JP2020067693A - Information transmission device and program - Google Patents

Abstract

To achieve both of: transmitting information of a transmission object without depending on visual sensation or hearing sensation; and transmitting the information intuitively.SOLUTION: An information transmission device includes an information acquisition unit, a waveform generation unit, and a stimulation electrode. The information acquisition unit acquires information on a transmission object. The waveform generation unit generates a stimulation waveform of a prescribed periodic pattern on the basis of a physiological phenomenon of a living body in response to information acquisition of the information acquisition unit. The stimulation electrode applies stimulation current to a skin of a wearer on the basis of the stimulation waveform generated by the waveform generation unit.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an information transmission device and a program.

  BACKGROUND ART Conventionally, a device that transmits information by applying a specific pattern of electrical stimulation according to the content of information to be transmitted to the skin has been disclosed (for example, Patent Document 1).

JP, 2005-91622, A

  However, according to the conventional technique as described in Patent Document 1 described above, considerable training is necessary and given in order to understand the correspondence between the pattern of electrical stimulation and the information of the transmission target. There was a problem that it was necessary to concentrate consciousness on the electrical stimulation in order to read the content of information from the electrical stimulation. That is, the conventional technology has a problem in that when the information to be transmitted is transmitted without visual or auditory information, the information cannot be transmitted intuitively.

  One aspect of the present invention is to generate an stimulus waveform having a predetermined periodic pattern according to a physiological phenomenon of a living body in response to an information acquisition unit that acquires information to be transmitted and the information acquisition unit that acquires the information. And a stimulation electrode that applies a stimulation current based on the stimulation waveform generated by the waveform generation section to the skin of the wearer.

  Further, according to one aspect of the present invention, in the above-described information transmission device, the stimulation waveform is a waveform corresponding to a pulsation.

  Further, according to one aspect of the present invention, in the above information transmission device, the stimulation waveform is a waveform corresponding to an acceleration pulse wave waveform.

  Further, according to an aspect of the present invention, in the above-described information transmission device, the waveform generation unit is based on a degree of risk to a wearer indicated by the information acquired by the information acquisition unit, the cycle of the stimulation waveform. The stimulus waveform is generated in a cycle.

  Further, according to one aspect of the present invention, in the above-described information transmission device, the waveform generation unit is based on the degree of risk to the wearer indicated by the information acquired by the information acquisition unit, the intensity of the stimulation waveform. The intensity is generated to generate the stimulation waveform.

  Further, according to one aspect of the present invention, in the above-described information transmission device, a biometric information acquisition unit that acquires biometric information of the wearer is further provided, and the information acquisition unit includes the biometric information acquired by the biometric information acquisition unit. , As the information.

  Further, according to an aspect of the present invention, in the above-described information transmission device, the biological information is pulsation information indicating a pulsation of a wearer, and the waveform generation unit is acquired by the biological information acquisition unit. The stimulus waveform having a cycle corresponding to the wearer's pulsation cycle indicated by the pulsation information is generated.

  Further, according to one aspect of the present invention, in the above-described information transmission device, the information acquisition unit acquires, as the information, ambient condition information that is output by another device and indicates the ambient condition of the wearer.

  Further, according to one aspect of the present invention, in the information transmission device described above, an impedance measuring unit that measures the impedance of the skin of the wearer is further provided, and the waveform generating unit, the intensity of the stimulation waveform, the impedance measuring unit. The stimulation waveform is generated with an intensity according to the impedance to be measured.

  According to one aspect of the present invention, a computer acquires an information acquisition step of acquiring information to be transmitted, and a predetermined periodic pattern according to a physiological phenomenon of a living body in response to the information being acquired in the information acquisition step. A program for executing a waveform generation step of generating a stimulation waveform, and a stimulation current output step of outputting a stimulation current based on the stimulation waveform generated in the waveform generation step from a stimulation electrode that gives to the skin of the wearer. .

  According to the present invention, it is possible to provide an information transmission device and a program capable of both transmitting information to be transmitted without depending on sight or hearing and intuitively transmitting information.

It is a figure which shows an example of the external appearance structure of the information transmission apparatus which concerns on 1st Embodiment. It is a figure which shows an example of the external appearance structure of the stimulation electrode which concerns on this embodiment. It is a figure which shows an example of a functional structure of the information transmission apparatus which concerns on this embodiment. It is a figure which shows an example of the stimulation pattern memorize | stored in the memory | storage part which concerns on this embodiment. It is a figure which shows an example of operation | movement of the information transmission apparatus which concerns on this embodiment. It is a figure which shows an example of the stimulation waveform which the waveform generation part which concerns on this embodiment produces | generates. It is a figure which shows an example of an acceleration pulse wave waveform. It is a figure which shows an example of a functional structure of the information transmission apparatus which concerns on 2nd Embodiment. It is a figure which shows an example of a functional structure of the information transmission apparatus which concerns on 3rd Embodiment.

[First Embodiment]
An embodiment according to the present invention will be described below with reference to the drawings.
FIG. 1 is a diagram showing an example of an external configuration of an information transmission device 1 according to this embodiment.

As shown in FIG. 1, the information transmission device 1 is configured as, for example, a wristwatch-type device that is wrapped around a wrist. The information transmission device 1 includes a display unit DP, an operation unit TP, an environment sensor SS, a biological sensor MS, a band WB, a stimulation electrode E, and a control unit 10.
In addition, the illustrated shape is an example, and the information transmission device 1 may be configured in other shapes.

The display unit DP includes a liquid crystal display or the like and displays information such as characters and images.
The operation unit TP includes a touch panel and the like, and detects an operation performed by the wearer U.
The environment sensor SS detects the situation of the environment around the information transmission device 1. The ambient environment to be detected includes, for example, temperature, humidity, solar radiation amount, precipitation amount, illuminance, and the like. The environment sensor SS outputs the detected result to the control unit 10 as ambient condition information SR.
The biometric sensor MS detects biometric information of the wearer U. The biological information to be detected includes, for example, body temperature (for example, skin temperature, core body temperature), blood pressure, sweat rate, heart rate, pulse wave, brain wave, myoelectric potential, and the like. The biometric sensor MS outputs the detected result as biometric information BM to the control unit 10.
The band WB is wound around the wrist of the wearer U to bring the stimulation electrode E into contact with the wrist of the wearer U.

FIG. 2 is a diagram showing an example of an external configuration of the stimulation electrode E according to this embodiment. The stimulation electrode E includes a positive electrode E1 and a negative electrode E2. The stimulation electrode E uses the positive electrode E1 and the negative electrode E2 as a stimulation electrode pair to apply a stimulation current SC to the skin of the wearer U of the information transmission device 1.
The information transmission device 1 may include a plurality of stimulation electrodes E as shown in FIG.

FIG. 3 is a diagram showing an example of a functional configuration of the information transmission device 1 according to the present embodiment. The information transmission device 1 includes a storage unit MR in addition to the control unit 10 and the stimulation electrode E described above. Information to be transmitted D is supplied from the information supply device 20 to the information transmission device 1. The information supply device 20 is, for example, a server device of a weather information service company. The information supply device 20 supplies various kinds of weather information as the transmission target information D. In this example, the transmission target information D includes temperature, humidity, solar radiation, precipitation, and the like at the location of the information transmission device 1. Each value indicated by the transmission target information D may be a current or past actual measurement value or a future prediction value.
In this example, the information supply device 20 determines that the weather condition of the location of the information transmission device 1 is a dangerous condition for the wearer U of the information transmission device 1 (for example, the wearer U suffers from heat stroke). When the temperature is abnormally high and high enough to cause the disease), the transmission target information D is output.
The information supply device 20 may be a device that supplies disaster information such as earthquakes, typhoons, tsunamis, floods, and eruptions. For example, when a member of a rescue team such as a rescue team wears the information transmitting device 1, the information transmitting device 1 may cause the member to have a degree of danger around the disaster site (for example, secondary due to gas concentration, oxygen concentration, etc.). (Danger of disaster) is transmitted as the transmission target information D.

The information supply device 20 may supply information indicating the degree of danger of the wearer U by including it in the transmission target information D. For example, the information supply device 20 outputs the transmission target information D in which the danger level LV of the wearer U is shown in six levels from the risk level LV0 (zero) to the risk level LV5.
In this case, the information supply device 20 may be configured not to output the transmission target information D when the risk level LV is the risk level LV0, and output the transmission target information D indicating the risk level LV0. It may be configured. In the example described below, the information supply device 20 is configured to output the transmission target information D indicating the risk level LV0 when the risk level LV is the risk level LV0.

The control unit 10 includes an information acquisition unit 110 and a waveform generation unit 120.
The information acquisition unit 110 acquires the transmission target information D.

  In this example, the information acquisition unit 110 acquires the transmission target information D output by the information supply device 20. That is, the information acquisition unit 110 acquires, as the transmission target information D, the surrounding situation information SR indicating the surrounding situation of the wearer U, which is output by the information supply device 20 which is another device.

  The waveform generation unit 120 generates the stimulation waveform SW having a predetermined periodic pattern according to the physiological phenomenon of the living body in response to the information acquisition unit 110 acquiring the transmission target information D. For example, the predetermined periodic pattern according to the physiological phenomenon of the living body includes a pulsating periodic pattern. In this example, the waveform generation unit 120 generates the stimulation waveform SW based on the stimulation pattern P stored in the storage unit MR.

  FIG. 4 is a diagram showing an example of the stimulation pattern P stored in the storage unit MR of the present embodiment. In the storage unit MR, the stimulation level, the stimulation cycle SP, and the stimulation intensity SI are associated with each other and stored as a stimulation pattern P. The level of stimulation is a stage of stimulation corresponding to the above-described risk level LV. For example, the stimulation level “1” corresponds to the risk level LV1.

  Returning to FIG. 3, the waveform generation unit 120 acquires from the storage unit MR the stimulation pattern P corresponding to the risk level LV of the transmission target information D acquired by the information acquisition unit 110. The waveform generation unit 120 generates the stimulation waveform SW based on the acquired stimulation pattern P. The waveform generator 120 outputs the generated stimulation waveform SW to the stimulation electrode E.

  The stimulation electrode E applies a stimulation current SC based on the stimulation waveform SW generated by the waveform generation unit 120 to the skin of the wearer U.

[Operation of Information Transmission Device 1]
Next, an example of the operation of the information transmission device 1 of this embodiment will be described with reference to FIG.
FIG. 5: is a figure which shows an example of operation | movement of the information transmission apparatus 1 of this embodiment.

(Step S10) The information acquisition unit 110 acquires the transmission target information D. As described above, the transmission target information D includes information indicating the risk level LV. The information acquisition unit 110 outputs the acquired transmission target information D to the waveform generation unit 120.
(Step S20) The waveform generation unit 120 determines the risk level LV included in the transmission target information D. When the waveform generation unit 120 determines that the risk LV included in the transmission target information D is the risk LV0 (step S20; risk LV0), the process proceeds to step S30. When the waveform generation unit 120 determines that the risk level LV included in the transmission target information D is the risk level LV1 to 5 (step S20; risk level LV1 to 5), the process proceeds to step S40.

(Step S30) The waveform generation unit 120 ends the process without outputting the stimulation waveform SW to the stimulation electrode E. As a result, the stimulation current SC is not output from the stimulation electrode E.

(Step S40) The waveform generation unit 120 generates the stimulation waveform SW according to the risk level LV. As a specific example, when the risk level LV included in the transmission target information D acquired in step S10 is the risk level LV1, the waveform generation unit 120 determines that the stimulation cycle SP is “1 sec” and the stimulation intensity SI is “1.2 mA. ”Is generated. When the risk level LV is the risk level LV5, the waveform generation unit 120 generates the stimulation waveform SW having the stimulation cycle SP of “100 msec” and the stimulation intensity SI of “2.4 mA”. That is, when the degree of risk LV included in the transmission target information D is low, the waveform generation unit 120 generates the stimulation waveform SW with low stimulation, and the degree of risk LV included in the transmission target information D is high. In this case, the stimulation waveform SW with high stimulation is generated.

That is, the waveform generation unit 120 generates the stimulation waveform SW by setting the cycle of the stimulation waveform SW as the stimulation cycle SP based on the risk LV to the wearer U indicated by the transmission target information D acquired by the information acquisition unit 110. . In other words, the waveform generation unit 120 changes the stimulation cycle SP based on the risk level LV.
Further, the waveform generation unit 120 generates the stimulation waveform SW by setting the intensity of the stimulation waveform SW to the stimulation intensity SI based on the risk LV to the wearer U indicated by the transmission target information D acquired by the information acquisition unit 110. . In other words, the waveform generator 120 changes the stimulation intensity SI based on the risk level LV.

  In this example, the waveform generation unit 120 sets both the cycle and the intensity of the stimulation waveform SW based on the risk level LV, but is not limited to this. The waveform generation unit 120 may set only one of the cycle and the intensity of the stimulation waveform SW based on the risk level LV. When the risk level LV is equal to or higher than the risk level LV1 (in this example, the risk level LV1 to the risk level LV5), the waveform generation unit 120 sets the stimulation cycle SP and the stimulation intensity SI to the risk level LV. Therefore, the stimulation waveform SW may be generated with a constant value (that is, without changing according to the risk level LV).

Here, an example of the stimulation waveform SW generated by the waveform generation unit 120 will be described with reference to FIG.
FIG. 6 is a diagram showing an example of the stimulation waveform SW generated by the waveform generation unit 120 of this embodiment. The waveform generation unit 120 generates the stimulation waveform SW by setting the time interval between the stimulation waveforms SW adjacent to each other on the time axis (for example, the stimulation waveform SW1 and the stimulation waveform SW2) to a predetermined cycle (stimulation cycle SP). In this example, the waveform generation unit 120 changes the intensity stepwise by the rectangular pulse and generates the stimulation waveform SW.
Note that the above-described stimulation intensity SI is described as a value indicating the maximum value of the intensity of the rectangular pulse forming the stimulation waveform SW, but the present invention is not limited to this. For example, the stimulation intensity SI may be a value indicating an area obtained by time-integrating the intensity of a rectangular pulse forming the stimulation waveform SW.

  The temporal change in the intensity of the stimulation waveform SW generated by the waveform generation unit 120 (that is, the envelope of the stimulation waveform SW) is determined based on the acceleration pulse wave waveform APW. The acceleration pulse wave waveform APW will be described with reference to FIG. 7.

FIG. 7 is a diagram showing an example of the acceleration pulse wave waveform APW. Here, the acceleration pulse wave waveform APW is a waveform obtained by second-order differentiating the waveform of the volume pulse wave with respect to the time axis. The waveform of the volume pulse wave is obtained by, for example, a photoelectric pulse wave meter.
The stimulation waveform SW is determined based on the waveform of the portion corresponding to the acceleration pulse wave waveform APW1 in the acceleration pulse wave waveform APW shown in FIG. That is, the stimulation waveform SW is a waveform corresponding to the acceleration pulse wave waveform APW. Although the stimulation waveform SW is determined based on the waveform of the portion corresponding to APW1 in FIG. 7 as an example, the stimulation waveform SW may be determined in detail based on the waveform including a plurality of peak values of the acceleration pulse wave waveform APW. Good.

(Step S50) Returning to FIG. 5, the waveform generator 120 outputs the stimulation waveform SW generated in step S40 to the stimulation electrode E in a predetermined cycle according to the risk level LV. As a result, the stimulation electrode E outputs a stimulation current SC with a cycle and intensity corresponding to the risk LV to the skin of the wearer U.
The waveform generation unit 120 ends the process after repeatedly outputting the stimulation waveform SW for a predetermined time or a predetermined wave number, for example.

[Summary of First Embodiment]
As described above, the information transmission device 1 stimulates the skin (eg, wrist) of the wearer U with the stimulation waveform SW having a predetermined periodic pattern according to the physiological phenomenon of the living body. According to the information transmission device 1 configured as described above, a state that is dangerous to the wearer U (for example, a state that may cause heat stroke) is transmitted regardless of the sense of sight, hearing, and fingertips. You can

Here, when the wearer U is provided with the stimulation waveform SW having a predetermined periodic pattern according to the physiological phenomenon of the living body, compared to the case where the wearer U is stimulated with another waveform that does not correspond to the physiological phenomenon of the living body. The fact that the wearer U is in danger can be more intuitively transmitted to the wearer U. As an example, a predetermined periodic pattern according to a physiological phenomenon of a living body (for example, a periodic pattern according to a heartbeat (beat)) rather than a stimulation by another waveform that does not correspond to a physiological phenomenon of a living body (for example, simple vibration) The stimulus caused by can give the wearer U the illusion that his / her own body has changed from normal times (for example, being in a tense state), and it is more intuitive that the danger is imminent. Can be transmitted to U.
That is, according to the information transmission device 1 configured as described above, the fact that the wearer U is in danger is more intuitive than the wearer U, regardless of the sense of sight, hearing, fingertips, and the like. Can be communicated to. Further, according to the information transmission device 1, since electrical stimulus is given to the wearer U, for example, the configuration of the device can be simplified as compared with the case where mechanical stimulus is given, and stimulus having relatively high strength can be easily performed. Can be given.
Therefore, according to the information transmission device 1, for example, even in a situation where it is difficult to appeal to the sense of sight or hearing such as when jogging, the information can be transmitted to the wearer U more intuitively. Further, the sense of sight, hearing, fingertips, and the like are senses that are extremely important information sources in everyday life. According to the information transmission device 1, the wearer U is not affected by these important senses. Information can be transmitted.

  Further, the information transmission device 1 of the present embodiment gives a stimulus to the wearer U by the stimulus waveform SW having a waveform corresponding to the pulsation. By giving the wearer U a waveform corresponding to the beat as the stimulus waveform SW, the wearer U recognizes the given stimulus as the beat of the wearer U himself. According to the information transmission device 1 configured as described above, it is possible to more intuitively inform the wearer U that the danger is imminent.

Further, the information transmission device 1 of the present embodiment gives a stimulus to the wearer U with the stimulation waveform SW having a waveform corresponding to the acceleration pulse wave waveform APW. Here, the acceleration pulse wave waveform APW is a waveform based on an average heartbeat of a person, for example. By giving the wearer U a waveform corresponding to the acceleration pulse wave waveform APW as the stimulation waveform SW, the wearer U recognizes that his / her pulsation has changed from the normal time. According to the information transmission device 1 configured as described above, since the illusion that the activity of the heart, which is the most important organ for life support, has changed, the wearer U feels that danger is imminent. Can be transmitted.
Further, according to the information transmission device 1, it is possible to make the illusion that the pulsation of the wearer U becomes faster before the actual pulsation of the wearer U becomes faster, so that the state of the wearer U is actually dangerous. You can suggest that you can be in a dangerous state before you reach a critical state.

  Further, the information transmission device 1 changes the stimulation cycle SP based on the risk level LV. Here, the cycle of the human pulsation becomes faster as the danger increases and the tension increases (that is, the sympathetic nerve activity increases). The information transmitting apparatus 1 can make the wearer U feel that the tension is higher than that in the case where the stimulation cycle SP is slower by advancing the stimulation cycle SP as the risk level LV is higher. According to the information transmission device 1 configured as described above, the degree of danger can be transmitted to the wearer U more intuitively.

  Further, the information transmission device 1 changes the stimulation intensity SI based on the risk level LV. Here, the strength of human pulsation increases as the danger increases and the tension increases (that is, the sympathetic nerve activity increases). By increasing the stimulation intensity SI as the risk level LV is higher, the information transmission device 1 can make the wearer U feel that the tension is higher than when the stimulation intensity SI is weak. . According to the information transmission device 1 configured as described above, the degree of danger can be transmitted to the wearer U more intuitively.

[Modification]
In the above description, the information transmission device 1 is described as outputting the stimulation current SC based on the transmission target information D supplied by the information supply device 20, but the present invention is not limited to this.
As described above, the information transmission device 1 includes the environment sensor SS. The information transmission device 1 may be configured to output the stimulation current SC based on the result detected by the environment sensor SS. For example, when the environment sensor SS detects the temperature and the humidity, the information transmission device 1 determines that the temperature and the humidity are detected by the environment sensor SS when the temperature and the humidity are abnormally high (that is, when the temperature and humidity are abnormally high). Also, the risk level LV may be determined according to the humidity and the humidity, and the stimulation current SC based on the determined risk level LV may be output. The case where the environment sensor SS detects the temperature and the humidity has been described as an example, but the present invention is not limited to this. For example, the environment sensor SS may detect either one of the temperature and the humidity, and in this case, the information transmission device 1 determines that at least one of the temperature and the humidity detected by the environment sensor SS is abnormally high. Alternatively, the risk level LV may be determined according to the temperature or humidity, and the stimulation current SC based on the determined risk level LV may be output.

[Second Embodiment]
Next, an information transmission device 1a according to the second embodiment will be described with reference to FIG. The same components and operations as those of the first embodiment described above are designated by the same reference numerals, and the description thereof will be omitted.

  FIG. 8: is a figure which shows an example of a function structure of the information transmission apparatus 1a of 2nd Embodiment. The information transmission device 1a according to the present embodiment differs from the above-described embodiments in that the biological information acquisition unit 130 is included.

The information transmission device 1a includes a biometric information acquisition unit 130.
As described above, the biometric sensor MS detects the biometric information of the wearer U. The biological information to be detected includes, for example, body temperature (for example, skin temperature, core body temperature), blood pressure, sweat rate, heart rate, pulse wave, brain wave, myoelectric potential, and the like. The biometric sensor MS outputs the detected result as biometric information BM to the control unit 10a.
The biometric information acquisition unit 130 acquires the biometric information BM of the wearer U output by the biometric sensor MS. The biometric information acquisition unit 130 outputs the acquired biometric information BM to the information acquisition unit 110a.
The information acquisition unit 110 a acquires the biometric information BM output by the biometric information acquisition unit 130 as the transmission target information D, and outputs the acquired transmission target information D (that is, the biometric information BM) to the waveform generation unit 120.
The waveform generation unit 120 generates the stimulation waveform SW based on the transmission target information D (that is, the biometric information BM) output by the information acquisition unit 110a in the same manner as the waveform generation unit 120 described above.
According to the information transmission device 1a configured as described above, information can be transmitted to the wearer U even when information cannot be acquired from another device (for example, the information supply device 20). it can.
Further, since the transmission target information D is the biometric information detected by the wearer U himself, the wearer U is compared with the case where the content of the transmission target information D is information not detected by the wearer U himself. Information can be transmitted according to the person's situation.
The biometric sensor MS and biometric information BM may be used in combination with the environment sensor SS and ambient condition information SR described above, or with the information supply device 20.

[Modification]
The biometric sensor MS may include a pulsation sensor that detects the pulsation of the wearer U. That is, the biometric information BM includes pulsation information PI indicating the pulsation of the wearer U.
In this case, the waveform generation unit 120 generates the stimulation waveform SW of the stimulation cycle SP according to the pulsation cycle of the wearer U indicated by the pulsation information PI acquired by the biological information acquisition unit 130.
According to the information transmission device 1a configured as described above, the stimulation current SC can be output according to the pulsation cycle and intensity of the wearer U. According to the information transmission device 1 configured as described above, the wearer U recognizes that his / her pulsation is emphasized, and thus the danger occurrence can be more intuitively transmitted to the wearer U. it can.

[Third Embodiment]
Next, an information transmission device 1b according to the third embodiment will be described with reference to FIG. It should be noted that the same configurations and operations as those of the above-described embodiments are denoted by the same reference numerals, and the description thereof will be omitted.

  FIG. 9: is a figure which shows an example of a function structure of the information transmission apparatus 1b of 3rd Embodiment. The information transmission device 1b of the present embodiment differs from the above-described embodiments in that it includes an impedance sensor IS and an impedance measuring unit 140.

The impedance sensor IS detects the impedance of the skin of the wearer U. Here, the skin of the wearer U changes according to the amount of sweat of the wearer U and the like. For example, when the wearer U has a relatively large amount of sweat, the conductivity of the skin increases, and the impedance of the skin decreases. The impedance sensor IS detects, for example, the conductivity CD of the skin, and outputs the detected conductivity CD to the impedance measuring unit 140.
The impedance measuring unit 140 calculates the impedance of the skin of the wearer U based on the detection result (for example, the conductivity CD) output by the impedance sensor IS. The impedance measuring section 140 outputs the calculated impedance to the waveform generating section 120b as the impedance measurement result IP.
The waveform generation unit 120b changes the stimulation intensity SI based on the impedance of the skin of the wearer U indicated by the impedance measurement result IP. That is, the waveform generation unit 120b generates the stimulation waveform SW by setting the stimulation intensity SI of the stimulation waveform SW to the stimulation intensity SI according to the impedance measurement result IP measured by the impedance measurement unit 140.

  According to the information transmission device 1b configured as described above, it is possible to output the stimulation current SC having the stimulation intensity SI according to the state of the skin of the wearer U (for example, the amount of sweating). Here, when the wearer U has a relatively large amount of sweat and the conductivity of the skin is increased, the stimulation of the stimulation current SC output from the stimulation electrode E is smaller than that when the amount of sweat is small. It may feel strongly. According to the information transmission device 1b of the present embodiment, it is possible to provide the wearer U with a stimulus having a stable intensity regardless of the state of the skin of the wearer U.

  Although the embodiment of the present invention has been described in detail above with reference to the drawings, the specific configuration is not limited to this embodiment, and appropriate modifications may be made without departing from the spirit of the present invention. it can. Further, the configurations and operations described in the above embodiments can be arbitrarily combined without departing from the spirit of the present invention.

  Each of the above-mentioned devices has a computer inside. The process of each process of each device described above is stored in a computer-readable recording medium in the form of a program, and the above process is performed by the computer reading and executing the program. Here, the computer-readable recording medium refers to a magnetic disk, a magneto-optical disk, a CD-ROM, a DVD-ROM, a semiconductor memory, or the like. Further, the computer program may be distributed to the computer via a communication line, and the computer that receives the distribution may execute the program.

Further, the program may be for realizing a part of the functions described above.
Further, it may be a so-called difference file (difference program) that can realize the above-mentioned functions in combination with a program already recorded in the computer system.

  1, 1a, 1b ... Information transmission device, 10, 10a, 10b ... Control unit, 110, 110a ... Information acquisition unit, 120, 120b ... Waveform generation unit, 130 ... Biological information acquisition unit, 140 ... Impedance measurement unit, 20 ... Information supply device, DP ... Display unit, TP ... Operation unit, WB ... Band, SS ... Environment sensor, MS ... Biological sensor, IS ... Impedance sensor, P ... Stimulation pattern, D ... Transmission target information, APW ... Acceleration pulse wave waveform , SC ... stimulation current, LV ... danger degree, SI ... stimulation intensity, SP ... stimulation cycle, BM ... biological information

Claims (10)

An information acquisition unit that acquires information to be transmitted,
In response to the information acquisition unit acquires the information, a waveform generation unit that generates a stimulation waveform of a predetermined periodic pattern according to the physiological phenomenon of the living body,
A stimulation electrode for applying a stimulation current based on the stimulation waveform generated by the waveform generation unit to the skin of the wearer,
An information transmission device including. The information transmission device according to claim 1, wherein the stimulation waveform is a waveform corresponding to a pulsation. The information transmission device according to claim 2, wherein the stimulation waveform is a waveform corresponding to an acceleration pulse wave waveform. The waveform generation unit,
The stimulus waveform is generated by setting the cycle of the stimulus waveform to a cycle based on the degree of danger to the wearer indicated by the information acquired by the information acquisition unit. The information transmission device described in. The waveform generation unit,
The intensity of the stimulus waveform is set to an intensity based on the degree of danger to the wearer indicated by the information acquired by the information acquisition unit, and the stimulus waveform is generated. The information transmission device described in. Further comprising a biometric information acquisition unit for acquiring biometric information of the wearer,
The information transmission device according to any one of claims 1 to 5, wherein the information acquisition unit acquires the biometric information acquired by the biometric information acquisition unit as the information. The biological information is pulsation information indicating the pulsation of the wearer,
The waveform generation unit,
The information transmission device according to claim 6, wherein the stimulus waveform having a cycle corresponding to the pulsation cycle of the wearer indicated by the pulsation information acquired by the biological information acquisition unit is generated. The information transmission device according to any one of claims 1 to 7, wherein the information acquisition unit acquires, as the information, ambient condition information indicating the ambient condition of the wearer output by another device. Further comprising an impedance measuring unit for measuring the impedance of the wearer's skin,
The waveform generation unit,
The information transmission device according to any one of claims 1 to 8, wherein the intensity of the stimulation waveform is set to an intensity corresponding to the impedance measured by the impedance measuring unit to generate the stimulation waveform. On the computer,
An information acquisition step of acquiring information to be transmitted,
In response to the information being acquired in the information acquisition step, a waveform generation step of generating a stimulation waveform of a predetermined periodic pattern according to a physiological phenomenon of a living body,
A stimulating current output step of outputting a stimulating current based on the stimulating waveform generated in the waveform generating step from a stimulating electrode that gives the wearer's skin.
A program to execute.

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