustrating an embodiment of the human body communication system of FIG. 1. Referring to FIG. 2, the human body communication system 200 includes a transmitting device 210, a security filter device 220, and a receiving device 230. Each of the transmission device 210, the security filter device 220, and the reception device 230 corresponds to the transmission device 110, the security filter device 120, and the reception device 130 of FIG. 1.

The transmission device 210 may include a transmission circuit 211 and a transmission electrode 214. The transmit circuit 211 may include a transmit signal generator 212 and a transmit controller 213. The transmission signal generator 212 may generate the transmission signal TS under the control of the transmission controller 213. The transmission device 210 may further include a power generator (not shown), and the transmission signal generator 212 may generate the transmission signal TS based on a voltage provided from the power generator (not shown). In exemplary embodiments, the transmission signal generator 212 may generate a transmission signal TS based on transmission information stored in a memory (not shown), or may transmit a signal based on an external biosignal or a signal received from an external electronic device. (TS) can be generated. The transmission signal TS may be an analog signal or a digital signal.

The transmission controller 213 may control the transmission signal generator 212 to generate the transmission signal TS. For example, under the control of the transmission controller 213, the transmission signal generator 212 receives transmission information stored in a memory (not shown), modulates and amplifies the received transmission information to generate a transmission signal TS. Can be. Such transmission information may include data and clock signals for generating the transmission signal TS. In addition, the transmission controller 213 may control an output time point of the transmission signal TS.

The transmission electrode 214 receives the transmission signal TS from the transmission circuit 211, and the received transmission signal TS may be output to the outside through the transmission electrode 214. The transmission electrode 214 is electrically connected to the transmission circuit 211 and may be formed on an outer surface of the transmission device 210. As described above, the transmission electrode 214 may be in contact with the human body or spaced apart from the human body at a small distance. According to the transmission signal TS, an electric field is formed between the human body and the transmission electrode 214, and a part of the transmission signal TS may be transmitted to the human body based on the formed electric field.

Although the transmission electrode 214 outputs the transmission signal TS to the human body, it is not limited thereto. For example, the transmission electrode 214 may be in contact with the security filter device 220 or may be spaced apart from the security filter device 220 by a small distance. In this case, the transmission signal TS may be modified by the security filter device 220 before being transmitted to the human body, and the modified signal may be output to the human body. In this case, the signal radiated in the air and not the human body may be different from each other. Since the signal radiated in the air and the signal transmitted to the human body are distinguished, security of the transmission signal can be secured.

The security filter device 220 may transform the transmission signal TS into a distortion signal and output the distortion signal to the reception device 230. Here, the distortion signal may be a reception signal RS. The security filter device 220 may be a device detachable to a human body, such as a ring, a necklace, a bracelet, a thimble, or a sticker. The security filter device 220 includes a first electrode 221, a distortion filter 222, and a second electrode 223.

The first electrode 221 may receive the transmission signal TS from the transmission device 210, and the received transmission signal TS may be transmitted to the distortion filter 222 through the first electrode 221. The first electrode 221 may be electrically connected to the distortion filter 222 and may be formed on an outer surface of the security filter device 220. The first electrode 221 may be in contact with the human body such that the transmission signal TS is input to the first electrode 221 through the human body. However, the present invention is not limited thereto, and the transmission signal TS may be input to the first electrode 221 without passing through the human body. To this end, the first electrode 221 may be in contact with the transmission electrode 214 or may be spaced apart from the transmission electrode 214 by a small distance.

The distortion filter 222 receives the transmission signal TS from the first electrode 221, and the received transmission signal TS may be transformed into a distortion signal by the distortion filter 222. The distortion filter 222 outputs the modified distortion signal as a reception signal RS. Therefore, the signal transmitted to the receiving device 230 via the security filter device 220 has a waveform different from that of the signal not passing through the security filter device 220. An actual implementation of the human body communication system 200 using the security filter device 220 is shown in FIGS. 5 and 6.

The distortion filter 222 may transform the transmission signal TS according to a set response characteristic, that is, a set transfer function. The response characteristic of the distortion filter 222 may be determined based on a circuit implemented in the distortion filter 222. For example, the distortion filter 222 may include passive elements such as resistors, inductors, and capacitors to implement a band pass filter. However, the present invention is not limited thereto, and the distortion filter 222 may be implemented to have characteristics such as a low pass filter, a high pass filter, or a band cut filter, and for amplifying or attenuating some frequency bands of the transmission signal TS. It may include an active device.

The response characteristic, transfer function or order of the distortion filter 222 may be adjusted. To this end, the distortion filter 222 may include a variable resistor, a variable inductor, or a variable capacitor. The response characteristic of the distortion filter 222 may be changed by an external electronic device. Alternatively, the response characteristic of the distortion filter 222 may be changed by the transmitting apparatus 210 further transmitting a filter control signal in addition to the transmission signal TS. In order to adjust the response characteristic, the security filter device 220 may further include a filter controller (not shown). The response characteristic of the distortion filter 222 may be changed periodically. When the response characteristic is periodically changed, the leakage of transmission information by others can be further reduced.

The response characteristic, the transfer function, or the order of the distortion filter 222 may be set differently for each human body communication system. For example, the security filter device 220 may be provided separately to different users. The security filter device 220 worn by different users may be different. Since the distortion filter 222 is provided to have different response characteristics for each security filter device 220, even if the transmission signal TS is transmitted to another person, the signal transmitted to the other person may not be recognized by the reception device 230. . That is, the reliability and security of the human body communication system 200 may be improved by using the security filter device 220 having a user-specific response characteristic.

The second electrode 223 may receive the distorted reception signal RS by the distortion filter 222, and the received reception signal RS may be output to the outside through the second electrode 223. The second electrode 223 may be electrically connected to the distortion filter 222 and may be formed on an outer surface of the security filter device 220. The second electrode 223 may be in contact with the human body such that the reception signal RS is input to the receiving device 230 through the human body. However, the present invention is not limited thereto, and the reception signal RS may be input to the reception device 230 without passing through the human body. To this end, the second electrode 223 may be in contact with the receiving device 230 or may be spaced apart from the receiving device 230 to have a small distance.

The receiving device 230 may include a receiving electrode 231, a correction filter 232, and a receiving circuit 233. The reception electrode 231 may receive the reception signal RS from the security filter device 220, and the received reception signal RS may be output to the correction filter 232 through the reception electrode 231. The receiving electrode 231 is electrically connected to the correction filter 232, and may be formed on an outer surface of the receiving device 230. The receiving electrode 231 may be contacted with the human body or spaced apart from the human body so as to receive the reception signal RS through the human body. Alternatively, the receiving electrode 231 may be in contact with the second electrode 223 to receive the reception signal RS without passing through the human body, or may be spaced apart from the second electrode 223 by a small distance.

The distance between the receiving electrode 231 (or the receiving device 230) and the security filter device 220 may be closer than the distance between the transmitting electrode 214 (or the transmitting device 210) and the security filter device 220. . As the distance between the reception electrode 231 and the security filter device 220 increases, a path through which the reception signal RS is transmitted increases. As the area of the human body to which the reception signal RS is transmitted increases, the possibility that the reception signal RS is leaked by others or the like increases. For example, when another person contacts an area of the human body to which the received signal RS is transmitted, the received signal RS may be transmitted to another person. Therefore, the reception device 230 may be disposed close to the security filter device 220 so that the transmission path of the reception signal RS is minimized.

The correction filter 232 may receive the reception signal RS from the reception electrode 231, and the received reception signal RS may be transformed into a correction signal by the correction filter 232. The correction filter 232 may be provided to correct the waveform distorted by the distortion filter 222. If the distortion and loss of the signal due to the human body or the like are not taken into consideration, the correction signal modified by the correction filter 232 may exhibit the same waveform as the transmission signal TS.

The correction filter 232 may transform the received signal RS according to a set response characteristic, that is, a set transfer function. The response characteristic of the correction filter 232 is determined based on the circuit implemented in the correction filter 232, but depends on the response characteristic of the distortion filter 222. The correction filter 232 may be implemented such that the product of the transfer function of the correction filter 232 and the transfer function of the distortion filter 222 maintains a reference value. That is, from the perspective of the human body communication system 200 as a whole, the system response may have a constant gain with respect to frequency. For example, the reference value may be one. For example, when the distortion filter 222 is implemented to have the characteristics of a band pass filter, the correction filter 232 may be implemented to have the characteristics of a band cut filter. The correction filter 232 may include passive elements such as resistors, inductors, and capacitors in order to have a set response characteristic, but is not limited thereto and may include active elements for amplifying some frequency bands.

The response characteristic, transfer function, or order of the correction filter 232 can be adjusted. To this end, the correction filter 232 may include a variable resistor, a variable inductor, or a variable capacitor. The response characteristic of the correction filter 232 may be changed by an external electronic device. Alternatively, the response characteristic of the correction filter 232 may be changed based on the filter control signal provided from the transmitting device 210. Since the response characteristic of the correction filter 232 depends on the response characteristic of the distortion filter 222, the response characteristic of the correction filter 232 may be changed according to the changed response characteristic of the distortion filter 222. In order to adjust the response characteristic, the reception device 230 may further include a filter controller (not shown). Alternatively, the response characteristic of the correction filter 232 may be changed under the control of the reception controller 235 included in the reception circuit 233. The response characteristic of the correction filter 232 may be changed periodically.

The response characteristic, the transfer function, or the order of the correction filter 232 may be set differently for each human body communication system like the distortion filter 222. That is, a correction filter 232 having a user-specific response characteristic may be provided. For example, when the receiving device 230 is provided to a user individually, each of the receiving devices may include a correction filter having different response characteristics. Alternatively, when a plurality of users wearing different security filter devices share one receiving device, the receiving device 230 may change a response characteristic of the correction filter 232 according to the identified user.

The receiving circuit 233 may convert the correction signal modified by the correction filter 232 into data information corresponding to the transmission signal TS. The data information corresponding to the transmission signal TS may be transmission information generated by the transmission signal generator 212 to output the transmission signal TS. The receiving circuit 233 may restore the transmission signal TS or the transmission information based on the correction signal. The reception circuit 233 may include a reception signal recoverer 234 and a reception controller 235.

The reception signal restorer 234 may process the correction signal to be restored to a signal that matches the transmission signal TS or the transmission information under the control of the reception controller 235. For example, the reception signal restorer 234 may amplify the attenuated signal through the human body. To this end, the received signal reconstructor 234 may include an amplifier. The received signal reconstructor 234 may extract data and clock signals that match the transmission information from the amplified correction signal. The correction signal may be an analog signal or a digital signal, and when the correction signal is an analog signal, the received signal reconstructor 234 may include an analog-to-digital converter for converting the analog signal into a digital signal.

The reception controller 235 may control the reception signal restorer 234 to recover the transmission signal TS or the transmission information. For example, under the control of the reception controller 235, the reception signal restorer 234 converts the correction signal into data information corresponding to the transmission signal TS, and the data information may be stored in a memory (not shown). Can be.

Although not shown, the receiving device 230 may further include a processor (not shown) for performing an essential function of the human body communication system 200 based on the restored signal. For example, when the human body communication system 200 is applied to control an electronic device such as a computer, the receiving device 230 may be a computer, and based on the restored signal, the processor (not shown) may display a specific image. It can display, control the on-off of the computer, or process certain operations.

FIG. 3 is a graph illustrating a relationship between the distortion filter and the correction filter of FIG. 2. Referring to FIG. 3, the transfer function Hd (f) for the distortion filter 222 of FIG. 2 and the transfer function Hc (f) for the correction filter 232 of FIG. 2 are illustrated by way of example. The horizontal axis of the graphs of FIG. 3 represents frequency, and the vertical axis represents the magnitude of the transfer function. For convenience of description, FIG. 3 will be described with reference to the reference numerals of FIG. 2.

The transfer function Hd of the distortion filter 222 is illustratively shown to have the characteristics of a band pass filter. However, the present invention is not limited thereto, and the transfer function Hd of the distortion filter 222 may have various filter characteristics that may transform the transmission signal TS. The transmission signal TS is transformed into a distortion signal by the distortion filter 222. In exemplary embodiments, the transmission signal TS may be modified to have a high gain in the intermediate frequency band and a low gain in the remaining frequency band by the transfer function Hd of the distortion filter 222.

The transfer function Hc of the correction filter 232 is illustratively shown to have the characteristics of a band cut filter. The transfer function Hc of the correction filter 232 may be determined by the transfer function Hd of the distortion filter 222. For example, when the transfer function Hd of the distortion filter 222 has the characteristics of the low pass filter, the transfer function Hc of the correction filter 232 may have the characteristics of the high pass filter. The distortion signal is transformed by the correction filter 232. For example, the distortion signal may be modified to have a low gain in the intermediate frequency band and a high gain in the remaining frequency band by the transfer function Hc of the correction filter 232.

The product of the transfer function Hd of the distortion filter 222 and the transfer function Hc of the correction filter 232 may have a predetermined reference value. For example, the reference value may be one. In this case, the system response of the human body communication system 200 including the distortion filter 222 and the correction filter 232 may be one. That is, the signal output from the correction filter 232 may coincide with the transmission signal TS unless attenuation or distortion by a signal transmission path such as a human body is considered. That is, in an ideal case, the signal received by the received signal reconstructor 234 may be an undistorted signal that matches the transmission signal TS.

4 is a block diagram illustrating an embodiment of a receiving apparatus that may be replaced in the human body communication system of FIG. 2. Referring to FIG. 4, the receiving device 230_2 may include a receiving electrode 231_2 and a receiving circuit 233_2. The reception electrode 231_2 receives the reception signal RS from the security filter device 220 of FIG. 2, and the received reception signal RS is transmitted to the reception circuit 233_2.

The reception circuit 233_2 includes a reception signal recovery circuit 234_2 and a reception controller 235_2. The received signal recovery circuit 234_2 includes a correction filter 236_2. The received signal recovery circuit 234_2 performs substantially the same function as the received signal restorer 234 of FIG. 2 except for the function performed by the correction filter 236_2. The reception controller 235_2 performs substantially the same function as the reception controller 235 of FIG. 2.

Unlike the correction filter 232 of FIG. 2, the correction filter 236_2 may be implemented as a digital filter in the reception signal recovery circuit 234_2. When the received signal RS is an analog signal, the received signal recovery circuit 234_2 may convert the received signal RS into a digital signal. The correction filter 236_2 may transform the converted digital signal into a correction signal. To process the digital signal, correction filter 236_2 may include an adder, a multiplier, or a shift register. Correction filter 236_2 is implemented to correct for distortion by security filter device 220. Like the correction filter 232 of FIG. 2, the response characteristic of the correction filter 236_2 may depend on the response characteristic of the distortion filter 222 of FIG. 2. The received signal recovery circuit 234_2 may restore the transmission signal TS or the transmission information based on the correction signal.

FIG. 5 is a diagram illustrating an actual application example of the human body communication system of FIG. 2. Referring to FIG. 5, the human body communication system 200_a may be applied to a gate access system. For example, the human body communication system 200_a may be provided to allow the user USER to pass through the gate. The human body communication system 200_a includes a transmitting device 210_a, a security filter device 220_a, and a receiving device 230_a. Each of the transmitting device 210_a, the security filter device 220_a, and the receiving device 230_a corresponds to the transmitting device 210, the security filter device 220, and the receiving device 230 of FIG. 2.

The transmitting device 210_a may be a device for outputting a transmission signal and identifying a user USER. For example, in FIG. 5, it is assumed that the transmitting device 210_a is an identification card that is worn around the neck of the user USER. When the transmitting device 210_a is an identification card, the transmitting device 210_a may not be in direct contact with the skin due to the movement of the top and the user USER. That is, the transmission device 210_a may radiate the transmission signal to the outside in a non-contact manner. Part of the transmission signal may be emitted to the periphery of the user (USER), such as a dotted line. A part of the transmission signal may be transmitted to the reception device 230_a through a user USER, such as a solid line.

The security filter device 220_a may transform a portion of the transmission signal transmitted through the user USER into a distortion signal (receive signal). For example, it is assumed that the security filter device 220_a is attached to the leg in FIG. 5. However, the present invention is not limited thereto, and the security filter device 220_a may be attached to a finger of the user USER. In this case, the human body communication may be performed by placing the finger with the security filter device 220_a in contact with or adjacent to the receiving device 230_a. The security filter device 220_a may be disposed closer to the receiving device 230_a than the transmitting device 210_a.

The reception device 230_a may receive a distortion signal (receive signal) modified by the security filter device 220_a. For example, in FIG. 5, it is assumed that the reception device 230_a is a gate device that manages entry and exit to a specific place. When the reception device 230_a receives the reception signal, the reception device 230_a may process the reception signal to open the gate. The correction filter included in the reception device 230_a may correct the modified received signal as a correction signal. The receiving device 230_a may recognize the user USER based on the correction signal.

When the other person AA without the transmitting device 210_a contacts the user USER, the transmission signal output from the transmitting device 210_a may be transmitted to the other person AA. If the reception device 230_a opens the gate in response to the transmission signal without the security filter device 220_a, the tine AA may pass through the gate in contact with the user USER. In order to secure the security and reliability of the gate access system to which the human body communication system 200_a is applied, the reception device 230_a may convert only the signal passing through the security filter device 220_a into data information corresponding to the transmission signal. . In this case, the reception device 230_a cannot convert a signal transmitted through the tine AA into data information corresponding to the transmission signal, and the tine AA cannot pass through the gate.

FIG. 6 is a diagram illustrating an actual application example of the human body communication system of FIG. 2. Referring to FIG. 6, the human body communication system 200_b may be applied to a vehicle system. For example, the human body communication system 200_b may be provided at a door to allow a user to ride in a vehicle. The human body communication system 200_b includes a transmitting device 210_b, a security filter device 220_b, and a receiving device 230_b. Each of the transmitting device 210_b, the security filter device 220_b, and the receiving device 230_b corresponds to the transmitting device 210, the security filter device 220, and the receiving device 230 of FIG.

The transmitting device 210_b may be a device that outputs a transmission signal for the user's vehicle. The transmitting device 210_b may radiate a transmission signal to the outside in a contact or non-contact manner. Some of the transmitted signal may be radiated to the surroundings of the user, such as dotted lines. Part of the transmission signal may be transmitted to the security filter device 220_b through the user, such as a solid line.

The security filter device 220_b may transform the transmission signal transmitted through the user into a distortion signal (receive signal). For example, it is assumed in FIG. 6 that the security filter device 220_b has a thimble shape and is worn on a user's finger. However, the present invention is not limited thereto, and the security filter device 220_b may have a ring shape and may be worn on a user's finger. The security filter device 220_b may be in contact with or adjacent to the reception device 230_b, so that a reception signal may be transmitted. The security filter device 220_b may be disposed closer to the receiving device 230_b than the transmitting device 210_b.

The security filter device 220_b may include a first electrode 221_b, a distortion filter 222_b, and a second electrode 223_b. The first electrode 221_b may be in contact with a user to receive a transmission signal, and the transmission signal may be transmitted to the distortion filter 222_b through the first electrode 221_b. The distortion filter 222_b transforms the transmitted signal into a received signal based on the set response characteristic or transfer function. The distortion filter 222_b may be configured to be detachable from the security filter device 220_b. For example, to improve security, a new distortion filter 222_b may be attached to the security filter device 220_b. The second electrode 223_b may receive a modified reception signal from the distortion filter 222_b, and the reception signal may be transmitted to the reception device 230_b through the second electrode 223_b. The second electrode 223_b may be formed on an outer surface of the security filter device 220_b so as to be in contact with the receiving device 230_b.

The receiving device 230_b may receive the received signal modified by the security filter device 220_b. For example, in FIG. 6, it is assumed that the reception device 230_b is a device that controls opening and closing of a vehicle door. When the reception device 230_b receives the reception signal, the reception device 230_b may process the reception signal to open the vehicle door. The correction filter included in the reception device 230_b may correct the received signal with the correction signal. Since the transmission signal radiated around the user is different from the reception signal, the reception device 230_b may not open the vehicle door based on the transmission signal radiated around the user.

FIG. 7 is a block diagram specifically illustrating an embodiment of the human body communication system of FIG. 1. Referring to FIG. 7, the human body communication system 300 includes a transmitting device 310, a first security filter device 320, a second security filter device 330, and a receiving device 340. The transmitting device 310 corresponds to the transmitting device 110 of FIG. 1, the first and second security filter devices 320 and 330 correspond to the security filter device 120 of FIG. 1, and the receiving device 340. ) Corresponds to the receiving device 130 of FIG. 1.

The transmitting device 310 outputs the transmission signal TS to the outside. The transmission device 310 includes a transmission circuit 311 and a transmission electrode 314. The transmit circuit 311 includes a transmit signal generator 312 and a transmit controller 313. Since the transmitting device 310 is substantially the same as the transmitting device 210 of FIG. 2, a detailed description thereof will be omitted.

The first security filter device 320 may transform the transmission signal TS into a distortion signal DS and output the distortion signal DS to the second security filter device 330. The first security filter device 320 receives a transmission signal TS, receives a first electrode 321 for transmitting the distortion signal 322, and a distortion filter 322 for transforming the transmission signal TS into a distortion signal DS. ) And a second electrode 323 that receives the distortion signal DS from the distortion filter 322 and outputs it to the outside. Since the first security filter device 320 is substantially the same as the security filter device 220 of FIG. 2, a detailed description thereof will be omitted.

The second security filter device 330 may transform the distortion signal DS into a reception signal RS and output the distortion signal DS to the reception device 340. The second security filter device 330 receives the distortion signal DS, receives the distortion signal DS, and transmits the third electrode 331 and the distortion signal DS to the correction filter 332. ) And a fourth electrode 333 that receives the received signal RS from the correction filter 332 and outputs it to the outside. The product of the transfer function of the distortion filter 322 and the transfer function of the correction filter 332 may have a reference value, and for example, the reference value may be one.

Unlike FIG. 2, in the human body communication system 300 of FIG. 7, the correction filter 332 is separated from the receiving device 340. The first security filter device 320 and the second security filter device 330 may be in contact with a human body. The position at which the first security filter device 320 and the second security filter device 330 are attached to the human body may be determined according to an exemplary embodiment of the human body communication system 300. The first security filter device 320 and the second security filter device 330 may transmit signals with the human body interposed therebetween. However, the present invention is not limited thereto, and the first security filter device 320 and the second security filter device 330 may be in contact with each other.

In one example, the second security filter device 330 is disposed adjacent to the receiving device 340, the first security filter device 320 is disposed closer to the second security filter device 330 than the transmitting device 310. Can be. In this case, leakage of the distortion signal DS and the reception signal RS may be minimized. For example, the second security filter device 330 may be disposed adjacent to the receiving device 340, and the first security filter device 320 may be disposed adjacent to the transmitting device 310. In this case, a signal radiated to the periphery of the human body and a signal transmitted to the human body may be distinguished, and the leakage of the reception signal RS may be minimized. In one example, the first security filter device 320 is disposed adjacent to the transmitting device 310, the second security filter device 330 is disposed closer to the first security filter device 320 than the receiving device 340. Can be. In this case, a signal radiated to the periphery of the human body and a signal transmitted to the human body may be distinguished, and leakage of the distortion signal DS may be minimized.

The reception device 340 may restore data information corresponding to the transmission signal TS based on the reception signal RS. The receiving device 340 includes a receiving electrode 341 and a receiving circuit 343. The receive circuit 343 includes a receive signal recoverer 344 and a receive controller 345. Since the reception device 340 is substantially the same as the reception device 230 of FIG. 2 except for the correction filter 232 included in the reception device 230 of FIG. 2, a detailed description thereof will be omitted.

FIG. 8 is a block diagram specifically illustrating an embodiment of the human body communication system of FIG. 1. Referring to FIG. 8, the human body communication system 400 includes a transmitting device 410, a security filter device 420, and a receiving device 430. Each of the transmitting device 410, the security filter device 420, and the receiving device 430 corresponds to the transmitting device 110, the security filter device 120, and the receiving device 130 of FIG. 1.

The transmitter 410 outputs the transmission signal TS to the outside. The transmission device 410 includes a transmission circuit 411, a transmission electrode 414, and a distortion filter 415. The transmit circuit 411 includes a transmit signal generator 412 and a transmit controller 413. Since the transmission signal generator 412 and the transmission controller 413 are substantially the same as the transmission signal generator 212 and the transmission controller 213 of FIG. 2, detailed descriptions thereof will be omitted. For example, the transmitting circuit 411 may generate data information and convert the data information into an analog signal. Here, the analog signal may correspond to the transmission signal TS of FIG. 2. The transmitting circuit 411 may transmit this analog signal to the distortion filter 415.

The distortion filter 415 may be included in the transmitting device 410 unlike other embodiments. The distortion filter 415 transforms the signal received from the transmission circuit 411 into a transmission signal TS. The distortion filter 415 may include passive elements such as resistors, inductors, and capacitors, but is not limited thereto and may include active elements. Although the distortion filter 415 has been described as being an analog filter, the present invention is not limited thereto and may be implemented as a digital filter. In this case, the distortion filter 415 may be included in the transmission signal generator 412 to transform the digital signal. The transmission signal TS is output to the outside through the transmission electrode 414.

The security filter device 420 may transform the transmission signal TS into a reception signal RS and output the transformed signal TS to the reception device 430. The security filter device 420 may include a first electrode 421 that receives a transmission signal TS and transmits it to the correction filter 422, a correction filter 422 that transforms the transmission signal TS into a reception signal RS, And a second electrode 423 which receives the received signal RS from the correction filter 422 and outputs it to the outside. The product of the transfer function of the correction filter 422 and the transfer function of the distortion filter 415 may have a reference value, and for example, the reference value may be one.

The reception device 430 may restore data information corresponding to the signal generated by the transmission circuit 411 based on the reception signal RS. The receiving device 430 includes a receiving electrode 431 and a receiving circuit 433. Since the reception device 430 is substantially the same as the reception device 340 of FIG. 7, a detailed description thereof will be omitted.

The above description is specific examples for practicing the present invention. The present invention will include not only the embodiments described above but also embodiments that can be easily changed or simply changed in design. In addition, the present invention will also include techniques that can be easily modified and carried out using the above-described embodiments.

100, 200, 300, 400: human body communication system
110, 210, 310, 410: transmitter
120, 220, 320, 330, 420: security filter unit
130, 230, 340, 430: receiver
222, 322, 415: distortion filter
232, 332, 422: calibration filter

Claims (15)

A transmission device for outputting a transmission signal to a living body;
A security filter device including a distortion filter for transforming the transmission signal received through the living body into a distortion signal; And
And a reception device for converting the distortion signal into data information corresponding to the transmission signal. According to claim 1,
The security filter device,
A first electrode receiving the transmission signal from the living body; And
And a second electrode for outputting the distortion signal. According to claim 1,
The security filter device,
A human body communication system separate from the transmitting device and the receiving device. According to claim 1,
The receiving device,
A receiving electrode receiving the distortion signal;
A correction filter for transforming the received distortion signal into a correction signal; And
And a reception circuit for converting the correction signal into the data information. The method of claim 4, wherein
The product of the transfer function of the distortion filter and the transfer function of the correction filter maintains a reference value. According to claim 1,
The receiving device,
A receiving electrode receiving the distortion signal; And
And a receiving circuit converting the received distortion signal into a digital signal, transforming the converted digital signal into a correction signal, and converting the correction signal into the data information. According to claim 1,
And the security filter device is configured to be in contact with the living body, wherein the distance between the receiving device and the security filter device is disposed closer than the distance between the transmitting device and the security filter device. A transmission device for outputting a transmission signal to the outside;
A security filter device for modifying a part of a transmission signal transmitted through a living body among the transmission signals output to the outside; And
And a reception device for restoring data information corresponding to the transmission signal based on the modified transmission signal. The method of claim 8,
The security filter device,
A first electrode receiving a portion of the transmission signal transmitted through the living body;
A distortion filter for transforming the transmission signal received from the first electrode into a distortion signal; And
And a second electrode configured to output the distortion signal to the receiving device. The method of claim 9,
The receiving device,
A correction filter for transforming the received distortion signal into a correction signal,
The product of the transfer function of the correction filter and the transfer function of the distortion filter has a reference value. The method of claim 8,
The transmitting device,
A transmission circuit generating the data information and converting the data information into an analog signal; And
And a distortion filter for transforming the analog signal into a transmission signal. The method of claim 11, wherein
The security filter device,
Comprising a correction filter for transforming a portion of the transmission signal transmitted through the living body to a correction signal,
The product of the transfer function of the correction filter and the transfer function of the distortion filter has a reference value. The method of claim 8,
The security filter device,
A first security filter device for transforming a portion of the transmission signal transmitted through the living body into a distortion signal; And
And a second security filter device for converting the distortion signal into a correction signal and outputting the correction signal to the receiving device.
And a product of the transfer function of the first security filter device and the transfer function of the second security filter device has a reference value. The method of claim 13,
The first security filter device,
A first electrode for receiving a portion of the transmission signal;
A distortion filter configured to transform the transmission signal received from the first electrode into the distortion signal; And
A second electrode configured to output the distortion signal received from the distortion filter to the living body;
The second security filter device,
A third electrode configured to receive a portion of the distortion signal received from the living body;
A correction filter for transforming the distortion signal received from the third electrode into the correction signal; And
And a fourth electrode configured to output the correction signal received from the correction filter to the receiving device. The method of claim 13,
And the first security filter device and the second security filter device are separated from each other.

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