Disclosure of Invention
The invention provides a dynamic management method of a medical information system, which comprises the following steps:
s1, the intelligent terminal acquires a plurality of pieces of appointment registration information of the user, wherein each piece of appointment registration information belongs to different visiting departments, whether the plurality of pieces of appointment registration information belong to the same hospital or not is judged, and if all pieces of appointment registration information belong to the same hospital, the step S2 is carried out; if all the appointment register information does not belong to the same hospital, the step S3 is carried out;
s2, acquiring the available appointment time periods of each appointment registration information, calculating the minimum appointment time length of the user based on each available appointment time period, and selecting the appointment sequence number of each appointment registration information in the minimum appointment time length; acquiring geographical position information of a place of departure preset by the user and geographical position information of a hospital to which the appointment registration information belongs, acquiring travel mode information of the user, planning an optimal travel path for the user based on the geographical position of the place of departure, the geographical position information of the hospital and the travel mode information, and calculating travel time required by the optimal travel path; proceeding to step S4;
s3, obtaining geographical location information of a place of departure preset by the user and geographical location information of a hospital to which each appointment registration information belongs, obtaining travel mode information of the user, planning an optimal travel path for the user based on the geographical location of the place of departure, each geographical location information, and the travel mode information, and calculating travel time required for each sub-path in the optimal travel path; acquiring a diagnosis time period which can be reserved by each piece of reservation registration information, calculating the minimum diagnosis and travel time of the user based on each reserved diagnosis time period and the travel time required by the corresponding sub-path, and selecting a reservation sequence number of each piece of reservation registration information in the minimum diagnosis and travel time;
s4, the client of the doctor in the department of medical examination obtains the appointment sequence numbers and the real-time position information of a plurality of users in the working time period, the remaining travel time length is calculated based on the real-time position information and the travel mode information, and the doctor adjusts the appointment sequence numbers according to the remaining travel time length and sends the adjusted appointment sequence numbers to the users.
As a preferred embodiment, the step S4 further includes:
the doctor adjusts the reservation serial numbers of a plurality of different users according to the remaining travel time length, and the waiting time length required by each adjusted reservation serial number is approximately equal to the remaining travel time length required by the corresponding user; and sending each adjusted reservation sequence number and the required waiting time length to the corresponding user.
As a preferred embodiment, the step S2 further includes:
and acquiring the appointment time of the appointment sequence number with the earliest time in the minimum visit duration, and calculating the latest departure time of the user based on the appointment time and the optimal travel path.
And if the geographic position of the departure place at the trip time in the trip peak time period or the latest departure time in the map database is in a congestion state, prompting the user to change a trip mode or adjusting the appointment registration information.
As a preferred embodiment, the planning an optimal travel path for the user based on the geographic location of the departure location, each piece of the geographic location information, and the travel mode information specifically includes:
planning a first optimal travel path for the user for the first sub-starting point and the first sub-ending point according to a first trip mode in the trip mode information by taking the geographic position of the starting place as a first sub-starting point and the geographic position information closest to the first sub-starting point as a first sub-ending point;
planning a second optimal travel path for the user for the second sub-starting point and the second sub-ending point according to a second travel mode in the travel mode information by taking the first sub-ending point as a second sub-starting point and the nearest geographical position information apart from the first sub-ending point from the second sub-starting point as a second sub-ending point;
according to the method, until an Nth optimal travel path is planned, the first optimal travel path, the second optimal travel path and the Nth optimal travel path form the optimal travel path.
The invention provides a medical information system and a dynamic management method thereof, wherein the method can be used for a user to select a plurality of different hospitals and a plurality of visiting departments thereof, the user can freely select to avoid visiting peak time, and simultaneously the user visits the hospitals to check different projects of the visiting departments simultaneously, thereby meeting the diversified requirements of the user; finally, a plurality of appointment sequence numbers of the same hospital are provided for the user to meet the requirement of checking and registering after the visit, so that the time is saved, and the visit efficiency is improved; in addition, the doctor can obtain the position information of the patient in real time and then calculate the residual travel time information, so that the diagnosis appointment sequence number of the patient is dynamically adjusted, the diagnosis efficiency of the doctor is improved, and meanwhile, the schedule of the patient is considered for diagnosis.
Further, the invention provides a medical information system, comprising the following modules:
the system comprises a destination judgment module, a first planning module and a second planning module, wherein the destination judgment module is used for acquiring a plurality of pieces of appointment registration information of a user by an intelligent terminal, each piece of appointment registration information belongs to different visiting departments, judging whether the plurality of pieces of appointment registration information belong to the same hospital or not, and executing the first planning module if all pieces of appointment registration information belong to the same hospital; if all the appointment register information does not belong to the same hospital, executing a second planning module;
the first planning module is used for acquiring the appointment time periods which can be appointed by each appointment registration information, calculating the minimum appointment time length of the user based on each appointment time period which can be appointed, and selecting the appointment sequence number of each appointment registration information in the minimum appointment time length; acquiring geographical position information of a place of departure preset by the user and geographical position information of a hospital to which the appointment registration information belongs, acquiring travel mode information of the user, planning an optimal travel path for the user based on the geographical position of the place of departure, the geographical position information of the hospital and the travel mode information, and calculating travel time required by the optimal travel path; an execution information pushing module;
a second planning module, configured to obtain geographical location information of a departure place preset by the user and geographical location information of a hospital to which each appointment registration information belongs, obtain travel mode information of the user, plan an optimal travel path for the user based on the geographical location of the departure place, each geographical location information, and the travel mode information, and calculate travel time required by each sub-path in the optimal travel path; acquiring a diagnosis time period which can be reserved by each piece of reservation registration information, calculating the minimum diagnosis and travel time of the user based on each reserved diagnosis time period and the travel time required by the corresponding sub-path, and selecting a reservation sequence number of each piece of reservation registration information in the minimum diagnosis and travel time;
and the appointment sequence number adjusting module is used for acquiring a plurality of appointment sequence numbers and real-time position information of the users in the working time period by the client of the doctor in the consulting department, calculating the residual travel time length based on the real-time position information and the travel mode information, adjusting the appointment sequence number by the doctor according to the residual travel time length, and sending the adjusted appointment sequence number to the users.
As a preferred implementation, the reservation number adjusting module further includes:
the doctor adjusts the reservation serial numbers of a plurality of different users according to the remaining travel time length, and the waiting time length required by each adjusted reservation serial number is approximately equal to the remaining travel time length required by the corresponding user; and sending each adjusted reservation sequence number and the required waiting time length to the corresponding user.
As a preferred embodiment, the first planning module further comprises:
and acquiring the appointment time of the appointment sequence number with the earliest time in the minimum visit duration, and calculating the latest departure time of the user based on the appointment time and the optimal travel path.
And if the geographic position of the departure place at the trip time in the trip peak time period or the latest departure time in the map database is in a congestion state, prompting the user to change a trip mode or adjusting the appointment registration information.
As a preferred embodiment, the planning an optimal travel path for the user based on the geographic location of the departure location, each piece of the geographic location information, and the travel mode information specifically includes:
planning a first optimal travel path for the user for the first sub-starting point and the first sub-ending point according to a first trip mode in the trip mode information by taking the geographic position of the starting place as a first sub-starting point and the geographic position information closest to the first sub-starting point as a first sub-ending point;
planning a second optimal travel path for the user for the second sub-starting point and the second sub-ending point according to a second travel mode in the travel mode information by taking the first sub-ending point as a second sub-starting point and the nearest geographical position information apart from the first sub-ending point from the second sub-starting point as a second sub-ending point;
according to the method, until an Nth optimal travel path is planned, the first optimal travel path, the second optimal travel path and the Nth optimal travel path form the optimal travel path.
The invention provides a medical information system and a dynamic management method thereof, wherein the method can be used for a user to select a plurality of different hospitals and a plurality of visiting departments thereof, the user can freely select to avoid visiting peak time, and simultaneously the user visits the hospitals to check different projects of the visiting departments simultaneously, thereby meeting the diversified requirements of the user; finally, a plurality of appointment sequence numbers of the same hospital are provided for the user to meet the requirement of checking and registering after the visit, so that the time is saved, and the visit efficiency is improved; in addition, the doctor can obtain the position information of the patient in real time and then calculate the residual travel time information, so that the diagnosis appointment sequence number of the patient is dynamically adjusted, the diagnosis efficiency of the doctor is improved, and meanwhile, the diagnosis efficiency of the schedule arrangement of the patient is considered.
Detailed Description
The embodiments of the present invention are further described below with reference to the drawings.
The first embodiment is as follows:
the invention provides a dynamic management method of a medical information system, which comprises the following steps:
s1, the intelligent terminal acquires a plurality of pieces of appointment registration information of the user, wherein each piece of appointment registration information belongs to different visiting departments, whether the plurality of pieces of appointment registration information belong to the same hospital or not is judged, and if all pieces of appointment registration information belong to the same hospital, the step S2 is carried out; if all the appointment register information does not belong to the same hospital, the step S3 is carried out; it should be noted that the plurality of appointment registration information may be a plurality of consulting departments in the same hospital or different hospitals, so as to meet the requirement of the user for consulting a plurality of departments at the same time, thereby improving the efficiency of one-time consulting. Further, the appointment registration information includes information of the hospital and the consulting department thereof, the doctor in the consulting department, the consulting time and the like which are appointed by the user.
S2, acquiring the available appointment time periods of each appointment registration information, calculating the minimum appointment time length of the user based on each available appointment time period, and selecting the appointment sequence number of each appointment registration information in the minimum appointment time length; acquiring geographical position information of a place of departure preset by the user and geographical position information of a hospital to which the appointment registration information belongs, acquiring travel mode information of the user, planning an optimal travel path for the user based on the geographical position of the place of departure, the geographical position information of the hospital and the travel mode information, and calculating travel time required by the optimal travel path; proceeding to step S4; step S2 is executed when the user has reserved a plurality of visiting departments of one hospital. Illustratively, a client of the medical information system shows that the available appointment time period of department a which can be appointed by the user is 9 to 9: 40 minutes, and the available appointment time period of department B is 10 to 10: 40 minutes, then the minimum time period of the visit of the user is calculated to be 9 to 10: 10 minutes based on the two available appointment time periods, and the appointment number of each piece of appointment registration information, that is, the appointment number of department a with 9 to 40 minutes and the appointment number of department B with 10 to 10 minutes, is selected in the minimum time period of the visit.
S3, obtaining geographical location information of a place of departure preset by the user and geographical location information of a hospital to which each appointment registration information belongs, obtaining travel mode information of the user, planning an optimal travel path for the user based on the geographical location of the place of departure, each geographical location information, and the travel mode information, and calculating travel time required for each sub-path in the optimal travel path; acquiring a diagnosis time period which can be reserved by each piece of reservation registration information, calculating the minimum diagnosis and travel time of the user based on each reserved diagnosis time period and the travel time required by the corresponding sub-path, and selecting a reservation sequence number of each piece of reservation registration information in the minimum diagnosis and travel time; step S3 is executed when the user has reserved a plurality of visiting departments of a plurality of different locations of the hospital. Illustratively, if a user makes an appointment with a department m of a hospital X and a department n of a hospital Y at a client of the medical information system, an optimal travel path is planned for the user based on a geographic position D0 of a departure place of the user, the geographic position information DX and DY of each hospital, and travel mode information selected by the user; for example, if the location D0 is closer to the location DX, an optimal travel path from D0 to D1 is planned for the user, an optimal travel path from D1 to D2 is planned for the user, and travel times T1=40 minutes and T2=20 minutes required for each sub-path in the two optimal travel paths are calculated. Further, the client of the medical information system shows to the user that the available appointment time period of department m that can be appointed by the user is 9 o 'clock to 9 o' clock 40 min, and the available appointment time period of department n is 9 o 'clock 50 min to 10 o' clock 40 min, then the minimum visit and travel time period of the user is calculated based on the two available appointment time periods and the travel time T1 and T2 required for the sub-route, that is, since T2=20 min, the travel time is between hospital X and hospital Y, the time difference between the appointment numbers of the two appointment registration information should not be less than 20 min, at this time, the user can select the appointment number within the range that the time difference between the two appointment numbers is greater than or equal to 20 min, for example, the available appointment time period of department m is 9 o 'clock 30min, and the available time period of department n is 10 o' clock, therefore, the reservation and registration requirements of two different hospitals can be met simultaneously.
S4, the client of the doctor in the department of medical examination obtains the appointment sequence numbers and the real-time position information of a plurality of users in the working time period, the remaining travel time length is calculated based on the real-time position information and the travel mode information, and the doctor adjusts the appointment sequence numbers according to the remaining travel time length and sends the adjusted appointment sequence numbers to the users. Illustratively, the users P and Q have reserved the reservation serial numbers 5 and 8 of the doctor W in the department m of the hospital X in day 5, month 18 at the client of the medical information system, and after the doctor W opens the client of the medical information system in day 5, month 18, the reservation serial numbers of all the patients who reserve the doctor W in the day, the current position information of all the patients who do not see a doctor, the travel mode information, the remaining travel time length and the predicted waiting time length of the current reservation serial number are seen; calculating the time difference between the residual travel time length and the predicted waiting time length, wherein the time difference is a vector value, and carrying out the same labeling on the appointment sequence numbers of the patients with the sum of the time differences of about 0 so as to prompt the doctor W to adjust the corresponding appointment sequence numbers; through the adjustment, the user Q who arrives early is expected to see a doctor first, and the user P who arrives late is expected to see a doctor later, so that the satisfaction of the user in seeing a doctor and the efficiency of seeing a doctor are improved, and the benefits of both doctors and patients are considered.
As an alternative embodiment of step S4, a diagnosis prompt message and travel planning message are generated according to the appointment number and provided to the intelligent terminal of the user. It should be noted that the medical treatment prompting information may include information of hospital, department, doctor, time, etc. of medical treatment; the travel planning information may include travel information such as a route map, a travel mode, travel time, estimated time consumption, and the like of each optimal sub-path on the map, which is not limited herein.
As a preferred embodiment, the step S4 further includes:
the doctor adjusts the reservation serial numbers of a plurality of different users according to the remaining travel time length, and the waiting time length required by each adjusted reservation serial number is approximately equal to the remaining travel time length required by the corresponding user; and sending each adjusted reservation sequence number and the required waiting time length to the corresponding user. Continuing with the above embodiment, if the time difference between the remaining travel time of the user P and the expected waiting time is +30min, i.e., 30min later, and the time difference between the remaining travel time of the user Q and the expected waiting time is-28 min, i.e., 28min earlier, since the sum of +30min and-28 min is about 0; the subscription numbers 5 and 8 of the users P and Q are adjusted to 8 and 5. Then, the reservation serial number 8 and the required waiting time after the user P is adjusted are increased by 30min and sent to the mobile terminal of the corresponding user P, and the reservation serial number 5 and the required waiting time after the user Q is adjusted are decreased by 30min and sent to the mobile terminal of the corresponding user P; so as to adjust the stroke of the medical instrument and avoid urgent delay of treatment. In addition, the doctor can also adjust the appointment number for multiple times according to the actual needs and the method, so that the diagnosis efficiency is further improved. Therefore, the appointment sequence number for seeing and examining of the patient is dynamically adjusted, the seeing and examining efficiency of a doctor is improved, and meanwhile, the schedule of the patient is taken into consideration.
As a preferred embodiment, the step S2 further includes:
and acquiring the appointment time of the appointment sequence number with the earliest time in the minimum visit duration, and calculating the latest departure time of the user based on the appointment time and the optimal travel path. Continuing with the above embodiment, the latest time when the user arrives at hospital X is the scheduled visit time period of department m, i.e. 9: 30 minutes, and the travel time T1=40 minutes required for the first sub-route, the latest departure time of the user is 9: 30 minutes minus 40 minutes, i.e. 8: 50 minutes.
As a preferred embodiment, the step S2 further includes:
and if the geographic position of the departure place at the trip time in the trip peak time period or the latest departure time in the map database is in a congestion state, prompting the user to change a trip mode or adjusting the appointment registration information. It should be noted that the data in the map database is historical road trip information in the same time period of the route under the conventional condition, and the user is prompted with the peak time and the congested route, so that the user can grasp the road condition information earlier and make a prediction in advance, and the delay of the diagnosis time is avoided.
As a preferred embodiment, the planning an optimal travel path for the user based on the geographic location of the departure location, each piece of the geographic location information, and the travel mode information specifically includes:
planning a first optimal travel path for the user for the first sub-starting point and the first sub-ending point according to a first trip mode in the trip mode information by taking the geographic position of the starting place as a first sub-starting point and the geographic position information closest to the first sub-starting point as a first sub-ending point;
planning a second optimal travel path for the user for the second sub-starting point and the second sub-ending point according to a second travel mode in the travel mode information by taking the first sub-ending point as a second sub-starting point and the nearest geographical position information apart from the first sub-ending point from the second sub-starting point as a second sub-ending point;
according to the method, until an Nth optimal travel path is planned, the first optimal travel path, the second optimal travel path and the Nth optimal travel path form the optimal travel path. It should be noted that the above method is only an example, and the method without exceeding the spirit of the above method is within the scope of the present invention.
The invention provides a medical information system and a dynamic management method thereof, wherein the method can be used for a user to select a plurality of different hospitals and a plurality of visiting departments thereof, the user can freely select to avoid visiting peak time, and simultaneously the user visits the hospitals to check different projects of the visiting departments simultaneously, thereby meeting the diversified requirements of the user; finally, a plurality of appointment sequence numbers of the same hospital are provided for the user to meet the requirement of checking and registering after the visit, so that the time is saved, and the visit efficiency is improved; in addition, the doctor can obtain the position information of the patient in real time and then calculate the residual travel time information, so that the diagnosis appointment sequence number of the patient is dynamically adjusted, the diagnosis efficiency of the doctor is improved, and meanwhile, the schedule of the patient is considered for diagnosis.
Example two:
as shown in fig. 1, the present invention provides a medical information system, which includes the following modules:
the system comprises a destination judgment module, a first planning module and a second planning module, wherein the destination judgment module is used for acquiring a plurality of pieces of appointment registration information of a user by an intelligent terminal, each piece of appointment registration information belongs to different visiting departments, judging whether the plurality of pieces of appointment registration information belong to the same hospital or not, and executing the first planning module if all pieces of appointment registration information belong to the same hospital; if all the appointment register information does not belong to the same hospital, executing a second planning module; it should be noted that the plurality of appointment registration information may be a plurality of consulting departments in the same hospital or different hospitals, so as to meet the requirement of the user for consulting a plurality of departments at the same time, thereby improving the efficiency of one-time consulting. Further, the appointment registration information includes information of the hospital and the consulting department thereof, the doctor in the consulting department, the consulting time and the like which are appointed by the user.
The first planning module is used for acquiring the appointment time periods which can be appointed by each appointment registration information, calculating the minimum appointment time length of the user based on each appointment time period which can be appointed, and selecting the appointment sequence number of each appointment registration information in the minimum appointment time length; acquiring geographical position information of a place of departure preset by the user and geographical position information of a hospital to which the appointment registration information belongs, acquiring travel mode information of the user, planning an optimal travel path for the user based on the geographical position of the place of departure, the geographical position information of the hospital and the travel mode information, and calculating travel time required by the optimal travel path; an execution information pushing module; step S2 is executed when the user has reserved a plurality of visiting departments of one hospital. Illustratively, a client of the medical information system shows that the available appointment time period of department a which can be appointed by the user is 9 to 9: 40 minutes, and the available appointment time period of department B is 10 to 10: 40 minutes, then the minimum time period of the visit of the user is calculated to be 9 to 10: 10 minutes based on the two available appointment time periods, and the appointment number of each piece of appointment registration information, that is, the appointment number of department a with 9 to 40 minutes and the appointment number of department B with 10 to 10 minutes, is selected in the minimum time period of the visit.
A second planning module, configured to obtain geographical location information of a departure place preset by the user and geographical location information of a hospital to which each appointment registration information belongs, obtain travel mode information of the user, plan an optimal travel path for the user based on the geographical location of the departure place, each geographical location information, and the travel mode information, and calculate travel time required by each sub-path in the optimal travel path; acquiring a diagnosis time period which can be reserved by each piece of reservation registration information, calculating the minimum diagnosis and travel time of the user based on each reserved diagnosis time period and the travel time required by the corresponding sub-path, and selecting a reservation sequence number of each piece of reservation registration information in the minimum diagnosis and travel time; step S3 is executed when the user has reserved a plurality of visiting departments of a plurality of different locations of the hospital. Illustratively, if a user makes an appointment with a department m of a hospital X and a department n of a hospital Y at a client of the medical information system, an optimal travel path is planned for the user based on a geographic position D0 of a departure place of the user, the geographic position information DX and DY of each hospital, and travel mode information selected by the user; for example, if the location D0 is closer to the location DX, an optimal travel path from D0 to D1 is planned for the user, an optimal travel path from D1 to D2 is planned for the user, and travel times T1=40 minutes and T2=20 minutes required for each sub-path in the two optimal travel paths are calculated. Further, the client of the medical information system shows to the user that the available appointment time period of department m that can be appointed by the user is 9 o 'clock to 9 o' clock 40 min, and the available appointment time period of department n is 9 o 'clock 50 min to 10 o' clock 40 min, then the minimum visit and travel time period of the user is calculated based on the two available appointment time periods and the travel time T1 and T2 required for the sub-route, that is, since T2=20 min, the travel time is between hospital X and hospital Y, the time difference between the appointment numbers of the two appointment registration information should not be less than 20 min, at this time, the user can select the appointment number within the range that the time difference between the two appointment numbers is greater than or equal to 20 min, for example, the available appointment time period of department m is 9 o 'clock 30min, and the available time period of department n is 10 o' clock, therefore, the reservation and registration requirements of two different hospitals can be met simultaneously.
And the appointment sequence number adjusting module is used for acquiring a plurality of appointment sequence numbers and real-time position information of the users in the working time period by the client of the doctor in the consulting department, calculating the residual travel time length based on the real-time position information and the travel mode information, adjusting the appointment sequence number by the doctor according to the residual travel time length, and sending the adjusted appointment sequence number to the users. Illustratively, the users P and Q have reserved the reservation serial numbers 5 and 8 of the doctor W in the department m of the hospital X in day 5, month 18 at the client of the medical information system, and after the doctor W opens the client of the medical information system in day 5, month 18, the reservation serial numbers of all the patients who reserve the doctor W in the day, the current position information of all the patients who do not see a doctor, the travel mode information, the remaining travel time length and the predicted waiting time length of the current reservation serial number are seen; calculating the time difference between the residual travel time length and the predicted waiting time length, wherein the time difference is a vector value, and carrying out the same labeling on the appointment sequence numbers of the patients with the sum of the time differences of about 0 so as to prompt the doctor W to adjust the corresponding appointment sequence numbers; through the adjustment, the user Q who arrives early is expected to see a doctor first, and the user P who arrives late is expected to see a doctor later, so that the satisfaction of the user in seeing a doctor and the efficiency of seeing a doctor are improved, and the benefits of both doctors and patients are considered.
As a preferred implementation, the reservation number adjusting module further includes:
the doctor adjusts the reservation serial numbers of a plurality of different users according to the remaining travel time length, and the waiting time length required by each adjusted reservation serial number is approximately equal to the remaining travel time length required by the corresponding user; and sending each adjusted reservation sequence number and the required waiting time length to the corresponding user. Continuing with the above embodiment, if the time difference between the remaining travel time of the user P and the expected waiting time is +30min, i.e., 30min later, and the time difference between the remaining travel time of the user Q and the expected waiting time is-28 min, i.e., 28min earlier, since the sum of +30min and-28 min is about 0; the subscription numbers 5 and 8 of the users P and Q are adjusted to 8 and 5. Then, the reservation serial number 8 and the required waiting time after the user P is adjusted are increased by 30min and sent to the mobile terminal of the corresponding user P, and the reservation serial number 5 and the required waiting time after the user Q is adjusted are decreased by 30min and sent to the mobile terminal of the corresponding user P; so as to adjust the stroke of the medical instrument and avoid urgent delay of treatment. In addition, the doctor can also adjust the appointment number for multiple times according to the actual needs and the method, so that the diagnosis efficiency is further improved. Therefore, the appointment sequence number for seeing and examining of the patient is dynamically adjusted, the seeing and examining efficiency of a doctor is improved, and meanwhile, the schedule of the patient is taken into consideration.
As a preferred embodiment, the first planning module further comprises:
and acquiring the appointment time of the appointment sequence number with the earliest time in the minimum visit duration, and calculating the latest departure time of the user based on the appointment time and the optimal travel path. Continuing with the above embodiment, the latest time when the user arrives at hospital X is the scheduled visit time period of department m, i.e. 9: 30 minutes, and the travel time T1=40 minutes required for the first sub-route, the latest departure time of the user is 9: 30 minutes minus 40 minutes, i.e. 8: 50 minutes.
As a preferred embodiment, the first planning module further comprises:
and if the geographic position of the departure place at the trip time in the trip peak time period or the latest departure time in the map database is in a congestion state, prompting the user to change a trip mode or adjusting the appointment registration information. It should be noted that the data in the map database is historical road trip information in the same time period of the route under the conventional condition, and the user is prompted with the peak time and the congested route, so that the user can grasp the road condition information earlier and make a prediction in advance, and the delay of the diagnosis time is avoided.
As a preferred embodiment, the planning an optimal travel path for the user based on the geographic location of the departure location, each piece of the geographic location information, and the travel mode information specifically includes:
planning a first optimal travel path for the user for the first sub-starting point and the first sub-ending point according to a first trip mode in the trip mode information by taking the geographic position of the starting place as a first sub-starting point and the geographic position information closest to the first sub-starting point as a first sub-ending point;
planning a second optimal travel path for the user for the second sub-starting point and the second sub-ending point according to a second travel mode in the travel mode information by taking the first sub-ending point as a second sub-starting point and the nearest geographical position information apart from the first sub-ending point from the second sub-starting point as a second sub-ending point;
according to the method, until an Nth optimal travel path is planned, the first optimal travel path, the second optimal travel path and the Nth optimal travel path form the optimal travel path. It should be noted that the above method is only an example, and the method without exceeding the spirit of the above method is within the scope of the present invention.
The invention provides a medical information system and a dynamic management method thereof, wherein the method can be used for a user to select a plurality of different hospitals and a plurality of visiting departments thereof, the user can freely select to avoid visiting peak time, and simultaneously the user visits the hospitals to check different projects of the visiting departments simultaneously, thereby meeting the diversified requirements of the user; finally, a plurality of appointment sequence numbers of the same hospital are provided for the user to meet the requirement of checking and registering after the visit, so that the time is saved, and the visit efficiency is improved; in addition, the doctor can obtain the position information of the patient in real time and then calculate the residual travel time information, so that the diagnosis appointment sequence number of the patient is dynamically adjusted, the diagnosis efficiency of the doctor is improved, and meanwhile, the schedule of the patient is considered for diagnosis.
It will be understood by those within the art that each block of the block diagrams and/or flowchart illustrations, and combinations of blocks in the block diagrams and/or flowchart illustrations, 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, 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 methods specified in the block or blocks of the block diagrams and/or flowchart block or blocks.
Those of skill in the art will appreciate that various operations, methods, steps in the processes, acts, or solutions discussed in the present application may be alternated, modified, combined, or deleted. Further, various operations, methods, steps in the flows, which have been discussed in the present application, may be interchanged, modified, rearranged, decomposed, combined, or eliminated. Further, steps, measures, schemes in the various operations, methods, procedures disclosed in the prior art and the present invention can also be alternated, changed, rearranged, decomposed, combined, or deleted.
The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes performed by the present specification and drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.