KR102001785B1 - the method of changing GPS coordinates to AIM coordinates - Google Patents

Abstract

이고,
m은 최대값 수열을 나타내며,
a는 실제 변환될 초 값 수열을 나타내며,
n은 수열의 크기를 나타냄]
또한 본 발명은 상기한 GPS 좌표를 AIM 좌표로 변환하는 방법을 포함하고,
AIM 좌표 값을 10진수 순서 값으로 산출하는 과정(제7과정),
10진수로 변환된 순서 값을 도분초좌표 값으로 산출하는 과정(제8과정),
상기한 과정에서 산출된 좌표값 수열에서 위도 초 순서값과 경도 초 순서값을 실제 위도 초 값인 소수점 값으로 변환하는 과정(제9과정),
상기의 과정에서 구한 도분초 좌표 값 수열을 문자열로 변환하는 과정(제11과정),
을 포함하여 이루어진 변환된 AIM 좌표를 GPS 좌표로 다시 변환하는 방법을 제공한다.The present invention relates to a method for displaying coordinates of a map. In particular, the present invention relates to a method for converting GPS coordinates into AIM coordinates that reduces the conventional GPS coordinates to a minimum length.
The present invention relates to a process for digitizing the coordinate values of GPS coordinates (first process)
(Step 2) of obtaining the index value of the seconds value from the decelerated coordinate values,
The order value of the seconds value obtained from the above is a coordinate value converted into the order value by replacing the latitude second order value and the longitude second order value with the latitude second value and the longitude second value by the latitude second order value and the longitude second order value, (Third process),
A fourth step of calculating a coordinate value converted into the order value by a decimal order value,
(Step 5) of calculating the nine-character coordinate value of the decimal order value obtained as described above,
(Step 6) of forming the calculated nine-character coordinate value into an encoding coordinate value,
To an AIM coordinate system.
Further, the present invention is characterized in that the process of obtaining the index value of the seconds value (the second process)
The second and first longitude values are decimated with the decimated coordinate values (second process-1)
In the process (1-1 of the second process) of performing the numerical deterioration of the second value from the decelerated coordinate values,
(1-1-1 of the second process) of forming a first-order numerical deterioration in which the number of decimal places before the decimal point and the number after the decimal point are described in order,
(1-1-2 of the second step) of completing the numerical deterioration describing the first-order water-deteriorated seconds value formed in the above-described manner in reverse order,
(1-1-3 of the second process), and the process of completing the hydrothermal decomposition by a method of describing the above-mentioned first-order water deterioration value in reverse order,
(Step 1-1-4 of the second process) of forming the numerical deterioration with respect to the maximum value for each sequence of the completed numerical aperture,
The process of calculating the order value of the second value (1-1-5 of the second process)
The process of obtaining the ordinal value of the second value from the decelerated coordinate values (1-2 in the second process)
(1-2-1 of the second step) of forming a primary water deterioration in which the number of decimal points before the decimal point and the number of decimal points after the decimal point are described in order,
(1-2-2 of the second step) of completing the numerical deterioration in which the first-order water-deteriorated second value formed in the above-described manner is described in reverse order,
(1-2-3 of the second process), and the process of completing the hydrothermal decomposition by a method of describing the above-mentioned first-order water-deteriorated second value in reverse order,
(Step 1-2-4 of the second process) of forming the numerical deterioration with respect to the maximum value for each sequence of the completed numerical aperture,
The process of calculating the order value of the second value (1-2-5 of the second process)
And converting the GPS coordinates into AIM coordinates.
Further, the present invention is characterized in that a process of calculating a coordinate value converted into the ordinal value as a decimal ordinal value (fourth process)
A process of forming a maximum value sequence of transformed coordinate values (fourth process-1),
(Step 4) of calculating a decimal order value of the minute coordinate value by substituting the maximum value sequence obtained in the above equation (2) into the AIM coordinates . ≪ / RTI >
[Equation 2]

ego,
m represents a maximum value sequence,
a represents the second value sequence to be actually converted,
n represents the size of the sequence]
The present invention also includes a method for converting the GPS coordinates into AIM coordinates,
(Step 7) of calculating the AIM coordinate value as a decimal order value,
(Step 8) of calculating a sequence value converted into a decimal number as a fractional coordinate value,
The ninth step of converting the latitude second order value and the longitude second order value into a decimal value which is an actual latitude second value in the coordinate value sequence calculated in the above process,
(Step 11) of transforming the localized coordinate value sequence obtained in the above process into a character string,
And converting the converted AIM coordinates into GPS coordinates.

Description

How to convert GPS coordinates to AIM coordinates {the method of changing GPS coordinates to AIM coordinates}

The present invention relates to a method for displaying coordinates of a map. In particular, the present invention relates to a method for converting GPS coordinates into AIM coordinates that reduces the conventional GPS coordinates to a minimum length.

People have long since created a map of the topography of the area and then created an Index Map that allows you to navigate to that location by numbering or typing a specific location on the map, We are using the Military Grid Reference System (MGRS), which grids the grid and continues to narrow down the grid and use the grid numbers as coordinates.

We usually use addresses when we need to tell any location by text or voice, but we rarely use coordinates.

The reason for this is that the GPS coordinates become longer as the position information becomes more precise, and the GPS coordinates can be displayed most accurately when displaying any position, but they are disadvantageous in that they are long in length and are inconvenient for people writing or inputting. (In the case of MGRS coordinates, a 15-character area code and 10-character coordinate number are required.)

In general, the coordinates on the earth are obtained by using GPS (Ground Positioning System) satellite to obtain their latitude and longitude coordinates. The latitude and longitude coordinates are obtained by dividing the left and right sides of the earth from 360 degrees to 180 degrees and 180 degrees and 180 degrees. WGS84, which is represented by degrees and minus degrees (degrees) - minutes (minutes) - seconds (degrees), expressed as a decimal point, is also called longitude and latitude coordinates by combining the longitude value and the latitude value when divided by 90 degrees. (Degrees) coordinates, and there are about 27 characters for the minute coordinates and 18 coordinates for the degrees (when the accuracy is 3m).

One of the characteristics of the latitude and longitude coordinates is that the accuracy of coordinates increases as the length of the coordinates increases. WGS84-based coordinates are used to represent these latitude and longitude coordinates. WGS84-based coordinates are used to represent general latitude and longitude coordinates. However, if more precision is required, WGS84-based coordinates Coordinates are mainly used.

A registered patent (No. 10-1105425, method of displaying the GPS coordinate position in the design drawing) is related to the above related art, and it is described in a step of creating a design drawing (S1) for digitizing surrounding feature and construction information using a Bessel coordinate system, A design drawing input step (S2) for inputting the created design drawing to a terminal, a GPS signal reception step (S3) for receiving a coordinate position from the satellite, a signal conversion step (S4) for converting the received coordinate position to vessel coordinates, An error correction step S4 'for correcting an error generated when the position is converted into the vessel coordinate, a design drawing searching step S5 for finding a design drawing corresponding to the converted vessel coordinate, A design drawing outputting step (S6) for outputting the design coordinate to the design drawing (S6) for outputting the coordinate position and a coordinate position displaying step (S7) for displaying the coordinate position on the output design drawing .

Although the conventional GPS coordinates (latitude and longitude coordinates) can be used to specify any position precisely anywhere, there is a problem that the length of the coordinates is from 27 to 18, which makes it difficult for a person to write or speak.

Thus, although addresses are universally used, addresses can not specify all locations,

The address does not specify all locations that are not closely connected with the road or building because it specifies the position of the road or building. This means that it can be easily used by ordinary people in emergencies such as human accidents, The use of coordinates is increasing every day because it leads to the absence of a location information representation system.

Basically, the reason for writing the numbers of the latitude and longitude coordinates is to add a number under the decimal point to increase the accuracy of the coordinates. Although these decimal numbers allow a person to understand the estimation process of the coordinates, There is a problem that it is very difficult for a person to understand.

Accordingly, the present invention is an improvement of the above-described conventional GPS coordinates (latitude and longitude coordinates) display method. It is an object of the present invention to provide a high accuracy We propose a high precision coordinate system or a coordinate transformation method which solves the problem of long length of coordinates and provide AIM (Arithmetic Index Map) coordinate system which minimizes GPS coordinate length.

In addition, the present invention provides a method of converting GPS coordinates, which can be represented by about 9 characters, to AIM coordinates, which is about 27 characters when the accuracy is 3m with conventional GPS coordinates (coordinate of coordinates).

The present invention relates to a process for digitizing the coordinate values of GPS coordinates (first process)

(Step 2) of obtaining the index value of the seconds value from the decelerated coordinate values,

The order value of the seconds value obtained from the above is a coordinate value converted into the order value by replacing the latitude second order value and the longitude second order value with the latitude second value and the longitude second value by the latitude second order value and the longitude second order value, (Third process),

A fourth step of calculating a coordinate value converted into the order value by a decimal order value,

(Step 5) of calculating the nine-character coordinate value of the decimal order value obtained as described above,

(Step 6) of forming the calculated nine-character coordinate value into an encoding coordinate value,

To an AIM coordinate system.

Further, the present invention is characterized in that the process of obtaining the index value of the seconds value (the second process)

The second and first longitude values are decimated with the decimated coordinate values (second process-1)

In the process (1-1 of the second process) of performing the numerical deterioration of the second value from the decelerated coordinate values,

(1-1-1 of the second process) of forming a first-order numerical deterioration in which the number of decimal places before the decimal point and the number after the decimal point are described in order,

(1-1-2 of the second step) of completing the numerical deterioration describing the first-order water-deteriorated seconds value formed in the above-described manner in reverse order,

(1-1-3 of the second process), and the process of completing the hydrothermal decomposition by a method of describing the above-mentioned first-order water deterioration value in reverse order,

(Step 1-1-4 of the second process) of forming the numerical deterioration with respect to the maximum value for each sequence of the completed numerical aperture,

The process of calculating the order value of the second value (1-1-5 of the second process)

The process of obtaining the ordinal value of the second value from the decelerated coordinate values (1-2 in the second process)

(1-2-1 of the second step) of forming a primary water deterioration in which the number of decimal points before the decimal point and the number of decimal points after the decimal point are described in order,

(1-2-2 of the second step) of completing the numerical deterioration in which the first-order water-deteriorated second value formed in the above-described manner is described in reverse order,

(1-2-3 of the second process), and the process of completing the hydrothermal decomposition by a method of describing the above-mentioned first-order water-deteriorated second value in reverse order,

(Step 1-2-4 of the second process) of forming the numerical deterioration with respect to the maximum value for each sequence of the completed numerical aperture,

The process of calculating the order value of the second value (1-2-5 of the second process)

And converting the GPS coordinates into AIM coordinates.

Further, the present invention is characterized in that a process of calculating a coordinate value converted into the ordinal value as a decimal ordinal value (fourth process)

A process of forming a maximum value sequence of transformed coordinate values (fourth process-1),

(Step 4) of calculating a decimal order value of the minute coordinate value by substituting the maximum value sequence obtained in the above equation (2) into the AIM coordinates . ≪ / RTI >

[Equation 2]

ego,

m represents a maximum value sequence,

a represents the second value sequence to be actually converted,

n represents the size of the sequence,

c means zero maintenance method (c = 0 when applied, c = 1 when not applied).

The present invention also includes a method for converting the GPS coordinates into AIM coordinates,

(Step 7) of calculating the AIM coordinate value as a decimal order value,

(Step 8) of calculating a sequence value converted into a decimal number as a fractional coordinate value,

The ninth step of converting the latitude second order value and the longitude second order value into a decimal value which is an actual latitude second value in the coordinate value sequence calculated in the above process,

(Step 11) of transforming the localized coordinate value sequence obtained in the above process into a character string,

And converting the converted AIM coordinates into GPS coordinates.

Conventional GPS coordinates (map coordinates) indicate that geographical information is about 27 characters when the accuracy is 3m, and WGS84 requires about 18 characters, which causes inconvenience to users in coordinate display and also requires geographical information that requires higher accuracy It was difficult to display,

The AIM coordinates according to the method of converting the GPS coordinates to the AIM coordinates according to the present invention show the same accuracy (3m of suspension), and can be displayed in a reduced number of nine letters, so that the convenience of use is improved. In addition, The display can be markedly reduced so that the accuracy of the coordinates is remarkably increased.

In addition, if the AIM coordinates according to the present invention are applied to the private sector, it is possible to make a logistics system (courier, mail) arriving at a precision of 3 m anywhere in the world if only 9 letters are small, For foreigners who do not know, you can make a tour booklet that tells you exactly where you are, with nine letters shorter than your phone number. You can write your name card in front of your desk in your office card, It is possible to implement navigation app UX and UX app UX that can navigate with precision, and even if local shops and shops are not easily located (eg, in front of exit 3 of subway OO) By precisely delineating the location, potential customers can easily memorize and navigate the location of the mall, And GPS necklaces with AIM coordinates to help the police structure, or to help the poor countries that do not have an address system.

In addition, the AIM coordinates according to the present invention provide an opportunity to synergy with the local economy and create greater value when the new and useful coordinate system, which can be easily used by people, is distributed to people.

In addition, when people get the AIM coordinate system, which is a high-precision global coordinate system, it is possible to do a lot of things that were not possible before, that is, when the AIM coordinate system makes it possible to arrange 9 letters anywhere on the earth, For those who live far away from each other, the earth can be geographically geographically localized so that it does not seem to be far from each other, just like a narrower place. It is a hope for the poor people living in harsh areas that do not have addresses, To people in the middle of the sea who need to go to a country that uses a language I do not know, to those who need rescue in crime and disaster situations, Which is beneficial for tourists visiting the city.

By using the AIM coordinate system according to the present invention, it is possible to enhance the operational linkage in the ROK-US Alliance by applying the AIM coordinate system, which is a digital coordinate system, not the analog MGRS coordinate system using different maps, The AIM coordinates can be utilized effectively when the coordinates are used as voice or essay.

[ AIM coordinates  Yes]

1. It is possible to construct a geographical coordinate information system for supporting special operations forces that can transfer the geographical coordinate information within a maximum operation radius of 21.6km with a precision of 2 ~ 5 coordinates within 1 ~ 2 seconds through voice at high speed,

2. Geo-coordinate information system for the support of ROK Armed Forces Command, which enables high-speed exchange of geographical coordinate information within the entire Korean Peninsula through the voice at a high speed within 6 to 7 seconds,

3. It is possible to send and receive geographical coordinate information with 3m accuracy to the world within 3 ~ 5 sec by using 9 coordinates only, and it is possible to put altitude information and range information in coordinates with short and various precision. To be able to build a geographic coordinate information system for the Navy.

1 shows a general GPS coordinate display system.
FIG. 2 is a view showing a military grid reference system (MGRS) used in the military. FIG.
FIG. 2B is a view for explaining a military grid reference system (MGRS) used in the military. FIG.
3 is a diagram illustrating an effect of the AIM coordinate display system according to the present invention.
FIG. 3B is a diagram showing variable precision of the AIM coordinate display system according to the present invention; FIG.
3C is a diagram illustrating a maximum altitude of the AIM coordinate display system according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings.

The present invention provides a method for converting GPS coordinates to AIM coordinates.

The present invention may be embodied in a general method, or may be embodied in a computer program or an application program which is equipped with hardware.

In general, the coordinates on the earth are obtained by using GPS (Ground Positioning System) satellite to obtain their latitude and longitude coordinates. The latitude and longitude coordinates are obtained by dividing the left and right sides of the earth from 360 degrees to 180 degrees and 180 degrees and 180 degrees. When dividing by 90 degrees, this longitude value and the latitude value are combined and referred to as the latitude and longitude coordinates, and the degree and latitude degrees are expressed in degrees (degrees) - (minutes) - seconds (seconds). WGS84 coordinates There are about 27 characters in the minute coordinates and about 18 characters in the WGS84 coordinates. (When accuracy is 3m)

One of the characteristics of the latitude and longitude coordinates is that the accuracy of coordinates increases as the length of the coordinates increases. WGS84 (WGS84) and Coordinates (WGS84) are used for the coordinates of the latitude and longitude coordinates. However, if more precision is required, WGS84 (WGS84 coordinates) and Coordinates are used.

As shown in Fig. 1, an example in which the coordinates on the earth are expressed in 3m accuracy,

In the case of the minute coordinates, it is displayed as "36 degrees 28 minutes 39.5 seconds east longitude, 137 degrees 11 minutes 13.7 degrees north latitude", and is displayed as a total of 27 letters ("space", " And "." Is recognized as a letter).

In addition, the WGS84 coordinates that express the decompression coordinates are expressed as "36.27189, 137.58247" in the case of "36.77 minutes 19.7 seconds in east longitude, 137.78 degrees in 24.7 degrees in north latitude".

In this way, the GPS coordinates can be displayed most accurately when a certain position is displayed, but the GPS coordinates have a long length, which is disadvantageous for a person to write or to speak.

That is, it is about 27 to 18 characters, so we mainly use addresses rather than coordinates.

As shown in FIG. 2 and FIG. 2B, the military uses the so-called Military Grid Reference System (MGRS), in which the grids are largely laid out on a globe, The system has different merits from the latitude and longitude coordinates, but it has the advantage that the calculation method of the coordinates is very easy.

For example, in the case of MGRS coordinates, the local-area code number is 52N, the compartment number is 23, and the stair number is 4263135412. It reaches 15 characters.

However, in the case of a unit having an area of activity only within the area, it is possible to call the stair number without calling the 5-digit area code separately, so it is possible to operate 1M coordinates in a specific area with only 10 characters. However, this is limited to only within the area, and if it goes out of the area, it becomes 15 again.

Also, when the Korean peninsula should be represented, the regional map numbers are different. To express the coordinates across the peninsula, the coordinates should be expressed in four parts on the Korean peninsula.

However, by using the AIM coordinates of the present invention, it is possible to express coordinate values for the entire world, not only the entire Korean peninsula by only nine characters, and designate a specific position on the Korean Peninsula as a center value, It is possible to extract and operate the coordinates efficiently.

The AIM coordinates of the present invention are the coordinates of the Arithmetic Index Map which, beyond the direct indexing of such maps, help to index all parts of the map arithmetically without reference to the AIM It is called coordinates.

Although the existing coordinates represent the coordinate values more precisely and the convenience of the measurement method of the coordinates is mainly made, the AIM coordinates aim to maintain the precision while reducing the length of the coordinates based on the latitude and the longitude coordinates.

It is necessary for the address to understand the place name based on the history of the area, but it can be understood by the person that the calculation of the latitude and longitude coordinates measured by the electronic device is not for the convenience of the person, The process of calculation can be understood, but it is very difficult for a person to know the exact position of the coordinates only by the coordinates.

In order to understand the surveying process, the length of coordinates is not from 18 to 27, but rather than concentrating on human understanding of coordinates, it is more convenient for modern people, It can be seen that

As described above, the AIM coordinates of the present invention allow variable precision to be applied to various kinds of coordinates, which means that emphasis is placed on shortening the length of the coordinate system rather than the human understanding.

As described above, by using such GPS coordinates (latitude and longitude coordinates), it is possible to specify any position exactly at any position, but there is a problem that the length of the coordinates is from 27 to 18, which is very difficult for a person to write or speak.

Therefore, although the address is commonly used, the address can not specify all the locations, and the address can not specify all the locations that are not close to the road or building because the location of the road or the building is specified. In the case of emergencies such as human accidents involving mountainous or marine structures, the use of coordinate information has become increasingly necessary because it has led to the absence of a location information expression system that can be easily used by ordinary people.

Basically, the reason for writing the numbers of the latitude and longitude coordinates is to add a number under the decimal point to increase the accuracy of the coordinates. Although these decimal numbers allow a person to understand the estimation process of the coordinates, It is very difficult for a person to understand.

In other words, it is important to solve the long-length problem of high-precision coordinates, which is the most stumbling block in current people's use of coordinates, rather than making it easier for people to understand the calculation process of coordinates. The "AIM (Arithmetic Index Map) coordinates" that minimize the length of the "GPS coordinates" are AIM coordinates that can be displayed in fractional coordinates (with a precision of 3 meters) And performs the function of maintaining the precision as it is.

Such AIM coordinates are lossless compressed and have a shorter effect than the cell phone number 11 digits [010-XXXX-XXXX].

[Variable precision and maximum altitude of AIM coordinates]

The AIM coordinates can express the accuracy of each of the lengths with different accuracy. The 9-character accuracy is 3m, and the 12-character accuracy can be expressed in 10-degree coordinates on the street. In addition, AIM coordinates can include altitude information in coordinates, and altitude can also include altitude with different accuracy for each length.

As described above, in the case of a 1-digit decimal point, the accuracy is 3 m, and if the decimal point is 5 digits, the accuracy is 300 μm.

However, as described above, in order to display the generalized second coordinates, it is also expressed in GPS coordinates even in the case of expressing from second unit to 1 decimal point. Even when the minute coordinate length is about 27 characters and the coordinates are used, about 18 It is very uncomfortable to use because it is too long in length.

The AIM coordinate system of the present invention has a coordinate system using a hexadecimal number and can represent one decimal place of the decimal point by nine digits and can represent 13 digits when the decimal point is five decimal places The convenience of expression and use is significantly improved.

As shown in FIG. 3, the GPS coordinates are displayed as 27 characters when the longitude is 36 degrees 28 minutes and 39.5 seconds and the North coordinates are 137 degrees 11 minutes and 13.7 seconds. On the other hand, when using the AIM coordinates of the present invention, The effect of being displayed in nine letters is displayed.

The following shows an example of comparing efficiency by coordinate system in case of coordinates representing 1-digit accuracy of decimal point of minute coordinates.

DMS: 39 ° 21'11.2 '' N 127 ° 20'29.7 '' (26 characters)

WGS84: 39.3531111 °, 127.3415833 ° (24 characters)

DM: 39 ° 21.18667 ', 127 ° 20.49500' (26 characters)

MGRS: 52SCJ 5710757274 (15 characters)

Maidenhead: DM39QI04XR79 (12 characters)

GEOREF: WIHK20492118 (12 characters)

UTM: 52S 357107mE 4357274mN (20 characters)

UTM centimeter: 52s 357107.35mE 4357274.41mN (26 characters)

AIM Coordinates: AX0 27L TXI (9 characters)

As shown above, the AIM coordinates of the present invention have the effect of remarkably improving the convenience of expression and use as compared with other coordinate systems.

The following shows the range of the variable precision of the AIM coordinates and the maximum altitude range of the AIM coordinates.

[Variable precision range of AIM coordinates] (* DMS range is an example)

4 characters [expressible range: 180 degrees 360 degrees] [Accuracy: about 300km]

5 characters [expressible range: 180 degrees 6 minutes 360 degrees 6 minutes] [accuracy: about 30km]

6 characters [Expression range: 180 degrees 60 minutes 360 degrees 60 minutes] [Accuracy: about 3km]

7 characters [Expression range: 180 degrees 60 minutes 6 seconds 360 degrees 60 minutes 6 seconds] [Accuracy: about 300m]

8 characters [Expression range: 180 degrees 60 minutes 60 seconds 360 degrees 60 minutes 60 seconds] [Accuracy: about 30m]

9 characters [Expression range: 180 degrees 60 minutes 600 seconds 360 degrees 60 minutes 600 seconds] [Accuracy: 3m]

11 characters [Expression range: 180 degrees 60 minutes 6000 seconds 360 degrees 60 minutes 6000 seconds] [Accuracy: about 30cm]

12 characters [Expression range: 180 degrees 60 minutes 60000 seconds 360 degrees 60 minutes 60000 seconds] [Accuracy: about 3cm]

13 characters [Expression range: 180 degrees 60 minutes 600,000 seconds 360 degrees 60 minutes 600,000 seconds] [Accuracy: about 3mm]

15 characters [expressible range: 180 degrees 60 minutes 000000 seconds 360 degrees 60 minutes 6000000 seconds] [accuracy: about 300μm]

[Maximum altitude range of AIM coordinates]

1 character [expressible range: 0 ~ 35 meters] [altitude notation: m]

2 characters [Expression range: 0 ~ 1,295 meters] [Altitude notation: m]

3 characters [Expression range: 0 ~ 46,655 cm (maximum 466M)] [Altitude notation: cm]

4 characters [Expression range: 0 ~ 1,679,615 millimeters (maximum 1.6km)] [altitude notation: mm]

5 characters [Expression range: 0 ~ 60,466,176 cm (maximum 604 km)] [Altitude notation: cm]

6 characters [Expression range: -1,088,391,168 ~ 1,088,391,168 centimeters (maximum 10,000 kilometers)] [Altitude notation: cm]

7 characters [Expression range: -39,182,082,048 ~ 39,182,082,048 cm (maximum 390 thousand km)] [Altitude notation: cm]

8 characters [Expression range: 0 ~ 2,821,109,907,456 cm (maximum 28.2 million km)] [Altitude notation: cm]

9 characters [Expression range: 0 ~ 101,559,956,668,416 meters (maximum 10 billion kilometers)] [Altitude notation: m]

The AIM elevation notation can be written in the same way as the AG9 G8C DL4 / 46N, with a / (slash) followed by the AIM coordinates and the corresponding AIM elevation. (AIM coordinates can be separated by putting a "-" between coordinates like phone numbers, or vice versa.)

The present invention provides a method for converting GPS coordinates to AIM coordinates.

In the map, 0.1 s is 3 m, 1 s is 30 m, 1 s is 1.8 km, and 1 s is 108 km.

In general, in degrees, the degree is expressed in degrees in Minute, and in Second, but it can be expressed in other forms as well.

The AIM coordinates of the present invention are not the decimal system used in the existing coordinate system and the lattice coordinates of the MGRS.

In addition, the AIM coordinates of the present invention are generally expressed in 36-ary method, but are not limited to, but are expressed in more than 11 decimal notation, and are also based on minute coordinates.

In addition, the AIM coordinates of the present invention are designed to represent 36-valued coordinates differently for each language according to the embodiment, and the coordinates of each language are compatible with each other.

In this case, the character value list (encoding list) of the 36-ary method that can be used according to each language can be expressed as in the following embodiment.

The following list of encodings is a value indicating the corresponding value from 0 to 35.

[English 36 Encoding List]

6 (6), 7 (7), 8 (8), 9 (9), 3 (3) A (10), B (11), C (12), D (13), E (14), F (15), G (16) (27), S (28), T (29), K (20), L (21), M (22) U (30), V (31), W (32), X (33), Y (34)

* The value corresponding to the number in parentheses above is the number outside parentheses.

The following abbreviates the numbers in parentheses.

[Korean 36 Encoding List]

The ball is three and a half and the arm is the Kana Nada.

[List of Japanese 36 Encoding Encoding]

Mo mo ya ya yu yo yo wa wa rai ri ri ru re re ro ro ka kiki ku ke ko ko sa sa su se se so ta ta te to na na ni nu nu Ne no no ha ha hi to hu he ho ho ma ma mi mi mu me me

[Encoding conversion example]

AX0 27L TXI

= Kamui ball is a chiltedo

= Kamimayuri and Fumio

That is, the AIM coordinates of the present invention are implemented so that each of the three countries of the United States can display the same nine-letter coordinate system according to their own pronunciation method and the letters of their own country. If only the order of 36 letters of each country is known It is also very easy to convert to another language.

The reason for this coordinate system is that if the AIM coordinate system in Korea is to be used for police or military purposes, it should be a coordinate system that can be read by elderly people, children, or soldiers who are not familiar with English.

In addition, if English encoding is used, it is unlikely to be good for pronunciation in other languages.

The 36-ary encoding method described above can be expressed in various forms according to a user's request and setting.

Therefore, in the present invention, the 36-ary encoding method may be preset in various forms.

Also, in the present invention, a series composed of a mixture of several water bodies is referred to as a 'complex water series'. In ordinary life, a large number of people is represented by using multiple decimal numbers. The time expression is also a kind of 'complex decimal number', which expresses time in 24 digits and minutes and seconds in 60s. A total of 86,400 cases It is expressed using a combination of multiple digits to represent it.

Conversion between a complex number sequence and a decimal number can be easily done, but when calculating a decimal number as a complex number, the conventional calculation method simply calculates the division number so that the most recent complex number value .

In other words, when 86,400 is 23:59:59, to find out what time the number 86,400 is, you need to calculate that the number means 59 seconds 59 minutes.

However, when dealing with coordinates, the last digit is too precise, so it does not matter, and you need to get the first numbers first. That is, a left-to-right calculation method is required for calculating coordinates, not a conventional right-to-left calculation method.

In addition, all numerical systems do not fully utilize the case number of the corresponding case when expressing a sequence with a sequence. When the length of a sequence is more than 2 letters, when the number 0 is at the beginning of the sequence, It is not assumed when expressing.

This is a repair method for when the sequence length can not be variably represented. It is regarded that 1, 01, 001 and 0001 are all indicating the same order. In the present invention, this phenomenon is referred to as a "0 repair method".

In order to make full use of complex conjugation, it is necessary to calculate a 'complete complement sequence' which does not apply the zero-complement method to maximize the number of complex conjugations.

The present invention provides a method for calculating a complementary complex number sequence calculated in a left-to-right direction when a complex number sequence is converted to a decimal number sequence.

The present invention first carries out the process of decimating the coordinate values of the GPS coordinates (Step 1)

The meaning of the above-mentioned water deterioration process means that the fountain coordinate values are transformed into a numerical form and formed into a matrix form.

For example, if the coordinates of the figure used are the following,

"Latitude: 39 degrees 21 minutes 11.2 seconds N (north), longitude 127 degrees 20 minutes 29.7 seconds E (east)".

The above coordinates are given in the form of 39 ° 21'11.2 '' N 127 ° 20'29.7 ''.

This type of transformation is performed in the following numerical form.

{39, 21, 11.2, 127, 20, 29.7}

In the present invention, the process of transforming into the above-mentioned number form can be performed by a process of inputting by the user the above-mentioned coordinate values.

In other words, when the present invention is executed as a program in hardware of a computer or the like, the above-mentioned coordinates can be input by the user, and when displayed, "latitude: 39 degrees 21 minutes 11.2 seconds N (north) 20 minutes 29.7 seconds E (east) ".

The coordinate system expressed in this way is deformed to be deformed as in {39, 21, 11.2, 127, 20, 29.7}.

Here, if the azimuth of the latitude is S (south) rather than N (north), the process of adding 90 to the degree of latitude ° proceeds.

If the orientation value of the hardness is W (West) instead of E (East), 180 is added to the degree of degree of hardness.

That is, if the latitude is 39 degrees 21 minutes 11.2 seconds S (south), and the latitude is 127 degrees 20 minutes 29.7 seconds W (west), the sequencing will proceed to {129, 21, 11.2, 307, 20, 29.7} .

Such a process can be implemented by a normal operation program.

In the present invention, the data degraded as described above can be stored in a database and stored in a matrix-like structure.

The above-mentioned database can be constructed on a computer memory.

The present invention performs a process of obtaining an index value of a second value from the decelerated coordinate values (second process)

The second value of the decelerated coordinates includes a latitude second value and a longitude second value, and an index value of each latitude second value and an index value of the longitude value are obtained it means.

In the above sequence, the seconds value of the latitude and the seconds value of the hardness are displayed as decimal places. The process of obtaining the latitude value and the hardness value as an order value should be preceded.

The procedure for obtaining the ordinal value of the latitude second value and the order value of the longitude value of the present invention is performed in the following manner.

First, a process of numerically decoding the latitude second value and the longitude value from the deconvoluted coordinate values is performed. (Step 1 of the second process)

In the present invention, the process of decimating the second value and the longitude value in the decoded data may be changed in the order of the process.

In the above example, the coordinate values decimated are {39, 21, 11.2, 127, 20, 29.7}.

The third value, which is the latitude second value, and the sixth value, which is the longitude value, include the decimal point value.

As will be described again, the complex number conversion formula used in the AIM coordinate system can be converted to an integer because only integers can be converted. The second value must be converted to an integer order value by performing the above process.

In the above example, the process of decimating the latitude second value 11.2 and the longitude second value 29.7 is performed in the following manner.

In the present invention, the procedure for obtaining the ordinal value of the second value from the decelerated coordinate values is as follows.

First, in order to obtain an ordinal value of a second value, the present invention performs a process of numerically decoding a latitude second value from the deconvolved coordinate value (1-1-1 of the second process). )

As described above, the decimal places of the latitude second value and the longitude second value may be one or more.

In the case of the present invention, the decimal point of the second value can be set to 5 or more, and if the decimal point is 5 or less, the accuracy is 300 μm.

As described above, the present invention can display at least one decimal point unit, but it is possible to display all the coordinates on the earth, even if the decimal point unit is generally five decimal points.

In the present invention, the above-described numerical deterioration of the seconds value is performed in the following manner.

In the present invention, the sequence of seconds values is first subjected to a first order number decomposition process in which the number before the decimal point and the number after the decimal point are listed in order (1-1-2 of the second process).

In other words, if the decimal point is replaced with a sequence of "11.2", which is the seconds value of up to five latitudes, through the primary number decomposition process, it becomes [11, 2, 0, 0, 0, 0].

The present invention also performs a process of completing the numerical deterioration of the latitude second value by describing the above-mentioned first-order decayed second values in reverse order (1-1-3 of the second process).

In the above example, if the decimal point is written in reverse order from the end unit, the sequence of the seconds value completed by the serialization is [0, 0, 0, 0, 2, 11].

The above process can be performed by a general process or a computing process.

The present invention carries out a process of forming a numerical deterioration with respect to a maximum value for each sequence of the completed numerical aperture deterioration (1-1-4 of the second process)

The present invention performs a process of forming a maximum value for a sequence of numbers before and after a decimal point of a second value (1-1-4-1 of the second process)

That is, the second value (latitude second value and longitude second value) of the present invention can be expressed up to the fifth decimal point. Since the decimal point is applied before the decimal point, 60 is the maximum value before the decimal point, The maximum value of 10 is applied to each of them, and the process of describing the maximum value in order is performed to form the numerical deterioration with respect to the maximum value for each series of the completed water deterioration.

In the above example, the maximum value of the latitude and longitude is five digits after the decimal point.

[60, 10, 10, 10, 10, 10]

In other words, 60 seconds are used for 0 to 59 seconds in the minute coordinates, and 5 decimal places are used as the decimal numbers.

However, the complex number sequence increases from the rightmost value, such as [0,0,0], [0,0,1] [0,0,2] [0,1,0] [0,1,1] do.

Therefore, when a sequence is written in [60, 10, 10, 10, 10, 10], the number of 59.9 seconds is represented as 600 in AIM coordinates (9 characters) The order value of seconds is not compatible at all, which means that the order value can be changed every time the decimal point length of the seconds value is changed.

Therefore, the order of the sequence is inverted so that the order values are compatible even if the precision is different.

In the present invention, as described above, the process of describing the maximum value of the seconds in the reverse order of the first number degradation completes the numerical value of the maximum value of seconds. (1-1-4-2 of the second process)

That is, the sequence having the maximum value of the latitude seconds value is [10, 10, 10, 10, 10, 60] in which the first numerical deterioration [60,10,10,10,10,10] do.

Thus, if you look at the sequence of numbers with one decimal place in the seconds value, there are 600 cases from 0.0 second to 59.9 seconds, which is not a decimal point, It is expressed as a sequence.

The present invention performs a process of calculating the order value of the second value (1-1-5 of the second process)

The order value of the seconds value is calculated by the following equation.

[Equation 1]

M represents a maximum value sequence,

Also, a represents a sequence of seconds to be actually converted,

n represents the size of the sequence,

c means zero maintenance method (c = 0 when applied, c = 1 when not applied).

Therefore, m = [10, 10, 10, 10, 10, 60]

a = [0, 0, 0, 0, 2, 11]

0 is the sequence to which the complement method applies, c = 0,

The number of the above-mentioned series is 6 and n = 6.

When the sequence of 11.2, which is the value of the latitude second, is substituted into the above-mentioned [Expression 1]

0x (10x10x10x10x60)

+ 0x (10x10x10x60)

+ 0x (10x10x60)

+ 0x (10x60)

+ 2x (60)

+11 = 131

That is, the decimal order index value of the latitude second value 11.2 is 131.

The above-mentioned [Expression 1] will be described in more detail as follows.

Maximum value sequence m = [10, 10, 10, 10, 10, 60]

값은 10이 되고,

값은 60이 된다.when

The value is 10,

The value is 60.

The latitude second value sequence a = [0, 0, 0, 0, 2, 11]

값은 0,

값은 2,

값은 11이 된다.when

The value is 0,

Values are 2,

The value is 11.

이므로, k 값이 1부터 6까지 반복해서,Sigma value

, The value of k is repeated from 1 to 6,

Add the calculated value to the right-hand side of equation

이 존재하므로, 각 수열의 값들을 하나씩 더한다.Then to the formula

The values of the respective sequences are added one by one.

Then 0 + 0 + 0 + 0 + 2 + 11. However, since there is a pie value later,

(Pie means to multiply instead of adding all the values that come out after repeating like sigma.)

값을 더하기 전에, 각각의

값에 해당되는 파이 값을 구해서 곱한다.Sigma side angle

Before adding the values,

Find the pie value corresponding to the value and multiply it.

When k is 1, x is 2 and n is 6, that is, from the second to sixth values of the maximum value sequence,

값은 10x10x10x10x60 이 되며, a값이 0이므로, 0x(10x10x10x10x60) 이 된다.

The value is 10x10x10x10x60, and since the value of a is 0, it becomes 0x (10x10x10x10x60).

In the present invention, a sequence value of a second value is obtained from the decelerated coordinate values. (1-2 in the second process)

The procedure of obtaining the ordinal value of the longitude value of the present invention is performed in the same manner as the method of obtaining the ordinal value of the latitude value.

That is, the process of obtaining the ordinal value of the longitude value can be summarized as follows, which is the same as the procedure of obtaining the ordinal value of the latitude value.

That is, the process of obtaining the ordinal value of the second value from the decelerated coordinate values (1-2 in the second process)

(1-2-1 of the second step) of forming a primary water deterioration in which the number of decimal points before the decimal point and the number of decimal points after the decimal point are described in order,

(1-2-2 of the second step) of completing the numerical deterioration in which the first-order water-deteriorated second value formed in the above-described manner is described in reverse order,

(1-2-3 of the second process), and the process of completing the hydrothermal decomposition by a method of describing the above-mentioned first-order water-deteriorated second value in reverse order,

(Step 1-2-4 of the second process) of forming the numerical deterioration with respect to the maximum value for each sequence of the completed numerical aperture,

The process of calculating the order value of the second value (1-2-5 of the second process)

.

Therefore, if a series of digits up to five decimal places is obtained for the longitude value "29.7" as the above embodiment,

Maximum value sequence m = [10, 10, 10, 10, 10, 60]

Longitude value sequence a = [0, 0, 0, 0, 7, 29]

Sequence size n = 6

.

The above-mentioned sequence is referred to as [Expression 1]

To obtain the order value.

Thus, the ordinal value of the longitude value,

0x (10x10x10x10x60)

+ 0x (10x10x10x60)

+ 0x (10x10x60)

+ 0x (10x60)

+ 7x (60)

+29 = 449

449.

In the present invention, the order value of the seconds value obtained as described above is replaced with the latitude seconds value and the longitude seconds value by replacing the latitude second order value and the longitude second order value with the latency seconds value and the longitude seconds value, Into a coordinate value converted into a value (step 3).

That is, in the present invention, the latitude second order value and the longitude second order value obtained in the above-described process are replaced with the decoded latitude second value and longitude second value to form the coordinate value converted into the order value.

In the above-described embodiment, the coordinates of the figure are converted into the numerical data,

[39, 21, 11.2, 127, 20, 29.7]

Change the longitude 11.2 to 131, and change the longitude 29.7 to 449.

Therefore, the coordinate value converted into the innocence value is

[39, 21, 131, 127, 20, 449]

.

In the present invention, a coordinate value converted into the order value is calculated as a decimal order value. (Step 4)

The process of calculating the coordinate value converted into the order value by the decimal order value first carries out the process of forming the maximum value sequence of the converted coordinate value. (Step 4-1)

The maximum value sequence for the transformed coordinate values [39, 21, 131, 127, 20, 449]

 m = [180, 60, 600, 360, 60, 600].

The method of obtaining the maximum value sequence means performing a process of inputting the maximum value of each of the converted coordinate values.

That is, since the first sequence 180 on the left is the "degree value" of the latitude value, the maximum value is 180,

The second 60 from the left is the "minute" of the latitude value, so the maximum value is 60,

The third sequence 600 from the left is the "seconds value" of the latitude value, which is up to one decimal place, so the maximum value is 600.

That is, since the second value is two decimal places, the maximum value is 60 * 10 * 10, so 6,000 is the maximum value.

Likewise, since the fourth leftmost sequence 180 is the "value" of the hardness value, the maximum value is 360,

Since the fifth sequence 60 from the left is the "minute value" of the hardness value, the maximum value is 60,

The sixth order 600 from the left is the "second value" of the hardness value, which is up to one decimal point, so 600 is the maximum value.

If the decimal point is two digits, the value is 60 * 10 * 10, so 6,000 is the maximum value.

A process of forming the maximum value sequence of the transformed coordinate values is performed and a decimal order value of the second coordinate value is calculated even if the maximum value sequence is substituted into the formula 2. [ -2)

The process of calculating the decimal order value of the above-mentioned coordinate value is calculated by the following equation (2).

[Equation 2]

M represents a maximum value sequence,

Also, a represents a sequence of seconds to be actually converted,

n represents the size of the sequence,

c means zero maintenance method (c = 0 when applied, c = 1 when not applied).

In the above example,

Maximum value sequence m = [180, 60, 600, 360, 60, 600]

Coordinate value sequence a = [39, 21, 131, 127, 20, 449]

0 is the sequence to which the complement method applies, c = 0,

Sequence size n = 6

By substituting the above example into the above equation (2)

39x (60x600x360x60x600)

+21 (600x360x60x600)

+131 (360x60x600)

+127 (60x600)

+ 20x (600)

+449

= 39x (466,560,000,000)

+21 (7,776,000,000)

+131 (12,960,000)

+127 (36,000)

+ 20x (600)

+449

= 18,360,838,344,449

.

That is, the decimal order index value of the minute coordinate value is 18,360,838,344,449.

This value can be used to calculate the 9-character sequence as shown below.

In the present invention, the process of calculating the decimal order value is performed and then the calculation of the nine character coordinate value is performed. (Step 5)

The process of calculating the nine-character coordinate value of the decimal order value calculated above can be performed according to the following equation (3).

[Equation 3]

In the above formula,

i = order value of the degree minutiae coordinate,

n is the order size,

m is the maximum value sequence,

c means zero maintenance method (c = 0 when applied, c = 1 when not applied)

a represents the AIM coordinate value sequence.

(└x "is a discard function (Gaussian function), which means that all values under the decimal point of a value in └" are discarded)

Therefore, in the above equation, m represents a maximum value sequence, and the decimal order value is converted into a desired sequence size n.

Therefore, the maximum value sequence m and the sequence size n are variable and can be variously applied according to the user's desire.

In the above example, the values in the maximum value sequence m are set to 36 in order to show an example of constructing the AIM coordinates in the 36-ary method.

In the present invention, when the AIM coordinate value sequence size is aimed at 9 digits, the maximum value sequence number is preferably 10 or more, preferably 20 or more, and more preferably 20 to 72 or so.

The inventors of the present invention desirably include, but not limited to, a case where the general sequence number is 9 digits, and the maximum value sequence is 32 to 40, more preferably, 36.

That is, the inventor intends to apply the 36-ary method when the sequence size is 9 digits and the usable range of the arrays is 20 to 72. However, this does not limit the size of the arrays to be applied due to technical limitations to the 36-ary method.

Therefore, the process of calculating the 9-digit coordinate value by substituting the above-mentioned decimal order value into the above-mentioned [Expression 3] is performed.

The above example, that is, the decimal order index value of the fingertip coordinate value is 18,360,838,344,449, and the process of calculating the 9-digit coordinate value is as follows.

Ordinal value of the degree sketch coordinate i = 18,360,838,344,449

Sequence size n = 9

Maximum value sequence m = [36, 36, 36, 36, 36, 36, 36, 36, 36]

AIM coordinate value sequence a = [?,?,?,?,?,?,?,?,?]

0 is the sequence to which the complement method applies, c = 0,

The number value of the coordinate to be sought x (x is 1 when calculating the first digit of the sequence)

1. Calculate the first digit of a sequence

18,360,838,344,449 ÷ 36 ^ 8 = 18,360,838,344,449 ÷ 2,821,109,907,456 = 6

2. Calculate the second digit of the sequence

(18,360,838,344,449-6x (36 ^ 8)) ÷ 36 ^ 7 = 18.30146363 = 18

3. Calculate the third digit of the sequence

(18,360,838,344,449 -6x (36 ^ 8) -18x (36 ^ 7) ÷ 36 ^ 6 = 10.85269096 = 10

4. Calculate the fourth digit of the sequence

(36,3 8) -18x (36 ^ 7) -10x (36 ^ 6) ÷ 36 ^ 5 = 30

5. Calculate the fifth digit of the sequence

(36, 8) -18x (36 ^ 7) -10x (36 ^ 6) -30x (36 ^ 5) ÷ 36 ^ 4 = 25

6. Calculate the sixth digit of the sequence

(36 ^ 8) -18x (36 ^ 7) -10x (36x6) -30x (36x5) -25x (36x4)) / 36 ^ 3 = 3

7. Calculate the seventh digit of the sequence

(36 ^ 8) -18x (36 ^ 7) -10x (36 ^ 6) -30x (36 ^ 5) -25x (36 ^ 4) -3x (36 ^ 3) ÷ 36 ^ 2 = 5

8. Calculate the eighth digit of the sequence

(36 ^ 8) -18x (36 ^ 7) -10x (36x6) -30x (36x5) -25x (36x4) -3x (36x3) -5x )) ÷ 36 = 13

9. Calculate the ninth digit of a sequence

(36 ^ 8) -18x (36 ^ 7) -10x (36x6) -30x (36x5) -25x (36x4) -3x (36x3) -5x ) -13x (36)) = 29

AIM coordinate value sequence a = [6, 18, 10, 30, 25, 3, 5, 13, 29]

In Equation (3) above,

When x is 1 (that is, when calculating the first digit of a sequence)

i is 18,360,838,344,449,

은 시그마의 최대 값이 x-1이므로,Sigma value

Since the maximum value of sigma is x-1,

Since the maximum value is 0, both the sigma and the product of the multiplication of the value are zero.

는 s=x+1이니 s는 2가 되고, n은 9이니, 해당 파이 곱 값은

Is s = x + 1, s is 2, n is 9,

총 8개 값을 곱한 것이 된다.

The result is a total of 8 values.

The value of the maximum value sequence is all 36, that is, the value of the pie is 36 ^ 8.

When x is 6 (ie, calculating the sixth digit of the sequence)

i is 18,360,838,344,449,

은 시그마의 최대 값이 5가 되고,Sigma value

The maximum value of sigma becomes 5,

이니, 최대 값 수열

은 -6,

은 -18이 되며,

Therefore,

-6,

Is -18,

가 존재하니The values are then -10, -30, and -25, respectively, followed by the sigma

There is

When k is 1, p becomes 2, and the maximum value product from 2 to 9 is 36 ^ 8,

에서 k가 1일 때 값은 -6x(36^8)이 된다.

When k is 1, the value is -6x (36 ^ 8).

는 s=6+1이니 즉 s=7, n은 9니 36^3이 된다.The pie value at the end

Is s = 6 + 1, that is, s = 7 and n is 9, 36 ^ 3.

The present invention performs the process of calculating the nine-character coordinate value and then forming the encoded coordinate value. (Step 6)

The process of forming the encoding coordinate values may be performed according to an encoding scheme preset by the user as described above.

For example, the encoding of the display coordinates may be performed according to a 36-ary encoding method preset by the user.

The 36-ary encoding method for the AIM coordinate value sequence a = [6, 18, 10, 30, 25, 3, 5, 13, 29] obtained in the above embodiment is as follows.

That is, in the following example, at the preset encoding coordinate value as described above,

[Coordinate Value Encoding Table]

"0: 0 1: 1 2: 2 3: 3 4: 4 5: 5 6: 6 7: 7 8: 8 9: 9 10: A 11: B 12: C 13: D 14: E 15: F 16 : G17: H18: I19: J20: K21: L22: M22: M23: N24: O25: P26: Q27: R28: S29: T30: U31: V32 : W 33: X 34: Y 35: Z "

So that each numerical value is converted into a character value in accordance with the encoding value.

Therefore, the AIM coordinate value sequence a for [6, 18, 10, 30, 25, 3, 5, 13, 29] is [6, I, A, U, P, 3, 5, D, And the converted AIM coordinates are 6IA UP3 5DT.

The present invention can change the coordinates of about 27 characters represented by the minute coordinates to the nine-character AIM coordinate system such as " 6IA UP3 5DT "

The present invention also provides a method for transforming the above AIM coordinates back to the folio coordinate system.

In the method of transforming the AIM coordinates into the minute coordinate system, the present invention first calculates the AIM coordinate value as a decimal order value. (Step 7)

The process of calculating the AIM coordinate value as a decimal order value is performed by calculating the value in the following equation.

[Equation 4]

The definition of the above formula is as defined above.

Therefore, the converted AIM coordinate "6IA UP3 5DT" is first converted into the coordinate value of the 36-ary method, which is a predetermined convolution method. (Step 6-1)

6, 18, 10, 30, 25, 3, 5, 13, 29] of the 36-ary method by substituting the converted AIM coordinates "6IA UP3 5DT" .

In the present invention, the coordinate values of the 36-ary method are substituted into the equation (4) to calculate the ordinal value as a decimal value. (Sixth step-2)

Therefore, if the coordinate value of the 36-ary method is substituted into the above-mentioned expression (4)

Maximum value sequence m = [36, 36, 36, 36, 36, 36, 36, 36, 36]

AIM coordinate value sequence a = [6, 18, 10, 30, 25, 3, 5, 13, 29]

Sequence size n = 9

0 is the sequence to which the caret is applied c = 0

6x (36 ^ 8)

+ 18x (36 ^ 7)

+ 10x (36 ^ 6)

+ 30x (36 ^ 5)

+ 25x (36 ^ 4)

+ 3x (36 ^ 3)

+ 5x (36 ^ 2)

+ 13x (36)

+29

= 18,360,838,344,449

That is, the ordinal value i converted to the decimal number of the AIM coordinate is 18,360,838,344,449.

The present invention performs the process of calculating the ordinal value converted into the above decimal number as the figure minute coordinate value (Step 8)

The process of calculating the order value converted into the decimal number by the minute coordinate value is performed by substituting into the following equation (5).

[Equation 5]

The order values i 18,360,838,344,449 converted into decimal numbers of the AIM coordinates are applied to the above equation as follows.

( └x "is the discard function (Gaussian function) └ "means to discard all values below the decimal point)

Order value of AIM coordinates i = 18,360,838,344,449

Sequence size n = 6

Maximum value sequence m = [180, 60, 600, 360, 60, 600]

Coordinates of a degree coordinate sequence a = [?,?,?,?,?,?]

0 is the sequence to which the complement method applies, c = 0,

The number value of the coordinate to be sought x (x is 1 when calculating the first digit of the sequence)

1. Calculate the first digit of a sequence

18,360,838,344,449 ÷ (60x600x360x60x600) = 39

2. Calculate the second digit of the sequence

(18,360,838,344,449 -39x (60x600x360x60x600)) / (600x360x60x600) = 21

3. Calculate the third digit of the sequence

(18,360,838,344,449 -39x (60x600x360x60x600) -21x (600x360x60x600)) / (360x60x600) = 131

4. Calculate the fourth digit of the sequence

(60x600x360x60x600) -21x (600x360x60x600) -131x (360x60x600) / (60x600) = 127

5. Calculate the fifth digit of the sequence

(18,360,838,344,449 -39x (60x600x360x60x600) -21x (600x360x60x600) -131x (360x60x600) -127x (60x600)) / 600 = 20

6. Calculate the fifth digit of the sequence

18360,838,344,449 -39x (60x600x360x60x600) -21x (600x360x60x600) -131x (360x60x600) -127x (60x600) -20x (600) = 449

In other words, the motion vector value sequence a = [39, 21, 131, 127, 20, 449] is obtained.

The present invention performs a process of converting a latitude second order value and a longitude second order value into a decimal point value which is an actual latitude second value in the coordinate value sequence as described above.

The process of transforming the coordinate value sequence 131, which is a state converted from the coordinate value sequence to the decimal order value, and the longitude order value 449, to a decimal point value is performed.

The process of converting the above-mentioned latitude second order value into the actual latitude second value is performed by substituting into the following equation and converting it. (Ninth Process-1)

[Equation 6]

In the above example,

Latitude second order value i = 131

Sequence size n = 6

Maximum value sequence m = [10, 10, 10, 10, 10, 60]

Latitude seconds value sequence a = [?,?,?,?,?,?]

0 is the sequence to which the complement method applies, c = 0,

The number value of the coordinate to be sought x (x is 1 when calculating the first digit of the sequence)

1. Calculate the first digit of a sequence

131 ÷ (10x10x10x10x60) = 0

2. Calculate the second digit of the sequence

131 ÷ (10x10x10x60) = 0

3. Calculate the third digit of the sequence

131 ÷ (10 × 10 × 60) = 0

4. Calculate the fourth digit of the sequence

131 ÷ (10 × 60) = 0

5. Calculate the fifth digit of the sequence

131 ÷ (60) = 2

6. Calculate the sixth digit of the sequence

131 -2x (60) = 11

That is, the latitude second value sequence a is [0, 0, 0, 0, 2, 11].

In the present invention, the latitude second value sequence derived from the above is inverted and a latitude value string is formed. (Step 9-2)

Thus, in the above example, [0, 0, 0, 0, 2, 11], which is the latitude second value sequence a, is reversed and a string is made 11.20000.

Here, the decimal point is set to be taken after the last sequence of the latitude second value sequence is written.

In the present invention, when the latitude value character string is described, it may be set to indicate up to one decimal place.

Therefore, the latitude value string of 11.20000 is written to be 11.2.

The process of converting the hardness second order value into the actual hardness second value is performed by substituting into the following equation to convert it.

[Equation 7]

In the above example,

Longitude second order value i = 449

Sequence size n = 6

Maximum value sequence m = [10, 10, 10, 10, 10, 60]

Longitude value sequence a = [?,?,?,?,?,?],

0 is the sequence to which the complement method applies, c = 0,

The number value of the coordinate to be sought x (x is 1 when calculating the first digit of the sequence)

1. Calculate the first digit of the sequence 449 ÷ (10x10x10x10x60) = 0

2. Calculate the second digit of the sequence 449 ÷ (10x10x10x60) = 0

3. Calculate the third digit of the sequence 449 ÷ (10x10x60) = 0

4. Calculate the fourth digit of the sequence 449 ÷ (10x60) = 0

5. Calculate the fifth digit of the sequence 449 ÷ (60) = 7

6. Calculate the sixth digit of the sequence 449 -7x (60) = 29

That is, the longitude value sequence a is [0, 0, 0, 0, 7, 29].

In the present invention, the longitude value sequence derived from the above is inverted and a latitude value string is formed. (Ninth Process-4)

Thus, in the above example, if [0, 0, 0, 0, 7, 29], which is the latitude second value sequence a, is reversed and a character string is created, 29.70000 is obtained.

Here, the decimal point is set to be taken after the last sequence of the latitude second value sequence is written.

In the present invention, when the latitude value character string is described, it may be set to indicate up to one decimal place.

Therefore, the latitude value string of 29.70000 is written to be 29.7.

The present invention performs a process of converting the latitude and longitude values obtained above into actual values. (Step 10)

The process of converting the latitude second value and the latitude second value into the actual values is performed by substituting latitude and longitude values obtained as the actual values into minute and minute coordinate values.

That is, in the above example, the process of changing the latency value 131 included in the numerical value [39, 21, 131, 127, 20, 449] .

Therefore, the decimated coordinate values obtained by converting the latitude and longitude values obtained as described above into actual values are [39, 21, 11.2 127, 20, 29.7].

The present invention performs a process of transforming a localized coordinate value sequence obtained in the above process into a character string (Step 11)

The transforming of the transformed coordinate value sequence into a character string is performed by converting the transformed coordinate value into a character string corresponding to the transformed local coordinate value sequence.

In the present invention, the first series of the coordinate values is set as a latitude value, the second series is set to a minute value of latitude, and the third series is set to a second value, the fourth series is a degree value of longitude, The minute value of the hardness, and the sixth sequence are set in advance by the user as the seconds value of the hardness,

Therefore, if the latitude value is less than 90 degrees, the azimuth angle is set to N (south). If the latitude value is 90 degrees or more, 90 is subtracted from the latitude value and the azimuth angle is set to S In the same manner, the sequence of minute coordinate values is converted into a string.

If the hardness value is less than 180 degrees, the azimuth angle is set to E (east). If the hardness value is 180 degrees or more, 180 is subtracted from the hardness value and the azimuth angle is set to W Is converted into a preset method.

In the embodiment of the present invention, when the transformed numerical value of the transformed coordinate value is converted into a character string [39, 21, 11.2 127, 20, 29.7], the transformed coordinate value is [39 ° 21'11.2 ' ° 20'29.7''E], and as another display method, it can be converted into a character string such as [latitude 39 degrees 21 minutes 11.2 seconds longitude 127 degrees 20 minutes 29.7 degrees].

The method of converting to a character string can be variously converted according to the setting of the user for each sequence of the above-mentioned coordinate values.

The present invention provides a method for converting GPS coordinates into AIM coordinates in the manner described above.

The present invention also provides a method for converting AIM coordinates converted into GPS coordinates by the above method.

The present invention is a very useful invention for an industry using a coordinate system.

Particularly, the present invention is a very innovative invention in logistics industry, advertising industry, IT industry, and military industry which use a coordinate system.

Claims (3)

(Step 1) of digitizing the coordinate values of the coordinates of the GPS coordinates,
(Step 2) of obtaining the index value of the seconds value from the decelerated coordinate values,
The process of obtaining the index value of the seconds value (the second process)
The second and first longitude values are decimated with the decimated coordinate values (second process-1)
In the process (1-1 of the second process) of performing the numerical deterioration of the second value from the decelerated coordinate values,
(1-1-1 of the second process) of forming a first-order numerical deterioration in which the number of decimal places before the decimal point and the number after the decimal point are described in order,
(1-1-2 of the second step) of completing the numerical deterioration describing the first-order water-deteriorated seconds value formed in the above-described manner in reverse order,
(1-1-3 of the second process), and the process of completing the hydrothermal decomposition by a method of describing the above-mentioned first-order water deterioration value in reverse order,
(Step 1-1-4 of the second process) of forming the numerical deterioration with respect to the maximum value for each sequence of the completed numerical aperture,
The process of calculating the order value of the second value (1-1-5 of the second process)
The process of obtaining the ordinal value of the second value from the decelerated coordinate values (1-2 in the second process)
(1-2-1 of the second step) of forming a primary water deterioration in which the number of decimal points before the decimal point and the number of decimal points after the decimal point are described in order,
(1-2-2 of the second step) of completing the numerical deterioration in which the first-order water-deteriorated second value formed in the above-described manner is described in reverse order,
(1-2-3 of the second process), and the process of completing the hydrothermal decomposition by a method of describing the above-mentioned first-order water-deteriorated second value in reverse order,
(Step 1-2-4 of the second process) of forming the numerical deterioration with respect to the maximum value for each sequence of the completed numerical aperture,
(Step 1-2-5 of the second process) of calculating the order value of the second value,
The order value of the seconds value obtained from the above is a coordinate value converted into the order value by replacing the latitude second order value and the longitude second order value with the latitude second value and the longitude second value by the latitude second order value and the longitude second order value, (Third process),
A fourth step of calculating a coordinate value converted into the order value by a decimal order value,
(Step 5) of calculating the nine-character coordinate value of the decimal order value obtained as described above,
(Step 6) of forming the calculated nine-character coordinate value into an encoding coordinate value,
Wherein the GPS coordinates are converted into AIM coordinates.
delete A method for converting GPS coordinates of claim 1 into AIM coordinates,
(Step 7) of calculating the AIM coordinate value as a decimal order value,
(Step 8) of calculating a sequence value converted into a decimal number as a fractional coordinate value,
The ninth step of converting the latitude second order value and the longitude second order value into a decimal value which is an actual latitude second value in the coordinate value sequence calculated in the above process,
(Step 11) of transforming the localized coordinate value sequence obtained in the above process into a character string,
And converting the converted AIM coordinates into GPS coordinates.

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