CN116320178A - Batch terminal binding configuration method under multi-level - Google Patents

Abstract

The invention discloses a batch terminal binding configuration method under a multi-level, which comprises the following steps: dividing a target space for installing the configuration terminals to be bound into a plurality of installation areas according to a hierarchy, arranging a plurality of installation units in the installation areas, and installing all the configuration target terminals into all the installation units of all the installation areas in the target space after the hierarchy division is completed; operating each terminal and obtaining a corresponding operation time stamp, and respectively performing new operation on the next installation unit or installation area after a first preset time interval and a second preset time interval; and allocating block codes, wherein the block codes are bounded by a current first preset time interval, and whether the terminals are divided into the same installation unit or installation area is determined based on the first preset time interval and a second preset time interval. The invention can greatly save time and energy, improve the binding configuration efficiency of the batch terminals, and can more efficiently finish the binding configuration of the batch terminals.

Description

Batch terminal binding configuration method under multi-level

Technical Field

The invention relates to the technical field of terminal binding processing, in particular to a batch terminal binding configuration method under a multi-level.

Background

The information construction of hospitals is becoming important, and most of the outpatient departments and inpatient departments of all hospitals currently have information systems, for example, a hospital information system HIS system of the hospitals covers the inpatient departments. For hospitalization units, it is often necessary to specify which hospital bed caller is calling, i.e. to determine exactly which hospital bed caller is corresponding to each ward, each floor below the ward, each ward below the floor, a specific hospital bed within the ward. In the case of multi-level scenarios including ward-floor-ward/ward calling machines, which specific terminal to call, it is necessary to configure and bind the terminals after each terminal is physically installed.

In the prior art, in the face of binding configuration of such numerous batch terminals, each terminal needs to be operated once, for example, binding configuration operation such as IP setting needs to be performed manually before each sickbed calling machine in each ward, and the same configuration operation needs to be repeated for each terminal. The operation amount of the binding configuration is very huge, and the binding configuration can be completed in a short time by a very large number of people, or can be completed by one or a few people, so that the binding configuration can be completed by running back and forth in each area, and the operation is complex and the task amount is huge. Thus, there is a need for an efficient binding configuration method that is less operational and simpler.

Disclosure of Invention

Aiming at the defects of the prior art, the invention aims to provide a batch terminal binding configuration method under a multi-level, which can solve the problems described in the background art.

The technical scheme for realizing the purpose of the invention is as follows: a batch terminal binding configuration method under a multi-level comprises the following steps:

step 1: dividing a target space for installing a to-be-bound configuration terminal into a plurality of installation areas according to a hierarchy, wherein a plurality of installation units are arranged in the installation areas, the installation units represent minimum areas which can be divided for installing the terminal, and all the target terminals which are bound and configured are installed in all the installation units of all the installation areas in the target space after the hierarchy division is completed;

step 2: obtaining operation time stamps responding to signals returned by terminal operation, and determining an installation unit to which each terminal belongs and an installation area to which each installation unit belongs based on comparison results of the operation time stamps and preset time intervals;

step 3: assigning a block code to each terminal based on the belonging installation area and the belonging installation unit to obtain a terminal block code, wherein the terminal block code characterizes the current terminal belonging installation unit and the installation area of the unit,

step 4: and establishing a mapping relation between the terminal block codes of the terminal, thereby completing binding configuration of the terminal.

Further, the specific implementation process of the step 2 includes the following steps:

selecting any installation area from the target space as a current installation area, selecting any installation unit from the current installation area as a current installation unit, respectively operating each terminal in the current installation unit at least once, and receiving an operation time stamp of a signal generated by operation;

after a first preset time interval, the first preset time interval represents the travel time from the current installation unit to the next installation unit, each terminal in the next installation unit in the current installation area is continuously operated at least once and operation time stamps are also obtained, an installation time period corresponding to the next installation unit is obtained, after the terminal operation in one installation unit is completed, the terminal in the next installation unit is continuously operated after the first preset time interval until all the installation units in the current installation area obtain a corresponding installation time period,

after the operation of all the terminals in the current installation area is completed, the second preset time interval represents the travel time from the current installation area to the next installation area, the same operation is continuously carried out on the next installation area, the installation time periods corresponding to all the installation units in the next installation area are obtained, and the installation time periods of all the installation units in all the installation areas in the target space are obtained.

Further, the specific implementation process of the step 3 includes the following steps:

respectively allocating a first block code to each installation area, wherein the first block code is used as an installation area block code, thereby obtaining an installation area block code, allocating a second block code to each installation unit, combining the installation area block code and the second block code to form an installation unit block code, thereby obtaining an installation unit block code, respectively allocating a third block code to each terminal, combining the installation unit block code and the third block code as the block codes of the terminal, thereby obtaining a terminal block code,

wherein, with the current first preset time interval as a boundary, all terminals before the first preset time interval are classified as one installation unit, all terminals after the first preset time interval are classified as another one installation unit until a new first preset time interval is encountered, each terminal is classified as a unique corresponding group of installation units, each time when the first preset time interval is newly added, the current first preset time interval is continuously used as a boundary, all terminals before the first preset time interval are classified as one installation unit, all terminals after the first preset time interval are classified as another one installation unit until all the first preset time intervals are classified as a boundary,

similarly, taking the second preset time interval as a boundary, regarding all the installation units before the second preset time interval as the same installation area, and regarding all the installation units after the second preset time interval as another installation area.

Further, the total number of terminals is the same or different between the respective mounting areas, and the total number of terminals in the respective mounting units in the same mounting area is the same or different.

Further, the first preset time interval is larger than a time difference of two operation time stamps adjacent in any operation order in the installation unit.

Further, the second preset time interval is greater than a time difference between a last operation time stamp of a last installation unit and a first operation time stamp of a next installation unit in any two adjacent installation units in the safety area.

Further, the first preset time interval is the same or different each time, and the second preset time interval is the same or different each time.

Further, the second preset time interval is the same as or different from the first preset time interval.

Further, the block codes are composed of single or multiple pure numbers or pure letters or combination of numbers and letters or other character combinations, and random numbers are used for distributing the block codes.

Further, a first block code is allocated to each installation area in turn in a sequential increasing or decreasing order, a second block code is allocated to each installation unit, and a third block code is allocated to each terminal.

The beneficial effects of the invention are as follows: compared with the prior batch terminal binding configuration operation, the invention continuously operates at the terminal to obtain the operation time stamp of the returned response signal, thereby determining which terminals belong to the same installation unit and which installation units belong to which installation area through the comparison result of the time difference between the two adjacent operation time stamps and the preset time interval, and further distributing the block codes to the terminals in batches at the rear end to obtain the terminal block codes of the terminals, and running back to the rear end (such as a server) to distribute the block codes of the current terminal after each terminal operation is not needed, and continuing the same operation to the next terminal. Time and energy can be saved greatly, the binding configuration efficiency of the batch terminals can be improved, and the binding configuration of the batch terminals can be completed more efficiently.

Drawings

FIG. 1 is a schematic flow chart of the present invention;

fig. 2 is a schematic diagram of a hierarchical division of a target space using a hospitalization unit as an example.

Detailed Description

The invention will be further described with reference to the accompanying drawings and detailed description:

as shown in fig. 1-2, a batch terminal binding configuration method under a multi-hierarchy includes the following steps:

step 1: dividing a target space for installing a configuration terminal to be bound into a plurality of installation areas according to a hierarchy, wherein a plurality of installation units are arranged in the installation areas, and the installation units represent minimum areas which can be divided for installing the terminal. And installing all the target terminals which are configured in a binding mode in each installation unit of each installation area in the target space after the division of the hierarchy is completed.

In this step, the target space is generally divided into two or more levels, and if the target space is not divided, the entire target space may be regarded as being divided into one installation area, that is, the entire target space may be regarded as one installation unit. The installation area of same level is provided with a plurality of installation units, and a plurality of target terminals are installed to each installation unit in the level to target terminals, and the total number of target terminals between each installation area can be the same, also can be different, and the total number of target terminals in each installation unit in same installation area can be the same, also can be different. The hierarchy characterizes the coverage of the area where the target terminal is located, and the installation area of the upper hierarchy covers all the target terminals in the installation areas of all the lower hierarchy. And is divided from low to high or from high to low in a hierarchy. For example, three levels are divided from low to high, namely a first installation area, a second installation area and a third installation area, wherein the third installation area covers the second installation area, the second installation area covers the first installation area, and naturally, the third installation area covers the first installation area through the second installation area; or conversely, three mounting areas are divided from high to low into a first mounting area, a second mounting area and a third mounting area respectively.

Step 2: and selecting any installation area from the target space as a current installation area, selecting any installation unit from the current installation area as a current installation unit, respectively operating each terminal in the current installation unit at least once, receiving operation time stamps of signals generated by operation, or receiving operation time stamps of response signals returned by response operation signals, and obtaining the installation time period of the current installation unit based on a time period formed from the received first operation time stamp to the last operation time stamp as the installation time period of the current installation unit.

The first preset time interval is greater than the time difference between two operation time stamps adjacent in any order of operation within the installation unit. The second preset time interval is greater than the time difference between the last operation time stamp of the last installation unit and the first operation time stamp of the next installation unit in any two adjacent installation units in the safety area. So as to distinguish which time stamp corresponds to the terminal belonging to the same installation unit and which installation unit belongs to the same installation area based on each operation time stamp.

Wherein the operation is clicking. For example, the terminal is provided with a touch screen, and an operation time stamp is formed by clicking on the touch screen one time or a plurality of times in succession.

After a first preset time interval, continuing to operate each terminal in the next installation unit of the current installation area at least once, and likewise obtaining an operation time stamp of the returned response signal to obtain an installation time period corresponding to the next installation unit. After the terminal operation in one installation unit is completed, after a first preset time interval, the terminal in the next installation unit is continuously operated until all installation units in the current installation area obtain a corresponding installation time period. That is, the time difference from the completion of the operation of the last terminal in the current installation unit to the operation of the first terminal in the next installation unit is not less than or equal to the preset time interval, and whether two adjacent terminals operated in time sequence belong to the same installation unit or not can be distinguished through the preset time interval. If the time difference formed by the operation time stamps generated by two adjacent operations is more than or equal to the preset time interval, the two adjacent terminals are not in the same installation unit, and the terminal in the current operation is required to be regarded as being in the current installation unit, and the terminal in the last current operation is regarded as being in the last installation unit.

Wherein the first preset time interval between any two adjacent installation units is the same or different. For example, after the terminal operation in the installation unit a is completed, the operation is continued on the terminal in the next installation unit b after a first preset time interval (for example, 1 minute) elapses. After the terminal operation in the installation unit b is completed, the terminal in the next installation unit c continues to be operated after a first preset time interval (for example, 1 minute and 30 seconds) of the second time passes. By analogy, the first preset time interval for each time may be the same or different.

However, it should be noted that the first preset time interval between two adjacent installation units needs to be at least greater than the time difference between any two adjacent operations in the same installation unit, so as to avoid that two adjacent operations on two terminals in the same installation unit are regarded as operations in two different installation units.

After the operation of all the terminals in the current installation area is completed, after a second preset time interval, continuing to operate the next installation area to obtain the installation time periods corresponding to all the installation units in the next installation area until the installation time periods of all the installation units in all the installation areas in the target space are obtained, namely, all the installation units in the target space have a unique corresponding installation time period.

The second preset time intervals corresponding to any two adjacent installation areas in the time operation sequence can be the same or different, that is, the second preset time intervals of each operation can be the same or different. For example, the second preset time interval of the current installation area 1 and the next installation area 2 is set to 2 minutes; the second preset time interval of the current installation area 2 and the next installation area 3 is set to 2 minutes or 3 minutes.

The second preset time interval may be the same as or different from the first preset time interval, and preferably, the second preset time interval is greater than the first preset time interval. The reason is that the time actually spent (i.e., travel time) from one mounting area to the next is typically greater than the time from one mounting unit to another.

Step 3: and respectively distributing a first block code for each installation area, wherein the first block code is used as the installation area block code, so that the installation area block code is obtained. And allocating a second block code to each installation unit, wherein the combination of the installation area block code and the second block code forms an installation unit block code, thereby obtaining the installation unit block code. And respectively distributing a third block code to each terminal, and installing a combination of the unit block code and the third block code as the block code of the terminal, thereby obtaining the terminal block code.

It can be seen that there is a correlation among the installation area block code, the installation unit block code and the terminal block code, the installation unit block code includes the installation area block code so as to enable the installation unit to which the installation unit block code corresponds to belong, and similarly, the terminal block code includes the installation unit block code so as to enable the installation unit to which the terminal block code corresponds to belong.

The block codes (first block code, second block code, third block code) may be single or multiple numbers only or letters only or a combination of numbers and letters or other character combinations, and may be one character (e.g., one number) or a combination of multiple characters. For example, the first block code is 01, the second block code is a1, and the third block code is 3.

Note that the first block code as the installation area block code means that the installation area includes the first block code, and does not mean that the installation area block code is composed of only the first block code and cannot include other block codes. Thus, the installation area block code may include only the first block code, or may include the first block code and other block codes other than the first block code. Likewise, the installation unit block code and the end point block code are similarly composed.

And classifying all terminals before the first preset time interval into one installation unit by taking the current first preset time interval as a boundary, and classifying all terminals after the first preset time interval into another same installation unit until encountering a new first preset time interval. Thereby grouping each terminal to a unique corresponding group of mounting units. And each time a first preset time interval is newly added, continuing to divide all terminals before the first preset time interval into one installation unit by taking the current first preset time interval as a boundary, and dividing all terminals after the first preset time interval into another same installation unit until all the first preset time intervals are divided into terminals by boundary. Similarly, taking the second preset time interval as a boundary, regarding all the installation units before the second preset time interval as the same installation area, and regarding all the installation units after the second preset time interval as another installation area.

In an alternative embodiment, a first block code is assigned to each installation area, a second block code is assigned to each installation unit, and a third block code is assigned to each terminal, in sequential increasing or decreasing order. I.e. the first block code of the current installation area is the first block code of the last installation area + a fixed number (e.g. + 1). The same is true for the second block code and the third block code.

In another alternative embodiment, a random number is used to assign the block code. That is, one first block code is randomly allocated to each mounting region, and the first block codes are not the same for each mounting region. Similarly, a random number is randomly assigned to each of the mounting units and the destination as the second block code and the third block code, respectively. The second block codes of the respective mounting units in at least one of the mounting areas are different, and the third block codes of the respective terminals in at least one of the mounting units are different.

In another optional embodiment, if a new operation time stamp is not obtained within a first preset time interval after at least one operation time stamp is obtained, all terminals corresponding to the currently obtained operation time stamp are allocated with a third block code, and an installation unit where the current terminal is located is allocated with a second block code. And then, similarly, after at least one new operation time stamp is obtained, and after the new operation time stamp is not obtained in the first preset time interval, continuing to distribute the third block code to all terminals corresponding to the current obtained operation time stamp, distributing the second block code to the installation unit where the current terminal is located, thus distributing the second block code and the third block code to the current installation unit and the terminal in the current installation unit respectively every time after the terminal operation in one installation unit is completed and before the terminal operation in the next installation unit is completed, and then, distributing the corresponding second block code and the third block code to all the installation units in the current installation area and all the terminals in the installation unit by analogy.

The same is true for the allocation of the first block code to the respective installation areas. That is, after at least one operation time stamp is obtained for the current installation area, after a second preset time interval, a new operation time stamp is not obtained yet, and then the first block codes are allocated to the current installation area in sequence, so that the first block codes are still allocated to the new installation area continuously.

In another alternative embodiment, after the operation of each terminal of each installation unit of each installation area is completed, the first block code, the second block code and the third block code are uniformly distributed after the corresponding first preset time interval and the second preset time interval are obtained.

Step 4: and establishing a mapping relation between the terminal block codes of the terminal, thereby completing binding configuration of the terminal. For example, a mapping relation with terminal block codes of the terminals is established on the server, so that the terminal block codes of the terminals can be obtained by accessing the server, and the current terminal installation unit and the current terminal installation area are identified based on the terminal block codes, so that each terminal can be accurately distinguished and identified.

Referring to fig. 2, taking a hospitalization unit building as an example of the target space, the hospitalization unit building is assumed to have 15 floors, each floor has 15 sickrooms, each sickroom has 3-4 beds, and each bed needs to be provided with a sickbed calling machine. Each layer is taken as an installation area, each ward is taken as an installation unit, each sickbed calling machine is taken as a terminal, and the terminal group code which is uniquely corresponding to each terminal is finally allocated to each terminal, and the current sickbed calling machine can be distinguished from the beds, the ward and the floor to which the sickbed calling machine belongs through the terminal group code, so that which bed in which ward of which layer is called can be determined, and quick response is facilitated.

The operator performs binding configuration to first go to the ward 1 of the first layer to perform operation, and clicks the touch screen on each sickbed calling machine in the ward 1 three times continuously, so as to generate an operation signal to the rear end (i.e. the server) and form an operation time stamp. Then, the operator walks into the ward 2 from the ward 1, and clicks the touch screen on each sickbed calling machine in the ward 2 three times continuously, and a corresponding operation time stamp is formed. Since the space of one ward is relatively limited, the time interval for two adjacent operations within the same ward is relatively short, and thus the time difference of the operation time stamps generated by the two adjacent operations within the ward 1 is much smaller than the first preset time interval. The time difference from the completion of the operation of the last sickbed caller in the ward 1 to the execution of the first sickbed caller by the ward 2 is much larger than the time difference of the operation time stamps generated by the two adjacent operations, so that the time difference from the completion of the operation of the last sickbed caller in the ward 1 to the execution of the first sickbed caller by the ward 2, that is, the time difference from the completion of the operation of the last sickbed caller in the ward 1 to the execution of the first sickbed caller by the ward 2, is characterized by a first preset time interval, that is, the first preset time interval is used as a boundary to distinguish which sickbed callers belong to the ward 1 and which sickbed callers belong to the ward 2. Similarly, after the operation of the sickbed calling machines in all the sickrooms in the first layer is completed, the operator walks to the second layer to perform the same operation, and sequentially goes on until the sickbed calling machines in 15 floors in total of all the floors of the hospitalized building are completed to be operated to form corresponding operation time stamps, so that the sickbed calling machines belonging to the same floor and the sickbed calling machines belonging to the other floor can be distinguished through a second preset time interval.

Compared with the prior batch terminal binding configuration operation, the invention continuously operates at the terminal to obtain the operation time stamp of the returned response signal, thereby determining which terminals belong to the same installation unit and which installation units belong to which installation area through the comparison result of the time difference between the two adjacent operation time stamps and the preset time interval, and further distributing the block codes to the terminals in batches at the rear end to obtain the terminal block codes of the terminals, and running back to the rear end (such as a server) to distribute the block codes of the current terminal after each terminal operation is not needed, and continuing the same operation to the next terminal. Time and energy can be saved greatly, the binding configuration efficiency of the batch terminals can be improved, and the binding configuration of the batch terminals can be completed more efficiently.

The embodiment disclosed in the present specification is merely an illustration of one-sided features of the present invention, and the protection scope of the present invention is not limited to this embodiment, and any other functionally equivalent embodiment falls within the protection scope of the present invention. Various other corresponding changes and modifications will occur to those skilled in the art from the foregoing description and the accompanying drawings, and all such changes and modifications are intended to be included within the scope of the present invention as defined in the appended claims.

Claims (10)

1. The batch terminal binding configuration method under the multi-level is characterized by comprising the following steps of:

step 1: dividing a target space for installing a to-be-bound configuration terminal into a plurality of installation areas according to a hierarchy, wherein a plurality of installation units are arranged in the installation areas, the installation units represent minimum areas which can be divided for installing the terminal, and all the target terminals which are bound and configured are installed in all the installation units of all the installation areas in the target space after the hierarchy division is completed;

step 2: obtaining operation time stamps responding to signals returned by terminal operation, and determining an installation unit to which each terminal belongs and an installation area to which each installation unit belongs based on comparison results of the operation time stamps and preset time intervals;

step 3: assigning a block code to each terminal based on the belonging installation area and the belonging installation unit to obtain a terminal block code, wherein the terminal block code characterizes the current terminal belonging installation unit and the installation area of the installation unit,

step 4: and establishing a mapping relation between the terminal block codes of the terminal, thereby completing binding configuration of the terminal.

2. The batch terminal binding configuration method under the multi-hierarchy level according to claim 1, wherein the specific implementation process of the step 2 includes the following steps:

selecting any installation area from the target space as a current installation area, selecting any installation unit from the current installation area as a current installation unit, respectively operating each terminal in the current installation unit at least once, and receiving an operation time stamp of a signal generated by operation;

after a first preset time interval, the first preset time interval represents the travel time from the current installation unit to the next installation unit, each terminal in the next installation unit in the current installation area is continuously operated at least once and operation time stamps are also obtained, an installation time period corresponding to the next installation unit is obtained, after the terminal operation in one installation unit is completed, the terminal in the next installation unit is continuously operated after the first preset time interval until all the installation units in the current installation area obtain a corresponding installation time period,

after the operation of all the terminals in the current installation area is completed, the second preset time interval represents the travel time from the current installation area to the next installation area, the same operation is continuously carried out on the next installation area, the installation time periods corresponding to all the installation units in the next installation area are obtained, and the installation time periods of all the installation units in all the installation areas in the target space are obtained.

3. The batch terminal binding configuration method under the multi-hierarchy level according to claim 2, wherein the specific implementation process of the step 3 includes the following steps:

respectively allocating a first block code to each installation area, wherein the first block code is used as an installation area block code, thereby obtaining an installation area block code, allocating a second block code to each installation unit, combining the installation area block code and the second block code to form an installation unit block code, thereby obtaining an installation unit block code, respectively allocating a third block code to each terminal, combining the installation unit block code and the third block code as the block codes of the terminal, thereby obtaining a terminal block code,

wherein, with the current first preset time interval as a boundary, all terminals before the first preset time interval are classified as one installation unit, all terminals after the first preset time interval are classified as another one installation unit until a new first preset time interval is encountered, each terminal is classified as a unique corresponding group of installation units, each time when the first preset time interval is newly added, the current first preset time interval is continuously used as a boundary, all terminals before the first preset time interval are classified as one installation unit, all terminals after the first preset time interval are classified as another one installation unit until all the first preset time intervals are classified as a boundary,

similarly, taking the second preset time interval as a boundary, regarding all the installation units before the second preset time interval as the same installation area, and regarding all the installation units after the second preset time interval as another installation area.

4. A batch termination binding configuration method at a multi-level according to claim 3, wherein the total number of the termination points is the same or different between the respective installation areas, and the total number of the termination points in the respective installation units in the same installation area is the same or different.

5. A multi-level batch termination binding configuration method according to claim 3, wherein the first predetermined time interval is greater than a time difference between two operation time stamps adjacent in any order of operation within the installation unit.

6. A method of batch termination binding configuration at a multi-level as claimed in claim 3, wherein the second predetermined time interval is greater than the time difference between the last operating time stamp of the last installation unit and the first operating time stamp of the next installation unit in any two adjacent installation units within the secure area.

7. A method of batch end-binding configuration at multiple levels as claimed in claim 3, wherein the first preset time interval is the same or different each time and the second preset time interval is the same or different each time.

8. The batch termination binding configuration method of claim 3, wherein the second predetermined time interval is the same as or different from the first predetermined time interval.

9. A multi-level batch end-binding configuration method according to claim 3, wherein the block codes are composed of single or multiple pure numbers or pure letters or combinations of numbers and letters or other character combinations, and random numbers are used to assign the block codes.

10. A batch terminal binding configuration method at a multi-level according to claim 3, wherein a first block code is assigned to each installation area, a second block code is assigned to each installation unit, and a third block code is assigned to each terminal in order of increasing or decreasing sequentially.

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