阅读说明：本技术 一种基于物联网的危重病人信息采集方法及系统 (Internet of things-based critical patient information acquisition method and system ) 是由 党晓敏 尚东 任徽 于 2021-07-27 设计创作，主要内容包括：本发明公开了一种基于物联网的危重病人信息采集方法,包括如下步骤：由第一移动终端收集危重病人的体征信息,并由第二移动终端收集危重病人的体征信息；由第一移动终端接收由基站分配的侧链路通信资源集合,并由第二移动终端接收由基站分配的侧链路通信资源集合；由第一移动终端在第一调度周期的调度分配周期时段内的第一子帧内向中继移动终端发送第一调度消息；由第二移动终端在第一调度周期的调度分配周期时段内的第二子帧内向中继移动终端发送第二调度消息；由第二移动终端监听由第一移动终端发送的第一调度消息,并由第二移动终端基于第一调度消息确定用于由第一移动终端发送数据的第一资源的时频位置。(The invention discloses a critical patient information acquisition method based on the Internet of things, which comprises the following steps: collecting the physical sign information of the critical patient by a first mobile terminal, and collecting the physical sign information of the critical patient by a second mobile terminal; receiving, by a first mobile terminal, a set of sidelink communication resources assigned by a base station, and receiving, by a second mobile terminal, the set of sidelink communication resources assigned by the base station; transmitting, by a first mobile terminal, a first scheduling message to a relay mobile terminal in a first subframe within a scheduling assignment cycle period of a first scheduling cycle; transmitting, by the second mobile terminal, a second scheduling message to the relay mobile terminal in a second subframe within the scheduling assignment cycle period of the first scheduling cycle; the method includes listening, by the second mobile terminal, for a first scheduling message sent by the first mobile terminal, and determining, by the second mobile terminal, a time-frequency location of a first resource for sending data by the first mobile terminal based on the first scheduling message.)

1. The critical patient information acquisition method based on the Internet of things is characterized by comprising the following steps of: collecting the physical sign information of the critical patient by a first mobile terminal, and collecting the physical sign information of the critical patient by a second mobile terminal; receiving, by a first mobile terminal, a set of sidelink communication resources assigned by a base station, and receiving, by a second mobile terminal, the set of sidelink communication resources assigned by the base station; transmitting, by a first mobile terminal, a first scheduling message to a relay mobile terminal within a first subframe within a scheduling assignment cycle period of a first scheduling cycle, wherein the first scheduling message includes an indication of a first resource for transmitting data by the first mobile terminal, wherein the first resource is located in a data period of a second scheduling cycle, wherein the first scheduling cycle is located in the set of sidelink communication resources; transmitting, by a second mobile terminal, a second scheduling message to a relay mobile terminal within a second subframe within a scheduling assignment cycle period of a first scheduling cycle, wherein the second scheduling message includes an indication of a second resource for transmitting data by the second mobile terminal, wherein the first resource at least partially overlaps with the second resource, wherein the second subframe is subsequent to the first subframe in a time domain, wherein the second resource is located in a data period of the second scheduling cycle, wherein the second scheduling cycle is located in the set of sidelink communication resources; monitoring, by a second mobile terminal, a first scheduling message sent by the first mobile terminal, and determining, by the second mobile terminal, a time-frequency location of a first resource for sending data by the first mobile terminal based on the first scheduling message; monitoring, by the first mobile terminal, a second scheduling message sent by the second mobile terminal, and determining, by the first mobile terminal, a time-frequency location of a second resource for sending data by the second mobile terminal based on the second scheduling message; transmitting, by a first mobile terminal, data to the relay mobile terminal on the first resources in response to determining that a time-frequency resource of the first resources that overlaps with the second resources and in response to the first scheduling message being transmitted within the first subframe.

2. The internet of things-based critical patient information collection method according to claim 1, wherein the internet of things-based critical patient information collection method comprises the following steps: in response to determining that the second scheduling message is transmitted within the second subframe, transmitting, by a second mobile terminal, a third scheduling message to a relay mobile terminal within a scheduling allocation period of the second scheduling period, wherein the third scheduling message indicates to the relay mobile terminal third resources for transmitting data by the second mobile terminal, wherein the third resources include ones of the second resources that do not overlap with the first resources; transmitting, by the second mobile terminal, data to the relay mobile terminal on the third resource in response to transmitting the third scheduling message to the relay mobile terminal.

3. The internet of things-based critical patient information collection method according to claim 2, wherein the internet of things-based critical patient information collection method comprises the following steps: receiving, by a first mobile terminal, a set of sidelink communication resources allocated by a base station, and receiving, by the first mobile terminal, a first indication sent by the base station, wherein the first indication indicates to the first mobile terminal how to split overlapping resources; receiving, by a second mobile terminal, a set of sidelink communication resources allocated by a base station, and receiving, by the second mobile terminal, a second indication sent by the base station, wherein the second indication indicates to the second mobile terminal how to split overlapping resources; monitoring, by a second mobile terminal, a first scheduling message sent by the first mobile terminal, and determining, by the second mobile terminal, a time-frequency location of a first resource for sending data by the first mobile terminal based on the first scheduling message; monitoring, by the first mobile terminal, a second scheduling message sent by the second mobile terminal, and determining, by the first mobile terminal, a time-frequency location of a second resource for sending data by the second mobile terminal based on the second scheduling message; determining, by a first mobile terminal, a first subset of the first resources that overlap with the second resources based on the first indication in response to determining that the first scheduling message is transmitted within the first subframe; in response to determining the first subset, transmitting, by the first mobile terminal, a fourth scheduling message to the relay mobile terminal within a scheduling allocation period of the second scheduling period, wherein the fourth scheduling message indicates to the relay mobile terminal fourth resources for transmitting data by the first mobile terminal, wherein the fourth resources comprise time-frequency resources of the first resources that do not overlap with the second resources and the fourth resources further comprise the first subset; transmitting, by the first mobile terminal, data to the relay mobile terminal on the fourth resource in response to transmitting the fourth scheduling message to the relay mobile terminal.

4. The internet of things-based critical patient information collection method according to claim 3, wherein the internet of things-based critical patient information collection method comprises the following steps: determining, by a second mobile terminal, a second subset of the second resources that overlap the first resources based on the second indication in response to determining that the second scheduling message is transmitted within the second subframe, wherein an amount of time-frequency resources in the first subset is greater than an amount of time-frequency resources in the second subset; in response to determining the second subset, transmitting, by a second mobile terminal, a fifth scheduling message to a relay mobile terminal within a scheduling allocation period of the second scheduling period, wherein the fifth scheduling message indicates to the relay mobile terminal fifth resources for transmitting data by the second mobile terminal, wherein the fifth resources comprise time-frequency resources of the second resources that do not overlap with the first resources and the fifth resources further comprise the second subset; transmitting, by the second mobile terminal, data to the relay mobile terminal on the fifth resource in response to transmitting the fifth scheduling message to the relay mobile terminal.

5. The internet of things-based critical patient information collection method according to claim 4, wherein the internet of things-based critical patient information collection method comprises the following steps: receiving, by a first mobile terminal, a set of sidelink communication resources allocated by a base station and receiving, by the first mobile terminal, a priority indication broadcast by the base station, wherein the priority indicates that the first mobile terminal has a low priority, wherein the priority indicates that the second mobile terminal has a high priority; receiving, by the second mobile terminal, the set of sidelink communication resources allocated by the base station and receiving, by the second mobile terminal, the priority indication broadcast by the base station; monitoring, by a second mobile terminal, a first scheduling message sent by the first mobile terminal, and determining, by the second mobile terminal, a time-frequency location of a first resource for sending data by the first mobile terminal based on the first scheduling message; monitoring, by the first mobile terminal, a second scheduling message sent by the second mobile terminal, and determining, by the first mobile terminal, a time-frequency location of a second resource for sending data by the second mobile terminal based on the second scheduling message; in response to determining that the first mobile terminal has a high priority, transmitting, by the first mobile terminal, a first scheduling message to a relay mobile terminal within a scheduling allocation period of a first scheduling period, wherein the first scheduling message indicates to the relay mobile terminal a first resource for transmitting data by the first mobile terminal, wherein the first resource includes a first resource that does not overlap with a second resource; transmitting, by a second mobile terminal, data to the relay mobile terminal on the second resource in response to determining that a time-frequency resource of the second resources that overlaps the first resource and in response to the first mobile terminal having a low priority.

6. The critical patient information collection system based on the Internet of things is characterized by comprising units for the following operations: collecting the physical sign information of the critical patient by a first mobile terminal, and collecting the physical sign information of the critical patient by a second mobile terminal; receiving, by a first mobile terminal, a set of sidelink communication resources assigned by a base station, and receiving, by a second mobile terminal, the set of sidelink communication resources assigned by the base station; transmitting, by a first mobile terminal, a first scheduling message to a relay mobile terminal within a first subframe within a scheduling assignment cycle period of a first scheduling cycle, wherein the first scheduling message includes an indication of a first resource for transmitting data by the first mobile terminal, wherein the first resource is located in a data period of a second scheduling cycle, wherein the first scheduling cycle is located in the set of sidelink communication resources; transmitting, by a second mobile terminal, a second scheduling message to a relay mobile terminal within a second subframe within a scheduling assignment cycle period of a first scheduling cycle, wherein the second scheduling message includes an indication of a second resource for transmitting data by the second mobile terminal, wherein the first resource at least partially overlaps with the second resource, wherein the second subframe is subsequent to the first subframe in a time domain, wherein the second resource is located in a data period of the second scheduling cycle, wherein the second scheduling cycle is located in the set of sidelink communication resources; monitoring, by a second mobile terminal, a first scheduling message sent by the first mobile terminal, and determining, by the second mobile terminal, a time-frequency location of a first resource for sending data by the first mobile terminal based on the first scheduling message; monitoring, by the first mobile terminal, a second scheduling message sent by the second mobile terminal, and determining, by the first mobile terminal, a time-frequency location of a second resource for sending data by the second mobile terminal based on the second scheduling message; transmitting, by a first mobile terminal, data to the relay mobile terminal on the first resources in response to determining that a time-frequency resource of the first resources that overlaps with the second resources and in response to the first scheduling message being transmitted within the first subframe.

7. The internet of things based critical patient information collection system of claim 6, comprising means for: in response to determining that the second scheduling message is transmitted within the second subframe, transmitting, by a second mobile terminal, a third scheduling message to a relay mobile terminal within a scheduling allocation period of the second scheduling period, wherein the third scheduling message indicates to the relay mobile terminal third resources for transmitting data by the second mobile terminal, wherein the third resources include ones of the second resources that do not overlap with the first resources; transmitting, by the second mobile terminal, data to the relay mobile terminal on the third resource in response to transmitting the third scheduling message to the relay mobile terminal.

8. The internet of things based critical patient information collection system of claim 7, comprising means for: receiving, by a first mobile terminal, a set of sidelink communication resources allocated by a base station, and receiving, by the first mobile terminal, a first indication sent by the base station, wherein the first indication indicates to the first mobile terminal how to split overlapping resources; receiving, by a second mobile terminal, a set of sidelink communication resources allocated by a base station, and receiving, by the second mobile terminal, a second indication sent by the base station, wherein the second indication indicates to the second mobile terminal how to split overlapping resources; monitoring, by a second mobile terminal, a first scheduling message sent by the first mobile terminal, and determining, by the second mobile terminal, a time-frequency location of a first resource for sending data by the first mobile terminal based on the first scheduling message; monitoring, by the first mobile terminal, a second scheduling message sent by the second mobile terminal, and determining, by the first mobile terminal, a time-frequency location of a second resource for sending data by the second mobile terminal based on the second scheduling message; determining, by a first mobile terminal, a first subset of the first resources that overlap with the second resources based on the first indication in response to determining that the first scheduling message is transmitted within the first subframe; in response to determining the first subset, transmitting, by the first mobile terminal, a fourth scheduling message to the relay mobile terminal within a scheduling allocation period of the second scheduling period, wherein the fourth scheduling message indicates to the relay mobile terminal fourth resources for transmitting data by the first mobile terminal, wherein the fourth resources comprise time-frequency resources of the first resources that do not overlap with the second resources and the fourth resources further comprise the first subset; transmitting, by the first mobile terminal, data to the relay mobile terminal on the fourth resource in response to transmitting the fourth scheduling message to the relay mobile terminal.

9. The internet of things based critical patient information collection system of claim 8, wherein the internet of things based critical patient information collection system comprises means for: determining, by a second mobile terminal, a second subset of the second resources that overlap the first resources based on the second indication in response to determining that the second scheduling message is transmitted within the second subframe, wherein an amount of time-frequency resources in the first subset is greater than an amount of time-frequency resources in the second subset; in response to determining the second subset, transmitting, by a second mobile terminal, a fifth scheduling message to a relay mobile terminal within a scheduling allocation period of the second scheduling period, wherein the fifth scheduling message indicates to the relay mobile terminal fifth resources for transmitting data by the second mobile terminal, wherein the fifth resources comprise time-frequency resources of the second resources that do not overlap with the first resources and the fifth resources further comprise the second subset; transmitting, by the second mobile terminal, data to the relay mobile terminal on the fifth resource in response to transmitting the fifth scheduling message to the relay mobile terminal.

10. The internet of things based critical patient information collection system of claim 9, comprising means for: receiving, by a first mobile terminal, a set of sidelink communication resources allocated by a base station and receiving, by the first mobile terminal, a priority indication broadcast by the base station, wherein the priority indicates that the first mobile terminal has a low priority, wherein the priority indicates that the second mobile terminal has a high priority; receiving, by the second mobile terminal, the set of sidelink communication resources allocated by the base station and receiving, by the second mobile terminal, the priority indication broadcast by the base station; monitoring, by a second mobile terminal, a first scheduling message sent by the first mobile terminal, and determining, by the second mobile terminal, a time-frequency location of a first resource for sending data by the first mobile terminal based on the first scheduling message; monitoring, by the first mobile terminal, a second scheduling message sent by the second mobile terminal, and determining, by the first mobile terminal, a time-frequency location of a second resource for sending data by the second mobile terminal based on the second scheduling message; in response to determining that the first mobile terminal has a high priority, transmitting, by the first mobile terminal, a first scheduling message to a relay mobile terminal within a scheduling allocation period of a first scheduling period, wherein the first scheduling message indicates to the relay mobile terminal a first resource for transmitting data by the first mobile terminal, wherein the first resource includes a first resource that does not overlap with a second resource; transmitting, by a second mobile terminal, data to the relay mobile terminal on the second resource in response to determining that a time-frequency resource of the second resources that overlaps the first resource and in response to the first mobile terminal having a low priority.

Technical Field

The invention relates to the technical field of critical patient management, in particular to a critical patient information acquisition method and system based on the Internet of things.

Background

The critical patients refer to patients with unstable vital signs, rapid disease change, unstable functions of more than two organ systems, decline or failure, and the development of the disease may endanger the life of the patients.

Prior art CN203251437U discloses a regional critical patient real-time monitoring system based on wireless network, which includes: the system comprises a multi-physiological-parameter collector, a tree-shaped and star-shaped wireless hybrid sensing network and a central monitoring station; the multi-physiological-parameter collector is used for collecting vital signs (blood pressure, heart rate, blood oxygen saturation and body temperature) of a patient, and the physiological data collected by the multi-physiological-parameter collector is transmitted to a monitoring computer of a central monitoring station based on the tree-shaped and star-shaped wireless mixed sensing network.

The information disclosed in this background section is only for enhancement of understanding of the general background of the invention and should not be taken as an acknowledgement or any form of suggestion that this information forms the prior art already known to a person skilled in the art.

Disclosure of Invention

The invention aims to provide a method and a system for acquiring critical patient information based on the Internet of things, which can overcome the defects of the prior art.

In order to achieve the purpose, the invention provides a critical patient information acquisition method based on the Internet of things, which is characterized by comprising the following steps: collecting the physical sign information of the critical patient by a first mobile terminal, and collecting the physical sign information of the critical patient by a second mobile terminal; receiving, by a first mobile terminal, a set of sidelink communication resources assigned by a base station, and receiving, by a second mobile terminal, the set of sidelink communication resources assigned by the base station; transmitting, by a first mobile terminal, a first scheduling message to a relay mobile terminal within a first subframe within a scheduling assignment cycle period of a first scheduling cycle, wherein the first scheduling message includes an indication of a first resource for transmitting data by the first mobile terminal, wherein the first resource is located in a data period of a second scheduling cycle, wherein the first scheduling cycle is located in a sidelink communication resource set; transmitting, by the second mobile terminal, a second scheduling message to the relay mobile terminal within a second subframe within the scheduling assignment cycle period of the first scheduling cycle, wherein the second scheduling message includes an indication of a second resource for transmitting data by the second mobile terminal, wherein the first resource at least partially overlaps with the second resource, wherein, in the time domain, the second subframe is subsequent to the first subframe, wherein the second resource is located in a data period of the second scheduling cycle, wherein the second scheduling cycle is located in a set of sidelink communication resources; monitoring, by the second mobile terminal, a first scheduling message sent by the first mobile terminal, and determining, by the second mobile terminal, a time-frequency location of a first resource for sending data by the first mobile terminal based on the first scheduling message; monitoring, by the first mobile terminal, a second scheduling message sent by the second mobile terminal, and determining, by the first mobile terminal, a time-frequency location of a second resource for sending data by the second mobile terminal based on the second scheduling message; in response to determining that the time-frequency resource of the first resources overlaps with the second resource, and in response to the first scheduling message being transmitted within the first subframe, transmitting, by the first mobile terminal, data to the relay mobile terminal on the first resource.

In a preferred embodiment, the critical patient information acquisition method based on the internet of things comprises the following steps: in response to determining that a time-frequency resource of the second resources that overlaps with the first resource and in response to the second scheduling message being transmitted within the second subframe, transmitting, by the second mobile terminal, a third scheduling message to the relay mobile terminal within a scheduling allocation period of the second scheduling period, wherein the third scheduling message indicates to the relay mobile terminal a third resource for transmitting data by the second mobile terminal, wherein the third resource comprises a time-frequency resource of the second resources that does not overlap with the first resource; transmitting, by the second mobile terminal, data to the relay mobile terminal on the third resource in response to transmitting the third scheduling message to the relay mobile terminal.

In a preferred embodiment, the critical patient information acquisition method based on the internet of things comprises the following steps: receiving, by the first mobile terminal, a set of sidelink communication resources allocated by the base station, and receiving, by the first mobile terminal, a first indication sent by the base station, wherein the first indication indicates to the first mobile terminal how to split the overlapping resources; receiving, by the second mobile terminal, a set of sidelink communication resources allocated by the base station, and receiving, by the second mobile terminal, a second indication sent by the base station, wherein the second indication indicates to the second mobile terminal how to split the overlapping resources; monitoring, by the second mobile terminal, a first scheduling message sent by the first mobile terminal, and determining, by the second mobile terminal, a time-frequency location of a first resource for sending data by the first mobile terminal based on the first scheduling message; monitoring, by the first mobile terminal, a second scheduling message sent by the second mobile terminal, and determining, by the first mobile terminal, a time-frequency location of a second resource for sending data by the second mobile terminal based on the second scheduling message; determining, by the first mobile terminal, a first subset of time-frequency resources of the first resources that overlap with the second resources based on the first indication, in response to determining the time-frequency resources of the first resources that overlap with the second resources, and in response to the first scheduling message being transmitted within the first subframe; in response to determining the first subset, transmitting, by the first mobile terminal, a fourth scheduling message to the relay mobile terminal within a scheduling allocation period of the second scheduling period, wherein the fourth scheduling message indicates to the relay mobile terminal fourth resources for transmitting data by the first mobile terminal, wherein the fourth resources include time-frequency resources of the first resources that do not overlap with the second resources, and the fourth resources further include the first subset; transmitting, by the first mobile terminal, data to the relay mobile terminal on the fourth resource in response to transmitting the fourth scheduling message to the relay mobile terminal.

In a preferred embodiment, the critical patient information acquisition method based on the internet of things comprises the following steps: determining, by the second mobile terminal, a second subset of the second resources that overlap the first resources based on the second indication in response to determining that the time-frequency resources of the second resources that overlap the first resources and in response to the second scheduling message being transmitted within the second subframe, wherein an amount of the time-frequency resources in the first subset is greater than an amount of the time-frequency resources in the second subset; in response to determining the second subset, transmitting, by the second mobile terminal, a fifth scheduling message to the relay mobile terminal within a scheduling allocation period of the second scheduling period, wherein the fifth scheduling message indicates to the relay mobile terminal fifth resources for transmitting data by the second mobile terminal, wherein the fifth resources include time-frequency resources of the second resources that do not overlap with the first resources, and the fifth resources further include the second subset; transmitting, by the second mobile terminal, data to the relay mobile terminal on the fifth resource in response to transmitting the fifth scheduling message to the relay mobile terminal.

In a preferred embodiment, the critical patient information acquisition method based on the internet of things comprises the following steps: receiving, by the first mobile terminal, a set of sidelink communication resources allocated by the base station and receiving, by the first mobile terminal, a priority indication broadcast by the base station, wherein the priority indicates that the first mobile terminal has a low priority, wherein the priority indicates that the second mobile terminal has a high priority; receiving, by the second mobile terminal, the set of sidelink communication resources allocated by the base station and receiving, by the second mobile terminal, the priority indication broadcast by the base station; monitoring, by the second mobile terminal, a first scheduling message sent by the first mobile terminal, and determining, by the second mobile terminal, a time-frequency location of a first resource for sending data by the first mobile terminal based on the first scheduling message; monitoring, by the first mobile terminal, a second scheduling message sent by the second mobile terminal, and determining, by the first mobile terminal, a time-frequency location of a second resource for sending data by the second mobile terminal based on the second scheduling message; in response to determining that the time-frequency resources of the first resources overlap with the second resources and in response to the second mobile terminal having a high priority, transmitting, by the first mobile terminal, a sixth scheduling message to the relay mobile terminal within a scheduling allocation period of the second scheduling period, wherein the sixth scheduling message indicates to the relay mobile terminal sixth resources for transmitting data by the first mobile terminal, wherein the sixth resources include time-frequency resources of the first resources that do not overlap with the second resources; in response to determining that the time-frequency resource of the second resources overlaps the first resource, and in response to the first mobile terminal having a low priority, transmitting, by the second mobile terminal, data to the relay mobile terminal on the second resource.

The invention provides a critical patient information acquisition system based on the Internet of things, which is characterized by comprising the following units: collecting the physical sign information of the critical patient by a first mobile terminal, and collecting the physical sign information of the critical patient by a second mobile terminal; receiving, by a first mobile terminal, a set of sidelink communication resources assigned by a base station, and receiving, by a second mobile terminal, the set of sidelink communication resources assigned by the base station; transmitting, by a first mobile terminal, a first scheduling message to a relay mobile terminal within a first subframe within a scheduling assignment cycle period of a first scheduling cycle, wherein the first scheduling message includes an indication of a first resource for transmitting data by the first mobile terminal, wherein the first resource is located in a data period of a second scheduling cycle, wherein the first scheduling cycle is located in a sidelink communication resource set; transmitting, by the second mobile terminal, a second scheduling message to the relay mobile terminal within a second subframe within the scheduling assignment cycle period of the first scheduling cycle, wherein the second scheduling message includes an indication of a second resource for transmitting data by the second mobile terminal, wherein the first resource at least partially overlaps with the second resource, wherein, in the time domain, the second subframe is subsequent to the first subframe, wherein the second resource is located in a data period of the second scheduling cycle, wherein the second scheduling cycle is located in a set of sidelink communication resources; monitoring, by the second mobile terminal, a first scheduling message sent by the first mobile terminal, and determining, by the second mobile terminal, a time-frequency location of a first resource for sending data by the first mobile terminal based on the first scheduling message; monitoring, by the first mobile terminal, a second scheduling message sent by the second mobile terminal, and determining, by the first mobile terminal, a time-frequency location of a second resource for sending data by the second mobile terminal based on the second scheduling message; in response to determining that the time-frequency resource of the first resources overlaps with the second resource, and in response to the first scheduling message being transmitted within the first subframe, transmitting, by the first mobile terminal, data to the relay mobile terminal on the first resource.

In a preferred embodiment, the internet of things based critical patient information collection system comprises means for: in response to determining that a time-frequency resource of the second resources that overlaps with the first resource and in response to the second scheduling message being transmitted within the second subframe, transmitting, by the second mobile terminal, a third scheduling message to the relay mobile terminal within a scheduling allocation period of the second scheduling period, wherein the third scheduling message indicates to the relay mobile terminal a third resource for transmitting data by the second mobile terminal, wherein the third resource comprises a time-frequency resource of the second resources that does not overlap with the first resource; transmitting, by the second mobile terminal, data to the relay mobile terminal on the third resource in response to transmitting the third scheduling message to the relay mobile terminal.

In a preferred embodiment, the internet of things based critical patient information collection system comprises means for: receiving, by the first mobile terminal, a set of sidelink communication resources allocated by the base station, and receiving, by the first mobile terminal, a first indication sent by the base station, wherein the first indication indicates to the first mobile terminal how to split the overlapping resources; receiving, by the second mobile terminal, a set of sidelink communication resources allocated by the base station, and receiving, by the second mobile terminal, a second indication sent by the base station, wherein the second indication indicates to the second mobile terminal how to split the overlapping resources; monitoring, by the second mobile terminal, a first scheduling message sent by the first mobile terminal, and determining, by the second mobile terminal, a time-frequency location of a first resource for sending data by the first mobile terminal based on the first scheduling message; monitoring, by the first mobile terminal, a second scheduling message sent by the second mobile terminal, and determining, by the first mobile terminal, a time-frequency location of a second resource for sending data by the second mobile terminal based on the second scheduling message; determining, by the first mobile terminal, a first subset of time-frequency resources of the first resources that overlap with the second resources based on the first indication, in response to determining the time-frequency resources of the first resources that overlap with the second resources, and in response to the first scheduling message being transmitted within the first subframe; in response to determining the first subset, transmitting, by the first mobile terminal, a fourth scheduling message to the relay mobile terminal within a scheduling allocation period of the second scheduling period, wherein the fourth scheduling message indicates to the relay mobile terminal fourth resources for transmitting data by the first mobile terminal, wherein the fourth resources include time-frequency resources of the first resources that do not overlap with the second resources, and the fourth resources further include the first subset; transmitting, by the first mobile terminal, data to the relay mobile terminal on the fourth resource in response to transmitting the fourth scheduling message to the relay mobile terminal.

In a preferred embodiment, the internet of things based critical patient information collection system comprises means for: determining, by the second mobile terminal, a second subset of the second resources that overlap the first resources based on the second indication in response to determining that the time-frequency resources of the second resources that overlap the first resources and in response to the second scheduling message being transmitted within the second subframe, wherein an amount of the time-frequency resources in the first subset is greater than an amount of the time-frequency resources in the second subset; in response to determining the second subset, transmitting, by the second mobile terminal, a fifth scheduling message to the relay mobile terminal within a scheduling allocation period of the second scheduling period, wherein the fifth scheduling message indicates to the relay mobile terminal fifth resources for transmitting data by the second mobile terminal, wherein the fifth resources include time-frequency resources of the second resources that do not overlap with the first resources, and the fifth resources further include the second subset; transmitting, by the second mobile terminal, data to the relay mobile terminal on the fifth resource in response to transmitting the fifth scheduling message to the relay mobile terminal.

In a preferred embodiment, the internet of things based critical patient information collection system comprises means for: receiving, by the first mobile terminal, a set of sidelink communication resources allocated by the base station and receiving, by the first mobile terminal, a priority indication broadcast by the base station, wherein the priority indicates that the first mobile terminal has a low priority, wherein the priority indicates that the second mobile terminal has a high priority; receiving, by the second mobile terminal, the set of sidelink communication resources allocated by the base station and receiving, by the second mobile terminal, the priority indication broadcast by the base station; monitoring, by the second mobile terminal, a first scheduling message sent by the first mobile terminal, and determining, by the second mobile terminal, a time-frequency location of a first resource for sending data by the first mobile terminal based on the first scheduling message; monitoring, by the first mobile terminal, a second scheduling message sent by the second mobile terminal, and determining, by the first mobile terminal, a time-frequency location of a second resource for sending data by the second mobile terminal based on the second scheduling message; in response to determining that the time-frequency resources of the first resources overlap with the second resources and in response to the second mobile terminal having a high priority, transmitting, by the first mobile terminal, a sixth scheduling message to the relay mobile terminal within a scheduling allocation period of the second scheduling period, wherein the sixth scheduling message indicates to the relay mobile terminal sixth resources for transmitting data by the first mobile terminal, wherein the sixth resources include time-frequency resources of the first resources that do not overlap with the second resources; in response to determining that the time-frequency resource of the second resources overlaps the first resource, and in response to the first mobile terminal having a low priority, transmitting, by the second mobile terminal, data to the relay mobile terminal on the second resource.

Compared with the prior art, the invention has the advantages that the critical patient management is always the key and difficult point of hospital management, and certain changes of the patients often cause disputes. In order to avoid disputes, hospitals often invest a large amount of manpower and material resources to manage critical patients, but due to limited judgment ability and limited energy of people, the mode of increasing manpower investment cannot achieve good effects. In order to improve the management efficiency of critical patients, the internet of things and a wearable monitoring device need to be introduced for assistance. Aiming at the needs of the prior art, the application provides a critical patient information acquisition method and system based on the Internet of things.

Drawings

FIG. 1 is a schematic diagram of a system architecture according to an embodiment of the present invention;

FIG. 2 is a flow diagram of a method according to an embodiment of the invention;

FIG. 3 is a timing diagram according to an embodiment of the invention.

Detailed Description

The following detailed description of the present invention is provided in conjunction with the accompanying drawings, but it should be understood that the scope of the present invention is not limited to the specific embodiments.

Throughout the specification and claims, unless explicitly stated otherwise, the word "comprise", or variations such as "comprises" or "comprising", will be understood to imply the inclusion of a stated element or component but not the exclusion of any other element or component.

FIG. 1 is a schematic diagram of a system architecture according to an embodiment of the present invention;

FIG. 2 is a flow diagram of a method according to an embodiment of the invention;

as shown in the figure, the method of the present invention comprises the steps of:

step 101: collecting the physical sign information of the critical patient by a first mobile terminal, and collecting the physical sign information of the critical patient by a second mobile terminal;

step 102: receiving, by a first mobile terminal, a set of sidelink communication resources assigned by a base station, and receiving, by a second mobile terminal, the set of sidelink communication resources assigned by the base station;

step 103: transmitting, by a first mobile terminal, a first scheduling message to a relay mobile terminal within a first subframe within a scheduling assignment cycle period of a first scheduling cycle, wherein the first scheduling message includes an indication of a first resource for transmitting data by the first mobile terminal, wherein the first resource is located in a data period of a second scheduling cycle, wherein the first scheduling cycle is located in a sidelink communication resource set;

step 104: transmitting, by the second mobile terminal, a second scheduling message to the relay mobile terminal within a second subframe within the scheduling assignment cycle period of the first scheduling cycle, wherein the second scheduling message includes an indication of a second resource for transmitting data by the second mobile terminal, wherein the first resource at least partially overlaps with the second resource, wherein, in the time domain, the second subframe is subsequent to the first subframe, wherein the second resource is located in a data period of the second scheduling cycle, wherein the second scheduling cycle is located in a set of sidelink communication resources;

step 105: monitoring, by the second mobile terminal, a first scheduling message sent by the first mobile terminal, and determining, by the second mobile terminal, a time-frequency location of a first resource for sending data by the first mobile terminal based on the first scheduling message;

step 106: monitoring, by the first mobile terminal, a second scheduling message sent by the second mobile terminal, and determining, by the first mobile terminal, a time-frequency location of a second resource for sending data by the second mobile terminal based on the second scheduling message;

step 107: in response to determining that the time-frequency resource of the first resources overlaps with the second resource, and in response to the first scheduling message being transmitted within the first subframe, transmitting, by the first mobile terminal, data to the relay mobile terminal on the first resource. Those skilled in the art should understand that since the first mobile terminal transmits data to the relay mobile terminal on the first resource, the first mobile terminal only needs to transmit a first scheduling message to the relay mobile terminal in the first sub-frame within the scheduling assignment period of the first scheduling cycle, and does not need to transmit a scheduling message to the relay mobile terminal again within the scheduling assignment period of the first scheduling cycle.

In a preferred embodiment, the critical patient information acquisition method based on the internet of things comprises the following steps: in response to determining that a time-frequency resource of the second resources that overlaps with the first resource and in response to the second scheduling message being transmitted within the second subframe, transmitting, by the second mobile terminal, a third scheduling message to the relay mobile terminal within a scheduling allocation period of the second scheduling period, wherein the third scheduling message indicates to the relay mobile terminal a third resource for transmitting data by the second mobile terminal, wherein the third resource comprises a time-frequency resource of the second resources that does not overlap with the first resource; transmitting, by the second mobile terminal, data to the relay mobile terminal on the third resource in response to transmitting the third scheduling message to the relay mobile terminal.

In a preferred embodiment, the critical patient information acquisition method based on the internet of things comprises the following steps: receiving, by the first mobile terminal, a set of sidelink communication resources allocated by the base station, and receiving, by the first mobile terminal, a first indication sent by the base station, wherein the first indication indicates to the first mobile terminal how to split the overlapping resources; the first indication may indicate how to partition the overlapping resources in various suitable manners, and in one embodiment, the first indication may indicate to the first mobile terminal that the first mobile terminal sequentially selects 70% of the overlapping resources, and in one embodiment, the first indication may indicate to the first mobile terminal sequentially selects 60% of the overlapping resources, and in one embodiment, assuming that a time-frequency resource overlapping with the second resource in the first resource includes 20 PRBs in a frequency domain and includes 14 symbols in a time domain, the first mobile terminal and the second mobile terminal may each define a resource unit composed of a first symbol in the time domain (a first symbol in time is referred to as a first symbol) and a first PRB in the frequency domain (a frequency is, for example, composed of the first PRB after high-to-low ordering) as a resource unit with a number of 1, the resource unit composed of the second symbol in the time domain and the first PRB in the frequency domain is defined as the number 2, the resource unit composed of the third symbol in the time domain and the first PRB in the frequency domain is defined as the number 3, and so on, and the resource unit composed of the first symbol in the time domain and the second PRB in the frequency domain is defined as the number 15, and so on. As mentioned before, the time-frequency resource overlapping the second resource in the first resource comprises 280 resource units numbered sequentially, if the first indication indicates to the first mobile terminal that the first mobile terminal sequentially selects 70% of the overlapping resources, then the first mobile terminal first selects the resource units numbered from 1 to 196 with 280 x 0.7=196, and then the first mobile terminal sequentially selects them as the first subset; receiving, by the second mobile terminal, a set of sidelink communication resources allocated by the base station, and receiving, by the second mobile terminal, a second indication sent by the base station, wherein the second indication indicates to the second mobile terminal how to split the overlapping resources; monitoring, by the second mobile terminal, a first scheduling message sent by the first mobile terminal, and determining, by the second mobile terminal, a time-frequency location of a first resource for sending data by the first mobile terminal based on the first scheduling message; monitoring, by the first mobile terminal, a second scheduling message sent by the second mobile terminal, and determining, by the first mobile terminal, a time-frequency location of a second resource for sending data by the second mobile terminal based on the second scheduling message; determining, by the first mobile terminal, a first subset of time-frequency resources of the first resources that overlap with the second resources based on the first indication, in response to determining the time-frequency resources of the first resources that overlap with the second resources, and in response to the first scheduling message being transmitted within the first subframe; in response to determining the first subset, transmitting, by the first mobile terminal, a fourth scheduling message to the relay mobile terminal within a scheduling allocation period of the second scheduling period, wherein the fourth scheduling message indicates to the relay mobile terminal fourth resources for transmitting data by the first mobile terminal, wherein the fourth resources include time-frequency resources of the first resources that do not overlap with the second resources, and the fourth resources further include the first subset; transmitting, by the first mobile terminal, data to the relay mobile terminal on the fourth resource in response to transmitting the fourth scheduling message to the relay mobile terminal.

In a preferred embodiment, the critical patient information acquisition method based on the internet of things comprises the following steps: determining, by the second mobile terminal, a second subset of the second resources that overlap the first resources based on the second indication in response to determining that the time-frequency resources of the second resources that overlap the first resources and in response to the second scheduling message being transmitted within the second subframe, wherein an amount of the time-frequency resources in the first subset is greater than an amount of the time-frequency resources in the second subset; in response to determining the second subset, transmitting, by the second mobile terminal, a fifth scheduling message to the relay mobile terminal within a scheduling allocation period of the second scheduling period, wherein the fifth scheduling message indicates to the relay mobile terminal fifth resources for transmitting data by the second mobile terminal, wherein the fifth resources include time-frequency resources of the second resources that do not overlap with the first resources, and the fifth resources further include the second subset; transmitting, by the second mobile terminal, data to the relay mobile terminal on the fifth resource in response to transmitting the fifth scheduling message to the relay mobile terminal.

In a preferred embodiment, the critical patient information acquisition method based on the internet of things comprises the following steps: receiving, by the first mobile terminal, a set of sidelink communication resources allocated by the base station and receiving, by the first mobile terminal, a priority indication broadcast by the base station, wherein the priority indicates that the first mobile terminal has a low priority, wherein the priority indicates that the second mobile terminal has a high priority; receiving, by the second mobile terminal, the set of sidelink communication resources allocated by the base station and receiving, by the second mobile terminal, the priority indication broadcast by the base station; monitoring, by the second mobile terminal, a first scheduling message sent by the first mobile terminal, and determining, by the second mobile terminal, a time-frequency location of a first resource for sending data by the first mobile terminal based on the first scheduling message; monitoring, by the first mobile terminal, a second scheduling message sent by the second mobile terminal, and determining, by the first mobile terminal, a time-frequency location of a second resource for sending data by the second mobile terminal based on the second scheduling message; in response to determining that the time-frequency resources of the first resources overlap with the second resources and in response to the second mobile terminal having a high priority, transmitting, by the first mobile terminal, a sixth scheduling message to the relay mobile terminal within a scheduling allocation period of the second scheduling period, wherein the sixth scheduling message indicates to the relay mobile terminal sixth resources for transmitting data by the first mobile terminal, wherein the sixth resources include time-frequency resources of the first resources that do not overlap with the second resources; in response to determining that the time-frequency resource of the second resources overlaps the first resource, and in response to the first mobile terminal having a low priority, transmitting, by the second mobile terminal, data to the relay mobile terminal on the second resource.

The invention provides a critical patient information acquisition system based on the Internet of things, which is characterized by comprising the following units: collecting the physical sign information of the critical patient by a first mobile terminal, and collecting the physical sign information of the critical patient by a second mobile terminal; receiving, by a first mobile terminal, a set of sidelink communication resources assigned by a base station, and receiving, by a second mobile terminal, the set of sidelink communication resources assigned by the base station; transmitting, by a first mobile terminal, a first scheduling message to a relay mobile terminal within a first subframe within a scheduling assignment cycle period of a first scheduling cycle, wherein the first scheduling message includes an indication of a first resource for transmitting data by the first mobile terminal, wherein the first resource is located in a data period of a second scheduling cycle, wherein the first scheduling cycle is located in a sidelink communication resource set; transmitting, by the second mobile terminal, a second scheduling message to the relay mobile terminal within a second subframe within the scheduling assignment cycle period of the first scheduling cycle, wherein the second scheduling message includes an indication of a second resource for transmitting data by the second mobile terminal, wherein the first resource at least partially overlaps with the second resource, wherein, in the time domain, the second subframe is subsequent to the first subframe, wherein the second resource is located in a data period of the second scheduling cycle, wherein the second scheduling cycle is located in a set of sidelink communication resources; monitoring, by the second mobile terminal, a first scheduling message sent by the first mobile terminal, and determining, by the second mobile terminal, a time-frequency location of a first resource for sending data by the first mobile terminal based on the first scheduling message; monitoring, by the first mobile terminal, a second scheduling message sent by the second mobile terminal, and determining, by the first mobile terminal, a time-frequency location of a second resource for sending data by the second mobile terminal based on the second scheduling message; in response to determining that the time-frequency resource of the first resources overlaps with the second resource, and in response to the first scheduling message being transmitted within the first subframe, transmitting, by the first mobile terminal, data to the relay mobile terminal on the first resource.

In a preferred embodiment, the internet of things based critical patient information collection system comprises means for: in response to determining that a time-frequency resource of the second resources that overlaps with the first resource and in response to the second scheduling message being transmitted within the second subframe, transmitting, by the second mobile terminal, a third scheduling message to the relay mobile terminal within a scheduling allocation period of the second scheduling period, wherein the third scheduling message indicates to the relay mobile terminal a third resource for transmitting data by the second mobile terminal, wherein the third resource comprises a time-frequency resource of the second resources that does not overlap with the first resource; transmitting, by the second mobile terminal, data to the relay mobile terminal on the third resource in response to transmitting the third scheduling message to the relay mobile terminal.

In a preferred embodiment, the internet of things based critical patient information collection system comprises means for: receiving, by the first mobile terminal, a set of sidelink communication resources allocated by the base station, and receiving, by the first mobile terminal, a first indication sent by the base station, wherein the first indication indicates to the first mobile terminal how to split the overlapping resources; receiving, by the second mobile terminal, a set of sidelink communication resources allocated by the base station, and receiving, by the second mobile terminal, a second indication sent by the base station, wherein the second indication indicates to the second mobile terminal how to split the overlapping resources; monitoring, by the second mobile terminal, a first scheduling message sent by the first mobile terminal, and determining, by the second mobile terminal, a time-frequency location of a first resource for sending data by the first mobile terminal based on the first scheduling message; monitoring, by the first mobile terminal, a second scheduling message sent by the second mobile terminal, and determining, by the first mobile terminal, a time-frequency location of a second resource for sending data by the second mobile terminal based on the second scheduling message; determining, by the first mobile terminal, a first subset of time-frequency resources of the first resources that overlap with the second resources based on the first indication, in response to determining the time-frequency resources of the first resources that overlap with the second resources, and in response to the first scheduling message being transmitted within the first subframe; in response to determining the first subset, transmitting, by the first mobile terminal, a fourth scheduling message to the relay mobile terminal within a scheduling allocation period of the second scheduling period, wherein the fourth scheduling message indicates to the relay mobile terminal fourth resources for transmitting data by the first mobile terminal, wherein the fourth resources include time-frequency resources of the first resources that do not overlap with the second resources, and the fourth resources further include the first subset; transmitting, by the first mobile terminal, data to the relay mobile terminal on the fourth resource in response to transmitting the fourth scheduling message to the relay mobile terminal.

In a preferred embodiment, the internet of things based critical patient information collection system comprises means for: determining, by the second mobile terminal, a second subset of the second resources that overlap the first resources based on the second indication in response to determining that the time-frequency resources of the second resources that overlap the first resources and in response to the second scheduling message being transmitted within the second subframe, wherein an amount of the time-frequency resources in the first subset is greater than an amount of the time-frequency resources in the second subset; in response to determining the second subset, transmitting, by the second mobile terminal, a fifth scheduling message to the relay mobile terminal within a scheduling allocation period of the second scheduling period, wherein the fifth scheduling message indicates to the relay mobile terminal fifth resources for transmitting data by the second mobile terminal, wherein the fifth resources include time-frequency resources of the second resources that do not overlap with the first resources, and the fifth resources further include the second subset; transmitting, by the second mobile terminal, data to the relay mobile terminal on the fifth resource in response to transmitting the fifth scheduling message to the relay mobile terminal.

In a preferred embodiment, the internet of things based critical patient information collection system comprises means for: receiving, by the first mobile terminal, a set of sidelink communication resources allocated by the base station and receiving, by the first mobile terminal, a priority indication broadcast by the base station, wherein the priority indicates that the first mobile terminal has a low priority, wherein the priority indicates that the second mobile terminal has a high priority; receiving, by the second mobile terminal, the set of sidelink communication resources allocated by the base station and receiving, by the second mobile terminal, the priority indication broadcast by the base station; monitoring, by the second mobile terminal, a first scheduling message sent by the first mobile terminal, and determining, by the second mobile terminal, a time-frequency location of a first resource for sending data by the first mobile terminal based on the first scheduling message; monitoring, by the first mobile terminal, a second scheduling message sent by the second mobile terminal, and determining, by the first mobile terminal, a time-frequency location of a second resource for sending data by the second mobile terminal based on the second scheduling message; in response to determining that the time-frequency resources of the first resources overlap with the second resources and in response to the second mobile terminal having a high priority, transmitting, by the first mobile terminal, a sixth scheduling message to the relay mobile terminal within a scheduling allocation period of the second scheduling period, wherein the sixth scheduling message indicates to the relay mobile terminal sixth resources for transmitting data by the first mobile terminal, wherein the sixth resources include time-frequency resources of the first resources that do not overlap with the second resources; in response to determining that the time-frequency resource of the second resources overlaps the first resource, and in response to the first mobile terminal having a low priority, transmitting, by the second mobile terminal, data to the relay mobile terminal on the second resource.

Due to the special environment of a hospital, which needs to use inter-device communication to implement a related technical solution, prior art 3GPP paper R1-144572 discloses an inter-device communication technique, in which a first mobile terminal sends a reservation message in a first subframe within an SA cycle period of a first scheduling cycle, a second mobile terminal sends a reservation message in a second subframe within the SA cycle period of the first scheduling cycle, and both mobile terminals select to reserve at least the same subframe within a data period of the first scheduling cycle. The problems of the prior art are as follows: since it is necessary to avoid transmitting data on the overlapped subframes, the mobile terminal can transmit only the reserved resource identifier and cannot transmit the scheduling information in the SA period of the first scheduling cycle. This is because the mobile terminal does not know whether other mobile terminals will occupy their scheduled data resources, and if other mobile terminals subsequently reserve the same resources as the scheduled resources, this overlapping resource must be discarded according to the prior art method, which will result in an error in the scheduling information that the mobile terminal initially transmits. That is, in the first scheduling period, any mobile terminal can only transmit the occupation information, which wastes the resources of the SA channel and increases the scheduling delay. Simply discarding all resources involved in the overlap results in a waste of resources, which is not significant when the number of overlapping resources is small, but the number of overlapping resources cannot be only 1 subframe on 1 subband, and is excessive when the number of subframes and the number of subbands increase. The present application is directed to efficient and waste-less scheduling of inter-device communications.

As will be appreciated by one skilled in the art, embodiments of the present application may be provided as a method, system, or computer program product. Accordingly, the present application may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present application may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and the like) having computer-usable program code embodied therein.

The present application is described with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems), and computer program products according to embodiments of the application. It will be understood that each flow and/or block of the flow diagrams and/or block diagrams, and combinations of flows and/or blocks in the flow diagrams and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

The foregoing descriptions of specific exemplary embodiments of the present invention have been presented for purposes of illustration and description. It is not intended to limit the invention to the precise form disclosed, and obviously many modifications and variations are possible in light of the above teaching. The exemplary embodiments were chosen and described in order to explain certain principles of the invention and its practical application to enable one skilled in the art to make and use various exemplary embodiments of the invention and various alternatives and modifications as are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the claims and their equivalents.