JP2004153695A - Method and device for data transmission - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a technology for reducing the power consumption within transmission standby time, and for improving transmission reliability without using transmission power control, in a data transmission technology for transmitting data using a radio wave. <P>SOLUTION: A transmission control unit performs a transmission process in every predetermined time. When the transmission process is activated, the transmission control unit decides whether or not communication environments including the residual battery power, acceleration added to a data transmission device, and an inclination angle of the data transmission device are suitable for the transmission of pulse wave data (S100 to S150). When each of the communication environments is suitable for the pulse wave data transmission, the pulse wave data and the pulse wave data stored in a memory are supplied to a data transmission unit (S160 to S180). When any one of the communication environments is not suitable for the pulse wave data transmission, a communication error is requested to be displayed on a display unit. The pulse wave data temporally stored in the transmission control unit is supplied to the memory (S190 and S200). <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a technique for transmitting data using radio waves.
[0002]
[Prior art]
Conventionally, in one-way communication in which a communication flow only flows from a slave station to a master station, if the communication environment surrounding the slave station and the master station deteriorates, the SNR (signal-to-noise ratio) at the master station decreases and the communication reliability is reduced. Sex could not be secured enough.
[0003]
On the other hand, a technology (so-called transmission power control technology) has been developed in which a slave station receives a reference signal wirelessly transmitted from the master station and controls transmission power according to the reception strength (power) of the reference signal. (For example, see Patent Document 1).
That is, since the reception strength of the reference signal changes according to the communication environment surrounding the slave station and the master station, for example, when the reception power decreases and it is estimated that the communication environment has deteriorated, the transmission power is increased. , It is possible to prevent the SNR at the master station from being too low.
[0004]
[Patent Document 1]
Japanese Patent Publication No. 5-11690 (page 2-3, FIG. 1)
[0005]
[Problems to be solved by the invention]
However, when the above-described transmission power control is used, the slave station must always wait while measuring the strength of the reference signal even in a state where data is not transmitted, and power is always consumed. I was For this reason, if the slave station is a device driven by a battery (for example, a mobile phone), there is a problem that the usage time is reduced correspondingly.
[0006]
If the slave station uses a communication system with a limited maximum transmission power, such as weak radio wave communication or specific low power communication, the transmission power should be increased even if the communication environment deteriorates. Therefore, such transmission power control cannot be applied.
[0007]
In order to solve the above-mentioned problems, the present invention provides a data transmission technique for transmitting data using radio waves, which reduces power consumption during transmission standby and improves communication reliability without using transmission power control. The aim is to provide technology that improves
[0008]
[Means for Solving the Problems]
In the data transmission method according to claim 1, which has been made to achieve the above object, in transmitting data using radio waves, it is determined at a preset timing whether or not a communication environment is suitable for data transmission. If it is determined to be suitable, the data is transmitted.If it is determined to be inappropriate, the data is stored. If it is determined to be suitable at the next timing, the stored data is transmitted. I do.
[0009]
According to such a data transmission method, it is determined whether or not the communication environment is suitable for data transmission only at a preset timing, so that a reference signal is always received from a receiving device as in a conventional device. There is no need to wait while measuring the reception strength. That is, it is possible to reduce the power consumption during the transmission standby. In addition, data is transmitted only when it is determined that the communication environment is suitable for data transmission (that is, when it is estimated that the SNR of the signal received by the receiving device is sufficiently ensured). Thus, data can be reliably transmitted to the receiving device without using transmission power control.
[0010]
As described above, according to the present invention, in a data transmission technique for transmitting data using radio waves, it is possible to reduce power consumption during a transmission standby state and improve communication reliability without using transmission power control.
The “preset timing” may be a periodic timing or a timing at which data to be transmitted exists.
[0011]
Next, in the data transmission device according to the second aspect, when transmitting data using radio waves, the transmission control means sets in advance whether or not the communication environment detected by the environment detection means is suitable for data transmission. At a predetermined timing, and when it is determined that the data is appropriate, the data is transmitted to a transmitting unit that transmits data using radio waves, and when it is determined that the data is inappropriate, a storage unit that stores the data. The data stored in the storage unit is transmitted to the transmission unit when it is determined that the data is suitable at the next and subsequent timings.
[0012]
That is, the present invention is an apparatus that realizes the invention described in claim 1, and can obtain the same effect as the invention described in claim 1.
The transmitting means is configured to store a plurality of data having the same transmission destination in the same packet and transmit the same when a plurality of data are supplied from the transmission control means. It is desirable to have been.
[0013]
If the transmission means is set in this way, for example, when a plurality of data are supplied from the transmission control means, a packet is generated for each data, even though the transmission destination of these data is the same, Since transmission is not performed by the number of data, the number of transmissions when transmitting a plurality of data having the same destination can be reduced. Also, according to the present invention, when a plurality of data having the same destination is transmitted for each data, the address indicating the destination is duplicated with another packet, but according to the present invention, duplicate information is transmitted. , The time required for transmission can be reduced. As described above, according to the present invention, it is possible to reduce the power required when transmitting a plurality of data having the same destination.
[0014]
It is preferable that the data transmitting apparatus includes a notifying unit that notifies the user that the transmission control unit determines that the communication environment is not suitable for data transmission.
With the data transmission device configured in this manner, the user can confirm that the communication environment is unsuitable for data transmission, and remove the cause to make the communication environment suitable for data transmission. can do.
[0015]
Here, as set forth in claim 5, for example, the environment detection means includes metal detection means for detecting a metal object existing within a preset range, and the transmission control means, wherein the metal detection means is a metal object. May be set so as to determine that the communication environment is not suitable for data transmission when detecting is detected.
[0016]
According to such a data transmission device, a power loss occurs in radio waves transmitted from the data transmission device around the data transmission device. It is possible to prevent data from being transmitted.
Further, for example, the environment detecting means includes an acceleration detecting means for detecting an acceleration applied to the data transmitting device, and the transmission controlling means has a preset acceleration detected by the acceleration detecting means. If the acceleration value is larger than the acceleration value, the communication environment may be determined to be inappropriate for data transmission.
[0017]
According to such a data transmission device, data can be transmitted normally by setting, as an acceleration value, an acceleration at which electrical connection between electronic components constituting the data transmission device becomes unstable. It is possible to prevent data from being transmitted in spite of the fact that difficult acceleration is applied to the data transmission device.
[0018]
Further, for example, the environment detecting means includes a reflected power detecting means for detecting a power of a reflected wave obtained by reflecting a radio wave transmitted from the data transmitting device to an external object, and the communication means. The control means may be set to determine that the communication environment is not suitable for data transmission when the power detected by the reflected power detection means is larger than a preset power value.
[0019]
According to such a data transmission device, for example, by setting the power value obtained by subtracting the minimum power necessary for reliably transmitting data from the power at the time of transmission of a radio wave as the power value, It is possible to prevent data from being transmitted in the traveling direction despite the presence of an obstacle that causes a reflection that hinders the reliable transmission of data.
[0020]
When the transmitting means is configured to transmit a radio wave using an antenna having directivity, for example, the environment detecting means detects the attitude of the antenna. And an attitude detecting means for outputting a parameter indicating the attitude of the antenna. The transmission control means, when the value of the parameter output from the attitude detecting means is not within a preset allowable range, determines that the communication environment It is desirable that the setting is made so as to be determined to be inappropriate for transmission.
[0021]
According to such a data transmission device, if an allowable range, for example, a parameter value range indicating a range of an attitude of an antenna that can efficiently propagate a radio wave is set, the antenna position can efficiently propagate a radio wave. It is possible to prevent data from being transmitted in a difficult posture.
[0022]
In a case where the receiving device that receives the data transmitted from the data transmitting device is configured to emit light, the environment detecting means may include a light detecting device that detects the light. It is preferable that the communication control means be provided with a detection means, and be set so as to determine that the communication environment is unsuitable for data transmission when the light detection means does not detect light.
[0023]
According to such a data transmitting apparatus, it is possible to prevent data from being transmitted despite an obstacle existing between the data transmitting apparatus and the receiving apparatus.
Further, when the data transmitting device is driven by a battery, the environment detecting means includes power detecting means for detecting the remaining power of the battery, and the communication control means includes the power detecting means. When the remaining power detected by the means is smaller than a preset power value, it is preferable that the communication environment is determined to be unsuitable for data transmission.
[0024]
According to such a data transmission device, for example, by setting the minimum power required to reliably transmit data to the reception device as the power value, the remaining power of the battery ensures transmission of the data. , It is possible to prevent data from being transmitted in spite of being insufficient.
[0025]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[First Embodiment]
First, FIG. 1 is a functional block diagram illustrating an internal configuration of the data transmission device 1 according to the present embodiment. The data transmission device 1 of the present embodiment is used by being worn on a user's arm or the like, detects a user's pulse wave, and converts the pulse wave data by a weak radio wave having a transmission power equal to or less than a radio law standard. This is transmitted to an analysis system 3 (see FIG. 3) for analyzing pulse wave data. However, the analysis system 3 is always on standby so as to receive the pulse wave data from the data transmission device 1.
[0026]
As shown in FIG. 1, the data transmission device 1 includes an acceleration sensor 11 that detects acceleration applied to the data transmission device 1, an inclination sensor 12 that detects an inclination (posture) of the data transmission device 1, and a data transmission device A power detection unit 13 that detects remaining power of a battery that supplies power to each unit of the device 1, a pulse wave sensor 14 that detects a user's pulse wave and generates pulse wave data, a power detection unit 11 and an acceleration sensor 12 And a transmission control unit 15 for determining a supply destination of the pulse wave data based on the detection result, and accumulating the pulse wave data supplied from the transmission control unit 15. In response to a request from the transmission control unit 15, the nonvolatile memory 16 that supplies the stored pulse wave data to the transmission control unit 15, and the pulse wave data supplied from the transmission control unit 15 A data transmission unit 17 that stores the data in a packet and superimposes it on a radio wave having a transmission power equal to or less than the radio law standard, and a display unit 18 that performs a warning display or the like according to a request from the communication control unit 15 I have.
[0027]
Here, the data transmission unit 17 is set to generate and transmit a packet in which the ID or address of the analysis system 3 is added to the plurality of pulse wave data supplied from the transmission control unit 15. However, the data transmission unit 17 is set to store a plurality of pulse wave data in the same packet. The transmitting antenna 171 provided in the data transmitting unit 17 has an axial shape and emits a radio wave in a direction perpendicular to the axial direction of the transmitting antenna 171 (that is, the transmitting antenna 171 is , And has directivity in a direction perpendicular to the axial direction of the transmission antenna 171.) The transmission antenna 171 is fixed to the housing of the data transmission device 1.
[0028]
The acceleration sensor 11 and the inclination sensor 12 output voltage signals according to the magnitude of the acceleration applied to the data transmission device 1 and the magnitude of the inclination angle (inclination angle) of the data transmission device 1, respectively. Have been. Note that the tilt sensor 12 is installed so as to detect the tilt of the data transmitting device 1 as 0 degree when the axial direction of the transmitting antenna 171 is along the direction of gravity.
[0029]
The power detection unit 13 detects the voltage of the battery, calculates the remaining power of the battery based on the detected voltage and the internal impedance of the battery, and outputs the calculated remaining power as a remaining power value.
In addition, the pulse wave sensor 14 is configured to sample the user's pulse wave every predetermined time (0.05 seconds in this embodiment) and output the pulse wave data of about 10 bits.
[0030]
Then, the transmission control unit 15 temporarily stores (buffers) the pulse wave data supplied from the pulse wave sensor 14, and performs the following transmission processing at a predetermined time interval (10 seconds in the present embodiment). , The pulse wave data temporarily stored is set to be output.
[0031]
However, the transmission control unit 15 has a limit acceleration value G as a reference value for determining detection results from the acceleration sensor 11, the inclination sensor 12, and the power detection unit 13. ₁ And the limit angle θ ₁ , Required power value P ₁ Is set. For example, the limit acceleration value G ₁ Is set to an acceleration at which the electrical connection between the electronic components constituting the data transmission device 1 becomes unstable. Also, the limit angle θ ₁ Is set to a limit value of the inclination angle of the data transmission device 1 (that is, also corresponds to the inclination angle of the transmission antenna 171) that can reliably transmit the radio wave to the analysis system 3. And the required power value P ₁ Is set to the minimum power required to reliably transmit data to the analysis system 3.
[0032]
Hereinafter, the transmission process performed by the transmission control unit 15 will be described with reference to the flowchart illustrated in FIG.
As shown in FIG. 2, when the present process is started, the transmission control unit 15 first makes a display reset request to the display unit 18 (S100), and then transmits the remaining power supplied from the power detection unit 13. Power value is required power value P ₁ It is determined whether or not the remaining power value is larger than the required power value P (S110). ₁ If it is larger, the acceleration applied to the data transmission device 1 is calculated based on the voltage signal from the acceleration sensor 11 (S120). Then, the calculated acceleration is the limit acceleration value G ₁ It is determined whether the calculated acceleration is smaller than the limit acceleration value G (S130). ₁ If it is smaller, the inclination angle of the data transmission device 1 is calculated based on the voltage signal from the inclination sensor 12 (S140).
[0033]
When the calculation of the inclination angle ends, the transmission control unit 15 sets the inclination angle to the limit angle θ. ₁ It is determined whether or not the inclination angle is smaller than the limit angle θ (S150). ₁ If it is smaller, it is confirmed whether or not pulse wave data is stored in the memory 16 (S160). Here, when it is confirmed that the pulse wave data is stored in the memory 16, the pulse wave data stored in the memory 16 is supplied to the data transmitting unit 17 (S170), and then the transmission control unit 15 is operated. The pulse wave data temporarily stored in is supplied to the data transmission unit 17 (S180), and this processing is ended. On the other hand, if it is confirmed that the pulse wave data is not stored in the memory 16, the processing is terminated. Is transferred to S180, and this processing ends.
[0034]
In S110, S130, and S150, the remaining power value is equal to the required power value P. ₁ Is smaller than the limit acceleration value G. ₁ Or the inclination angle of the data transmission device 1 is larger than the limit angle θ. ₁ If it is larger than this, the transmission control unit 15 requests the display unit 18 to display a communication error (S190), and then supplies the temporarily stored pulse wave data to the memory 16 (S200). The process ends.
[0035]
In the data transmission device 1 configured as described above, the remaining power of the battery of the data transmission device 1, the acceleration applied to the data transmission device 1, the inclination angle of the data transmission device 1 at predetermined time intervals. Is determined to be suitable for transmission of pulse data. Then, in the determination of the communication environment, if the remaining power of the battery of the data transmission device 1 is insufficient to reliably transmit the pulse wave data to the analysis system 3, the pulse wave data is not transmitted. The data is stored in the memory 16 of the data transmission device 1. Further, even when the user using the data transmission device 1 shakes his arm vigorously or the like, the electrical connection between the electronic components constituting the data transmission device 1 becomes unstable, The pulse wave data is stored in the memory 16 of the data transmission device 1 without being transmitted. Further, as shown in FIG. 3, the pulse wave data is transmitted even when the data transmission device 1 is used at an angle so that the radio wave radiated from the transmission antenna 171 is not reliably transmitted to the analysis system 3. Instead, the data is stored in the memory 16 of the data transmission device 1.
[0036]
Therefore, according to the data transmission device 1 of the present embodiment, the determination as to whether or not the above communication environment is suitable for the transmission of the pulse wave data is made at regular time intervals. There is no need to wait while receiving a reference signal or the like from the PC and measuring the reception strength. That is, the power consumption in the transmission standby state is smaller than that of the conventional device. In addition, when it is determined that the communication environment described above is suitable for transmitting pulse wave data (that is, it is estimated that the SNR of the signal from the data transmission device 1 received by the analysis system 3 is sufficiently ensured). ), The pulse wave data can be reliably transmitted to the analysis system 3 without using transmission power control.
[0037]
That is, according to the data transmission apparatus 1 of the present embodiment, in the data transmission technique of transmitting data using radio waves, the power consumption in the transmission standby mode is reduced, and the reliability of communication is reduced without using transmission power control. Can be improved.
Further, since the data transmitting apparatus 1 stores a plurality of pulse wave data in one packet and transmits the same to the analysis system 3, the number of transmissions can be reduced. In addition, when a packet is generated for each pulse wave data such as the ID and the address of the analysis system 3, information that overlaps with other packets is not transmitted, so that the time required for transmission can be reduced. . That is, the data transmission device 1 requires less power when transmitting a plurality of pulse wave data.
[0038]
Furthermore, when pulse data cannot be transmitted, the data transmitting apparatus 1 displays a communication error on the display unit 18, so that the user can confirm that the above-described communication environment is not suitable for transmitting pulse data. Then, by removing the cause, the communication environment described above can be brought into a state suitable for transmitting the pulse wave data.
[0039]
In the present embodiment, since the pulse wave sensor 14 samples the pulse wave as pulse data of 10 bits every 0.05 seconds, even if the pulse wave data cannot be transmitted for one day, The total amount of pulse data stored in the memory 17 is only about 21 kbytes. For this reason, even if a memory element having a small storage capacity is used for the memory 17, it can cope sufficiently.
[0040]
Here, in the present embodiment, the data transmitting unit 17 corresponds to the transmitting unit of the present invention, and the memory 16 corresponds to the storing unit of the present invention. Further, the acceleration sensor 11 corresponds to the acceleration detecting means of the present invention, the tilt sensor 12 corresponds to the attitude detecting means of the present invention, and the power detecting unit 13 corresponds to the power detecting means of the present invention. The transmission control unit 15 corresponds to transmission control means of the present invention, and the display unit 18 corresponds to notification means of the present invention.
[0041]
In the present embodiment, an inclination sensor is used to detect the inclination angle of the data transmission device 1. However, another sensor such as a gyro for detecting the posture may be used instead.
[Second embodiment]
Next, a second embodiment will be described.
[0042]
First, FIG. 4 is a functional block diagram illustrating an internal configuration of the data transmission device 2 according to the present embodiment. It should be noted that the data transmission device 2 of the present embodiment includes an acceleration sensor 11, an inclination sensor 12, a data transmission unit 17, and a transmission control unit 15 in the data transmission device 1 of the first embodiment, respectively, a reflected power measurement unit 21, an eddy current It is configured by replacing the sensor group 22, the data transmission unit 27, and the transmission control unit 25.
[0043]
Therefore, here, the same components as those of the data transmission device 1 are denoted by the same reference numerals, and the description thereof will be omitted. Only different components will be described in detail.
First, similarly to the data transmission unit 17 of the first embodiment, the data transmission unit 27 not only generates and transmits a packet by receiving the supply of pulse wave data from the transmission control unit 25, but also supplies the pulse wave data. It is configured to always transmit an unmodulated radio wave even when the radio wave is not received. The transmission antenna 171 of the data transmission unit 27 is connected to the data transmission unit 27 via the directional coupler 271.
[0044]
The reflected power measuring unit 21 is connected to the line on the reflected power supply side of the directional coupler 271 (that is, the line to which the transmitting antenna 171 is not connected), and the radio wave radiated from the transmitting antenna 171 Is configured to measure the received power at the transmitting antenna 171 of a reflected wave reflected by an external object. The reflected power measuring unit 21 outputs an RSSI (Received Signal Strength Indicator) signal having a voltage corresponding to the received power of the reflected wave.
[0045]
The eddy current sensor group 22 includes a plurality of eddy current sensors, and is disposed so as to detect a metal object existing around the data transmission device 2. However, each of the eddy current sensors has a sensitivity capable of detecting a metal object existing within a preset distance (for example, 5 cm), and the voltage level changes in a binary manner according to the presence or absence of the metal object. A detection signal is output.
[0046]
Then, the transmission control unit 25 determines the supply destination of the pulse wave data supplied from the pulse wave sensor 14 based on the detection results from the reflected power measurement unit 21, the eddy current sensor 22, and the power detection unit 13. Has been. The transmission control unit 25, like the transmission control unit 15, temporarily stores the pulse wave data supplied from the pulse wave sensor 14, and performs the transmission process described below for a predetermined period of time (the first embodiment). Repeatedly every 10 seconds), the temporarily stored pulse wave data is set to be output.
[0047]
However, like the transmission control unit 15, the transmission control unit 25 has the required power value P ₁ Is set, and the allowable voltage value V of the RSSI signal is used as a reference value for determining the detection result of the reflected power measurement unit 21. ₁ Is set. Note that the allowable voltage value V ₁ Is set to the voltage of the RSSI signal corresponding to the power obtained by subtracting the minimum power required for reliably transmitting the pulse wave data to the analysis system 3 from the power at the time of transmitting the radio wave.
[0048]
Hereinafter, the transmission process performed by the transmission control unit 25 will be described with reference to the flowchart illustrated in FIG. The transmission process performed by the transmission control unit 25 differs from the transmission process performed by the transmission control unit 15 only in part of the flow of the process. Only the processing is described, and the description of the processing is omitted.
[0049]
As shown in FIG. 5, when this processing is started, the transmission control unit 25 first performs the processing of S100 and S110, and then performs data processing based on the voltage level of the detection signal from the eddy current sensor group 22. It is determined whether a metal object exists around the transmission device 2 (S115). Here, when it is confirmed that there is no metal object around the data transmission device 2, the transmission control unit 25 sets the voltage of the RSSI signal from the reflected power measurement unit 21 to the allowable voltage value V ₁ Is determined (S125), and the allowable voltage value V ₁ If it is smaller than this, the process shifts from S160 to S180, and the process ends.
[0050]
In addition to S110, in S115 and S125, it is determined that there is a metal object around the data transmission device 1, or the voltage of the RSSI signal becomes the allowable voltage value V. ₁ If it is determined that the value is larger than the threshold value, the transmission control unit 25 shifts the processing to S190 and S200, and ends the processing.
[0051]
In the data transmitting apparatus 2 configured as described above, the remaining power of the battery of the data transmitting apparatus 2 and the magnitude of the reflected wave formed by reflecting the transmitted radio wave to an external object at predetermined time intervals are set. (Power), it is determined whether or not the communication environment including the presence of a metal object around the data transmission device 2 is suitable for transmitting pulse data. Then, in the determination of the communication environment, when the remaining power of the battery of the data transmission device 2 is insufficient to reliably transmit the pulse wave data to the analysis system 3 as in the data transmission device 1 of the first embodiment. , The pulse wave data is stored in the memory 16 of the data transmission device 2 without being transmitted. In addition, for example, as shown in FIG. 6, when a user measures a pulse wave while lying on a metal bed, the data transmission device 2 is disposed near a member of the bed, and the data transmission device 2 is placed near the bed member. Even when the radio wave transmitted from 2 causes a large power loss due to the member of the bed and is attenuated, the pulse wave data is not transmitted, but is stored in the memory 16 of the data transmitting device 2. Furthermore, even if the radio wave transmitted from the data transmission device 2 is not reliably propagated to the analysis system 3 and is reflected by an external object (for example, a bed member), the pulse wave data is not transmitted without being transmitted. The data is stored in the memory 16 of the data transmission device 2.
[0052]
Therefore, according to the data transmission device 2 of the present embodiment, similarly to the data transmission device 1 of the first embodiment, in the data transmission technique of transmitting data using radio waves, power consumption during transmission standby is reduced and Thus, communication reliability can be improved without using transmission power control.
[0053]
Here, in the present embodiment, the directional coupler 271 and the reflected power measuring unit 21 correspond to a reflected power detecting unit in the present invention, and the eddy current sensor 22 corresponds to a metal object detecting unit in the present invention.
In the present embodiment, the directional coupler 271 and the reflected power measurement unit 21 are used to detect whether or not an obstacle exists between the data transmission device 2 and the analysis system 3. For example, the analysis system 3 includes a light source element such as an infrared light emitting diode, and the data transmission device 2 includes a light detection unit (for example, an infrared detection element) that detects light emitted from the analysis system 3, thereby preventing an obstacle. May be detected. When the data transmission device 2 and the analysis system 3 are configured as described above, when an obstacle exists between the data transmission device 2 and the analysis system 3, the light radiated from the analysis system 3 emits light. It is possible to detect the presence or absence of an obstacle by being blocked before reaching.
[0054]
As described above, the embodiments of the present invention have been described, but the present invention is not limited to the above embodiments, and it goes without saying that various forms can be adopted as long as they belong to the technical scope of the present invention. .
For example, in the above embodiment, the determination of the communication environment (that is, the transmission process) is performed every predetermined time, but the determination of the communication environment is performed every time pulse wave data is supplied from the pulse wave sensor 14. You may go.
[0055]
In the above embodiment, the transmission control unit 15 or 25 displays the communication error on the display unit 18 when the communication environment is not suitable for transmitting the pulse wave data. May be set to display on the display unit 18 whether the transmission is inappropriate. In this case, the user can easily know which communication environment is unsuitable for transmitting the pulse data, and can immediately start removing the cause.
[0056]
In the above-described embodiment, the display unit 18 is used to notify the user that the communication environment is not suitable for transmitting the pulse wave data. However, the user may be notified by sound using a speaker or the like.
Further, in the above embodiment, the present invention is applied to the data transmitting apparatus for transmitting the pulse wave data, but may be applied to other electronic apparatuses for transmitting data using radio waves.
[Brief description of the drawings]
FIG. 1 is a functional block diagram illustrating an internal configuration of a data transmission device 1 according to a first embodiment.
FIG. 2 is a flowchart illustrating a flow of a transmission process performed by a transmission control unit 15;
FIG. 3 is an explanatory diagram showing a situation where a transmitting antenna 171 is tilted.
FIG. 4 is a functional block diagram illustrating an internal configuration of a data transmission device 2 according to a second embodiment.
FIG. 5 is a flowchart illustrating a flow of a transmission process performed by a transmission control unit 25;
FIG. 6 is an explanatory diagram showing one usage example of the data transmission device 2.
[Explanation of symbols]
1, 2 ... data transmission device, 3 ... analysis system, 11 ... acceleration sensor, 12 ... inclination sensor, 13 ... power detection unit, 14 ... pulse wave sensor, 15, 25 ... transmission control unit, 16 ... memory, 17, 27 ... Data transmission unit, 18 display unit, 21 reflected power measurement unit, 22 eddy current sensor group, 171 transmission antenna, 271 directional coupler.

Claims (10)

In a data transmission method of transmitting data using radio waves,
Whether or not the communication environment is suitable for transmitting the data is determined at a preset timing, if determined to be suitable, the data is transmitted, and if determined to be inappropriate, A data transmission method comprising: storing the data; and transmitting the stored data when it is determined that the data is suitable at the next and subsequent timings. In a data transmission device including a transmission unit that transmits data using radio waves,
Environment detection means for detecting a communication environment;
Storage means for storing the data;
It is determined at a preset timing whether or not the communication environment detected by the environment detecting means is suitable for transmitting the data, and when it is determined that the communication environment is suitable, the transmitting means transmits the data. If it is determined that the data is inappropriate, the data is stored in the storage means, and if it is determined that the data is suitable at the next and subsequent timings, the data stored in the storage means is transmitted to the transmission means. Transmission control means for causing
A data transmission device comprising: 3. The data according to claim 2, wherein, when a plurality of data are supplied from the transmission control unit, the transmission unit stores the plurality of data having the same destination in the same packet and transmits the same packet. Transmission device. The data transmission apparatus according to claim 2, further comprising a notification unit configured to notify a user that the transmission control unit determines that the communication environment is not suitable for transmitting the data. The environment detection unit includes a metal detection unit that detects a metal object existing within a preset range,
The data according to any one of claims 2 to 4, wherein the transmission control unit determines that a communication environment is not suitable for the transmission of the data when the metal detection unit detects a metal object. Transmission device. The environment detection unit includes an acceleration detection unit that detects an acceleration applied to the data transmission device,
The transmission control unit determines that the communication environment is not suitable for the transmission of the data when the acceleration detected by the acceleration detection unit is larger than a preset acceleration value. The data transmission device according to claim 5. The environment detecting means includes reflected power detecting means for detecting the power of a reflected wave obtained by reflecting the radio wave transmitted from the data transmitting device to an external object,
3. The communication control unit, when the power detected by the reflected power detection unit is larger than a preset power value, determines that the communication environment is not suitable for transmitting the data. The data transmitting device according to claim 6. The transmitting means is configured to transmit the radio wave using an antenna having directivity,
The environment detection unit includes a posture detection unit that detects a posture of the antenna and outputs a parameter indicating the posture of the antenna,
The transmission control unit determines that the communication environment is not suitable for transmitting the data when the value of the parameter output from the posture detection unit is not within a preset allowable range. The data transmission device according to any one of claims 2 to 7. A receiving device that receives data transmitted from the data transmitting device is configured to emit light,
The environment detection means includes light detection means for detecting the light,
9. The data according to claim 2, wherein the transmission control unit determines that the communication environment is not suitable for transmitting the data when the light detection unit does not detect the light. Transmission device. The data transmission device is driven by a battery,
The environment detection means includes power detection means for detecting the remaining power of the battery, and the transmission control means, when the remaining power detected by the power detection means is smaller than a preset power value, a communication environment. 10. The data transmission device according to claim 2, wherein the data transmission device determines that the data transmission is inappropriate.

Images