KR102412908B1 - Human body communication device having single electrode - Google Patents

Abstract

The present invention relates to a human body communication device. The human body communication device of the present invention provides an electrode, a matching circuit connected to the electrode and configured to provide impedance matching, a first path electrically connected to the matching circuit in a first state, and a matching circuit in a second state and a switch configured to provide a second path electrically coupled, in a first state, coupled with the matching circuit through the first path of the switch, outputting a first sensing signal to the matching circuit through the switch, and first sensing a detector configured to output a second detection signal when a difference between the signal generated by the matching circuit in response to the signal and the first signal is equal to or greater than a threshold, in a second state, connected to the matching circuit through a second path of the switch, a transmitter configured to output a data signal to the matching circuit via the switch; and a controller configured to, in the first state, control the switch from the first state to the second state in response to receiving a second sense signal from the detector. do.

Description

Human body communication device with single electrode {HUMAN BODY COMMUNICATION DEVICE HAVING SINGLE ELECTRODE}

The present invention relates to an electronic device, and more particularly, to a human body communication device having a single electrode.

A human body communication device is a device that transmits or receives a signal using a human body as a medium. The human body communication device may be configured to transmit or receive a signal through electrodes in contact with the human body. The human body communication device may be combined with a wearable device that maintains contact with the human body, thereby providing various new experiences to the user.

The fact that a plurality of electrodes of the human body communication device must maintain contact with the human body acts as an obstacle to the commercialization of the human body communication device. Maintaining a plurality of electrodes in contact with the human body may impair the convenience of a user's daily life. Therefore, there is a need for research to reduce the number of electrodes that must be kept in contact with the human body.

SUMMARY OF THE INVENTION An object of the present invention is to provide a human body communication device that improves user convenience and reduces power consumption by having a single electrode.

A human body communication device according to an embodiment of the present invention provides an electrode, a matching circuit connected to the electrode and configured to provide impedance matching, a first path electrically connected to the matching circuit in a first state, and a second state a switch configured to provide a second path electrically connected with the matching circuit in and a detector configured to output a second detection signal when a difference between a signal generated by the matching circuit in response to the first detection signal and the first signal is equal to or greater than a threshold, in the second state, the matching circuit through a second path of the switch a transmitter coupled to and configured to output a data signal to the matching circuit via the switch, and in a first state, configured to control the switch from the first state to the second state in response to receiving a second sense signal from the detector It includes a controller that is

As an embodiment, in the first state, the controller is further configured to control the detector to the active mode and to control the transmitter to the power save mode.

As an embodiment, in the second state, the controller is further configured to control the detector to the power saving mode, and to control the transmitter to the active mode.

As an embodiment, in response to the switch entering the second state from the first state, the transmitter is further configured to output the same data as a data signal.

As an embodiment, in the second state, in response to the transmitter completing output of the data signal, the controller is further configured to control the switch from the second state to the first state.

A human body communication device according to an embodiment of the present invention provides an electrode, a matching circuit connected to the electrode and configured to provide impedance matching, a first path electrically connected to the matching circuit in a first state, and a second state a switch configured to provide a second path electrically connected with the matching circuit in and a detector configured to output a second detection signal when a difference between a signal generated by the matching circuit in response to the first detection signal and the first signal is equal to or greater than a threshold, in the second state, the matching circuit through a second path of the switch a receiver coupled to and configured to receive a data signal through the switch to the matching circuit, and in a first state, configured to control the switch from the first state to the second state in response to receiving a second sense signal from the detector It includes a controller that is

As an embodiment, in the first state, the controller is further configured to control the detector to the active mode and to control the receiver to the power save mode.

As an embodiment, in the second state, the controller is further configured to control the detector to a power saving mode and to control the receiver to an active mode.

As an embodiment, in the second state, when the idle time during which no data signal is received is longer than the threshold, the controller is further configured to control the switch from the second state to the first state.

A human body communication device according to an embodiment of the present invention provides an electrode, a matching circuit connected to the electrode and configured to provide impedance matching, a first path electrically connected to the matching circuit in a first state, and a second state a switch configured to provide a second path electrically connected with the matching circuit in and a detector configured to output a second detection signal when a difference between a signal generated by the matching circuit in response to the first detection signal and the first signal is equal to or greater than a threshold, in the second state, the matching circuit through a second path of the switch a transceiver coupled to and configured to output a first data signal to or receive a second data signal from the matching circuit through the switch, and in a first state, in response to receiving a second sensing signal from the detector and a controller configured to control the switch from the first state to the second state.

As an embodiment, in the first state, the controller is further configured to control the sensor to the active mode and to control the transceiver to the power save mode.

As an embodiment, in the second state, the controller is further configured to control the sensor to a power saving mode and control the transceiver to an active mode.

As an embodiment, in the second state, when the idle time of not outputting the first data signal and not receiving the second data signal is longer than a threshold, the controller is further configured to control the switch from the second state to the first state do.

According to the present invention, there is provided a human body communication device that detects a human body contact using a single electrode, and performs human body communication using a single electrode when the human body contact is detected. Accordingly, a human body communication device with improved user convenience can be provided. In addition, the components for sensing the human body communication device and the components for communication alternately enter the power saving mode. Accordingly, a human body communication device with reduced power consumption can be provided.

1 shows a human body communication system according to a first embodiment of the present invention.
FIG. 2 is a flowchart illustrating an operation method of the first human body communication device of FIG. 1 .
3 is a flowchart illustrating an operation method of the second human body communication device of FIG. 1 .
4 shows a human body communication system according to a second embodiment of the present invention.
5 is a flowchart illustrating an operation method of the third human body communication devices of FIG. 4 .

Hereinafter, embodiments of the present invention will be described clearly and in detail to the extent that those skilled in the art can easily practice the present invention.

1 shows a human body communication system 10 according to a first embodiment of the present invention. Referring to FIG. 1 , the human body communication system 10 may include a human body 100 , a first body communication device 200 , and a second body communication device 300 . The human body may be a medium for communication between the first body communication device 200 and the second body communication device 300 .

The first human body communication device 200 includes a first electrode 210 , a first matching circuit 220 , a first switch 230 , a first detector 240 , a transmitter 250 , and a first controller 260 . may include The first electrode 210 may be exposed to the outside of the first human body communication device 200 to contact the human body 100 . The first electrode 210 may be a single electrode that enables the first human body communication device 200 to communicate with the human body.

The first matching circuit 220 may be connected to the first electrode 210 . The first matching circuit 220 may provide impedance matching for the human body 100 . The first matching circuit 220 may include passive elements such as resistors, capacitors, and inductors. The first matching circuit 220 may include a variable resistor, a variable capacitor, or a variable inductor. Each of the variable resistor, the variable capacitor, or the variable inductor may be implemented by combining switches and passive elements. For example, the switches may operate in response to the control of the first controller 260 .

The first switch 230 may be connected to the first matching circuit 220 . The first switch 230 may operate in response to the control of the first controller 260 . The first switch 230 may select one of the first detector 240 and the transmitter 250 , and may electrically connect the selected component to the first matching circuit 220 .

For example, the first switch 230 may electrically connect the first detector 240 to the first matching circuit 220 in the first state. The first state may be a sensing state. The first switch 230 may electrically connect the transmitter 250 to the first matching circuit 220 in the second state. The second state may be a communication state.

The first detector 240 may operate in response to the control of the first controller 260 . The first detector 240 may receive the first activation signal EN1 from the first controller 260 . In a first state (ie, a sensing state), the first activation signal EN1 is an active state (eg, a voltage of a first level), and in a second state (ie, a communication state), the first activation signal EN1 may be in an inactive state (eg, a second level of voltage).

In response to the first activation signal EN1 becoming an active state, the first detector 240 may enter an active mode. In response to the first activation signal EN1 becoming inactive, the first detector 240 may enter a power saving mode.

For example, when the first switch 230 enters the first state (ie, the sensing state) by the first controller 260 , the first activation signal EN1 becomes the active state, and the first detector 240 ) can be in the active mode. In the active mode, the first detector 240 may output the first detection signal SS1 to the first electrode 210 through the first switch 230 and the first matching circuit 220 . The first detection signal SS1 may include a signal having a repeating pattern such as a continuous wave or a square wave.

In the active mode, the first detector 240 may determine whether the first electrode 210 is in contact with the human body 100 in response to a change in the first detection signal SS1 . For example, the first detector 240 tracks the envelope of the first detection signal SS1 generated by the first matching circuit 220, and responds to a change in the envelope of the first electrode 210 It can be determined whether or not the human body 100 is in contact.

When the size of the envelope of the first detection signal SS1 is greater than (or less than) a specific threshold value, the first detector 240 may determine that the first electrode 210 is not in contact with the human body 100 . have. When the size of the envelope of the first detection signal SS1 is less than (or greater than) a specific threshold, the first detector 240 may determine that the first electrode 210 is in contact with the human body 100 . .

When it is determined that the first electrode 210 is not in contact with the human body 100 , the first detector 240 sets the second detection signal SS2 output to the first controller 260 to an inactive state (eg, voltage of the third level). When it is determined that the first electrode 210 is in contact with the human body 100 , the first detector 240 generates the second detection signal SS2 output to the first controller 260 in an active state (eg, the second detection signal SS2 ). voltage of a fourth level that is different from the third level) can be controlled.

When the first switch 230 enters the second state (ie, the communication state) by the first controller 260 , the first activation signal EN1 is in an inactive state (eg, a second state different from the first level) level of voltage) can be controlled. As the first activation signal EN1 becomes inactive, the first detector 240 may enter a power saving mode.

In the power saving mode, the first detector 240 may consume less power than the power consumed in the sensing mode. For example, in the power saving mode, the first detector 240 detects that the first activation signal EN1 is controlled to the active state, and configures other components except for the components for entering the first state (sensing state). The power supplied to the elements, for example, generating the first detection signal SS1, determining the contact of the human body 100, and generating the second detection signal SS2, may be cut off. have.

The transmitter 250 may operate in response to the control of the first controller 260 . The transmitter 250 may receive the second activation signal EN2 from the first controller 260 . In a second state (ie, communication state), the second activation signal EN2 is an active state (eg, a voltage of a fifth level), and in a first state (ie, a sensing state), the second activation signal EN2 may be in an inactive state (eg, a sixth level voltage).

In response to the second activation signal EN2 becoming an active state, the transmitter 250 may enter an active mode. In response to the second activation signal EN2 becoming inactive, the transmitter 250 may enter a power saving mode.

In the active mode, the transmitter 250 may receive the first data signal DT1 from the first controller 260 . The transmitter 250 may generate the second data signal DT2 by modulating the first data signal DT1 into a form suitable for human body communication. The transmitter 250 may output the second data signal DT2 to the first electrode 210 through the first switch 230 and the first matching circuit 220 .

For example, the first data signal DT1 may include fixed information. Whenever the first switch 230 enters the second state (ie, the communication state), and the second activation signal EN2 becomes the active state, the transmitter 250 transmits the second data signal ( DT2). For example, the transmitter 250 may be configured to generate the first data signal DT1 by itself instead of receiving it from the first controller 260 . For example, the transmitter 250 may include a storage for storing information for generating the first data signal DT1 .

For example, in response to entering the active mode, the transmitter 250 may be configured to repeatedly transmit the second data signal DT2 twice or more. For example, when two or more first body communication devices 200 are provided in the body communication system 10 , different first body communication devices 200 may transmit different information.

After the transmitter 250 completes the transmission of the second data signal DT2, under the control of the first controller 260, the first switch 230 enters the first state (ie, the detection state), and The transmitter 250 may enter a power saving mode. In power saving mode, transmitter 250 may consume less power than power dissipated in active mode.

The first controller 260 may control operations of the first human body communication device 200 . The first controller 260 enters a second state (communication state) in response to the human body 100 making contact with the first electrode 210 in the first state (sensing state) to transmit the second data signal DT2 The first human body communication device 200 may be controlled to output and return to the first state (sensing state).

The second human body communication device 300 includes a second electrode 310 , a second matching circuit 320 , a second switch 330 , a second detector 340 , a receiver 350 , and a second controller 360 . may include The second electrode 310 may be exposed to the outside of the second human body communication device 300 to contact the human body 100 . The second electrode 310 may be a single electrode that enables the human body communication of the second body communication device 300 .

The second matching circuit 320 may provide impedance matching. The second matching circuit 320 may have the same configuration and the same operation as the first matching circuit 220 described above.

The second switch 330 may be connected to the second matching circuit 320 . The second switch 330 may operate in response to the control of the second controller 360 . The second switch 330 may select one of the second detector 340 and the receiver 350 and electrically connect the selected component to the second matching circuit 320 .

For example, the second switch 330 may electrically connect the second detector 340 to the second matching circuit 320 in the first state (ie, the sensing state). The second switch 330 may electrically connect the receiver 350 to the second matching circuit 320 in a second state (ie, a communication state). The second state may be a communication state.

The second detector 340 may receive the third activation signal EN3 from the second controller 360 . In the first state (ie, the sensing state), the third activation signal EN3 is in the active state (eg, the voltage of the first level), and in the second state (ie, the communication state), the third activation signal EN3 may be in an inactive state (eg, a second level of voltage).

In response to the third activation signal EN3 becoming an active state, the second detector 340 may enter an active mode. In response to the third activation signal EN3 becoming inactive, the second detector 340 may enter a power saving mode.

In the first state (ie, the sensing state), the third activation signal EN3 may be in an active state. That is, in the first state (ie, the sensing state), the second detector 340 may enter the active mode. In the second state (ie, the communication state), the third activation signal EN3 may be in an inactive state. That is, in the second state (ie, the communication state), the second detector 340 may enter the power saving mode.

In the first state (ie, the sensing state), the second detector 340 outputs the third sensing signal SS3 to the second electrode 310 through the second switch 330 and the second matching circuit 320 . can do. As described with reference to the first detector 240 , when it is determined that the human body 100 is in contact with the second electrode 310 , the second detector 340 turns the fourth detection signal SS4 into an inactive state. It can adjust from (eg, a voltage of a third level) to an active state (eg, a voltage of a fourth level). The fourth detection signal SS4 may be transmitted to the second controller 360 .

The receiver 350 may receive the fourth activation signal EN4 from the second controller 360 . In a second state (ie, communication state), the fourth activation signal EN4 is an active state (eg, a voltage of a fifth level), and in a first state (ie, a sensing state), the fourth activation signal EN4 may be in an inactive state (eg, a sixth level voltage).

In response to the fourth activation signal EN4 becoming an active state, the receiver 350 may enter an active mode. In response to the fourth activation signal EN4 becoming inactive, the receiver 350 may enter a power saving mode.

In the second state (ie, the communication state), the fourth activation signal EN4 may be in an active state. That is, in the second state (ie, communication state), the receiver 350 may enter the active mode. In the first state (ie, the sensing state), the fourth activation signal EN4 may be in an inactive state. That is, in the first state (ie, the sensing state), the receiver 350 may enter the power saving mode.

In the second state (ie, communication state), the receiver 350 may receive the third data signal DT3 from the second electrode 310 through the second switch 330 and the second matching circuit 320 . have. The receiver 350 may generate the fourth data signal DT4 by demodulating the third data signal DT3 . The fourth data signal DT4 may be output to the second controller 360 or may be provided to the user through an interface device configured to provide information to the user, such as a display device or a speaker.

When the idle time during which the third data signal DT3 (or the fourth data signal DT4 ) is not received by the receiver 350 is longer than the first threshold time, according to the control of the second controller 360 , the second The switch 330 may enter a first state (ie, a sensing state), and the receiver 350 may enter a power saving mode. In power saving mode, receiver 350 may consume less power than is consumed in active mode.

The second controller 360 may control operations of the second human body communication device 300 . The second controller 360 enters a second state (communication state) in response to the human body 100 making contact with the first electrode 210 in the first state (sensing state) to transmit the fourth data signal DT4 Then, when the idle time is longer than the first threshold time, the second human body communication device 300 may be controlled to return to the first state (sensing state).

FIG. 2 is a flowchart illustrating an operation method of the first human body communication device 200 of FIG. 1 . 1 and 2 , in step S110 , the first human body communication device 200 may enter a first state (sensing state). In response to entering the first state (sensing state), in step S120 , the first human body communication device 200 electrically connects the first detector 240 to the first electrode 210 , and the first detector ( 240) to an active mode, and deactivate the transmitter 250 to a sleep mode.

In step S130 , the first human body communication device 200 may determine whether a contact with the human body 100 is detected by the first electrode 210 . For example, based on the envelope of the first detection signal SS1 sensed by the first detector 240 , the first detector 240 may determine whether a contact with the human body 100 is detected.

If the human body contact is not detected, the first human body communication device 200 may maintain a sensing state. When the human body contact is detected, in step S140 , the first human body communication device 200 may enter a second state (communication state). In response to entering the second state (communication state), in step S150 , the first human body communication device 200 electrically connects the transmitter 250 to the first electrode 210 , and the first detector 240 . may be deactivated to the power saving mode, and the transmitter 250 may be activated to the active mode.

In operation S160 , the first human body communication device 200 may output the second data signal DT2 to the first electrode 210 . When the data transmission is completed, the first human body communication device 200 may re-enter the first state (sensing state) in step S110.

That is, in response to detecting the contact of the human body 100 in the first state (sensing state), the first human body communication device 200 enters the second state (communication state) to transmit the second data signal DT2 transmit, and return to a first state (sensing state).

For example, the first detector 240 may perform sensing using the first detection signal SS1 having a frequency different from that of the transmitter 250 . In order to improve the quality of communication, the first matching circuit 220 may be configured to provide impedance matching to the transmitter 250 . The first detector 240 reduces the effect of the first matching circuit 220 on the first detector 240 by using the first detection signal SS1 having a frequency lower than the frequency of the transmitter 240 (or can be minimized).

3 is a flowchart illustrating an operation method of the second human body communication device 300 of FIG. 1 . 1 and 3 , steps S210 to S240 are shown in FIG. 2 , except that the components of the first body communication device 200 are replaced with corresponding components of the second body communication device 300 . Steps S110 to S140 are performed in the same way. Accordingly, overlapping descriptions are omitted.

In response to entering the second state (communication state), in step S250 , the second human body communication device 300 electrically connects the receiver 350 to the second electrode 310 , and the second detector 340 . may be deactivated to the power saving mode, and the receiver 350 may be activated to the active mode.

In operation S260 , the second human body communication device 300 may wait for reception of the fourth data signal DT4 . In operation S270 , the second human body communication device 300 may determine whether the idle time during which the fourth data signal DT4 (or the third data signal DT3) is not received is longer than the first threshold time. If the idle time is longer than the first threshold time, the second human body communication device 300 may re-enter the first state (sensing state) in step S210 .

That is, in response to detecting the contact of the human body 100 in the first state (sensing state), the second human body communication device 300 enters the second state (communication state) and Waiting for reception, and returning to the first state (sensing state) when the idle time is longer than the first threshold time.

If the fourth data signal DT4 is not continuously received while the second human body communication device 300 is in contact with the human body 100 , the second human body communication device 300 sets the first state (sensing state) and the second state. It is possible to periodically transition between two states (communication states).

For example, the second detector 340 may perform sensing using the third detection signal SS3 having a frequency different from that of the receiver 350 . In order to improve the quality of communication, the second matching circuit 320 may be configured to provide impedance matching to the receiver 350 . The second detector 340 uses the third detection signal SS3 having a frequency lower than the frequency of the receiver 340 , thereby reducing the effect of the second matching circuit 320 on the second detector 340 (or can be minimized).

4 shows a human body communication system 20 according to a second embodiment of the present invention. Referring to FIG. 4 , the human body communication system 20 may include a human body 100 and third body communication devices 400 . The human body may be a medium for communication of the third human body communication devices 400 . Unlike the first body communication device 200 and the second body communication device 300 of FIG. 1 , the third body communication devices 400 may perform two-way communication including transmission and reception.

Each of the third human body communication devices 400 includes a third electrode 410 , a third matching circuit 420 , a third switch 430 , a third detector 440 , a transceiver 450 , and a third controller. (460). The third electrode 410 may be exposed to the outside of each of the third human body communication devices 400 to contact the human body 100 . The third electrode 410 may be a single electrode that enables each of the third human body communication devices 400 to communicate with each other.

The third matching circuit 420 may provide impedance matching. The third matching circuit 420 may have the same configuration and the same operation as the first matching circuit 220 described above.

The third switch 430 may be connected to the third matching circuit 420 . The third switch 430 may operate in response to the control of the third controller 460 . The third switch 430 may select one of the third detector 440 and the transceiver 450 , and electrically connect the selected component to the third matching circuit 420 .

For example, the third switch 430 may electrically connect the third detector 440 to the third matching circuit 420 in the first state (ie, the sensing state). The third switch 430 may electrically connect the transceiver 450 to the third matching circuit 420 in the second state (ie, the communication state). The second state may be a communication state.

The third detector 440 may receive the fifth activation signal EN5 from the third controller 460 . In the first state (ie, the sensing state), the fifth activation signal EN5 is in the active state (eg, the voltage of the first level), and in the second state (ie, the communication state), the fifth activation signal EN5 may be in an inactive state (eg, a second level of voltage).

In response to the fifth activation signal EN5 becoming an active state, the third detector 440 may enter an active mode. In response to the fifth activation signal EN5 becoming inactive, the third detector 440 may enter a power saving mode.

In the first state (ie, the sensing state), the fifth activation signal EN5 may be in an active state. That is, in the first state (ie, the sensing state), the third detector 440 may enter the active mode. In the second state (ie, the communication state), the fifth activation signal EN5 may be in an inactive state. That is, in the second state (ie, the communication state), the third detector 440 may enter the power saving mode.

In the first state (ie, the sensing state), the third detector 440 outputs the fifth sensing signal SS5 to the third electrode 410 through the third switch 430 and the third matching circuit 420 . can do. As described with reference to the first detector 240 , when it is determined that the human body 100 is in contact with the third electrode 410 , the third detector 440 turns the sixth detection signal SS6 into an inactive state. It can adjust from (eg, a voltage of a third level) to an active state (eg, a voltage of a fourth level). The sixth detection signal SS6 may be transmitted to the third controller 460 .

The transceiver 450 may receive the sixth activation signal EN6 from the third controller 460 . In the second state (ie, communication state), the sixth activation signal EN6 is an active state (eg, a fifth level of voltage), and in the first state (ie, a sensing state), the sixth activation signal EN6 may be in an inactive state (eg, a sixth level voltage).

In response to the sixth activation signal EN6 becoming an active state, the transceiver 450 may enter an active mode. In response to the sixth activation signal EN6 becoming inactive, the transceiver 450 may enter a power saving mode.

In the second state (ie, the communication state), the sixth activation signal EN6 may be in an active state. That is, in the second state (ie, communication state), the transceiver 450 may enter the active mode. In the first state (ie, the sensing state), the sixth activation signal EN6 may be in an inactive state. That is, in the first state (ie, the sensing state), the transceiver 450 may enter the power saving mode.

In the second state (ie, communication state), the transceiver 450 may perform transmission and reception. During transmission, the transceiver 450 may receive the fifth data signal DT5 from the third controller 460 . The transceiver 450 may generate the sixth data signal DT6 by demodulating the fifth data signal DT5 . The transceiver 450 may output the sixth data signal DT6 to the third electrode 410 through the third switch 430 and the third matching circuit 420 .

Upon reception, the transceiver 450 may receive the sixth data signal DT6 from the third electrode 410 through the third switch 430 and the third matching circuit 420 . The transceiver 450 may generate the fifth data signal DT5 by demodulating the sixth data signal DT6 . The fifth data signal DT5 may be output to the third controller 460 or provided to the user through an interface device configured to provide information to the user, such as a display device or a speaker.

When the idle time during which the sixth data signal DT6 (or the fifth data signal DT5) is not transmitted or received in the transceiver 450 is longer than the second threshold time, according to the control of the third controller 460, The third switch 430 may enter a first state (ie, a sensing state), and the transceiver 450 may enter a power saving mode. In the power saving mode, the transceiver 450 may consume less power than the power consumed in the active mode.

The third controller 460 may control respective operations of the third human body communication devices 400 . The third controller 460 enters into a second state (communication state) in response to the human body 100 contacting the first electrode 210 in the first state (sensing state) to transmit or receive, and When the idle time is longer than the second threshold time, each of the third human body communication devices 400 may be controlled to return to the first state (sensing state).

5 is a flowchart illustrating an operation method of the third human body communication devices 400 of FIG. 4 . 4 and 5 , steps S310 to S340 are the same as in FIG. 4 and 5 , except that the components of the first human body communication device 200 are replaced with corresponding components of the third body communication devices 400 . Steps S110 to S140 of 2 are performed in the same manner. Accordingly, overlapping descriptions are omitted.

In response to entering the second state (communication state), in step S350 , the third human body communication devices 400 electrically connect the transceiver 450 to the third electrode 410 , and the third detector 440 . ) to the power saving mode, and activating the transceiver 450 to the active mode.

In operation S360 , the third human body communication devices 400 may transmit or receive the sixth data signal DT6 . In step S370, the third human body communication devices 400 may determine whether the idle time during which the sixth data signal DT6 (or the fifth data signal DT5) is not transmitted or received becomes longer than the second threshold time. have. If the idle time is longer than the second threshold time, the third human body communication devices 400 may re-enter the first state (sensing state) in step S310 .

That is, in response to detecting the contact of the human body 100 in the first state (sensing state), the third human body communication devices 400 enter the second state (communication state) to obtain the sixth data signal DT6 . is transmitted or received, and when the idle time is longer than the second threshold time, the second state (sensing state) may be returned.

If the sixth data signal DT6 (or the fifth data signal DT5) is not continuously transmitted or received while the third human body communication devices 400 are in contact with the human body 100 , the third human body communication device The devices 400 may periodically transition between a first state (sensing state) and a second state (communication state).

For example, the third detector 440 may perform sensing using a fifth sensing signal SS5 having a frequency different from that of the transceiver 450 . In order to improve the quality of communication, the third matching circuit 420 may be configured to provide impedance matching to the transceiver 450 . The third detector 440 uses the fifth detection signal SS5 having a frequency lower than the frequency of the transceiver 440 , thereby reducing the effect of the third matching circuit 420 on the third detector 440 (or can be minimized).

In the above-described embodiments, components according to the technical idea of the present invention have been described using terms such as first, second, third, and the like. However, terms such as first, second, third, etc. are used to distinguish the elements from each other, and do not limit the present invention. For example, terms such as first, second, third, etc. do not imply an order or any form of numerical meaning.

In the above-described embodiments, components according to embodiments of the present invention have been referred to by using blocks. Blocks include various hardware devices such as IC (Integrated Circuit), ASIC (Application Specific IC), FPGA (Field Programmable Gate Array), CPLD (Complex Programmable Logic Device), etc., firmware running on the hardware devices, software such as applications, Alternatively, the hardware device and software may be implemented in a combined form. In addition, the blocks may include circuits composed of semiconductor elements in the IC or circuits registered as IP (Intellectual Property).

The above are specific embodiments for carrying out the present invention. The present invention will include not only the above-described embodiments, but also simple design changes or easily changeable embodiments. In addition, the present invention will include techniques that can be easily modified and implemented using the embodiments. Accordingly, the scope of the present invention should not be limited to the above-described embodiments and should be defined by the claims and equivalents of the claims of the present invention as well as the claims to be described later.

10: human body communication system
100: human body
200: first human body communication device
210: first electrode
220: first matching circuit
230: first switch
240: first detector
250: transmitter
260: first controller
300: second human body communication device
310: second electrode
320: second matching circuit
330: second switch
340: second sensor
350: receiver
360: second controller

Claims (13)

electrode;
a matching circuit coupled to the electrode and configured to provide impedance matching;
a switch configured to provide a first path electrically coupled with the matching circuit in a first state, and a second path electrically coupled with the matching circuit in a second state;
In the first state, connected to the matching circuit through the first path of the switch, outputting a first sensing signal to the matching circuit through the switch, and in response to the first sensing signal, the matching circuit a detector configured to output a second detection signal when the change in the magnitude of the signal generated in the is greater than or equal to a threshold;
a transmitter connected to the matching circuit through the second path of the switch in the second state, and configured to output a data signal to the matching circuit through the switch; and
and a controller configured to, in the first state, control the switch from the first state to the second state in response to receiving the second sensing signal from the detector. According to claim 1,
In the first state, the controller is further configured to control the detector in an active mode and control the transmitter in a power save mode. According to claim 1,
In the second state, the controller is further configured to control the detector to the power saving mode, and to control the transmitter to the active mode. According to claim 1,
In response to the switch entering the second state from the first state, the transmitter is further configured to output the same data as the data signal. According to claim 1,
In the second state, in response to the transmitter completing output of the data signal, the controller is further configured to control the switch from the second state to the first state. electrode;
a matching circuit coupled to the electrode and configured to provide impedance matching;
a switch configured to provide a first path electrically coupled with the matching circuit in a first state, and a second path electrically coupled with the matching circuit in a second state;
In the first state, connected to the matching circuit through the first path of the switch, outputting a first sensing signal to the matching circuit through the switch, and in response to the first sensing signal, the matching circuit a detector configured to output a second detection signal when the change in the magnitude of the signal generated in the is greater than or equal to a threshold;
a receiver coupled to the matching circuit through the second path of the switch in the second state, and configured to receive a data signal to the matching circuit through the switch; and
and a controller configured to, in the first state, control the switch from the first state to the second state in response to receiving the second sensing signal from the detector. 7. The method of claim 6,
In the first state, the controller is further configured to control the detector to an active mode and to control the receiver to a power save mode. 7. The method of claim 6,
In the second state, the controller is further configured to control the detector in a power saving mode and control the receiver in an active mode. 7. The method of claim 6,
In the second state, when the idle time during which the data signal is not received is longer than a threshold, the controller is further configured to control the switch from the second state to the first state. electrode;
a matching circuit coupled to the electrode and configured to provide impedance matching;
a switch configured to provide a first path electrically coupled with the matching circuit in a first state, and a second path electrically coupled with the matching circuit in a second state;
In the first state, connected to the matching circuit through the first path of the switch, outputting a first sensing signal to the matching circuit through the switch, and in response to the first sensing signal, the matching circuit a detector configured to output a second detection signal when the change in the magnitude of the signal generated in the is greater than or equal to a threshold;
in the second state, connected to the matching circuit through the second path of the switch, configured to output a first data signal to the matching circuit through the switch or receive a second data signal from the matching circuit becoming a transceiver; and
and a controller configured to, in the first state, control the switch from the first state to the second state in response to receiving the second sensing signal from the detector. 11. The method of claim 10,
In the first state, the controller is further configured to control the sensor in an active mode and control the transceiver in a power saving mode. 11. The method of claim 10,
In the second state, the controller is further configured to control the detector in a power saving mode and control the transceiver in an active mode. 11. The method of claim 10,
In the second state, when the idle time of not outputting the first data signal and not receiving the second data signal is longer than a threshold, the controller controls the switch from the second state to the first state a human body communication device further configured to:

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