CN117809403A - Process management system, method and device coordinated with inspection process - Google Patents

Abstract

The invention provides a process management system, method and device that are coordinated with the inspection process, and relates to the field of medical technology. Based on the speed information and path distance information, obtain the first path time information corresponding to each item to be tested; obtain the standard waiting time information corresponding to the patient's items to be tested, and the test result waiting time information; obtain the time information of each item to be tested in different Corresponding total time information under the inspection order; select the total time information with the minimum value, and send the inspection order of the items to be inspected corresponding to the total time information to the user. The invention can obtain the total time information corresponding to each item to be inspected under different inspection orders, and send the inspection order of the item to be inspected corresponding to the total time information with the minimum value to the user. The invention can help patients reasonably arrange the inspection sequence of each item to be inspected.

Description

Flow management system, method and device coordinated with inspection flow

Technical Field

The invention belongs to the technical field of medical treatment, and particularly relates to a flow management system, method and device coordinated with an inspection flow.

Background

During hospital treatment, depending on the individual daily flows, there may be waiting times.

However, the current flow arrangement still has a number of inconveniences.

Due to the limited space inside the hospital, waiting areas may be congested with excessive people flow.

In addition, patients need to perform various physical examination or procedures, such as fee collection, initial diagnosis, examination, review, etc., each waiting takes a certain time, which results in a long waiting time of the patients.

During the course of a patient's different physical examination or procedures, it may be necessary to wait for the test results or reports. Such waiting times can extend patient visits and delay doctor diagnosis and treatment planning.

Furthermore, the physical condition of the patient who arrives at the hospital may be poor, and particularly for some patients with inconvenient legs and feet, the long waiting and walking may cause more difficulties and inconvenience, and different examination items are often not in the same area or the same floor, so that the patient with inconvenient legs and feet encounters difficulty in the walking process, which increases the consumption of physical strength and endurance of the patient. For these patients, they have a greater need to choose a shorter or more convenient path to reduce walking distance and time.

In summary, how to provide a process management system, method and device that coordinates with the inspection process is a technical problem that needs to be solved currently.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provides a flow management system, a method and a device which are coordinated with a checking flow, wherein the method and the device can acquire path distance information of a path between end point information and starting point information corresponding to each item to be checked and first path time information; summarizing the first path time information, the waiting time information and the waiting time information of the inspection result to obtain total time information corresponding to each item to be inspected under different inspection sequences; and the checking sequence of the items to be checked corresponding to the total time information with the minimum value is sent to the patient, so that the patient is helped to reasonably arrange the checking sequence of each item to be checked, and the total time value required to be consumed is reduced.

The invention provides a flow management method coordinated with a checking flow, S1, collecting the current position information of a patient as starting point information and the speed information of the patient;

s2, acquiring position information of a destination corresponding to a to-be-inspected item of a patient as terminal information, and acquiring path distance information based on the terminal information and the starting point information;

acquiring first path time information corresponding to each item to be checked based on the speed information and the path distance information;

s3, standard waiting time information corresponding to the item to be tested of the patient and testing result waiting time information are obtained;

s4, summarizing the first path time information, the waiting time information and the waiting time information of the inspection result to obtain total time information corresponding to each item to be inspected under different inspection sequences;

s5, selecting the total time information with the minimum value, and sending the checking sequence of the items to be checked corresponding to the total time information to the user. The method and the device can obtain the total time information corresponding to each item to be inspected under different inspection sequences, and send the inspection sequence of the item to be inspected corresponding to the total time information with the minimum value to the user.

Further, the step of S2 of acquiring the speed information of the patient includes acquiring different traveling modes of the patient and speed information corresponding to each traveling mode.

Further, the method further comprises the steps of obtaining medical record information of the patient, judging a preferable travelling mode of the patient, and obtaining speed information corresponding to the preferable travelling mode.

Further, S3 further comprises, in case of triggering the assist waiting mode, obtaining a waiting time of a first item to be checked of the patient, comprising the steps of:

acquiring speed information of an assisting person, and acquiring second path time information corresponding to the item to be inspected based on an acquisition result;

obtaining a time difference value of the first path time information and the second path time information;

and deducting the time difference value from the standard waiting time information to obtain the real waiting time information.

Further, the method further comprises the step of taking the true waiting time information of the rest items to be checked, which are arranged after the first item to be checked, to be 0.

Further, the step S2 further includes analyzing whether the start position and the end position in the path distance information relate to a change of the floor;

under the condition of involving floor change, step distance corresponding to the floor change is obtained, and step path time information corresponding to the floor change is obtained based on the step distance and speed information of a patient;

acquiring elevator path time information corresponding to floor change;

comparing the step path time with the elevator path time, selecting a smaller value, and adding the smaller value into the first path time information or the second path time information corresponding to the item to be checked.

Further, the step of obtaining the elevator path time information corresponding to the floors further comprises the step of respectively obtaining the elevator path time information of the escalator and the vertical elevator;

the step of acquiring the elevator path time information of the vertical elevator comprises the step of acquiring the vertical elevator waiting time information of the vertical elevator.

Further, the step of obtaining the path time information of the escalator comprises the step of continuously carrying out face recognition tracking on passengers stepping on the escalator until the passengers leave the escalator; the time that the passenger stays on the escalator is counted.

The invention also provides a process management system coordinated with the inspection process, which comprises the following steps:

the starting point information acquisition unit is used for acquiring the current position information of the patient as starting point information and the speed information of the patient;

a first path time obtaining unit for obtaining position information of a destination corresponding to an item to be inspected of a patient as end point information, and obtaining path distance information based on the end point information and the start point information;

acquiring first path time information corresponding to each item to be checked based on the speed information and the path distance information;

the test time acquisition unit is used for acquiring standard waiting time information corresponding to a to-be-tested item of a patient and test result waiting time information;

the path mode calculating unit is used for summarizing the first path time information, the waiting time information and the waiting time information of the inspection result to obtain total time information corresponding to each item to be inspected under different inspection sequences;

and the optimal path sending unit is used for selecting the total time information with the minimum value and sending the checking sequence of the items to be checked corresponding to the total time information to the user.

The invention also provides a flow management device coordinated with the inspection flow, comprising the following steps:

the starting point information acquisition module is used for acquiring the current position information of the patient as starting point information and the speed information of the patient;

the first path time obtaining module is used for obtaining position information of a destination corresponding to a to-be-inspected item of a patient as end point information and obtaining path distance information based on the end point information and the start point information;

acquiring first path time information corresponding to each item to be checked based on the speed information and the path distance information;

the test time acquisition module is used for acquiring standard waiting time information corresponding to a to-be-tested item of a patient and test result waiting time information;

the path mode calculation module is used for summarizing the first path time information, the waiting time information and the waiting time information of the inspection result to obtain total time information corresponding to each item to be inspected under different inspection sequences;

and the optimal path sending module is used for selecting the total time information with the minimum value and sending the checking sequence of the items to be checked corresponding to the total time information to the user.

Compared with the prior art, the invention has the following advantages and positive effects by taking the technical scheme as an example:

the first path time of each item can be calculated from the current position and speed information of the patient and the position information of the item to be checked. Meanwhile, the waiting time and the waiting time of the test result are considered, the total time of each item under different test sequences is obtained in a summarizing mode, the patient is helped to select the optimal test sequence, the time of the patient is saved, discomfort experienced by the patient in the test item due to overlong time consumption is reduced, and the experience of the patient is improved.

Different ways of patient travel and corresponding speed information are taken into account to calculate the first path time more accurately. The preferred advancing mode of the patient can be judged by acquiring the medical record information of the patient, and the corresponding speed information is judged and calculated based on the preferred advancing mode.

The invention also has an auxiliary waiting mode, in which the second path time information of the first to-be-checked item of the patient is analyzed, and the real waiting time information is adjusted according to the difference value of the first path time and the second path time, so as to obtain more accurate estimation of the waiting time and reduce the waiting time.

The invention also considers whether the change of the floor is related in the path distance information, calculates the step path time and the elevator path time required by the floor change under the condition of the floor change, selects a smaller value to be added into the path time information, and can more accurately obtain the path time information corresponding to each item to be checked, thereby being beneficial to the analysis of the total time information in the follow-up.

Drawings

Fig. 1 is a flow chart of a flow management method with coordinated inspection flow provided by the invention.

Detailed Description

The technical scheme disclosed in the invention is described in detail in the following with reference to specific embodiments.

Techniques, methods known to those of ordinary skill in the relevant art may not be discussed in detail, but should be considered part of the specification where appropriate. In all examples shown and discussed herein, any specific values should be construed as merely illustrative, and not a limitation. Thus, other examples of the exemplary embodiments may have different values.

The invention provides a flow management method coordinated with a checking flow, as shown in fig. 1, comprising the following steps:

s1, collecting current position information of a patient as starting point information and speed information of the patient.

The acquisition of the current position information and the speed information of the patient can be realized by a GPS positioning program on a terminal carried by the patient.

In another embodiment, the acquisition of the position information and the speed information is performed by means of wireless signals, for example, wireless signal devices such as Wi-Fi or bluetooth are installed inside a hospital, and are used for monitoring the position and the movement of the patient. By collecting and analyzing these signals, the patient's location and speed information in the hospital can be tracked in real time.

Similarly, sensors, such as infrared sensors or human motion sensors, may also be mounted at strategic locations within the hospital for detecting the arrival or departure of the patient. By combining the position information, the patient's speed information can be estimated.

For the acquisition of the speed information of the patient, the acquisition is not necessarily performed in a hospital, and the acquisition can be performed by calling the daily speed information of the patient. That is, the average traveling speed in the daily life scene at ordinary times, in which the patient is not in the hospital, is taken as the speed information in the present method.

The method is more suitable for general patients, and the speed is not obviously different in daily scenes and hospital scenes, so that the daily speed average value can be used as a reference of speed information in the flow management method.

In another embodiment, by tracking the location of the patient, when the patient is tracked to be at or near the hospital, it is determined that the patient has a tendency or need to seek medical attention, and at this time, a speed detection program is started to detect the traveling speed of the patient, and the average speed is used as speed information.

Alternatively, the patient may be manually triggered by the speed detection program as needed, and in the event of a trigger, the speed information acquisition operation for the patient may be initiated.

S2, acquiring position information of a destination corresponding to an item to be inspected of the patient as end point information, and acquiring path distance information based on the end point information and the start point information.

The path distance refers to a distance of travel from the current position of the patient to a destination to which the item to be inspected corresponds.

Based on the speed information and the path distance information, first path time information corresponding to each item to be checked is obtained.

S2, acquiring the speed information of the patient comprises acquiring different advancing modes of the patient and speed information corresponding to each advancing mode.

Different advancing modes in the daily life of a patient are monitored, such as walking, jogging, riding a bicycle and the like, and classification recording can be performed when speed information is acquired. This allows a more accurate knowledge of the patient's speed differences in different modes of travel.

For each travel pattern, information such as average speed, maximum speed, minimum speed, etc. of the patient may be recorded. Such speed information may be obtained through the use of smart devices, motion trackers, or other related techniques. For example, by monitoring a smart watch or a mobile phone application used by a patient in daily life, speed data for different modes of travel can be recorded.

By collecting speed information of different travelling modes of the patient, the travelling speed of the patient in the hospital can be estimated more accurately, so that the time required by the patient to reach the destination can be estimated better, and the examination sequence of the patient can be arranged more reasonably.

Further, S1 further includes acquiring medical record information of the patient, determining a preferred traveling mode of the patient, and acquiring speed information corresponding to the preferred traveling mode.

Medical record information includes, but is not limited to, patient base information, medical records, diagnostic results, drug prescriptions, test results, and the like.

And calling medical record information of the patient in the hospital electronic medical record system, extracting and screening key information related to the current disease or symptom of the patient, judging the physical condition of the patient, and obtaining a preferred travelling mode which corresponds to the physical condition and is most likely to be selected by the patient.

Key information includes, but is not limited to, department information that the patient has seen a doctor in the past, keywords related to the illness, past test items for the patient, results corresponding to the test items, and medications taken by the patient, and surgical or other treatment items that the patient has received.

Specifically, if the patient has been treated for orthopaedics and received the orthopaedics-related operation of the lower limb in the medical record information of the patient, it can be determined that the lower limb of the patient has a disease and the walking ability is limited. At this time, the patient is determined to be traveling in a preferred manner by wheelchair movement, by assistance from a crutch or the like, or by assistance from a walker, at a slower speed.

And correspondingly acquiring speed information corresponding to the movement of the wheelchair or acquiring speed information corresponding to the walking.

For another example, key information extracted from medical history information of a patient includes that the patient has been treated for heart surgery and has undergone heart surgery, it can be inferred that the heart of the patient may be ill, and walking may be limited to a certain extent. Alternatively, the patient has received chemotherapy or had other major illness. In a similar situation where it is determined that the patient's physical condition is poor, the patient is considered to be limited in walking, and the preferred way of travel may be slow walking or use of a wheelchair.

For another example, the extracted key information in the medical record information of the patient shows that the patient is diagnosed with the gynecological disease, takes the medicine related to the gynecological disease, has no other major diseases or other relevant information related to the diseases possibly causing the movement limitation, and can determine that the mobility of the patient is good.

In cases where the mobility of a person is good like this, the preferred way of travel may be running and/or walking. And correspondingly acquiring the speed information corresponding to running and/or walking.

Typically, adults can run at speeds up to 8-12 km/h, while walking at slower speeds, typically 4-6 km/h.

More preferably, the step S2 further includes analyzing whether the start position and the end position are on the same floor or involve a change in floor in the path distance information.

In the case of different floors, this is then considered to involve a change of floor.

In the case of floor changes, the patient moves between different floors, typically with 2 alternative ways of movement, in addition to the distance that the plane is required to move on a single floor.

First, the patient moves between floors via stairs.

And secondly, the patient moves between floors by an elevator.

The selection of these two options may be performed in conjunction with a previously acquired preferred travel pattern of the patient, determined based on patient medical record information. That is, when the patient has limited mobility or poor physical condition and the preferred travel mode is wheelchair or slow walking, the second option is selected.

In contrast, where patient mobility is not limited and the preferred mode of travel is running or walking, then both regimens one and two may be considered simultaneously.

In a scenario where it is assumed that the patient chooses to move between floors by stairs, a step distance corresponding to a floor change is obtained.

Specifically, it can be obtained by the following steps:

and determining the number of stairs which the patient needs to pass through according to the floor difference between the starting position and the ending position. For each stair, the number of steps of the stair and the height of each step are obtained. The step distance of each stair can be obtained by multiplying the step number of each stair by the step height.

For each hospital, the step distance between the upper and lower floors can be considered to be constant at the completion of construction of the stairs. The step distance corresponding to the floor change can be calculated by multiplying the preset step distance between adjacent floors by the number of floors needed to be spanned by the patient.

For example, the patient's starting point is on floor one, and the patient's item to be tested is on floor 3.

If the step distance between adjacent floors is 0.2 meters, the patient needs to go from 1 floor to 3 floors, then 0.2 meters can be multiplied by the number of spans of 2 floors to get a step distance of 0.4 meters.

Based on the step distance and the speed information of the patient, dividing the total step distance by the speed to obtain the step path time information corresponding to the floor change.

In a scenario where it is assumed that the patient chooses to move between floors by means of elevators, elevator path time information corresponding to the floors is obtained.

The elevators in hospitals are mainly two types, namely a vertical elevator and a handrail stair elevator.

The step of obtaining the elevator path time information corresponding to the floors further comprises the step of respectively obtaining the elevator path time information of the escalator and the vertical elevator.

The elevator path time of the escalator is related to the running speed of the escalator and the length of the escalator, so that the running speed of the escalator in real time is obtained, and the elevator path time of a single escalator can be obtained.

For the total elevator path time information of the escalator corresponding to the floor change, the elevator path time of the single escalator can be multiplied by the number of escalator elevators needed to be taken by a patient, so that the total elevator path time information of the escalator corresponding to the floor change is obtained.

When calculating the elevator path time, the start time, stop time and time for passengers to get on and off the elevator. These factors may affect the actual elevator path time. These factors can therefore be taken into account when calculating the elevator path time. Through daily running state to the elevator and the time of passenger's use elevator monitor, can obtain more accurate elevator route time information.

The time that the passenger gets on or off the elevator can be through shooing the elevator, cooperates face identification technique, when certain passenger steps on the elevator, carries out continuous face identification to track to it, until this passenger leaves the elevator, leaves the shooting scope. The time that the passenger stays on the elevator is then counted. The above procedure is repeated for different passengers, obtaining an average time for passengers to get on and off the elevator.

And for vertical elevators the operating speed of the vertical elevator is obtained by measuring or from information provided by the elevator manufacturer. The running speed is typically in meters per second or floors per second.

The height difference between each floor is acquired. The height difference may be obtained from a floor plan or measurement. The path time of the vertical elevator can be calculated by dividing the difference in height between floors by the running speed of the vertical elevator. For example, if the traveling speed of the vertical elevator is 1 m/s and the height difference between floors is 4 m, the path time is 4 seconds.

In some hospitals, the use of vertical elevators may require waiting in cases where the volume of people is high.

Still further, the acquiring elevator path time information of the vertical elevator includes acquiring vertical elevator latency information of the vertical elevator.

Factors affecting the waiting time information include, but are not limited to, the speed of travel of the vertical elevator, the floor height differential, the start time of the elevator, the stop time, the time for passengers to get on and off the elevator, and the waiting time of the vertical elevator.

Sensors or monitoring devices are installed to monitor the use of the elevator and collect elevator usage data including the number of passengers in different time periods, the waiting time of the elevator, the time of passengers getting on and off the elevator, etc. By analyzing these data, the average latency over different time periods can be derived.

When calculating and analyzing the elevator path time information, the average waiting time corresponding to the time period is matched by calling the current time period information, and the average waiting time is corrected by matching with the real-time monitoring result of the service condition of the elevator to be used as the vertical elevator waiting time information after correction.

Comparing the step path time with the elevator path time, selecting a smaller value, and adding the smaller value into the first path time information or the second path time information corresponding to the item to be checked.

Of course, if the determination result of the preferred travel mode of the patient is combined, the elevator path time or the step path time corresponding to the preferred travel mode is preferentially selected, and the smaller value of the step path time and the elevator path time is not necessarily selected.

Specifically, for example, if a patient with limited mobility, even if the elevator path time is longer than the step path time, the elevator path time is preferentially selected and added into the first path time information or the second path time information corresponding to the item to be checked.

For patients with unrestricted mobility, the step path time and the elevator path time are compared according to the common practice, and smaller values are selected and added into the first path time information or the second path time information corresponding to the item to be tested.

For example, the starting point information of a patient is on floor one, and the patient needs to go to floor 2 and floor 3, respectively, to accept the test item. The time required for the patient to reach the stairs or the elevator of the first floor, respectively, is calculated starting from the current position of the patient, and then the step path time for the patient to use the stairs and the elevator path time for the patient to use the elevator, respectively, are calculated.

The elevator path time is divided into the elevator path time of the escalator and the elevator vertical to the escalator, and the smaller value is selected as the elevator path time information of the patient.

The elevator path time of the patient is compared with the step path time, and a smaller value of the elevator path time is selected.

After the patient arrives at floor 2 by means of stairs or elevators, the patient also needs to travel a distance in floor 2 to arrive at the test item as the first end point, and the time required for the path is calculated.

The time from the starting point to the elevator of the patient is added to the time corresponding to the elevator path time and the time corresponding to the path required to move in the building 2, so that the first path time information of the patient from the starting point position and the first end point position can be obtained.

S3, standard waiting time information corresponding to the item to be tested of the patient and testing result waiting time information are obtained.

The patient may need to accept more than one item to be tested, each item being located at a different location and waiting time. And after the items to be inspected are received, corresponding waiting time of the inspection results exists until the inspection results come out.

The standard waiting time of each item to be checked is determined based on past records and statistical data. This refers to the average waiting time expected by a patient during waiting normally. Different standard waiting times are set according to different examination items, different wards or departments.

Examples: at a hospital chest CT was performed, with an average of 25 minutes waiting time between 9 and 12 am.

Also, based on the characteristics of each item to be inspected and the required processing time, the corresponding inspection result waiting time is estimated. This refers to the time required to wait for a report of results to be generated after the patient has completed the test.

Further, a test result waiting time is set. The total test time and reporting time were limited to 24 hours.

Variations in the volume of people in different time periods in a hospital may affect standard latency information and test result latency information.

By collecting and analyzing the historical data, average waiting time and test result waiting time corresponding to different time periods, different dates and different areas are obtained. If the volume of people is high, the average waiting time may be prolonged, the time for processing the test sample and generating the result report may be increased, and the standard waiting time and the test result waiting time may be adjusted according to the actual situation.

For example, the standard waiting time of the peak period is set to be at least greater than the standard waiting time of the low peak period, and the standard waiting time is increased in the peak period to reflect the longer waiting time, so that the waiting time of the patient can be estimated more accurately.

Further, by monitoring the traffic and waiting conditions in real time, the traffic is estimated, the real-time traffic is compared with the preset traffic corresponding to the preset standard waiting time and the waiting time of the checking result, and the standard waiting time and the waiting time of the checking result are correspondingly adjusted. If the flow of people suddenly increases, the waiting time and waiting time of the patient can be reasonably controlled by adjusting according to the real-time data.

S3 further comprises, in case of triggering the assisted waiting mode, obtaining a waiting time of a first item to be checked of the patient, comprising the steps of:

and acquiring speed information of the assisting person, and acquiring second path time information corresponding to the item to be inspected based on the acquisition result.

The speed information of the assisting person may be acquired in a similar manner to the speed information of the reference patient, and will not be described in detail herein. Likewise, the second path time information obtaining process may refer to the first path time information obtaining process described above.

It is noted that the second path and the first path may not be identical, as the speed and physical condition of the assisting person and the patient may be different, and the planning path selection result of the assisting person may be different from that of the patient.

For example, where patient movement is limited, the manner of travel is selected to be vertical elevators.

The assistant person can choose the escalator or the stair as the travelling mode because the movement is not limited.

This results in a second path which is selected by the assisting person and which is theoretically the shortest, and a first path which is selected by the patient and which is longer but which is adapted to his or her physical condition, being inconsistent in route, and furthermore, the first path time and the second path time may also be inconsistent due to inconsistent speeds of the assisting person and the patient.

And obtaining the time difference value of the first path time information and the second path time information.

For example, it takes 5 minutes for the assisting person to reach the first test position and 15 minutes for the patient. The assisting person starts waiting after reaching the end point. During the remaining ten minutes of patient continued to progress toward the endpoint, the patient may be considered to have been waiting since the assisting person is already waiting. When the patient reached the endpoint, the patient was considered to have been waiting ten minutes.

And deducting the time difference value from the standard waiting time information to obtain the real waiting time information.

For example, in a hospital, chest CT is performed, with a standard waiting time of 25 minutes on average between 9 and 12 am.

Assisting the person to reach the chest CT test item takes 5 minutes and the patient takes 15 minutes.

The real waiting time is: 25 min- (15 min-5 min) =15 min.

When the patient arrives at the first test position, the assisting person can go from the first test position to the second test position and start waiting in advance. After the patient completes the test item at the first test location, the patient is moved to the second test location and connected to the assisting person. At this point, the sum of the waiting time of the test item of the patient at the previous first test position and the time spent by the test procedure is considered to be greater than the waiting time required at the second test position. Thus, when the patient is connected with the helper, the patient is considered to be unnecessary to wait repeatedly, and the real waiting time information takes a value of 0.

After connection with the patient, the assisting person continues to go to the third test position, starts waiting in advance, and so on.

The true waiting time information of the remaining items to be inspected, which are arranged after the first item to be inspected, is valued at 0.

And S4, summarizing the first path time information, the waiting time information and the waiting time information of the inspection result to obtain total time information corresponding to each item to be inspected under different inspection sequences.

S5, selecting the total time information with the minimum value, and sending the checking sequence of the items to be checked corresponding to the total time information to the patient.

Under different inspection sequences, the first path time information, the waiting time information and the waiting time of the inspection result may be different from each other, so as to influence the value of the total time.

Specifically, for example, a patient with good mobility will participate in the A, B, C test on the 2,3,4 floors, respectively.

There are several test sequences: ABC, ACB, BAC, BCA, CAB, CBA.

For the checking order ABC, the total time is first path time (a) +wait time (a) +check result wait time (a) +first path time (B) +wait time (B) +check result wait time (B) +first path time (C) +wait time (C) +check result wait time (C).

For the inspection sequence ACB, the total time is first path time (a) +wait time (a) +inspection result wait time (a) +first path time (C) +wait time (C) +inspection result wait time (C) +first path time (B) +wait time (B) +inspection result wait time (B).

For other test sequences, the total time may be calculated in a similar manner, and finally all the calculation results are summarized, and the test sequence with the minimum total time is selected and sent to the patient for reference.

In practice, a special mobile phone application program can be designed to allow patients to check in when arriving at a hospital and record their location information. Through the mobile phone application, the hospital can track the position and speed of the patient in real time, thereby better arranging the waiting sequence.

For elderly users who do not partly carry an intelligent terminal, the patient may be provided with an intelligent device, such as a wristband or a smart watch, for monitoring and tracking the patient's position and speed. These devices can be connected to the hospital system for data transmission in real time, thereby achieving more accurate waiting and inspection process coordination.

The invention provides a flow management system coordinated with a checking flow, which comprises the following steps:

the starting point information acquisition unit is used for acquiring the current position information of the patient as starting point information and the speed information of the patient;

a first path time obtaining unit for obtaining position information of a destination corresponding to an item to be inspected of a patient as end point information, and obtaining path distance information based on the end point information and the start point information;

acquiring first path time information corresponding to each item to be checked based on the speed information and the path distance information;

the test time acquisition unit is used for acquiring standard waiting time information corresponding to a to-be-tested item of a patient and test result waiting time information;

the path mode calculating unit is used for summarizing the first path time information, the waiting time information and the waiting time information of the inspection result to obtain total time information corresponding to each item to be inspected under different inspection sequences;

and the optimal path sending unit is used for selecting the total time information with the minimum value and sending the checking sequence of the items to be checked corresponding to the total time information to the user.

The invention provides a flow management device coordinated with a checking flow, which comprises the following steps:

the starting point information acquisition module is used for acquiring the current position information of the patient as starting point information and the speed information of the patient;

the first path time obtaining module is used for obtaining position information of a destination corresponding to a to-be-inspected item of a patient as end point information and obtaining path distance information based on the end point information and the start point information;

acquiring first path time information corresponding to each item to be checked based on the speed information and the path distance information;

the test time acquisition module is used for acquiring standard waiting time information corresponding to a to-be-tested item of a patient and test result waiting time information;

the path mode calculation module is used for summarizing the first path time information, the waiting time information and the waiting time information of the inspection result to obtain total time information corresponding to each item to be inspected under different inspection sequences;

and the optimal path sending module is used for selecting the total time information with the minimum value and sending the checking sequence of the items to be checked corresponding to the total time information to the user.

Within the scope of the present disclosure, terms such as "comprising" and the like should be interpreted by default as inclusive or open-ended, rather than exclusive or closed-ended, unless expressly defined to the contrary. All technical, scientific, or other terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Common terms found in dictionaries should not be too idealized or too unrealistically interpreted in the context of the relevant technical document unless the present disclosure explicitly defines them as such.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (10)

1. A process management method coordinated with a verification process, comprising the steps of:

s1, collecting current position information of a patient as starting point information and speed information of the patient;

s2, acquiring position information of a destination corresponding to a to-be-inspected item of a patient as terminal information, and acquiring path distance information based on the terminal information and the starting point information;

acquiring first path time information corresponding to each item to be checked based on the speed information and the path distance information;

s3, standard waiting time information corresponding to the item to be tested of the patient and testing result waiting time information are obtained;

s4, summarizing the first path time information, the waiting time information and the waiting time information of the inspection result to obtain total time information corresponding to each item to be inspected under different inspection sequences;

s5, selecting the total time information with the minimum value, and sending the checking sequence of the items to be checked corresponding to the total time information to the patient.

2. The flow management method in coordination with a verification flow according to claim 1, wherein:

s2, acquiring the speed information of the patient comprises acquiring different advancing modes of the patient and speed information corresponding to each advancing mode.

3. The console intelligent support device of claim 2, wherein:

the method further comprises the steps of acquiring medical record information of the patient, judging a preferable advancing mode of the patient, and acquiring speed information corresponding to the preferable advancing mode.

4. The process control method according to claim 1, wherein,

s3 further comprises, in case of triggering the assisted waiting mode, obtaining a waiting time of a first item to be checked of the patient, comprising the steps of:

acquiring speed information of an assisting person, and acquiring second path time information corresponding to the item to be inspected based on an acquisition result;

obtaining a time difference value of the first path time information and the second path time information;

and deducting the time difference value from the standard waiting time information to obtain the real waiting time information.

5. The intelligent console support apparatus of claim 4, wherein: and further comprises the step of taking the true waiting time information of the rest items to be checked, which are arranged after the first item to be checked, as 0.

6. The flow management method in coordination with a verification flow according to claim 1 or 4, wherein: the S2 further comprises the step of analyzing whether the starting point position and the end point position relate to the change of the floor or not in the path distance information;

under the condition of involving floor change, step distance corresponding to the floor change is obtained, and step path time information corresponding to the floor change is obtained based on the step distance and speed information of a patient;

acquiring elevator path time information corresponding to floor change;

comparing the step path time with the elevator path time, selecting a smaller value, and adding the smaller value into the first path time information or the second path time information corresponding to the item to be checked.

7. The flow management method in coordination with a verification flow according to claim 6, wherein: the step of acquiring the elevator path time information corresponding to the floors further comprises the step of respectively acquiring the elevator path time information of the escalator and the vertical elevator;

the step of acquiring the elevator path time information of the vertical elevator comprises the step of acquiring the vertical elevator waiting time information of the vertical elevator.

8. The flow management method in coordination with a verification flow according to claim 7, wherein: the step of obtaining the path time information of the escalator comprises the steps of carrying out face recognition tracking on passengers stepping on the escalator until the passengers leave the escalator; the time that the passenger stays on the escalator is counted.

9. A process management system for coordinating with a verification process, comprising the steps of:

the starting point information acquisition unit is used for acquiring the current position information of the patient as starting point information and the speed information of the patient;

a first path time obtaining unit for obtaining position information of a destination corresponding to an item to be inspected of a patient as end point information, and obtaining path distance information based on the end point information and the start point information;

acquiring first path time information corresponding to each item to be checked based on the speed information and the path distance information;

the test time acquisition unit is used for acquiring standard waiting time information corresponding to a to-be-tested item of a patient and test result waiting time information;

the path mode calculating unit is used for summarizing the first path time information, the waiting time information and the waiting time information of the inspection result to obtain total time information corresponding to each item to be inspected under different inspection sequences;

and the optimal path sending unit is used for selecting the total time information with the minimum value and sending the checking sequence of the items to be checked corresponding to the total time information to the user.

10. A process management apparatus for coordinating with a verification process, comprising the steps of:

the starting point information acquisition module is used for acquiring the current position information of the patient as starting point information and the speed information of the patient;

the first path time obtaining module is used for obtaining position information of a destination corresponding to a to-be-inspected item of a patient as end point information and obtaining path distance information based on the end point information and the start point information;

acquiring first path time information corresponding to each item to be checked based on the speed information and the path distance information;

the test time acquisition module is used for acquiring standard waiting time information corresponding to a to-be-tested item of a patient and test result waiting time information;

the path mode calculation module is used for summarizing the first path time information, the waiting time information and the waiting time information of the inspection result to obtain total time information corresponding to each item to be inspected under different inspection sequences;

and the optimal path sending module is used for selecting the total time information with the minimum value and sending the checking sequence of the items to be checked corresponding to the total time information to the user.