CN110856269A

CN110856269A - Pathology detecting system based on wireless transmission

Info

Publication number: CN110856269A
Application number: CN201911075912.4A
Authority: CN
Inventors: 裘柳懿; 杨勇; 陈丰农; 王茂峰; 葛飞航
Original assignee: Dongyang Peoples Hospital
Current assignee: Dongyang Peoples Hospital
Priority date: 2019-11-06
Filing date: 2019-11-06
Publication date: 2020-02-28

Abstract

The invention discloses a pathology detection system based on wireless transmission, which comprises: a pathology detection apparatus, a data collection apparatus, a base station, and a central server configured to: detecting the biological sample by a pathology detection device and generating detection data; by the pathology detection apparatus sending an RRC connection request message to the base station; transmitting, by the base station, an uplink grant to the pathology detection apparatus in response to receiving the RRC connection request message; in response to receiving the uplink grant, sending, by the pathology detection apparatus, a contention resolution message to the base station on the uplink resource; in response to receiving the contention resolution message, determining, by the base station, a type of a buffer status report included in the contention resolution message; and if the conventional buffer state report aiming at the inter-equipment communication is judged to be contained, scheduling time-frequency resources for the inter-equipment communication to the pathology detection device by the base station.

Description

Pathology detecting system based on wireless transmission

Technical Field

The invention relates to the technical field of pathology, in particular to a pathology detection system based on wireless transmission.

Background

Remote medical treatment refers to the remote diagnosis, treatment and consultation of the sick and wounded in remote areas, islands or ships with poor medical conditions by fully playing the advantages of medical technology and medical equipment of large hospitals or specialized medical centers by relying on computer technology, remote sensing, remote measuring and remote control technology.

The prior art CN106960128B discloses an intelligent medical data management method based on a distributed verification technology, which includes: s1, the user sends the personal identification information and the medical treatment information encrypted by the first user private key to the server in advance; the medical treatment information comprises information of a medical treatment legal authorizer and information of conflict rules; s2, sending the first user private key of the user to the server through the trusted channel; meanwhile, wearable identification code information is generated according to the private key of the first user; s3, configuring user medical format data, wherein the user medical data format comprises user basic information and user extension information, and the user basic information comprises a user unique identification number and gender; the user extension information comprises physiological index data and historical medical data; and S4, configuring the permission of the disclosure of each item of data in the user extension information according to the selection of the user, wherein the permission includes full disclosure data and limitation disclosure data, and setting disclosure object information corresponding to the limitation disclosure data.

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 pathology detection system based on wireless transmission, which can overcome the defects of the prior art.

In order to achieve the above object, the present invention provides a pathology detection system based on wireless transmission, comprising: pathology detection device, data collection device, base station and central server, wherein pathology detection device, data collection device, base station and central server are configured to: detecting the biological sample by a pathology detection device and generating detection data; by the pathology detection apparatus sending an RRC connection request message to the base station; transmitting, by the base station to the pathology detection apparatus, an uplink grant in response to receiving the RRC connection request message, wherein the uplink grant indicates uplink resources to the detection apparatus so that the pathology detection apparatus can transmit a contention resolution message to the base station; in response to receiving the uplink grant, transmitting, by the pathology detection apparatus, a contention resolution message on uplink resources to the base station, wherein if the pathology detection apparatus determines to transmit the detection data to the data collection apparatus, the contention resolution message includes a conventional buffer status report for inter-device communication; in response to receiving the contention resolution message, determining, by the base station, a type of a buffer status report included in the contention resolution message; if the contention resolution message contains a conventional cache state report aiming at the communication between the devices, scheduling time-frequency resources for the communication between the devices to a pathology detection device by a base station; sending, by a base station, an inter-device communication grant message to a pathology detection apparatus, wherein the inter-device communication grant message includes an indication of a time-frequency resource, and wherein the inter-device communication grant message is scrambled using an identity identifier of the pathology detection apparatus; in response to receiving the inter-device communication authorization message, the pathology detection apparatus determines that the random access procedure is successful and the contention resolution is successful; transmitting detection data to a data collection device on a time-frequency resource by a pathology detection device; the data collection device transmits the detection data to the base station, and the base station transmits the detection data to the central server.

In a preferred embodiment, wherein the pathology detection apparatus, the data collection apparatus, the base station and the central server are configured to: if the pathology detection apparatus determines that the detection data is to be transmitted to the data collection apparatus and the base station, the contention resolution message includes a conventional buffer status report for inter-device communication and a conventional buffer status report for uplink communication; in response to receiving the contention resolution message, determining, by the base station, a type of a buffer status report included in the contention resolution message; if the contention resolution message is judged to contain a conventional buffer status report for inter-device communication and a conventional buffer status report for uplink communication, scheduling, by the base station, a first time-frequency resource for inter-device communication and a second time-frequency resource for uplink transmission to the pathology detection apparatus; transmitting, by the base station, a communication grant message to the pathology detection apparatus, wherein the inter-device communication grant message includes an indication of the first time-frequency resource and the second time-frequency resource, and wherein the inter-device communication grant message is scrambled using an identity identifier of the pathology detection apparatus; in response to receiving the inter-device communication authorization message, the pathology detection apparatus determines that the random access procedure is successful and the contention resolution is successful; transmitting, by the pathology detection apparatus, a portion of the detection data on a first time-frequency resource to the data collection apparatus and another portion of the detection data on a second time-frequency resource to the base station; the data collection device transmits the detection data to the base station, and the base station transmits the detection data to the central server.

In a preferred embodiment, wherein the pathology detection apparatus, the data collection apparatus, the base station and the central server are configured to: if the pathology detection apparatus determines that the detection data is to be transmitted to the data collection apparatus, the contention resolution message includes a regular buffer status report for inter-device communication and a periodic buffer status report for uplink communication; in response to receiving the contention resolution message, determining, by the base station, a type of a buffer status report included in the contention resolution message; if the contention resolution message is judged to contain a conventional buffer status report for inter-device communication and a periodic buffer status report for uplink communication, scheduling, by the base station, a first time-frequency resource for inter-device communication and a second time-frequency resource for uplink transmission to the pathology detection apparatus; transmitting, by a base station, an inter-device communication grant message to a pathology detection apparatus, wherein the inter-device communication grant message includes an indication of a first time-frequency resource, and wherein the inter-device communication grant message is scrambled using an identity identifier of the pathology detection apparatus; transmitting, by the base station, an uplink communication grant message to the pathology detection apparatus, wherein the uplink communication grant message includes an indication of the second time-frequency resource, and wherein the inter-device communication grant message is scrambled using an identity identifier of the pathology detection apparatus; in response to receiving the inter-device communication authorization message, the pathology detection apparatus determines that the random access procedure is successful and the contention resolution is successful; transmitting, by the pathology detection apparatus, a portion of the detection data on a first time-frequency resource to the data collection apparatus and another portion of the detection data on a second time-frequency resource to the base station; sending the detection data to the base station by the data collection device, and sending the detection data to the central server by the base station; if the pathology detection device receives only the uplink communication authorization message, the pathology detection device judges that the random access process is unsuccessful and the contention resolution is unsuccessful; in response to determining that the random access procedure is unsuccessful and the contention resolution is unsuccessful, the normal buffer status report for inter-device communication and the periodic buffer status report for uplink communication are retransmitted to the base station by the pathology detection apparatus.

In a preferred embodiment, wherein the pathology detection apparatus, the data collection apparatus, the base station and the central server are configured to: if the pathology detection apparatus determines that the detection data is to be transmitted to the base station, the contention resolution message includes a periodic buffer status report for inter-device communication and a conventional buffer status report for uplink communication; in response to receiving the contention resolution message, determining, by the base station, a type of a buffer status report included in the contention resolution message; if the contention resolution message is judged to contain the periodic buffer status report aiming at the inter-device communication and the conventional buffer status report aiming at the uplink communication, the base station schedules a first time-frequency resource used for the inter-device communication and a second time-frequency resource used for the uplink transmission to the pathology detection device; transmitting, by a base station, an inter-device communication grant message to a pathology detection apparatus, wherein the inter-device communication grant message includes an indication of a first time-frequency resource, and wherein the inter-device communication grant message is scrambled using an identity identifier of the pathology detection apparatus; transmitting, by the base station, an uplink communication grant message to the pathology detection apparatus, wherein the uplink communication grant message includes an indication of the second time-frequency resource, and wherein the inter-device communication grant message is scrambled using an identity identifier of the pathology detection apparatus.

In a preferred embodiment, wherein the pathology detection apparatus, the data collection apparatus, the base station and the central server are configured to: in response to receiving the uplink communication grant message, determining, by the pathology detection apparatus, that the random access procedure is successful and the contention resolution is successful; transmitting, by the pathology detection apparatus, a portion of the detection data on a first time-frequency resource to the data collection apparatus and another portion of the detection data on a second time-frequency resource to the base station; sending the detection data to the base station by the data collection device, and sending the detection data to the central server by the base station; if the pathology detection device only receives the inter-device communication authorization message, the pathology detection device judges that the random access process is unsuccessful and the contention resolution is unsuccessful; in response to determining that the random access procedure is unsuccessful and the contention resolution is unsuccessful, the periodic buffer status report for inter-device communication and the regular buffer status report for uplink communication are retransmitted to the base station by the pathology detection apparatus.

The present invention also provides a computer-readable storage medium for a pathology detection system based on wireless transmission, comprising code enabling a pathology detection apparatus, a data collection apparatus, a base station, and a central server to: detecting the biological sample by a pathology detection device and generating detection data; by the pathology detection apparatus sending an RRC connection request message to the base station; transmitting, by the base station to the pathology detection apparatus, an uplink grant in response to receiving the RRC connection request message, wherein the uplink grant indicates uplink resources to the detection apparatus so that the pathology detection apparatus can transmit a contention resolution message to the base station; in response to receiving the uplink grant, transmitting, by the pathology detection apparatus, a contention resolution message on uplink resources to the base station, wherein if the pathology detection apparatus determines to transmit the detection data to the data collection apparatus, the contention resolution message includes a conventional buffer status report for inter-device communication; in response to receiving the contention resolution message, determining, by the base station, a type of a buffer status report included in the contention resolution message; if the contention resolution message contains a conventional cache state report aiming at the communication between the devices, scheduling time-frequency resources for the communication between the devices to a pathology detection device by a base station; sending, by a base station, an inter-device communication grant message to a pathology detection apparatus, wherein the inter-device communication grant message includes an indication of a time-frequency resource, and wherein the inter-device communication grant message is scrambled using an identity identifier of the pathology detection apparatus; in response to receiving the inter-device communication authorization message, the pathology detection apparatus determines that the random access procedure is successful and the contention resolution is successful; transmitting detection data to a data collection device on a time-frequency resource by a pathology detection device; the data collection device transmits the detection data to the base station, and the base station transmits the detection data to the central server.

In a preferred embodiment, a computer readable storage medium for a pathology detection system based on wireless transmission comprises code enabling a pathology detection apparatus, a data collection apparatus, a base station, and a central server to: if the pathology detection apparatus determines that the detection data is to be transmitted to the data collection apparatus and the base station, the contention resolution message includes a conventional buffer status report for inter-device communication and a conventional buffer status report for uplink communication; in response to receiving the contention resolution message, determining, by the base station, a type of a buffer status report included in the contention resolution message; if the contention resolution message is judged to contain a conventional buffer status report for inter-device communication and a conventional buffer status report for uplink communication, scheduling, by the base station, a first time-frequency resource for inter-device communication and a second time-frequency resource for uplink transmission to the pathology detection apparatus; transmitting, by the base station, a communication grant message to the pathology detection apparatus, wherein the inter-device communication grant message includes an indication of the first time-frequency resource and the second time-frequency resource, and wherein the inter-device communication grant message is scrambled using an identity identifier of the pathology detection apparatus; in response to receiving the inter-device communication authorization message, the pathology detection apparatus determines that the random access procedure is successful and the contention resolution is successful; transmitting, by the pathology detection apparatus, a portion of the detection data on a first time-frequency resource to the data collection apparatus and another portion of the detection data on a second time-frequency resource to the base station; the data collection device transmits the detection data to the base station, and the base station transmits the detection data to the central server.

In a preferred embodiment, a computer readable storage medium for a pathology detection system based on wireless transmission comprises code enabling a pathology detection apparatus, a data collection apparatus, a base station, and a central server to: if the pathology detection apparatus determines that the detection data is to be transmitted to the data collection apparatus, the contention resolution message includes a regular buffer status report for inter-device communication and a periodic buffer status report for uplink communication; in response to receiving the contention resolution message, determining, by the base station, a type of a buffer status report included in the contention resolution message; if the contention resolution message is judged to contain a conventional buffer status report for inter-device communication and a periodic buffer status report for uplink communication, scheduling, by the base station, a first time-frequency resource for inter-device communication and a second time-frequency resource for uplink transmission to the pathology detection apparatus; transmitting, by a base station, an inter-device communication grant message to a pathology detection apparatus, wherein the inter-device communication grant message includes an indication of a first time-frequency resource, and wherein the inter-device communication grant message is scrambled using an identity identifier of the pathology detection apparatus; transmitting, by the base station, an uplink communication grant message to the pathology detection apparatus, wherein the uplink communication grant message includes an indication of the second time-frequency resource, and wherein the inter-device communication grant message is scrambled using an identity identifier of the pathology detection apparatus; in response to receiving the inter-device communication authorization message, the pathology detection apparatus determines that the random access procedure is successful and the contention resolution is successful; transmitting, by the pathology detection apparatus, a portion of the detection data on a first time-frequency resource to the data collection apparatus and another portion of the detection data on a second time-frequency resource to the base station; sending the detection data to the base station by the data collection device, and sending the detection data to the central server by the base station; if the pathology detection device receives only the uplink communication authorization message, the pathology detection device judges that the random access process is unsuccessful and the contention resolution is unsuccessful; in response to determining that the random access procedure is unsuccessful and the contention resolution is unsuccessful, the normal buffer status report for inter-device communication and the periodic buffer status report for uplink communication are retransmitted to the base station by the pathology detection apparatus.

In a preferred embodiment, a computer readable storage medium for a pathology detection system based on wireless transmission comprises code enabling a pathology detection apparatus, a data collection apparatus, a base station, and a central server to: if the pathology detection apparatus determines that the detection data is to be transmitted to the base station, the contention resolution message includes a periodic buffer status report for inter-device communication and a conventional buffer status report for uplink communication; in response to receiving the contention resolution message, determining, by the base station, a type of a buffer status report included in the contention resolution message; if the contention resolution message is judged to contain the periodic buffer status report aiming at the inter-device communication and the conventional buffer status report aiming at the uplink communication, the base station schedules a first time-frequency resource used for the inter-device communication and a second time-frequency resource used for the uplink transmission to the pathology detection device; transmitting, by a base station, an inter-device communication grant message to a pathology detection apparatus, wherein the inter-device communication grant message includes an indication of a first time-frequency resource, and wherein the inter-device communication grant message is scrambled using an identity identifier of the pathology detection apparatus; transmitting, by the base station, an uplink communication grant message to the pathology detection apparatus, wherein the uplink communication grant message includes an indication of the second time-frequency resource, and wherein the inter-device communication grant message is scrambled using an identity identifier of the pathology detection apparatus.

In a preferred embodiment, a computer readable storage medium for a pathology detection system based on wireless transmission comprises code enabling a pathology detection apparatus, a data collection apparatus, a base station, and a central server to: in response to receiving the uplink communication grant message, determining, by the pathology detection apparatus, that the random access procedure is successful and the contention resolution is successful; transmitting, by the pathology detection apparatus, a portion of the detection data on a first time-frequency resource to the data collection apparatus and another portion of the detection data on a second time-frequency resource to the base station; sending the detection data to the base station by the data collection device, and sending the detection data to the central server by the base station; if the pathology detection device only receives the inter-device communication authorization message, the pathology detection device judges that the random access process is unsuccessful and the contention resolution is unsuccessful; in response to determining that the random access procedure is unsuccessful and the contention resolution is unsuccessful, the periodic buffer status report for inter-device communication and the regular buffer status report for uplink communication are retransmitted to the base station by the pathology detection apparatus.

Compared with the prior art, the invention has the advantages that China has made a great deal of progress in 70 years after the country is built, but China is a vast large country with vast operators, the development conditions of all parts of the country are greatly different, and some high-quality medical resources are still concentrated in some two-line cities. Although the imbalance of the resource distribution still exists in a short time, the remote medical technology is relied on, and the current situation of the imbalance of the medical resource distribution can be completely relieved, the basic technology of the remote medical technology is the remote transmission of medical information, large-scale optical fiber communication is unrealistic to establish in some lagging areas (because the cost of the optical fiber communication is too high), a wireless communication system is feasible to establish in the lagging areas, the medical information in the lagging areas can be transmitted to experts of top hospitals far away by virtue of the wireless communication system, and then the experts can perform some preliminary diagnoses on the patients without going out of home so as to help the patients to determine the illness state as soon as possible. In order to realize the communication mode, a corresponding information transmission mode needs to be provided, and the invention provides a pathology detection system based on wireless transmission, which can help to realize the remote medical technology.

Drawings

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

FIG. 2 is a block diagram of a system 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. As shown in the drawings, the pathology detection system based on wireless transmission of the present invention includes: the pathology detection device (with a wireless communication module), the data collection device (such as a mobile phone), the base station and the central server can be communicated with each other, and the communication between the base station and the central server is realized through a core network and the Internet.

FIG. 2 is a block diagram of a system according to an embodiment of the invention. As shown in the figure, the pathology detection apparatus, the data collection apparatus, the base station, and the center server of the present invention are configured to perform the following operations:

step 101: detecting the biological sample by a pathology detection device and generating detection data;

step 102: by the pathology detection apparatus sending an RRC connection request message to the base station;

step 103: transmitting, by the base station to the pathology detection apparatus, an uplink grant in response to receiving the RRC connection request message, wherein the uplink grant indicates uplink resources to the detection apparatus so that the pathology detection apparatus can transmit a contention resolution message to the base station;

step 104: in response to receiving the uplink grant, transmitting, by the pathology detection apparatus, a contention resolution message on uplink resources to the base station, wherein if the pathology detection apparatus determines to transmit the detection data to the data collection apparatus, the contention resolution message includes a conventional buffer status report for inter-device communication;

step 105: in response to receiving the contention resolution message, determining, by the base station, a type of a buffer status report included in the contention resolution message;

step 106: if the contention resolution message contains a conventional cache state report aiming at the communication between the devices, scheduling time-frequency resources for the communication between the devices to a pathology detection device by a base station;

step 107: sending, by a base station, an inter-device communication grant message to a pathology detection apparatus, wherein the inter-device communication grant message includes an indication of a time-frequency resource, and wherein the inter-device communication grant message is scrambled using an identity identifier of the pathology detection apparatus;

step 108: in response to receiving the inter-device communication authorization message, the pathology detection apparatus determines that the random access procedure is successful and the contention resolution is successful;

step 109: transmitting detection data to a data collection device on a time-frequency resource by a pathology detection device;

step 110: the data collection device transmits the detection data to the base station, and the base station transmits the detection data to the central server.

The present invention also provides a computer-readable storage medium for a wireless transmission-based pathology detection system, the computer-readable storage medium for a wireless transmission-based pathology detection system comprising code that enables a pathology detection apparatus, a data collection apparatus, a base station, and a central server to: detecting the biological sample by a pathology detection device and generating detection data; by the pathology detection apparatus sending an RRC connection request message to the base station; transmitting, by the base station to the pathology detection apparatus, an uplink grant in response to receiving the RRC connection request message, wherein the uplink grant indicates uplink resources to the detection apparatus so that the pathology detection apparatus can transmit a contention resolution message to the base station; in response to receiving the uplink grant, transmitting, by the pathology detection apparatus, a contention resolution message on uplink resources to the base station, wherein if the pathology detection apparatus determines to transmit the detection data to the data collection apparatus, the contention resolution message includes a conventional buffer status report for inter-device communication; in response to receiving the contention resolution message, determining, by the base station, a type of a buffer status report included in the contention resolution message; if the contention resolution message contains a conventional cache state report aiming at the communication between the devices, scheduling time-frequency resources for the communication between the devices to a pathology detection device by a base station; sending, by a base station, an inter-device communication grant message to a pathology detection apparatus, wherein the inter-device communication grant message includes an indication of a time-frequency resource, and wherein the inter-device communication grant message is scrambled using an identity identifier of the pathology detection apparatus; in response to receiving the inter-device communication authorization message, the pathology detection apparatus determines that the random access procedure is successful and the contention resolution is successful; transmitting detection data to a data collection device on a time-frequency resource by a pathology detection device; the data collection device transmits the detection data to the base station, and the base station transmits the detection data to the central server.

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.

Claims

1. A pathology detection system based on wireless transmission, its characterized in that: the wireless transmission based pathology detection system comprises: a pathology detection apparatus, a data collection apparatus, a base station, and a central server, wherein the pathology detection apparatus, the data collection apparatus, the base station, and the central server are configured to:

detecting a biological sample by the pathology detection apparatus and generating detection data;

by the pathology detection apparatus sending an RRC connection request message to the base station;

transmitting, by the base station to the pathology detection apparatus, an uplink grant in response to receiving the RRC connection request message, wherein the uplink grant indicates uplink resources to the detection apparatus so that the pathology detection apparatus can transmit a contention resolution message to the base station;

transmitting, by the pathology detection apparatus, a contention resolution message to the base station on the uplink resource in response to receiving the uplink grant, wherein the contention resolution message includes a regular buffer status report for inter-device communication if the pathology detection apparatus determines to transmit the detection data to the data collection apparatus;

in response to receiving the contention resolution message, determining, by the base station, a type of a buffer status report included in the contention resolution message;

if the contention resolution message contains a conventional cache state report for inter-device communication, scheduling time-frequency resources for the inter-device communication to the pathology detection device by the base station;

transmitting, by the base station, an inter-device communication grant message to the pathology detection apparatus, wherein the inter-device communication grant message includes an indication of the time-frequency resource, and wherein the inter-device communication grant message is scrambled using an identity identifier of the pathology detection apparatus;

in response to receiving the inter-device communication authorization message, determining, by the pathology detection apparatus, that a random access procedure is successful and contention resolution is successful;

sending, by the pathology detection apparatus, the detection data to the data collection apparatus on the time-frequency resources;

the detection data is transmitted by the data collection device to the base station, and the base station transmits the detection data to the central server.

2. The wireless transmission-based pathology detection system of claim 1, wherein: wherein the pathology detection apparatus, data collection apparatus, base station and central server are configured to:

if the pathology detection apparatus determines to transmit the detection data to the data collection apparatus and the base station, the contention resolution message includes a normal buffer status report for inter-device communication and a normal buffer status report for uplink communication;

scheduling, by the base station, a first time-frequency resource for inter-device communication and a second time-frequency resource for uplink transmission to the pathology detection apparatus if it is determined that the contention resolution message includes a conventional buffer status report for inter-device communication and a conventional buffer status report for uplink communication;

transmitting, by the base station, a communication grant message to the pathology detection apparatus, wherein the inter-device communication grant message includes an indication of the first time-frequency resource and the second time-frequency resource, and wherein the inter-device communication grant message is scrambled using an identity identifier of the pathology detection apparatus;

transmitting, by the pathology detection apparatus, a portion of the detection data to the data collection apparatus on the first time-frequency resource and another portion of the detection data to the base station on the second time-frequency resource;

3. The wireless transmission-based pathology detection system of claim 2, wherein: wherein the pathology detection apparatus, data collection apparatus, base station and central server are configured to:

if the pathology detection apparatus determines to transmit the detection data to the data collection apparatus, including a regular buffer status report for inter-device communication and a periodic buffer status report for uplink communication in the contention resolution message;

scheduling, by the base station, a first time-frequency resource for inter-device communication and a second time-frequency resource for uplink transmission to the pathology detection apparatus if it is determined that the contention resolution message includes a regular buffer status report for inter-device communication and a periodic buffer status report for uplink communication;

transmitting, by the base station, an inter-device communication grant message to the pathology detection apparatus, wherein the inter-device communication grant message includes an indication of the first time-frequency resource, and wherein the inter-device communication grant message is scrambled using an identity identifier of the pathology detection apparatus;

transmitting, by the base station, an uplink communication grant message to the pathology detection apparatus, wherein the uplink communication grant message includes an indication of the second time-frequency resource, and wherein the inter-device communication grant message is scrambled using an identity identifier of the pathology detection apparatus;

transmitting, by the data collection device, the detection data to the base station, and transmitting, by the base station, the detection data to the central server;

determining, by the pathology detection apparatus, that a random access procedure is unsuccessful and contention resolution is unsuccessful, if the pathology detection apparatus receives only the uplink communication grant message;

in response to determining that the random access procedure is unsuccessful and contention resolution is unsuccessful, retransmitting, by the pathology detection apparatus, a regular buffer status report for inter-device communication and a periodic buffer status report for uplink communication to the base station.

4. The wireless transmission-based pathology detection system of claim 3, wherein: wherein the pathology detection apparatus, data collection apparatus, base station and central server are configured to:

if the pathology detection apparatus determines to transmit the detection data to the base station, the contention resolution message includes a periodic buffer status report for inter-device communication and a regular buffer status report for uplink communication;

scheduling, by the base station, a first time-frequency resource for inter-device communication and a second time-frequency resource for uplink transmission to the pathology detection apparatus if it is determined that the contention resolution message includes a periodic buffer status report for inter-device communication and a conventional buffer status report for uplink communication;

transmitting, by the base station, an uplink communication grant message to the pathology detection apparatus, wherein the uplink communication grant message includes an indication of the second time-frequency resource, and wherein the inter-device communication grant message is scrambled using an identity identifier of the pathology detection apparatus.

5. The wireless transmission-based pathology detection system of claim 4, wherein: wherein the pathology detection apparatus, data collection apparatus, base station and central server are configured to:

determining, by the pathology detection apparatus, that a random access procedure is successful and contention resolution is successful in response to receiving the uplink communication grant message;

if the pathology detection apparatus receives only the inter-device communication authorization message, the pathology detection apparatus determines that a random access procedure is unsuccessful and contention resolution is unsuccessful;

in response to determining that the random access procedure is unsuccessful and contention resolution is unsuccessful, retransmitting, by the pathology detection apparatus, to the base station, the periodic buffer status report for inter-device communication and the regular buffer status report for uplink communication.

6. A computer-readable storage medium for a wireless transmission based pathology detection system, characterized by: the computer-readable storage medium for a pathology detection system based on wireless transmission includes code that enables a pathology detection apparatus, a data collection apparatus, a base station, and a central server to:

7. The computer-readable storage medium for a wireless transmission-based pathology detection system of claim 6, wherein: the computer-readable storage medium for a pathology detection system based on wireless transmission includes code that enables a pathology detection apparatus, a data collection apparatus, a base station, and a central server to:

if the pathology detection apparatus determines to transmit the detection data to the data collection apparatus and the base station, including a regular buffer status report for inter-device communication and a regular buffer status report for uplink communication in the contention resolution message;

8. The computer-readable storage medium for a wireless transmission-based pathology detection system of claim 7, wherein: the computer-readable storage medium for a pathology detection system based on wireless transmission includes code that enables a pathology detection apparatus, a data collection apparatus, a base station, and a central server to:

9. The computer-readable storage medium for a wireless transmission-based pathology detection system of claim 8, wherein: the computer-readable storage medium for a pathology detection system based on wireless transmission includes code that enables a pathology detection apparatus, a data collection apparatus, a base station, and a central server to:

10. The computer-readable storage medium for a wireless transmission-based pathology detection system of claim 9, wherein: the computer-readable storage medium for a pathology detection system based on wireless transmission includes code that enables a pathology detection apparatus, a data collection apparatus, a base station, and a central server to: