CN110855408B - Urine conventional detection system based on wireless network - Google Patents

Abstract

The invention discloses a urine routine detection system based on a wireless network, which comprises: detection device, data acquisition device, base station and data storage center, detection device, data acquisition device, base station and data storage center are configured to carry out the following operation: detecting the urine routine sample by a detection device and generating detection data; transmitting, by a detection device, a lateral link scheduling request to a base station through a PUCCH; in response to receiving the sidelink scheduling request, transmitting, by the base station, a first uplink grant to the detection apparatus via the PDCCH; notifying, by the detection apparatus, the base station of a buffer status of the detection apparatus on the first uplink resource in response to receiving the first uplink grant; starting, by the detection device, a buffer status retransmission timer in response to notifying the base station of the buffer status of the detection device; in response to receiving the buffer status of the detection device, determining, by the base station, whether the base station can allocate sufficient lateral link resources to the detection device based on the buffer status of the detection device.

Description

Urine conventional detection system based on wireless network

Technical Field

The invention relates to the technical field of nephrology, in particular to a urine routine detection system based on a wireless network.

Background

The urine routine is one of three routine projects in medical inspection, and proteinuria or visible components in urinary sediments can appear in early stage of kidney diseases. The kit also has important reference value for diagnosing certain systemic diseases and diseases of other organs of the body influencing urine changes, such as diabetes, hematopathy, liver and gall diseases, epidemic hemorrhagic fever and the like. Meanwhile, the urine test can also reflect the treatment effect and prognosis of some diseases. The corresponding disease symptoms can be judged through the examination.

The prior art CN107767949B discloses a primary medical system, which includes at least one all-in-one machine terminal and a central management platform connected to the all-in-one machine terminal via a network, where the all-in-one machine terminal includes a plurality of inspection/analysis instruments, a communication module, and an informatization management platform connected to the plurality of inspection/analysis instruments, and the informatization management platform includes a data analysis module and a storage module, and is used to receive detection data transmitted from the inspection/analysis instruments, analyze the detection data to form a detection report, and transmit the detection data to the central management platform via the network connection.

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

It is an object of the present invention to provide a wireless network based urine routine detection system that overcomes the disadvantages of the prior art.

In order to achieve the above object, the present invention provides a urine routine detecting system based on a wireless network, comprising: the system comprises a detection device, a data acquisition device, a base station and a data storage center, wherein the detection device, the data acquisition device, the base station and the data storage center are configured to perform the following operations: detecting the urine routine sample by a detection device and generating detection data; transmitting, by a detection device, a lateral link scheduling request to a base station through a PUCCH; in response to receiving the sidelink scheduling request, transmitting, by the base station, a first uplink grant to the detection apparatus via the PDCCH, wherein the first uplink grant indicates the first uplink resource to the detection apparatus so that the detection apparatus can inform the base station of a buffer status of the detection apparatus on the first uplink resource; notifying, by the detection apparatus, the base station of a buffer status of the detection apparatus on the first uplink resource in response to receiving the first uplink grant; starting, by the detection device, a buffer status retransmission timer in response to notifying the base station of the buffer status of the detection device; in response to receiving the buffer status of the detection device, determining, by the base station, whether the base station can allocate enough lateral link resources to the detection device so that the detection device can transmit all buffered data in the allocated lateral link resources based on the buffer status of the detection device; if it is determined that the base station is capable of allocating sufficient lateral link resources to the detection apparatus so that the detection apparatus is capable of transmitting all buffered data in the allocated lateral link resources, transmitting, by the base station, a lateral link grant to the detection apparatus, wherein the lateral link grant indicates the lateral link resources, and wherein an identity identifier of the detection apparatus is included in the lateral link grant.

In a preferred embodiment, the detection device, the data acquisition device, the base station and the data storage center are configured to: stopping, by the detection device, the buffer status retransmission timer in response to receiving the side link grant; in response to receiving the lateral link authorization, sending, by the detection device, detection data to the data acquisition device on the lateral link resource indicated by the lateral link authorization; in response to receiving the detection data, sending, by the data acquisition device, the detection data to the base station; in response to receiving the detection data, the detection data is transmitted by the base station to a data storage center.

In a preferred embodiment, the detection device, the data acquisition device, the base station and the data storage center are configured to: if the base station is judged to be incapable of allocating enough lateral link resources to the detection device so that the detection device can transmit all the cached data in the allocated lateral link resources, the base station does not send any message to the detection device; responding to the overtime of the buffer state retransmission timer, and sending a lateral link scheduling request to the base station through a PUCCH again by the detection device; in response to receiving the sidelink scheduling request, re-transmitting, by the base station, the first uplink grant to the detection apparatus via the PDCCH, wherein the first uplink grant indicates the first uplink resource to the detection apparatus so that the detection apparatus can notify the base station of the buffer status of the detection apparatus on the first uplink resource; in response to receiving the first uplink grant, notifying, by the detection apparatus, the base station of the buffer status of the detection apparatus on the first uplink resource again; in response to notifying the base station of the buffer status of the detection apparatus, the buffer status retransmission timer is reset and started by the detection apparatus.

In a preferred embodiment, the detection device, the data acquisition device, the base station and the data storage center are configured to: transmitting, by a detection device, a scheduling request to a base station through a PUCCH; in response to receiving the scheduling request, transmitting, by the base station, a second uplink grant to the detection apparatus via the PDCCH, wherein the second uplink grant indicates a second uplink resource to the detection apparatus so that the detection apparatus can notify the base station of a buffer status of the detection apparatus on the second uplink resource; notifying, by the detection apparatus, the base station of the buffer status of the detection apparatus on the second uplink resource in response to receiving the second uplink grant; starting, by the detection device, a second buffer status retransmission timer in response to notifying the base station of the buffer status of the detection device; in response to receiving the buffer status of the detection apparatus, determining, by the base station, based on the buffer status of the detection apparatus, whether the base station is capable of allocating sufficient uplink resources to the detection apparatus so that the detection apparatus is capable of transmitting all buffered data in the allocated uplink resources; if it is determined that the base station is capable of allocating sufficient uplink resources to the detection apparatus such that the detection apparatus is capable of transmitting all buffered data in the allocated uplink resources, an uplink grant is sent by the base station to the detection apparatus, wherein the uplink resources are indicated in the uplink grant, and wherein an identity identifier of the detection apparatus is included in the uplink grant.

In a preferred embodiment, the detection device, the data acquisition device, the base station and the data storage center are configured to: stopping, by the detection apparatus, the second buffer status retransmission timer in response to receiving the uplink grant; in response to receiving the uplink grant, transmitting, by the detection device, detection data to the base station on uplink resources indicated by the uplink grant; sending, by the base station, the detection data to a data storage center in response to receiving the detection data; wherein the second uplink resource indicated by the second uplink grant is different from the first uplink resource indicated by the first uplink grant; the timeout period of the buffer status retransmission timer is shorter than the timeout period of the second buffer status retransmission timer.

The present invention also provides a computer-readable storage medium for a wireless network-based urine routine detection system, the computer-readable storage medium for a wireless network-based urine routine detection system comprising code, wherein the code enables the detection device, the data acquisition device, the base station, and the data storage center to: detecting the urine routine sample by a detection device and generating detection data; transmitting, by a detection device, a lateral link scheduling request to a base station through a PUCCH; in response to receiving the sidelink scheduling request, transmitting, by the base station, a first uplink grant to the detection apparatus via the PDCCH, wherein the first uplink grant indicates the first uplink resource to the detection apparatus so that the detection apparatus can inform the base station of a buffer status of the detection apparatus on the first uplink resource; notifying, by the detection apparatus, the base station of a buffer status of the detection apparatus on the first uplink resource in response to receiving the first uplink grant; starting, by the detection device, a buffer status retransmission timer in response to notifying the base station of the buffer status of the detection device; in response to receiving the buffer status of the detection device, determining, by the base station, whether the base station can allocate enough lateral link resources to the detection device so that the detection device can transmit all buffered data in the allocated lateral link resources based on the buffer status of the detection device; if it is determined that the base station is capable of allocating sufficient lateral link resources to the detection apparatus so that the detection apparatus is capable of transmitting all buffered data in the allocated lateral link resources, transmitting, by the base station, a lateral link grant to the detection apparatus, wherein the lateral link grant indicates the lateral link resources, and wherein an identity identifier of the detection apparatus is included in the lateral link grant.

In a preferred embodiment, a computer readable storage medium for a wireless network based urine routine detection system includes code, wherein the code enables the detection device, the data acquisition device, the base station, and the data storage center to: stopping, by the detection device, the buffer status retransmission timer in response to receiving the side link grant; in response to receiving the lateral link authorization, sending, by the detection device, detection data to the data acquisition device on the lateral link resource indicated by the lateral link authorization; in response to receiving the detection data, sending, by the data acquisition device, the detection data to the base station; in response to receiving the detection data, the detection data is transmitted by the base station to a data storage center.

In a preferred embodiment, a computer readable storage medium for a wireless network based urine routine detection system includes code, wherein the code enables the detection device, the data acquisition device, the base station, and the data storage center to: if the base station is judged to be incapable of allocating enough lateral link resources to the detection device so that the detection device can transmit all the buffered data in the allocated lateral link resources, the base station does not send any message to the detection device; responding to the timeout of the buffer state retransmission timer, and sending the lateral link scheduling request to the base station through the PUCCH again by the detection device; in response to receiving the sidelink scheduling request, re-transmitting, by the base station, the first uplink grant to the detection apparatus via the PDCCH, wherein the first uplink grant indicates the first uplink resource to the detection apparatus so that the detection apparatus can notify the base station of the buffer status of the detection apparatus on the first uplink resource; in response to receiving the first uplink grant, notifying, by the detection apparatus, the base station of the buffer status of the detection apparatus on the first uplink resource again; in response to notifying the base station of the buffer status of the detection device, the buffer status retransmission timer is reset and started by the detection device.

In a preferred embodiment, a computer readable storage medium for a wireless network based urine routine detection system includes code, wherein the code enables the detection device, the data acquisition device, the base station, and the data storage center to: transmitting, by a detection device, a scheduling request to a base station through a PUCCH; in response to receiving the scheduling request, transmitting, by the base station, a second uplink grant to the detection apparatus via the PDCCH, wherein the second uplink grant indicates the second uplink resource to the detection apparatus so that the detection apparatus can inform the base station of a buffer status of the detection apparatus on the second uplink resource; notifying, by the detection apparatus, the base station of the buffer status of the detection apparatus on the second uplink resource in response to receiving the second uplink grant; starting, by the detection device, a second buffer status retransmission timer in response to notifying the base station of the buffer status of the detection device; determining, by the base station, whether the base station can allocate sufficient uplink resources to the detection apparatus so that the detection apparatus can transmit all buffered data in the allocated uplink resources based on the buffer status of the detection apparatus in response to receiving the buffer status of the detection apparatus; if it is determined that the base station is capable of allocating sufficient uplink resources to the detection apparatus such that the detection apparatus is capable of transmitting all buffered data in the allocated uplink resources, an uplink grant is sent by the base station to the detection apparatus, wherein the uplink resources are indicated in the uplink grant, and wherein an identity identifier of the detection apparatus is included in the uplink grant.

In a preferred embodiment, a computer readable storage medium for a wireless network based urine routine detection system includes code, wherein the code enables the detection device, the data acquisition device, the base station, and the data storage center to: stopping, by the detection apparatus, the second buffer status retransmission timer in response to receiving the uplink grant; in response to receiving the uplink grant, transmitting, by the detection device, detection data to the base station on uplink resources indicated by the uplink grant; transmitting, by the base station, the detection data to a data storage center in response to receiving the detection data; wherein the second uplink resource of the second uplink grant indication is different from the first uplink resource of the first uplink grant indication; the timeout length of the buffer status retransmission timer is shorter than the timeout length of the second buffer status retransmission timer. Compared with the prior art, the invention has the following advantages that with the continuous improvement of the informatization degree of the hospital, the number of devices connected by WiFi in the hospital is multiplied, so that not only the mobile phone of a patient needs to use WiFi resources, but also auxiliary personnel such as doctors, nursing staff, cleaning staff and the like also need to use WiFi resources. In this case, if the detection device is connected to the WiFi system in a tasteless manner, the data transmission speed of the detection device is reduced, which may cause problems such as repeated unsuccessful detection data transmission. In order to solve the problem, hospitals should advocate the detection devices to access the wireless communication system for internet of things operation, so that since the base stations of the future 5G communication system are very dense, a small base station can be specially allocated to the detection devices, and thus, the data transmission speed of the detection devices can be guaranteed. In order to realize such a scenario, a corresponding system needs to be correspondingly proposed, and in order to solve the problem, the invention provides a urine routine detection system based on a wireless network.

Drawings

Fig. 1 is a schematic diagram of a system configuration 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 figure, the urine routine detection system based on the wireless network of the present invention includes a plurality of detection devices, a data acquisition device (for example, a mobile phone and a tablet computer with a relevant APP), a base station, and a data storage center, wherein the detection devices and the base station can perform wireless communication through an air interface, the detection devices and the data acquisition device can perform inter-device (D2D) communication, and the base station passes through a core network entity and the data storage center.

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

operation 101: detecting the conventional urine sample by a detection device and generating detection data;

operation 102: transmitting, by a detection device, a lateral link scheduling request to a base station through a PUCCH; operation 103: in response to receiving the sidelink scheduling request, transmitting, by the base station, a first uplink grant to the detection apparatus via the PDCCH, wherein the first uplink grant indicates a first uplink resource to the detection apparatus so that the detection apparatus can inform the base station of a buffer status of the detection apparatus on the first uplink resource;

operation 104: notifying, by the detection apparatus, the base station of a buffer status of the detection apparatus on the first uplink resource in response to receiving the first uplink grant;

operation 105: starting, by the detection device, a buffer status retransmission timer in response to notifying the base station of the buffer status of the detection device;

operation 106: in response to receiving the buffer status of the detection device, determining, by the base station, whether the base station can allocate enough lateral link resources to the detection device so that the detection device can transmit all buffered data in the allocated lateral link resources based on the buffer status of the detection device;

operation 107: if it is determined that the base station is capable of allocating sufficient sidelink resources to the detection device so that the detection device is capable of transmitting all buffered data in the allocated sidelink resources, a sidelink grant is sent by the base station to the detection device, wherein the sidelink grant indicates the sidelink resources, and wherein an identity identifier of the detection device is included in the sidelink grant.

In a preferred embodiment, the detection device, the data acquisition device, the base station and the data storage center are configured to: stopping, by the detection device, the buffer status retransmission timer in response to receiving the side link grant; in response to receiving the lateral link authorization, sending, by the detection device, detection data to the data acquisition device on a lateral link resource indicated by the lateral link authorization; in response to receiving the detection data, sending, by the data acquisition device, the detection data to the base station; in response to receiving the detection data, the detection data is transmitted by the base station to a data storage center.

In a preferred embodiment, the detection device, the data acquisition device, the base station and the data storage center are configured to: if the base station is judged to be incapable of allocating enough lateral link resources to the detection device so that the detection device can transmit all the cached data in the allocated lateral link resources, the base station does not send any message to the detection device; responding to the overtime of the buffer state retransmission timer, and sending a lateral link scheduling request to the base station through a PUCCH again by the detection device; in response to receiving the sidelink scheduling request, re-transmitting, by the base station, the first uplink grant to the detection apparatus via the PDCCH, wherein the first uplink grant indicates the first uplink resource to the detection apparatus so that the detection apparatus can notify the base station of the buffer status of the detection apparatus on the first uplink resource; in response to receiving the first uplink grant, notifying, by the detection apparatus, the base station of the buffer status of the detection apparatus on the first uplink resource again; in response to notifying the base station of the buffer status of the detection device, the buffer status retransmission timer is reset and started by the detection device.

In a preferred embodiment, the detection device, the data acquisition device, the base station and the data storage center are configured to: transmitting, by a detection device, a scheduling request to a base station through a PUCCH; in response to receiving the scheduling request, transmitting, by the base station, a second uplink grant to the detection apparatus via the PDCCH, wherein the second uplink grant indicates the second uplink resource to the detection apparatus so that the detection apparatus can inform the base station of a buffer status of the detection apparatus on the second uplink resource; notifying, by the detection apparatus, the buffer status of the detection apparatus on the second uplink resource to the base station in response to receiving the second uplink grant; starting, by the detection device, a second buffer status retransmission timer in response to notifying the base station of the buffer status of the detection device; determining, by the base station, whether the base station can allocate sufficient uplink resources to the detection apparatus so that the detection apparatus can transmit all buffered data in the allocated uplink resources based on the buffer status of the detection apparatus in response to receiving the buffer status of the detection apparatus; if it is determined that the base station is capable of allocating sufficient uplink resources to the detection apparatus such that the detection apparatus is capable of transmitting all buffered data in the allocated uplink resources, an uplink grant is sent by the base station to the detection apparatus, wherein the uplink resources are indicated in the uplink grant, and wherein an identity identifier of the detection apparatus is included in the uplink grant.

In a preferred embodiment, the detection device, the data acquisition device, the base station and the data storage center are configured to: stopping, by the detection apparatus, the second buffer status retransmission timer in response to receiving the uplink grant; in response to receiving the uplink grant, transmitting, by the detection device, detection data to the base station on uplink resources indicated by the uplink grant; transmitting, by the base station, the detection data to a data storage center in response to receiving the detection data; wherein the second uplink resource of the second uplink grant indication is different from the first uplink resource of the first uplink grant indication; the timeout period of the buffer status retransmission timer is shorter than the timeout period of the second buffer status retransmission timer.

The present invention also provides a computer-readable storage medium for a wireless network-based urine routine detection system, the computer-readable storage medium for a wireless network-based urine routine detection system comprising code, wherein the code enables the detection device, the data acquisition device, the base station, and the data storage center to: detecting the urine routine sample by a detection device and generating detection data; transmitting, by a detection device, a lateral link scheduling request to a base station through a PUCCH; in response to receiving the sidelink scheduling request, transmitting, by the base station, a first uplink grant to the detection apparatus via the PDCCH, wherein the first uplink grant indicates the first uplink resource to the detection apparatus so that the detection apparatus can inform the base station of a buffer status of the detection apparatus on the first uplink resource; notifying, by the detection apparatus, the base station of a buffer status of the detection apparatus on the first uplink resource in response to receiving the first uplink grant; starting, by the detection device, a buffer status retransmission timer in response to notifying the base station of the buffer status of the detection device; in response to receiving the buffer status of the detection device, determining, by the base station, whether the base station can allocate enough lateral link resources to the detection device so that the detection device can transmit all buffered data in the allocated lateral link resources based on the buffer status of the detection device; if it is determined that the base station is capable of allocating sufficient lateral link resources to the detection apparatus so that the detection apparatus is capable of transmitting all buffered data in the allocated lateral link resources, transmitting, by the base station, a lateral link grant to the detection apparatus, wherein the lateral link grant indicates the lateral link resources, and wherein an identity identifier of the detection apparatus is included in the lateral link grant.

In a preferred embodiment, a computer readable storage medium for a wireless network based urine routine detection system includes code, wherein the code enables the detection device, the data acquisition device, the base station, and the data storage center to: stopping, by the detection device, the buffer status retransmission timer in response to receiving the side link grant; in response to receiving the lateral link authorization, sending, by the detection device, detection data to the data acquisition device on the lateral link resource indicated by the lateral link authorization; in response to receiving the detection data, sending, by the data acquisition device, the detection data to the base station; in response to receiving the detection data, the detection data is transmitted by the base station to a data storage center.

In a preferred embodiment, a computer readable storage medium for a wireless network based urine routine detection system includes code, wherein the code enables the detection device, the data acquisition device, the base station, and the data storage center to: if the base station is judged to be incapable of allocating enough lateral link resources to the detection device so that the detection device can transmit all the cached data in the allocated lateral link resources, the base station does not send any message to the detection device; responding to the timeout of the buffer state retransmission timer, and sending the lateral link scheduling request to the base station through the PUCCH again by the detection device; in response to receiving the sidelink scheduling request, re-transmitting, by the base station, the first uplink grant to the detection apparatus via the PDCCH, wherein the first uplink grant indicates the first uplink resource to the detection apparatus so that the detection apparatus can inform the base station of a buffer status of the detection apparatus on the first uplink resource; in response to receiving the first uplink grant, notifying, by the detection apparatus, the base station of the buffer status of the detection apparatus on the first uplink resource again; in response to notifying the base station of the buffer status of the detection device, the buffer status retransmission timer is reset and started by the detection device.

In a preferred embodiment, a computer readable storage medium for a wireless network based urine routine detection system includes code, wherein the code enables the detection device, the data acquisition device, the base station, and the data storage center to: transmitting, by a detection device, a scheduling request to a base station through a PUCCH; in response to receiving the scheduling request, transmitting, by the base station, a second uplink grant to the detection apparatus via the PDCCH, wherein the second uplink grant indicates the second uplink resource to the detection apparatus so that the detection apparatus can inform the base station of a buffer status of the detection apparatus on the second uplink resource; notifying, by the detection apparatus, the buffer status of the detection apparatus on the second uplink resource to the base station in response to receiving the second uplink grant; starting, by the detection device, a second buffer status retransmission timer in response to notifying the base station of the buffer status of the detection device; in response to receiving the buffer status of the detection apparatus, determining, by the base station, based on the buffer status of the detection apparatus, whether the base station is capable of allocating sufficient uplink resources to the detection apparatus so that the detection apparatus is capable of transmitting all buffered data in the allocated uplink resources; if it is determined that the base station is capable of allocating sufficient uplink resources to the detection apparatus such that the detection apparatus is capable of transmitting all buffered data in the allocated uplink resources, an uplink grant is sent by the base station to the detection apparatus, wherein the uplink resources are indicated in the uplink grant, and wherein an identity identifier of the detection apparatus is included in the uplink grant.

In a preferred embodiment, a computer readable storage medium for a wireless network based urine routine detection system includes code, wherein the code enables the detection device, the data acquisition device, the base station, and the data storage center to: stopping, by the detection apparatus, the second buffer status retransmission timer in response to receiving the uplink grant; in response to receiving the uplink grant, transmitting, by the detecting means, detection data to the base station on uplink resources indicated by the uplink grant; transmitting, by the base station, the detection data to a data storage center in response to receiving the detection data; wherein the second uplink resource indicated by the second uplink grant is different from the first uplink resource indicated by the first uplink grant; the timeout period of the buffer status retransmission timer is shorter than the timeout period of the second buffer status retransmission timer. 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 (2)

1. A urine routine detection system based on a wireless network, characterized in that:

the wireless network-based urine routine detection system comprises: the system comprises a detection device, a data acquisition device, a base station and a data storage center, wherein the detection device, the data acquisition device, the base station and the data storage center are configured to perform the following operations: the data acquisition device is a mobile phone or a tablet computer provided with related APP, wherein the detection device and the base station can perform wireless communication through an air interface, the detection device and the data acquisition device can perform inter-device (D2D) communication, and the base station is connected with the data storage center through a core network entity;

detecting a urine routine sample by the detection device and generating detection data;

transmitting, by the detection device, a lateral link scheduling request to the base station through a PUCCH; in response to receiving the sidelink scheduling request, transmitting, by the base station, a first uplink grant to the detection apparatus via a PDCCH, wherein the first uplink grant indicates a first uplink resource to the detection apparatus so that the detection apparatus can notify the base station of a buffer status of the detection apparatus on the first uplink resource;

notifying, by the detection apparatus, the base station of a buffer status of the detection apparatus on the first uplink resource in response to receiving the first uplink grant;

starting, by the detection apparatus, a buffer status retransmission timer in response to notifying the base station of the buffer status of the detection apparatus;

in response to receiving the buffer status of the detection device, determining, by the base station, whether the base station can allocate enough lateral link resources to the detection device so that the detection device can transmit all buffered data in the allocated lateral link resources based on the buffer status of the detection device;

sending, by the base station, a sidelink grant to the detection apparatus if it is determined that the base station is capable of allocating sufficient sidelink resources to the detection apparatus for the detection apparatus to be able to transmit all buffered data in the allocated sidelink resources, wherein the sidelink grant indicates the sidelink resources, and wherein an identity identifier of the detection apparatus is included in the sidelink grant,

stopping, by the detection device, the buffer status retransmission timer in response to receiving the sidelink grant;

in response to receiving the sidelink authorization, sending, by the detection device, the detection data to the data collection device over the sidelink resource indicated by the sidelink authorization;

sending, by the data acquisition device, the detection data to the base station in response to receiving the detection data;

transmitting, by the base station, the detection data to the data storage center in response to receiving the detection data,

if the base station is judged to be incapable of allocating enough lateral link resources to the detection device so that the detection device can transmit all the cached data in the allocated lateral link resources, the base station does not send any message to the detection device;

in response to the buffer status retransmission timer expiring, re-sending, by the detection device, a lateral link scheduling request to the base station over a PUCCH;

in response to receiving the sidelink scheduling request, re-transmitting, by the base station, a first uplink grant to the detection apparatus via the PDCCH, wherein the first uplink grant indicates a first uplink resource to the detection apparatus so that the detection apparatus can inform the base station of a buffer status of the detection apparatus on the first uplink resource; in response to receiving the first uplink grant, re-notifying, by the detection apparatus, the base station of the buffer status of the detection apparatus on the first uplink resource;

resetting and starting, by the detection apparatus, a buffer status retransmission timer in response to notifying the base station of the buffer status of the detection apparatus,

transmitting, by the detection device, a scheduling request to the base station through a PUCCH;

in response to receiving the scheduling request, transmitting, by the base station, a second uplink grant to the detection apparatus via the PDCCH, wherein the second uplink grant indicates a second uplink resource to the detection apparatus so that the detection apparatus can inform the base station of a buffer status of the detection apparatus on the second uplink resource;

notifying, by the detection apparatus, the base station of a buffer status of the detection apparatus on the second uplink resource in response to receiving the second uplink grant;

starting, by the detection apparatus, a second buffer status retransmission timer in response to notifying the base station of the buffer status of the detection apparatus;

in response to receiving the buffer status of the detection apparatus, determining, by the base station, based on the buffer status of the detection apparatus, whether the base station can allocate sufficient uplink resources to the detection apparatus for the detection apparatus to be able to transmit all buffered data in the allocated uplink resources;

transmitting, by the base station, an uplink grant to the detection apparatus if it is determined that the base station is capable of allocating sufficient uplink resources to the detection apparatus so that the detection apparatus is capable of transmitting all buffered data in the allocated uplink resources, wherein the uplink grant indicates the uplink resources and wherein an identity identifier of the detection apparatus is included in the uplink grant,

stopping, by the detection apparatus, the second buffer status retransmission timer in response to receiving the uplink grant;

in response to receiving the uplink grant, transmitting, by the detecting device, the detection data to the base station on the uplink resource indicated by the uplink grant;

sending, by the base station, the detection data to the data storage center in response to receiving the detection data;

wherein a second uplink resource of the second uplink grant indication is different from a first uplink resource of the first uplink grant indication; the timeout length of the buffer status retransmission timer is shorter than the timeout length of the second buffer status retransmission timer.

2. A computer readable storage medium for a wireless network-based urine routine detection system, the computer readable storage medium for a wireless network-based urine routine detection system comprising code, wherein,

the code enables the detection device, the data acquisition device, the base station and the data storage center to: the data acquisition device is a mobile phone or a tablet computer provided with related APP, wherein the detection device and the base station can carry out wireless communication through an air interface, the detection device and the data acquisition device can carry out device-to-device (D2D) communication, the base station is connected with a data storage center through a core network entity,

detecting a urine routine sample by the detection device and generating detection data;

transmitting, by the detection device, a lateral link scheduling request to the base station through a PUCCH; in response to receiving the sidelink scheduling request, transmitting, by the base station, a first uplink grant to the detection apparatus via the PDCCH, wherein the first uplink grant indicates a first uplink resource to the detection apparatus so that the detection apparatus can inform the base station of a buffer status of the detection apparatus on the first uplink resource;

notifying, by the detection apparatus, the base station of a buffer status of the detection apparatus on the first uplink resource in response to receiving the first uplink grant;

starting, by the detection apparatus, a buffer status retransmission timer in response to notifying the base station of the buffer status of the detection apparatus;

in response to receiving the buffer status of the detection device, determining, by the base station, whether the base station can allocate enough lateral link resources to the detection device so that the detection device can transmit all buffered data in the allocated lateral link resources based on the buffer status of the detection device;

sending, by the base station, a sidelink grant to the detection apparatus if it is determined that the base station is capable of allocating sufficient sidelink resources to the detection apparatus for the detection apparatus to be able to transmit all buffered data in the allocated sidelink resources, wherein the sidelink grant indicates the sidelink resources, and wherein an identity identifier of the detection apparatus is included in the sidelink grant,

stopping, by the detection device, the buffer status retransmission timer in response to receiving the sidelink authorization;

in response to receiving the sidelink authorization, sending, by the detection device, the detection data to the data collection device over the sidelink resource indicated by the sidelink authorization;

sending, by the data acquisition device, the detection data to the base station in response to receiving the detection data;

transmitting, by the base station, the detection data to the data storage center in response to receiving the detection data,

if the base station is judged to be incapable of allocating enough lateral link resources to the detection device so that the detection device can transmit all the cached data in the allocated lateral link resources, the base station does not send any message to the detection device;

in response to the buffer status retransmission timer being expired, re-transmitting, by the detection device, a lateral link scheduling request to the base station over a PUCCH;

in response to receiving the sidelink scheduling request, re-transmitting, by the base station, a first uplink grant to the detection apparatus via the PDCCH, wherein the first uplink grant indicates a first uplink resource to the detection apparatus so that the detection apparatus can inform the base station of a buffer status of the detection apparatus on the first uplink resource; in response to receiving the first uplink grant, re-notifying, by the detection apparatus, the base station of the buffer status of the detection apparatus on the first uplink resource;

resetting and starting, by the detection apparatus, a buffer status retransmission timer in response to notifying the base station of the buffer status of the detection apparatus,

transmitting, by the detection device, a scheduling request to the base station through a PUCCH;

in response to receiving the scheduling request, transmitting, by the base station, a second uplink grant to the detection apparatus via the PDCCH, wherein the second uplink grant indicates a second uplink resource to the detection apparatus so that the detection apparatus can notify the base station of a buffer status of the detection apparatus on the second uplink resource;

notifying, by the detection apparatus, the base station of a buffer status of the detection apparatus on the second uplink resource in response to receiving the second uplink grant;

starting, by the detection apparatus, a second buffer status retransmission timer in response to notifying the base station of the buffer status of the detection apparatus;

in response to receiving the buffer status of the detection apparatus, determining, by the base station, based on the buffer status of the detection apparatus, whether the base station can allocate sufficient uplink resources to the detection apparatus so that the detection apparatus can transmit all buffered data in the allocated uplink resources;

transmitting, by the base station, an uplink grant to the detection apparatus if it is determined that the base station is capable of allocating sufficient uplink resources to the detection apparatus so that the detection apparatus is capable of transmitting all buffered data in the allocated uplink resources, wherein the uplink resources are indicated in the uplink grant and wherein an identity identifier of the detection apparatus is included in the uplink grant,

stopping, by the detection apparatus, the second buffer status retransmission timer in response to receiving the uplink grant;

transmitting, by the detecting means, the detection data to the base station on the uplink resource indicated by the uplink grant in response to receiving the uplink grant;

sending, by the base station, the detection data to the data storage center in response to receiving the detection data;

wherein a second uplink resource of the second uplink grant indication is different from a first uplink resource of the first uplink grant indication; the timeout length of the buffer status retransmission timer is shorter than the timeout length of the second buffer status retransmission timer.

Images