KR20190013245A - Portal App Service for Providing Time-Based Information Centered on Local Area - Google Patents

Abstract

The present invention relates to a portal application service to provide time-based information centered on a local area. According to the present invention, the portal application service uses a grid for representing an event related to time and allows a user to register information on the grid through various ways, such as direct registration of a user′s event on the grid, and a predetermined user′s action, for example click, drag, and the like.

Description

Providing information according to time in the vicinity of a local area Portal app service {Providing Time-Based Information Centered on Local Area}

The present invention relates to an information providing method, and more particularly, to an information providing portal app service according to time at a local area.

 A grid is a space that visually displays time-related schedules in a given grid on a grid table divided by time, day, and date. In the prior art, when a calendar or a timetable is used in a portable device, it is common that the grid is fixed and information is provided therein. For example, in the case of a calendar, an event is described in a predetermined grid. The event here is all information related to time, including but not limited to schedule, lecture, performance, movie release date, exercise time, expiration date, etc. Of course, you can also write general information, not events.

The technical problem of the present invention is to provide an information providing portal app service based on a time zone near a local area.

According to one aspect of the present invention, an information providing portal app service is implemented according to time in a near area.

According to the present invention, an information providing portal app service is provided according to time in the vicinity of a local area.

FIG. 1 shows an example in which an event is registered in the grid.
Figure 2 shows an example of an event classified according to personality.
3 shows an example screen in which the grid is moved.
FIG. 4 shows an example of extending the grid from the 5-day view to the 7-day view through zoom-out.
5 shows an example in which the current time is displayed.
6 shows an example of registered event movement using a gesture.
7 shows an example of the detailed contents of the event provided in the present invention.
8 shows an example of data provided by the present invention.
Fig. 9 shows an example of a reduction of the grid.
10 shows an example of event registration through cell selection.

Kim, who is a service that implements part of the idea of the present invention, uses a grid for the purpose of expressing events related to this time, and a user can directly register his or her event on this grid, It can be registered in various ways such as registering through a specific action, such as clicking or dragging. This registration brings the data corresponding to the time related to the information into the storage space of the electronic device, numerically classifies the hour, minute and second of the time data, and matches the classified numerical value to the grid area and the classified data values It is used as an argument of the function expression to derive the area and position to be drawn according to the return coordinates of the result of the formula. The formula for obtaining the index is (at the start of the event to be registered, at the start of the grid) + (60 minutes of the event to register) + (3600 / second of the event to register). In one embodiment, if the time displayed on the left side of the grid is 8:00 to 16:00, the area of the grid to be displayed on the grid is divided into 8 equal parts by subtracting the screen ratio from 16:00 to 8:00, Draw a horizon along the line. (9 - 8) + (30/60) + (30/3600) at the start of the event when the start time of the event to be registered in the configured grid is 9:30:30. Then, the actual height coordinate of the registration event is calculated by multiplying the corresponding height value by 1/8 of the grid height with the index. This type of transformation effectively converts all data areas that can be spoken by a specific event or time into absolute positions on a two-dimensional plane and efficiently draws them on the grid, and calculates absolute coordinates as a ratio, the registration event area can be drawn at the same ratio in the display. Each piece of information is shared by a series of server data through the API to provide synchronized data regardless of the device and platform.

FIG. 1 shows an example in which an event is registered in the grid.

Events registered on the grid can be divided into different fields according to their purpose. For example, it can be divided into a personal schedule and a formal schedule, which can vary widely depending on the conditions. Kim, who is part of the idea of the present invention, distinguished the nature of the event according to his own method. Due to this classification method, the user can immediately grasp the nature of the event at a glance without having to check each event individually. To apply this method, the first time a user registers an event on the grid, the character string of the event title, time, location, etc. is sliced and morphological analysis is performed. Using the analytical system of Kim, the results are derived. And a unique ID is assigned to each event field according to the obtained result value. The events that are broken down by each personality are designed by introducing visual elements that can be immediately grasped by the user. There are many ways to express these visual elements, and as an example, we can express the border thickness of the registered event with a difference.

Figure 2 shows an example of an event classified according to personality.

The grid was applied dynamically, recognizing that time is always flowing. Most of the third-party calendars have a date displayed according to their presentation (weekly, monthly, etc.). When you scroll horizontally, the date of the grid is moved in a certain unit regardless of the flow of time. In other words, if horizontal scrolling is performed in the calendar grid, the weekly grid is shifted by one week in the case of the weekly grid, and the monthly grid is shifted by one month. The grid of the assistant Kim, which is a service implementing part of the idea of the present invention, can be moved in a unit desired by the user rather than being moved in a certain unit when horizontally scrolling. For example, if you move one day to the right from the weekly grid, you move one day, not weekly. This is accomplished through the following series of steps. First, the virtual horizontal area is painted dynamically on the left and right besides the grid on the display. The virtual horizontal area is a real-time area that measures the degree of horizontal scrolling of the user. First, the user measures the degree of movement by touching the grid horizontally. After the measured horizontal distance is stored, the coordinate of the x-axis of the current coordinate area is shifted by the measured horizontal distance, and the coordinate of the x-axis is converted by the entire moving distance. This effect has the effect of moving the entire x-coordinate value of all drawn objects currently displayed on the screen by the user's horizontal scrolling, resulting in the horizontally extending effect of the screen. In one embodiment, if the user touches and scrolls by 50 pixels on the display resolution of the electronic device and then stops touching, the objects drawn on the current grid screen are all moved horizontally by 50 pixels. The following formula applies to this series of processes. The calendar has Offset values for X and Y, which means the current scrolled state value. Based on this, we render the OpenGL Matrix by translating it into X, Y position. The horizontally movable range is from 1000 to 3000 years, and the function to obtain the total number of days for the date is applied as follows. (y - 1) / 4 - (y - 1) / 100 + (y - 1) / 400 + (m - 1) * 30.42f + d. Then, the index of the date / time is fetched according to the following function based on the time of initializing the calendar. f1 (y, m, d) = f0 ('initialization YEAR', 'initialization MONTH', 'initialization DAY') - f0 (y, m, d). Since the size of each electronic device is different, considering the above, we calculate the Whidth and Height values through f2 (c) = DisplayPixelWidth / c / Density and f3 (c) = min (f2 (c) * 0.9, DisplayPixelWidth / 4 / Density) do. The scrolling range of the X axis and the Y axis is implemented through the following functions. (1000, 1, 1) * f2 (number of columns) <= X <= f1 (3000,1,1) * f2 * F3 ('Number of Columns') - DisplayPixelWidth / Density). Also, since the area currently being viewed by the user needs to be drawn in a fluid and real-time manner, the area from floor (X / f2 (number of columns)) to ceiling ((X + DisplayPixelWidth / Density) / f2 Render.

 In another embodiment, the grid is moved based on a predetermined reference line automatically according to the passage of time. For example, if the day of the week falls on a Wednesday in the middle of the x-axis of the grid, Wednesday is in the middle of Sunday to Saturday, and if you move on a time-by-hour basis, One example is how the first part of Thursday comes to midnight at 0 am on Thursday. The difference is that the grid moves automatically over time, but there may be a way to move at short intervals of time and a continuous move along time. You can also move the grid to fit the user's preference. In this case, the movement of the grid is shifted according to the units fixed by the user (1 day, 2 days, 3 days, etc.) instead of 1 day.

 If you move the grid from the user's perspective and move to another date, you want to return to its original location (today's date). Accordingly, Kim, who is implementing some of the ideas of the present invention, implements the function of returning to today's date when the grid moves from today's date. The current date and its index are stored in the product in advance, and when the user takes an action to return to today's date, the value is reordered and the grid is rearranged.

3 shows an example screen in which the grid is moved.

The display of the grid through a mutual interface in which a user gives an action (touch, click, touch-drag, sensor recognition, etc.) to a digital electronic device on a grid of a teacher who implements a part of the idea of the present invention Change the unit. It calculates the degree of zoom on the interface and provides a variety of views depending on the degree of zoom calculated (the grid can be viewed in days, weeks, months, etc.) The start time, and the like, and the functions of the provided views may be different from one another. If the user takes a zoom-in / zoom-out action (touching two fingers on a digital electronic device and then widening or narrowing) that is familiar to the user in a digital electronic device, the display unit of the grid instantly switches. According to each touch action, when the gesture input is inputted by setting a value on the screen page, the display unit of the grid is changed according to the zoom level indicating the current zoom state. For this purpose, the level of zoom is standardized and the logic processed for each unit is implemented differently.

This logic is as follows. When you take a zoom in / out gesture with your finger, the module built in the electronic device (ScaleGestureDetector) brings the zoomed in / out value in proportion to the previous scale value. The function f4 (focus) = (X + focus) / f2 ('Number of Columns'), which takes the center point of two fingers that take a gesture as the zoom focus point, Apply the function f5 (scale) = DisplayPixelWidth / 4 / 'Minimum number of columns' * scale; to get the width of the zoomed area. Finally, the X offset for the scale change value is f4 ('zoom focus') * f5 ('scale') - 'zoom focus'.

FIG. 4 shows an example of extending the grid from the 5-day view to the 7-day view through zoom-out.

The unit of time is very diverse. The time unit of this schedule type mainly expresses the time on the day, week, and month basis. Kim, who is part of this idea, wants to express this unit of time in more detail. Since the unit of time used in real life is mainly hour, the concept of this time is expressed effectively on the grid. The current time is calculated on a day-by-day basis and visually implemented by the user. To apply this, the following process is performed. If the current time is included in the current viewing area, draw a line from f1 ('current') to f1 ('tomorrow'). Also, to render a special animation of the current time, the line from max (f1 (current) - X, 0) to f1 (tomorrow) is rendered and applied.

5 shows an example in which the current time is displayed.

Events registered in the grid using the user's gesture can also be moved. Long touch-drag and drop action (an example of multiple gestures) (long touch and drag and drop) comes in. In order to distinguish long touch from scroll touch, first define long touch threshold, Is less than the threshold, it is judged to be a long click. Then find the absolute position of the current action in the display resolution of the digital electronic device. Absolute position can be obtained through an API provided on the system logic of the electronic device. Then, the index is determined as to which portion of the grid is divided by the horizontal and vertical axes according to the current time and day. To obtain the index, obtain the vertical and horizontal distances equal to a predetermined multiple of the number of hours of the new axis or the number of days of the week on the horizontal axis, find a certain multiple including the coordinates of the touched region, . Since the stored events have index values representing time on the coordinate plane, an event having a numerical value including the index of the currently touched area is found in reverse. When a rectangular area of the event is found, the rectangular area is again dynamically drawn, and the rectangular area is drawn again in real time according to the degree of movement of the event by scrolling after the long touch. If the touch is stopped after moving the scroll with the long touch, the position of the interruption is also obtained. The index of the horizontal and vertical of the event is updated. Then, the boxed event is drawn again at that point and the information stored in the DB is also updated. In this way, you can move the event to the desired location. The moved event preserves the existing information and only changes the time information according to the newly located location. When the selected event is moved to a new position, it moves on the grid consisting of time. Magnetic is a programmatic technique in which a selected object does not move randomly in space but an object selected by a preset unit moves in accordance with the unit.

6 shows an example of registered event movement using a gesture.

The detailed contents are the information corresponding to the events registered in the grid. For example, if the event registered in the grid is a specific time, a specific schedule, or a specific class (a specific course in the class schedule), click on the event and the detailed contents will be displayed. You can add / modify data. The various information mentioned here basically provides detailed information about the event, and also provides a multi-star rating and a community space that can be used to score the effectiveness of the event. In addition, through the photo memo, a personal management space is provided to permanently leave the event. Rating and walls can be used only by individuals, but they can be shared with many unspecified persons and exchange information in both directions.

 For example, the information provided by Kim, a service that implements a part of the idea of the present invention, is created by making a string of 'year + month + day + hour + minute + place' . Many users who have registered these events in the grid are automatically recognized as the same group, and they can share the ratings and the walks in the detailed contents of the event in real time. The ability for users to score, upload, and collect photos, text, and files for an event is a key to collecting and analyzing various information about events through the data collection of collective intelligence of users. Based on these data, the event plays an independent community role for each one and provides more valuable information based on the accumulated data. The user is provided with an experience in which one schedule is recognized as one community based on various information of users provided for one event.

  It also allows users to create an event themselves and share it only with a specific person to use the wall. These events are introduced by introducing the concept of sharing to make the event unique ID. If the creator and the target agree on the shared event, the event is automatically registered to the target and grouped so that the real time can use the wall.

 When new news or a certain time comes to such an event, it can induce communication by triggering a sentence according to each personality by using a bot of a wall. A bot is a program that automatically finds or behaves according to a given command. When triggering the sentence, the natural language is analyzed through the Recurrent Neural Network for the time series data after natural language preprocessing, and processed into meaningful data and matched with the trigger of the corresponding information. At this time, the natural language learns the meaning through learning about the informal data, and matches the meaning of the natural language with the data related to the language processing.

In order to perform such a trigger, various types of events are DB and classified according to each criterion (personality, purpose, user age group, etc.), and a triggering sentence corresponding thereto is provided.

The information that is input to the detailed contents is stored in the DB and distributedly stored in each node. In the future, the data is collected, maps, and redesced, and the data is processed as intended to reproduce meaningful information I'll do it.

Such recycling is organized in DB for each piece of information input from a plurality of digital electronic devices, and when a specific user needs specific information, the user can use the result displayed after searching in the DB.

FIG. 7 shows an example of the detailed contents of the event provided by Kim.

Kim, who has implemented a part of the idea of the present invention, processes and provides information on his own. This information is configured to allow time-related information to be registered on the grid. This information can be applied to various fields if they are related to time. As an example, we provide university enrollment data. The college's attendance data is one of the information that consists of time. This information is divided into the key value (tiem, place, display, additonal, etc.) The processed data can be selected by the user and registered directly on the grid.

Fig. 8 shows an example of data provided by Kim.

In existing calendars, if you provide information on your own, part of the grid will inevitably be hidden to show information. It is not possible to use more than 1/3 of the area of existing grid to show grid and information at the same time. Kim, who implements part of the idea of the present invention, presented this problem through a new approach. When Kim provided his own information, he did not divide the grid and the area but narrowed down the entire grid area to express all the areas that were previously hidden. You can also zoom in or out on a grid that was collapsed while the user was typing information into the grid. It can scale the grid by using the zoom key, by a specific touch, or by a user's specific action. In one embodiment, when the grid is enlarged by the user, the value of how much it is enlarged by using the touch Delta value is calculated and adjusted to a size suitable for the enlargement. The touch Delta value refers to the distance traveled from a location where a point is touched in a digital electronic device. This reduces the margin of the grid window by the touch Delta value. Conversely, the same principle applies when shrinking by a user. In particular, it is possible to check whether the information selected by the enlarged grid has been correctly input at the originally intended date or time. In one embodiment, the reduced grid shows about one-sixth the size of the entire screen. In some cases, the size of the grid can be adjusted appropriately.

Fig. 9 shows an example of a reduction of the grid.

In order to register an event in the existing calendar format, an item of time is required, and the user inputs this item directly. In this way, existing products are forced to provide an inconvenient interface to the user. Kim, who is part of the idea of the present invention, introduced visual elements in the process of inputting time items. Since the item of time is represented on the grid, the user can simply register the event by one-touching the position of the desired time on the grid. This works in accordance with the following principles. This function implements a function to obtain Matrix X and Y Offset of the touched cell. This function is expressed as: f6 (t) = X + t / Density, f7 (t) = Y + t / Density. (T) = floor (f6 (t) / f2 (number of columns)) + f1 (1970, 1, 1) ).

10 shows an example of event registration through cell selection.

Yet another embodiment implements the function of reading a calendar (timetable) of the day inputted in a calendar or a timetable (grid) when a specific condition is established at a specific time in a calendar function or a timetable function. For example, if an alarm is set at a specific time (eg, 6:00 am), the user can set the schedule to be activated immediately after the alarm is stopped or after a certain period of time (eg after 5 seconds or after 20 seconds) You can provide them. In another embodiment, when the alarm is not set, the mobile phone recognizes that the user is awake or the user can recognize the voice, or a certain time after recognizing the voice, You can provide them. For example, if the user is awake or the user is able to recognize the voice, for example, if the mobile phone is not moving for a certain period of time during the night, then it is assumed that the user wakes up and uses the mobile phone . That is, in one embodiment, if the motion recognition sensor of the mobile phone does not sense the movement of the mobile phone for at least 4 hours at 4:00 am and the sensor senses the movement of the mobile phone for the first time after 4:00 am, It can be assumed that the state is capable of recognizing the voice. In this case, you can provide the day's schedule regardless of whether the user views or uses the calendar immediately after the sense or after a certain time (after 5 seconds, or 20 seconds, etc.).

In another embodiment, when a deadline is set for a schedule, the number of days remaining at a specific position at the top is calculated and displayed. In other words, all of the events that have a deadline are displayed at the specified position in the upper part, and the event that the deadline is set by the rotation method is provided. Deadline deadline is excluded from the above rotation.

Claims (1)

Providing information over time, near the local area Portal app service.

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