KR20230112194A - Analyizing system for eating habits with moving data and door events in a form of binary data set of monitorized senior person - Google Patents

Abstract

The present invention provides an eating habits analysis system (10a) including a user's activity sensor (1a), a location sensor located in each room to check the user's location movement path, and a door sensor (2a) attached to the refrigerator, a time counter (3a) that measures time elapsed and checks the time interval between events, and a control unit (4a) that determines whether or not the purpose of moving to the refrigerator is eating or not eating through information on the time interval between events and movement path, and also detects the state of a subject to be monitored by the sick or the elderly , It relates to a method for calibrating an activity sensor used in a system that performs safety management by confirming, and more specifically, when the user goes out of the living space, when the average value of each output signal of the activity sensors is less than the predetermined average value of the output signal when going out, the output signal of the corresponding activity sensor converts the signal of 1, which is determined to be the case of the user's activity, to a signal of 0. If it is less than the average value of the toilet output signal, a calibration method for the activity sensor, characterized in that performing a non-going procedure of converting a signal of 1 determined to be a case of user activity in the corresponding toilet activity sensor output signal to a signal of 0. Can be provided.

Description

Eating habits analysis system and algorithm including binary data, movement patterns and door events

The present invention relates to an eating habits analysis system and an algorithm control method, and the present invention relates to a system and control method for achieving more accurate eating habits analysis, out of a traditional method or a method relying only on expensive equipment.

In addition, the present invention relates to a method for calibrating an activity sensor used in a system that detects and confirms the state of a person subject to monitoring of the diseased or the elderly and performs safety management. If the average value of the bathroom activity sensor output signal when not going out is less than or equal to the preset average value of the toilet output signal when not going out, a signal of 1 determined to be the case of user activity in the corresponding toilet activity sensor output signal is converted into a signal of 0.

Recently, with the development of medical technology, the survival age is continuously increased, and the society is stepping into a life extension society.

However, patients with dementia often require psychological and psychosomatic observation, and accordingly, the demand for observation in the space where the patient resides is increasing.

In the case of a patient with dementia, a caregiver is in charge of normal protective observation for the elderly who need help from others due to difficulties living alone, but such caregivers are remarkably insufficient.

In order to solve these problems, wearable (wearable) health care devices worn by patients are being developed, but utilization and maintenance are difficult, so the actual patient use rate is low.

Therefore, cases where an activity sensor for detecting activity in a patient's living space are installed in a space such as a patient's home or a hospital room are increasing.

The activity sensor photographs and recognizes the user's appearance at regular time intervals (for example, every 2 seconds) to determine whether there is activity of the user, outputs a signal of 1 as a digital output signal in the case of activity, and outputs a signal of 0 as a digital output signal in the case of no activity, and generates life log data to determine the level of activity of the user according to the type and frequency of the output signal.

In order to determine the degree of activity of the user according to the type and frequency of the output signal, the lifelog data generated from the activity sensor is transmitted to the server, and the server analyzes the received lifelog data to confirm the user's activity index, bedtime information, and outing index to confirm and determine the stability of the user's daily state.

At this time, as a result of the analysis by the server, if the activity index and the outing index are lower than the reference values and it is determined that the user is currently in a dangerous situation, the server contacts the emergency institution or hospital to notify the patient of the emergency situation so that necessary measures can be taken.

However, noise may be generated due to the nature of the activity sensor generating the lifelog data used for determining the emergency situation, and an error may occur in determining the emergency situation due to such noise.

For example, even though the user has not visited the bathroom, it may be determined that the user has fallen in the bathroom due to the noise of the activity sensor of the bathroom, and as a result, the emergency service may be dispatched to the user's residence.

Therefore, in order to prevent misjudgment of an emergency situation due to sensor noise as described above, a moving average filter technique for removing noise on a signal of an activity sensor is used to remove noise of the sensor. Noise filtering technology of the activity sensor is known.

However, the technique using the moving average filter is effective in removing sudden sensor noise, but has a disadvantage in that accuracy is somewhat reduced in a place where a plurality of sensors are used.

In addition, the technology using the moving average filter can perform noise filtering only on signals in the form of a continuous stream, and due to the nature of the sensor, data measured every few seconds are aggregated and the aggregated information is transmitted only once every few minutes. It is difficult to apply noise filtering to packet-type data.

On the other hand, in observing the lifestyle of the subject to be monitored, such as the sick or the elderly, the conventional technology, especially in the monitoring of eating habits, uses a questionnaire to analyze the eating habits, and the daily meal amount and daily beverage quantity in the questionnaire. In addition, it was analyzed using a refrigerator connected to IoT equipment and a network, such as the latest refrigerator, and in the case of data collection using such labor-intensive data or expensive equipment, cost problems are encountered. In other words, the analysis of eating habits using a questionnaire has the disadvantage of not being able to grasp the food and beverage habits that change in real time and the problem of very low accuracy depending on the questionnaire ability of the surveyor and the psychology and memory state of the respondent. It has the advantage of checking the items in the refrigerator through expensive equipment, for example, expensive equipment such as a refrigerator linked to a recently introduced network. There are limits.

Eating habits analysis using questionnaires has disadvantages in that accuracy is very low depending on the questionnaire ability of the surveyor and the psychology and memory state of the respondent, and it is not possible to grasp food and beverage habits that change in real time.

A method using expensive equipment is also being introduced to solve problems caused by inaccuracy of data due to survey deviation caused by such a person's direct survey or increased cost and fatigue caused by a labor-intensive survey method. However, as described above, expensive equipment, for example, a recently introduced network-linked refrigerator, has the advantage of checking the items of the refrigerator, but the subject cannot check the process before going to the refrigerator, and therefore only performs a role of inventory inventory of the refrigerator, making it impossible to collect accurate data and accompanying the problem of increasing cost.

In addition, the present invention, which was devised to solve other conventional problems, provides a noise filtering method that can accurately determine the user's abnormal situation based on the user's lifelog data, thereby providing an ambulance or hospital room. The technical problem of the present invention is to prevent unnecessary dispatch to the scene.

The purpose of the present invention is to analyze eating habits that enable confirmation of whether the purpose of moving to the refrigerator is for preparing/eating a meal or opening the refrigerator to eat a drink by analyzing the time spent between moving paths such as room -> living room -> kitchen and the moving path and the time between events of a door sensor attached to the refrigerator through sensors located in each room (LOCATION) through an activity sensor.

In addition, the purpose of this study is to confirm the pre-signal related to health by confirming that water intake due to diabetes increases frequently, which is a major case when you open the refrigerator door at dawn and eat a drink among the eating habits.

That is, the present invention includes a user's activity sensor, a location sensor located in each room to check the user's location movement path, a door sensor attached to the refrigerator, a time counter that measures time lapse and checks the time interval between events, and a control unit that determines whether the purpose of moving to the refrigerator is eating/non-eating based on the time interval between events and movement path information.

In addition, the present invention provides a user's activity amount sensor, a location sensor located in each room to check the user's location and movement path, and a door sensor attached to the refrigerator, a time counter that measures time lapse and checks the time interval between events, and a control unit that determines whether or not the purpose of moving to the refrigerator is eating or not eating based on the time interval between events and movement path information. A provision step of providing an eating habit analysis system, and a movement route detection step of detecting the user's activity and movement route through the eating habit analysis system provided in the providing step, and movement route detection step An event check step of executing an event check when an event occurs, and a meal event check step of determining whether or not there is an eating habit event and confirming eating/non-eating when a door open signal generated from a refrigerator door sensor occurs in the event checking step.

In addition, the configuration of the calibration method of the activity sensor for determining an emergency situation of the present invention for achieving another technical problem as described above is a step when going out that converts a signal of 1 determined to be a case of user activity in each output signal of the corresponding activity sensors to a signal of 0 when the average value of each output signal of the activity sensors is less than a predetermined average value of the output signal when going out when the user goes out of the living space, and a predetermined average value of the bathroom activity sensor output signal when the user is not out of the living space If it is less than the average value of the toilet output signal when not going out, it is characterized in that a non-going out procedure of converting a signal of 1 determined to be a case of user activity in the corresponding toilet activity sensor output signal to a signal of 0 is performed.

That is, according to one aspect of the present invention, in the method for calibrating the activity sensor of an activity monitoring system comprising at least one activity sensor installed in a user's living space to sense the user's activity state and a repeater for transmitting the value of the output signal of the activity sensor to the server, when the user goes out of the living space, the repeater, if the average value of each output signal of each activity sensor is less than or equal to the preset average output signal when going out, the activity of the user in each output signal of the corresponding activity sensor A method for correcting an activity sensor is also provided, characterized in that performing a procedure when going out converts a signal of 1 determined to be a case of the presence of a signal of 0 to a signal of 0.

In the method for correcting the activity sensor of the eating habit analysis system, when the user is not going out of the living space, if the average value of the bathroom activity sensor output signal is less than or equal to the predetermined average value of the toilet activity sensor output signal when not going out, a non-going procedure of converting a signal of 1 determined to be the case of user activity in the corresponding toilet activity sensor output signal to a signal of 0 when not going out is performed.

In the method for correcting the activity sensor of the eating habit analysis system, when the user goes out, the activity sensor 1 installed in the user's living space is searched for the location of the activity sensor 1 installed in the user's living space by searching a database linked with the repeater 40 (S1); Searching a database linked with the repeater 40 and confirming a point where the user is last located in the living space (S2); When the user's last location is confirmed in step S2, the repeater 40 determines whether the user exists in the living space or has gone out from the living space based on the confirmed user's last location data (S3); As a result of the determination in step S3, if it is determined that the user has gone out, the repeater 40 queries and reads output signal values of all activity sensors 10 installed in the user's living space (S4); The repeater 40 calculates an average value of the output signals of all the activity sensors that have been inquired, determines an output value of each activity sensor by referring to the calculated average value (S5), and outputs the determined output value of each activity sensor to the server 100 through the communication network 200 (S6); It may be configured to include.

In the calibration method of the activity sensor of the eating habit analysis system, in the step S5, the repeater 40 temporarily copies the values of the output signals of all the activity sensors inquired in the step S4 to the interlocked memory (S10), and arranges the values of the output signals in the past for a predetermined number of times based on the current time point (S11); Determining, by the repeater 40, whether respective values of the output signals of all the activity sensors at the current time point are not 0 (S12); As a result of the determination in step S12, if the values of the output signals of all activity sensors at the current time point are not 0, calculating an average value of the output signals of activity sensors arranged a certain number of times in step S11 (S13); determining whether the calculated average value of each activity sensor output signal is equal to or less than a preset average output signal value when going out (S14); In the step S14, when the average value of each activity sensor output signal is equal to or less than the predetermined average value of the output signal when going out, the repeater 40 converts a signal of 1 determined to be the case of user activity in the corresponding output signal into a signal of 0 determined to be the case of no user activity (S15).

In the method for calibrating the activity sensor of the eating habit analysis system, if it is determined that the user is in a non-going state existing in the living space as a result of the determination in step S3, the repeater 40 is installed in the bathroom of the user's living space. Inquiring and reading the values of the output signal of the bathroom activity sensor 20; The repeater 40 may include a step (S8) of calculating an average value of the output signals of the bathroom activity sensor and determining an output value of the bathroom activity sensor 20 by referring to the calculated average value.

In the calibration method of the activity sensor of the eating habit analysis system, in the step S8, the repeater 40 temporarily copies the values of the output signal of the toilet activity sensor inquired in step S7 to the memory (S20), and arranges the values of the output signals of the past toilet activity sensor for a predetermined number of times based on the current time point (S21); Calculating, by the repeater 40, an average value of the output signals of the bathroom activity sensors arranged a certain number of times in the step S21 (S22); The repeater 40 determines whether the average value of the output signal of the non-going out bathroom activity sensor 20 calculated by the repeater 40 is equal to or less than a predetermined average value of the non-going out bathroom output signal (S23); In the step S23, when the average value of the output signal of the bathroom activity sensor 20 is equal to or less than the predetermined average value of the toilet output signal when not going out, the repeater 40 converts a signal of 1 determined to be the case of user activity in the power signal of the bathroom activity sensor 20 to a signal of 0 determined to be the case of no user activity (S24).

The food intake analysis system and control method of the present invention are effective in tracking changes in eating habits by analyzing eating habits through the bent, binary data, and movement patterns of the door attached to the refrigerator, responding to sudden changes in eating habits, and detecting health issues such as diabetes in which people seek water at dawn in advance, confirming them, and notifying them to the subject to take care of their health in advance.

In addition, another aspect of the present invention is that even if one of the activity sensors outputs an erroneous signal due to noise when the user is out or not going out, the signal due to such noise is removed in advance, so that the emergency service can prevent the possibility of an erroneous dispatch, and the emergency service can accurately identify the user's emergency situation.

1 is a block diagram of an activity sensor and a server for determining an emergency situation of the present invention;
2 is a conceptual diagram of a method for correcting an activity sensor for determining an emergency situation according to the present invention;
3 is a flowchart of a method for correcting an activity sensor for determining an emergency situation according to the present invention;
4 is a flow chart of a method for correcting an activity amount sensor for determining an emergency of the present invention when a user goes out;
5 is a flowchart illustrating a method for correcting an activity sensor for determining an emergency situation according to the present invention when a user is not going out.

Hereinafter, the configuration of the correction method of the activity sensor for determining an emergency situation according to the present invention will be described in detail with reference to the drawings.

However, the disclosed drawings are provided as examples to sufficiently convey the spirit of the present invention to those skilled in the art. Accordingly, the present invention may be embodied in other aspects without being limited to the drawings presented below.

In addition, unless there is another definition in the terms used in the specification of the present invention, they have meanings commonly understood by those of ordinary skill in the art to which the present invention belongs, and the gist of the present invention in the following description and accompanying drawings. Detailed descriptions of well-known functions and configurations that may unnecessarily obscure will be omitted.

1 is a block diagram showing the relationship between an activity sensor for determining an emergency situation and a server according to the present invention.

Referring to the drawings, the method of calibrating an activity sensor for determining an emergency situation according to the present invention, as described above, is a method of calibrating an activity sensor 1 installed in a house or a hospital space where a user such as a dementia patient resides, and an activity sensor 1 executed on an activity monitoring system that receives life log data from the activity sensor 1 and transmits the data to the server 100 through a repeater 40.

The activity sensor 1 photographs the user's appearance at regular time intervals, recognizes the captured image as an image, and determines whether there is an activity of the user.

As a result of the determination, when it is determined that there is user activity, a signal of 1 is output as a digital output signal, and when it is determined that there is no user activity, a signal of 0 is output as a digital output signal.

The signal output from the activity sensor 1 forms the user's lifelog data, and such lifelog data is transmitted to the server 100 via the communication network 200 through the repeater 40. ) transmits an alarm signal requesting action by dispatching to the user's residence to the emergency institution server 300 such as a hospital or fire station linked to the communication network 200.

Therefore, the ambulance server 300 receiving such an alarm signal is sent to the user's residence and takes necessary measures to resolve the emergency situation.

In addition, as described above, the activity sensor 1 is divided into a room activity sensor 10 installed in a room, a bathroom activity sensor 20 installed in a bathroom, and a living room activity sensor 30 installed in a living room according to the type of space in which a user resides.

At this time, the present invention performs a data correction method in order to remove noise on the lifelog data generated by the activity sensor 1.

For example, even though the user has not visited the bathroom, it may be determined that the user has fallen in the bathroom due to the noise of the bathroom activity sensor 20, and as a result, an ambulance agency is dispatched to the user's residence. A situation may occur.

Therefore, in order to prevent misjudgment of an emergency situation due to sensor noise as described above, the present invention provides a correction method for resolving the disadvantage that accuracy is somewhat reduced in a place where a plurality of sensors are used when the conventional moving average filter technique is applied and the restriction that noise filtering is possible only for signals in the form of a continuous stream, and this correction method is pre-processed in the repeater 40 that collects log life data of the activity sensor 1 The correction method may be performed by a ing (pre-processing) method or a post-processing (post-processing) method in the server 100. Hereinafter, the correction method of the present invention will be described in more detail.

2 is a conceptual diagram of a method for correcting an activity sensor for determining an emergency situation according to the present invention.

Referring to the drawings, the calibration method of the activity sensor (hereinafter, abbreviated as 'correction method') of the present invention performs a procedure when the user goes out, which is the case when the user does not exist in the living space where the activity sensor 1 is installed, and a procedure when not going out, when the user exists in the living space where the activity sensor 1 is installed.

First, in the case of the user going out procedure, the value of Channel_RO (Room), an output signal of the room activity sensor 10 constituting the activity sensor 1, the value of Channel_RA (bath), an output signal of the bathroom activity sensor 20, and the value of Channel_LV (living), an output signal of the living room activity sensor 30, all output 0.

In this state, in the correction method of the present invention, when the average value of the 10 output signals of the room activity sensor output signal (Channel_RO), the average value of the 10 output signals of the bathroom activity sensor output signal (Channel_RA), and the average value of the 10 output signals of the living room activity sensor output signal (Channel_LV) are equal to or less than the preset average value of the output signal when going out (0.2 or less in the embodiment of the present invention), the repeater 40 corresponds to the corresponding In the output signal, a signal of 1 determined to be a case of user activity is converted into a signal of 0 determined to be a case of no user activity and output.

That is, even if an output signal of 1 is generated from any one of the activity sensors when the user is out of the house, the repeater 40 ignores the generated output signal of 1 and converts it to 0 when the average value of 10 output signals of all activity sensors as a whole is 0.2 or less, and outputs the output signal.

In the example of the drawing, when 1 is generated in the bathroom activity sensor output signal (Channel-RA) of the first output section (B2-1), the second output section (B2-2), the third output section (B2-3), and the fourth output section (B2-4) of each activity amount output sensor in the second output section (B2-2), the repeater 40 operates from the time when the output signal at which 1 was generated occurs before that time. The average value of the bathroom activity sensor output signal (Channel-RA) is calculated by calculating the average value of 10 output signals. In the illustrated example, since the bathroom activity sensor output signal (Channel-RA) is generated only once in the second output period (B2-2), the average value is continuously calculated as 0.1 in the second output period (B2-2).

In this state, when the user goes out, the average value of 10 output signals of the room activity sensor output signal (Channel_RO), the average value of 10 output signals of the bathroom activity sensor output signal (Channel_RA), and the average value of 10 output signals of the living room activity sensor output signal (Channel_LV) from the second signal period (B2-2) to the third signal period (B2-3) are all preset average values of output signals when going out, 0 Since it is less than .2, the signal value of 1 of the toilet activity amount sensor output signal (Channel-RA) generated in the corresponding signal section (B2-2) is converted to 0.

However, in the illustrated example described above, the signal value of the bathroom activity sensor output signal (Channel-RA) is generated three times in the fourth output section (B2-4), and the average value of the previous 10 output signals is calculated as 0.2, 0.2, 0.3, 0.3 0.3, 0.3 0.4, 0.4, 0.3, and these average values are the preset average output signal value when going out. Since it exceeds 0.2, the signal value of 1 of the bathroom activity sensor output signal (Channel-RA) generated in the corresponding signal section (B2-4) is continuously maintained.

Next, in the case of the user non-going procedure, the value of Channel_RO (Room), an output signal of the room activity sensor 10 constituting the activity sensor 1, the value of Channel_RA (bath), an output signal of the bathroom activity sensor 20, and the value of Channel_LV (living), an output signal of the living room activity sensor 30, are in a state in which 1 can be output, and the correction method of the present invention is a bathroom activity sensor output signal when the user is not going out ( When the average value of the 10 output signals of Channel_RA) is less than or equal to the predetermined average value of the toilet output signal when not going out (0.1 or less in the embodiment of the present invention), the repeater 40 converts the signal of 1 determined to be the case of user activity in the corresponding output signal to a signal of 0 determined to be the case of no user activity.

That is, even if the output signal of the bathroom activity sensor 20 is 1 in the situation when the user is not going out, the repeater 40 ignores the generated output signal of 1 when the average value of the previous 10 output signals is 0.1 or less, converts it to 0 and outputs it, so that even if the activity sensor outputs an erroneous signal due to noise, it is removed in advance.

For example, in the example of FIG. 2 , in a state in which the signal value of the toilet activity sensor output signal (Channel-RA) is generated three times in the fourth output period (B2-4) and the average value of the previous 10 output signals is calculated as 0.2, 0.2, 0.3, 0.3, 0.3, 0.3, 0.4, 0.4, 0.3, if the user is not going out In one situation, since the average values of the signal values of the toilet activity sensor output signal (Channel-RA) exceed the preset average value of the toilet output signal when not going out, 0.1, the signal value of 1 of the toilet activity sensor output signal (Channel-RA) generated in the corresponding signal section (B2-4) is continuously maintained.

Next, the calibration method of the activity sensor according to the present invention will be described with reference to the drawings. 3 is a flow chart of a method for correcting an activity sensor for determining an emergency situation according to the present invention.

The correction method of the present invention shown in FIG. 3 may be performed by pre-processing by the repeater 40 or post-processing by the server 100, and for convenience of description, the correction method of the present invention by the repeater 40. It will be described as being pre-processed.

In addition, it should be noted that in the specification of the present invention, the configuration of pre-processing of the correction method by the repeater 40 as described above replaces the configuration of post-processing of the correction method of the present invention by the server 100.

First, the location of the activity sensor 1 installed in the user's living space is inquired by searching the database linked with the repeater 40 (S1).

Next, the database where the repeater 40 is interlocked is searched to confirm the point where the user is last located in the living space (S2).

The confirmation of the user's last location point is to determine whether the user exists in the living space or has gone out from the living space.

When the user's last location is confirmed in step S2, the repeater 40 determines whether the user exists in the living space or has gone out from the living space based on the confirmed user's last location data (S3).

For example, if the user's last location is a room and the user is still in the room, the user exists in the living space, and if the user's last location is the living room and the user's last location in other spaces, including the living room, is not confirmed, it indicates that the user is not currently in the living space and is out of the living room.

As a result of the determination in step S3, if it is determined that the user has gone out, the repeater 40 inquires and reads output signal values of all activity sensors 10 installed in the user's living space (S4).

For example, if there are a room activity sensor 10, a bathroom activity sensor 20, and a living room activity sensor 30 in the living space, the values of these sensors 10, 20, and 30 are all inquired and read.

Next, the repeater 40 calculates an average value of output signals of all activity sensors that have been inquired, determines an output value of each activity sensor by referring to the calculated average value (S5), and outputs the determined output value of each activity sensor to the server 100 through the communication network 200 (S6).

Specifically, in the step of determining the output value of each activity sensor in step S5, if all of the average values of the activity sensors inquired are equal to or less than the predetermined average value of output signals when going out, the repeater 40 converts the output signal of the activity sensors to a signal of 1, which is determined to be the case of user activity, into a signal of 0, which is determined to be the case of no user activity, and then determines the output value with the converted value.

In the embodiment of the present invention, when the user goes out, the average value of the 10 output signals of the room activity sensor output signal, the average value of the 10 output signals of the bathroom activity sensor output signal, and the average value of the 10 output signals of the living room activity sensor output signal are less than the predetermined average value of the output signal when going out of 0.2. Convert to 0 signal.

On the other hand, as a result of the determination in step S3, if it is determined that the user is in a non-going state existing in the living space, the repeater 40 inquires and reads the output signal values of the bathroom activity sensor 20 installed in the bathroom in the user's living space (S7).

Next, the repeater 40 calculates an average value of the output signals of the inquired bathroom activity amount sensor, determines an output value of the bathroom activity amount sensor 20 by referring to the calculated average value (S8), and outputs the determined output value of the bathroom activity amount sensor to the server 100 through the communication network 200 (S6).

Specifically, in the step of determining the output value of the bathroom activity sensor 20 in step S8 (S8), when the average value of the output signal of the bathroom activity sensor 20 when the user is not going out is equal to or less than the preset average value of the bathroom output signal when not going out, the repeater 40 converts the signal of 1 determined to be the case of user activity in the corresponding output signal to a signal of 0 determined to be the case of no user activity, and then determines the output value with the converted value will do

In an embodiment of the present invention, when the average value of 10 output signals from the bathroom activity sensor 20 is 0.1 or less in a situation in which the repeater 40 does not go out, the repeater 40 determines the output value of the bathroom activity sensor output signal by converting a signal of 1 determined as the case of user activity in the output signal of the bathroom activity sensor 20 into a signal of 0 determined as the case of no user activity.

Hereinafter, when it is determined that the user has gone out, the repeater 40 calculates the average value of the output signals of all the activity sensors inquired, and determines the output value of each activity sensor by referring to the calculated average value, and when it is determined that the user is in a non-going state existing in the living space, the repeater 40 calculates the average value of the output signals of the inquired bathroom activity sensor and determines the output value of the bathroom activity sensor 20 with reference to the calculated average value. The configuration will be described in more detail.

4 is a flow chart of the method for correcting an activity sensor for determining an emergency situation when a user is out of the house, and FIG. 5 is a flowchart of the method for correcting an activity sensor for determining an emergency situation when a user is not going out according to the present invention.

Referring to FIG. 4 , when it is determined that the user has gone out, step S5 in which the repeater 40 calculates an average value of output signals of all activity sensors inquired and determines the output value of each activity sensor with reference to the calculated average value is configured as follows.

First, the repeater 40 temporarily copies the values of the output signals of all the activity sensors inquired in step S4 to the interlocked memory (S10), and the values of the output signals in the past based on the current time point are sorted by a certain number of times (S11). In an embodiment of the present invention, values of output signals for the past 10 times are aligned based on the current output signal.

Next, the repeater 40 determines whether respective values of the output signals of all the activity sensors at the current time point are not 0 (S12).

As a result of the determination in step S12, if all values of the output signals of all the activity sensors are 0, the process is returned to step S11, and as a result of the determination in step S12, if the values of the output signals of all the activity sensors at the present time are not 0, an average value of the output signals of the activity sensors arranged a certain number of times is calculated in step S11 (S13).

Then, it is determined whether the calculated average value of each activity sensor output signal is equal to or less than a preset average output signal value when going out (0.2 or less in the embodiment of the present invention) (S14).

In step S14, when the average value of each activity sensor output signal is equal to or less than the predetermined average value of output signals when going out, the repeater 40 converts the signal of 1 determined to be the case of user activity in the corresponding output signal to a signal of 0 determined to be the case of no user activity (S15), and outputs the converted value to the server 100 through the communication network 200 (S16).

Therefore, according to the correction method according to the embodiment of the present invention, even if an output signal of 1 is generated from any one of the activity sensors while the user is out of the house, if the average value of 10 output signals of all activity sensors as a whole is 0.2 or less, the output signal of 1 generated is ignored and converted to 0 and output. From the point of view of the air supply system, it is possible to accurately grasp the user's emergency situation.

Next, referring to FIG. 5 , when it is determined that the user has not gone out, the repeater 40 calculates an average value of the output signals of the bathroom activity sensor 20 and determines the output value of the bathroom activity sensor 20 by referring to the calculated average value. Step S8 is configured as follows.

First, the repeater 40 temporarily copies the values of the output signals of the bathroom activity sensors inquired in step S7 to the memory (S20), and arranges the values of the output signals of the bathroom activity sensors in the past based on the current time point by a certain number of times (S21). In an embodiment of the present invention, values of output signals for the past 10 times are aligned based on the current output signal.

Next, the repeater 40 calculates an average value of the output signals of the bathroom activity sensors arranged a certain number of times in step S21 (S22).

Then, the repeater 40 determines whether the calculated average value of the output signal of the non-going out bathroom activity sensor 20 is equal to or less than a predetermined average value of the non-going out bathroom output signal (0.1 or less in the embodiment of the present invention) (S23).

In the step S23, when the average value of the output signal of the bathroom activity sensor 20 is less than or equal to the predetermined average value of the toilet output signal when not going out, the repeater 40 converts the signal of 1 determined to be the case of user activity in the power signal of the bathroom activity sensor 20 to a signal of 0 determined to be the case of no user activity (S24), and outputs the converted value to the server 100 through the communication network 200 (S 25).

In an embodiment of the present invention, when the average value of 10 output signals from the bathroom activity sensor 20 is 0.1 or less in a situation where the repeater 40 is not going out, the repeater 40 determines the output value of the bathroom activity sensor output signal by converting a signal of 1 determined to be the case of user activity in the output signal of the bathroom activity sensor 20 into a signal of 0 determined to be the case of no user activity.

Therefore, even if the output signal of the bathroom activity sensor output value when the user is not going out is 1, even if the average value of the 10 output signals of the bathroom activity sensor output signal is 0.1 or less, the output signal of 1 generated is ignored and converted to 0. of can be performed accurately.

The present invention includes a user's activity sensor 1a, a location sensor located in each room to check the user's location and movement path, and a door sensor 2a attached to the refrigerator, a time counter 3a that measures time and checks the time interval between events, and a control unit 4a that determines whether the purpose of moving to the refrigerator is eating/non-eating through information on the time interval between events and movement path.

In addition, the present invention provides a provision step (SD1) of providing an eating habit analysis system including a user's activity amount sensor, a location sensor located in each room to check the user's location movement path and a door sensor attached to the refrigerator, a time counter that measures time elapsed and checks the time interval between events, and a control unit that determines whether or not the purpose of moving to the refrigerator is eating or not eating based on the time interval between events and movement route information. ), an event check step (SD3) of executing an event check when an event occurs in the moving path detection step, and a meal event check step (SD4) of determining whether or not there is an eating habit event and confirming eating/non-eating when a door open signal generated from a refrigerator door sensor is generated in the event checking step.

* Description of symbols for main parts of drawings *
One; activity sensor
10; room activity sensor
20; toilet activity sensor
30; living room activity sensor
40; repeater
100; server
200; communications network
300; ambulance server

Claims (2)

a user's activity sensor 1a;
Position sensors located in each room and door sensors 2a attached to the refrigerator to check the user's location movement path;
a time counter 3a which measures the passage of time and checks the time interval between events;
Eating habit analysis system (10a) including a control unit (4a) that determines whether the purpose of moving to the refrigerator is eating/non-eating through time intervals between events and movement route information.
A provision step (SD1) of providing an eating habit analysis system including a user's activity sensor, a location sensor located in each room to check the user's location movement path, a door sensor attached to the refrigerator, a time counter that measures time elapsed and checks the time interval between events, and a controller that determines whether the purpose of moving to the refrigerator is eating/non-eating based on the time interval between events and movement route information;
A movement path detection step (SD2) of detecting the user's activity and movement route through the eating habit analysis system provided in the providing step;
An event check step (SD3) of executing an event check when an event occurs in the moving path detection step;
and a meal event checking step (SD4) of determining whether there is an eating habit event and checking whether eating or not eating when a door open signal generated by a refrigerator door sensor is generated in the event checking step.