JP6770677B2 - Biological information measurement system - Google Patents

Description

The present invention relates to a biological information measurement system, and more particularly to a biological information measurement system that measures a subject's physical condition based on defecation gas discharged into a bowl of a toilet bowl installed in a toilet room.

In recent years, the mortality rate from cancer has become extremely low due to the evolution of medical technology, the diagnostic technology of major diseases such as cancer, and the technological evolution of cancer treatment itself. However, it is burdensome for patients to go to the hospital to receive regular diagnoses to prevent cancer. For this reason, in reality, many patients go to the hospital after feeling unwell, and unfortunately many still get cancer. In addition, a practical device for suppressing the development of cancer has not yet been developed, and the fact is that it is not sufficient for the realization of cancer prevention.

In view of this situation, the present inventors have created a device that makes it easier to diagnose major diseases such as cancer at home without going to the hospital, and can really prevent or treat major diseases at an early stage. With a strong desire to manufacture the equipment required by the market, he has been conducting research for a long time.

So far, the applicant has collected the defecation gas that is mounted on the toilet seat of a Western-style toilet and is discharged into the bowl when the subject defecates, and based on the concentration of carbon dioxide contained in this defecation gas, it is used as a biometric information index. A device for determining the amount of defecation (see Patent Document 1) and a defecation device incorporated in the toilet seat of a flush toilet are used to suck the defecation gas that is also generated when the subject defecates, and the carbon dioxide concentration of the sucked gas is carbon dioxide. We have developed a device (see Patent Document 2) that measures the intestinal condition of a subject based on the measured carbon dioxide concentration by measuring with a gas sensor. However, these devices only estimate the current intestinal condition, and cannot easily achieve the inventor's purpose of being able to easily diagnose a major disease such as cancer and grasp its risk status. Further, a flatulence detection device (Patent Document 3) is also known in which a gas sensor is arranged so as to come into contact with air near a human excretion part and a flatulence is detected based on the peak value of the gas sensor output. In this flatulence detection device, a tube is pulled out from the excretory part in the diaper or underwear of the patient sleeping on the bed, and air is sucked by a suction pump to collect the patient's flatulence. In addition, this flatulence detector distinguishes between flatulence and urination based on the half-value range of the peak gas sensor output, allowing the doctor to see if a flatulence has occurred after appendicitis surgery and to detect when to change diapers. It is nothing more than an achievement of the inventor's purpose. On the other hand, Japanese Patent Application Laid-Open No. 2014-160049 (Patent Document 4) displays a sensor that measures methyl mercaptan gas from a component of flatulence released by a subject, and a calculation unit that calculates the concentration of methyl mercaptan gas obtained from this sensor. A portable colorectal cancer risk measuring device that has a unit and estimates the risk of developing colorectal cancer is known.

Further, Japanese Patent Application Laid-Open No. 9-43182 (Patent Document 5) describes a biological monitoring device. In this biological monitoring device, a gas sensor is attached to a T-shaped band made of cloth so that the gas sensor is arranged near the anus, and a flatulence released from the anus is detected. The signal from the gas sensor is transmitted to the processing device and stored in the memory. It is also known that the data stored in the memory is compared with the past data, and a warning is displayed on the display device when there is an abnormality such as when the difference is large.
Japanese Patent No. 3525157 (Patent Document 6) describes a method for measuring an intestinal gas component. In this method for measuring the intestinal gas component, a sampling tube is arranged on the toilet seat of the toilet bowl. When the subject turns on the main switch of the device, the suction pump operates and the gas near the anus is sucked. The index gas detector constantly measures the carbon dioxide concentration in the sucked gas, and when the measured concentration suddenly increases, the control / arithmetic processing unit recognizes that the intestinal gas has been released. When the intestinal gas is dissipated, another suction pump is activated and a part of the sucked gas is taken into the sample measuring tube. The taken-in sample is sent to the column, the gas component is separated, and it is ionized. It is also known that this amount of ionization is converted into an electric signal to measure the concentration of the gas component to be detected in the intestinal gas.
Japanese Unexamined Patent Publication No. 2014-206945 (Patent Document 7) describes a health information utilization system. In this health information utilization system, personal health information related to health management input from a terminal device is separately stored in databases of a plurality of data centers, and an analysis server device reads and analyzes the personal health information. The big data creation server device searches for personal health information under specific conditions, and creates and stores big data. The health information utilization system allows the terminal device to browse health contents based on the knowledge of a specialized field, stores and manages personal health information in multiple data centers, and automatically judges the personal health information. Or, let the terminal view the health judgment result processed by the expert. Such things are also known.

Further, in developing a device capable of diagnosing such a major disease such as cancer, it has been known in recent years that there is a correlation between the disease of colorectal cancer and the gas component in the intestine contained in flatulence and defecation. ing. Specifically, colorectal cancer patients have more methyl mercaptan gas containing a sulfur component in the gas component in the intestine than healthy people.

Patent No. 5131646 Patent No. 5019267 Japanese Patent Application Laid-Open No. 2003-90812 JP-A-2014-160049 JP-A-9-43182 Patent No. 3525157 JP-A-2014-206945

The gas component in the intestine is discharged as flatulence and defecation gas together with stool during defecation. Therefore, as published in the Nihon Keizai Shimbun on January 5, 2015, the inventors specified the flatulence discharged during defecation and methyl mercaptan gas in the defecation gas, as in Patent Document 4 above. I thought that it would be possible to detect colon cancer in the intestine by measuring the gas in the intestine, so I continued my research. However, a measuring device capable of accurately measuring only a specific gas such as this methyl mercaptan gas is very expensive and large. In addition, the amount of methyl mercaptan gas contained in the defecation gas is very small, and it is very difficult to measure because it is even smaller in the stage before cancer, so at least such an accurate gas analyzer can be used at home. The inventors faced the problem that it is not very realistic in terms of cost and size to incorporate it into a toilet device and spread it as a consumer product.

However, the inventors want to reduce the number of people who get serious illnesses such as cancer. For that purpose, I continued my research with a very strong feeling that it is necessary to make a device that can be easily purchased by general consumers and can be easily diagnosed at home, and finally found a technical solution for its realization. is there.

An object of the present invention is to prevent general consumers from becoming a serious illness such as cancer by measuring defecation gas at home, or to go to a hospital for treatment in a mild state. It is to provide a highly practical diagnostic system that can be encouraged to receive the disease and is truly sought after by the market.

In order to solve the above-mentioned problems, the present invention measures the physical condition of a subject based on the defecation gas discharged into the bowl of the flush urinal arranged in the toilet installation space where the flush urinal is installed. A biological information measurement system, a suction device that sucks the gas in the bowl from which the stool gas is discharged by the subject, and a gas sensor that reacts with the odorous gas containing the sulfur component contained in the stool gas sucked by this suction device. A gas detection device equipped with, a control device that controls the suction device and the gas detection device, a data analysis device that analyzes the physical condition of the subject based on the detection data detected by the gas detection device, and analysis by this data analysis device. It has a display device that displays the result, and the data analysis device corrects the detected data according to a predetermined first predetermined condition, and displays the corrected analysis result on the display device. A correction circuit is provided, and this physical condition display correction circuit determines the reliability of the measured value with respect to the physical condition of the subject, corrects the detection data based on the measurement reliability of the measured value, and analyzes the corrected physical condition. It is characterized by displaying the result on a display device.

Conventionally, there has been no effective device other than diagnosis at a hospital for confirmation of whether or not a patient has a major disease such as cancer or confirmation for prevention of a major disease. On the other hand, according to the present invention, a general consumer can easily purchase a subject-side device and measure it at home. Furthermore, since the defecation gas discharged during defecation is measured, the subject does not have to bother to perform a new measurement action, and simply performing the daily excretion action normally causes a serious illness such as cancer. You can prevent this from happening, or you can go to the hospital and receive treatment in a mild condition. As described above, according to the present invention, it is possible to realize an apparatus truly sought after by the market and to provide a highly practical diagnostic system, which is an excellent effect.

Here, before concretely explaining the effect of the present invention, a technical idea that enables a system that can be widely used as a consumer product in general households will be described. The key points are the idea of reversal and the knowledge of effective division by understanding the characteristics of major diseases such as cancer and using them.

Specifically, one of the key points of the system of the present invention is the reversal idea that the subject-side device installed in each home does not diagnose that the patient has a major disease such as cancer. That is, the subject, who is a general consumer who purchases the device on the subject side, does not want to know that he / she has cancer, but the risk of cancer increases at the stage before cancer (hereinafter, this stage is referred to as non-illness). Recognizing this, I really want to improve my future life so that I don't get cancer. In other words, we thought that the value of the equipment required for ordinary households is that healthy people can accurately grasp the risk of cancer and improve their physical condition so that they do not get cancer.

Next, one of the key points of the system of the present invention is a device for diagnosing a specific type of cancer such as rectal cancer, or a device capable of diagnosing an increased risk of a specific type of cancer. It is in the division that it is not. This is a characteristic that the subject is not anxious about a particular type of cancer, such as rectal cancer, but is anxious about any cancer. Therefore, the inventors can specify the type of cancer by considering that there is no need for accuracy to specify the type of cancer, not that there is no commercial value unless a specific type of cancer is diagnosed. It was decided that the accuracy of such measurement was unnecessary.

Next, one of the key points of the system of the present invention is that the diagnostic accuracy for each excretion act may be extremely low. This is based on the characteristic that cancer is a disease that progresses over a long period of several years, and we realize that the chances of diagnosis are long-term, on a yearly basis. Therefore, if it is positioned as a device for a healthy person to reduce the risk of developing cancer by himself / herself, he / she realizes that there is virtually no problem even if the accuracy of one diagnosis is low, and it is effective based on this. Dividing is one of the keys.

Hereinafter, the peculiar effect of the system based on the present invention constructed based on these findings and effective division will be described.
In the present invention, since the physical condition of the subject is analyzed by measuring the defecation gas discharged into the bowl of the toilet bowl, the subject does not have to bother to perform the measurement action, and simply defecates daily. You can make a diagnosis just by doing it. In addition, since there is no trouble, the subject is not burdened, and the measurement can be continued for a long period of time, and information on changes in the health condition and the situation where the cancer risk is increased can be surely obtained.

Further, in the present invention, a sensor for pinpoint measurement of methyl mercaptan gas is not used, and a sensor that widely reacts to odorous gas other than methyl mercaptan gas in defecation gas is used. When a sensor that measures methyl mercaptan gas in a pinpoint manner is used, it can be reliably detected that it is colorectal cancer because there is a correlation between the amount of methyl mercaptan gas and colorectal cancer, and the risk of cancer is increased. Can be surely understood from the amount. However, this increases the risk of cancer to some extent, and it cannot be determined that the risk of cancer increases unless the amount of methyl mercaptan gas increases, which is unsuitable for the present invention for the purpose of preventing cancer. I noticed that.

On the other hand, in the case of a sensor that responds widely to odorous gas, it is possible to detect not only an increase in cancer risk but also an unwell state. Specifically, first, in a state where the risk of cancer is increased, a very strong odorous gas containing a sulfur component such as methyl mercaptan gas or hydrogen sulfide increases. A sensor that widely reacts to odorous gas can always detect such an increase in gas.

Further, in the present invention, a gas detection device that reacts not only with methyl mercaptan gas but also with odorous gas in defecation gas other than methyl mercaptan gas is used, and only the amount of odorous gas in defecation gas can be known. The amount of methyl mercaptan gas cannot be measured, and the state of cancer cannot be accurately identified. However, the inventors have increased the risk of cancer in healthy people by using a gas detector that reacts not only with methyl mercaptan gas but also with odorous gas in defecation gas other than methyl mercaptan gas. We have found that it functions effectively as a device to prevent the condition and the risk of developing cancer. In detail, a healthy person has a small total amount of odorous gas other than methyl mercaptan gas and methyl mercaptan gas. On the other hand, the total amount of odorous gas other than methyl mercaptan gas and methyl mercaptan gas temporarily increases due to deterioration of the intestinal environment in addition to cancer. The deterioration of the intestinal environment is specifically a deterioration of the intestinal environment due to factors such as excessive constipation, food type, lack of sleep, overdrinking and overdrinking, and excessive stress. However, all of these factors can be said to be bad lifestyle habits. Cancer develops after a bad lifestyle, but until now, even if the risk of cancer has increased, there is no way to recognize it, and at present, many people have a bad life with the convenient belief that they are okay. I'm continuing my habit.

As described above, the bad lifestyle as described above increases all or any of the odorous gases in the defecation gas such as methyl mercaptan, hydrogen sulfide, acetic acid, trimethylamine, and ammonia. On the other hand, the present invention is based on the detection data of a gas detection device that detects not only methyl mercaptan gas but also odorous gas in defecation gas other than methyl mercaptan gas such as hydrogen sulfide, acetic acid, trimethylamine and ammonia. Is being analyzed. Therefore, the analysis result based on the total amount of odorous gas in the stool gas reflects the result of the subject's poor physical condition and bad lifestyle, and the analysis result shows the physical condition and lifestyle that increase the risk of such cancer. It can be used as an index based on objective data to improve the condition, that is, as an effective index for maintaining health and reducing the risk of developing cancer, for the purpose of improving lifestyle and controlling cancer risk. It was found to be an excellent effect that works extremely effectively.

As described above, according to the present invention, since odorous gas other than methyl mercaptan gas and methyl mercaptan gas is measured, it is in a state where the risk of cancer is increased, or if such a state is continued for a long period of time. It has become possible to make measurements so that the subject can be notified of a suitable warning that he / she will develop cancer. We have found suitable findings for the purpose of reducing the number of people who develop cancer by the so-called reversal idea.

Further, according to the present invention, since a sensor that widely reacts not only with methyl mercaptan gas but also with odorous gases other than methyl mercaptan gas is used, the apparatus can be manufactured at low cost and can be provided as a consumer product. It became possible. As a result, the subject can be easily diagnosed at home, prevent serious illnesses such as cancer, or be encouraged to go to the hospital and receive treatment in a mild condition. It was able to fully meet the requirements.

In this way, the inventors dared to use not only methyl mercaptan gas but also odorous gas other than methyl mercaptan gas in the gas sensor for detecting methyl mercaptan gas in order to provide a system that can be widely used as a consumer product in general households. We considered using a sensor that also responds to the above, but in such a case, a new problem described below arose.

When a sensor that reacts with odorous gas other than methyl mercaptan gas is used, offensive odor gas components such as sweat and urine attached to the subject, perfume, and odorous gas and fragrance remaining in the stool and toilet space attached to the toilet bowl. , Also affected by alcohol disinfectants. In particular, if the perfume or air freshener is strong, or if the body or toilet space is unsanitary, the measurement accuracy may decrease. In addition, when using immediately after defecation by another person, there is a high possibility that offensive odor components such as defecation gas and adhering odor of the person who used it before are left in the toilet bowl or toilet space, which is unsanitary. It is possible that the measurement will be affected even if it is not in space.

In addition, the amount of methyl mercaptan gas contained in the defecation gas is very small, and further, it becomes even smaller in the stage before cancer, so that these offensive odor gas components have a great influence on the measurement result. In addition, the amount of methyl mercaptan gas during defecation also changes depending on the condition of the stool, for example, whether it is diarrhea or normal stool. Further, the sensor sensitivity of the semiconductor gas sensor and the solid electrolyte sensor changes when the measurement environment such as temperature and humidity changes. In this way, when a sensor that reacts not only with methyl mercaptan but also with odorous gases other than methyl mercaptan is used, it is affected by various disturbances (noise), so doctors and others make a diagnosis based on the detection results. There was a problem that accurate diagnosis was hindered when performing the procedure, and that the analysis result of the physical condition was erroneously placed on the sick side of the actual condition, causing a psychological burden on the subject.

As described above, in the measurement by the biological information measurement system of the present invention, the measurement environment is in the toilet installation space, and the odorous gas remaining in the toilet installation space affects the analysis result as a noise component. In addition, since the gas sensor does not react only to methyl mercaptan gas, the analysis results are affected by the subject's body odor and disturbances caused by perfume, etc., and the analysis results are also large due to temporary changes in physical condition such as diarrhea. It will be different. According to the present invention configured as described above, the detection data is corrected according to a predetermined first predetermined condition, and the corrected analysis result is displayed on the display device. Therefore, even if the analysis result changes significantly for each measurement due to noise components, other disturbances, temporary changes in physical condition, etc., those effects are reduced from the analysis result output by the correction. be able to. As a result, even if the analysis result of each measurement contains a large measurement error, it is possible to present a relatively reasonable analysis result to the subject, and the analysis result of the physical condition output in each measurement can be presented. The reliability can be improved, and it is possible to prevent the subject from giving an unnecessary psychological burden due to the measurement error.

The risk for major diseases such as colorectal cancer does not fluctuate significantly in a short period of time, but changes little by little over a very long period of time. For this reason, if the physical condition presented today is significantly worse than the physical condition presented yesterday by the biometric information measurement system, not only the subject is given a great psychological burden, but also the subject is presented. There is a risk of doubting the credibility of the analysis results themselves. According to the present invention configured as described above, since the physical condition display correction circuit corrects the measurement data based on the measurement reliability of the measured value, even if the analysis result of each time contains a large error. It is possible to present highly reliable analysis results to the subject, and it is possible to improve the reliability of physical condition measurement.

In the present invention, preferably, a subject identification device for identifying a subject who uses a flush toilet, and a storage device for storing the analysis result of the physical condition by the data analysis device for each subject specified by the subject identification device. The physical condition display correction circuit determines the historical representative value based on the past analysis result displayed on the display device for the subject, and the direction in which the physical condition analysis result to be displayed this time approaches the historical representative value. Execute past history correction to correct to.

According to the present invention configured in this way, the history representative value is determined based on the past analysis result, and the analysis result of the physical condition to be output this time is corrected in the direction approaching the history representative value, so that it is newly displayed. It is possible to make the analysis result of the physical condition related to the past analysis result. As a result, it is possible to prevent the newly displayed analysis result from deviating significantly from the previously displayed analysis result due to the occurrence of a large measurement error, and the reliability of the displayed physical condition analysis result can be improved. Can be improved.

In the present invention, preferably, the physical condition display correction circuit changes the correction amount close to the history representative value by the past history correction according to the measurement reliability of the current detection data by the gas detection device.
According to the present invention configured in this way, the amount of correction by the past history correction is changed according to the measurement reliability of the detected data this time, so that the correction is more accurate according to the reliability of the detected data. It is possible to improve the reliability of the analysis result of the displayed physical condition.

In the present invention, preferably, the historical representative value is the center of gravity point of the past plurality of analysis results displayed on the display device for the subject, or the weighting of the past plurality of analysis results with respect to the distant past. It is determined as the center of gravity point calculated to be larger than the weight.

According to the present invention configured in this way, since the historical representative value is determined based on the results of a plurality of past analyzes, it is possible to offset the error mixed in each physical condition measurement, and it is more accurate. The analysis result can be corrected so that the value becomes the same.

In the present invention, preferably, the server further includes a server configured to be able to receive the analysis result by the data analysis device, the storage device stores at least the analysis result after correction by the physical condition display correction circuit, and the server stores the analysis result after correction by the physical condition display correction circuit. , At least the analysis result before correction by the physical condition display correction circuit is stored.

According to the present invention configured in this way, since the corrected analysis result is stored in the storage device, the analysis result of the physical condition presented to the subject is greatly deteriorated due to the measurement error, and the subject is unnecessary psychological. It is possible to prevent giving a burden. On the other hand, the analysis result before correction is stored on the server side, but since it is assumed that the detection data on the server side will be referred to by specialists such as doctors, the measurement error of the detection data can be accurately checked. It is possible to take this into consideration, and by referring to the raw data before correction, a more appropriate diagnosis of the disease can be made.

In the present invention, preferably, the physical condition display correction circuit increases the amount of correction by past history correction when the noise in the current measurement is large, as compared with the case where the noise is small.

The detection data may be mixed with noise due to odorous gas remaining in the toilet installation space, body odor of the subject, perfume, etc., and these noises reduce the reliability of the detection data. According to the present invention configured as described above, when the noise in the measurement is large, the correction amount by the past history correction is increased, so that the analysis result of this time is corrected to a value closer to the history representative value. As a result, it is possible to prevent the analysis result of the displayed physical condition from being deteriorated by the detection data having a large noise and giving an unnecessary psychological burden to the subject.

In the present invention, preferably, the gas detection apparatus, the health system gas discharged much from healthy subjects also be configured to detect, physical condition display correction circuit, when health-based gas is more than a predetermined amount, the display The correction amount by the past history correction is changed so that the analysis result to be performed approaches the side showing a good physical condition, or the analysis result corrected in the past history is corrected to the side showing a good physical condition.

Residual odorous gas and noise such as the subject's body odor change the analysis result to the side of poor physical condition. On the other hand, if a large amount of healthy gas emitted when the subject is in good physical condition is detected, it is presumed that the subject is in good physical condition. According to the present invention configured as described above, when the amount of healthy gas exceeds a predetermined amount, the displayed analysis result is corrected to the side showing good physical condition, so that the influence of noise and the like is reduced. , More reasonable analysis results can be presented to the subject.

In the present invention, preferably, the gas detector is configured to detect at least two healthy gases selected from hydrogen gas, carbon dioxide gas, methane gas, acetic acid gas, and propionic acid gas, and is a data analyzer. Is configured to display the analysis result on the display device as a point on the physical condition display table using the odorous gas as the first index and at least one of the health gas as the second index. The display correction circuit uses the amount of health gas that is not used as the second index of the health gas as the third index, and is displayed when the third index is equal to or more than a predetermined value. The amount of correction by past history correction is changed so that the analysis result approaches the side showing good physical condition, or the analysis result corrected in the past history is corrected to the side showing good physical condition.

According to the present invention configured in this way, in addition to the first and second indexes by the odorous gas and the health gas, the other health gas is used as the third index for correction. It is possible to evaluate the physical condition of the patient from various aspects, and to present the analysis result of the physical condition with higher reliability to the subject.

In the present invention, preferably, the gas detection device is configured to detect at least two types of odorous gases and a healthy gas emitted in large quantities from a healthy subject, and the data analysis device is among the odorous gases. The analysis result is displayed on the display device as a point on the physical condition display table using at least one of the above as the first index and the health gas as the second index, and the physical condition display correction circuit is odorous. The amount of a specific odorous gas among the gases is used as the fourth index, and when this fourth index is equal to or higher than a predetermined value, the displayed analysis result approaches the side showing poor physical condition in the past. The amount of correction by history correction is changed, or the analysis result corrected in the past history is corrected to the side showing poor physical condition.

According to the present invention configured as described above, in addition to the first and second indexes by the odorous gas and the health gas, the detection value of another odorous gas is used as the fourth index for correction. , It becomes possible to more accurately grasp the odorous gas contained in the defecation gas in an extremely small amount, and it is possible to present the subject with a more reliable analysis result of the physical condition.

In the present invention, preferably, when the detected data this time corresponds to a predetermined second predetermined condition, the data analysis device obtains a normal analysis result in the case where the second predetermined condition is not satisfied. Without displaying on the display device, the physical condition display correction circuit does not use the current detection data or reduces the weighting of the current detection data in the subsequent determination of the historical representative value.

If the measurement noise is extremely large, or if the subject has diarrhea, the detection data may contain an extremely large error, or the discharged defecation gas may not be suitable for the measurement of physical condition. If a normal analysis is performed based on the detection data in such a state, an abnormal analysis result will be output. According to the present invention configured as described above, when the detection data this time corresponds to a predetermined second predetermined condition, the normal analysis result is not displayed on the display device, so that the abnormal detection data is abnormal. It is possible to prevent the subject from being unnecessarily burdened by the abnormal analysis result. Further, in such a case, since the current detection data is not adopted or the weighting is lowered in the subsequent determination of the historical representative value, a large error is mixed in the historical representative value due to the abnormal detection data. Can be prevented.

In the present invention, preferably, the data analysis device stores the detection data or the analysis result of the physical condition based on the detection data in the storage device when the predetermined third predetermined condition is satisfied, while analyzing the physical condition. Do not display the result on the display device.

According to the present invention configured in this way, since the mode is provided in which the analysis result is stored in the storage device and the analysis result is not displayed on the display device, the analysis result is presented with low reliability and is unnecessary for the subject. It is possible to accumulate detection data while preventing a heavy psychological burden.

In the present invention, preferably, the data analysis device determines that the third predetermined condition is satisfied when the number of analysis results of the physical condition stored in the storage device for a specific subject is not more than a predetermined number.

In the past history correction of the present invention, the detected data this time is corrected so as to approach the historical representative value. However, for example, when the past detection data is not sufficiently accumulated, it is not possible to present a sufficiently reliable analysis result even if the past history correction is performed. According to the present invention configured as described above, when the number of physical condition analysis results is less than or equal to a predetermined number, the analysis results are stored in the storage device, but the physical condition analysis results are not displayed on the display device. It is possible to accumulate detection data while presenting unreliable analysis results and preventing the subject from giving an unnecessary psychological burden.

In the present invention, preferably, the physical condition display correction circuit corrects the analysis result of the physical condition to be displayed this time so that the distance from the historical representative value is equal to or less than a predetermined value.
The results of each analysis may differ greatly due to various causes, even for the same subject. In such a case, even if the analysis result is corrected, the current analysis result may deviate significantly from the historical representative value. According to the present invention configured as described above, the analysis result is corrected so that the distance from the historical representative value is equal to or less than a predetermined value. Therefore, the display of the abnormal analysis result causes an excessive psychological burden on the subject. Can be prevented from giving.

In the present invention, preferably, the physical condition display correction circuit corrects the poor physical condition to the side of good physical condition by continuously correcting the past history performed in the latest past a predetermined number of times or more. In the correction, the amount of correction for correcting poor physical condition to the side of good physical condition is reduced.

In the past history correction of the present invention, the detected data this time is corrected so as to approach the historical representative value. However, if the analysis result is excessively corrected in the direction of showing a good physical condition by the past history correction, the subject may be delayed in recognizing the deterioration of his / her physical condition, and the improvement of lifestyle may be delayed. According to the present invention configured as described above, when the latest analysis result is corrected from poor physical condition to good physical condition for a predetermined number of times or more in a row, poor physical condition is detected in this past history correction. Since the amount of correction to be corrected to the side of good physical condition is reduced, the subject can be made to recognize the deterioration of physical condition at a relatively early stage, and the improvement of lifestyle and the like can be promoted at an early stage.

In the present invention, preferably, the physical condition display correction circuit collectively determines the historical representative values of the past analysis results displayed on the display device for the subject for each predetermined period, and the data analysis device determines each history. Display the representative value on the display device.

According to the present invention configured in this way, past analysis results are collected for each predetermined period, each historical representative value is determined, and each historical representative value is displayed on the display device, resulting in a huge number. It is possible to present the changing tendency of the past analysis results to the subject in a state that is easy to recognize. This makes it possible to effectively utilize the results of physical condition analysis by the biological information measurement system for the health management of the subject.

According to the present invention, it can be easily purchased by general consumers, and it is possible to prevent serious illnesses such as cancer by measuring defecation gas at home, or to go to a hospital for treatment in a mild state. It is possible to provide a highly practical diagnostic system that is truly sought after by the market.

It is a figure which shows the state which attached the biological information measurement system by 1st Embodiment of this invention to the flush toilet installed in the toilet room. It is a block diagram which shows the structure of the biological information measurement system of 1st Embodiment of this invention. It is a figure which shows the structure of the gas detection apparatus provided in the biological information measurement system of 1st Embodiment of this invention. It is a figure explaining the flow of the physical condition measurement by the biological information measurement system of 1st Embodiment of this invention. It is a figure which shows an example of the screen displayed on the display device of the remote controller provided in the biological information measurement system of 1st Embodiment of this invention. It is a figure which shows an example of the physical condition display table displayed on the display device of the remote controller provided in the biological information measurement system of 1st Embodiment of this invention. (A) is a diagram showing an example of movement of the plot points of the latest data by correction, and (b) is a diagram showing limit processing for the movement amount of the plot points. It is a figure which shows an example of the diagnostic table displayed on the server side in the biological information measurement system of 1st Embodiment of this invention. It is a graph which shows typically the detection signal by each sensor provided in the biological information measurement system 1 in one defecation behavior of a subject. (A) It is a figure explaining the estimation of the emission amount of odorous gas when the reference value of residual gas is not constant, and (b) is the value detected by the odorous gas sensor when the subject uses an alcohol-based toilet seat disinfectant. It is a graph which shows an example. It is a figure which shows an example of the update of a diagnostic table. It is a figure for demonstrating the method of determining the measurement reliability. It is a figure which shows the subject attached offensive odor gas noise correction table for determining the influence of the offensive odor gas attached to the subject's body and clothes. It is a figure which shows the humidity correction table for determining the influence of humidity. It is a figure which shows the temperature correction table for determining the influence of temperature. It is a figure which shows the excretion count correction table for determining the influence of the excretion count. It is a figure which shows the correction table which shows the relationship between the reliability recorded in the data analysis apparatus, and the correction factor of a measured value. It is a figure which shows the environmental noise correction table. It is a figure which shows the reference value stability correction table. It is a figure which shows the sterilization toilet seat cleaning correction table. It is a figure which shows the defecation gas total amount correction value table. It is a figure which shows the flatulence correction value table. It is a figure which shows the stool volume correction value table. It is a figure which shows the flight type correction value table. It is a figure which shows the defecation interval correction value table. It is a figure which shows the data accumulation amount correction table. It is a figure which shows the air volume correction value table. It is a figure which shows the CO ₂ correction table. It is a figure which shows the methane gas correction table. It is a figure which shows the sulfide gas correction table. It is a figure which shows the relationship between the discharge time and the discharge amount of each condition S1, S2, S3 which the total gas discharge amount of the defecation gas is constant, but the discharge time and the discharge amount (discharge concentration) per hour are different. It is a figure which shows the detection waveform of the gas sensor when the discharge time and the discharge amount per hour are changed. The amount of gas calculated based on the detection waveform of the gas sensor is shown. FIG. 32 is a diagram showing an initial portion of a detection waveform of a gas sensor shown in FIG. 32 with an enlarged time axis. It is a graph which shows the relationship between the discharge amount (discharge concentration) per hour, and the slope of the rise of the detection data waveform detected by a sensor. Gas estimated based on the product of the slope of the detection waveform of the semiconductor gas sensor and the arrival time to the peak (gas sensor waveform area) for each condition S1, S2, S3 in which the discharge time and the discharge amount (discharge concentration) per hour are different. It is a figure which shows the quantity. (A) is a diagram showing a state in which the subject-side device of the biological information measurement system according to another embodiment is attached to a flush toilet installed in the toilet room, and (b) is shown in FIG. It is a perspective view which shows the measuring apparatus of the subject side apparatus. It is a figure which shows the structure of the suction device of another embodiment of this invention. It is a figure which shows the structure of the gas detection apparatus which was configured to separate the influence of hydrogen gas by shifting the arrival time of hydrogen gas and odorous gas to an odorous gas sensor by another embodiment of this invention. It is a figure which shows the detection waveform detected by the semiconductor gas sensor of the gas detection apparatus shown in FIG. 39. (A) is a diagram showing an example of plot point correction displayed on a display device in a biological information measurement system according to another embodiment of the present invention, and (b) is a correction table based on the amount of carbon dioxide gas. .. (A) is a diagram showing an example of plot point correction displayed on the display device in the modified example of the embodiment shown in FIG. 41, and (b) is a correction table based on the amount of carbon dioxide gas. It is a figure which shows an example of the physical condition display table displayed on the display device in the biological information measurement system by another embodiment of this invention. It is a figure which shows the result of having measured the amount of the healthy gas and the odorous gas contained in the defecation gas of the healthy person of 60s or less, the healthy person of 60s to 70s, the patient of early cancer, and the patient of advanced cancer. .. It is the figure which compared the gas amount of hydrogen sulfide contained in the defecation gas between a healthy person and a colorectal cancer patient. It is a figure which compared the gas amount of methyl mercaptan gas contained in defecation gas between a healthy person and a colorectal cancer patient. It is a figure which compared the gas amount of hydrogen gas contained in defecation gas in a healthy person and a colorectal cancer patient. It is a figure which compared the gas amount of carbon dioxide gas contained in defecation gas in a healthy person and a colorectal cancer patient. It is a figure which compared the gas amount of propionic acid gas contained in defecation gas in a healthy person and a colorectal cancer patient. It is a figure which compared the gas amount of acetic acid gas contained in defecation gas in a healthy person and a colorectal cancer patient. It is a figure which compared the gas amount of butyric acid gas contained in defecation gas in a healthy person and a colorectal cancer patient.

Hereinafter, an embodiment of the biological information measurement system of the present invention will be described in detail with reference to the drawings.
Further, FIG. 1 is a diagram showing a state in which the biometric information measurement system according to the first embodiment of the present invention is attached to a flush toilet installed in a toilet room. FIG. 2 is a block diagram showing a configuration of the biological information measurement system of the present embodiment. FIG. 3 is a diagram showing a configuration of a gas detection device provided in the biological information measurement system of the present embodiment.

As shown in FIG. 1, the biological information measurement system 1 is mounted on a measuring device 6 incorporated inside a toilet seat 4 placed on a flush toilet 2 installed in a toilet room R and a wall surface of the toilet room R. It has a subject-side device 10 composed of an attached remote control 8. Further, as shown in FIG. 2, the biometric information measurement system 1 includes a server 12, a subject terminal 14 in which dedicated software is incorporated in a smartphone or the like, and a medical institution terminal 16 installed in a medical institution such as a hospital. These perform a part of the function of the biological information measurement system 1 by exchanging data with the subject-side device 10. Further, the server 12 and the medical institution terminal 16 accumulate measurement data transmitted from a large number of subject-side devices 10 and perform data analysis.

In the biological information measurement system 1 of the present embodiment, the physical condition including the determination of cancer based on the odorous gas containing the sulfur component in the defecation gas released by the subject during defecation, particularly the methyl mercaptan (CH ₃ SH) gas. It is for analysis. Further, in the biological information measurement system 1 of the present embodiment, not only the odorous gas but also the health gas is measured, and the analysis accuracy of the physical condition state is improved based on these correlations. The healthy gas is a gas derived from intestinal fermentation and increases as the degree of health in the intestine increases. Specifically, it is a gas such as carbon dioxide, hydrogen, methane, and short-chain fatty acids. In the present embodiment, carbon dioxide gas and hydrogen gas are measured as health-related gases because they are easy to measure and the amount is large, so that the reliability of measurement of the health index can be kept high. Here, each subject-side device 10 is configured to display the analysis result during or immediately after defecation of the subject. On the other hand, in the server 12, measurement results by a large number of subjects are accumulated, and more detailed analysis is possible by comparison with other subjects. As described above, in the biological information measurement system 1 of the present embodiment, the subject-side device 10 installed in the toilet room R performs a simple analysis, and the server 12 performs a more detailed analysis.

Here, the principle of measuring physical condition in the biological information measurement system 1 of the present embodiment will be described.
It has been reported in the literature and the like that when suffering from gastrointestinal cancer, especially colon cancer, odorous gas containing sulfur components such as methyl mercaptan and hydrogen sulfide is discharged from the affected area at the same time as defecation. The digestive organs are the esophagus, stomach, duodenum, small intestine, large intestine, liver, pancreas, and gallbladder. The large intestine can also be classified into the appendix, cecum, rectum, and colon. These four parts are collectively referred to as the large intestine. .. Cancer has little daily change and gradually progresses. As the cancer progresses, the amount of odorous gas containing sulfur components, especially methyl mercaptan, increases. That is, when the amount of odorous gas containing a sulfur component increases, it can be determined that the cancer has progressed. Furthermore, in recent years, the idea of "not ill" has spread, and the idea of improving the physical condition and preventing the illness is spreading when the physical condition deteriorates before becoming ill. Therefore, it is required to detect cancer, particularly advanced cancer such as colorectal cancer, before becoming cancer and improve the physical condition.

Here, in addition to hydrogen sulfide and methyl mercaptan, the defecation gas excreted during defecation includes nitrogen, oxygen, argon, water vapor, carbon dioxide, hydrogen, methane, acetic acid, trimethylamine, ammonia, propionic acid, methyl disulfide, and tri. Contains methyl sulfide and the like. Of these, in order to determine a cancer disease, it is necessary to measure an odorous gas containing a sulfur-based component, particularly methyl mercaptan. Propionic acid, methyl disulfide, and methyl trifluide contained in the defecation gas are extremely small compared to methyl mercaptan, and therefore do not pose a problem in physical condition analysis such as cancer determination and can be ignored. However, other gas components cannot be said to be negligible. In order to accurately determine cancer, it is naturally conceivable to use a sensor capable of detecting only an odorous gas containing a sulfur component. However, since a sensor that detects only an odorous gas containing a sulfur component is large and very expensive, it is difficult to configure it as a household device.

On the other hand, as a result of diligent research, the inventors have reduced the cost by using a gas sensor that detects not only methyl mercaptan in defecation gas but also other odorous gases. I came up with the idea that it can be configured as a household device. Specifically, the inventors use a general-purpose semiconductor gas sensor or solid electrolyte sensor that reacts not only with sulfur-containing gas containing sulfur components but also with other odorous gases as a sensor for detecting gas. And said.

At an increased risk of cancer, there is a large amount of very strong odorous gas containing sulfur components such as methyl mercaptan gas. A sensor that widely reacts to odorous gas, such as a semiconductor gas sensor or a solid electrolyte sensor, can always detect such an increase in gas. However, as will be described later, sensors that widely react to odorous gases, such as semiconductor gas sensors and solid electrolyte sensors, include hydrogen sulfide, methyl mercaptan, acetic acid, trimethylamine, and ammonia, which increase when poor physical condition is caused by bad lifestyle. It also detects odorous gas. However, cancer is a disease that progresses over a long period of several years, and when it becomes cancer, a very strong odorous gas containing sulfur components such as methyl mercaptan gas and hydrogen sulfide becomes stronger. It lasts for a long time. Therefore, even if a general-purpose semiconductor gas sensor or solid electrolyte sensor that reacts not only with sulfur-containing gas containing sulfur components but also with other odorous gases is used, if the gas amount is high for a long period of time, cancer will occur. It can be judged that the possibility of the disease is high and the risk of cancer is increasing.

Further, the semiconductor sensor and the solid electrolyte sensor using the oxidation / reduction reaction detect not only methyl mercaptan gas but also acetic acid, trimethylamine, ammonia and the like which are odorous gases in the stool gas. However, as a result of experiments, the inventors have found that the mixed amount of odorous gases such as hydrogen sulfide, methyl mercaptan, acetic acid, trimethylamine, and ammonia increases when the physical condition deteriorates due to a bad lifestyle, and the physical condition is good. It was found that it tends to decrease. Specifically, a healthy person has a small total amount of odorous gas other than methyl mercaptan gas and methyl mercaptan gas. In contrast, the total amount of methyl mercaptan gas and odorous gases other than methyl mercaptan gas is due to factors such as excessive constipation, diet type, lack of sleep, overdrinking, overdrinking, and excessive stress. Temporarily increase due to deterioration.

In addition, acetic acid in the defecation gas tends to increase not only when the physical condition deteriorates due to diarrhea or the like but also when the physical condition is good. That is, it does not necessarily match the tendency of the amount of other odorous gases such as methyl mercaptan due to the above-mentioned change in physical condition. However, the amount of acetic acid contained in the defecation gas is much smaller than that of methyl mercaptan, and even if the amount of acetic acid gas increases when the person is in good physical condition, the amount of increase is the amount of decrease in other odorous gases. Very small compared to. Furthermore, the amount of increase in acetic acid when the physical condition deteriorates due to diarrhea or the like is much larger than the amount increased when the physical condition is good. Therefore, the amount of odorous gas contained in the defecation gas tends to increase as a whole when the physical condition deteriorates due to a bad lifestyle, and decrease when the physical condition is good. Then, after the deterioration of the intestinal environment due to such a bad lifestyle, cancer develops. Therefore, the amount of odorous gas contained in the defecation gas improves the physical condition while the cancer is not sick. It is a suitable index for this.
In this embodiment, the physical condition is based on the detection data of a semiconductor sensor or a solid electrolyte sensor that reacts not only with methyl mercaptan gas but also with odorous gas in stool gas other than methyl mercaptan gas such as hydrogen sulfide, acetic acid, trimethylamine, and ammonia. Perform analysis. As a result, analysis results that reflect the results of poor physical condition and bad lifestyle habits can be obtained, and these analysis results can be used as indicators based on objective data for improving physical condition and lifestyle habits that increase the risk of cancer. Can be done.

In addition, the defecation gas contains not only odorous gas but also H ₂ and methane, and when a semiconductor gas sensor or a solid electrolyte sensor is used as the gas sensor, these sensors also react with H ₂ and methane. It ends up. Furthermore, if a measuring device using a semiconductor gas sensor or a solid electrolyte sensor is set in each household, these sensors may react to fragrances and perfumes.
On the other hand, as will be described in detail later, the inventors have used a hydrogen sensor, a methane sensor and a column to separate the influence of hydrogen and methane from the detection data of the semiconductor gas sensor and the solid electrolyte sensor, and We have established a method to remove the effects of fragrances and perfumes as noise by detecting defecation behavior. In this way, the effects of hydrogen and methane can be separated from the data detected by the semiconductor gas sensor and solid electrolyte sensor, and the effects of air fresheners and perfumes can be removed to estimate only the amount of odorous gas in the defecation gas. Is now possible.

In addition, the amount of methyl mercaptan and other odorous gases contained in the defecation gas is much smaller than that of H ₂ and methane. Therefore, even if a semiconductor gas sensor or a solid electrolyte sensor is used, the amount of mixed gas of these odorous gases may not be accurately measured.
On the other hand, the inventors have stated that in healthy subjects, the intestinal environment is acidic, but in cancer patients, odorous gas containing a sulfur component is generated, and the amount of the gas increases. In addition, the intestinal environment becomes alkaline, and the amount of bifidobacteria decreases, so that the amount of healthy gas of fermentation-related components such as CO ₂ , H ₂ , and fatty acids is inversely proportional to the increase in the amount of odorous gas. We paid attention to the fact that the amount of carbon dioxide will surely decrease continuously.
For this reason, the inventors do not necessarily have high measurement accuracy in each measurement, but the daily correlation between the amount of odorous gas such as methyl mercaptan and the amount of gas of healthy gas components such as CO ₂ and H ₂ is daily. We thought that the occurrence of advanced cancer could be detected by monitoring during defecation.

Therefore, the inventors measured the amount of healthy gas and odorous gas contained in the defecation gas of healthy people in their 60s or younger, healthy people in their 60s to 70s, patients with early cancer, and patients with advanced cancer. As a result, the result as shown in FIG. 44 was obtained. That is, the defecation gas of a healthy person has a large amount of healthy gas and a small amount of odorous gas. On the other hand, the defecation gas of cancer patients has a small amount of healthy gas and a large amount of odorous gas. The amount of health gas contained in the defecation gas of advanced cancer is smaller than that of early cancer. Furthermore, when the amount of healthy gas and the amount of odorous gas are intermediate between those of cancer patients and healthy subjects, it is considered to be in the gray zone, that is, in a non-diseased state. Therefore, based on the above findings, the inventors consider that the amount of health gas and the amount of odorous gas of the subject can be measured, and the accuracy of determining the health condition can be improved based on these correlations. It was.

Further, FIGS. 45 to 51 show measurement data comparing the amounts of various gases contained in the defecation gas between healthy subjects and colorectal cancer patients (including advanced cancer and early stage cancer).
FIG. 45 is a diagram comparing the amount of hydrogen sulfide gas contained in defecation gas between healthy subjects and colorectal cancer patients, FIG. 46 is methyl mercaptan gas, FIG. 47 is hydrogen gas, and FIG. 48 is carbon dioxide gas. 49 is a propionic acid gas, FIG. 50 is an acetate gas, and FIG. 51 is a diagram comparing the amounts of butyric acid gas between healthy subjects and colorectal cancer patients. In these figures, the measurement data of healthy subjects are shown by the plots of circles, and the measurement data of colorectal cancer patients are shown by the plots of triangles, and the average value of each is shown by a short line segment.

As is clear from the measurement data of FIGS. 45 to 51, although the amount of various gases contained in the defecation gas varies greatly between healthy subjects and colorectal cancer patients, hydrogen sulfide gas and methyl mercaptan, which are odorous gases, are found. Regarding gas, there are many data showing a large amount of gas in colorectal cancer patients, and there is almost no data showing a large amount of gas in healthy subjects. On the other hand, regarding hydrogen gas and carbon dioxide gas, there are many data showing a large amount of gas in healthy subjects, and almost no data showing a large amount of gas in colorectal cancer patients. In this way, the amount of odorous gas contained in the defecation gas, which indicates the risk of colorectal cancer, is large in colorectal cancer patients and small in healthy subjects, whereas it is a healthy gas such as hydrogen gas and dioxide. The amount of carbon gas is large in healthy subjects and low in colorectal cancer patients. Furthermore, the short-chain fatty acid gases propionic acid gas, acetic acid gas, and butyric acid gas were detected in healthy subjects, whereas in colorectal cancer patients, these gases were hardly contained in the defecation gas. You can see that. According to this data, the gas amounts of these short-chain fatty acid gas, odorous gas, and health-related gas vary greatly in each gas amount measurement, but if short-chain fatty acid gas is detected, the subjects are almost the same. It shows that you are definitely healthy. Furthermore, the relationship between odorous gas and healthy gas is reversed between healthy subjects and colorectal cancer patients, and by continuously measuring these gases multiple times over a predetermined period, the physical condition of the subject can be reliably measured. It shows that it can be done.

In addition, the inventors measured the defecation gas, and found that when one defecation was performed multiple times (one flatulence or one stool was discharged), the first defecation was performed. It was found that the amount of defecation gas discharged by the act was large and that a large amount of odorous gas was also contained. Therefore, in the present embodiment, in order to accurately measure a trace amount of odorous gas, the health condition of the subject is analyzed based on the initial defecation gas. As a result, when measuring the amount of gas in the second and subsequent excretion actions, it may be affected by the stool and flatulence discharged by the first excretion action, and this effect can be reduced.
The biological information measurement system 1 of the present embodiment is based on the above-mentioned measurement principle. The odorous gas in the following description includes methyl mercaptan gas, which is an odorous gas containing a sulfur component, and odorous gas such as hydrogen sulfide, methyl mercaptan, acetic acid, trimethylamine, and ammonia other than methyl mercaptan. It is a gas.

Next, a specific configuration of the biological information measurement system 1 of the present embodiment will be described in detail.
As shown in FIG. 1, the subject-side device 10 in the biological information measurement system 1 is attached to a flush toilet bowl 2 in the toilet room R, and is partially incorporated in a toilet seat 4 with a buttocks washing function. The toilet seat 4 with a tail cleaning function includes a suction device 18 that sucks the gas in the bowl 2a of the flush toilet bowl 2 and a gas detection device 20 that detects a specific component contained in the sucked gas as the measuring device 6. It has been incorporated. The suction device 18 also has some functions as a deodorizing device incorporated in a normal toilet seat 4 with a cleaning function. The gas sucked by the suction device 18 is deodorized by the deodorizing device, and then the bowl 2a is used. Returned to. Further, each device incorporated in the toilet seat 4, such as the suction device 18 and the gas detection device 20, is controlled by the control device 22 (FIG. 2) built in the toilet seat side.

As shown in FIG. 2, the subject-side device 10 includes a measuring device 6 built in the toilet seat 4 and a data analysis device 60 built in the remote controller 8.
The measuring device 6 includes a control device 22 having a CPU 22a and a storage device 22b. The control device 22 includes a hydrogen gas sensor 24, an odorous gas sensor 26, a carbon dioxide sensor 28, a humidity sensor 30, a temperature sensor 32, a room entry detection sensor 34, a seating detection sensor 36, and a stool / urine detection sensor. 38, a toilet lid opening / closing device 40, a nozzle drive device 42, a nozzle cleaning device 44, a toilet cleaning device 46, a toilet disinfection device 48, an aromatic sprayer 50 which is an aromatic injection device, and deodorizing air. It is connected to the feeder 52, the suction device 18, the sensor heating heater 54, the transmitter / receiver 56, and the duct cleaner 58. As will be described later, the hydrogen gas sensor and the odorous gas sensor can be integrated into one sensor.

The temperature sensor 32 measures the temperature of the detection unit such as the odorous gas sensor 26. Further, the humidity sensor 30 measures the humidity of the gas sucked from the bowl 2a. The sensor sensitivity of these sensors changes slightly depending on the temperature of the detection unit. In addition, changes in humidity due to urination and the like also affect the sensitivity of the sensor. In the present embodiment, since the amount of odorous gas is very small, the toilet bowl side can measure this small amount of gas accurately and stably according to the temperature and humidity measured by these sensors 30 and 32. The CPU 22a controls a sensor heating heater 54 and a humidity adjusting device 59 (FIG. 3), which will be described later, so as to accurately maintain the sensor temperature and suction humidity of the sensors 30 and 32 within a predetermined range, and controls a predetermined temperature and humidity environment. Adjust to. It should be noted that these sensors and devices are not indispensable, and it is desirable to provide them in order to improve the accuracy.

The entry detection sensor 34 is, for example, an infrared sensor, which detects the entry / exit of the subject into the toilet room R.
The seating detection sensor 36 is, for example, an infrared sensor, a pressure sensor, or the like, and detects whether or not the subject is seated on the toilet seat 4.
In the present embodiment, the defecation / urination detection sensor 38 is composed of a microwave sensor, and whether the stool discharged by the subject is urine or stool, and whether the stool is floating in the sealed water. It is configured to detect the state of defecation such as whether it is sinking or whether the stool is in a diarrhea state. Alternatively, the defecation / urination detection sensor 38 can be configured by a CCD, a water level sensor that measures the transition of the sealed water, or the like.

The toilet lid opening / closing device 40 is a device for opening / closing the toilet lid according to a situation based on a detection signal of the entry detection sensor 34 or the like.
The nozzle drive device 42 is a device used for cleaning the buttocks, and is a device for cleaning the buttocks of a subject after defecation. The nozzle driving device 42 is configured to drive the nozzle to wash the flush toilet bowl 2.
The nozzle cleaning device 44 is a device for cleaning the nozzle of the nozzle driving device 42, and in the present embodiment, hypochlorous acid is generated from tap water, and the nozzle is cleaned with the generated hypochlorous acid. It is configured in.

The toilet bowl cleaning device 46 is a device for discharging water or tap water stored in a cleaning water tank (not shown) into the toilet bowl and cleaning the inside of the bowl 2a of the flush toilet bowl 2. The toilet bowl cleaning device 46 is normally operated by the operation of the remote controller 8 by the subject to clean the inside of the bowl 2a, but as will be described later, the toilet bowl cleaning device 46 is automatically operated by the control device 22 depending on the situation.
The toilet bowl sterilizer 48 is, for example, a device that generates sterilized water such as hypochlorous acid water from tap water, sprays the generated sterilized water onto the bowl 2a of the flush toilet bowl 2, and sterilizes the bowl 2a. Is.

The air freshener sprayer 50 is a device for spraying a predetermined air freshener into the toilet room R. This is provided to prevent the subject from spraying an arbitrary fragrance into the toilet room R and spraying an odorous component that would disturb the measurement. By providing the air freshener sprayer 50, it is possible to spray a predetermined amount of an air freshener that does not affect a predetermined measurement at a predetermined time according to the situation, and biometric information that the air freshener has been sprayed. The measurement system 1 can recognize it. As a result, the disturbance to the physical condition measurement is reduced and the analysis result is stabilized, so that the air freshener sprayer 50 functions as an output result stabilizing means.
The suction device 18 includes a fan for sucking the gas in the bowl 2a of the flush toilet 2, and the sucked gas flows through a detection unit such as an odorous gas sensor 26 and then is deodorized by a deodorizing filter. .. The detailed configuration of the suction device 18 will be described later.

The deodorizing air supply device 52 is a device that is sucked by the suction device 18 and discharges the deodorized air into the bowl 2a.
The sensor heating heater 54 is for heating and activating the detection unit of the odorous gas sensor 26 and the like. Each sensor can accurately detect a predetermined gas component by maintaining the detection unit at a predetermined temperature.
The duct cleaner 58 is a device for cleaning the inside of the duct 18a attached to the suction device 18 with, for example, hypochlorous acid obtained by electrolyzing tap water.

In the present embodiment shown in FIG. 1, the suction device 18, the deodorizing air supply device 52, and the duct cleaner 58 are integrally configured as the deodorizing device. That is, the gas in the bowl 2a is sucked into the duct 18a by the suction device 18, the sucked gas is deodorized by the deodorizing filter 78 (FIG. 3), and the deodorized gas is released into the bowl 2a again. As a result, the gas that reacts with the odorous gas sensor 26 flows into the bowl 2a from the outside, and it is suppressed that the gas component in the bowl 2a changes due to factors other than the defecation gas discharged from the subject during the defecation period of the subject. Will be done. Therefore, the deodorizing device provided with the deodorizing filter 78 and the deodorizing air supply device 52 function as output result stabilizing means. Alternatively, as a modification, a measurement gas supply device (not shown) for flowing a gas that does not react with each gas sensor into the bowl 2a is provided, and an equal amount of measurement gas as the gas sucked by the suction device 18 is provided. The present invention can also be configured to flow into the bowl 2a. In this case, the measurement gas supply device (not shown) functions as an output result stabilizing means for stabilizing the analysis result.

Next, as shown in FIG. 2, the remote controller 8 has a built-in data analysis device 60, and the data analysis device 60 includes a subject identification device 62, an input device 64, a transmitter / receiver 66, and a display device. 68 and the speaker 70 are connected. In the present embodiment, the transmitter / receiver 66, the display device 68, and the speaker 70 function as an output device that outputs an analysis result by the data analysis device 60. Further, the data analysis device 60 is composed of a CPU, a storage device, a program for operating these, and the like, and a database is constructed in the storage device.

In the present embodiment, the input device 64 and the display device 68 are composed of a touch panel, receive various inputs such as subject identification information such as the subject's name, and display various information such as physical condition measurement results. It is supposed to be done.
The speaker 70 is configured to output various alarms, messages, and the like issued by the biological information measurement system 1.
Subject identification information such as a subject's name is registered in advance in the subject identification device 62. When the subject uses the biological information measurement system 1, the registered subject is displayed on the touch panel, and the subject selects his / her own name.

Further, the transmitter / receiver 66 on the remote controller 8 side is communicably connected to the server 12 via the network. The subject terminal 14 is composed of, for example, a smartphone, a tablet PC, or a device capable of displaying received data such as a PC.

The server 12 includes a defecation gas database. The defecation gas database contains measurement data including the amount of odorous gas and the amount of healthy gas in each defecation behavior in association with the subject identification information of each subject using the biological information measurement system 1, and reliability data. And are recorded together with the measurement date and time. In addition, the server 12 has a diagnostic table recorded and has a data analysis circuit.
Further, the server 12 is connected to a medical institution terminal 16 installed in a hospital, a health institution, or the like via a network. The medical institution terminal 16 is composed of, for example, a PC or the like, and can browse the data recorded in the database of the server 12.

Next, the configuration of the gas detection device 20 built in the toilet seat 4 will be described with reference to FIG.
First, in the biological information measurement system 1 of the present embodiment, a semiconductor gas sensor is used as a gas sensor in the gas detection device 20 in order to detect odorous gas and hydrogen gas. Further, in order to detect carbon dioxide, a solid electrolyte type sensor is used in the gas detection device 20.
The semiconductor gas sensor has a detection unit made of a metal oxide film containing tin oxide or the like. When the detection unit is heated to several hundred degrees Celsius and the heated detection unit is exposed to the reducing gas, an oxidation / reduction reaction occurs between the oxygen adsorbed on the surface and the reducing gas. The semiconductor gas sensor can detect the reducing gas by electrically detecting the change in the resistance value of the detection unit due to the oxidation / reduction reaction. The reducing gas that can be detected by the semiconductor gas sensor includes hydrogen gas and odorous gas. In the present embodiment, a semiconductor gas sensor is used for both the sensor for detecting the odorous gas and the sensor for detecting the hydrogen gas, but the detection unit used for the odorous gas sensor reacts strongly with the odorous gas. As described above, the material of each detection unit is adjusted so that the detection unit used in the hydrogen gas sensor reacts strongly with hydrogen gas.

As described above, in the present embodiment, the "semiconductor gas sensor" is used as the "odorous gas sensor", but as described above, this "semiconductor gas sensor" is the methyl mercaptan gas to be detected and other substances. A general substance that reacts widely with odorous gas is used. Further, as will be described later, it is possible to use a solid electrolyte sensor as the "odorous gas sensor", but the solid electrolyte sensor also widely reacts to methyl mercaptan gas and other odorous gases like the semiconductor gas sensor. You can use a general one. In other words, a gas sensor that reacts only with methyl mercaptan gas is extremely difficult to manufacture, and even if it can be manufactured, it becomes an extremely large and expensive gas sensor. If such a large and expensive gas sensor is adopted, a biometric information measurement system can be manufactured at a cost that can be sold as a consumer product, even if it is feasible as a medical device used in advanced clinical examinations. That will be impossible. In the biometric information measurement system of the present embodiment, a simple, general-purpose gas sensor that reacts with other odorous gases other than the methyl mercaptan gas to be detected is adopted as the "odorous gas sensor". , It has made it possible to realize a biometric information measurement system as a consumer product. As described above, the gas sensor adopted in the present embodiment is a sensor that reacts with methyl mercaptan gas and odorous gas other than methyl mercaptan gas, but in the present specification, this is used for convenience. We will call it an "odorous gas sensor". Typical examples of the odorous gas with which the "odorous gas sensor" used in the present embodiment reacts include methyl mercaptan gas, hydrogen sulfide gas, ammonia gas, and alcohol-based gas.

Further, the "odorous gas sensor" adopted in the biological information measurement system 1 of the present embodiment is a sensor that reacts not only with the target methyl mercaptan gas but also with other odorous gases, which will be described later. Even if such a gas sensor is used, it is necessary as a consumer product and it is possible to measure with sufficient accuracy by various ingenuity. Specifically, in a space such as a toilet room where various odorous gases exist, data on defecation gas is extracted by assuming the defecation behavior of the subject from the device for improving the measurement environment and the detection signal by the gas sensor. Ingenuity in data processing, even if detection data with a large error is obtained, ingenuity to prevent the subject from being overly psychologically burdened. Details of each device will be described later.

In this embodiment, the case where the semiconductor gas sensor is used as the sensor for detecting the odorous gas and the hydrogen gas will be described, but instead of this, a solid electrolyte sensor can be used. The solid electrolyte sensor is a sensor that detects gas based on the amount of ion permeation that permeates the solid electrolyte, for example, by heating a solid electrolyte such as stable zirconia. The gas that can be detected by the solid electrolyte sensor includes hydrogen gas and odorous gas. Further, in the present embodiment, a solid electrolyte sensor is used as a sensor for detecting carbon dioxide. The carbon dioxide sensor is not limited to these, and an infrared method or the like may be used. The sensor that detects carbon dioxide can be omitted.

As shown in FIG. 3, in the present embodiment, the gas detection device 20 is arranged inside the suction device 18.
The suction device 18 is composed of a duct 18a directed downward, an intake passage 18b directed substantially horizontally, and a suction fan 18c arranged on the downstream side of the intake passage 18b. Further, inside the duct 18a, a duct cleaner 58 and a humidity adjusting device 59 are provided.
The gas detection device 20 includes a filter 72 arranged inside the intake passage 18b, an odorous gas sensor 26, a hydrogen gas sensor 24, and a carbon dioxide sensor 28. As shown in FIG. 3, the filter 72 is arranged so as to cross the intake passage 18b, and the odorous gas sensor 26, the hydrogen gas sensor 24, and the carbon dioxide sensor 28 are juxtaposed on the downstream side of the filter 72.

Further, a deodorizing filter 78 is provided on the downstream side of the odorous gas sensor 26, and the suction device 18 also functions as a deodorizing device by deodorizing the gas taken in by the deodorizing filter 78.
Further, a humidity adjusting device 59 is provided on the downstream side of the deodorizing filter 78. A moisture absorbing agent is sealed in the humidity control device 59, and when it is necessary to reduce the humidity in the bowl 2a, the air that has passed through the deodorizing filter 78 passes through the enclosed moisture absorbing agent. The flow path is switched to, and moisture is removed from the air circulating in the bowl 2a. As a result, the humidity in the bowl 2a is maintained at an appropriate value, and the detection sensitivity of each gas sensor is maintained substantially constant. Therefore, the humidity adjusting device 59 functions as an output result stabilizing means for suppressing the humidity change in the bowl 2a.

The suction fan 18c sucks offensive odor gas including odorous gas in the bowl 2a of the flush toilet 2 at a constant speed, deodorizes it, and then returns it to the bowl 2a. The deodorizing duct 18a is opened in the bowl 2a with the suction port facing downward so that droplets such as urine do not enter the inside. Odorous gas such as methyl mercaptan and hydrogen gas have a small molecular weight, so they rise immediately after defecation. On the other hand, in the present embodiment, the discharged odorous gas and hydrogen gas are surely introduced into the gas detection device 20 by sucking the discharged odorous gas and hydrogen gas from the inlet of the duct 18a opened in the bowl 2a by the suction fan 18c. be able to. In this way, the suction device 18 is operated before the subject starts defecation, and a gas having a constant flow velocity is brought into contact with each gas sensor during the defecation period of the subject. Thereby, a stable measured value can be obtained. Therefore, the suction device 18 and the control device 22 that operates the suction device 18 function as output result stabilizing means.

The filter 72 is a filter that does not have a deodorizing function, and is configured to pass through odorous gas, hydrogen, and carbon dioxide, and to prevent the passage of foreign substances such as urine and a cleaning agent. As such a filter 72, a member that mechanically collects foreign substances, for example, a fine net-like member can be used without utilizing a chemical reaction. As a result, it is possible to prevent the odorous gas sensor 26, the hydrogen gas sensor 24, and the carbon dioxide sensor 28 from being contaminated by urine stones and the like.

Further, for each gas sensor, a sensor heating heater 54 is provided on the upstream side of each gas sensor and on the downstream side of the filter 72, respectively. As described above, the odorous gas sensor 26 and the hydrogen gas sensor 24, which are semiconductor gas sensors, can detect hydrogen and odorous gas in a state where the detection unit is heated to a predetermined temperature. The sensor heating heater 54 is provided to heat the detection unit of the odorous gas sensor 26 and the hydrogen gas sensor 24. Further, the carbon dioxide sensor 28 also needs to heat the solid electrolyte to a predetermined temperature, and the sensor heating heater 54 is provided. These sensor heating heaters 54 also function as an offensive odor removing device for heating and removing offensive odor gas components adhering to the sensor. Even when a solid electrolyte sensor is used as the odorous gas sensor and the hydrogen gas sensor, it is necessary to provide a sensor heating heater for heating the detection unit.

Further, the sensor heating heater 54 also functions as a means for removing deposits adhering to each sensor. Although foreign matter is removed from the gas that has passed through the filter 72, the sucked gas contains various offensive odor gas components. Such offensive odor gas components adhere to each gas sensor and can cause noise when measuring a trace amount of odorous gas. On the other hand, by heating the detection unit of the sensor with the sensor heating heater 54, it is possible to heat and remove the offensive odor gas adhering to the sensor without providing a new device. Further, the control device 22 controls the sensor heating heater 54 so that the temperature of each gas sensor becomes constant even before the defecation behavior of the subject is started. That is, the control device 22 controls the sensor heating heater 54 so as to prevent the temperature of each gas sensor from dropping due to contact with the air flow. As a result, the sensitivity of each gas sensor is controlled to a predetermined value during the defecation period of the subject, and the measurement error by each gas sensor can be suppressed. Therefore, the control device 22 and the sensor heating heater 54 function as output result stabilizing means for stabilizing the output analysis result.

Further, the deodorizing filter 78 is a catalyst filter that adsorbs an offensive odor gas such as an odorous gas. The air from which gases such as odorous gas have been removed by the deodorizing filter 78 is returned to the bowl 2a. At this time, if the gas returned to the bowl 2a contains an odorous gas or the like, the odorous gas or the like flowing into the bowl 2a is sucked again from the duct 18a, and the odorous gas sensor 26 detects it again. There is a risk that it will end up. Therefore, in the present embodiment, by arranging the deodorizing filter 78 on the downstream side of the odorous gas sensor 26, the odorous components such as the odorous gas are surely removed from the gas returned to the bowl 2a.

When the subject sits on the toilet seat 4, the upper part of the bowl 2a is closed by underwear or the like. When the inside of the bowl 2a becomes negative pressure, the offensive odor gas component adhering to the subject's body, clothes, etc. is sucked into the bowl 2a. In the biological information measurement system 1 of the present embodiment, the sensitivity of the odorous gas sensor 26 is set extremely high in order to detect the odorous gas contained in the defecation gas in a very small amount, and the subject's body and clothes Even the offensive odor gas component adhering to the above causes a disturbance to the measurement. On the other hand, in the present embodiment, since the deodorized gas is returned to the bowl 2a, the inside of the bowl 2a does not have a negative pressure, and the offensive odor gas component adhering to the subject's body, clothes, etc. Can be prevented from being drawn into the bowl 2a.

Here, the semiconductor gas sensor used as the odorous gas sensor 26 detects not only the odorous gas but also hydrogen. Therefore, it is necessary to separate the influence of hydrogen gas from the detection data detected by the semiconductor gas sensor. In the present embodiment, as a hydrogen separation mechanism for separating the influence of such hydrogen gas, it is detected by the hydrogen gas sensor 24 from the detection value of the odorous gas detected by the semiconductor gas sensor in the gas detector 20. By subtracting the detected value of hydrogen gas, the influence of hydrogen gas is separated and output as the detected value of the odorous gas sensor 26. A configuration that includes such a hydrogen separation mechanism, a semiconductor gas sensor, and a hydrogen gas sensor 24 and outputs a detection value according to the amount of odorous gas and the amount of hydrogen gas is called a detection value output mechanism. The data analysis device 60 or the like may perform arithmetic processing for subtracting the detection value of the hydrogen gas detected by the hydrogen gas sensor 24 from the detection value of the odorous gas detected by the semiconductor gas sensor. Further, in the present embodiment, the hydrogen separation mechanism for separating the influence of hydrogen gas from the detection data detected by the semiconductor gas sensor will be described, but the detection data detected by the semiconductor gas sensor is provided by providing the methane sensor for detecting methane. It is also possible to isolate the effects of methane from. As the methane gas sensor, a semiconductor gas sensor in which the material of the detection unit is adjusted so as to strongly react with methane may be used.

In addition, since there are no methanogens that produce methane in the intestines of many people, or even if they do exist, the amount of methane is very small, so many people have a very large amount of methane contained in defecation gas. Few. Therefore, in this embodiment, a hydrogen sensor 24 and a carbon dioxide sensor 26 are provided as health gas sensors. However, in rare cases, there are people who have a very high number of methanogens in their intestines. In this way, the defecation gas of a person who has a large amount of methanogens in the intestine produces a large amount of methane, but a small amount of hydrogen. Therefore, when only the hydrogen sensor 24 and the carbon dioxide sensor 26 are provided, the defecation gas of a person having a very large amount of methanogens in the intestine is judged to have a small amount of healthy gas emissions, which is not preferable. In the present embodiment, a hydrogen sensor 24 and a carbon dioxide sensor 26 are provided as health gas sensors in order to fit many people, but a methane gas sensor is provided instead of the hydrogen sensor 24 according to a person with a large amount of methane gas. You may. Furthermore, it is more preferable to provide a methane gas sensor in addition to the hydrogen sensor 24 and the carbon dioxide sensor 26 in advance so that any subject can be dealt with.

As described above, the defecation gas contains a large amount of hydrogen, but the semiconductor gas sensor detects not only odorous gas but also hydrogen. On the other hand, the influence of hydrogen can be separated accurately by subtracting the amount of hydrogen gas detected by the hydrogen gas sensor 24 from the amount of gas detected by the odorous gas sensor 26 which is a semiconductor gas sensor. The amount of odorous gas can be measured.
Further, the hydrogen gas contained in the defecation gas has a very small molecular weight as compared with air, and easily escapes from the bowl 2a. On the other hand, in the present embodiment, since the defecation gas is sucked by the fan 18c of the suction device 18, the defecation gas containing the hydrogen gas can be reliably collected.

Further, if the sucked defecation gas is returned to the bowl 2a as it is, the measurement accuracy by the odorous gas sensor 26 is lowered. On the other hand, in the present embodiment, since the sucked defecation gas is deodorized by the deodorizing filter 78 and returned to the bowl, the amount of odorous gas and the amount of hydrogen can be accurately measured. Further, such a deodorizing filter 78 needs to be arranged on the downstream side of each sensor, but if such a deodorizing filter 78 is provided downstream of each sensor, the sensor may be directly contaminated by foreign matter. .. On the other hand, in the present embodiment, since the filter 72 having no deodorizing function is provided on the upstream side of the sensor, it is possible to reduce the contamination of the sensor by foreign matter without affecting the measurement of the odor component.

Further, when the gas in the bowl 2a is sucked, the pressure in the bowl 2a is lowered, and the offensive odor gas component adhering to the body or clothes of the subject may flow into the bowl 2a. On the other hand, in the present embodiment, since the air from which the odor component after deodorization has been removed is returned to the bowl 2a, it is possible to prevent the offensive odor gas component adhering to the subject's body and clothes from flowing into the bowl 2a. , Accurate measurement is possible.

However, it is not an essential configuration to return the deodorized air from which the odor component has been removed into the bowl 2a. If the configuration in which the air from which the deodorized odor component is removed is not returned to the bowl 2a in this way, the offensive odor gas component adhering to the body or clothes of the subject may flow into the bowl 2a. However, as will be described later with reference to FIG. 9, when setting the reference value of the residual gas, the reference value of the residual gas is taken into consideration after including the influence of the offensive odor gas component adhering to the body and clothes of these subjects. The value is set. Therefore, it is possible to estimate the amount of gas without returning the deodorized air from which the odor component has been removed to the bowl 2a.

Next, with reference to FIGS. 4 and 5, a flow of measuring the physical condition by the biological information measurement system 1 according to the first embodiment of the present invention will be described.
FIG. 4 is a diagram for explaining the flow of physical condition measurement, in which the upper part shows each process in physical condition measurement, and the lower part shows an example of a screen displayed on a display device of a remote controller in each process. FIG. 5 is a diagram showing an example of a screen displayed on the display device of the remote controller.

In the biological information measurement system 1 of the present embodiment, the physical condition including the determination of cancer is analyzed based on the correlation between the odorous gas in the defecation gas released by the subject during defecation and the health gas. Here, in each subject-side device, it is preferable that the analysis result is displayed during the defecation period or in a short time from the end of one defecation period to the exit. However, if the analysis is performed in a short time, the analysis accuracy may decrease. Further, it is difficult to suck all the defecation gas discharged by the subject by the suction device 18, and these become disturbances in a very unsanitary state in the toilet bowl or the toilet or in a measurement environment where the air freshener is strong. This may affect the measurement accuracy. For this reason, in each subject-side device, when communicating the physical condition including the presence or absence of illness to the subject, the psychological burden of the subject was taken into consideration, and the measurement was performed during a large number of defecation behaviors over a long period of time. Based on this, not only the absolute amount of odorous gas, which is highly related to cancer, is strongly transmitted, but also the change in the physical condition of the subject, that is, the change in the intestinal condition is strongly transmitted. In addition, in consideration of the measurement error during each defecation behavior, in the present embodiment, the subject is notified so that the physical condition notified to the subject does not change significantly based on the measurement result during one defecation behavior. I am trying to be notified. This utilizes the characteristic that cancer is a disease that progresses over a long period of time, and it is related to cancer that the amount of odorous gas, which is strongly related to cancer, changes significantly in a short period of time. This is because it is not strong, but is largely due to the results of bad lifestyles and the effects of noise, and when the physical condition changes significantly, it causes unnecessary psychological anxiety for the subject.

In view of the above points, in the present embodiment, first, the subject-side device 10 is based on the measurement result of the first defecation gas in one defecation action, that is, the defecation gas discharged in the first defecation action. , Analyze the health condition easily and display the analysis result of the health condition. On the other hand, in the server 12, a more detailed analysis can be performed by comparing with other subjects based on the total amount of gas discharged during one defecation action. Therefore, in the biological information measurement system 1 of the present embodiment, a simple analysis is performed by the subject-side device 10 installed in the toilet room R, and a more detailed analysis is performed by the server 12.

As shown in FIG. 4, in the measurement at the time of one defecation action by the biological information measurement system 1 of the present embodiment, the pre-measurement environment maintenance step S1, the measurement start preparation step S2, and the measurement reference value setting step S3 , The measurement step S4, the examination step S5, the communication step S6, and the post-measurement environment maintenance step S7 are executed.

The pre-measurement environment maintenance step S1 is a step performed before the subject enters the toilet room R. Whether or not the subject has entered the toilet room R is detected by the entry detection sensor 34 (FIG. 2).
In the pre-measurement environment maintenance step S1, the control device 22 on the toilet seat side controls the sensor heating heater 54, the suction device 18, and the toilet lid opening / closing device 40 by changing them to the measurement standby mode. In the measurement standby mode, the sensor heating heater 54 sets the temperature of the detection unit of the odorous gas sensor 26 to a temperature lower than the temperature at which the measurement is performed (for example, 200 ° C.) based on the temperature measured by the temperature sensor 32. Is controlled to be. The suction device 18 is controlled so that the suction air volume is minimized in the measurement standby mode. The toilet lid opening / closing device 40 is controlled so that the toilet lid is closed in the measurement standby mode.

Further, in the pre-measurement environment maintenance step S1, the detection unit of the odorous gas sensor 26 measures the gas concentration of the odorous gas, although the temperature is lower than the optimum temperature because the sensor heating heater 54 is in the measurement standby mode. Is possible. When there is a source of offensive odor gas in the bowl 2a, such as when there is stool attached to the flush toilet 2, the gas concentration measured by the odorous gas sensor 26 becomes a predetermined value or more. In the pre-measurement environment maintenance step S1, the control device 22 executes toilet bowl cleaning when the value of the gas concentration measured by the odorous gas sensor 26 exceeds a predetermined value. Specifically, the control device 22 discharges the washing water from the nozzle to wash the bowl 2a by the nozzle driving device 42, and discharges the water stored in the washing water tank by the toilet bowl washing device 46 into the bowl 2a. Wash the inside of the bowl 2a, or use the toilet bowl sterilizer 48 to generate sterilized water such as hypochlorite water from tap water, and spray the generated sterilized water onto the bowl 2a to sterilize the bowl 2a. Do.

Further, when the gas concentration measured by the odorous gas sensor 26 is equal to or higher than a predetermined value, the control device 22 may operate the suction device 18 to discharge the gas in the bowl 2a to reduce the gas concentration. Since the gas sucked by the suction device 18 is deodorized by the deodorizing filter 78, the suction device 18 and the deodorizing filter 78 function as deodorizing devices. Further, by sucking the gas with the suction device 18 with the toilet lid open, not only the inside of the bowl 2a but also the inside of the toilet room R can be deodorized. Therefore, the suction device 18 and the deodorizing filter 78 can be used in the toilet room. It can also function as a deodorizing device. Preferably, when the suction device 18 and the deodorizing filter 78 function as the deodorizing device, the amount of gas sucked by the suction device 18 is larger than that when the physical condition is measured during the defecation period of the subject.

Alternatively, the ventilation device (not shown) provided in the toilet room R may be configured so that the control device 22 can control it, and the gas concentration may be lowered by operating the ventilation device. In this way, the concentration of the odorous gas remaining in the bowl 2a is reduced, and the influence of the residual gas noise caused by the remaining gas is reduced. Therefore, the cleaning or sterilization of the bowl 2a by the nozzle driving device 42, the toilet bowl cleaning device 46 or the toilet bowl sterilizing device 48, and the exhaust / deodorization in the bowl 2a or the toilet room R, which are executed in the pre-measurement environment maintenance step S1, are performed. It functions as a noise countermeasure means for reducing the influence of residual gas noise and a residual gas removing means for reducing the concentration of residual odorous gas. Further, the noise countermeasure means executed when the subject is not in the toilet room R and is not during the defecation period of the subject functions as the first noise countermeasure means and also functions as the residual gas removing means.

Further, in the pre-measurement environment maintenance step S1, if the amount of gas measured by the odorous gas sensor 26 does not fall below a predetermined value even after the above-mentioned toilet bowl cleaning, the control device 22 is cleaned by the transmitter / receiver 56. Send a command signal. When the transmitter / receiver 66 on the remote controller 8 side receives the cleaning warning command signal, the display device 68 or the speaker 70 notifies the subject to clean the toilet.

Further, in the pre-measurement environment maintenance step S1, the control device 22 periodically cleans the suction environment. Specifically, the control device 22 drives the duct cleaner 58 and sprays cleaning water into the duct 18a of the suction device 18 to clean the duct 18a and the like. Further, the hydrogen gas sensor 24, the odorous gas sensor 26, and the carbon dioxide sensor 28 are heated to a high temperature by the sensor heating heater 54 to burn off the offensive odor gas components adhering to the surfaces of the gas sensors 24, 26, and 28.

Next, when the entry of the subject is detected by the entry detection sensor 34, the control device 22 transmits a signal to the transmitter / receiver 66 on the remote controller 8 side via the transmitter / receiver 56 to start the measurement start preparation step S2. , The measurement start preparation step S2 is performed in synchronization with the remote controller side.

In the measurement start preparation step S2, first, the subject identification device 62 built in the remote controller 8 identifies the subject. Specifically, the resident of the house in which the system is installed is registered in the biological information measurement system 1, and the registered resident is displayed as a candidate for the subject. That is, as shown in FIG. 5, "subject A", "subject B", and "subject C" are displayed above the display device 68 of the remote controller 8. .. The candidate's button is displayed as, and the subject is identified when the subject who enters the toilet room R presses the button corresponding to himself / herself. Further, the data analysis device 60 built in the remote controller 8 refers to the storage device and displays the past measurement data of the personal identification information received by the subject identification device 62 and the physical condition display table as the reference data for the analysis. get.

Further, in the measurement start preparation step S2, as shown in FIG. 5, the data analysis device 60 receives the previous defecation such as "Did you defecate at another place last time?" In the second stage of the display device. Questions about whether or not this device was installed in the toilet and the answer options "Yes (this morning)", "Yes (yesterday afternoon)", "Yes (yesterday morning)", "Before the day before yesterday", Display "No". When the subject answers this question, the subject's defecation history information is input to the input device 64 of the data analysis device 60. The defecation history information regarding the elapsed time from the previous defecation behavior of such a subject is stored in a storage device (subject information storage device) built in the remote control 8, and the subject registered in advance in this subject information storage device. Subject information regarding the weight, age, gender, etc. of the subject is also stored. Further, the defecation history information is transmitted to the server 12 and recorded in the database of the server 12.

Further, in the measurement start preparation step S2, the control device 22 on the toilet bowl side controls the sensor heating heater 54, the suction device 18, and the toilet lid opening / closing device 40 to the measurement mode. In the measurement mode, the sensor heating heater 54 is controlled so that the temperature of the detection unit of the odorous gas sensor 26 becomes a temperature suitable for measurement (350 ° C.) based on the temperature measured by the temperature sensor 32. Further, in the measurement mode, the suction device 18 raises the suction air volume to an air volume such that the defecation gas does not leak from the bowl 2a to the outside, and is constantly controlled so as not to fluctuate from such an air volume. Further, the toilet lid opening / closing device 40 is controlled to open the toilet lid in the measurement mode.

Further, in the measurement start preparation step S2, when the odorous gas concentration detected by the odorous gas sensor 26 is high, the control device 22 sterilizes the bowl 2a by the toilet bowl sterilizing device 48.
Further, in the measurement start preparation step S2, when the humidity measured by the humidity sensor 30 is a value that is not suitable for the measurement of the defecation gas by the odorous gas sensor 26, the control device 22 signals the humidity adjusting device 59. Is sent to control the humidity in the bowl to an appropriate value.

Further, when the toilet seat 4 is cleaned by spraying or a sheet using an alcohol-based disinfectant in the measurement start preparation step, the odorous gas sensor 26 reacts with alcohol and the gas concentration value rapidly increases. When the gas concentration measured by the odorous gas sensor 26 suddenly increases in this way, the data analysis device 60 displays a warning on the display device 68.

Further, the data analysis device 60 stores the measured value by the odorous gas sensor 26 as an environmental standard value which is a noise level which is a base for defecation gas measurement. Based on this environmental standard value, the data analysis device 60 determines whether or not the measurement is possible. Then, when the data analysis device 60 is measuring the noise level and determines that the measurement is not possible, the display device 68 displays "Preparing for measurement! Please wait for a while, if possible" as shown in the lower part of FIG. A display prompting the subject to wait for defecation is presented.
As described above, in the measurement start preparation step S2, the noise caused by the odorous gas remaining before the subject entered the toilet room and the subject noise caused by the odorous component adhering to the subject who entered the room. The noise level consisting of the above is determined before the subject is seated, stored as the environment / subject-derived noise reference value, and whether or not the measurement is possible is determined.

Next, when the seating detection sensor 36 detects that the subject is seated, the control device 22 transmits a signal to the data analysis device 60 via the transmitter / receiver 56 to start the measurement reference value setting step S3. , The measurement reference value setting step S3 is performed in synchronization with the data analysis device 60. If the seating detection sensor 36 repeats detection and non-detection a predetermined number of times, it is due to the influence of the subject cleaning the toilet seat. In such a case, it is desirable to return to S1.
In the measurement reference value setting step S3, the data analysis device 60 determines the subject adhering offensive odor noise, which is the determination of the noise level caused by the subject, based on the measured value measured by the odorous gas sensor 26. That is, if the measured value measured by the odorous gas sensor 26 is sufficiently lowered and is not stable, it is judged that the sterilization may have been performed by an alcohol-based sterilizer or the like, and FIG. Continue to display "Preparing for measurement! Please wait a moment if possible" shown at the bottom. Alternatively, when the noise level caused by the subject is equal to or higher than a predetermined value, the data analysis device 60 sends a signal to the nozzle drive device 42, which is a local cleaning device, and activates the signal to execute the cleaning of the subject's tail. Alternatively, the data analysis device 60 notifies the subject by the display device 68 so that the subject performs the buttocks washing. In this way, the execution of the butterflies cleaning by the data analysis device 60, the notification for prompting the cleaning, and the notification that the noise to the subject is large are the second noise correspondence that reduces the subject noise by the correspondence different from the first noise countermeasure means. Functions as a means. Further, the above-mentioned first noise countermeasure means is executed when the subject is not in the toilet room R, whereas the second noise countermeasure means is executed when the subject is in the toilet room R. Toilet. On the other hand, when the measured value measured by the odorous gas sensor 26 is sufficiently lowered, this display is erased. If the measured value measured by the odorous gas sensor 26 does not sufficiently decrease even after a lapse of a predetermined time, the data analysis device 60 stops the measurement of the physical condition and displays the fact on the display device 68 to the subject. Notify to. As described above, when the data analysis device 60 determines that the gas component in the bowl 2a before the defecation period of the subject is not suitable for the measurement, the data analysis device 60 stops the physical condition measurement of the subject, and thus serves as a means for stabilizing the output result. Function.

Further, in the measurement reference value setting step S3, the data analysis device 60 sets a reference value for estimating the gas amount based on the gas concentration measured by the odorous gas sensor 26, as will be described in detail later.
Next, as will be described in detail later, the data analysis device 60 determines that the subject has performed excretion when the value measured by the odorous gas sensor 26 rises significantly from the reference value. The data analysis device 60 performs the measurement step S4 from the determination that the subject has performed the excretion action until the seating detection sensor 36 detects that the subject has left the seat.

In the measurement step S4, the control device 22 includes a hydrogen gas sensor 24, an odorous gas sensor 26, a carbon dioxide sensor 28, a humidity sensor 30, a temperature sensor 32, a room entry detection sensor 34, a seating detection sensor 36, and defecation / urination. The detection data measured by the detection sensor 38 is stored in the storage device for each subject specified by the subject identification device 62. The control device 22 transmits these measured values stored in the storage device to the data analysis device 60 via the transmitter / receiver 56 after the measurement step S4 is completed. In the present embodiment, the measured value is transmitted from the control device 22 to the data analysis device 60 after the measurement step S4 is completed, but the present invention is not limited to this, and the measured value may be transmitted in real time in parallel with the measurement.
Further, the control device 22 starts the measurement of the defecation gas even when the subject has not input the information for identifying the subject into the subject identification device 62. The detection data detected before the information is input is stored in the storage device in association with the input subject information when the subject inputs the subject information during one defecation thereafter. It is a practical device that matches the characteristics of defecation so that various inputs can be performed after calming down without having to input various types first in the situation of defecation. Further, if the subject does not input the subject information even after a lapse of a predetermined time after the start of the measurement, a message prompting the subject to input is output from the display device 68 and the speaker 70 to notify the subject. As a result, it is possible to prevent the subject from forgetting to input.

At the same time, the data analysis device 60 determines whether or not the measurement is possible, as in the measurement reference value setting step S3. When it is determined by the data analysis device 60 that it can be measured, the data analysis device 60 uses the display device 68 to display "examiner: Totaro Higashi (subject identification information)" and "measurement" as shown in the lower part of FIG. Present the subject with an indication that the measurement is being performed, such as "OK! Measuring."

Next, when the seating detection sensor 36 detects that the subject has left the seat, the control device 22 transmits a signal to the data analysis device 60 via the transmitter / receiver 56 to start the examination step S5. When the data analysis device 60 receives this signal, the data analysis device 60 starts the medical examination step S5.
The data analysis device 60 first calculates the measurement reliability, which will be described in detail later, based on the measured values measured by each sensor.
On the other hand, if the information for identifying the subject is not input even after the subject leaves the seat, the control device 22 prohibits the flush toilet bowl 2 from being washed. That is, when the subject identification information is not input, even if the subject operates the cleaning button (not shown) of the remote controller 8, the control device 22 does not discharge the flush water of the flush toilet 2 and prompts the input. Is displayed. As a result, the subject can be strongly urged to input the subject specific information.

Further, the data analysis device 60 estimates the gas amounts of the odorous gas and the hydrogen gas (health gas), as will be described in detail later.
Further, in the examination step S5, the data analysis device 60 analyzes the physical condition of the subject based on the time course of the plurality of detected data detected in the plurality of defecations performed within the predetermined period and stored in the storage device. In addition to calculating the examination results, time-lapse diagnosis is performed based on the stored values. Then, the content of advice based on the time-lapse diagnosis is selected. As shown in the third row of FIG. 5, the data analysis device 60 displays the advice content selected on the display device 68 as a message related to health management. In the example shown in Fig. 5, as a result of the examination, the subject's current physical condition corresponds to "insufficient physical condition", and the advice is "The intestinal environment seems to be poor. Let's try to live a healthy life." It is displayed.

Further, below the examination result, the amount of healthy gas such as hydrogen gas and carbon dioxide gas in this measurement and the amount of unwell gas such as odorous gas are displayed. In addition, under the advice, the measurement results for the past four times are also displayed. Further, when the subject presses the "detailed screen" button on the display screen, a table showing the change in the physical condition of the subject in the past one month is displayed. This display will be described later. As described above, the analysis results displayed on the display device 68 of the remote controller 8 include only the physical condition state, advice, and physical condition change (history of measurement data), and the cancer is displayed on the medical institution terminal 16. It does not include notifications regarding the results of disease determination. The analysis results may be notified to the subject terminal 14.

Further, as shown in the lowermost part of FIG. 5, the reliability of the measurement data of this time is displayed in the lower part of the display device 68. In the example shown in FIG. 5, the reliability is displayed as "4", which is relatively high. If the reliability is low, the reason for the decrease in reliability and advice for improving it are displayed below the display of reliability. For example, if the residual gas noise caused by the gas remaining in the bowl or the subject noise caused by the subject is large, the reliability is lowered and the subject is notified that the noise affects the measurement result. .. Therefore, the display of reliability by the display device 68 functions as a noise countermeasure means. The calculation of reliability will be described later.

Next, when the control device 22 detects that the subject has left the room by the room entry detection sensor 34, the control device 22 transmits a signal to the data analysis device 60 via the transmitter / receiver 56 to transmit data. Upon receiving this signal, the data analysis device 60 performs the communication step S6.
In the communication process S6, the data analysis device 60 acquires the information identifying the subject specified by the subject identification device 62, the data measured by various sensors, the calculated reliability, the measurement date and time information, and the stool / urine detection sensor 38. Notification data including stool status information regarding at least one of the stool volume and stool status and stool history information is transmitted to the server 12 via the network. The server 12 records the received information in the database.

Further, the control device 22 performs the post-measurement environment maintenance step S7 after the subject leaves the room by the entry detection sensor 34.
The control device 22 measures the gas concentration by the odorous gas sensor 26 in the post-measurement environment maintenance step S7. Then, when the gas concentration measured by the odorous gas sensor 26 is larger than the predetermined value even after a predetermined time elapses after the end of the defecation period, the control device 22 has stool adhesion to the bowl 2a of the flush toilet bowl 2. The toilet bowl cleaning device 46 discharges the washing water stored in the washing water tank into the bowl 2a to wash the inside of the bowl 2a, or the toilet bowl sterilizing device 48 uses the hypochlorite from tap water. Disinfectant water such as acid water is generated, and the generated disinfectant water is sprayed onto the bowl 2a to sterilize the bowl 2a.

The additional toilet bowl cleaning by the toilet bowl cleaning device 46 and the sterilization of the bowl 2a by the toilet bowl sterilizing device 48 function as a residual gas removing means for reducing the concentration of the residual odorous gas. Preferably, the toilet bowl cleaning automatically performed by the residual gas removing means is set to have a higher cleaning power than the normal toilet bowl cleaning performed by the subject operating the cleaning switch (not shown) of the remote controller 8. I will do it. Specifically, in the toilet bowl cleaning performed by the residual gas removing means, it is preferable to set a large number of times of discharging the washing water to the bowl 2a or set a high flow velocity of the washing water. Further, the sterilization of the bowl 2a performed by the residual gas removing means is set to have a stronger sterilizing power than the normal bowl sterilization performed by the subject operating the sterilization switch (not shown) of the remote controller 8. deep. Specifically, in the sterilization of the bowl performed by the residual gas removing means, the sterilization water having a higher concentration than the normal sterilization is sprayed, or a large amount of sterilization water is sprayed.

Further, the residual gas removing means determines that the duct 18a is dirty when the gas concentration measured by the odorous gas sensor 26 is larger than the predetermined value even after a predetermined time has elapsed after the end of the defecation period. , Operate the duct cleaner 58. The duct cleaner 58 cleans the inside of the duct 18a attached to the suction device 18 with hypochlorous acid or the like obtained by electrolyzing tap water.
Further, when the residual gas removing means does not sufficiently reduce the gas concentration measured by the odorous gas sensor 26 even after performing the above cleaning and sterilization treatments and is larger than a predetermined value, a flush toilet bowl is used. A message prompting the cleaning of 2 is displayed on the display device 68.

Then, in the post-measurement environment maintenance step S7, the control device 22 changes the sensor heating heater 54, the suction device 18, and the toilet lid opening / closing device 40 to the measurement standby mode, and ends one measurement.

Next, the physical condition display table will be described with reference to FIG. This physical condition display table is a table displayed by pressing the "detailed screen" button on the display screen shown in FIG.
In the storage device on the remote controller 8 side, the physical condition display table, the defecation date and time of each subject, and the past measurement data are recorded for each subject in association with the subject identification information. The past measurement data stored in the storage device on the remote control 8 side may be data for the entire period during the defecation period, but due to the relationship with the capacity of the storage device, it is discharged by the first excretion action during the defecation period. It is preferable that it is the measurement data of the defecation gas (measurement data of the period of the first defecation act).

As shown in FIG. 6, the physical condition display table is a table determined based on the experiments conducted by the inventors described above, and the vertical axis is the odorous gas which is the first index (the display is a poor physical condition gas). The graph shows the index related to the amount of gas, and the horizontal axis shows the index related to the amount of health gas, which is the second index. The first index is related to the amount of odorous gas based on the first detection data detected by the gas detection device 20, and the second index is the second detection data detected by the gas detection device 20. It is based on the amount of hydrogen gas, which is a healthy gas. On the display device 68 of the remote controller 8, the measurement result of the defecation gas of the subject is displayed as plot points over time on the physical condition display table having such a vertical axis and a horizontal axis. That is, as shown in FIG. 6, the plot point representing the latest measurement result of the same subject is set to "1", the previous result is "2", and the result two times before is "3". .. .. As a result, the plot points for the past 30 times are displayed together with the numbers. As a result, the subject can recognize the change over time in his / her physical condition. In this embodiment, the dose is 30 times, but it may be for several weeks or months, or it may be for several years considering that the cancer progresses on an annual basis. It is more desirable to allow the subject to change the display range according to the situation, and if the display range is large, the display method is easy to see, such as one year or two years on average per month. Needless to say, it is even better to change it in consideration of.

In addition, in the physical condition display table, "disease suspicion level 2", "disease suspicion level 1", "physical condition deficiency level 2", "physical condition deficiency level", depending on the relationship between the index related to health gas and the index related to odorous gas. A plurality of stages of areas such as "1" and "good physical condition" are set according to the good or bad physical condition. Here, as shown in FIG. 6, the “disease suspicion level 2” corresponding to the worst physical condition is the physical condition display table in which the amount of odorous gas is the largest and the amount of health gas is the smallest. It is set in the upper left area. On the other hand, "good physical condition" corresponding to the best physical condition is set in the lower right area of the physical condition display table, where the amount of odorous gas is the smallest and the amount of healthy gas is the largest. The areas of "suspicious disease level 1", "illness level 2", and "physical condition level 1" indicating the physical condition level between these are set in order from the upper left as a band-shaped area rising to the right on the physical condition display table. Has been done. Such a physical condition display table is preset according to the weight, age, gender, etc. of the subject, and by displaying plot points based on the first and second indexes on this table, the detection data and the subject Information-based analysis can be performed.

As described above, in the present embodiment, two indexes, an index related to the amount of odorous gas and an index related to the amount of healthy gas, are used, so that the physical condition and changes in the physical condition of the subject can be examined in more detail. Can be evaluated. For example, even if the amount of healthy gas that indicates that you are in good physical condition is large, if the amount of odorous gas is also large, the evaluation will not be at the level of the best physical condition (on the physical condition display table). Upper right area). On the contrary, even if the amount of healthy gas indicating that the person is in good physical condition is very small, if the amount of odorous gas is small, the evaluation does not indicate the level of the worst physical condition (physical condition display table). Lower left area of).
Further, for example, at the boundary line between "physical condition level 1" and "physical condition level 2" indicating a state of poor physical condition, the index regarding the amount of healthy gas on the horizontal axis increases and the vertical axis is odorous. The index related to the amount of gas is also drawn upward to the right so that the index related to the amount of odorous gas at this boundary line is distributed on the side where the index related to the amount of odorous gas is large. Since the boundary line is set in this way, in the present embodiment, even if the index related to the amount of healthy gas on the horizontal axis is the same value, the value of the index related to the amount of odorous gas on the vertical axis indicates the physical condition. The evaluation will be different. Further, in order to obtain the same evaluation, it is necessary that the value of the amount of odorous gas on the vertical axis increases and the value of the amount of healthy gas on the horizontal axis also increases.

Further, the storage device on the remote controller 8 side records advice according to these physical conditions. Specifically, the advice "Please go to the hospital" for the physical condition "suspicious illness level 2" and the advice "Recommend to go to the hospital" for the physical condition "suspicious illness level 1" are the physical condition "physical condition". "Insufficiency level 2" is advised that "disease concern will increase. Let's reduce stress and improve lifestyle urgently", and "physical condition level 1" is "the intestinal environment seems to be bad. Healthy" The advice "Let's keep in mind" is recorded, and the advice "I am in good physical condition" is associated with the physical condition "I am in good physical condition". On the physical condition display table, along with plot points indicating the physical condition of the subject, advice corresponding to the area where the latest plot points are located is displayed.

However, the plot points shown on the physical condition display table of the display device 68 of the remote controller 8 do not show the analysis results analyzed by the data analysis device 60 as they are, and are corrected according to predetermined predetermined conditions. The plot points are shown at the moved positions. Here, the diseases that are supposed to be detected by the biological information measurement system 1 of the present embodiment are colorectal cancer and the like, and such diseases do not progress rapidly within a few days. On the other hand, since the biological information measurement system 1 of the present embodiment sucks the defecation gas from the bowl 2a of the flush toilet 2 installed in the toilet room R and analyzes the sucked gas, the entire amount of the defecation gas is collected. You can't. In addition, an error occurs in the measurement result of the physical condition due to various factors such as when the subject wears perfume or when gas that reacts with the odorous gas sensor 26 such as odorous gas remains in the toilet room R. There is a risk.

For this reason, if the displayed physical condition is large and swings to the side of poor physical condition based on the result of one measurement of the subject, the subject is given an unnecessary psychological burden. In addition, if the measurement result of the physical condition fluctuates greatly for each measurement, the subject's trust in the measurement result of the physical condition may be lost. Therefore, in the biological information measurement system 1 of the present embodiment, the physical condition display correction circuit 60a (FIG. 2) built in the data analysis device 60 corrects the physical condition analysis result according to a predetermined condition. ing. As a result, the displayed analysis result does not fluctuate significantly for each measurement, and the reliability of the displayed subject's physical condition is improved. Here, while the corrected analysis result is stored in the storage device of the remote controller 8, the analysis result transmitted to and stored in the server 12 is the uncorrected analysis result before the correction together with the reliability of the detected data. It will be remembered. The present invention can also be configured such that the uncorrected detection data is also stored in the storage device of the remote controller 8, and the corrected detection data is also transmitted and stored in the server 12. As described above, not all of the detection data obtained by the biological information measurement system 1 of the present embodiment have high reliability. However, by continuously acquiring data on daily defecation behavior for a long period of time and accumulating the data in the storage device of the remote controller 8 or the server 12, it is possible to detect changes in the physical condition of the subject over a long period of time. Therefore, it is possible to call attention not to lead to a major illness such as colorectal cancer before the subject's physical condition deteriorates significantly.
As described above, the correction applied to the detection data functions as an output result stabilizing means for suppressing the index of the physical condition of the subject output to the display device 68 from swinging in the direction of poor physical condition due to a detection error or the like.

Next, correction of plot points will be described with reference to FIG. 7.
FIG. 7A is a diagram showing an example of movement of the plot points of the latest data by correction, and FIG. 7B is a diagram showing limit processing for the movement amount of the plot points.
First, in the example shown in FIG. 7A, the plot point calculated by the data analysis device 60 based on the latest measurement is “1”, and this point is a value determined based on the past analysis result. There is a large deviation from the "history representative value G". The physical condition display correction circuit 60a built in the data analysis device 60 "corrects the past history" so that the position of the latest plot point "1" approaches the "history representative value G". In the present embodiment, the center of gravity G of the plot points of the past 30 detection data is adopted as the "history representative value G", and the coordinates (X _G , Y _G ) of the center of gravity G are the past detection data. When the coordinates are (X _i , Y _i ), it can be obtained by the formula (1).
As will be described later, if the reliability of the detected data this time is extremely low and the second predetermined condition described later is met, the detected data this time is excluded from the calculation of the historical representative value. (Do not use the current detection data) and stop displaying the plot points based on the current detection data.

In this way, if the plot point "1" that deviates greatly from the distribution of the detected data up to the previous time is displayed, the subject is given an excessive psychological burden. Since the risk of cancer does not increase in one day, such a large change in measurement data may be the result of bad lifestyle habits the day before or the effect of noise rather than the increased risk of cancer. high. Therefore, in the present embodiment, the correction is made in consideration of not giving an excessive psychological burden to the subject. Therefore, as described above, when the latest analysis result deviates significantly from the "history representative value", the physical condition display correction circuit 60a sets the plot point to be displayed as the "past history correction" to the "history representative value". It is corrected in the direction of approaching. That is, the position where the plot point "1" is displayed on the physical condition display table is moved by a predetermined distance in the direction of the center of gravity G, which is the "history representative value", based on the reliability of the measurement data this time. In the example shown in FIG. 7A, the latest measurement data is displayed at the position of the plot point "1'" corrected so as to move the plot point "1" in the direction of the center of gravity G (the side in good physical condition). (Actually, plot point "1" is not displayed). The amount of correction (moving distance) of the plot point "1" in the direction of the center of gravity G by this past history correction is changed according to the reliability of the latest detected data, and is increased as the reliability is lower. In this way, by moving the latest plot points to the side showing good physical condition, the psychological burden on the subject can be reduced. The calculation of the reliability of the detected data will be described later. Further, in the present embodiment, the value of the corrected detection data is adopted as the detection data (X _i , Y _i ) for calculating the coordinates (X _G , Y _G ) of the center of gravity G.

Further, as a modified example, the historical representative value can be calculated by weighting the past detected data. For example, the weighted center of gravity of the past N detection data can be used as the historical representative value, and its coordinates (X _GW , Y _GW ) can be determined by the mathematical formula (2).
Here, w _i is a "weight", and the weight w _i to be multiplied by the latest past detection data is set to be larger than the weight w _i to be multiplied by the detection data in the distant past. For example, it is conceivable to set the weight to be multiplied by the detection data for the last week to be larger than the weight to be multiplied by the detection data before that. By setting the weight in this way, it is possible to determine the historical representative value in which the latest past detection data is more important than the distant past detection data.
As will be described later, when the reliability of the detected data this time is extremely low and the second predetermined condition is satisfied, the weight of the detected data this time is extremely reduced or set to 0. (Do not use the current detection data) and stop displaying the plot points based on the current detection data.

As described above, in the present embodiment, the past history correction is performed so that the plot points based on the latest detection data do not deviate significantly from the history representative values. However, in the physical condition display correction circuit 60a, when the latest analysis result is corrected by the past history correction in the direction of showing a good physical condition continuously for a predetermined number of times or more, the correction amount (the latest plot point by the past history correction). The distance to approach the historical representative value) is reduced. As a result, the subject can recognize at an early stage that his / her physical condition tends to deteriorate, and can encourage the subject to make efforts to improve his / her physical condition.

In addition, when a very large noise is input in the latest physical condition measurement and the latest plot points are deviated very greatly, the displayed physical condition is still displayed even when the correction described in FIG. 7A is applied. It is conceivable that it will move significantly to the side of poor physical condition. Therefore, as shown in FIG. 7B, a predetermined limiter is applied to the moving distance of the latest data from the center of gravity G. That is, the movement of the latest data from the center of gravity G is limited to ± 40%, and even if the latest data deviates by 40% or more from the coordinates of the center of gravity G, the latest data is plotted at a position deviated by 40%. .. For example, if the coordinate values of the center of gravity G is (X _G, Y _G), the range of the coordinate values which the latest data can be plotted _{(0.6X G ~1.4X G, 0.6Y G} ~1.4Y G ), And it is not plotted at the position further shifted. That is, the physical condition display correction circuit 60a (FIG. 2) corrects the analysis result of the physical condition to be output this time so that the distance from the historical representative value is equal to or less than a predetermined value.

Further, when the movement of the latest data exceeding 40% is performed twice in succession, the range in which the latest data can be moved is relaxed to 60%. As a result, for example, when the coordinate value of the center of gravity G is (X _G , Y _G ), the range of coordinate values on which the latest data can be plotted is (0.4 X _{G to} 1.6 X _G , 0.4 Y _G to). It will be changed to 1.6Y _G ). This is because when large movements of the latest data occur frequently, it is considered that some change in the physical condition of the subject is reflected rather than a mere measurement error.

Next, a server-side diagnostic table will be described with reference to FIG. The processing in the following server is performed by the data analysis circuit provided in the server 12.
FIG. 8 is a diagram showing an example of a diagnostic table displayed on the server side. As described above, in the biometric information measurement system 1 of the present embodiment, the measurement data of the entire defecation period analyzed by the data analysis device 60 is sequentially transmitted to the server 12 via the Internet and recorded in the database on the server side. Has been done. The accumulated measurement data is configured to be displayable on a medical institution terminal 16 installed in a medical institution registered by a subject or the like. For example, when the subject visits a medical institution in response to the message "I recommend going to the hospital" displayed on the display device 68 of the remote controller 8, the medical institution terminal 16 can display the diagnostic table for the server. It has become like. The vertical axis and the horizontal axis of the diagnostic table represent the same index as the physical condition display table displayed on the display device 68 of the remote controller 8, but the physical condition assigned to each area is more specific. It has become. By referring to the measurement data of the subject recorded in the database on the server 12 side on the medical institution terminal 16, the doctor can refer to the physical condition of the subject over time, which is useful for examination and treatment at the medical institution. Can be done. Alternatively, when the measurement data transmitted to the server 12 indicates a significant illness, the subject terminal 14 of the subject is notified to be examined by the medical institution registered by the subject. The present invention can also be configured.

The diagnostic table displayed on the medical institution terminal 16 is different from the physical condition display table displayed on the subject display device 68 as described above. As shown in FIG. 8, the diagnostic table on the server 12 side is a table determined based on the experiments conducted by the inventors described above, and is the relationship between the amount of healthy gas and the amount of odorous gas. Correspondingly, the disease state is associated. Specifically, in the diagnostic table, "high concern about colorectal cancer", "high concern about early colorectal cancer", "suspected early colorectal cancer" according to the relationship between the amount of health gas and the amount of odorous gas. , "Insufficiency level 3", "Insufficiency level 2", "Insufficiency level 1", "Health condition", "Intestinal insufficiency (diarrhea)", and "Suspected erroneous measurement" are set. ..

The subject's past measurement data is plotted over time on the server-side diagnostic table set in this way, and based on the position of the plot points, "large intestine cancer concern", "early colorectal cancer concern", and "early stage" Judgment regarding cancer diseases such as "suspected colorectal cancer" is made. The plot points displayed in the diagnostic table on the server side are not corrected or limited, and the doctor comprehensively judges the displayed data together with its reliability. Further, since the diagnostic table and the judgment result displayed on the medical institution terminal 16 are set on the assumption that the doctor refers to them, the name of the disease, the degree of its progression, and the like are displayed more concretely. It has become. In addition, if the plot points are located within the area related to cancer diseases such as "large intestine cancer concern", "early colorectal cancer concern", and "early colorectal cancer suspected" for a long period of time, the disease is more likely to occur. Indicate that there is a high possibility of. The doctor can comprehensively judge the indicated plot points, the reliability of the measurement, and the like, and inform the subject of the state of his / her physical condition. Further, in the medical institution terminal 16, in addition to the diagnostic table in which the past measurement data is plotted over time, the reliability calculated by referring to the database, the data measured by various sensors, the stool volume and the stool condition The stool status information and the stool history information regarding at least one of them can also be displayed.

In addition, a large number of subject-side devices 10 are connected to the server 12, and measurement data of a large number of subjects are accumulated. Furthermore, in the database on the server 12 side, data is also accumulated as to what kind of medical condition the subject who visited the medical institution based on a certain measurement data had as a result of undergoing a detailed examination at the medical institution. There is. Therefore, the data measured by the biological information measurement system 1 of the present embodiment and the data associated with the actual medical condition can be accumulated on the server 12 side. The diagnostic table on the server side is sequentially updated based on the measurement data of a large number of subjects accumulated in this way, and more accurate diagnosis can be performed based on the updated diagnostic table. In addition, the physical condition display table can be updated based on the data accumulated on the server side. The physical condition display table updated based on the data on the server side is downloaded to each subject side device 10 via the Internet and displayed on the display device 68 of the remote controller 8. However, even when the physical condition display table is updated, the physical condition display table presented directly to the subject is modified so that it is appropriate to show the subject.

Next, with reference to FIG. 9, the data detected by each sensor provided in the biological information measurement system 1 of the present embodiment and the estimation of the gas amount based on the data will be described.
FIG. 9 is a graph schematically showing the detection signals by each sensor provided in the biological information measurement system 1 in one defecation of the subject. FIG. 9 shows the waveforms of the detection signals by the hydrogen gas sensor 24, the carbon dioxide sensor 28, the odorous gas sensor 26, the humidity sensor 30, the temperature sensor 32, the seating detection sensor 36, and the entry detection sensor 34 in this order from the top. ..

The estimation of the amount of gas based on the detection signals of the above sensors is performed by the data analysis device 60, which is a physical condition state determination means for determining the physical condition state, that is, the CPU and storage device built in the remote control 8, or the CPU and the server 12 CPU. Performed in storage. The data analysis device 60 has a start threshold value of the rate of change of the gas amount for determining the start time of the excretion action read from the storage means of the remote controller 8, and a gas amount capable of performing stable measurement. Stability thresholds for are preset. The act of excretion here includes a fart.

First, at time t ₁ in FIG. 9, the entrance detecting sensor 34 detects the entry of the subject. The data analysis device 60 measures the amount of odorous gas by the odorous gas sensor 26 even in the state before the subject enters and exits the toilet room R by the entry detection sensor 34 (time t _{0 to} t ₁ ). .. Even in this state, the odorous gas sensor 26 reacts due to the influence of the air freshener and the residual stool adhering to the bowl 2a of the flush toilet 2, and outputs a detection signal to some extent. In this way, the measured value of the odorous gas sensor 26 before the subject enters the room is set as the environmental standard value of the amount of gas which is the residual gas noise. In the state before the entry detection sensor 34 detects entry, the odorous gas sensor 26 and the suction device 18 are in a power saving state, and the sensor heating heater 54 for heating the detection unit of the odorous gas sensor 26 The temperature is set low, the rotation speed of the suction fan 18c is suppressed, and the passing flow rate is also low.

Next, at time t ₁ , when the entry detection sensor 34 detects that the subject has entered the room, the odorous gas sensor 26 and the suction device 18 are activated. As a result, the temperature of the sensor heating heater 54 of the odorous gas sensor 26 rises, and the rotation speed of the fan of the suction device 18 rises, so that a predetermined flow rate of gas is sucked. As a result, the value detected by the temperature sensor 32 once rises significantly, and then converges to an appropriate temperature (time t ₁ to FIG. 9). In this specification, the entrance detecting sensor 34 is referred to as "defecation behavior" period (time t ₁ ~t ₈ in FIG. 9) of one that detects the entry into the toilet room R of a subject .. Further, when the subject enters the room, the detection signal detected by the odorous gas sensor 26 rises. This is because the odorous gas sensor 26 reacts to the body odor of the subject, the perfume used, the hair styling product, and the like. That is, the increase from the residual gas noise before the subject enters the toilet room R is the subject noise caused by the subject. The noise measurement circuit built in the data analysis device detects residual gas noise caused by the gas remaining in the bowl 2a and subject noise caused by the subject. Further, since the odorous gas sensor 26 is set to have extremely high sensitivity for the purpose of detecting an extremely small amount of odorous gas contained in the defecation gas discharged into the toilet bowl in the order of ppb, the human sense of smell It also reacts to odors that cannot be perceived by.

Next, at time t ₂ in FIG. 9, when the subject is seated on the toilet seat 4 is detected by the seating detection sensor 36, this point is set as the starting point of one bowel movement period of the subject. In the present specification, the period during which the seating detection sensor 36 detects the subject sitting on the toilet seat 4 (time t _{2 to} t _{7 in} FIG. 9) is referred to as one “defecation period”. Then, the value detected by the odorous gas sensor 26 after the start time of the defecation period (time t ₂ ) and immediately before the start of the first excretion act described later (time t _{5 in} FIG. 9) is used as the reference value for the residual gas. Set as.

In the example shown in FIG. 9, after the subject is seated at time t _2, the humidity sensor 30 detected value between times t ₃ ~t ₄ is increased. This is the detection of the subject's urination, and since the detected value of the odorous gas sensor 26 has hardly changed, the data analysis device 60 determines that the excretion act has not been performed. Then, the detection value of the hydrogen gas sensor 24 and odorous gas sensor 26 is up abruptly at time t _5. As described above, when the detected value of the odorous gas sensor 26 suddenly rises during the defecation period after the subject is seated, the data analysis device 60 determines that the excretion act has been performed.

When the excretion action is performed, the data analysis device 60 adjusts to the fluctuation range of the value detected by the odorous gas sensor 26, which is the increase from the reference value of the residual gas (the shaded portion of the graph of the value detected by the odorous gas sensor 26). Based on this, the amount of odorous gas emitted from the subject is estimated. That is, the data analysis device 60 sets the value of the detection data at the start of the defecation period by the subject as the reference value which is the noise level caused by the subject, and sets the difference between the detection value detected by the odorous gas sensor and the reference value. By integrating the time from the start point to the end point, it is estimated as the amount of odorous gas associated with the first defecation action. In this way, since the data analysis device 60 estimates the amount of odorous gas based on the difference from the reference value, it is possible to suppress the influence of noise caused by the subject. Therefore, the circuit built in the data analysis device 60 that performs this calculation functions as a noise suppression circuit and also functions as a second noise countermeasure means for reducing the influence of the subject noise. Further, when the noise level caused by the subject is equal to or higher than a predetermined value, the data analysis device 60 notifies the fact by the display device 68. The details of estimating the amount of odorous gas will be described later. Similarly, the data analysis device 60 estimates the amount of hydrogen gas discharged from the subject based on the increase in the value detected by the hydrogen gas sensor 24 from the reference value of the residual gas. After the excretion act by the subject is performed (time t _{5 in} FIG. 9), the values detected by the odorous gas sensor 26 and the hydrogen gas sensor 24 return to the reference value of the residual gas. Then, at time t _6, the excretion behavior of the second by the subject is performed, again odorous gas sensor 26, the detection value by the carbon dioxide sensor 28 and the hydrogen gas sensor 24 rapidly rises. Similar to the first excretion act, the amount of odorous gas and the amount of hydrogen gas discharged from the subject are estimated based on the increase from the reference value of the residual gas in this second excretion act. When estimating the amount of odorous gas and hydrogen gas in the second and subsequent excretion actions, the reference value is changed for each time in consideration of the influence of floating stools floating in the sealed water in the bowl. You may.

In this way, when the subject performs multiple excretion actions after entering the room (that is, when changes in the amount of gas above a predetermined threshold are detected multiple times), defecation associated with each excretion action is performed. The amount of gas is estimated in the same way. When calculating the amount of defecation gas in the second and subsequent excretion actions, the reference value may be changed for each time in consideration of the influence of floating stools floating in the sealing water in the bowl.

Then, by the seating detection sensor 36 unseated subjects completed defecation period once detected at time t ₇ in FIG. 9, the entrance detecting sensor 34 at time t ₈ the exit of the subject is detected, defecation once The action ends. The data analysis device 60 estimates the amount of defecation gas associated with each excretion action until the entry detection sensor 34 detects the subject leaving the room.

Based on the amount of defecation gas measured in this way, the remote controller 8 and the server 12 determine the physical condition of the subject. At this time, it is desirable that the remote controller 8 can display the measurement of the physical condition during the defecation period or immediately after the end of the defecation period. Then, when the excretion act is performed a plurality of times, stool collects in the bowl 2a, so that the accuracy of measuring the amount of gas by the odorous gas is lowered. On the other hand, at the time of the first excretion, the defecation gas that has reached the most downstream part of the large intestine is discharged, so that the most useful information for measuring the physical condition can be obtained, and the reliability of the measurement is high. Based on these, on the remote controller 8 side, when the amount of defecation gas (the amount of odorous gas and hydrogen gas) due to the first excretion act can be estimated, the subject is based only on the amount of defecation gas due to the first excretion act. The physical condition of the remote controller 8 is measured and displayed on the display device 68 of the remote controller 8. Alternatively, the physical condition can be measured so that the weighting of the measured value based on the detection data regarding the early defecation behavior in one defecation behavior is heavier than the weighting regarding the late defecation behavior.

On the other hand, on the server 12 side, it is desirable to make a more accurate judgment by using the total amount of defecation gas obtained by a plurality of excretion actions. Therefore, on the server 12 side, the total amount of defecation gas (total amount of odorous gas and hydrogen gas) due to a plurality of excretion acts, more preferably all included in one defecation period from sitting to leaving. The physical condition of the subject is determined based on the total amount of defecation gas caused by the act of excretion. The determination of the physical condition of the subject on the server 12 side does not necessarily have to be the total amount of defecation gas due to all defecation actions included in one defecation period, but all excretion included in many defecation periods. It is preferable that it is based on the total amount of defecation gas produced by the act.

Here, in the example shown in FIG. 9, the reference value of the residual gas was constant, but the emission amount of the odorous gas can be estimated even when the reference value is not constant. For example, when the detected value detected by the odorous gas sensor 26 tends to increase, as shown in FIG. 10A, the increase in the detected value detected by the odorous gas sensor 26 before the start of the excretory action The reference value is the auxiliary line A drawn assuming that the rate of change continues before and after the excretion act. The amount of odorous gas can be estimated by determining the time when the slope of the value detected by the odorous gas sensor 26 changes significantly from the auxiliary line A as the time when one excretion action is started.

Since the amount of odorous gas is estimated based on the difference from the reference value by setting the residual gas before excretion as a reference value, it is desirable that the reference value does not fluctuate significantly. Therefore, in the data analysis device 60, the rate of change of the detected value detected by the odorous gas sensor 26 before the start of the defecation action (that is, the rate of change of the reference value = the slope of the auxiliary line A) is equal to or less than a predetermined threshold value. In the case of, the notification means including the display device 68 of the remote controller 8 or the speaker 70 indicates that the estimation accuracy of the defecation gas amount is high.

On the other hand, when a spray-type air freshener is sprayed immediately before the excretion act, or when a disinfectant sheet or a disinfectant spray of an alcohol-based toilet seat disinfectant is used, it is detected by the odorous gas sensor 26 before the excretion act. The detected value fluctuates greatly. If such a state is set as a reference value, it is not possible to accurately estimate the amount of odorous gas. Therefore, the data analysis device 60 uses the display device 68 or the speaker of the remote controller 8 when the reference value, which is the noise level caused by the subject, is equal to or higher than a predetermined value, or when the rate of change of the reference value is equal to or higher than a predetermined threshold value. The notification means including 70 notifies that the estimation accuracy of the defecation gas amount is low. If excretion is performed despite such notification, measurement for analysis of physical condition is not performed, or measurement reliability is set low.

Next, the detection of the use of the alcohol-based toilet seat disinfectant will be described with reference to FIG. 10 (b). FIG. 10B is a graph showing an example of the value detected by the odorous gas sensor 26 when the subject uses an alcohol-based toilet seat disinfectant.
At time t ₁₀ of FIG. 10 (b), after the entrance detecting sensor 34 is entry of the subject is detected, the detection value of the odorous gas sensor 26 gradually rises in response to body odor or the like of the subject. Then, when the subject takes out the toilet sterilization sheet using an alcohol-based disinfectant at time t _11, odorous gas sensor 26 reacts to the alcoholic odor, the detected value rises abruptly. At time t _12, subjects completed the eradication of the toilet seat 4, and to discard the eradication seat in the bowl 2a, alcohol-based detection value of the odor of gas sensor 26 immediately due to the high volatility starts to decline. Since this characteristic is different from the residual offensive odor gas component, the inventors have found that the rapid increase in the detected value due to alcohol-based sterilization decreases after a while, and measurement becomes possible. However, in the case of sterilization with an alcohol-based sterilization sheet, it may float in the sealed water when it is discarded. In this case, the volatilization of alcohol continues, so that the decrease tends to be delayed. Therefore, it is desirable to discharge the sheet as follows.

Then, after the seating detection sensor 36 detects the seating of a subject at time t _13, when the subject to perform a cleaning switch of washing by operating the (not shown) flush toilet second washing of the remote controller 8, distilled water bowl 2a Since the disinfectant sheet floating on the surface is discharged, the detected value of the odorous gas sensor 26 drops sharply. When an alcohol-based disinfectant is used, the odorous gas sensor 26 generally changes in this way.

Therefore, in the toilet seat sterilization detection circuit built in the data analysis device 60, after the entry detection sensor 34 detects the entry of the subject and before the seating detection sensor 36 detects the sitting of the subject, the odorous gas sensor 26 When the detected value rises sharply by a predetermined value or more, it is determined that the subject has eradicated the toilet seat 4 or the like using an alcohol-based sterilizing agent. In this way, the inventor can detect the sterilization action of the toilet seat 4, which is a peculiar action performed by the subject in the toilet room R, from the detection signals of the entry detection sensor 34, the seating detection sensor 36, and the odorous gas sensor 26. I found.

Further, if the toilet seat sterilization detection circuit detects the use of an alcohol-based sterilizing agent and the flush toilet bowl 2 is not washed for a predetermined time even after the subject is seated, the sterilization built in the data analysis device 60 is performed. The noise-corresponding circuit sends a signal to the toilet bowl cleaning device 46 to automatically perform toilet bowl cleaning. Further, when the toilet seat sterilization detection circuit detects the use of an alcohol-based sterilizer, the sterilization noise-compatible circuit increases the rotation speed of the suction fan 18c. As a result, the amount of gas sucked by the suction device 18 increases, and the alcohol component volatilized by the toilet seat sterilization is positively deodorized by the deodorizing filter 78, which reduces the detection value of the odorous gas sensor 26. it can. That is, in the sterilization noise-compatible circuit, when the toilet seat sterilization detection circuit detects sterilization, the deodorizing device is activated to reduce the influence of noise caused by the alcohol-based sterilizing agent.

Further, when the toilet seat sterilization detection circuit detects the use of an alcohol-based sterilizer and the detection value of the odorous gas sensor 26 is rising, the sterilization noise-compatible circuit stops the physical condition measurement and waits for defecation. A message is displayed on the display device 68 to notify the subject. The sterilization noise corresponding circuit causes the subject to display a message to wait for defecation on the display device 68 until the physical condition can be measured, and notifies the subject. As a result, the influence of noise caused by the alcohol-based disinfectant is reduced. On the other hand, the detected value of the odorous gas sensor 26, which has risen sharply due to the use of the alcohol-based sterilizing agent, begins to decrease when the subject finishes sterilizing.

When the noise level detected by the odorous gas sensor 26 starts to decrease, the sterilization noise-compatible circuit erases the message on the display device 68 to wait for defecation and notifies that the measurement is possible. To do. That is, in a situation where the noise level caused by the alcohol-based disinfectant tends to decrease, it is possible to detect the rise of the detection value of the odorous gas sensor 26 which tends to decrease. The data analysis device 60 detects the time when the detection value of the odorous gas sensor 26, which tends to decrease, rises as the release of defecation gas by the subject. However, in a state where the decrease in the noise level detected by the odorous gas sensor 26 is equal to or higher than a predetermined rate of change, the sterilization noise-compatible circuit stops the physical condition measurement and continues to display a message to wait for defecation. .. That is, in a state where the noise level is sharply lowered, the increase in the detected value due to the release of the defecation gas is masked, and the release of the defecation gas cannot be accurately detected. In addition, it is desirable to cancel the calculation while the reference value is greatly reduced because the error becomes large.

Further, when the noise level is equal to or higher than a predetermined value due to the use of an alcohol-based sterilizing agent, the sterilizing noise-compatible circuit stops the measurement for measuring the physical condition or sets the measurement reliability low. As described above, when the reliability of the measurement is set low, the plot points on the physical condition display table described with reference to FIG. 7 (a) are corrected more to the side showing good physical condition. That is, when the sterilization of the toilet seat is detected, the sterilization noise corresponding circuit corrects the good or bad of the physical condition output by the display device 68 to the side showing the good physical condition.

On the other hand, when there is a lot of stool attached to the flush toilet 2 or when a large amount of air freshener is used, the absolute value of the amount of gas detected by the odorous gas sensor 26 becomes large, and in some cases, the value detected by the sensor becomes large. In such a situation, it is difficult to accurately estimate the amount of odorous gas, which is a trace amount, because it is saturated or goes out of the band where the measurement accuracy is high. Therefore, even when the absolute amount of the reference value is equal to or more than a predetermined threshold value, the data analysis device 60 does not perform the measurement for measuring the physical condition, assuming that the second predetermined condition is satisfied. Set the measurement reliability low.

Further, as described above, the measurement data of the amount of odorous gas and the amount of health gas of the new subject are sequentially accumulated in the database of the server 12. Further, in the database of the server 12, the medical examination result of the cancer that the subject received at the medical institution from the medical institution terminal 16 is recorded in association with the identification information of the subject. The server 12 updates the recorded diagnostic table based on the results of such a cancer medical examination and the change in the history of changes in the gas amounts of the odorous gas and the healthy gas.

FIG. 11 is a diagram showing an example of updating the diagnostic table. For example, even if it is determined that "early colorectal cancer is suspected" as a result of plotting and analyzing the measurement data A of the subject's odorous gas and health gas in the old diagnostic table, the medical examination Suppose this patient is diagnosed with early colorectal cancer. In such a case, as shown in FIG. 11, “large intestine cancer concern” and “early colorectal cancer concern” are included so that the portion corresponding to the measurement data A of the subject diagnosed with early colorectal cancer is included. , Expand the area of "suspected early colorectal cancer" and narrow the area of "physical condition level". On the contrary, for example, even if the old diagnostic table determines that "early colorectal cancer is suspected" based on the correlation between the amounts of odorous gas and health gas, the result of the medical examination is suspected of cancer. If there are many subjects diagnosed as none, expand the area of "physical condition deficiency level" and narrow the area of "high concern about colorectal cancer", "high concern about early colorectal cancer", and "suspected early colorectal cancer". .. When the diagnostic table is updated, each area of the display table is also changed in the same manner.

In addition, the server 12 records a plurality of physical condition display tables conditioned on the tendency of the change history of the attribute information such as the body weight, age, and gender of the subject and the measurement data of the odorous gas and the health gas. ..

Then, when it is desired that the subject-side device 10 perform a more detailed analysis of the physical condition, attribute information such as the subject's weight, age, and gender is registered in the server 12 together with the subject's identification information. Then, when the measurement data of the subject who desires the more detailed analysis is accumulated in the server 12, the server 12 selects the physical condition display table under the conditions close to the attribute information of the subject and the history of changes in the measurement data. .. The server 12 transmits the selected physical condition display table to the subject-side device 10 via the network. When the subject-side device 10 receives a new physical condition display table from the server 12, the subject-side device 10 changes the already stored physical condition display table to the received physical condition display table. As a result, the subject-side device 10 can perform more accurate analysis of the physical condition according to the attributes of the subject and the history of the measurement data.

In the embodiment described above, the device 10 on the subject side also stores the history of the measurement data, but the measurement data is not limited to this, and the measurement data is stored only in the database of the server 12 on the subject side. The device 10 may read the history of past measurement data from the database of the server 12 and perform the examination result calculation and the time-lapse diagnosis in the examination step S5.

Here, the method of calculating the reliability in the examination step S5 of FIG. 4 will be described in detail below. A feature of the semiconductor gas sensor used as the odorous gas sensor 26 is that it detects not only odorous gas but also ambient odorous gas such as air fresheners and sterilizing sheets, and odorous gas adhering to the subject's body and clothes. Sometimes. Furthermore, the detected value of the odorous gas detected by the semiconductor gas sensor also changes depending on the state of the stool (for example, whether or not it is in a diarrhea state) and the amount of stool. Therefore, in determining a disease related to cancer, it is required to be able to evaluate the magnitude of the influence of these offensive odor gas noises and the condition of stool. In the present embodiment, the reliability determination circuit provided in the data analysis device 60 of the subject-side device 10 installed in the toilet room is used to measure the influence of the offensive odor gas noise of the defecation gas, the condition of the stool, and the like. The event that affects the accuracy is evaluated, and the measurement reliability is determined as an index indicating the accuracy of gas detection by the gas detection device 20.

FIG. 12 is a diagram for explaining a method of determining the measurement reliability. In the following description, a case where correction is performed due to the influence of offensive odor gas adhering to the body or clothes of the subject, the influence of humidity, the influence of temperature, and the influence of the number of defecation gas will be described as an example. The following measurement reliability determination is performed using a reliability determination circuit that determines the reliability of detection of odorous gas in the data analysis device 60 of the remote controller 8.

The output from the hydrogen gas sensor 24, the odorous gas sensor 26, the carbon dioxide sensor 28, the humidity sensor 30, the temperature sensor 32, the entry detection sensor 34, the seating detection sensor 36, and the stool / urine detection sensor 38 of the measuring device 6 is the remote control 8. Is sent to the data analysis device 60 of. FIG. 12 shows an example of the output from these sensors.

Further, in the data analysis device 60 of the remote controller 8, a plurality of reliability correction tables for calculating the reliability are recorded in advance.

13 to 16 show a subject-attached offensive odor gas noise correction table for determining the influence of offensive odor gas adhering to the subject's body and clothes, a humidity correction table for determining the influence of humidity, and a temperature influence, respectively. It is a figure which shows the temperature correction table for making an excretion, and the excretion number correction table for determining the influence by the number of excretion.

The semiconductor gas sensor used as the odorous gas sensor 26 detects offensive odor noise (environmental noise) other than the defecation gas adhering to the subject. When the amount of offensive odor gas component (noise amount) attached to the subject is large, it can be said that the reliability of the measurement is low. Therefore, as shown in FIG. 13, in the subject adhering offensive odor gas noise correction table, a correction value is set for the amount of adhering offensive odor gas noise. That is, when the noise in this measurement is large, the amount of correction by the past history correction is increased as compared with the case where the noise is small, and the displayed analysis result is brought closer to the history representative value. Specifically, when the amount of the offensive odor gas component attached to the subject is less than the predetermined value, the correction value is set to 1 as a value without correction, and when the amount of the offensive odor gas component attached to the subject is equal to or more than the predetermined amount. Is to increase the negative correction amount from 1 in order to gradually lower the reliability value as the amount of the offensive odor gas component increases, and when the amount of noise of the offensive odor gas component adhering to the subject is much larger than the predetermined amount. Is not measurable (correction value 0) because it corresponds to one of the predetermined second predetermined conditions. The amount of attached offensive odor gas noise is determined based on the detection data detected by the odorous gas sensor 26 during the non-defecation period before the subject is detected to be seated by the seating detection sensor 36. Since the offensive odor gas component adhering to the subject affects the entire defecation period, not a part of the defecation period, the reliability is corrected over the entire defecation period. Hereinafter, what corrects the reliability over the entire defecation period in this way is referred to as "overall correction".

Further, when the subject urinates, the humidity in the bowl 2a rises, and the humidity of the gas reaching the detection unit of the odorous gas sensor 26 rises. When the humidity of the gas reaching the odorous gas sensor 26 becomes high, the resistance of the odorous gas sensor 26 changes, and the sensor sensitivity decreases. Further, when urine is applied to the attached stool in the bowl 2a, the attached stool becomes soft from the dry state, and a large amount of defecation gas is temporarily released from the attached stool while the urine is applied to the bowl 2a again. There is. The defecation gas released from the adhered stool may be detected by the odorous gas sensor as noise when measuring the defecation gas released from the subject. Therefore, as shown in FIG. 14, in the humidity correction table, when the humidity measured by the humidity sensor 30 is lower than the predetermined value, it is set to 1, and when it is equal to or higher than the predetermined value, the reliability increases as the humidity increases. Is reduced and exceeds the measurement limit value, measurement is not possible (correction value 0). Since the act of urinating is a temporary act, the humidity correction table uses "partial correction" to correct only the period during which the change in humidity measured by the humidity sensor 30 is observed. Hereinafter, the method of correcting the reliability only in a specific period of the defecation period, or the method of correcting the entire defecation period but differently in each period of the defecation period is referred to as "partial correction".

Further, the semiconductor gas sensor used as the odorous gas sensor 26 produces an odorous gas based on the oxidation / reduction reaction of oxygen adsorbed on the surface and the reducing gas in a state where the detection unit made of tin oxide is heated. It is being detected. Therefore, when the temperature of the detection unit is higher or lower than the predetermined temperature range, the sensor sensitivity is lowered. Therefore, as shown in FIG. 15, in the temperature correction table, the correction value is determined according to the temperature detected by the temperature sensor 32. Specifically, when the temperature detected by the temperature sensor 32 is within the optimum temperature range suitable for the measurement of the detection unit of the odorous gas sensor 26, the correction value is set to a value larger than 1 so as to increase the reliability. If the temperature detected by the temperature sensor 32 is slightly higher or lower than the optimum temperature range, the correction value is set to a value less than 1 so as to lower the reliability value, and the temperature is further detected by the temperature sensor. If the temperature is larger than the upper limit of the measurable temperature or smaller than the lower limit of the measurable temperature, it is not measurable (correction value 0). Since the temperature correction does not fluctuate significantly during the defecation period, it is an overall correction that corrects the entire defecation period.

In addition, as described above, when excretion is performed multiple times during one defecation period, the amount of defecation gas itself increases (the amount of odorous gas also increases) in the first defecation period. The accuracy of the analysis is higher in the early defecation behavior than in the late defecation behavior. Therefore, as shown in FIG. 16, in the excretion act frequency correction table, the correction value of the first defecation gas is set to a value larger than 1 so as to increase the reliability value, the second time is set to 1, and the third and subsequent times are set to 1. The value was set to less than 1, and gradually decreased as the number of times increased. As a result, the first defecation gas is given priority for diagnosis. The excretion act frequency correction table corrects only the period during which defecation gas is detected, and is a partial correction.

As shown in FIG. 12, when the entrance detecting sensor 34 at time t ₁ is entry of the subject is detected, the controller 22 of the measuring device 6, moves to the measurement start preparation process from the measurement before environmental improvement step is in standby mode Then, the sensor heating heater 54 and the suction device 18 are driven. As a result, the temperature detected by the temperature sensor 32 rises and converges to an appropriate temperature. Then, the data analysis device 60 of the remote control 8 refers to the temperature correction table in the non-delivery period before the seating detection sensor 36 detects the seating, and the correction value corresponding to the convergent temperature measured by the temperature sensor 32. To get. In the example shown in FIG. 12, the temperature correction value is 0.9.

Also. The odor noise attached to the subject when the subject to enter at time t _1, after the detection data detected increased by odorous gas sensor 26, converges to a constant value. Then, the seating by the seating detection sensor 36 at time t ₂ is detected. The data analysis device 60 of the remote controller 8 obtains a correction value corresponding to the detection data measured by the odorous gas sensor 26 during the non-defecation period before the seating detection sensor 36 detects the seating. In the present embodiment, the correction value of the offensive odor gas noise attached to the subject is 0.7.

Then, at time t _3, the defecation period after the seating is detected by the seating detection sensor 36, the detected value of the humidity sensor 30 when the subject urinating rises. The humidity rise detected by the humidity sensor 30 may be measured, for example, based on the humidity before the defecation period, that is, before the seating detection sensor 36 detects seating. In this way, when the humidity sensor 30 detects an increase in the detection data, the data analysis device 60 refers to the humidity correction table for the period during which the detection data is increasing, and corresponds to the increased detection data. Find the correction value. In the present embodiment, the partial correction value during the period when the data detected by the humidity sensor 30 rises (that is, times t _{3 to} t ₄ ) is 0.6.

Next, when the subject excretes at time t ₅ and t ₆ and the rate of change of the difference between the detection data detected by the odorous gas sensor 26 and the reference value becomes equal to or more than a predetermined value, the data is obtained. The analyzer 60 calculates the amount of gas associated with this excretion action. At the same time, the data analysis device 60 refers to the number correction table according to the number of excretion actions within the defecation period, and the period corresponding to the first excretion action (that is, time t _{5 to} t ₅ ') is set. , The correction value is 1.5, and the period corresponding to the second excretion action (that is, time t _{6 to} t ₆ ') is the correction value 1.0.

The data analysis device 60 calculates the measurement reliability of gas detection associated with each excretion action based on the total correction value and the partial correction value estimated in this way. In the present embodiment, the reliability is based on 3, and the reliability for each excretion action is calculated as 3 × the product of all the total correction values × the product of all the corresponding partial correction values. Specifically, the reliability of the first excretion action is 3 (reference) x 0.9 (temperature correction value) x 0.7 (subject adhesion noise correction value x 1.5 (number of times correction value) = 2.84. The reliability of the second excretion action is 3 (reference) x 0.9 (temperature correction value) x 0.7 (subject adhesion noise correction value x 1.0 (number of times correction value) = 1. It becomes 89.

Then, the reliability calculated in this way is displayed on the display device 68 of the remote controller 8 as described with reference to FIG. Further, the calculated reliability is transmitted from the subject-side device to the server 12 together with the detection data of the odorous gas sensor 26 and the detection data of the hydrogen gas sensor 24, and is recorded in the defecation gas database of the server 12. At this time, in the defecation gas database of the server 12, the detection data of the odorous gas sensor and the detection data of the hydrogen gas sensor are recorded as raw data that has not been corrected by the reliability described later. Then, when the measurement data is viewed by the medical institution terminal 16 connected to the server 12, the measurement reliability is displayed together with the detection data of the odorous gas sensor 26 and the detection data of the hydrogen gas sensor 24. The doctor of the medical institution makes a diagnosis by referring to the measurement reliability displayed together with the odorous gas and the hydrogen gas displayed on the medical institution terminal 16. As a result, when a doctor or the like diagnoses the physical condition of a subject based on the measurement data, the data with high measurement reliability can be used to make a more accurate diagnosis. In addition, the doctor may make a diagnosis without using or emphasizing data having low measurement reliability. If the reliability of a part or all of the measurement data is 1 or less, the measurement accuracy is very low. Therefore, it is not necessary to transmit the measurement data to the server 12 because the measurement is impossible.

Further, it is also possible to correct the detection data of the odorous gas sensor 26 and the hydrogen gas sensor 24 based on the measurement reliability calculated in this way as one of the predetermined first predetermined conditions. .. Specifically, when the measurement reliability is high, the actual detected value is used, but when the measurement reliability is low, the detected value becomes a value close to the past detected value (for example, the historical representative value). To correct the past history. As an example, when the subject-side device 10 analyzes the physical condition based on the detection data of the defecation gas associated with the first excretion action, it is newly detected so as to approach the past measurement data recorded in the storage device of the remote controller 8. A case of correcting the detected value will be described. As described above, the reliability associated with the first excretion act was calculated to be 2.84.

The data analysis device 60 determines the correction amount of the measured value by the past history correction based on the reliability calculated in this way. FIG. 17 is a diagram showing a correction table showing the relationship between the reliability recorded in the data analysis device and the correction factor of the measured value. As shown in the figure, for example, in the present embodiment, when the reliability is 1 or less, the reliability of the detected data is too low, so that it corresponds to one of the predetermined second predetermined conditions. , The measured value is disabled. That is, the physical condition is not analyzed based on the detection data during the period when the reliability is equal to or less than the predetermined value, the analysis is performed only based on the detection data whose reliability is higher than the predetermined value, and the analysis result is displayed on the display device 68. If the reliability is greater than 1 and less than 2, the past history correction is performed to bring the measured value closer to the past history side by 20%. That is, the plot point displayed this time is brought closer to the historical representative value by a distance of 20% of the distance between the plot point of the detected data this time and the historical representative value. Further, when the reliability of the measured value is greater than 2 and 3 or less, correction is performed to bring the measured value closer to the past history side by 15%. If the reliability is greater than 3 and less than 4, correction is performed to bring the measured value closer to the past history side by 10%. If the reliability is greater than 4 and 5 or less, correction is performed to bring the measured value closer to the past history side by 5%. When the measured value is larger than 5, the measured value is used without correction.

In the above example, the reliability associated with the first excretion act is 2.84. Therefore, as described with reference to FIG. 7A, the plot points of the latest data are corrected so as to be 15% closer to the past measured values, and are displayed together with the past data.

Note that such correction based on reliability may be performed on the server 12 side. In addition, when analyzing the physical condition on the server 12 side, for example, in the one defecation period, the detection value of the odorous gas and the detection value of the hydrogen gas of the excretion act whose reliability is equal to or higher than the predetermined value are totaled. , You may analyze your physical condition based on the total data. Further, the detection data stored in the storage device of the remote controller 8 does not necessarily have to be corrected based on the measurement reliability, and the corrected detection data may be recorded.

The correction table is not limited to the subject-attached offensive odor gas noise correction table, the temperature correction table, and the humidity correction table described above. 18 to 29 are diagrams showing an example of a correction table.

For example, if there is an offensive odor noise (environmental noise) other than defecation gas such as an air freshener in the toilet room, the odorous gas sensor 26 may detect this offensive odor noise, and the measurement accuracy may decrease. Therefore, the data analysis device 60 corrects the reliability in order to evaluate the influence of environmental noise. The amount of such environmental noise can be evaluated, for example, based on the detection data of the odorous gas sensor 26 before the entry of the subject is detected by the entry detection sensor 34. FIG. 18 is a diagram showing an environmental noise correction table. As shown in the figure, the environmental noise correction value is 1 when the noise amount of the environmental noise is smaller than the predetermined value, and is corrected to lower the reliability value as the noise amount of the environmental noise becomes larger than the predetermined value. Also reduce the coefficient. Then, when the noise amount of the environmental noise is equal to or more than the measurable upper limit value, it is considered that one of the predetermined second predetermined conditions is satisfied, and the measurement is not possible. Since the environmental noise correction value affects the entire defecation period, it may be used as an overall correction.

Further, for example, when a spray-type air freshener is used, the detection data of the odorous gas sensor 26 fluctuates greatly when setting the reference value, or when the reference value set when estimating the gas amount is used. If the slope is large, the accuracy of the estimated gas amount will be low. Therefore, the data analysis device 60 refers to the reference value stability correction table and corrects the reliability in order to evaluate the influence of such a reference value stability failure state (referred to as reference value stability failure). The reference value stability can be evaluated based on, for example, the inclination of the reference value with respect to the time axis during the non-defecation period and the magnitude of fluctuation of the detected value of the odorous gas sensor 26 when setting the reference value. FIG. 19 is a diagram showing a reference value stability correction table. As shown in the figure, the reference value stability noise correction value is 1 when the reference value stability defect is small, and becomes smaller as the reference value stability defect becomes larger. Then, when the reference value stability defect is equal to or more than a predetermined value, it is considered that one of the predetermined second predetermined conditions is met, and measurement is not possible. Since the reference value is set for each excretion act, the gas amount is estimated as a correction value only for the period corresponding to each excretion act, that is, a partial correction.

Further, for example, when the toilet seat is washed with the sterilization sheet, the odorous gas sensor 26 detects components such as alcohol contained in the sterilization sheet. As for the influence of components such as alcohol contained in the sterilization sheet, a large value is detected in the odorous gas sensor 26 immediately after using the sterilization sheet, but since alcohol is highly volatile, it is odorous in a short period of time. The value detected by the gas sensor 26 becomes low. Therefore, the data analysis device 60 refers to the sterilization toilet seat cleaning correction table and corrects the reliability according to the influence of the sterilization of the toilet seat. The sterilization sheet is used, for example, to detect the odorous gas sensor 26 after the entry detection sensor 34 detects that the subject has entered the room and before the seating detection sensor 36 detects that the subject has been seated. It can be detected by detecting that the data fluctuates more than a predetermined value. FIG. 20 is a diagram showing a disinfectant toilet seat cleaning correction table. When it is detected that the sterilization sheet has been used in this way, it is considered that one of the predetermined second predetermined conditions is met, and measurement is not possible for a predetermined period from the detection of the sterilization sheet (correction value 0). ), And the correction value for the period after that increases from a value less than 1 to 1 with the passage of time. Since the effect of the sterilization sheet changes with time as described above, it is a partial correction.

In addition, since the amount of odorous gas contained in the defecation gas is very small, the more odorous gas discharged during the defecation period, the more accurate the physical condition can be analyzed. Therefore, the data analysis device 60 refers to the defecation gas total amount correction value table and corrects the reliability based on the total amount of odorous gas. The total amount of defecation gas can be evaluated by the total amount of gas estimated based on the detection data of the odorous gas sensor during the defecation period. FIG. 21 is a diagram showing a defecation gas total amount correction value table. As shown in the figure, when the total amount of defecation gas is equal to or higher than the predetermined value, it is considered that some problem has occurred such as spraying a fragrance spray during the measurement. If one of the predetermined conditions is met, measurement is not possible (correction value 0), and if the total amount of defecation gas is less than or equal to the predetermined value, the amount of defecation gas is too small to perform accurate measurement. It is assumed that one of the second predetermined conditions is met and measurement is not possible (correction value 0). Then, within the range where it is not determined that measurement is not possible (correction value 0), the correction value is set to 1 when the total amount of defecation gas is large, and the correction value becomes smaller as the total amount of defecation gas decreases. Since the correction value is set based on the total amount of defecation gas for the entire defecation period, the total amount of defecation gas is corrected as a whole.

In addition, since a large amount of defecation gas is released into the bowl at the time of flatulence, the defecation gas by flatulence is suitable for analysis of physical condition. Therefore, when the flatulence by the subject is detected, the data analysis device 60 refers to the flatulence correction value table and corrects the reliability during the flatulence period based on the amount of defecation gas contained in the flatulence. To do. Regarding the flatulence act, when it is detected that the difference between the detection value of the odorous gas sensor 26 and the reference value suddenly increases at a rate of change of a predetermined value or more after the seating detection sensor 36 detects the seating. In addition, it can be determined that the act of flatulence has been performed. Further, the period from the time when the above difference suddenly increases until the detected value of the gas sensor 26 returns to the reference value may be set as the flatulence period. In order to more accurately detect that the act of flatulence has been performed, the detection data of the odorous gas sensor 26 rises sharply at a rate of change equal to or higher than a predetermined value, and the stool is put into the bowl by the water sealing amount sensor or the like. It suffices to detect that it has not been discharged. FIG. 22 is a diagram showing a flatulence correction value table. As shown in the figure, in the flatulence correction value table, when the amount of flatulence gas (the amount of defecation gas detected by the odorous gas sensor) is small, the correction value is 1, and as the amount of flatulence gas increases, , The correction value may be set to increase.

In addition, when the amount of stool in each excretion act is large, the amount of defecation gas is large and more accurate analysis of physical condition can be performed, but when the amount of stool in each excretion act is small, the amount of defecation gas is large. The amount is reduced and the accuracy of physical condition analysis is reduced. Therefore, the data analysis device 60 refers to the stool volume correction value table and corrects the reliability based on the stool volume at the time of each excretion act. The stool volume can be evaluated by, for example, a water sealing amount sensor (stool volume measuring device) that detects a change in the water sealing amount of the defecation / urination detecting sensor 38. FIG. 23 is a diagram showing a stool volume correction value table. As shown in the figure, when the stool volume is less than or equal to the predetermined value, the amount of defecation gas is very small as well as the stool volume, and accurate analysis cannot be performed. Therefore, 1 of the predetermined second predetermined condition It is not possible to measure because it corresponds to one. When the stool volume exceeds a predetermined value, the correction value gradually increases from a value less than 1 to a value exceeding 1 as the stool volume increases. Since the stool volume is determined for each excretion act, the stool volume correction value is a partial correction.

Further, for example, when the stool is in a diarrhea state, the release time is short, so that the sensor cannot sufficiently detect the defecation gas. Further, if the stool after defecation floats in the sealed water, the defecation gas is released from the stool floating in the sealed water, and the detection accuracy of the defecation gas is lowered. Therefore, the data analysis device 60 refers to the stool type correction table and corrects the reliability according to the stool type of each excretion act. The stool type can be detected based on the detection results by using the CCD of the defecation / urination detection sensor 38 as the stool state detection device, the microwave sensor, or the like. Further, the floating of stool can be detected by installing a CCD, a microwave sensor, or the like in the bowl as a floating detecting device. FIG. 24 is a diagram showing a flight type correction value table. As shown in the figure, in the case of diarrheal stool, it is considered that one of the second predetermined conditions set in advance is met, measurement is not possible (correction value 0), and when floating stool is detected, floating stool is detected. The correction value in the subsequent excretion action is set to a value less than 1, and when normal stool is detected, the correction value is set to 1. Since the stool type is determined for each excretion act, the stool type correction value is a partial correction. In addition, when the subject's diarrhea is detected and measurement is not possible, the message "Since it seems that you have diarrhea, physical condition measurement will not be performed." Is displayed on the display device 68, and the physical condition is analyzed. The results are not displayed normally.

In addition, healthy people usually defecate about once a day. On the other hand, if the gastrointestinal condition deteriorates due to food poisoning or the like, defecation may occur many times a day. In such a case, even if defecation is performed, the amount of defecation gas released during defecation is also reduced. In addition, when the frequency of defecation decreases due to constipation or the like, the amount of defecation gas increases due to reasons such as a longer generation time of odorous components and an increase in the amount of stool. If the defecation interval becomes too large, the accuracy of physical condition analysis will decrease. Therefore, the data analysis device 60 refers to the defecation interval correction table and corrects the reliability based on the defecation interval. The defecation interval can be determined based on the date and time of the previous defecation stored by the data analysis device 60 and the defecation history information input in the measurement start preparation step S2. FIG. 25 is a diagram showing a defecation interval correction value table. As shown in the figure, when the defecation interval is extremely short, the correction value is set to a value much lower than 1, and when the defecation interval is about 1 day, the correction value is set to 1, and the defecation interval is 2. When it is about a day, the correction value is set to a value lower than 1, and when the defecation interval is 4 days or more, the correction value is set to a value much lower than 1. The defecation interval correction value shall be the overall correction.

In the determination of the physical condition based on the defecation gas, for example, when the gastrointestinal condition deteriorates due to the cause such as eating and drinking the day before, the physical condition is judged to be worse than the original physical condition. For this reason, the analysis result of the physical condition varies depending on the daily life. Therefore, for example, when the analysis of the physical condition by the biological information measurement system of the present embodiment is started, if the days of poor physical condition happen to overlap due to overdrinking and eating, the analysis result of the poor physical condition even if the history is displayed. Only will be displayed, and there is a risk that medical institutions and the like will not be able to accurately determine the disease. Therefore, the data analysis device 60 corrects the reliability according to the number of data of the past measurement data of the subject stored in the subject side device with reference to the data storage amount correction table. FIG. 26 is a diagram showing a data storage amount correction table. As shown in the figure, if the number of accumulated data is less than 5, diagnosis is not possible (correction value 0), and if the number of accumulated data is 5 or more and less than 10 times, the correction value is 1. If the number of accumulated data is 10 times or more and less than 30 times, the correction value is set to a low value of less than 1, and if the number of accumulated data is 30 times or more, the correction value is corrected. The value is 1. The data storage amount correction value is the total correction.

That is, when the number of accumulated data is less than 5, the plot points based on the detected data this time are not displayed because it corresponds to the predetermined third predetermined condition. However, the storage device (FIG. 2) of the subject-side device stores and accumulates the detection data corrected by another reliability correction value. Therefore, the analysis result of the physical condition is not displayed on the display device 68 until the physical condition measurement for the subject reaches 5 times, and the detection data is stored in the storage device. As described above, the subject-side device in the present embodiment is not a device for diagnosing cancer, but is intended to make the subject aware that the risk of cancer is increasing with the change in physical condition and to improve the life. It is a device. For this reason, the accuracy of one measurement is not high, and the change history is the value of this device. Therefore, it is desirable to take such measures to prevent unnecessary psychological burden.

If the filter 72 installed in the duct 18a is clogged, the amount of air sucked into the duct 18a decreases. On the other hand, if the air volume of the gas sent to the odorous gas sensor 26 or the hydrogen gas sensor 24 changes, the detection data of the odorous gas sensor 26 or the hydrogen gas sensor 24 changes according to the air volume. Further, if the wind speed of the gas sent to the odorous gas sensor 26 or the hydrogen gas sensor 24 is high, the time for the gas to contact the sensor is short and the detection unit of the sensor does not sufficiently react. Therefore, it is desirable that the air volume sent to the odorous gas sensor 26 and the hydrogen gas sensor 24 is constant. Therefore, the data analysis device 60 refers to the air volume correction value table and corrects the reliability according to the air volume (wind speed) of the gas sent to the odorous gas sensor 26 and the hydrogen gas sensor 24. The gas air volume can be estimated based on, for example, the current and voltage of the suction fan 18c provided in the deodorizing device. FIG. 27 is a diagram showing an air volume correction value table. As shown in the figure, in the air volume correction table, when the air volume is less than the measurable lower limit value and more than the measurable upper limit value, it is considered that one of the predetermined second predetermined conditions is met and measurement is not possible ( The correction value is 0), the correction value is set to a value larger than 1 within the optimum air volume range, and the value is set to a value close to 1 within the other measurable range. In this embodiment, the effect of the decrease in air volume due to clogging has a greater effect on the sensor detection sensitivity than when the air volume is large, so the correction value in a range higher than the optimum range within the measurable range is The correction value in the range lower than the optimum range is set low. Since the air volume during measurement does not change significantly, it is used as an overall correction.

Like hydrogen gas, defecation gas includes CO ₂ gas as a health gas. Therefore, when a large amount of CO ₂ is detected by the CO ₂ gas sensor, the sensor device reliably detects the defecation gas. Therefore, the data analysis device 60 refers to the CO ₂ correction table and corrects the reliability based on the CO ₂ detection data detected by the carbon dioxide sensor 28. FIG. 28 is a diagram showing a CO ₂ correction table. As shown in the figure, in the CO ₂ correction table, when the detected amount of CO ₂ is less than the predetermined value, the correction value is set to 1, and when the detected amount of CO ₂ is equal to or more than the predetermined value, the value increases. The correction value is increased. Since the CO ₂ correction value can be calculated for each excretion act, it is a partial correction. As described above, in the present embodiment, since the detected hydrogen gas is corrected based on the amount of CO ₂ gas, the health gas is evaluated using hydrogen gas and CO ₂ gas.
When analyzing the physical condition using the detection data of the CO ₂ gas sensor as the detection data of the health gas, the higher the detection value detected by the hydrogen gas sensor 24 is, the more the correction value is, instead of the CO ₂ correction table. The H ₂ correction table that increases the value may be used.

Like hydrogen gas, defecation gas contains methane as a health gas. Therefore, for example, a methane gas sensor that strongly reacts with methane gas is installed in the duct 18a of the deodorizing device, and when a large amount of methane is detected by this methane gas sensor, a large amount of stool gas is released. Therefore, the data analyzer 60 refers to the methane gas correction table and corrects the reliability based on the detected amount of methane gas detected by the methane gas sensor. FIG. 29 is a diagram showing a methane gas correction table. As shown in the figure, in the methane gas correction table, when the detected amount of methane gas is less than the predetermined value, the correction value is set to 1, and when the detected amount of methane gas is more than the predetermined value, the correction value increases as it increases. Is getting bigger. Since the methane gas correction value can be calculated for each excretion act, it is a partial correction.

In the present embodiment, when the detected values of CO ₂ and methane are high, the reliability is corrected to be high, but the present invention is not limited to this, and when the detected values of CO ₂ and methane are high, hydrogen gas is used. It is also possible to make corrections that increase the detected value.

When there is cancer in the intestine, not only odorous gas but also hydrogen sulfide gas is included in the defecation gas. Therefore, for example, a hydrogen sulfide gas sensor that strongly reacts with hydrogen sulfide gas is installed in the duct 18a of the deodorizing device, and the reliability is determined based on the detection data of the hydrogen sulfide gas detected by the sensor by the hydrogen sulfide gas sensor. to correct. FIG. 30 is a diagram showing a hydrogen sulfide gas correction table. As shown in the figure, in the hydrogen sulfide gas correction table, when the detected amount of sulfide gas is less than the predetermined value, the correction value is set to 1, and when the detected amount of hydrogen sulfide gas is equal to or more than the predetermined value, it increases. The correction value is increased as the amount is increased. Since the hydrogen sulfide gas correction value can be calculated for each excretion act, it is a partial correction. The reliability is calculated using a part or all of the correction table described above.

Next, since detailed description of the method of estimating the amount of gas has been omitted in the example described with reference to FIG. 9, it will be described here.
A semiconductor gas sensor or a solid electrolyte sensor is used as the odorous gas sensor 26 for measuring the odorous gas. Gas sensors such as semiconductor gas sensors, solid electrolyte sensors, and hydrogen gas sensors react not only with odorous gases but also with fragrances and alcohol contained in disinfectant sheets.

That is, even when the subject is absent, the detection data of the gas sensor contains environmental noise due to, for example, the influence of the air freshener and the residual stool adhering to the bowl of the toilet bowl. The effects of such air fresheners and residual stools adhering to the bowl of the toilet bowl do not change significantly with time.

In addition, when the subject enters the toilet space, the detection value detected by the gas sensor slowly decreases due to the influence of the subject's body odor and the offensive odor gas components such as the perfume and hair styling products used on the subject's body and clothes. However, when the subject sits down, the upper part of the bowl is covered with the subject and clothes, so that the data value detected by the gas sensor stabilizes or slowly increases.

Further, if the subject cleans the toilet seat with the sterilization sheet, the amount of gas measured by the semiconductor gas sensor increases sharply at the moment when the sterilization sheet is used, but after sitting, that is, the sterilization sheet is used. After a while, the detection value measured by the gas sensor does not increase due to the influence of the sterilization sheet.

That is, after the subject is seated, the detection value of the gas sensor may slowly increase due to the influence of the offensive odor gas adhering to the subject's body, but it does not increase rapidly.

On the other hand, when the subject starts excretion, the gas sensor reacts with the odorous gas and hydrogen gas contained in the defecation gas at the time of each excretion, and the detection value of the gas sensor rapidly increases and peaks. After that, it decreases.

Therefore, the inventors have found that the value detected by the gas sensor does not increase sharply after the subject is seated on the toilet seat, and if this detected value is used as a reference value, the odorous gas or hydrogen gas contained in the defecation gas is used. Thought that it could be detected as a rapid increase from this standard value.

Therefore, in the present embodiment, as described with reference to FIG. 9, the data analysis device 60 excretes after the time t ₂ when it is detected by the seating detection sensor 36 that the subject is seated on the toilet seat 4. The detection data of the gas sensor in the non-excretion action period before the time t ₅ to start the above is set as the reference value. Next, the data analyzer 60 sets the time when the difference between the change rate becomes positive than a predetermined value between the detection value and the reference value of the gas sensor at the time t ₅ as the time of disclosure of bodily functions. Then, the data analysis device 60 integrates the difference between the detection value of the gas sensor at the time of excretion and the reference value over time from the start time to the end of the excretion (that is, from the reference value of the gas amount at the time of excretion). The area of the large part is calculated), and this is estimated as the amount of defecation gas. The end time of the excretion action may be a time when the detection value of the gas sensor returns to the reference value again, or a time when the rate of change of the difference between the detection value of the gas sensor and the reference value changes from positive to negative after the start time. ..

Similar to the odorous gas sensor 26, the hydrogen gas sensor 24 and the carbon dioxide sensor 28 may be affected by offensive odor noise other than defecation gas. Therefore, when estimating the gas amounts of hydrogen gas and carbon dioxide gas based on the detection data of the hydrogen gas sensor 24 and the carbon dioxide sensor 28, it is preferable to perform the same as the defecation gas.

The method for estimating the amount of gas is not limited to the above method. Hereinafter, a method for estimating the amount of gas in the biological information measurement system of the second embodiment will be described. In the second embodiment, only the method for estimating the amount of gas is different from that in the first embodiment.
In the system of this embodiment as well, as in the first embodiment, a semiconductor gas sensor or a solid electrolyte sensor is used as the odorous gas sensor 26 for measuring the odorous gas. Since the semiconductor gas sensor or the solid electrolyte sensor measures the amount of gas by detecting the reaction of the heated detection unit, the sensitivity is low. Further, the hydrogen gas sensor 24 also has low sensitivity like the semiconductor gas sensor. When a gas sensor having such low sensitivity is used, the following problems occur. The following problems are not unique to the semiconductor gas sensor, and the same applies to the solid electrolyte sensor and the hydrogen gas sensor.

For example, as shown in FIG. 31, a semiconductor gas sensor is used as the odorous gas sensor 26 for each of the conditions S1, S2, and S3 in which the total gas discharge amount of the defecation gas is constant but the discharge time and the discharge amount per hour are different. Consider the case where an odorous gas is detected. FIG. 32 is a diagram showing the detection waveform of the gas sensor when the discharge time and the discharge amount per hour are changed, and FIG. 33 shows the gas amount calculated based on the detection waveform of the gas sensor. Note that S1', S2', and S3'in FIGS. 32 and 33 correspond to S1, S2, and S3 in FIG. 31, respectively.

As shown in FIG. 32, even if the total amount of gas discharged from the defecation gas is constant, if the discharge time is different, the gas discharge waveform does not converge unless it takes about the same amount of time due to the time constant of the gas sensor. Therefore, the inventors paid attention to the inclination at the time of gas discharge. FIG. 34 is a diagram showing an initial portion of the detection waveform of the gas sensor shown in FIG. 32 with an enlarged time axis. As shown in the figure, when the discharge amount (discharge concentration) per hour is different, the slope from the start of discharge to the peak value and the time to reach the peak value are different. The larger the discharge amount (discharge concentration) per hour, the larger the slope to the peak value, and the longer the gas discharge time, the longer the time to reach the peak value. Further, FIG. 35 is a graph showing the relationship between the discharge amount (discharge concentration) per hour and the slope of the rising edge of the detection data waveform detected by the sensor. As shown in the figure, it can be said that there is a substantially proportional relationship between the discharge amount per hour (discharge concentration) and the slope of the rising edge of the waveform detected by the semiconductor gas sensor.

The inventors have found that the inclination of the waveform detected by the semiconductor gas sensor corresponds to the discharge amount (discharge concentration) of the discharged gas per hour, and the arrival time to the peak of the detected waveform by the semiconductor gas sensor corresponds to the discharge time. Based on this, it was decided to estimate the amount of gas based on the product of the slope of the detection waveform of the semiconductor gas sensor and the arrival time to the peak (gas sensor waveform area). In addition, FIG. 36 shows the product of the inclination of the detection waveform of the semiconductor gas sensor and the arrival time to the peak for each of the conditions S1, S2, and S3 in which the discharge time and the discharge amount (discharge concentration) per hour are different. The amount of gas estimated based on the gas sensor waveform area) is shown. As shown in the figure, the gas amounts S1 ″, S2 ″, and S3 ″ estimated based on the product of the slope of the gas amount waveform and the arrival time to the peak are the same amount, and the gas amount waveform. It can be seen that the accurate gas amount can be estimated based on the slope of the gas and the arrival time to the peak.

Therefore, in the present embodiment, as in the first embodiment described above, the detection data of the odorous gas sensor 26 after the time when the seating of the subject is detected by the seating detection sensor 36 and before the excretion action is started is used. Set the reference value based on. Then, as shown in FIG. 10A, the amount of defecation gas is estimated at the time when the rate of change of the difference between the detected value measured by the odorous gas sensor 26 and the reference value exceeds the preset start threshold value. Is set as the start time of (that is, the start time of the defecation act). Next, as shown in FIG. 10A, when the rate of change of the difference between the detection data detected by the odorous gas sensor 26 and the reference value becomes negative (that is, the peak of the detection data of the odorous gas sensor 26). (Time point) is set as the end time point of estimation of the defecation gas amount (that is, the end time point of the excretion act).

Next, the data analysis device 60 calculates the rate of change of the difference between the detected data and the reference value from the start time to the end time of the excretion act. In addition, the data analysis device 60 calculates the defecation gas discharge time from the start time to the end time of the excretion act. Then, the data analysis device 60 integrates the rate of change of the difference between the detected data and the reference value from the start time to the end time of the excretion act and the defecation gas discharge time, and estimates this integrated value as the gas amount. It should be noted that the estimation of the amount of hydrogen gas based on the detection data of the hydrogen gas sensor 24 and the estimation of the amount of carbon dioxide gas based on the detection data of the carbon dioxide sensor 28 can be performed in the same manner. According to the gas amount estimation method described above, the influence of the time constant of the gas sensor can be eliminated, and the defecation gas amount can be estimated more accurately.

Furthermore, when the inventors examined the relationship between the discharge amount of defecation gas per hour and the discharge time, they found that there was little individual difference in the relationship between the discharge amount and the discharge time. That is, when the amount of defecation gas discharged per hour is large, the discharge time is relatively short regardless of the subject, and when the amount of defecation gas discharged per hour is small, the discharge time is relatively short. The discharge time is long and constant regardless of the subject. Therefore, the inventors set the discharge time of the defecation gas (odorous gas) based on the hourly discharge amount of the odorous gas in the defecation gas (the rate of change of the detected value detected by the odorous gas sensor 26). I thought it could be estimated. Similarly, the defecation gas (hydrogen gas and carbon dioxide) is based on the hourly discharge amount of hydrogen gas and carbon dioxide (the rate of change of the detected values detected by the hydrogen gas sensor 24 and the carbon dioxide sensor 28). ) Discharge time can be estimated. In the present embodiment, the area is estimated so as to obtain a correlation between the amount of healthy gas and the amount of odorous gas. However, the concentration of healthy gas and the concentration of odorous gas have the same correlation, and the same applies. Since a good result can be obtained, the concentration may be obtained from the inclination of the measured value of each sensor. In this case, the area cannot be estimated, so that the measurement can be simplified.

Hereinafter, a method for estimating the amount of gas in the biological information measurement system of the third embodiment based on the above findings will be described. In the third embodiment, only the method of estimating the gas amount is different from that of the first and second embodiments. In the data analysis device 60, in addition to the start threshold value of the rate of change of the difference described in the above embodiment, the rate of change-discharge period data relating to the correspondence between the rate of change of the difference and the discharge time of the gas is set. There is.

A reference value is set based on the detection data of the odorous gas sensor 26 after the time when the subject's seating is detected by the seating detection sensor 36 and before the excretion action is started. The time when the rate of change of the difference between the detected value and the reference value measured by the odorous gas sensor 26 exceeds the preset start threshold value is defined as the start time of estimating the amount of defecation gas (that is, the start time of the excretion act). Set. Then, the data analysis device 60 refers to the rate of change-discharge period data, and acquires the discharge period data corresponding to the rate of change of the difference between the detected value at the start time and the reference value. Then, the data analysis device 60 integrates the rate of change of the difference between the detected data and the reference value at the start of the excretion action and the discharge time, and estimates this integrated value as the gas amount. It should be noted that the estimation of the amount of hydrogen gas based on the detection data of the hydrogen gas sensor 24 and the estimation of the amount of carbon dioxide gas based on the detection data of the carbon dioxide sensor 28 can be performed in the same manner. The gas amount estimation method described above can also eliminate the influence of the time constant of the gas sensor and estimate the defecation gas amount more accurately. In the gas amount estimation method of each of the above embodiments, the case where the semiconductor gas sensor is used as the odorous gas sensor 26 has been described, but the gas amount can be estimated even when the solid electrolyte sensor is used instead. It can be carried out. In the above embodiment, the data analysis device 60 obtains the rate of change of the difference, refers to the rate of change-discharge period data, and obtains the discharge period data corresponding to the rate of change of the difference between the detected value at the start time and the reference value. The gas amount was estimated based on the rate of change and the discharge period, but the present invention is not limited to this. For example, the rate of change-gas amount data in which the rate of change of the difference and the amount of gas are associated with each other is stored in advance, the rate of change of the difference is obtained, and the amount of gas is determined by referring to the rate of change-gas amount data. It may be estimated directly.

In the biometric information measurement system of the first embodiment described with reference to FIG. 1, the measuring device 6 is incorporated inside the toilet seat 4 placed on the flush toilet bowl 2 installed in the toilet room R. However, in the biometric information measuring system of the present invention, the measuring device does not necessarily have to be incorporated inside the toilet seat.

FIG. 37 (a) is a diagram showing a state in which the subject-side device in the biological information measurement system according to the fourth embodiment is attached to a flush toilet installed in the toilet room, and FIG. 37 (b) is a diagram (b). It is a perspective view which shows the measuring apparatus of the subject side apparatus shown in a). In the fourth embodiment, only the configuration of the subject-side device is different from that of the first embodiment. As shown in FIG. 37 (a), the biological information measurement system 101 of the present embodiment has the same configuration as that of the first embodiment, but only the configuration of the measuring device 106 of the subject-side device 110 is different. The measuring device 106 of the present embodiment is configured separately from the toilet seat 104.

As shown in FIG. 37 (b), the measuring device 106 is attached to the device main body 180, a duct 118a which is attached to the upper surface of the device main body 180 so as to extend laterally and whose tip is bent downward, and the device. Includes a power cord 182 connected to the main body 180. As shown in FIG. 37 (a), the measuring device 106 is fixed in a state where the tip of the duct 118a is located in the bowl by hooking the tip of the duct 118a on the side wall of the bowl of the flush toilet 2. ..

Similar to the first embodiment, the device main body 180 includes a hydrogen gas sensor, an odorous gas sensor, a carbon dioxide sensor, a humidity sensor, a temperature sensor, a room entry detection sensor, a seating detection sensor, and a stool / urine detection sensor. , A suction device, a sensor heater, and a transmitter / receiver. The gas taken in from the duct 118a is deodorized and discharged from the deodorized air outlet provided on the bottom surface of the apparatus main body 180. A hydrogen gas sensor, an odorous gas sensor, a carbon dioxide sensor, a humidity sensor, a temperature sensor, a sensor heater, and a fan are provided in the duct 118a. Since the arrangement of the sensors in the duct 118a is the same as that of the first embodiment, the description thereof will be omitted. With such a configuration, the measuring device 106 of the present embodiment also uses the odorous gas sensor, the hydrogen gas sensor, and the carbon dioxide sensor to determine the amount of odorous gas, hydrogen gas, and carbon dioxide contained in the stool gas. It is possible to acquire the corresponding detection data.

The toilet seat 104 used together with the measuring device 106 of the present embodiment includes a toilet lid opening / closing device, a nozzle driving device, a nozzle cleaning device, a toilet cleaning device, and a toilet sterilization device. It is desirable to use a toilet seat with a cleaning function that can communicate with. By using the measuring device 106 together with such a toilet seat, it becomes possible to perform various cleaning and sterilizing operations when an offensive odor gas is detected.

Further, in the first embodiment, as shown in FIG. 3, the gas detection device 20 is configured to provide the hydrogen gas sensor 24 on the downstream side of the deodorizing filter 78, but it is not always necessary to have such a configuration. FIG. 38 is a diagram showing a configuration of a gas detection device in the biological information measurement system of the fifth embodiment. In the fifth embodiment, only the configuration of the gas detection device is different from that of the first embodiment. As shown in the figure, in the present embodiment, the arrangement of the hydrogen gas sensor 24 in the gas detection device 120 is different from that in the embodiment shown in FIG. In the present embodiment, the hydrogen gas sensor 24 is provided downstream of the deodorizing filter 78 in the intake passage 18b. According to such a configuration, even when a sensor that reacts not only with hydrogen gas but also with odorous gas is used as the hydrogen gas sensor 24, the influence of the odorous gas can be determined from the data output by the hydrogen gas sensor 24. Can be removed.

Further, in the first embodiment, the effect of hydrogen gas is separated and the detected value of odorous gas is calculated by subtracting the detected value detected by the hydrogen gas sensor 24 from the detected value detected by the odorous gas sensor 26. However, the present invention is not limited to this, and for example, it is possible to separate the influence of hydrogen gas by shifting the arrival times of hydrogen gas and odorous gas to the odorous gas sensor 26 as described below. ..

FIG. 39 is a diagram showing a configuration of a gas detection device of a sixth embodiment configured to separate the influence of hydrogen gas by shifting the arrival times of hydrogen gas and odorous gas to the odorous gas sensor. .. In the sixth embodiment, only the configuration of the gas detection device is different from that of the first embodiment. As shown in the figure, in the present embodiment, a branch path 283b branching from the main path 283a of the intake passage 18b in the duct 18a is provided. In the first embodiment, the hydrogen gas sensor and the odorous gas sensor are separately provided, but in the present embodiment, both the hydrogen gas and the odorous gas are detected by one semiconductor gas sensor.

Similar to the first embodiment, the intake passage 18b is provided with a filter 72, a deodorizing filter 78 provided downstream of the filter 72, and a suction fan 18c, and the branch path 283b is on the downstream side of the filter 72. Branches at. The filter 72 is a filter that does not have a deodorizing function and passes through odorous gas and hydrogen to prevent the passage of foreign substances such as urine and cleaning agents. Further, the deodorizing filter 78 is also a catalyst that adsorbs a gas component such as an odorous gas, as in the first embodiment.

The defecation gas in the bowl 2a of the toilet bowl is sucked into the intake passage 18b by the suction fan 18c at a constant flow rate. The defecation gas sucked into the intake passage 18b passes through the filter 72 to remove foreign substances such as urine and a cleaning agent, and the deodorizing filter 78 removes gas components such as odorous gas. Returned to bowl 2a.

The branch path 283b is provided with a flow path switching valve 284, a column 286, a semiconductor gas sensor 288, and a pump 290 in this order from the upstream side to the downstream side.

The flow path switching valve 284 is opened only for a part of the time during the excretion action (for a very short time), and a part of the defecation gas flowing in the intake passage 18b (for a part of the time during the excretion action of the subject) is released. It is a valve for drawing into the branch path 283b. The flow path switching valve 284 is provided at the uppermost stream of the branch path 283b.

The column 286 is provided on the downstream side of the flow path switching valve 284, and is configured by filling an elongated pipe with, for example, a fine fiber material. The column 286 is a mechanism that causes a difference in the passage time of gas depending on the size (molecular weight) of the molecule according to the principle of gas chromatography.

On the upstream side of the semiconductor gas sensor 288, a sensor heating heater 54 for heating the detection unit of the semiconductor gas sensor 288 to a predetermined temperature and removing the offensive odor gas component adhering to the semiconductor gas sensor 288 is provided.

The flow path switching valve 284 allows a small amount of defecation gas that has passed through the filter 72 flowing through the intake passage 18b to flow into the branch passage 283b. Then, when the pump 290 is driven, the hydrogen and the odorous gas contained in the defecation gas pass through the column 286 over a different time depending on the molecular weight and reach the semiconductor gas sensor 288 according to the principle of gas chromatography. That is, hydrogen having a small molecular weight easily passes through the column 286 and reaches the semiconductor gas sensor 288 in a short time, and odorous gas having a large molecular weight does not easily pass through the column 286 and reaches the semiconductor gas sensor 288 in a longer time than hydrogen. To reach. The pump 290 is configured to suck the defecation gas at a constant flow rate.

FIG. 40 is a diagram showing a detection waveform detected by the semiconductor gas sensor of the gas detection device shown in FIG. 39. As shown in the figure, according to the configuration of the gas detection device 220 of the present embodiment, the semiconductor gas sensor 288 reacts with hydrogen gas and odorous gas in a state of being separated in time. In particular, the act of excretion is performed in a short time, and the defecation gas containing hydrogen and odorous gas is also released only for a short time. Since the release of the defecation gas is short in this way, by providing the column 286 upstream of the semiconductor gas sensor 288, the time required for the hydrogen gas and the odorous gas to reach the semiconductor gas sensor can be staggered. The semiconductor gas sensor 288 can detect the amount of hydrogen gas and the amount of odorous gas. Again, the inventors have adopted a method in which the physical condition is judged by the correlation between health gas and odorous gas without measuring the total amount of methyl mercaptan gas that correlates with cancer. Is based on the technical knowledge found that only the measurement of gas for a specific period is sufficient. It is cheap to use a reduction sensor, but it is difficult to separate a large amount of hydrogen contained in the defecation gas. On the other hand, according to the present embodiment, since the measurement is performed only for a small amount for a specific period, hydrogen separation becomes easy and practicality can be realized with an extremely inexpensive sensor.
In the present embodiment, the arrival time of hydrogen and odorous gas to the semiconductor gas sensor 288 is shifted by the column 286, but it is naturally possible to shift the arrival time of methane contained in the defecation gas. .. This makes it possible to separate the effects of methane as well as hydrogen from the detection data detected by the semiconductor gas sensor.

Next, the biometric information measurement system according to the seventh embodiment of the present invention will be described with reference to FIG. 41.
In the first embodiment described above, plot points indicating the physical condition are displayed on the physical condition display table based on the detected odorous gas and hydrogen gas detection data. The present embodiment differs from the above-described first embodiment only in that the positions of the plot points displayed on the physical condition display table are corrected based on the detection data of carbon dioxide gas. Therefore, here, only the points different from the first embodiment of the present embodiment will be described, and the description of the same configuration and the like will be omitted.

FIG. 41A is a diagram showing an example of correction of plot points displayed on the physical condition display table. FIG. 41B is a diagram showing an example of a correction amount based on the detected amount of carbon dioxide gas.
As described in the first embodiment, on the physical condition display table, the analysis result of the physical condition of the subject is plotted with the odorous gas as the first index and the healthy gas hydrogen gas as the second index. Is displayed by. In addition, on the physical condition display table, as an analysis result, in addition to the plot points based on the detection data detected in the current defecation action, the plot points based on the past detection data are also displayed. Further, the display position of the plot point this time is corrected (FIG. 17) so as to approach the center of gravity position G of the past data, which is a historical representative value, based on the reliability of the measurement this time. That is, in the first embodiment, in FIG. 41A, when the plot point based on the raw data of the detected data this time is "1", the display position of this plot point approaches the center of gravity position G of the past data. As shown above, the past history is corrected and displayed at the position of "1'" (actually, the plot point of "1" is not displayed). Further, the position of the plot point "1" is corrected more greatly as the reliability of the measurement this time is lower, and is brought closer to the center of gravity position G (the plot point "1'" is moved closer to the center of gravity position G).

On the other hand, in the present embodiment, the position of the plot point "1'" whose past history has been corrected based on the reliability is further corrected based on the detection data of carbon dioxide gas. That is, carbon dioxide gas is a gas that is discharged in large quantities when the intestinal condition is good, and in the present embodiment, carbon dioxide gas, which is a health gas different from the second index, is used as the third index. Perform correction as an indicator. Therefore, in this measurement, even if the detection data of odorous gas and hydrogen gas show poor physical condition, if a certain amount of healthy gas such as carbon dioxide gas is emitted. , It can be judged that the condition in the intestine is not necessarily bad. Therefore, in the present embodiment, the correction amount (correction amount between the plot points "1" → "1'") by the past history correction in the detection data this time is used as the detection data of carbon dioxide gas which is the third index. Based on this, the correction is made to the side in which the physical condition is good (healthy side, to the right in FIG. 41 (a)).

FIG. 41B is an example of a correction amount based on the amount of carbon dioxide gas in the defecation gas.
For example, when the detected amount of carbon dioxide gas corresponds to the correction of "20%", the plot point "1'" is the distance corresponding to 20% of the distance between the plot points "1" → "1'". The plot point is displayed at the position of "1""that is moved to the healthy side (to the right in FIG. 41 (a)) (actually, the plot points" 1 "and"1'" Is not displayed). Further, as shown in FIG. 41 (b), the correction amount of the plot points to the healthy side (good physical condition side) increases as the amount of detected carbon dioxide gas increases. In this way, by correcting the position of the plot points displayed on the display device to the side of good physical condition based on the amount of carbon dioxide gas, the intestinal condition of the subject becomes more multifaceted to the plot points on the physical condition display table. Since it is reflected, the reliability of the physical condition presented to the subject can be improved.

Further, in the seventh embodiment described above, a physical condition display table is created using odorous gas as the first index and hydrogen gas as the second index, and correction is performed using carbon dioxide gas, which is the third index. However, other gases can be used as a modification. For example, at least two gases are selected from hydrogen gas, methane gas, acetic acid gas, propionic acid gas, butyric acid gas and the like known as health gas, one of which is used as a second index and the other is a third. It is also possible to analyze the physical condition of the subject as an index of. The amount of gas such as acetic acid gas, propionic acid gas, butyric acid gas, etc. can be detected by using the column or the like described in the sixth embodiment described above.

Further, in the above-mentioned seventh embodiment, the physical condition of the subject was measured by two kinds of health gas and an odorous gas, but as a modification, a plurality of gases that are indicators of poor physical condition and one kind. It is also possible to measure the physical condition of the subject by using the health gas of. For example, the physical condition display table is constructed by using the detection data of the gas sensors that react with a plurality of odorous gases as the first index and the detection data of the gas sensors that react with the hydrogen gas as the second index. The present invention can also be configured to correct the plot points on the physical condition display table by using, for example, the detection data of hydrogen sulfide gas different from the first index as the fourth index. In this case, the positions of the plot points determined by the first index and the second index are moved to the side of poor physical condition based on the amount of hydrogen sulfide gas, which is the fourth index. That is, when the amount of hydrogen sulfide gas is equal to or more than a predetermined amount, the correction amount by the past history correction in the current detection data is the side showing poor physical condition based on the detection data of hydrogen sulfide gas which is the fourth index. (Upward in FIG. 41 (a)) is corrected. In addition, the amount of correction for the poor physical condition of the plot points increases as the amount of hydrogen sulfide gas detected increases.

Next, with reference to FIG. 42, a further modification of the biological information measurement system according to the seventh embodiment of the present invention will be described.
In the seventh embodiment and its modification described above, the correction amount of the past history correction (correction of the plot points "1" → "1'") of the plot points of the detected data this time is used as another index (third). Based on the detection data of (index: carbon dioxide gas or fourth index: hydrogen sulfide gas), it is corrected to the healthy side or the poor physical condition side (correction of plot points "1'" → "1""). It was. On the other hand, in this modification, the plot points after the past history correction based on the reliability (plot point "1'" in FIG. 41 (a)) are directly corrected based on the detection data of carbon dioxide gas. The point is different from the seventh embodiment.

As shown in FIG. 42 (a), in this modification, the plot points on the physical condition display table are directly corrected based on the correction amount set based on FIG. 42 (b). That is, when the detected carbon dioxide gas amount detection data corresponds to "10% up" in FIG. 42 (b), the plot points after the past history correction based on the reliability (FIG. 42 (a)). The value of the hydrogen gas amount (healthy gas amount) of "1 ^* " and (corresponding to "1'" in FIG. 41 (a)) is corrected to a value increased by 10%. As a result, the plot point "1 ^* " in FIG. 42 (a) is translated along the axis of the amount of hydrogen gas (horizontal axis in FIG. 42 (a)) and moved to the plot point "1 ^** ". To. In other words, in the embodiment described with reference to FIG. 41, the correction amount by the past history correction is corrected based on another index (third or fourth index), whereas the present modification shown in FIG. 42 is used. Then, the analysis result corrected in the past history is corrected to the health side based on the detection data of the amount of carbon dioxide gas which is the third index.

In this way, by correcting the position of the plot point displayed on the display device to the healthy side (to the right in FIG. 42 (a)) based on the amount of carbon dioxide gas, the intestinal condition of the subject is more multifaceted. Since it is reflected in the plot points on the physical condition display table, the reliability of the physical condition presented to the subject can be improved. Further, in this modification, since the plot points on the physical condition display table are simply translated along the axis of the amount of healthy gas, it can be corrected by a simple calculation. As in the modification of the embodiment described with reference to FIG. 41, the plot points after the past history correction are used, for example, the hydrogen sulfide gas detection data as the fourth index, and the side of poor physical condition (FIG. 42 (a)). The present invention can also be configured to correct in the upward direction in)).

Next, the biological information measurement system according to the eighth embodiment of the present invention will be described with reference to FIG. 43.
In the above-described first embodiment, plot points based on the detection data of the past 30 days are displayed on the physical condition display table, but in the present embodiment, the analysis results over a long period of the past are further displayed. It differs from the above-described first embodiment only in that it has a physical condition display table. Therefore, here, only the points different from the first embodiment of the present embodiment will be described, and the description of the same configuration and the like will be omitted.

As shown in FIG. 43, in the present embodiment, the past analysis results are collectively plotted on the physical condition display table as a plurality of historical representative values for each predetermined period. That is, in the present embodiment, the center of gravity point of the analysis result measured this year is displayed as a plot point "0" on the physical condition display table as one history representative value. Similarly, past analysis results are summarized for each year and each historical representative value is determined. The center of gravity of the analysis results measured last year is the plot point "1", two years ago is "2", and three years. The front is "3". .. .. Is shown as a plot point on the physical condition display table. This makes it possible for the subject to easily recognize the changing tendency of the vast amount of past analysis results. In the example shown in FIG. 43, the physical condition change of a certain subject over the past 10 years is displayed on the physical condition display table, and under the physical condition display table, "Improvement required: It seems that the physical condition is getting worse year by year. The message "Let's have a good lifestyle!" Is displayed. The physical condition display table shown in FIG. 43 is provided in addition to the physical condition display table (FIG. 6) in the first embodiment, and is shown in FIG. 43 by operating a button from the physical condition display table of FIG. The physical condition display table is displayed. Further, in the present embodiment, the analysis results are collectively determined for each year, but the historical representative value is determined and displayed for every arbitrary period such as several months, half a year, several years, and the like. be able to.

According to the biological information measurement system of the embodiment of the present invention, the physical condition of the subject analyzed based on the detection data is corrected according to a predetermined first predetermined condition (FIGS. 7 (a) and 41 (a)). ), FIG. 42 (a)), and the corrected analysis result is displayed on the display device 68. Therefore, even if the analysis result changes significantly for each measurement due to noise components, other disturbances, temporary changes in physical condition, etc., those effects are reduced from the analysis result displayed by the correction. be able to. Therefore, even if the analysis result of each measurement contains a large measurement error, it is possible to present a relatively reasonable analysis result to the subject, and the analysis result of the physical condition displayed in each measurement can be presented. The reliability can be improved, and it is possible to prevent the subject from giving an unnecessary psychological burden due to the measurement error.

Further, according to the biological information measurement system of the embodiment of the present invention, the physical condition display correction circuit 60a corrects the measurement data based on the measurement reliability of the measured value (FIGS. 7 (a), 41 (a), Since FIG. 42 (a)), even if the analysis result of each time contains a large error, it is possible to present a highly reliable analysis result to the subject, and it is possible to improve the reliability of the physical condition measurement. it can.

Further, according to the biometric information measurement system of the embodiment of the present invention, the historical representative values (center of gravity G (X _G , Y _G ), weighted center of gravity G (X _GW , Y _GW )) are determined based on the past analysis results. Since the analysis result of the physical condition to be determined and displayed this time is corrected in the direction approaching the historical representative value (Fig. 7 (a)), the newly displayed analysis result of the physical condition is related to the past analysis result. It is possible to have it. As a result, it is possible to prevent the newly displayed analysis result from deviating significantly from the previously displayed analysis result due to the occurrence of a large measurement error, and the reliability of the displayed physical condition analysis result can be improved. Can be improved.

Further, according to the biological information measurement system of the embodiment of the present invention, the correction amount (“1” → “1'” in FIG. 7A) by the past history correction depends on the reliability of the detected data this time. Since it is changed (FIG. 17), more accurate correction can be performed according to the reliability of the detected data, and the reliability of the analysis result of the displayed physical condition can be improved.

Further, according to the biometric information measurement system of the embodiment of the present invention, the historical representative value is determined based on the results of a plurality of past analyzes (mathematical formulas (1) and (2)), so that the values are mixed in each physical condition measurement. It is possible to offset the error and correct the analysis result so that the value becomes more accurate.

Further, according to the biological information measurement system of the embodiment of the present invention, since the analysis result after correction is stored in the storage device in the remote controller 8, the analysis result of the physical condition presented to the subject is greatly deteriorated due to the measurement error. However, it is possible to prevent the subject from giving an unnecessary psychological burden. On the other hand, the analysis result before correction is stored on the server 12 side, but since it is assumed that the detection data on the server 12 side is referred to by a specialist such as a doctor, the measurement error of the detection data is appropriate. It is possible to take this into consideration, and by referring to the raw data before correction, a more appropriate diagnosis of the disease can be made.

Further, according to the biological information measurement system of the embodiment of the present invention, when the noise in the measurement is large, the correction amount by the past history correction is increased (FIGS. 17 to 20), so that the analysis result of this time is more historical. It is corrected to a value close to the representative value (FIG. 7 (a)). As a result, it is possible to prevent the analysis result of the displayed physical condition from being deteriorated by the detection data having a large noise and giving an unnecessary psychological burden to the subject.

Further, according to the biological information measurement system of the embodiment of the present invention, when the amount of healthy gas is a predetermined amount or more (FIGS. 41 (b) and 42 (b)), the displayed analysis result is in good physical condition. ("1'" → "1""in Fig. 41 (a)," 1 ^* "→" 1 ^** "in Fig. 42 (a)), so the influence of noise etc. is reduced. Therefore, more reasonable analysis results can be presented to the subject.

Further, according to the biometric information measurement system of the embodiment of the present invention, in addition to the first and second indexes by the odorous gas and the health gas (hydrogen gas), another health gas (carbon dioxide gas) is added. Since the correction is performed as the third index, the physical condition of the subject can be evaluated from multiple aspects, and the analysis result of the physical condition with higher reliability can be presented to the subject.

Further, according to the biometric information measurement system of the embodiment of the present invention, the detection data of this time is determined in advance by a second predetermined condition (FIGS. 13 to 15, FIGS. 18 to 21, FIG. 23, FIG. 24, FIG. In the case of 26 and 27), since the normal analysis result (FIGS. 5 and 6) is not displayed on the display device 68, the abnormal analysis result due to the abnormal detection data causes an unnecessary psychological burden on the subject. Can be prevented from giving.

Further, according to the biological information measurement system of the embodiment of the present invention, when the number of physical condition analysis results is less than or equal to a predetermined number, the analysis results are stored in the storage device, while the physical condition analysis results are stored in the display device. Since it is not displayed (FIG. 26), the detection data can be accumulated while presenting an unreliable analysis result and preventing the subject from giving an unnecessary psychological burden.

Further, according to the biological information measurement system of the embodiment of the present invention, the analysis result is corrected so that the distance from the historical representative value is equal to or less than a predetermined value (FIG. 7B), so that the abnormal analysis result is obtained. The display can prevent the subject from being overly psychologically burdened.

Further, according to the biometric information measurement system of the embodiment of the present invention, past analysis results are collected for each predetermined period, each history representative value is determined, and each history representative value is displayed on the display device 68 ( Since FIG. 43), it is possible to present a huge number of changes in the past analysis results in a state in which the subject can easily recognize them.

Although the preferred embodiment of the present invention has been described above, various modifications can be made to the above-described embodiment. In particular, the configurations provided in the plurality of embodiments and modifications described above can be appropriately combined according to the application to form the biometric information measurement system of the present invention.

In addition, the above-described embodiment of the present invention sucks and analyzes the defecation gas discharged into the bowl of the toilet bowl, but when analyzing the physical condition of a bedridden patient or the like as a subject, the toilet bowl is used. It is also possible to collect defecation gas from other than the bowl. For example, in the embodiment shown in FIG. 37, a suction pipe can be connected to the tip of the duct 118a, and defecation gas can be collected directly from the subject through the suction pipe. In this case, a sheet-shaped defecation gas collecting device (not shown) is connected to the tip of the suction pipe, and this sheet-shaped defecation gas collecting device is incorporated into the bedding (mattress or comforter) of the subject. By setting the pressure, the defecation gas discharged by the subject can be sucked. The sucked defecation gas is sucked from the duct 118a through the suction pipe, and the detection data is acquired by the gas sensor incorporated in the apparatus main body 180. Alternatively, a defecation gas collecting device can be incorporated into the subject's underwear or diaper. It is also possible to directly incorporate a gas sensor necessary for the subject's bedding, underwear, diapers, etc. to measure defecation gas and analyze the physical condition. In this case, preferably, the detection data by the gas sensor is wirelessly transmitted to the subject-side device or the server.

Further, in the above-described embodiment, hydrogen gas, methane gas, carbon dioxide gas, etc. were detected as the healthy gas, but in many subjects, the defecation gas contained hydrogen gas as the healthy gas. While methane gas is not contained, in some subjects, methane gas is contained in the stool gas, but hydrogen gas is not contained, according to the research by the present inventors. .. Therefore, when measuring a healthy gas, it is preferable to provide a gas detection device capable of detecting both hydrogen gas and methane gas. Further, in the case of a device for a specific subject whose discharge of which health gas is known, it is possible to configure the device so that only one of the gases can be detected.

R Toilet room 1 Biological information measurement system according to the first embodiment of the present invention 2 Washing toilet bowl 2a Bowl 4 Toilet seat 6 Measuring device 8 Remote control 10 Subject side device 12 Server 14 Subject terminal 16 Medical institution terminal 18 Suction device 18a Duct 18b Intake Toilet 18c Suction fan 20 Gas detector 22 Control device 22a CPU
22b Storage device 24 Hydrogen gas sensor 26 Odorous gas sensor 28 Carbon dioxide sensor 30 Humidity sensor 32 Temperature sensor 34 Entrance detection sensor 36 Seating detection sensor 38 Defecation / urination detection sensor 40 Toilet lid opening / closing device 42 Nozzle drive device 44 Nozzle cleaning device 46 Toilet cleaning Equipment 48 Toilet disinfectant device 50 Fragrance sprayer 52 Deodorizing air supply device 54 Sensor heating heater 56 Transmitter / receiver 58 Duct cleaner 59 Humidity control device 60 Data analysis device 60a Physical condition display correction circuit 62 Subject identification device 64 Input device 66 Transmitter / receiver 68 Display device 70 Speaker 72 Filter 78 Deodorizing filter 101 Biometric information measurement system 104 Toilet seat 106 Measuring device 118a Duct 180 Device main body 182 Power cord 120 Gas detection device 283a Main path 283b Branch path 284 of the fifth embodiment Flow path switching valve 286 Column 288 Semiconductor gas sensor 290 Pump

Claims (15)

A biometric information measurement system that measures the physical condition of a subject based on the defecation gas discharged into the bowl of the flush toilet located in the toilet installation space where the flush toilet is installed.
A suction device that sucks the gas in the bowl from which the defecation gas has been discharged by the subject,
A gas detector equipped with a gas sensor that reacts with an odorous gas containing a sulfur component contained in the defecation gas sucked by this suction device, and
A control device that controls the suction device and the gas detection device,
A data analysis device that analyzes the physical condition of the subject based on the detection data detected by the gas detection device, and
It has a display device that displays the analysis result by this data analysis device, and
The data analysis device includes a physical condition display correction circuit that corrects the detection data according to a predetermined first predetermined condition and displays the corrected analysis result on the display device.
This physical condition display correction circuit determines the reliability of the measured value with respect to the physical condition of the subject, corrects the detection data based on the measurement reliability of the measured value, and obtains the corrected physical condition analysis result. A biological information measurement system characterized by displaying on a display device. Further, it has a subject identification device for identifying a subject who uses the flush stool, and a storage device for storing the analysis result of the physical condition by the data analysis device for each subject specified by the subject identification device. The physical condition display correction circuit determines the historical representative value based on the past analysis result displayed on the display device for the subject, and the analysis result of the physical condition to be displayed this time is in the direction of approaching the historical representative value. The biometric information measurement system according to claim 1, wherein the past history correction to be corrected is executed. The biometric information measurement system according to claim 2, wherein the physical condition display correction circuit changes a correction amount close to the history representative value by the past history correction according to the measurement reliability of the current detection data by the gas detection device. The history representative value sets the weighting for the latest past to be larger than the weighting for the distant past for the center of gravity points of the past plurality of analysis results displayed on the display device for the subject, or for the past plurality of analysis results. The biometric information measurement system according to claim 3, which is determined as the center of gravity point calculated in the above. Further, it has a server configured to be able to receive the analysis result by the data analysis device, the storage device stores at least the analysis result after correction by the physical condition display correction circuit, and the server stores at least the above-mentioned analysis result. The biometric information measurement system according to claim 3, wherein the analysis result before correction by the physical condition display correction circuit is stored. The biometric information measurement system according to claim 3, wherein the physical condition display correction circuit increases the amount of correction by the past history correction when the noise in the current measurement is large, as compared with the case where the noise is small. The gas detection device is configured to detect a large amount of healthy gas discharged from a healthy subject, and the physical condition display correction circuit displays an analysis result when the amount of the healthy gas is a predetermined amount or more. The living body according to claim 3, wherein the correction amount by the past history correction is changed so that the gas approaches the side showing good physical condition, or the analysis result corrected by the past history is corrected to the side showing good physical condition. Information measurement system. The gas detector is configured to detect at least two healthy gases selected from hydrogen gas, carbon dioxide gas, methane gas, acetic acid gas, and propionic acid gas, and the data analyzer is odorous. The physical condition display is configured to display the analysis result on the display device as a point on the physical condition display table using gas as the first index and at least one of the health gas as the second index. The correction circuit uses the amount of health gas that is not used in the second index of the health gas as the third index, and is displayed when the third index is equal to or more than a predetermined value. 7. The amount of correction by the past history correction is changed so that the analysis result is closer to the side showing good physical condition, or the analysis result corrected by the past history is corrected to the side showing good physical condition. The described biometric information measurement system. The gas detection device is configured to detect at least two types of the odorous gas and a healthy gas emitted in large quantities from a healthy subject, and the data analysis device is configured to detect at least one of the odorous gases. It is configured to display the analysis result on the display device as a point on the physical condition display table using one as the first index and the health gas as the second index, and the physical condition display correction circuit has the odor. The amount of a specific odorous gas among the sex gases is used as the fourth index, and when this fourth index is equal to or higher than a predetermined value, the displayed analysis result approaches the side showing poor physical condition. The biometric information measurement system according to claim 3, wherein the correction amount by the past history correction is changed, or the analysis result corrected by the past history is corrected to the side showing poor physical condition. When the detection data of this time corresponds to a predetermined second predetermined condition, the data analysis device displays a normal analysis result in the case where the second predetermined condition is not met on the display device. The biometric information measurement system according to claim 3, wherein the physical condition display correction circuit does not use the current detection data or reduces the weighting of the current detection data in the subsequent determination of the historical representative value. When the third predetermined condition is satisfied, the data analysis device stores the detection data or the analysis result of the physical condition based on the detection data in the storage device, and stores the analysis result of the physical condition in the storage device. The biometric information measurement system according to claim 3, which is not displayed on the display device. The eleventh aspect of claim 11, wherein the data analysis device determines that the third predetermined condition is satisfied when the number of physical condition analysis results stored in the storage device for a specific subject is less than or equal to a predetermined number. Biometric information measurement system. The biometric information measurement system according to claim 3, wherein the physical condition display correction circuit corrects the analysis result of the physical condition to be displayed this time so that the distance from the historical representative value is equal to or less than a predetermined value. In the above-mentioned past history correction, when the above-mentioned past history correction executed in the latest past continuously corrects poor physical condition to the side of good physical condition for a predetermined number of times or more, the above-mentioned physical condition display correction circuit may perform the above-mentioned past history correction. The biometric information measurement system according to claim 3, wherein the correction amount for correcting poor physical condition to the side of good physical condition is reduced. The physical condition display correction circuit collects the past analysis results displayed on the display device for the subject and determines each of the history representative values for each predetermined period, and the data analysis device determines each history representative value. The biometric information measurement system according to claim 3, wherein the above-mentioned display device is displayed.