JP2007195823A - Sleep information providing system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce time and cost required in a system providing sleep information via a communication line. <P>SOLUTION: A signal processing unit (20) receives raw data about physiological information of a sleeping subject from a sleep sensor, extracts sleep information indicating sleeping condition of the subject from the received raw date, and stores extracted sleep data sequentially, for example, at one-minute intervals. A terminal PC (35) transmits the sleep data acquired from the signal processing unit (20) to a central server (30). That is, the sleep data having relatively less information amount obtained from the signal processing unit (20) is transmitted to the central server (30) of the terminal PC (35), instead of the raw data acquired from the sleep sensor. The central server (30) generates a sleep report with a chart of the received sleep data, and transmits the sleep report to the terminal PC (35). <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a sleep information providing system that provides information related to a sleep state of a subject.

Conventionally, systems that provide information useful for improving sleep states have been proposed. For example, in the system disclosed in Patent Document 1, the server acquires data on the sleep state of the subject using a communication line such as the Internet, evaluates the sleep state of the subject from the data acquired by the server, and obtains the result as a doctor. It is transmitted to the terminal on the side.
JP 2004-344265 A

  As described above, in the conventional system disclosed in Patent Document 1, data on a subject's sleep state is processed by a server, and data obtained by a sensor installed at the subject's place (that is, before processing) All raw data) must be sent to the server via a communication line. In other words, a large amount of data must be transmitted from the local side to the server using a communication line. For this reason, the conventional system has a problem that communication time and communication cost increase.

  The present invention has been made in view of such a point, and an object thereof is to reduce the time and cost required for communication in a system that provides information related to sleep via a communication line.

  1st invention is connected to the sleep sensor (40) which detects the signal regarding a test subject's (90) biometric information, and sleep which shows a sleep state of a test subject (90) based on the signal received from this sleep sensor (40) Communication with the local device (20) that derives the data and the server device (30) that obtains sleep data from the local device (20) via the communication line and creates a sleep report that charts the acquired sleep data. And a display device (35) for displaying a sleep report acquired from the server device (30) via a line.

  In the first invention, the local device (20) receives the signal output from the sleep sensor (40). As a sleep sensor (40), a non-restrained sensor installed on a futon or the like to detect body movement of the subject (90) or a heart rate of the subject (90) attached to the body of the subject (90) A restraint type sensor that detects numbers and the like is exemplified. The local device (20) performs processing such as calculation using a signal (that is, raw data) received from the sleep sensor (40), and extracts sleep data indicating a sleep state. Examples of sleep data include sleep time, awake time, sleep time, frequency of awakening, and heart rate during sleep. The server device (30) receives sleep data derived by the local device (20) and creates a sleep report by charting this sleep data. That is, the server device (30) summarizes the sleep data obtained from the local device (20) into a chart so that a tester such as a sleep doctor can easily understand. The sleep report created by the server device (30) is transmitted to the display device (35) and displayed on the display or printed on paper. A tester such as a sleep doctor grasps the sleep state of the subject (90) from the sleep report displayed by the display device (35).

  In a second aspect based on the first aspect, the local device (20) is provided with recording means (22) for storing the derived sleep data, and the server device (30) The sleep data stored in the recording means (22) of the device (20) is acquired.

  In the second invention, the recording device (22) is provided in the local device (20). The sleep data derived based on the signal from the sleep sensor (40) is stored in the recording means (22). The server device (30) does not receive the sleep data immediately after being derived, but receives the sleep data that has been derived and accumulated in the recording means (22).

  According to a third aspect, in the first or second aspect, the display device (35) provides the subject (90) with information for diagnosing the sleep state of the subject (90) and improving the sleep state. It is a terminal device of a medical institution.

  In 3rd invention, terminal devices, such as a personal computer provided in the medical institution, comprise a display apparatus (35). And the terminal device of the medical institution which comprises a display apparatus (35) shows the sleep report sent from the server apparatus (30) on a display, or prints it on paper.

  In the present invention, processing of a signal detected by the sleep sensor (40) (that is, a signal related to biological information of the subject (90)) is performed by the local device (20), and sleep data obtained by the local device (20) is stored in the server. Sending to the device (30) using a communication line. In other words, instead of sending the huge amount of raw data obtained by the sleep sensor (40) to the server device (30) as in the past, the raw data obtained by the sleep sensor (40) is processed. Sleep data with a relatively small amount of data is transmitted to the server device (30). Therefore, according to the present invention, the amount of data transmitted using the communication line is reduced compared to the case where all of the raw data obtained by the sleep sensor (40) is transmitted to the server device (30) as in the prior art. It can be greatly reduced. As a result, it is possible to reduce the time and cost required for communication between the local device (20) and the server device (30).

  In the second aspect, the recording device (22) is provided in the local device (20), and the server device (30) receives the sleep data accumulated in the recording device (22) after being derived. For this reason, the sleep data for several days is accumulated in the recording means (22) of the local device (20), and the sleep data accumulated in the recording means (22) is collectively transmitted to the server device (30). It becomes possible. Therefore, according to this invention, the frequency which transmits sleep data from a local apparatus (20) to a server apparatus (30) can be reduced, and the usability of a sleep information provision system (10) can be improved.

  Moreover, according to the said 3rd invention, a sleep report can be shown to experts, such as a doctor of a medical institution, through a display apparatus (35), and suitable advice based on this sleep report is given to a test subject (90). It becomes possible to give.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  As shown in FIG. 1, the sleep information providing system (10) of this embodiment includes a central server (30) that is a server device, a signal processing unit (20) that is a local device, and a terminal personal computer that is a display device ( Personal computer) (35).

  The signal processing unit (20) can be connected to the terminal PC (35) via the communication cable (25), and can communicate with the terminal PC (35) using an interface such as USB (universal serial bus). It is configured. Moreover, as shown in FIG. 2, the sleep sensor (40) is connected to the signal processing unit (20).

  The central server (30) is configured to be able to communicate with the terminal personal computer (35) via the Internet, which is a type of communication line. The terminal PC (35) is installed in a medical institution such as a hospital. This terminal personal computer (35) displays this information sent from the central server (30) on a display to provide this information to a doctor of a medical institution. The terminal personal computer (35) also plays a role of transmitting data sent from the signal processing unit (20) to the central server (30). That is, this terminal personal computer (35) also serves as a transmission means for transmitting data stored in the signal processing unit (20) to the central server (30).

<Sleep sensor>
The sleep sensor (40) is configured to detect a signal related to biological information of the subject (90) while sleeping.

  Specifically, the sleep sensor (40) is comprised by the pressure receiving part (41), the pressure sensitive part (42), and the signal wire | line (43). The pressure receiving part (41) is constituted by a flexible hollow tube made of resin or the like, and is placed on a bedding (95) such as a bed or a futon. One end of the pressure receiving portion (41) is connected to the pressure sensing portion (42), and the other end is sealed. The pressure receiving part (41) is installed so as to cross the bedding (95), and the subject (90) lies on the pressure receiving part (41). On the other hand, although not shown, the pressure-sensitive part (42) includes a microphone and a pressure sensor, and is configured to measure fluctuations in the internal pressure of the pressure-receiving part (41) using this microphone or the like. The signal line (43) electrically connects the pressure sensing part (42) and the signal processing unit (20), and signals a signal related to the internal pressure of the pressure receiving part (41) obtained by the pressure sensing part (42). Transmit to the processing unit (20).

  In a state where the subject (90) is lying on the bedding (95), the internal pressure of the pressure receiving portion (41) varies due to body movement (eg, turning over, breathing, pulsation) of the subject (90). The pressure sensing part (42) converts the fluctuation of the internal pressure of the pressure receiving part (41) into an electrical signal and outputs it to the signal processing unit (20).

<Signal processing unit>
As shown in FIG. 3, the signal processing unit (20) includes a signal processing unit (21) and a data memory (22) as a recording means.

  The signal processing unit (21) receives a signal sent from the pressure sensing unit (42) through the signal line (43) (that is, a signal indicating fluctuations in the internal pressure of the pressure receiving unit (41)). The signal input from the pressure sensing unit (42) includes biological information of the subject (90). The signal processing unit (21) acquires the raw data by sampling the signal from the pressure sensing unit (42) at a sampling period of, for example, about 100 Hz, and temporarily stores the acquired raw data to a working memory outside the figure. save.

  For example, when raw data for one minute is accumulated in the memory, the signal processing unit (21) performs arithmetic processing using the accumulated raw data. Specifically, the sleep data indicating the sleep state of the subject (90) is extracted from the raw data by taking a standard deviation of the raw data stored in the memory or comparing the raw data with a predetermined reference value. To do. Examples of the sleep data include the sleep depth of the subject (90), the presence / absence and intensity of body movement, the heart rate, and the respiratory rate. The sleep data extracted by the signal processing unit (21) from the raw data for one minute is sent to the data memory (22). On the other hand, the raw data from which the sleep data has been extracted is erased from the work memory. New raw data is accumulated in the working memory in preparation for the next sleep data extraction.

  The data memory (22) is constituted by a semiconductor memory, a hard disk or the like. The data memory (22) sequentially stores sleep data input from the signal processing unit (21) at predetermined time intervals (every minute in the above example).

  The data memory (22) stores sleep data in a predetermined format as shown in FIG. 4, for example. Specifically, the format in the data memory (22) is divided into a header portion and a main body portion. Information common to the stored sleep data (for example, the identification number of the patient who is the subject, the identification number of the doctor in charge, the date of the measurement date, the measurement start time and end time, etc.) is recorded in the header part. . The sleep data extracted by the signal processing unit (21) is sequentially recorded in the main body, for example, every minute.

  When the signal processing unit (20) is connected to the terminal PC (35) via the communication cable (25), the sleep data stored in the data memory (22) is sucked into the terminal PC (35) and sent to the central server (30) Sent.

  The signal processing unit (20) may be provided with a temperature sensor that measures the room temperature, an illuminance sensor that measures the brightness of the room, a noise sensor that measures the noise in the room, and the like. When these sensors are provided in the signal processing unit (20), measured values obtained by these sensors are also stored in the data memory (22).

<Central server>
As described above, the central server (30) receives sleep data from the signal processing unit (20) via the terminal personal computer (35) and the Internet. The central server (30) creates a graph and a table based on the received sleep data, and creates a sleep report in which the created graph and table are laid out according to a predetermined format.

  FIG. 5 shows an example of a sleep report created by the central server (30). In the left half of the sleep report, columns of “sleep diary”, “sleep data list”, and “sleep quality” are provided. In the column of “Sleep Diary”, whether the subject (90) is in a sleeping state or in an awakening state is illustrated for each date and time by color-coding the band-like line. In the “Sleep Data List” column, sleep states such as bed / leave time, sleep / wake time, sleep time, intermediate wake-up time (WASO), frequency of mid-wake wake-up over 5 minutes (WASO5), etc. Is displayed in the form of a list. In the “sleep quality” column, a radar chart relating to a plurality of indicators indicating sleep quality and a comment explaining evaluation relating to sleep quality are displayed. On the other hand, in the right half of the sleep report, the transition of sleep data for one month is displayed in the form of a graph. In addition, a blank space is provided in the lower right corner of the sleep report to describe the comment of the doctor in charge.

  The central server (30) is provided with a storage unit (31) for storing the created sleep report. The storage unit (31) is configured by, for example, a large-capacity hard disk device. As shown in FIG. 6, for example, the storage unit (31) creates a folder for each signal processing unit (20) in a folder classified for each hospital, and creates a sleep report (strictly speaking, a sleep report). Data for drawing the report).

  The format of the sleep report created by the central server (30) need not be only one type. That is, the central server (30) may be configured so that a sleep report having a plurality of types of formats can be created, and an easy-to-use format may be appropriately selected according to the purpose of the user. Moreover, it is desirable that the data format of the sleep report created by the central server (30) can be displayed without using special software using a browser or the like.

-System operation-
The sleep sensor (40) and the signal processing unit (20) are lent out to a patient (subject) who visits the hospital. The patient takes the sleep sensor (40) and the signal processing unit (20) borrowed to the home, sets them in his bedding (95), and performs measurement. The patient performs measurement over a predetermined period of, for example, about 1 to 2 weeks. The sleep data obtained during that time is accumulated in the data memory (22) of the signal processing unit (20). When the predetermined period elapses, the patient visits the hospital again for consultation, and at that time, the sleep sensor (40) and the signal processing unit (20) are returned to the hospital.

  In the hospital, the signal processing unit (20) to which the staff is returned is connected to the terminal personal computer (35), and the sleep data recorded in the signal processing unit (20) is transmitted to the central server (30). That is, sleep data for one to two weeks is transmitted to the central server (30) in a batch. The central server (30) creates a sleep report based on the received sleep data, and sends the created sleep report back to the hospital terminal PC (35). The above operations are performed while a patient who visits a hospital waits for a medical examination. During the examination, the doctor in charge conducts an inquiry and diagnosis while referring to the sleep report prepared.

-Effect of the embodiment-
In the present embodiment, the signal processing unit (20) performs processing of signals related to the biological information of the subject (90) detected by the sleep sensor (40), and the sleep data obtained by the signal processing unit (20) is stored in the central server ( 30) to the Internet. In other words, rather than sending a huge amount of raw data obtained by the sleep sensor (40) to the server as in the past, a relatively large amount of data after processing the raw data obtained by the sleep sensor (40) The sleep data with little is transmitted to the central server (30). Therefore, according to the present embodiment, the amount of data transmitted using the Internet is greatly reduced as compared to the case where all the raw data obtained by the sleep sensor (40) is transmitted to the server as in the prior art. be able to. As a result, the time and cost required for communication between the signal processing unit (20) and the central server (30) can be reduced.

  Moreover, in this embodiment, the data memory (22) is provided in the signal processing unit (20), and the sleep data accumulated in the data memory (22) after derivation is transmitted to the central server (30). For this reason, several days' worth of sleep data is temporarily stored in the data memory (22) of the signal processing unit (20), and the sleep data stored in this data memo is sent to the central server (30) in a batch. It becomes possible. Therefore, according to the present embodiment, the frequency of transmitting sleep data from the signal processing unit (20) to the central server (30) can be reduced, and the usability of the sleep information providing system (10) can be improved. .

-Modification of the embodiment-
In this embodiment, the sleep data of the signal processing unit (20) is once taken up to the terminal personal computer (35), and the sleep data is transmitted from the terminal personal computer (35) to the central server (30). (20) may be directly connected to the Internet, and sleep data of the signal processing unit (20) may be directly transmitted to the central server (30).

  In this embodiment, the Internet is used to transmit sleep data to the central server (30). For example, the terminal PC (35) or the signal processing unit (20) is connected to the central server (30) through a dedicated line. Sleep data may be transmitted.

  In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  As described above, the present invention is useful for a sleep information providing system that provides information related to the sleep state of a subject.

It is a schematic block diagram of a sleep information provision system. It is a schematic perspective view which shows the installation state of a sleep sensor and a signal processing unit. It is a block diagram which shows the structure of a signal processing unit. It is the format of the data recorded on the data memory of the signal processing unit. It is an example of the sleep report which a central server produces. It is a data hierarchy at the time of storing a sleep report in a storage unit.

Explanation of symbols

20 Signal processing unit (local device)
22 Data memory (recording means)
30 Central server (server equipment)
35 Terminal PC (display device, terminal device)
40 Sleep sensor
90 subjects

Claims (3)

A local device connected to a sleep sensor (40) for detecting a signal related to biological information of the subject (90) and deriving sleep data indicating the sleep state of the subject (90) based on the signal received from the sleep sensor (40) (20)
A server device (30) that obtains sleep data from the local device (20) via a communication line and creates a sleep report that charts the acquired sleep data;
A sleep information providing system comprising: a display device (35) for displaying a sleep report acquired from the server device (30) via a communication line. In claim 1,
The local device (20) is provided with a recording means (22) for storing the derived sleep data,
The sleep information provision system, wherein the server device (30) acquires sleep data stored in the recording means (22) of the local device (20). In claim 1 or 2,
The display device (35) is a terminal device of a medical institution that provides the subject (90) with information for diagnosing the sleep state of the subject (90) and improving the sleep state. system.