KR20240057139A - Shared delibery service devices - Google Patents

Abstract

The present invention performs destination recommendation, selection, decision, and notification in consideration of the location of the terminal, order time, delivery time, and rider location, and the orderer terminal is located in various locations, grouped by region, and delivery zones are established for each grouped region. Set it.

Description

SHARED DELIBERY SERVICE DEVICES}

The present invention relates to a shared delivery service device, and more specifically, to a shared delivery service that allows one person to order food, where a user orders the food he or she wants to eat for delivery, and uses the shared delivery service using a base delivery zone. It's about devices.

Prior art related to the present invention includes food delivery sharing. Patent Document 1 Location-based food delivery sharing platform and system provides a delivery sharing service platform implementation system. In addition, in the food delivery sharing service method of Patent Document 2, a delivery request according to a time sale is received and delivery is performed in batches. In addition, Patent Document 3 food delivery sharing system and method can increase user satisfaction by reducing the burden of delivery fees due to users' small orders. In addition, Patent Document 4, a shared ordering service system and method for delivery food, prevents unnecessary waste of food and provides efficient food ordering.

However, the prior art has a problem in that it cannot perform destination recommendation, selection, decision, and notification by considering the location of the terminal, order time, delivery time, and rider location.

Public Patent Publication No. 10-2016-0098887 Location-based food delivery sharing platform and system Public Patent Publication No. 10-2020-0097152 Food delivery sharing service method Registered Patent Publication No. 10-2106578 Food delivery sharing system and method Public Patent Publication No. 10-2021-0132814 Shared ordering service system and method for delivery food

The purpose of the present invention is to provide a shared delivery service device that performs destination recommendation, selection, decision, and notification by considering the location of the terminal, order time, delivery time, and rider location.

Another object of the present invention is to provide a shared delivery service device in which orderer terminals are located in various locations, grouped by region, and delivery zones are set for each grouped region.

The shared delivery service device according to a preferred embodiment of the present invention controls GPS (21), touch (22), and communication unit (16), and performs one-person bundle (31), destination setting (32), and rider movement (33). ) a control unit (5) that performs; a single-person bundle (31) that groups single-person food orders and shares a destination for the grouped single-person food orders; Destination setting (32) that performs destination recommendation, selection, decision, and notification considering the location of the terminal (6), order time, delivery time, and rider location; And a rider movement 33 in which the rider collects food orders for one person, delivers the ordered food to the destination, and displays the movement route.

In addition, the destination setting 32 includes a recommendation 321 that recommends multiple destinations in consideration of the location of the terminal 6, order time, delivery time, and rider location; Selection 322 allowing duplicate selection of the terminal 6 among a plurality of recommended destinations; Decision 323 to determine the optimal destination among the overlapping destinations of the terminal 6 according to the system operation algorithm; and a notification 324 that notifies the terminal 6 of the determined destination.

In addition, an orderer terminal (6) for ordering food in the system; Business owner terminal (6) for collecting food orders; A rider terminal (43) that shares and delivers ordered food to the destination; A main server 45 that mediates the orderer terminal 6, the business owner terminal 6, and the rider terminal 43; A recommendation server 46 that performs destination recommendation, selection, decision, and notification; And a crawling server 47 that updates settings required for system access of the orderer terminal 6, the business owner terminal 6, and the rider terminal 43.

In addition, the orderer terminal 6 is located in various locations, is grouped by region, and a delivery zone 53 is set for each grouped region.

The present invention allows one person to order food by recommending, selecting, deciding, and notifying the destination by considering the location of the terminal, order time, delivery time, and rider location, and the user can order the food he or she wants to eat for delivery. You can have

In addition, in the present invention, orderer terminals are located in various locations, grouped by region, and delivery zones are set for each grouped region, so that users can have the effect of using a shared delivery service using the base delivery zone.

Figure 1 is a block diagram showing the configuration of the shared delivery service device of the present invention.
Figure 2 is an exemplary diagram showing the system configuration of the shared delivery service device in Figure 1.
Figure 3 is an example diagram showing the shared delivery operation of the shared delivery service device in Figure 1.
Figure 4 is an example diagram illustrating a configuration for verifying data errors to explain the present invention.
Figure 5 is an example diagram illustrating the hardware resources, operating system, operation of the core control unit, and system authentication configuration that grants authority to execute the control unit operation to explain the present invention.

Hereinafter, a shared delivery service device according to an embodiment of the present invention will be described in detail with reference to the drawings. Below, descriptions of previously known matters are omitted or simplified to clarify the gist of the present invention. The components included in the description of the present invention operate individually or in combination.

Figure 1 is a block diagram showing the configuration of the shared delivery service device of the present invention. Referring to Figure 1, the terminal 6 includes a GPS 21, a touch 22, a communication unit 16, a control unit 5, and one person. Includes bundling (31), destination setting (32), and rider movement (33).

The terminal 6 operates as a shared delivery service device.

The Global Positioning System (GPS) 21 receives signals sent from GPS satellites, calculates the current location of the terminal 6, and transmits the calculated location to the control unit 5 and the cloud 12.

The touch 22 is an input device that receives the location when touched by the hand. Instead of using the keyboard, when the hand touches a character or a specific location on the screen, the location is determined and input into the system.

The communication unit 16 includes a mobile communication network and the Internet, forms a communication channel between the terminal 6 and the cloud 12, and transmits data on the terminal 6 location, destination settings, and rider movement.

The control unit 5 controls the GPS 21, the touch 22, and the communication unit 16, and performs one-person bundling (31), destination setting (32), and rider movement (33).

The single-person bundle 31 groups single-person food orders and shares the destination for the grouped single-person food orders.

The destination setting 32 performs destination recommendation, selection, decision, and notification by considering the location of the terminal 6, order time, delivery time, and rider location. Recommendation 321 recommends multiple destinations considering the location, order time, delivery time, and rider location of the terminal 6, and selection 322 allows duplicate selection of the terminal 6 among the multiple recommended destinations. Decision 323 determines the optimal destination among the overlapping destinations of the terminal 6 according to the system's operation algorithm, and notification 324 notifies the terminal 6 of the determined destination.

Rider movement 33 collects food orders from one rider, delivers the ordered food to the destination, and displays the travel route.

Figure 2 is an example diagram showing the system configuration of the shared delivery service device in Figure 1. Referring to Figure 2, the orderer terminal 6 orders food in the system, the business owner terminal 6 collects the food order, and the rider The terminal 43 shares and delivers the ordered food to the destination, the main server 45 mediates the orderer terminal 6, the business owner terminal 6, and the rider terminal 43, and the recommendation server 46 recommends the destination. , performs selection, decision, and notification, and the crawling server 47 updates the settings necessary for system access of the orderer terminal 6, the business owner terminal 6, and the rider terminal 43.

The crawling server 47 uses a crawling module to extract restaurant information, menu information, and setting profiles encoded in web standards.

The crawling module includes an API (Application Programming Interface) that uses the crawling module in the control unit 5 of the crawl server 47; JSON protocol that transmits API requests to the browser driver as a URL (Uniform Resource Locator) based on JSON (JavaScript Object Notation) Wire Protocol; Includes a browser driver that receives URL commands from the JSON protocol and operates the actual browser using a script. For example, a crawling module could be a functional automation testing tool, Selenium or Cypress, and is used to write tests that mimic user behavior by controlling browser drivers.

The browser logs in to the web server according to the command of the crawling module, moves to the menu included in the web page after login authentication, and transmits restaurant information, menu information, and setting profile linked to the menu to the control unit 5.

Figure 3 is an example diagram showing the shared delivery operation of the shared delivery service device in Figure 1. Referring to Figure 3, the orderer terminal 52 is located in various locations, grouped by region, and delivery zone 53 for each grouped region. This is set. For example, the delivery zone 53 can use a goods storage area. The rider movement path 51 indicates that the rider moves between the delivery zones 53 and delivers the ordered food to the base delivery zone 53, and represents the movement path between the delivery zones 53, and the delivery zone 53 is It is determined by the selection and grouping of the orderer terminal 52.

Figure 4 is an example diagram illustrating a configuration for verifying data errors to explain the present invention.

Referring to FIG. 4, the control unit 5 stores sampling data, calculates a probability distribution by accumulating the number of occurrences for each size of the sampling data for a certain time, calculates a probability distribution for another certain time, and calculates the two probabilities. By calculating the distribution difference, area difference, and difference distance accumulation (S101), sampling circuit abnormalities, data errors, and data changes can be predicted and responded to (S102). The control unit 5 notifies the user of the prediction result so that the user can respond, or the control unit 5 can respond to hardware failure, data error, or data change.

The simple data includes the location of the terminal 6, order time, delivery time, rider location, destination recommendation, selection, decision, and notification data, and the control unit 5 is based on the sampling data to detect hardware failure, data error, etc. Respond to data changes.

The control unit 5 monitors the trend of each probability distribution for a certain period of time, predicts abnormalities in the probability distribution, responds to abnormal accidents, and reports normal operation to the outside if the data change in the probability distribution is constant. Additionally, the control unit 5 feeds back the data change rate to adjust a certain time interval. For example, if the data change rate is large, the certain time interval is increased, and if the data change rate is small, the certain time interval is shortened.

The control unit 5 executes a state machine for state transition and state processing corresponding to user manipulation and data input, and state processing performs calculation, display, vibration, and alarm, and ranges for user manipulation, data input, and random input. , time, and level input are verified, and system verification is performed according to state probability for user operation, data input, and random input. System verification includes state machine verification based on sampled data.

FIG. 5 is an exemplary diagram illustrating hardware resources and an operating system for explaining the present invention, operations of a control unit as a core, and a system authentication configuration that grants authority to execute control unit operations. Referring to FIG. 5, the present invention is a processor (1). ), memory (2), input/output device (3), operating system (4), and control unit (5).

The processor (1) is a CPU (Central Processing Unit), GPU (Graphic Processing Unit), FPGA (Field Programmable Gate Array), and NPU (Neural Processing Unit), and the operating system (4) and control unit (5) mounted on the memory (2) ) executes the execution code.

Memory (2) includes permanent mass storage devices such as random access memory (RAM), read only memory (ROM), disk drives, solid state drives (SSD), and flash memory. can do.

The input/output device 3 is an input device, such as a camera, keyboard, microphone, mouse, etc. including an audio sensor and/or image sensor, and an output device such as a display, speaker, haptic feedback device, etc. May include devices.

The operating system 4 may include Windows, Linux, IOS, virtual machines, web browsers, and interpreters, and supports tasks, threads, timer execution, scheduling, resource management, graphics, font processing, communication, etc.

The control unit 5 determines the state based on sensor, key, touch, and mouse input of the input/output device 3 with the support of the operating system 4 and performs operations according to the determined state. The control unit 5 performs job scheduling by timers and threads using parallel execution routines.

The control unit 5 determines the state using the sensor value of the input/output device 3 and performs an algorithm according to the determined state.

Referring to Figure 5, the system authentication configuration includes a terminal 6 including a control unit 5, and an authentication server 7.

The terminal 6 duplicates the data channel, receives the key value and biometric information of the terminal 6, and requests user authentication through the first data channel to the authentication server 7, and the terminal 6 receives the generated kit value. It is displayed on the display and transmitted to the authentication server (7).

The terminal 6 inputs the kit value displayed on the display of the terminal 6 and transmits it along with the user information to the authentication server 7 through the second data channel. The terminal 6 requests the authentication server 7 to authenticate the system mounted on the terminal 6 using the kit value and user information. The kit value of the terminal 6 can be generated from computer-specific information such as the CPU manufacturing number and the Ethernet chip number. The terminal 6 can obtain user information through face recognition using a camera, voice recognition using a microphone, and handwriting recognition using a display, and use it for authentication.

The authentication server 7 receives the kit value from the terminal 6, receives the kit value and user information from the terminal 6 through a duplicated data channel, compares the kit value and the user information of the terminal 6, and By matching, authentication for use of the system of the terminal 6 is processed. The authentication server 7 transmits the authentication result to the terminal 6 to authorize the user's use of the system. Due to the dual data channels of the terminal 6, kit value loss can be minimized.

The authentication server 7 performs history analysis of user information and compares and determines consistency and changes in user information over time. In history analysis, if user information shows consistency, the user's use is permitted; if it shows changes, the user's use is not permitted. By allowing users to use the system when user information shows consistency, security is strengthened to prevent users with altered user information from accessing the system.

The authentication server 7 assigns weights to consistency, change, frequency, frequency trend, and high frequency, and blocks access by untrusted users using a combination of weights. For example, if the frequency threshold is exceeded, access by untrusted users can be blocked in proportion to the accumulated number of excesses, and users who attempt access over a long period of time can be authenticated. At this time, additional authentication is requested for untrusted users.

The terminal 6, which is a means of authenticating the use of the system, does not connect directly to the system, but forms a bypass route through the authentication server 7, so that the network that makes up the Internet network is composed of an internal network and an external network, and the IP address setting process There is an advantage that the authentication process using the terminal 6 is performed smoothly in this cumbersome time. At this time, the system is mounted on the terminal 6, the terminal 6 becomes an authentication terminal means, and the authentication server 7 becomes an authentication server means.

The cloud (12) is a modularization of the container (7) with the support of the operating system (4) that manages the processor (1), memory (2), input/output device (3), and communication unit (6), and the web (8) and DB ( 9), provides the services of the protocol 10 and library 11, and the control unit 5 executes a cloud application using the services of the container 7. A standard software package, called a container (7), bundles an application's code with associated configuration files, libraries (11), and dependencies needed to run the app.

The cloud 12 integrates control of multiple terminals 6, stores sensor values received from the terminal 6, monitors them over time, processes operation errors of the terminal 6, and sends error messages to other terminals. Notifies the terminal 6, and performs switching control on the terminal 6 that is the control target.

Neural network learning selects features from time series data collected from input devices such as temperature, altitude, fingerprints, various sensors, images, infrared cameras, and lidar, selects a model through algorithm selection, and repeats through the learning and performance verification process. Model selection is repeated through trial and error. After performance verification is completed, an artificial intelligence model is selected.

The control unit 5 performs a deep learning algorithm using a neural network to determine sensor values, uses training data to learn the neural network, and verifies the neural network performance with test data.

The present invention is not limited to the specific preferred embodiments described above, and various modifications can be made by anyone skilled in the art without departing from the gist of the invention as claimed in the claims. Of course, such changes are within the scope of the claims.

1: processor
2: memory
3: Input/output device
4: Operating system
5: Control unit
6: Terminal
7: Authentication server
8: web
9: DB
11: Library
12: Cloud
14: Container
16: Department of Communications
21:GPS
22: touch
31: Bundle for 1 person
32: Destination settings
321: Recommended
322: selection
323: Decision
324: Notification
33: Rider movement

Claims (4)

A control unit (5) that controls the GPS (21), touch (22), and communication unit (16) and performs one-person bundling (31), destination setting (32), and rider movement (33);
a single-person bundle (31) that groups single-person food orders and shares a destination for the grouped single-person food orders;
Destination setting (32) that performs destination recommendation, selection, decision, and notification considering the location of the terminal (6), order time, delivery time, and rider location; and
A shared delivery service device, characterized in that it includes a rider movement (33) where the rider collects food orders for one person, delivers the ordered food to the destination, and displays the movement route. According to paragraph 1,
The destination setting (32) is,
Recommendation 321 that recommends multiple destinations considering the location of the terminal 6, order time, delivery time, and rider location;
Selection 322 allowing duplicate selection of the terminal 6 among a plurality of recommended destinations;
Decision 323 to determine the optimal destination among the overlapping destinations of the terminal 6 according to the system operation algorithm; and
A shared delivery service device comprising a notification 324 notifying the determined destination to the terminal 6. According to paragraph 1,
Orderer terminal (6) for ordering food in the system;
Business owner terminal (6) for collecting food orders;
A rider terminal (43) that shares and delivers ordered food to the destination;
A main server 45 that mediates the orderer terminal 6, the business owner terminal 6, and the rider terminal 43;
A recommendation server 46 that performs destination recommendation, selection, decision, and notification; and
A crawling server 47 that updates settings required for system access of the orderer terminal 6, the business owner terminal 6, and the rider terminal 43. Characterized in that it further comprises a shared delivery service device. According to paragraph 3,
The orderer terminal 6,
A shared delivery service device, characterized in that it is located in various locations, grouped by region, and delivery zones 53 are set for each grouped region.