JP2011103087A - Dietary management system and dietary management method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a dietary management system that enables a user to enter accurate dietary content before forgetting the dietary content. <P>SOLUTION: The dietary management system includes an exhalation component detection means for detecting gas components in exhalations, a dietary intake determination means for determining a user's dietary intake from oxygen and carbon dioxide gas volumes in exhalations detected by the exhalation component detection means, a dietary content inquiry means for inquiring the dietary content of the user when the determination means determines the user's dietary intake, a dietary content input means for allowing the user to input the dietary content, and a storage means for storing the user's dietary content input. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a meal management system for managing a user's meal using a portable terminal.

  In recent years, an increasing number of people suffer from cardiovascular diseases caused by lifestyle-related diseases such as diabetes and hypertension. Lifestyle-related diseases may be due to genetic factors, but many are caused by unhealthy daily life such as inappropriate diet and lack of exercise. Lifestyle-related diseases due to unhealthy daily life can be prevented by improving daily life, such as improving dietary habits and conducting moderate exercises. To this end, the user's daily life (food habits, exercise) must be ensured. Therefore, a management system that can grasp and manage and promote life improvement is required.

  As for exercise management, pedometers have been widely used in the past, and pedometers are highly convenient because they can easily manage exercises.

  On the other hand, with regard to the management of eating habits, it is necessary to manage meal contents such as a meal intake time zone, a menu, and a meal amount, but this is not easy. For example, if it is an inpatient, the hospital side (meal provider) can accurately manage and grasp the contents of the meal. However, in the case of non-hospitalized patients, it is necessary to manage the meal time and meal contents by themselves, but since meals are extremely daily matters, forgetting to record them or uncertain contents collectively including meals It is easy to record. For this reason, it is difficult for a person who needs meal management to manage all the contents of the meal himself, and the recording becomes inaccurate.

  Regarding forgetting to record, a method of prompting the user to record meal contents at a predetermined time is also conceivable. However, since the user's life rhythm is diverse, this method may cause a phenomenon such as prompting the recording of meal contents during a meeting or during sleep. Therefore, there is a problem that it cannot be adapted to the actual life rhythm of the user.

  There exists patent document 1 as a technique regarding meal management. Patent Document 1 discloses a life management system that detects a signal related to a meal and inquires a user of a meal record after a predetermined time has elapsed since the detection. In this technique, a pulse, skin conductivity, skin temperature, GSR (skin electrical reflection), mastication frequency, mastication interval, photoelectric pulse wave, and the like are used as signals related to meals. For this reason, it is necessary to have a user wear a detection device for detecting these signals. This technology that requires various devices to be mounted has a problem of imposing an excessive burden on the user.

: JP 2003-173375 A

  The present invention has been made in view of the above, monitors a user's eating behavior with a simple method, prompts a meal record when it is determined that a meal has been taken, and causes the user to record the meal content. The purpose is to provide a meal management system.

  A first aspect of the present invention related to a meal management system for solving the above-described problems includes an expiration component detection means for detecting a gas component in expiration, an amount of oxygen gas in the expiration detected by the expiration component detection means, Meal intake determination means for determining the user's meal intake based on the amount of carbon gas, a meal content inquiry means for inquiring the user about the meal content when the determination means determines that the user has eaten the meal, and the user It is provided with the meal content input means which inputs, and the memory | storage means which memorize | stores the input of a user's meal content, It is characterized by the above-mentioned.

  According to the meal management system of this configuration, when the user eats (when food is consumed), the expiration component detection means and the meal intake determination means detect that the meal has been eaten, and the meal content inquiry means promptly eats the user. Inquire about the contents (contents of food intake). Therefore, the user can enter the exact meal content via the meal content input means before forgetting the meal content. Since this content is recorded in the storage means, it is possible to appropriately manage the user's eating habits by utilizing this information.

Here, the amount of CO ₂ gas and O ₂ gas in the exhalation changes depending on the energy metabolism state at that time, and the energy consumption at that time is calculated using the Zuntz Schmburg-Lusk equation (the following equation 2). It is known that it can be sought. Then, from this energy consumption and the basal metabolic rate (which can be calculated by the following mathematical formula 1), the motion intensity (life activity strength) Af can be calculated (see the following mathematical formula 3). In addition, it is known that the action intensity of eating behavior is about 1.4, and by determining whether it is close to 1.4 (for example, whether it is 1.3 to 1.5), The presence or absence of a user's meal intake can be determined.

  It should be noted that Zuntz Schmburg-Lusk's expression is Patent Document 2, Harris-Benedict's Expression is Non-Patent Document 1, Non-Patent Document 2 is to obtain motion intensity, and Non-Patent Document is the relationship between daily activities and motion intensity. 3, respectively.

Patent Document 2 JP 2006-16330 A Non-Patent Document 1 Harris JA, Benedict FJ; A biometric study of Basal metabolism in man Carnegie Institution of Washington, Washington DC Lippincott Company, Philadelphia, USA, 1919
Non-Patent Document 2 Chemistry Dojin New Food Nutrition Science Series New Guidelines Compliant Basic Nutrition Nishikawa Yoshiyuki Tomomoto Tsujimoto Non-Patent Document 3 6th revision Japanese Dietary Requirements-Dietary Intake Standards, Health and Nutrition Information Study Group One publication (1999)

(Formula 1: Harris-Benedict formula)
Male basal metabolism (kcal / day) = 66.47 + 13.75 x body weight (kg) + 5.0 x height (cm)-6.76 x age Female basal metabolism (kcal / day) = 655.1 + 9.56 x body weight ( kg) + 1.85 x height (cm)-4.68 x age

(Formula 2: Energy consumption (Zuntz Schmburg-Lusk formula))
Heat consumption per unit time (kcal / min) = VO ₂ (ml / min) × (30817 + 1.23 × VCO ₂ / VO ₂ ) / 1000

(Formula 3: Calculation formula of motion intensity)
Af = Energy consumption by a certain movement (kcal / day) ÷ Basal metabolism (kcal / day)

  In addition, it is known that energy consumption is accelerated by physiological stress such as illness or injury. In such a case, it is necessary to further remove the stress coefficient corresponding to the user's symptom in the calculation of Af. .

  According to a second aspect of the present invention related to a meal management system for solving the above problems, an acceleration sensor attached to a user's lower arm and an acceleration for determining a user's meal intake based on acceleration information detected by the acceleration sensor A meal content inquiry means for querying the user about the meal content when the user determines that the user has eaten the meal, and a meal content input means for the user to input the meal content. Storage means for storing the input of the user's meal content.

  According to the meal management system of this configuration, when the user eats (when food is consumed), the acceleration sensor and the acceleration meal intake determination means detect that the meal is eaten, and the meal content inquiry means promptly ask the user for the meal content. Inquire about (food intake). Therefore, the same effect as the first aspect of the present invention according to the meal management system can be obtained.

  As the acceleration sensor, an acceleration sensor capable of detecting at least triaxial acceleration is used. Furthermore, an acceleration sensor that can also detect the angular velocity of the three axes may be used.

  Here, the acceleration sensor always detects gravitational acceleration along with acceleration due to movement. In human eating behavior, the operation of carrying food into the mouth is generally performed with bare hands, or using eating utensils such as chopsticks and forks. For example, when eating with chopsticks in the right hand, the user's lower arm moves as follows.

(1) Grab food with the right hand facing the user's left front.
(2) The elbow is rotated around the fulcrum so that the right hand is directed toward the upper left direction of the user, and the food is carried to the mouth.
(3) Put food in the mouth (almost stationary for a short time)

  In this movement, a large acceleration exceeding 3 times the gravitational acceleration is not detected in order not to drop the food. Moreover, the direction with respect to the gravity acceleration direction of each axis | shaft of an acceleration sensor differs in the state which grasps the foodstuff of said (1), and the state which puts the foodstuff of said (3) in a mouth. Therefore, since the above-described movement and the change in the direction of gravity acceleration due to the movement are peculiar to eating behavior, it can be determined whether or not a meal is ingested from the acceleration sensing information. Moreover, it is preferable to attach an acceleration sensor to a user's dominant arm side, More preferably, it attaches to both arms.

  According to a third aspect of the present invention related to a meal management system for solving the above-described problems, a user's meal intake is obtained by an acceleration sensor attached to a user's arm, breath collection means, and acceleration information detected by the acceleration sensor. Accelerated meal intake determining means for determining, and when the accelerated meal intake determining means determines that the user has ingested a meal, an expiration collection requesting means for prompting the user to collect expired air, and during expiration The meal intake determining means for determining the user's meal intake based on the amount of oxygen gas and the amount of gas dioxide, and the meal content for inquiring the user of the meal content when the meal intake determining means determines that the user has eaten the meal It comprises: inquiry means; meal content input means for the user to input meal contents; and storage means for storing input of the user's meal contents. To.

  Further, in the third aspect of the present invention, since exhaled gas analysis and acceleration analysis are used in combination, it is possible to determine the presence or absence of a user's meal intake with higher accuracy.

  A first aspect of the present invention relating to a meal management method for solving the above-described problems includes an expired gas detection step for detecting an amount of oxygen gas and an amount of dioxide gas contained in a user's expired gas, an amount of oxygen gas in the expired gas, An expiration gas determination step for determining whether or not a user has ingested a meal based on the amount of gas dioxide; a meal content inquiry step for referring to the user for a meal content when it is determined in the exhalation gas determination step that the meal is ingested; A user input step of inputting content and a storage step of storing input of the user's meal content are provided.

  According to a second aspect of the present invention related to a meal management method for solving the above-described problem, an acceleration detection step of detecting movement of a user's arm with an acceleration sensor and a signal from the acceleration sensor determine whether or not the user is eating food. An acceleration determination step, a meal content inquiry step for querying the user about the meal content when the acceleration determination step determines that a meal is ingested, a user input step for the user to input the meal content, and an input of the user's meal content And a storing step for storing.

  According to a third aspect of the present invention related to a meal management method for solving the above-mentioned problem, an acceleration detection step of detecting movement of the user's arm by an acceleration sensor and a signal from the acceleration sensor determine whether or not the user has eaten the meal. An acceleration determination step, an expiration collection inquiry step that prompts the user to collect expiration when the acceleration determination step determines that food is ingested, and an expiration gas that detects the amount of oxygen gas and the amount of dioxide contained in the expiration gas of the user The detection step, the expiration gas determination step for determining the presence or absence of the user's meal intake based on the amount of oxygen gas and the amount of dioxide gas in the expiration gas, A meal content inquiry step for inquiring the user, a user input step for the user to input the meal content, and the user's meal content Characterized in that it comprises a storage step of storing force, the.

  According to the first to third aspects of the present invention related to the meal management method, the same effects as those of the first to third aspects of the present invention related to the meal management system can be obtained.

  According to the present invention, it is detected that the user has eaten, and the meal content inquiry means promptly asks the user about the meal content. Therefore, the user can accurately check the meal content input means before forgetting the meal content. You can fill in the details of meals. By utilizing this meal content information, the user's eating habits can be properly managed.

FIG. 1 is a block diagram of a meal management system according to the first embodiment. FIG. 2 is a diagram illustrating a portable terminal of the meal management system according to the first embodiment. FIG. 3 is a diagram illustrating an operation flow of the meal management system according to the first embodiment. FIG. 4 is a diagram illustrating an operation flow of the meal management system according to the second embodiment. FIG. 5 is a diagram illustrating an operation flow of the meal management system according to the third embodiment. FIG. 6 is a diagram illustrating an operation flow of the meal management system according to the fourth embodiment.

(Embodiment 1)
The present embodiment will be described in detail with reference to the drawings. FIG. 1 is a block diagram of a meal management system according to the present embodiment, and FIG. 2 is a diagram illustrating a portable terminal to which the meal management system according to the present embodiment is applied.

  As shown in FIG. 1, the meal management system according to the present embodiment includes an expiration component detection unit 101 that detects gas contained in expiration, an oxygen gas amount in the expiration detected by the expiration component detection unit 101, Meal intake determination means 102 that determines the user's meal intake based on the amount of carbon gas; and the meal content inquiry means 103 that inquires of the user about the meal content when the meal intake determination means 102 determines that the user has ingested the meal. , A meal content input means 104 for the user to input the meal content, and a storage means 105 for storing the user's meal content input.

  The exhalation component detection means 101 detects a gas component contained in the exhalation gas, and can detect it using a known gas sensor.

The meal intake determination unit 102 calculates calorie consumption from the CO ₂ gas amount and O ₂ gas amount detected by the exhalation component detection unit 101 from the Zuntz Schmburg-Lusk equation, and operates in comparison with the basal metabolic rate of the user. The strength is calculated, and the motion strength is compared with the motion strength (1.4) of the meal to determine whether or not it is a meal intake. The Zuntz Schmburg-Lusk equation and the calculation formula for the motion intensity are stored in the storage unit 105.

  The meal content inquiry means 103 transmits a meal content inquiry signal to the user by sound, vibration, message presentation or the like when it is determined that the meal is ingested. When the meal management system according to the present embodiment is applied to a mobile phone, a meal content inquiry signal can be transmitted by mail (short mail, electronic mail) or telephone.

  The meal content input means 104 is used by the user to input meal content. For example, it is possible to employ a configuration that includes a display unit such as a liquid crystal screen and an input unit such as a keyboard and a touch panel, displays a menu entry screen on the display unit, and inputs meal contents on the input unit.

  The storage unit 105 stores, for example, user data such as the user's age, height, weight, diagnosis record, and past history, and various calculation formulas described above. As the storage unit 105, a hard disk, a semiconductor memory, a holographic memory, or the like can be used.

  As shown in FIG. 2, a mobile phone (smart phone) to which the meal management system according to the present embodiment is applied includes an exhaled gas component detection unit, a processing unit such as a central processing unit (CPU), a semiconductor memory, a hard disk, and the like. Storage unit, a display unit such as a liquid crystal screen, an input unit such as a keyboard, a communication unit, a speaker, and a vibrator. Each part of the expiratory gas component detection unit can be configured to double as each part originally provided in the mobile phone.

  The expiratory gas component detection unit detects expiratory gas, and a known gas sensor can be used. The expiratory gas component detector is preferably provided in the vicinity of the microphone for calling.

  Moreover, it can also be set as the structure which consists of a small detection terminal provided with the expiration gas component detection part and a communication part, and a mobile telephone provided with each part other than the expiration gas component detection part. In this case, since it is not necessary to take out the mobile phone for detection of exhalation, it is possible to prevent detection of exhalation from being missed. For example, the detection terminal can be configured to be attached to a collar portion of a user's clothes, a headset, or a microphone near a hands-free terminal. In this case, since the detection terminal can be arranged near the user's mouth, it is possible to prevent expiration detection omission.

  FIG. 3 shows an operation flow of the meal management system using the mobile phone.

  When the user's exhalation is collected (S11), the exhalation gas component detection unit measures the oxygen gas amount and the carbon dioxide gas amount in the exhalation gas (S12). This breath collection is performed at a predetermined time (for example, breakfast 6-8 o'clock, lunch 11-13 o'clock, dinner 18-20 o'clock), and a breath collection signal (sound, vibration, etc.) is sent to the user (processing start) ), And a configuration that prompts the user to collect expiration. In addition, the incoming call or outgoing call of the mobile phone may be started and collected at the time of the user's call.

  Using the detected oxygen gas amount, the detected carbon dioxide gas amount, and the Zuntz Schmburg-Lusk equation stored in the storage unit, the processing unit calculates calorie consumption and calculates the operation intensity from the calorie consumption (S13).

  It is determined whether food intake is not taken (S14). Here, it is known that the motion intensity (Af) when eating is about 1.4, for example, when the motion intensity is 1.3 to 1.5, the other is food intake If it is determined that the case is not a meal intake, the process proceeds to S15. If it is determined that the case is not a meal intake, the process ends.

  A message for inquiring about meal contents is presented to the user (S15). In this message presentation, the processing unit operates each unit so that sound is generated through a speaker, vibration is generated through a vibrator, a message is displayed on a display unit, and a mail or a phone call is received.

The processing unit presents a meal input screen on the display unit (S16).
Here, in the case of an operation intensity close to that of a meal, there is a risk that it is erroneously determined to be a meal intake in the expiration determination. For this reason, it is preferable to provide an answer item “no meal intake” in the meal answer.

  The user inputs the meal content and stores the input content (S17).

  It is determined whether or not the user has input meal contents (S18). If not entered, the process moves to S15 again to make a meal content inquiry. When the user has recorded the meal content, the process proceeds to the end.

  According to the present embodiment, since the meal content inquiry is performed only when it is determined that the meal is ingested based on the expired gas information, it is possible to perform reliable meal recording without increasing the burden on the user.

(Embodiment 2)
In this embodiment, instead of detecting expired gas, the movement of the arm is detected by an acceleration sensor to determine whether or not it is a meal intake. In this case, the first embodiment is the same as the first embodiment except that an acceleration sensor is used instead of the expiration component detection means, and an acceleration meal intake determination means is used instead of the meal intake determination means for determining meal intake using the expiration gas information. It is the same. Further, when applied to a mobile phone, it is the same as in the first embodiment, except that an acceleration sensor is used instead of the exhalation gas component detection unit.

  As the acceleration sensor, a sensor that detects at least triaxial accelerations orthogonal to each other is used. Furthermore, the angular velocity of the three axes may be detected. A well-known thing can be used for such an acceleration sensor.

  The acceleration sensor always detects gravitational acceleration as well as acceleration due to movement. Here, in human eating behavior, an operation of carrying food to the mouth is generally performed with bare hands or using a cooking tool such as a chopstick or a fork. For example, when eating with chopsticks in the right hand, the user's lower arm moves as follows.

(1) Grab food with the right hand facing the user's left front.
(2) The elbow is rotated around the fulcrum so that the right hand is directed toward the upper left direction of the user, and the food is carried to the mouth.
(3) Put food in the mouth (almost stationary for a short time)

  In this movement, a large acceleration exceeding 3 times the gravitational acceleration is not detected in order not to drop the food. Moreover, the direction with respect to the gravity acceleration direction of each axis | shaft of an acceleration sensor differs in the state which grasps the foodstuff of said (1), and the state which puts the foodstuff of said (3) in a mouth. Therefore, since the above-described movement and the change in the direction of gravity acceleration due to the movement are peculiar to eating behavior, it can be determined whether or not a meal is ingested from the acceleration sensing information. Moreover, it is preferable to attach an acceleration sensor to a user's dominant arm side, More preferably, it attaches to both arms.

  Since the acceleration sensor is attached to the lower arm of the user, the terminal having the acceleration sensor is preferably as small as possible. For this reason, when applying this Embodiment to a mobile phone, it is preferable to set it as the structure which consists of an acceleration sensor, a small detection terminal provided with a communication part, and a mobile phone provided with each part other than an acceleration sensor. . The acceleration sensor can be configured to be incorporated in, for example, a wristwatch or a bracelet.

FIG. 4 shows an operation flow of the meal management system according to the present embodiment.
The acceleration sensor detects the acceleration of the user's arm (S21).

  The processing unit analyzes the acceleration detection result (S22). At this time, noise removal, analog / digital conversion, Fourier transform, processing for canceling the gravitational acceleration detected at the initial stage, or the like may be performed.

  The processing unit compares the acceleration analysis result with the determination criterion stored in the storage unit to determine whether or not it is food intake (S23). If it is determined that the food is ingested, the process proceeds to S24. If it is determined that the food is not ingested, the process proceeds to S21.

  This determination is performed as follows, for example. The acceleration data of the user's meal intake with the acceleration sensor attached in advance is recorded in the storage unit, and this data is determined by collating the waveform.

  A message for inquiring about meal contents is presented to the user (S24).

  A meal input screen is presented on the user's mobile terminal (S25).

  The user inputs meal contents (S26).

  It is determined whether or not the user has recorded meal contents (S27). If not recorded, the process proceeds to S24 again. When the user has recorded the meal content, the process proceeds to S21. S24 to S27 may be the same as S15 to S18 of the first embodiment.

  According to the present embodiment, since the meal content inquiry is performed only when it is determined that the meal is ingested based on the acceleration sensing information, it is possible to perform reliable meal recording without increasing the burden on the user.

(Embodiment 3)
In the present embodiment, a mode in which expiration gas detection and an acceleration sensor are used in combination will be described. The device configuration and the configuration of the mobile phone are a combination of the first and second embodiments, and the description of each part is omitted. FIG. 5 shows an operation flow of the meal management system according to the present embodiment.

  The acceleration sensor detects the acceleration of the user's arm (S301).

  This acceleration is analyzed (S302).

  Here, it is determined whether or not the acceleration analysis result is meal intake (S303). If it is determined that the food is ingested, the process proceeds to S304. If it is determined that the food is not ingested, the process proceeds to S301.

  A message for collecting exhalation is presented to the user (S304).

  It is determined whether expiration has been collected (S305). If there is collection, the process proceeds to S306, and if there is no collection, S304 is performed again.

  The oxygen gas amount and the carbon dioxide gas amount in the exhalation are detected by the exhalation component detecting means (S306).

  From the detected oxygen gas amount and the detected carbon dioxide gas amount, the operation intensity is calculated by using an indirect calorimetry method (S307).

  A case where the motion intensity (Af) is 1.3 to 1.5 is determined not to be a meal intake, and a case where the motion intensity (Af) is other than a meal intake is determined (S308). If it is determined that the food is ingested, the process proceeds to S309. If it is determined that the food is not ingested, the process proceeds to S301.

  A message for inquiring about meal contents is presented to the user (S309). The message presentation may be the same as in the first embodiment.

  A meal input screen is presented on the user's mobile terminal (S310).

  The user inputs meal contents (S311).

  It is determined whether the user has recorded the meal contents (S312). If not recorded, the process proceeds to S309 again. When the user has recorded the meal content, the process proceeds to S301.

  In the present embodiment, after determining that it is food intake from the movement of the lower arm, it is determined again whether or not it is food intake using the expiratory gas information. For this reason, since the determination precision of a meal intake increases, a user's troublesomeness is reduced.

(Embodiment 4)
The present embodiment is the same as the first embodiment, except that it is configured to detect an action related to a meal and prompt the user to collect exhalation. FIG. 6 shows an operation flow of the meal management system according to the present embodiment.

  When an action signal related to a meal is detected (S41), the process is started, the information is transmitted to the portable terminal, and a breath collection message is displayed on the portable terminal (S42). The user collects exhaled breath (S43). It is determined whether or not to collect exhalation (S44). If it is confirmed, the process proceeds to S12 of the first embodiment. If not confirmed, an exhalation collection message is displayed again on the portable terminal (S42).

  As operations related to meals, there are, for example, an operation of turning on a cooking utensil (IH heater, gas stove, microwave oven, etc.), an operation of opening and closing a refrigerator, and an operation of moving a knife. These instruments are provided with sensors (pressure-sensitive sensors and acceleration sensors) and a communication device, and when a related operation is detected by the sensors, these are sent to the terminal on the user side by the communication device (also via the management server). Good), a breath collection message is presented to the user's terminal.

  In the present embodiment, after detecting a meal-related operation, the presence or absence of a meal intake is determined based on exhaled gas information, so that the meal intake can be determined with high accuracy. For this reason, when the related operation is not related to a meal (for example, when the refrigerator is opened and closed for food storage), the user is not burdened with a process of recording a meal, so the burden on the user is small.

  As described above, according to the present invention, it is detected that the user has eaten using expiratory gas component information and acceleration sensing information, and the meal content inquiry means promptly queries the user for the meal content. Can enter the exact meal content via the meal content input means before forgetting the meal content. By utilizing this meal content information, the user's eating habits can be properly managed. Therefore, the industrial significance is great.

Claims (10)

Expiratory component detection means for detecting a gas component in the exhalation;
Meal intake determination means for determining the user's meal intake based on the amount of oxygen gas in exhaled breath detected by the breath component detection means and the amount of carbon dioxide gas;
When it is determined by the determination means that the user has ingested a meal, the meal content inquiry means for referring to the user for the meal content;
A meal content input means for the user to input the meal content;
Storage means for storing user's meal content input;
A meal management system comprising: An acceleration sensor attached to the lower arm of the user;
Acceleration meal intake determination means for determining the user's meal intake from the acceleration information detected by the acceleration sensor;
When the acceleration meal intake determining means determines that the user has ingested a meal, the meal content inquiry means for referring to the user for the meal content;
A meal content input means for the user to input the meal content;
Storage means for storing user's meal content input;
A meal management system comprising: An acceleration sensor attached to the user's arm;
Breath collection means;
Acceleration meal intake determination means for determining the user's meal intake from the acceleration information detected by the acceleration sensor;
When the acceleration meal intake determining means determines that the user has ingested a meal, the breath collection requesting means for prompting the user to collect the breath;
Meal intake determination means for determining the user's food intake according to the amount of oxygen gas and the amount of gas dioxide in the breath collected by the breath collection means;
When it is determined by the meal intake determining means that the user has ingested a meal, the meal content inquiry means for referring to the user for the meal content;
A meal content input means for the user to input the meal content;
Storage means for storing user's meal content input;
A meal management system comprising: The meal intake determining means calculates the calorie consumption by the amount of oxygen gas in the exhaled breath, the amount of carbon dioxide gas, and determines the user's food intake from the calorie consumption and the basal metabolic rate,
The meal management system according to claim 1 or 3 characterized by things. The basal metabolic rate is calculated according to the user's age, height, weight, gender,
The meal management system according to claim 4 characterized by things. An expiration gas detection step for detecting the amount of oxygen gas and the amount of dioxide gas contained in the user's expiration gas;
An expiration gas determination step for determining the presence or absence of the user's meal intake based on the amount of oxygen gas and the amount of dioxide gas in the expiration gas;
A meal content inquiry step for inquiring about the meal content to the user when it is determined in the exhalation gas determination step that a meal is ingested;
A user input step in which the user inputs meal contents;
A storage step for storing the input of the user's meal content;
A meal management method comprising: An acceleration detection step of detecting movement of the user's arm with an acceleration sensor;
An acceleration determination step for determining whether or not the user has ingested food by a signal from the acceleration sensor;
A meal content inquiry step for inquiring about the meal content to the user when it is determined that the meal is ingested in the acceleration determination step;
A user input step in which the user inputs meal contents;
A storage step for storing the input of the user's meal content;
A meal management method comprising: An acceleration detection step of detecting movement of the user's arm with an acceleration sensor;
An acceleration determination step for determining whether or not the user has ingested food by a signal from the acceleration sensor;
If it is determined that the intake of food in the acceleration determination step, a breath collection requesting step that prompts the user to collect a breath;
An expiration gas detection step for detecting the amount of oxygen gas and the amount of dioxide gas contained in the user's expiration gas;
An expiration gas determination step for determining the presence or absence of the user's meal intake based on the amount of oxygen gas and the amount of dioxide gas in the expiration gas;
A meal content inquiry step for inquiring about the meal content to the user when it is determined in the exhalation gas determination step that a meal is ingested;
A user input step in which the user inputs meal contents;
A storage step for storing the input of the user's meal content;
A meal management method comprising: The exhalation determination step is a step of calculating calorie consumption by the amount of oxygen gas and carbon dioxide gas in the exhalation, and determining the user's food intake from the calorie consumption and the basal metabolic rate.
The meal management method according to claim 6 or 8. The basal metabolic rate is calculated according to the user's age, height, weight, gender,
The meal management method according to claim 9.

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