CN116777180A - Visual logistics scheduling method and system based on Internet of things - Google Patents

Abstract

The invention provides a visual logistics scheduling method and system based on the Internet of things, comprising the following steps: the method comprises the steps of respectively collecting basic information corresponding to each object to be sent, establishing a basic information comparison list, obtaining a logistics destination corresponding to each object to be sent based on the basic information comparison list, respectively distributing a dispatching vehicle for each object to be sent according to the logistics destination, respectively obtaining a dispatching process corresponding to each object to be sent, establishing dispatching information, finally establishing a dispatching 3D animation according to the dispatching information, transmitting the dispatching 3D animation to a designated terminal for display, distributing the dispatching vehicle for the object to be sent by utilizing the basic information of the object to be sent, supervising the dispatching process of each object to be sent in the dispatching process, establishing the 3D animation consistent with the dispatching process progress for a user to check the current logistics progress, and enabling the user to check the current position of the object to be sent at any time.

Description

Visual logistics scheduling method and system based on Internet of things

Technical Field

The invention relates to the technical field of logistics scheduling, in particular to a visual logistics scheduling method and system based on the Internet of things.

Background

The logistics dispatching mainly refers to the work that a logistics company reasonably arranges and dispatches vehicles and personnel to which the logistics company belongs to and controls the arrival of goods in the whole course according to the weight, the direction, the specification, the degree of urgency and the like of the goods to be sent in the logistics process. The work of carrying out commodity circulation dispatch among the prior art is gone on by the manual work, and the staff loads the dispatch car with the article on, then is transported the destination with the article by the driver, and in this process driver or other staff need at the current position of fixed website manual entry article, so there is the time difference between commodity circulation information and the actual commodity circulation progress that the user looked over.

Therefore, the invention provides a visual logistics scheduling method and system based on the Internet of things.

Disclosure of Invention

According to the visual logistics scheduling method and system based on the Internet of things, the basic information of the to-be-sent articles is utilized to distribute the scheduling vehicles for the to-be-sent articles, then the scheduling process of each to-be-sent article is supervised in the scheduling process, and a 3D animation consistent with the scheduling process progress is established for a user to check the current logistics progress, so that the user can check the current position of the to-be-sent article at any time.

The invention provides a visual logistics scheduling method based on the Internet of things, which comprises the following steps:

step 1: basic information corresponding to each object to be sent is collected respectively, and a basic information comparison list is established;

step 2: obtaining a logistics destination corresponding to each object to be sent based on the basic information comparison list, and respectively distributing a dispatching vehicle for each object to be sent according to the logistics destination;

step 3: respectively acquiring a scheduling process corresponding to each to-be-sent article, and establishing scheduling information;

step 4: and establishing a dispatching 3D animation according to the dispatching information, and transmitting the dispatching 3D animation to a designated terminal for display.

In one embodiment of the present invention, in one possible implementation,

the step 1 comprises the following steps:

step 11: respectively scanning object codes corresponding to each object to be sent;

step 12: analyzing each article code respectively to obtain basic information corresponding to each article to be sent;

step 13: and establishing a basic information comparison list according to the basic information corresponding to each object to be sent.

In one embodiment of the present invention, in one possible implementation,

the step 2 includes:

step 21: obtaining appearance characteristics, weight characteristics and logistics destinations corresponding to each to-be-sent article based on the basic information comparison table;

step 22: acquiring the current position of the to-be-sent article and combining with a logistics destination, respectively establishing a logistics path for each to-be-sent article, and simultaneously acquiring the residual space information and the forward route information corresponding to each dispatching vehicle;

step 23: matching corresponding dispatching vehicle sets for each to-be-sent article according to the advancing route information and the logistics route, and matching corresponding target dispatching vehicles for the to-be-sent article according to appearance characteristics, weight characteristics and residual space information of dispatching vehicles in the dispatching vehicle sets corresponding to each to-be-sent article;

step 24: and obtaining a target dispatching vehicle corresponding to each object to be sent, and establishing a dispatching vehicle corresponding list.

In one embodiment of the present invention, in one possible implementation,

the step 3 includes:

step 31: acquiring current scheduling information corresponding to each to-be-sent article and an article code corresponding to each to-be-sent article, and inputting the current scheduling information into the corresponding article code;

step 32: acquiring a corresponding list of the dispatching vehicles, respectively acquiring a plurality of dispatching vehicles corresponding to each object to be sent according to the corresponding list of the dispatching vehicles, and establishing a dispatching vehicle sequence according to a dispatching sequence corresponding to each dispatching vehicle;

step 33: obtaining a target dispatching vehicle where each object to be dispatched is currently located according to the current dispatching information, and marking an object code corresponding to each object to be dispatched in a corresponding dispatching vehicle list;

step 34: and acquiring the marking information of the object codes in the corresponding dispatching truck list at different moments, and establishing the dispatching information of the corresponding to-be-sent objects.

In one embodiment of the present invention, in one possible implementation,

the step 4 includes:

step 41: analyzing the scheduling information to obtain historical scheduling information corresponding to each to-be-sent article;

step 42: respectively acquiring object codes corresponding to each object to be sent, establishing corresponding virtual objects according to the number of the object codes, and naming the corresponding virtual objects by the object codes;

step 43: establishing a virtual advancing path corresponding to each virtual article according to the historical scheduling information, marking the current logistics position of the corresponding virtual article on the virtual advancing path, and establishing virtual logistics information;

step 44: mapping each piece of virtual stream information to a 3D animation model to establish a 3D stream animation, marking a corresponding object code on each 3D stream animation to generate a dispatching 3D animation, and transmitting the dispatching 3D animation to a designated terminal for display.

In one embodiment of the present invention, in one possible implementation,

the step 43 includes:

step 431: analyzing the historical scheduling information to obtain a scheduled path corresponding to each article to be sent in each preset historical period, and analyzing the scheduling information to obtain an unscheduled path of each article to be sent;

step 432: the method comprises the steps of obtaining scheduled paths corresponding to the same to-be-sent article, respectively obtaining execution time periods corresponding to each scheduled path, and establishing a virtual advanced route corresponding to a virtual article according to the sequence of the execution time periods;

step 433: establishing a virtual non-advancing route of the corresponding virtual article according to the non-scheduling route corresponding to each article to be sent;

step 434: the method comprises the steps of obtaining a virtual advanced route and a virtual non-advanced route corresponding to the same to-be-sent article, establishing a virtual advanced route, obtaining route nodes between the virtual advanced route and the virtual non-advanced route, recording the route nodes as the current logistics position of the virtual article, and establishing virtual logistics information.

The invention provides a visual logistics scheduling system based on the Internet of things, which comprises the following steps:

the acquisition module is used for respectively acquiring basic information corresponding to each object to be sent and establishing a basic information comparison list;

the distribution module is used for obtaining a logistics destination corresponding to each object to be sent based on the basic information comparison list, and respectively distributing a dispatching vehicle for each object to be sent according to the logistics destination;

the monitoring module is used for respectively acquiring the scheduling process corresponding to each to-be-sent article and establishing scheduling information;

and the execution module is used for establishing a dispatching 3D animation according to the dispatching information and transmitting the dispatching 3D animation to the appointed terminal for display.

In one embodiment of the present invention, in one possible implementation,

further comprises:

and the appointed terminal is used for displaying the dispatch 3D animation corresponding to the different to-be-sent articles.

In one embodiment of the present invention, in one possible implementation,

the execution module comprises:

the analysis unit is used for analyzing the scheduling information to obtain historical scheduling information corresponding to each to-be-sent article;

the modeling unit is used for respectively acquiring the object codes corresponding to each object to be sent, establishing corresponding virtual objects according to the number of the object codes, and naming the corresponding virtual objects by the object codes;

the simulation unit is used for establishing a virtual advancing path corresponding to each virtual article according to the historical scheduling information, marking the current logistics position of the corresponding virtual article on the virtual advancing path and establishing virtual logistics information;

and the projection unit is used for respectively mapping each piece of virtual stream information into the 3D animation model to establish a 3D stream animation, respectively marking a corresponding object code on each 3D stream animation to generate a dispatch 3D animation, and transmitting the dispatch 3D animation to the appointed terminal for display.

In one embodiment of the present invention, in one possible implementation,

the simulation unit includes:

the first simulation subunit is used for analyzing the historical scheduling information to obtain a scheduled path corresponding to each article to be sent in each preset historical period, and analyzing the scheduling information to obtain an unscheduled path of each article to be sent;

the second simulation subunit is used for acquiring scheduled paths corresponding to the same to-be-sent article, respectively acquiring execution time periods corresponding to each scheduled path, and establishing a virtual advanced route corresponding to the virtual article according to the sequence of the execution time periods;

the third simulation subunit is used for establishing a virtual non-advancing route of the corresponding virtual article according to the non-scheduling route corresponding to each article to be sent;

and the fourth simulation subunit is used for acquiring a virtual advanced route and a virtual non-advanced route corresponding to the same to-be-sent article, establishing a virtual advanced route, acquiring route nodes between the virtual advanced route and the virtual non-advanced route, recording the route nodes as the current logistics position of the virtual article, and establishing virtual logistics information.

The invention has the beneficial effects that: in order to achieve the purpose of monitoring the dispatching process of the to-be-sent articles in real time, basic information of each to-be-sent article is acquired firstly, so that a logistics destination corresponding to each to-be-sent article is obtained, then a dispatching truck is distributed according to the logistics destination, dispatching work is executed, the dispatching process of the to-be-sent article is acquired in the process of executing the dispatching work, then a 3D animation technology is utilized to establish a dispatching 3D animation, the dispatching process of the to-be-sent article is presented in an animation mode, therefore, a user can check the dispatching information of the to-be-sent article at any time at a designated terminal, the user can check the current position of the to-be-sent article at any time, and the interestingness of the showing effect is improved by carrying out logistics display in a 3D animation mode, so that the user is relieved in the process of waiting for the articles to be sent to the destination.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and claims thereof as well as the appended drawings.

The technical scheme of the invention is further described in detail through the drawings and the embodiments.

Drawings

The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate the invention and together with the embodiments of the invention, serve to explain the invention. In the drawings:

fig. 1 is a schematic workflow diagram of a visual logistics scheduling method based on the internet of things in an embodiment of the present invention;

fig. 2 is a schematic workflow diagram of step 4 of a visual logistics scheduling method based on the internet of things in an embodiment of the present invention;

fig. 3 is a schematic diagram of a visual logistics scheduling system based on the internet of things in an embodiment of the present invention.

Detailed Description

The preferred embodiments of the present invention will be described below with reference to the accompanying drawings, it being understood that the preferred embodiments described herein are for illustration and explanation of the present invention only, and are not intended to limit the present invention.

Example 1

The embodiment provides a visual logistics scheduling method based on the internet of things, as shown in fig. 1, including:

step 1: basic information corresponding to each object to be sent is collected respectively, and a basic information comparison list is established;

step 2: obtaining a logistics destination corresponding to each object to be sent based on the basic information comparison list, and respectively distributing a dispatching vehicle for each object to be sent according to the logistics destination;

step 3: respectively acquiring a scheduling process corresponding to each to-be-sent article, and establishing scheduling information;

step 4: and establishing a dispatching 3D animation according to the dispatching information, and transmitting the dispatching 3D animation to a designated terminal for display.

In this example, the to-be-sent item indicates an item to be sent to another place;

in this example, the basic information includes the package specification, package weight, transport start position, transport end position, and the like of the to-be-issued article;

in the example, basic information corresponding to each to-be-sent article is counted in a basic information comparison list;

in this example, the logistics destination represents the location to which the to-be-sent item is to be delivered;

in this example, the scheduling process includes: before starting dispatching, replacing a dispatching vehicle, and after completing dispatching;

in this example, a virtual scheduling process for scheduling a plurality of items to be sent is included in the 3D animation.

The working principle of the technical scheme has the beneficial effects that: in order to achieve the purpose of monitoring the dispatching process of the to-be-sent articles in real time, basic information of each to-be-sent article is acquired firstly, so that a logistics destination corresponding to each to-be-sent article is obtained, then a dispatching truck is distributed according to the logistics destination, dispatching work is executed, the dispatching process of the to-be-sent article is acquired in the process of executing the dispatching work, then a 3D animation technology is utilized to establish a dispatching 3D animation, the dispatching process of the to-be-sent article is presented in an animation mode, therefore, a user can check the dispatching information of the to-be-sent article at any time at a designated terminal, the user can check the current position of the to-be-sent article at any time, and the interestingness of the showing effect is improved by carrying out logistics display in a 3D animation mode, so that the user is relieved in the process of waiting for the articles to be sent to the destination.

Example 2

Based on embodiment 1, the visual logistics scheduling method based on the internet of things, the step 1 includes:

step 11: respectively scanning object codes corresponding to each object to be sent;

step 12: analyzing each article code respectively to obtain basic information corresponding to each article to be sent;

step 13: and establishing a basic information comparison list according to the basic information corresponding to each object to be sent.

In this example, one to-be-issued article corresponds to one article code, and the article code is unique;

in this example, the object code may be one of a two-dimensional code, a bar code, and a digital code.

The working principle of the technical scheme has the beneficial effects that: basic information of each to-be-sent article is obtained by scanning and analyzing the article code of the to-be-sent article, and then a basic information comparison list is established according to the basic information, so that a basis is made for subsequent dispatching truck allocation.

Example 3

Based on embodiment 1, the method for scheduling visual logistics based on the internet of things, the step 2, includes:

step 21: obtaining appearance characteristics, weight characteristics and logistics destinations corresponding to each to-be-sent article based on the basic information comparison table;

step 22: acquiring the current position of the to-be-sent article and combining with a logistics destination, respectively establishing a logistics path for each to-be-sent article, and simultaneously acquiring the residual space information and the forward route information corresponding to each dispatching vehicle;

step 23: matching corresponding dispatching vehicle sets for each to-be-sent article according to the advancing route information and the logistics route, and matching corresponding target dispatching vehicles for the to-be-sent article according to appearance characteristics, weight characteristics and residual space information of dispatching vehicles in the dispatching vehicle sets corresponding to each to-be-sent article;

step 24: and obtaining a target dispatching vehicle corresponding to each object to be sent, and establishing a dispatching vehicle corresponding list.

In this example, the appearance features include: appearance shape, appearance volume, appearance color, etc.;

in this example, the weight characteristic represents the weight of the item to be issued;

in this example, each scheduler corresponds to a fixed forward route;

in this example, the remaining space information includes: the residual capacity of the dispatching truck and the residual bearing of the dispatching truck;

in this example, the forward route information includes: a bidirectional forward route of the dispatcher;

in this example, the dispatching vehicles collectively comprise a plurality of dispatching vehicle replacement schemes consistent with the material flow path;

in this example, the target dispatcher represents a dispatcher which is consistent with the logistics destination direction of the to-be-sent article, and the remaining space can be used for placing the to-be-sent article;

in the example, the corresponding list of the dispatching vehicles comprises dispatching vehicles corresponding to the to-be-sent objects in different road sections;

in the example, after a target dispatching vehicle corresponding to each to-be-sent article is established, the to-be-sent article is placed on the target dispatching vehicle;

respectively calculating the residual cargo space corresponding to each target dispatching vehicle according to the formula (1);

wherein P is _i Representing the residual cargo capacity corresponding to the ith target dispatching truck, t _k Represents a kth schedule, and the ith target schedule is derived from the kth schedule, ik represents the kth schedule of the ith target schedule, t _j The j-th dispatch node of the target dispatch vehicle is represented, ij represents the j-th dispatch node of the i-th target dispatch vehicle, g _ikj Indicating the total quantity of the scheduled items in the process from the scheduling starting point to the jth scheduling node of the target scheduling vehicle, and h _m Representing the number of the scheduled items to be sent of the mth scheduling node in the process of the target scheduling vehicle from the scheduling starting point to the jth scheduling node, m represents the number of the scheduled items to be sent of the mth scheduling node,indicating the total number of the to-be-sent items of the target dispatching truck from the dispatching starting point to the j-th dispatching node, wherein the to-be-sent items are changed to indicate to be-sent items of the target dispatching truck to another dispatching truck, and the +.>Indicating the number of the existing to-be-sent articles in the target dispatching truck when the target dispatching truck goes from a dispatching starting point to a j-th dispatching node, wherein X is the number of the to-be-sent articles in the target dispatching truck _i0 ，Y _i0 ) Coordinates representing a schedule start point of an ith schedule, (X) _iZ ，Y _iZ ) Coordinates indicating a schedule end point of the ith schedule, q _ij Representing the j-th schedule sectionScheduling amount of points, U _max Represents a preset maximum loading probability, U _min Represents a preset minimum loading probability, M represents the total number of scheduling nodes, +.>Representing a full load probability when the target scheduler arrives at the mth scheduling node;

and (3) obtaining the residual cargo space corresponding to each target dispatching vehicle according to the calculation result of the formula (1), generating feedback information, and transmitting the feedback information to the designated terminal for display.

The working principle of the technical scheme has the beneficial effects that: in order to avoid the phenomenon of shell blocking of the to-be-sent articles in the transportation process, before dispatching, the to-be-sent articles are matched with the dispatching cars under different road sections according to the appearance characteristics and the weight characteristics of each to-be-sent article, then a corresponding list of the dispatching cars is established, dispatching work is carried out based on the list in the subsequent dispatching process, the preparation time for replacing the dispatching cars is shortened, and the dispatching efficiency is improved.

Example 4

Based on embodiment 1, the visual logistics scheduling system based on the internet of things, the step 3 includes:

step 31: acquiring current scheduling information corresponding to each to-be-sent article and an article code corresponding to each to-be-sent article, and inputting the current scheduling information into the corresponding article code;

step 32: acquiring a corresponding list of the dispatching vehicles, respectively acquiring a plurality of dispatching vehicles corresponding to each object to be sent according to the corresponding list of the dispatching vehicles, and establishing a dispatching vehicle sequence according to a dispatching sequence corresponding to each dispatching vehicle;

step 33: obtaining a target dispatching vehicle where each object to be dispatched is currently located according to the current dispatching information, and marking an object code corresponding to each object to be dispatched in a corresponding dispatching vehicle list;

step 34: and acquiring the marking information of the object codes in the corresponding dispatching truck list at different moments, and establishing the dispatching information of the corresponding to-be-sent objects.

In the example, the current scheduling information represents the scheduling position information of the to-be-sent article at the current moment and the information of the scheduling vehicle;

in this example, the target dispatcher represents a dispatcher where the object to be discovered is located;

in this example, the sequence of dispatchers includes all dispatchers that dispatch an item to be sent, and the sequence established is ordered in the order of dispatch.

The working principle of the technical scheme has the beneficial effects that: the current scheduling information of the to-be-sent article is input into the article code, the current scheduling information corresponding to different to-be-sent articles can be distinguished, then a plurality of scheduling carts corresponding to the to-be-sent articles are acquired by combining the scheduling carts corresponding list, so that a scheduling carts sequence is established, the article code of the to-be-sent article is marked in the scheduling carts sequence for positioning the current position of the to-be-sent article, and the scheduling information of the to-be-sent article is established according to the marking information of the to-be-sent article at different moments, so that the scheduling information of the to-be-sent article can be established by acquiring the marking information of the article code at different moments, the scheduling process of the to-be-sent article can be supervised, and users can conveniently check the corresponding scheduling information at different moments, and the inquiry demands of the users are met.

Example 5

On the basis of embodiment 1, the visual logistics scheduling method based on the internet of things, as shown in fig. 2, the step 4 includes:

step 41: analyzing the scheduling information to obtain historical scheduling information corresponding to each to-be-sent article;

step 42: respectively acquiring object codes corresponding to each object to be sent, establishing corresponding virtual objects according to the number of the object codes, and naming the corresponding virtual objects by the object codes;

step 43: establishing a virtual advancing path corresponding to each virtual article according to the historical scheduling information, marking the current logistics position of the corresponding virtual article on the virtual advancing path, and establishing virtual logistics information;

step 44: mapping each piece of virtual stream information to a 3D animation model to establish a 3D stream animation, marking a corresponding object code on each 3D stream animation to generate a dispatching 3D animation, and transmitting the dispatching 3D animation to a designated terminal for display.

In this example, the historical schedule information represents schedule information generated in the past time;

in this example, the virtual item representation is established in a virtual space in which a virtual product of the item to be issued can be represented;

in this example, the virtual advancing path represents a virtual trace that simulates the advance of the article to be issued in the virtual space;

in this example, the current logistics position represents the position of the virtual article on the virtual advancement path;

in this example, the virtual logistics information table is consistent with the historical schedule information;

in this example, the 3D animation model represents a generation model for creating a 3D animation, which is a model preset by the system, and the purpose of which is to output a 3D animation.

The working principle of the technical scheme has the beneficial effects that: the method comprises the steps of determining historical scheduling information corresponding to each to-be-sent article through analyzing the scheduling information, establishing a plurality of virtual articles by taking article codes as names, establishing a virtual advancing route of the virtual articles by utilizing the historical scheduling information, marking the positions of the virtual articles on the virtual advancing route, thereby establishing virtual logistics information for the virtual articles, combining the virtual logistics information with a 3D animation model in a mapping mode, generating a 3D scheduling code, and completing the establishment of a scheduling animation.

Example 6

Based on embodiment 5, the visual logistics scheduling method based on the internet of things, the simulation unit includes:

the step 43 includes:

step 431: analyzing the historical scheduling information to obtain a scheduled path corresponding to each article to be sent in each preset historical period, and analyzing the scheduling information to obtain an unscheduled path of each article to be sent;

step 432: the method comprises the steps of obtaining scheduled paths corresponding to the same to-be-sent article, respectively obtaining execution time periods corresponding to each scheduled path, and establishing a virtual advanced route corresponding to a virtual article according to the sequence of the execution time periods;

step 433: establishing a virtual non-advancing route of the corresponding virtual article according to the non-scheduling route corresponding to each article to be sent;

step 434: the method comprises the steps of obtaining a virtual advanced route and a virtual non-advanced route corresponding to the same to-be-sent article, establishing a virtual advanced route, obtaining route nodes between the virtual advanced route and the virtual non-advanced route, recording the route nodes as the current logistics position of the virtual article, and establishing virtual logistics information.

In this example, the preset history period may be 6 hours;

in this example, the scheduled path represents a path that the item to be issued has advanced;

in this example, the unscheduled path represents a path in which the item to be issued has not yet advanced;

in this example, one scheduled path corresponds to one execution period, and the execution period may not have a preset history period;

in this example, the virtual advanced route corresponds to the scheduled route, representing the scheduled route presented in the virtual space;

in this example, the virtual non-advancing route corresponds to an unscheduled route, representing an unscheduled route presented in the virtual space;

in this example, the route node represents a connection point between a virtual advanced route and a virtual non-advanced route.

The working principle of the technical scheme has the beneficial effects that: in order to avoid overlarge errors between virtual logistics information and actual logistics information, historical scheduling information is analyzed firstly to obtain scheduled paths of each to-be-sent article, scheduling information is analyzed at the same time to obtain unscheduled paths of the to-be-sent article, so that a virtual advancing path is established, route nodes between the virtual advancing path and the virtual unscheduled path are marked on the virtual advancing path, so that the current logistics position of the virtual article is obtained, virtual logistics information can be established, the virtual advancing path is established in a segmented collection scheduling path mode, firstly, the work of establishing the virtual advancing path can be completed, secondly, the current physical position of the virtual article can be determined according to scheduling paths in different states, and accordingly, errors between the virtual logistics information and the actual logistics information are reduced.

Example 7

The embodiment provides a visual logistics scheduling system based on the internet of things, as shown in fig. 3, including:

the acquisition module is used for respectively acquiring basic information corresponding to each object to be sent and establishing a basic information comparison list;

the distribution module is used for obtaining a logistics destination corresponding to each object to be sent based on the basic information comparison list, and respectively distributing a dispatching vehicle for each object to be sent according to the logistics destination;

the monitoring module is used for respectively acquiring the scheduling process corresponding to each to-be-sent article and establishing scheduling information;

and the execution module is used for establishing a dispatching 3D animation according to the dispatching information and transmitting the dispatching 3D animation to the appointed terminal for display.

In this example, the to-be-sent item indicates an item to be sent to another place;

in this example, the basic information includes the package specification, package weight, transport start position, transport end position, and the like of the to-be-issued article;

in the example, basic information corresponding to each to-be-sent article is counted in a basic information comparison list;

in this example, the logistics destination represents the location to which the to-be-sent item is to be delivered;

in this example, the scheduling process includes: before starting dispatching, replacing a dispatching vehicle, and after completing dispatching;

in this example, a virtual scheduling process for scheduling a plurality of items to be sent is included in the 3D animation.

The working principle of the technical scheme has the beneficial effects that: in order to achieve the purpose of monitoring the dispatching process of the to-be-sent articles in real time, basic information of each to-be-sent article is acquired firstly, so that a logistics destination corresponding to each to-be-sent article is obtained, then a dispatching truck is distributed according to the logistics destination, dispatching work is executed, the dispatching process of the to-be-sent article is acquired in the process of executing the dispatching work, then a 3D animation technology is utilized to establish a dispatching 3D animation, the dispatching process of the to-be-sent article is presented in an animation mode, therefore, a user can check the dispatching information of the to-be-sent article at any time at a designated terminal, the user can check the current position of the to-be-sent article at any time, and the interestingness of the showing effect is improved by carrying out logistics display in a 3D animation mode, so that the user is relieved in the process of waiting for the articles to be sent to the destination.

Example 8

Based on embodiment 7, the visual logistics scheduling system based on the internet of things further includes:

and the appointed terminal is used for displaying the dispatch 3D animation corresponding to the different to-be-sent articles.

In this example, the designated terminals may be mobile phones of related personnel and users, and the number of the designated terminals is a plurality.

The working principle of the technical scheme has the beneficial effects that: the dispatch 3D animation of different pairs of objects to be sent is displayed through the appointed terminal, so that a user and related personnel can conveniently acquire a dispatch process at any time

Example 9

Based on embodiment 7, the visual logistics scheduling system based on the internet of things, the execution module includes:

the analysis unit is used for analyzing the scheduling information to obtain historical scheduling information corresponding to each to-be-sent article;

the modeling unit is used for respectively acquiring the object codes corresponding to each object to be sent, establishing corresponding virtual objects according to the number of the object codes, and naming the corresponding virtual objects by the object codes;

the simulation unit is used for establishing a virtual advancing path corresponding to each virtual article according to the historical scheduling information, marking the current logistics position of the corresponding virtual article on the virtual advancing path and establishing virtual logistics information;

and the projection unit is used for respectively mapping each piece of virtual stream information into the 3D animation model to establish a 3D stream animation, respectively marking a corresponding object code on each 3D stream animation to generate a dispatch 3D animation, and transmitting the dispatch 3D animation to the appointed terminal for display.

In this example, the historical schedule information represents schedule information generated in the past time;

in this example, the virtual item representation is established in a virtual space in which a virtual product of the item to be issued can be represented;

in this example, the virtual advancing path represents a virtual trace that simulates the advance of the article to be issued in the virtual space;

in this example, the current logistics position represents the position of the virtual article on the virtual advancement path;

in this example, the virtual logistics information table is consistent with the historical schedule information;

in this example, the 3D animation model represents a generation model for creating a 3D animation, which is a model preset by the system, and the purpose of which is to output a 3D animation.

The working principle of the technical scheme has the beneficial effects that: the method comprises the steps of determining historical scheduling information corresponding to each to-be-sent article through analyzing the scheduling information, establishing a plurality of virtual articles by taking article codes as names, establishing a virtual advancing route of the virtual articles by utilizing the historical scheduling information, marking the positions of the virtual articles on the virtual advancing route, thereby establishing virtual logistics information for the virtual articles, combining the virtual logistics information with a 3D animation model in a mapping mode, generating a 3D scheduling code, and completing the establishment of a scheduling animation.

Example 10

Based on embodiment 9, the visual logistics scheduling method based on the internet of things, the simulation unit includes:

the first simulation subunit is used for analyzing the historical scheduling information to obtain a scheduled path corresponding to each article to be sent in each preset historical period, and analyzing the scheduling information to obtain an unscheduled path of each article to be sent;

the second simulation subunit is used for acquiring scheduled paths corresponding to the same to-be-sent article, respectively acquiring execution time periods corresponding to each scheduled path, and establishing a virtual advanced route corresponding to the virtual article according to the sequence of the execution time periods;

the third simulation subunit is used for establishing a virtual non-advancing route of the corresponding virtual article according to the non-scheduling route corresponding to each article to be sent;

and the fourth simulation subunit is used for acquiring a virtual advanced route and a virtual non-advanced route corresponding to the same to-be-sent article, establishing a virtual advanced route, acquiring route nodes between the virtual advanced route and the virtual non-advanced route, recording the route nodes as the current logistics position of the virtual article, and establishing virtual logistics information.

In this example, the preset history period may be 6 hours;

in this example, the scheduled path represents a path that the item to be issued has advanced;

in this example, the unscheduled path represents a path in which the item to be issued has not yet advanced;

in this example, one scheduled path corresponds to one execution period, and the execution period may not have a preset history period;

in this example, the virtual advanced route corresponds to the scheduled route, representing the scheduled route presented in the virtual space;

in this example, the virtual non-advancing route corresponds to an unscheduled route, representing an unscheduled route presented in the virtual space;

in this example, the route node represents a connection point between a virtual advanced route and a virtual non-advanced route.

The working principle of the technical scheme has the beneficial effects that: in order to avoid overlarge errors between virtual logistics information and actual logistics information, historical scheduling information is analyzed firstly to obtain scheduled paths of each to-be-sent article, scheduling information is analyzed at the same time to obtain unscheduled paths of the to-be-sent article, so that a virtual advancing path is established, route nodes between the virtual advancing path and the virtual unscheduled path are marked on the virtual advancing path, so that the current logistics position of the virtual article is obtained, virtual logistics information can be established, the virtual advancing path is established in a segmented collection scheduling path mode, firstly, the work of establishing the virtual advancing path can be completed, secondly, the current physical position of the virtual article can be determined according to scheduling paths in different states, and accordingly, errors between the virtual logistics information and the actual logistics information are reduced.

It will be apparent to those skilled in the art that various modifications and variations can be made to the present invention without departing from the spirit or scope of the invention. Thus, it is intended that the present invention also include such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.

Claims (10)

1. The visual logistics scheduling method based on the Internet of things is characterized by comprising the following steps of:

step 1: basic information corresponding to each object to be sent is collected respectively, and a basic information comparison list is established;

step 2: obtaining a logistics destination corresponding to each object to be sent based on the basic information comparison list, and respectively distributing a dispatching vehicle for each object to be sent according to the logistics destination;

step 3: respectively acquiring a scheduling process corresponding to each to-be-sent article, and establishing scheduling information;

step 4: and establishing a dispatching 3D animation according to the dispatching information, and transmitting the dispatching 3D animation to a designated terminal for display.

2. The visual logistics scheduling method based on the internet of things of claim 1, wherein the step 1 comprises:

step 11: respectively scanning object codes corresponding to each object to be sent;

step 12: analyzing each article code respectively to obtain basic information corresponding to each article to be sent;

step 13: and establishing a basic information comparison list according to the basic information corresponding to each object to be sent.

3. The visual logistics scheduling method based on the internet of things of claim 1, wherein the step 2 comprises:

step 21: obtaining appearance characteristics, weight characteristics and logistics destinations corresponding to each to-be-sent article based on the basic information comparison table;

step 22: acquiring the current position of the to-be-sent article and combining with a logistics destination, respectively establishing a logistics path for each to-be-sent article, and simultaneously acquiring the residual space information and the forward route information corresponding to each dispatching vehicle;

step 23: matching corresponding dispatching vehicle sets for each to-be-sent article according to the advancing route information and the logistics route, and matching corresponding target dispatching vehicles for the to-be-sent article according to appearance characteristics, weight characteristics and residual space information of dispatching vehicles in the dispatching vehicle sets corresponding to each to-be-sent article;

step 24: and obtaining a target dispatching vehicle corresponding to each object to be sent, and establishing a dispatching vehicle corresponding list.

4. The visual logistics scheduling method based on the internet of things of claim 1, wherein the step 3 comprises:

step 31: acquiring current scheduling information corresponding to each to-be-sent article and an article code corresponding to each to-be-sent article, and inputting the current scheduling information into the corresponding article code;

step 32: acquiring a corresponding list of the dispatching vehicles, respectively acquiring a plurality of dispatching vehicles corresponding to each object to be sent according to the corresponding list of the dispatching vehicles, and establishing a dispatching vehicle sequence according to a dispatching sequence corresponding to each dispatching vehicle;

step 33: obtaining a target dispatching vehicle where each object to be dispatched is currently located according to the current dispatching information, and marking an object code corresponding to each object to be dispatched in a corresponding dispatching vehicle list;

step 34: and acquiring the marking information of the object codes in the corresponding dispatching truck list at different moments, and establishing the dispatching information of the corresponding to-be-sent objects.

5. The visual logistics scheduling method based on the internet of things of claim 1, wherein the step 4 comprises:

step 41: analyzing the scheduling information to obtain historical scheduling information corresponding to each to-be-sent article;

step 42: respectively acquiring object codes corresponding to each object to be sent, establishing corresponding virtual objects according to the number of the object codes, and naming the corresponding virtual objects by the object codes;

step 43: establishing a virtual advancing path corresponding to each virtual article according to the historical scheduling information, marking the current logistics position of the corresponding virtual article on the virtual advancing path, and establishing virtual logistics information;

step 44: mapping each piece of virtual stream information to a 3D animation model to establish a 3D stream animation, marking a corresponding object code on each 3D stream animation to generate a dispatching 3D animation, and transmitting the dispatching 3D animation to a designated terminal for display.

6. The visual logistics scheduling method based on the internet of things of claim 1, wherein the step 43 comprises:

step 431: analyzing the historical scheduling information to obtain a scheduled path corresponding to each article to be sent in each preset historical period, and analyzing the scheduling information to obtain an unscheduled path of each article to be sent;

step 432: the method comprises the steps of obtaining scheduled paths corresponding to the same to-be-sent article, respectively obtaining execution time periods corresponding to each scheduled path, and establishing a virtual advanced route corresponding to a virtual article according to the sequence of the execution time periods;

step 433: establishing a virtual non-advancing route of the corresponding virtual article according to the non-scheduling route corresponding to each article to be sent;

step 434: the method comprises the steps of obtaining a virtual advanced route and a virtual non-advanced route corresponding to the same to-be-sent article, establishing a virtual advanced route, obtaining route nodes between the virtual advanced route and the virtual non-advanced route, recording the route nodes as the current logistics position of the virtual article, and establishing virtual logistics information.

7. Visual logistics scheduling system based on thing networking, characterized by comprising:

the acquisition module is used for respectively acquiring basic information corresponding to each object to be sent and establishing a basic information comparison list;

the distribution module is used for obtaining a logistics destination corresponding to each object to be sent based on the basic information comparison list, and respectively distributing a dispatching vehicle for each object to be sent according to the logistics destination;

the monitoring module is used for respectively acquiring the scheduling process corresponding to each to-be-sent article and establishing scheduling information;

and the execution module is used for establishing a dispatching 3D animation according to the dispatching information and transmitting the dispatching 3D animation to the appointed terminal for display.

8. The internet of things-based visual logistics scheduling system of claim 7, further comprising:

and the appointed terminal is used for displaying the dispatch 3D animation corresponding to the different to-be-sent articles.

9. The visual logistics scheduling system of claim 7, wherein the execution module comprises:

the analysis unit is used for analyzing the scheduling information to obtain historical scheduling information corresponding to each to-be-sent article;

the modeling unit is used for respectively acquiring the object codes corresponding to each object to be sent, establishing corresponding virtual objects according to the number of the object codes, and naming the corresponding virtual objects by the object codes;

the simulation unit is used for establishing a virtual advancing path corresponding to each virtual article according to the historical scheduling information, marking the current logistics position of the corresponding virtual article on the virtual advancing path and establishing virtual logistics information;

and the projection unit is used for respectively mapping each piece of virtual stream information into the 3D animation model to establish a 3D stream animation, respectively marking a corresponding object code on each 3D stream animation to generate a dispatch 3D animation, and transmitting the dispatch 3D animation to the appointed terminal for display.

10. The internet of things-based visual logistics scheduling system of claim 9, wherein the simulation unit comprises:

the first simulation subunit is used for analyzing the historical scheduling information to obtain a scheduled path corresponding to each article to be sent in each preset historical period, and analyzing the scheduling information to obtain an unscheduled path of each article to be sent;

the second simulation subunit is used for acquiring scheduled paths corresponding to the same to-be-sent article, respectively acquiring execution time periods corresponding to each scheduled path, and establishing a virtual advanced route corresponding to the virtual article according to the sequence of the execution time periods;

the third simulation subunit is used for establishing a virtual non-advancing route of the corresponding virtual article according to the non-scheduling route corresponding to each article to be sent;

and the fourth simulation subunit is used for acquiring a virtual advanced route and a virtual non-advanced route corresponding to the same to-be-sent article, establishing a virtual advanced route, acquiring route nodes between the virtual advanced route and the virtual non-advanced route, recording the route nodes as the current logistics position of the virtual article, and establishing virtual logistics information.