KR20150144150A - Battery power optimization system of telemedicine hub and method thereof - Google Patents

Abstract

According to the present invention, a system for optimizing battery power consumption of a telemedicine hub comprises: a communication unit (21) which performs communications between a telemedicine hub (20) and a telemedicine central server (10) by using cable and wireless communication; a near field communication unit (22) which communicates with a medical sensor device (30) through near field communication; a sensor unit (23) which senses a motion and location change of a service target; an interface unit (24) for connecting an external device; a battery unit (25) which supplies power; a memory unit (26) which stores a program for the telemedicine hub (20) and a data value generated when the program is operated; and a microprocessor (27) which executes the program of the memory unit (26).

Description

[0001] The present invention relates to a battery power optimization system for a telemedicine hub,

The present invention relates to a system and method for optimizing the battery power consumption of a remote medical hub, and more particularly, to a remote medical hub for connecting remote medical services and medical sensor devices of service subjects by a central server for communication with a central server And to optimize the power consumption of the battery by waiting for the mobile terminal to be in an offline state only when the mobile terminal is in an on-line state only when the mobile terminal is in an offline state and again when the communication is completed.

Nowadays, new forms of medical treatment such as telemedicine are being introduced because of the free transmission and reception of information through online such as the Internet, and telemedicine is a system in which a medical doctor , The patient's physical condition is checked and the test result is transmitted online to the patient. If you need periodic and ongoing medical services, such as elderly people with inadequate medical services or elderly people who are uncomfortable with the medical services, and telemedicine is used, There is an advantage to be able to receive.

The remote medical service is composed of a remote medical center server as a service subject, a medical sensor device of a service target person, a remote medical center server, and a remote medical hub for wirelessly connecting the medical sensor device, As the battery is being used, the hub always keeps on-line with the power applied, so there is a problem that the battery is frequently consumed and the battery needs to be changed frequently.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide a remote healthcare hub which connects medical sensor devices of remote medical service and service subjects by a central server, And to optimize the power consumption of the battery by waiting for an offline state when the communication is completed, and a method for optimizing the battery power consumption of the remote medical hub.

According to an aspect of the present invention, there is provided a remote medical service system including a remote medical center server for providing a remote medical service, a medical sensor device of a service person receiving remote medical service, And a remote medical hub 20 for wirelessly connecting the medical sensor device 30 with the remote medical hub 20. The remote medical hub 20 is connected to the remote medical center server 10 via a wired / A short range communication unit 22 for communicating with the medical sensor device 30 via short-range communication (Bluetooth, Wi-Fi, ZigBee, RF, etc.) A battery unit 25 for supplying power to all the components of the input remote medical hub 20, and a remote medical hub (not shown) And a microprocessor 27 for controlling the respective units and activating a program of the memory unit 26. The microprocessor 27 is connected to the memory unit 26, And a hub database 28 for storing data values of the sensor unit 23 and the medical sensor device 30 are connected to each other through the battery power consumption optimization system of the remote medical hub.

The present invention as described above enables the remote medical hub 20, which connects the remote medical service and the medical sensor devices 30 of the service subjects by the remote medical central server 10, to communicate with the central server 10 It is possible to optimize the power consumption of the battery by activating the system to be in an offline state only when it is necessary to wait for an offline state and waiting for an offline state when communication is completed.

1 is a system block diagram illustrating an embodiment of the present invention.
2 is a block diagram of a hub component illustrating an embodiment of the present invention.
3 is a flow chart illustrating an embodiment of the present invention
4 is a data structure diagram of a hub database illustrating an embodiment of the present invention

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

1 to 4, the remote medical service of the present invention includes a remote medical center server 10 providing remote medical services, a medical sensor device 30 of a service person receiving remote medical service, A hub database 28 is connected to the remote medical hub 20 and the remote medical hub 20 connecting the remote medical center server 10 and the medical sensor device 30 via wire or wireless communication.

The remote medical hub 20 includes a communication unit 21, a short range communication unit 22, a sensor unit 23, an interface unit 24, a battery unit 25, a memory unit 26 and a microprocessor 27 do.

The communication unit 21 transmits information of the medical sensor device 30 to the remote medical center server 10 using wire / wireless communication such as the Internet between the remote medical center server 10 and the remote medical hub 20, Information of the remote medical center server 10 is received.

The local communication unit 22 communicates information between the medical sensor device 30 and the remote medical hub 20 by using a short distance communication.

The short-range communication uses one or more of Bluetooth, WiFi, Zigbee, and Radio Frequency Identification (RFID).

The sensor unit 23 senses the movement and the positional change of the service target person and provides the data value through the microprocessor 27 to analyze the action radius and position during a specific period of the service target person.

The interface unit 24 is an interface for receiving data values such as a USB memory, which is an external memory, and for connecting an external device such as a computer.

The battery unit 25 supplies power to operate the communication unit 21, the short range communication unit 22, the sensor unit 23, the interface unit 24, the memory unit 26 and the microprocessor 27 do.

The memory unit 26 stores a program for the operation of the remote medical hub 20, and stores various data values and the like generated when the microprocessor 27 operates the program.

The microprocessor 27 reads and operates the program of the memory unit 26 and controls the communication unit 21, the short range communication unit 22, the sensor unit 23, the interface unit 24, the battery unit 25 ), The memory unit 26, and the like.

The hub database 28 analyzes the user's life pattern (time zone, monthly motion pattern analysis (momentum, activity time, sleeping time, etc.) by using the data values of the sensor unit 23 and the medical sensor device 30, Analysis of the behavior of the user through the external sensor device, analysis of the behavior radius and position during a specific period, and data of the behavior of the medical sensor device 30, Data 1, hub sensor data 2, medical sensor data 1, medical sensor data 2, medical sensor data 3, monitoring start time, and monitoring end time.

A method for optimizing the battery power consumption of the remote medical hub of the system of the present invention having the above-described configuration will now be described.

First, the remote medical hub 20 waits in a standby mode in an off-line state (S10).

The sensor unit 23 of the remote medical hub 20 in the standby mode senses the movement or the momentum of the service subject and sends the sensing signal to the microprocessor 27 (S20).

The microprocessor 27 receiving the detection signal reads the program of the memory unit 26 and drives the program to retrieve the data value of the hub database 28 and compare the data value with the detection signal to determine whether there is movement or momentum The process proceeds to the online step S40, and if there is no movement or momentum of the service subject, the process proceeds to the standby mode step S10 (S30).

In the analysis step S30, if there is a movement or a momentum of the service subject, the remote medical hub 20 is turned on (S40).

The microprocessor 27 of the remote medical hub 20 reads the program of the memory unit 26 and drives the program to operate the local communication unit 22 in the on- The data values of the medical sensor devices 30 stored in the memory unit 26 are stored in the memory unit 26 using the communication unit 21 and the data values of the medical sensor devices 30 stored in the memory unit 26 are stored in the memory unit 26, To the central server 10 (S50).

After transmitting the data values of the medical sensor devices 30 in the transmission step S50, the microprocessor 27 uses the data values of the sensor unit 23 and the medical sensor device 30 to calculate the life pattern of the user , Analysis of monthly motion pattern (momentum, activity time, sleeping time ,,, etc.), analysis of the behavior radius and position for a specific period, analysis of the patient's condition through external sensor device} The data of the medical sensor device 30 and the like are stored in the memory as the hub sensor data 1, the hub sensor data 2, the medical sensor data 1, the medical sensor data 2, the medical sensor data 3, the monitoring start time, In the hub database 28 and proceeds to the standby mode step S10 (S60).

As described above, according to the present invention, the remote medical hub 20 is activated in an online state only when it is necessary to wait in an off-line state according to a movement or a momentum of a service subject, It can be optimized.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but many variations and modifications may be made without departing from the scope of the invention. It will be understood by those skilled in the art that various changes may be made and equivalents may be resorted to without departing from the scope of the appended claims.

10: Remote medical central server 20: Remote medical hub
21: communication unit 22:
23: sensor unit 24: interface unit
25: battery unit 26: memory unit
27: microprocessor 28: hub database
30: Medical sensor device

Claims (3)

A remote medical center server 10 providing remote medical service and a medical sensor device 30 of a service subject who is provided with remote medical service are connected to the remote medical center server 10 and the medical sensor device 30 by wireless communication In a remote medical service comprised of a remote medical hub 20,
The remote medical hub 20 includes a communication unit 21 for communicating with the remote medical center server 10 using wire / wireless communication such as the Internet;
A short range communication section (22) for communicating with the medical sensor device (30) via short distance communication;
A sensor unit 23 for detecting a movement and a positional change of a service subject, an interface unit 24 for connecting an external memory and an external device,
A battery unit 25 for supplying power to all the components of the input remote medical hub 20;
A memory unit 26 for storing a program for the operation of the remote medical hub 20 and data values generated in the operation of the program;
A microprocessor 27 for controlling the respective units and activating a program of the memory unit 26;
And a hub database (28) for storing data values of the sensor unit (23) and the medical sensor device (30) are connected to each other.
The method according to claim 1,
Wherein the local communication uses at least one of Bluetooth, WiFi, Zigbee, and Radio Frequency Identification (RFID).
A standby mode step S10 in which the remote medical hub 20 waits in a standby mode in an off-line state;
A sensing step (S20) in which the sensor unit (23) of the remote medical hub (20) in the standby mode senses a movement or an amount of motion of a service subject;
The microprocessor 27 receiving the detection signal reads the program of the memory unit 26 and drives the program to search for and compare the data value of the hub database 28 with the detection signal S30;
An on-line step S40 of switching the remote medical hub 20 to an on-line state when there is a movement or a momentum of the service target in the analysis step S30;
The microprocessor 27 of the remote medical hub 20 reads the program of the memory unit 26 and drives the program to receive the data values of the medical sensor devices 30 by using the short range communication unit 22, (S50) of transmitting the data values of the medical sensor devices (30) to the remote medical center server (10) by using the data values of the medical sensor devices (30);
The microprocessor 27 is configured to store the data values of the sensor unit 23 and the medical sensor device 30 in the hub database 28 and to perform a standby step S60 to go to the standby mode step S10 A method for optimizing battery power consumption of a remote medical hub.

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