JPS60239879A - Encoding method of divided area value - Google Patents

Abstract

PURPOSE:To obtain an access code based upon a dicimal number corresponding to a required specific area by forming 4<n> square mesh divided areas and forming a binary bar code pattern corresponding to mesh dividing levels on two outer sides of the outline of the formed area. CONSTITUTION:A specific area is equally divided into four parts respectively in the vertical and horizontal directions to form sixteen large-scale divided areas and hexadecimal numbers consisting of divided area specifying codes ''0''-''F'' are assigned to respective areas. Similarly, each large-scale divided area is equally divided into four parts respectively in the vertical and horizontal directions to form medium-scale divided areas, each medium-scale divided area is equally divided into four parts respectively in the vertical and horizontal directions to form small-scale divided areas and then hexadecimal numbers are assigned to respective divided areas. When respective divided areas are to be divided into four parts, super large-scale hexadecimal meshes which are divided sixteen part are divided into four parts to form extremely large-scale divided areas and quaternary numbers consisting of divided area specifying codes are assigned to respective divided areas. Binary bar code patterns corresponding to the mesh dividing levels are formed on two vertical and horizontal sides on the outside of the outline of the formed part. Thus, a decimal access code corresponding to the required specific area can be found out by reading out the bar code pattern corresponding to the required specific divided area as a binary value and converting the binary number into a decimal number.

Description

[Detailed Description of the Invention] [Field of Application of the Invention] The present invention relates to a method of encoding divided area values, and more specifically, the present invention relates to a method for encoding divided area values, and more specifically, a mesh division level is set outside the outline of an area divided into 4n rectangular meshes. A method for encoding divided area values, in which a binary barcode pattern is formed, a code for calling a divided area is read as a binary value by the barcode, and then converted to a decimal value and a decimal value calling code is written. Regarding.

[Prior Art] When searching for specific information from a large amount of information sources, it is generally not done to index using symbols, etc. attached in advance to each piece of information within a minimum range based on a specific idea. It is.

For example, like a map, the desired location is indexed from the surface of the map using n2 squares obtained by dividing the latitude and longitudinal directions into n equal parts as the minimum range. Since the direction was simply divided into n equal parts, it was not possible to create an index that subdivided the region, and due to the relationship with the scale, it was not possible to create a fine-grained and detailed index.

[Objective of the Invention] This invention aims to eliminate the above-mentioned drawbacks, and is characterized by dividing 4n (n is a positive integer of 2 or more) rectangular mesh division areas into predetermined mesh divisions. At the same time, a binary barcode pattern corresponding to the mesh division level is formed on two vertical and horizontal sides outside the outline of the formed part, and a desired identification in the multiple square mesh division areas is formed. A method for encoding a divided area value in which a call code in a decimal value corresponding to the desired specific area is inserted by reading a barcode pattern corresponding to the area as a binary value and converting it to a decimal value. This is what we provide.

[Summary of the Invention] The basic concepts of a hexadecimal mesh, a hexadecimal mesh code, a quaternary mesh, and a quaternary mesh code for carrying out the search method of the present invention will be described.

The basic concept of this invention is to divide a specific area into four equal parts vertically and horizontally, forming a total of 16 large-scale divided areas, as shown in FIG.
and assign hexadecimal numbers rAJ to rFJ. Next, each large-scale divided area is divided into four equal parts vertically and horizontally to form 16 medium-sized divided areas, and the divided area designation codes rOJ~``9'' and rAJ~rFJ 16 Assign a base number.

Furthermore, each of these medium-sized divided areas is divided into four equal parts vertically and horizontally to form 16 small-scale divided areas, which are assigned divided area designation codes rOJ~"9" and rAJ~rF in the same manner as described above.
Assign the hexadecimal number of J. By preparing 16 hexadecimal mesh code tables 016 in this way, all 16 divided areas have 16X16X16X16=65.5
Thirty-six small-scale (unit) subdivision areas are formed. Therefore, the division area designation codes "o" to "9" and "A" to rF
A very large-scale divided area G written in each full-width space to which a hexadecimal number of J is assigned.

~GF are divided area designation codes rOJ~rFF, respectively.
FFJ will have a small division area assigned to it.

In this way, the divided areas in units of 16 are defined as hexadecimal mesh 16M1 and the divided area designation code as hexadecimal mesh code 16MC.

Next, as an example of dividing into 4 instead of 16 as described above, the extremely large hexadecimal mesh divided into 42 as described above is divided into 2, in other words, the large scale hexadecimal mesh is divided into 16 as described above. The large-scale hexadecimal mesh in FIG.
As shown in FIG. 2, each area is divided into extremely large-scale divided areas, and a divided area designation code rOJ~"3" in 4 decimal notation is assigned to each area. Next, the area is divided into large-scale divided areas each having 16 large-scale hexadecimal meshes, and a quaternary number of divided area designation codes rOJ to "3" is assigned to each large-scale divided area. Similarly, the next medium-sized 16 meshes have 16 small-sized hex meshes.
The meshes are divided into large and medium-sized divided areas in groups of four, and quaternary numbers of divided area designation codes "0" to "3" are assigned to these divided areas. Next, the area is divided into medium-sized divided areas each having 16 medium-sized hexadecimal meshes, and a quaternary number of divided area designation codes "0" to "3" is assigned to each medium-sized divided area. Next, divide the 16 small-scale hexadecimal meshes into four medium-sized division areas, and assign division area designation codes "0" to "3" to each area.
Assign a quaternary number of ``.

Furthermore, it is divided into small-scale division areas with 16 small-scale hexadecimal meshes as a unit, and divided area designation codes rOJ ~ "
Assign a quaternary number of 3. By preparing 16 such quaternary mesh code tables 04, 4x4x4x4x4x4x16-65.536 small-scale (unit) divided areas are formed in the specific divided area. Therefore, the divided area designation codes rOJ~"3" in quaternary digits are assigned and grouped into groups of 4, and the ultra-large scale divided areas GO~G33 written in full-width characters are assigned the divided area designation codes "0"~"3333," respectively. -3333j is assigned.A divided area in units of four is defined as a quaternary mesh 4M, and its divided area designation code is defined as a quaternary mesh code 4MG.

In this way, there are divided areas in units of 16 and divided areas in units of 4, in other words, hexadecimal meshes in units of 16, hexadecimal mesh codes (addresses) that specify the divided areas in hexadecimal numbers, and 4. It is used as a quaternary mesh code (address) that specifies a divided area using a quaternary mesh and a quaternary number.

The following table is a conversion table between the hexadecimal code and the quaternary code that mediates the binary values of the hexadecimal mesh code that specifies the divided areas in hexadecimal numbers and the quaternary mesh code that specifies the divided areas in quaternary numbers. .

Table 16HC (214HC16HC(2) 48C0000
0008100020 1000101' 9 1001 212001002
^ 1010 22 3 0011 03 B 1011 234 0100
10 C110010 5010111D 1101 31 6 0110 12 E 1110 327 0111
13 F 1111 3316HC = Hexadecimal mesh code 4MC = Quaternary mesh code (2) = Binary number or above As shown above, (1) The basic unit of this invention is 16 meshes that can be equally divided into 4 bits: 2 bits on the X axis and 2 bits on the Y axis. and 1 of the 4-bit multiple
Construct a hexadecimal mesh.

(2) Assign mesh codes (addresses) in hexadecimal to each of the 16 divided areas.

(3) Assign a quaternary mesh code to each of the 16 divided areas using a quaternary number.

(4) Quaternary mesh code O to 3 in binary numbers, ie O is "OO", 1 is "01", 2 is "1o", 3 is "11"
It is displayed as follows.

(5) Of the 2 bits of the code specifying the divided area,
The upper bit represents the line segment on the X axis, and the lower bit represents the line segment on the Y axis.

(6) Set the origin of mesh coordinates to 0.0.

(7) When the mesh level is set to O level as a whole, the mesh that can be divided by X and Y2 bits is level 0.
．． 5 4,,i,.

6,, 1.5 3,, 2.0 10? 2.5 12 rI 3.0 -14. , 3.5'I6 lI 4.0 4n , , n , 0 is the basic concept, and specific embodiments of the present invention will be described below.

[Embodiment of the Invention] Fig. 3 shows a quadratic mesh code assignment table 1, which is made of a transparent sheet of paper, and a frame of the same length is used to designate a specific area 2, leaving a slight margin at the upper end of the sheet. Draw a regular polymorph with line 3, and connect the points that divide this vertical and horizontal frame line 3 with super-large secant line 4 to create 4 super-large-scale division areas (mesh level 1.5)
5, and each divided area is assigned a divided area designation code fO.
Enter the quaternary mesh code 6 from J to "3". Next, the points that divide each of the bisected frame lines 3 into four are connected by the major dividing line 7 to form 16 large-scale divided areas (mesh level 2.
0) 8 is formed, and a quaternary mesh code 9 of divided area designation codes "0" to "3" is written in each of the four maximum-scale divided areas of each divided area.

In addition, the points that divide the frame line 3 divided into four equal parts into eight parts are connected by a large medium dividing line 10 to form 64 large medium-sized divided areas (mesh level 2.5>11), and the 16 points of each divided area are
Divided area designation code “O” to “
Enter the quaternary mesh code 12 of "3".

In addition, the points that divide the frame line 3 divided into 8 equal parts into 16 parts are connected by the middle dividing line 13A to form 256 medium-sized divided areas (mesh level 3.0) 13, and the 64 large-sized divided areas of each divided area are Division area designation code rOJ~ for each medium-sized division area
Enter the quaternary mesh code 13B of "3". Also,
Connect the points that divide the frame line 3 divided into 16 equal parts into 32 with the middle division line 14A, and divide the 1,024 small-scale division areas (
A mesh level 3.5) 14 is formed, and a quaternary mesh code 14B of divided area designation codes "O" to "3" is written in each of the 256 medium-sized divided areas of each divided area. Furthermore, the 64 dividing points of the 32 equally divided frame line 3 are connected with the subdivision line '5A to form 4.096 small-scale division areas (mesh level 4.0) 15, and each division area also has 1, A quaternary mesh code 15B of divided area designation codes "0" to "3" is entered for each of the 024 small-scale divided areas.

Eight binary barcodes 17 to 24 indicating the number of divisions of the frame line 3 are written in parallel on the upper frame and left side frame of the divided area allocation section 16 configured in this way, and the binary barcode 17 indicates the number of divisions. "1", the binary barcode 18 indicates the division number "2",
The binary barcode 19 is provided with a division number display section 25 which indicates the number of divisions ``3'' and the binary barcode 24 similarly indicates the number of divisions ``164''.

In the upper margin of the allocation table 1, a divided area display area 26 representing the range of the divided area and table in the same quaternary mesh as the configuration of the ultra-large-scale divided area described above, and the divided area designation code within the range are displayed. A quaternary mesh code display section 27, a conversion table 28 for mutually converting the aforementioned hexadecimal mesh code and quaternary mesh code via binary values, and a quaternary mesh code display section 27;
A display section 29 and a quaternary pattern code display section 30 for displaying a quaternary pattern code are described.

FIG. 4 shows a hexadecimal mesh code assignment table 31, which is made of transparent paper sheets similar to the quaternary mesh code assignment table described above.
Specified area 3 leaving a small margin at the top of this paper.
2, draw a square with frame lines 33 of the same length,
The point that divides this vertical and horizontal frame line 33 into four is the major dividing line 3.
4 to form 16 large-scale divided areas 35, and divided area designation codes "0" to "9" and rAJ~ to these divided areas.
Enter the rFJ hexadecimal mesh code 36.

Next, 256 medium-sized divided areas 38 are formed by connecting the 16 points of the frame line 33 divided into four equal parts by the middle dividing line 37, and each divided area is also divided into 16 medium-sized divided areas. Divided area designation codes rOJ~“9” and rAJ~rFJ
Enter the hexadecimal mesh code 39.

Further, 64 dividing points of the 16-equally divided frame line 33 are connected by subdivision lines 40 to form 4.096 small-scale divided areas 41, and each of these divided areas also has 4,096 small-scale divided areas. Divided area designation code rOJ ~ "9" and rAJ ~ r
Enter the FJ hexadecimal mesh code 42.

Eight binary barcodes 44 to 51 indicating the number of divisions of the frame line 33 are written in parallel on the upper frame and left side frame of the divided area allocation section 43 configured as described above, and the binary barcode 44 indicates the number of divisions. The binary barcode 45 indicates the number of divisions "2", the binary barcode 46 indicates the number of divisions "3", and the binary barcode 51 indicates the number of divisions "64". 52 are provided.

In the upper margin of the allocation table 31, there is a hexadecimal mesh division area display section 53 showing the hexadecimal mesh division area and the range of the table, which is the same as the configuration of the ultra-large-scale division area described above, and a hexadecimal mesh code within the range. a hexadecimal mesh code display section 54, a conversion table 55 for mutually converting the aforementioned hexadecimal mesh code and quaternary mesh code via binary values, a hexadecimal key display section 56, and a hexadecimal pattern code. Hexadecimal pattern code display section 57
is stated.

FIG. 5 shows a quaternary mesh code and hexadecimal mesh code assignment table 61, whose structure is a combination of the above-mentioned quaternary mesh code assignment table 1 and hexadecimal mesh code assignment table 31. The attached parts have the same configuration as described above, and numbers 61A and 61B corresponding to the decimal values of the XY coordinates are added to the two sides of the table 61.

Figure 6 is one of the three code assignment tables mentioned above.
As an example, the Shinmesh code assignment table is shown superimposed on a 1:50,000 map (northeastern Tokyo) 62.
Below, before describing the procedure for creating data specifying the location of a specific area on a map, in this case Tokyo Station, I will summarize the explanation a little. The relationship between the quaternary mesh designation code shown in FIG. 3 and the hexadecimal mesh designation code shown in FIG. 4 is as shown in FIG. The vertical and horizontal sides are divided into two halves as shown in Figure 7+b), and one of the four ultra-large-scale division areas obtained is called mesh level 05,
Quaternary mesh codes of division area designation codes "O" to "3" are attached, and when these four mesh codes are expressed in binary, the quaternary mesh code rOJ is "OO", the quaternary mesh code "1" is "01", and the four mesh codes are "01" and 4. Advance code “2”
is "10" and the quaternary mesh code "3" is "11"
Let the upper left corner of this area Δ to which the two bits of b are assigned be the origin of the mesh coordinates ``OO''.

Next is the division area “0” with a mesh level of 0.5.

As shown in Figure 7 (C), rlJ, r2J, and r3J are each divided into 2 equal lengths, resulting in more than 16 large-scale division areas, with "O" to "9" and rAJ to rFJ. Add a division area designation code in hexadecimal and further add b2 and b3 to display these 16 hexadecimal mesh codes in binary.
2 bits are assigned to the mesh level 1.0.
The divided areas, arrangement order, and hexadecimal mesh code are fixed in hexadecimal numbers.

The 16 ultra-large-scale divided areas shown in Figure 7 (C) are divided into 10-dimensional areas, and each side length is divided into two as shown in Figure 7 (small), and the 16 ultra-large-scale areas obtained by dividing into Divided area designation code rOJ~ into 4 divided areas for each advance mesh
A quaternary mesh code of "3" is assigned, and 2 bits of s and b are assigned to represent this quaternary mesh code in binary numbers, and this state is called mesh level 1.5.

As shown in Figure 7(e), the side length of each of the 15th-order maximum-scale four-part areas is divided into 1/2 equal parts, and the large-scale 16-part areas obtained by the same division are divided into divided area designation codes. The hexadecimal numbers "704 to 79" and "7A" to "7F" are assigned, and 2 bits of s and b are assigned to display these 16 hexadecimal mesh codes, and this state is called mesh level 2.0. It is called.

Hereinafter, as shown in FIGS. 7(f) to tb, the area A is subdivided into 4 divisions and 16 divisions in the same manner as described above.

FIG. 8 〈ω is a diagram showing the relationship between mesh level, bit level, quaternary mesh and hexadecimal mesh, and quaternary mesh code and hexadecimal mesh code (address). Here, the hexadecimal mesh code for 1-th to n-th division is carried in units of 4 bits, and the hexadecimal mesh code (0-FFFFn) that can be divided by the most significant 4 bits is fixed as an absolute address, and a certain next division mesh is By selecting the level of , it becomes a relative address.

The number of meshes when treated as an absolute address is 65,536 (8 bits vertically and 8 bits horizontally) from O to FFFF.
The mesh number for each level, when treated as a relative address, is 4 at mesh level 0.5, 16 at mesh level 1.0, and 16 at mesh level 4. 0 is 65,53
6 for a total of 87.382.

The digits of the mesh code represent the level of each division mesh, and the relationship between the quaternary mesh and hexadecimal mesh is shown in Figure 8 (b).
Hexadecimal mesh as shown.

The division area is obtained by dividing each primary division mesh (1st, 2nd, 3° 4th, Nth division) into 16 parts, and the division area of the quaternary mesh is the sum of 4 meshes at the 1st level, which is a decimal number. The relationship between (10), hexadecimal mesh code (168C), quaternary mesh code (48C), and binary code is shown in 8th
Shown in Figure (C).

At this point, we go back again and apply the hexadecimal mesh code assignment table 61 on the map 62 of northeastern Tokyo on a scale of 1:50,000, and find the location of "Tokyo Station" in the data entry form 6 shown in Figure 9.
Fill in 3. In this table shown in Figure 9, 64 is a column for entering mesh data of 1/200,000, and 65 is 1/50,000, which is used when searching by the drawing number attached to 1/250,000. . 1/50,000 figure number code entry field, 66 is a field to enter the mesh weight (0 to 15 levels), 67 is a field to enter the mesh color (0 to 15 colors),
68 corresponds to the CPU address and is 1/50,000.
1/25,000th 0.6250,000th and 0.312
69 is a field to enter the name of the administrative district, 70 to 73 are the nominal data names such as 1Tokyo", "East", "Northern", or "East", "Kyo", "
A column 74 is used to enter the type of mesh, such as ``station,'' which is a data name entry column that can be expressed with a maximum of six characters, including three kanji characters such as ``neck part'' and three special characters.

Here, the mesh code of 1/200,000 is "○Co1",
This 1:50,000 map is the 1:200,000 map mentioned above.
According to the hexadecimal mesh code allocation table, it falls in the division area of hexadecimal mesh code "7", and as shown in Figure 6 on the 1/50,000 scale map, Tokyo is located in the division area of hexadecimal mesh code rAJ, and then this 0 which divided the divided area into 1/4
, 1/31.25 million is in the rBJ division area, so
The location data for the Tokyo Expressway can be entered as r7A9BJ. That is, it is possible to zoom in and extract a map from a scale of 1/200,000 to a scale of 1/031,250,000.

The above is an example displayed in hexadecimal mesh code,
As shown in FIGS. 7(a) to (i), if a quaternary mesh code is used, it can be displayed as r 1322-2123J, and in a binary code, it can be displayed as "01111010-10011011J."Hexadecimal pattern code and quaternary pattern code can also be used. For example, it can be displayed as shown in FIG.

The hexadecimal mesh code is a code to correspond to the address of the cPU, and the quaternary mesh code is a code to correspond to an external input key and an index pattern code. The quaternary mesh code specifies the division area of the quaternary mesh by pressing the four input keys "0" to "3" and the mesh level by the number of times the mesh is pressed, and the hexadecimal mesh code specifies the mesh level by pressing the four input keys "0" to "3". By pressing the 16 input keys rAJ to rFJ, the division area of the hexadecimal mesh can be specified by the number of mesh levels, or by filling in the area where information is located for each level, external input can be performed. It can also be made to correspond to oysters.

Information on the main points on these maps is stored in the CPU's memory in hexadecimal mesh codes, that is, hexadecimal codes, as shown in Figure 9. From the mesh code or the map itself, it becomes "Tokyo 0CO1" and "Tokyo 7A9BJ," and as mentioned above, "7" is the 7th page of the atlas, "A" is the A division area of the 7th page,
By indicating that "9" is a 9-division area within an A-division area and "B" is a B-division area in a 9-division area, the location of the Tokyo shape can be accurately known.

Although not shown, by assigning one character to each mesh based on the mesh code table in a kanji character table, it is possible to assign a four-digit code to each kanji or character as described above, and it can also be used as a character search code. Can be used.

[Effect of the Invention] As described above, the present invention forms 4n (n is a positive integer of 2 or more) rectangular mesh division areas corresponding to a predetermined mesh division level, and also A binary barcode pattern corresponding to the mesh division level is formed on two vertical and horizontal sides on the outside, and a barcode pattern corresponding to a desired specific area among the many rectangular mesh division areas is read in binary value10. By converting to a decimal value, a call code in a decimal value corresponding to the desired specific area is entered, so that all meshes at level n correspond to CPU addresses, and at the same time, the mesh level and division area are specified. By doing this, you can specify the position and range of the whole with high accuracy. Selecting level 1 means reducing the whole by 1/16, and specifying one of these meshes means specifying a specific range for the whole. Here, controlling the mesh level means shifting the bit level, and assuming that level 2 corresponds to the entire CR7 screen and mesh accuracy is up to level 4), as mentioned above. As shown above, shifting 2 bits to the upper bits will enlarge the mesh level (doubling the mesh level precision), shifting 2 bits to the lower bits will reduce the mesh level (the mesh precision will become 1/2). Since it is possible to specify division areas and codes (addresses), the search speed is significantly faster.

[Brief explanation of the drawing]

Figures 1 to 10 all show one embodiment of the present invention, Figures 1 and 2 are explanatory diagrams of the basic concept of the invention, and Figure 3 is a diagram of the quaternary code assignment table. Diagram,
Figure 4 is a configuration diagram of a hexadecimal mesh code assignment table, and Figure 5 is a diagram showing the quaternary mesh code/hexadecimal mesh code and
A configuration diagram of a Y coordinate decimal code assignment table, Figure 6 is a diagram showing the usage status of a hexadecimal mesh code assignment table, and Figure 7 (a
)~Ya is an explanatory diagram of the quaternary mesh code, hexadecimal mesh code, and mesh level, and Figure 8 (a) is the mesh level, hit level, quaternary mesh, hexadecimal mesh, and address of the quaternary mesh code and hexadecimal mesh code.
The related diagram in Figure 8 (b) is the division area of the quaternary mesh and 1
Relationship diagram of hexadecimal mesh division areas, Figure 8 (C1 is a relationship diagram of binary/quaternary mesh codes, decimal numbers, and hexadecimal mesh codes, Figure 9 is a diagram showing an example of filling in a data entry form,
FIG. 10 is a diagram showing the relationship between each pattern code and mesh code. Code explanation 1... Quaternary code assignment table 2...
・Specific area 3.33... Frame line 4... Super large division line 5... Extremely large scale division area 6, 9.12.13B, 14B, 15B... Quaternary mesh code 7. 34...Large dividing line 8.35...Large dividing area 13.38...Medium dividing area 10...Large dividing line 13A, 37...Medium dividing line 11... ...Large medium-sized division area 14...Medium small-scale division area 15.41...Small-scale division area 14A...Medium subdivision line 15^, 40...Small division line 16, 43...Divided area allocation units 17-24.44-51...Binary barcodes 25, 5
2... Division count display section 26... Division area display section 27... Quaternary mesh code display section 28, 55
... Conversion table 29 ... Quaternary key display section 30 ... Quaternary pattern code display section 31 ...
... Hexadecimal mesh code assignment table 32 ... Specific area 36.39.42 ... Hexadecimal mesh code 53 ...
... Hexadecimal mesh division area display section 54 ...
- Hexadecimal mesh code display section 56... 16 entry key display section 57... Hexadecimal pattern code display section 61... Hexadecimal and quaternary mesh code allocation table 61A , 61B...Numeric value 62...Map 63...Data entry form 64...Mesh data entry field 65...
・Drawing number code entry column 66...Column 67 to enter mesh weight...
...Column 68 to enter the mesh color...Column 69 to enter the mesh designation code...Columns 70 to 73 to enter the administrative district name...Data name entry column A. ...Area Go~G 33. Go ~ GF...Very large scale division area G4...Quadary mesh code table 016...Hexadecimal mesh code table Figure 9/J 16 weir r1'' turn code and 16 East 1 tunnel: I--
Jif,? 2 2-2 7 2 J Procedures Manual (Method) Manabu Shiga, Commissioner of the Japan Patent Office, August 1980; Area value coding method 3, relationship with the case of the person making the amendment Patent applicant Funabashishima Ebara Higashi Address Tomo 4-19-18 Maehara Izumi, Funabashi City, Chiba Prefecture
Chika Toki Taka Name Tomo Kinsetsu Takashi 4, Agent postal code 110 5, Date of amendment order July 31, 1980 6, Subject of amendment Field for brief explanation of drawings in specification and amendment written patent application 1972-97241 No. 1, Mei 1, page 23, line 14, ``Fig. 1(a) to (e) and FIG. 2(ω to (e) are respectively explanatory diagrams of the basic concept of this invention, and FIG. 3(a) is an illustration of the quaternary mesh code allocation table. The configuration diagrams, FIG. 3(b) to <h+ are partial configuration diagrams in which the main parts of the above are enlarged, and FIG. 4(a) is a configuration diagram of the hexadecimal mesh code assignment table, and FIG. are enlarged configuration diagrams of the same main parts as above, Figure 5 (a) is a diagram of the configuration of the quaternary mesh code and hexadecimal mesh code and the decimal code assignment table of XY Zamura, Figure 5 + b + to Figure 5 (h) A configuration diagram showing the main parts of the above enlarged, No. 6
FIG. 6(a) is a diagram showing the state of use of the hexadecimal mesh code assignment table, and FIG. 2. Box 1 in the drawing is corrected as shown in the attached drawings, Figures 1(a) to 1(e). 3. Please replace Figure 2 of the box in the drawing with Figure 2 of the attached attached drawing (ω to 2nd figure).
Correct as shown in figure (e). 4. Please refer to Figure 3 of the box in the drawing attached to Figures 3 (A to 3) of the attached drawing.
Correct as shown in 5. Please replace Figure 4 of the box in the drawing with Figure 4 of the attached attached drawing (ω to 4th figure).
Correct as shown in 6. Please replace Figure 5 of the box in the drawing with Figure 5 of the attached attached drawing (ω to 5th figure).
Correct as shown in figure (h). 7. Amend Figure 6 of the attached drawings as shown in attached drawings Figure 6 (a) and Figure 6 (bl). Applicant Tomo Chika Setsu Filial Procedure Neho Seisho (self-motivated) August 22, 1980 Incident , Koshiki). Commissioner of the Japan Patent Office Manabu Shiga1, Indication of the case Patent Application No. 97241 of 19822, Coding method of the name of the invention divided area value3, Relationship with the case of the person making the amendment Patent applicant Funabashishima Ebara Higashi Address Tomo, 4-19-18 Maeharaizumi, Funabashi City, Chiba Prefecture
Chika Toki Taka Name Tomo Kin Setsu Takashi 4, Agent postal code 110 5, Date of amendment order July 31, 1980 6, Subject of amendment Column 7 for detailed explanation of the invention in the specification, Contents of amendment
As per the attached document, amended Japanese Patent Application No. 1, No. 1, page 3, line 16 of the Old Specification, “Figure 1” was changed to “Figure 1
Corrected to ω. 2. Add [Fig. 1 (b) to 1 (as shown in 01)] before "vertical and horizontal directions" on page 4, line 5 of the same book. 3. Add "as shown in Figure 1 (01)" on page 5, line 7 of the same circle. 1 Figure 1'' to ``Figure 1 (a)
~〈e)'' and changed ``Figure 2'' in line 8 of the same page to 1 to 2.
Figure (■) is corrected. 4. In front of “16” on page 5, line 20 of the same book, [Figure 2 (
1)) to "as shown in FIG. 2(e)" are added. 5. Change “Figure 3” on page 9, line 16 of the same book to “Figure 3 (a
)”. 6. In the same book, page 11, line 8, before “64”, add “as shown in Figure 3 (e)” and
Add "as shown in Fig. 3 ω ~ (S)" before "Description" on line 6. 7. Add "as shown in Fig. a) and ``as shown in Figure 3 ([) to mountain)'', and added ``Figure 4'' in line 12 of the same page as [-Figure 4 (a)''.
Correct. 8. Added "[as shown in 4th appearance] to Figure 4(e)" before "formation" on page 13, line 9 of the same book, and added "as shown in Figure 4 (e)" on page 13 of the same book
Add [Fig. 4 (ω ~ (as shown in small)] before "Description" in line 5. 9. Add [Fig. 4 (
ω and as shown in Figure 4 ([) to (h)”, and corrected “Figure 5” in line 11 of the same page to “Figure 5 (ω)”, and roughly added “Figure 5 (ω)” in line 16 of the same page. Before the line rXYJ [Figure 5 (b
) to (as shown in small). 10. Change "Figure 6" from page 14, line 18 of the same book to "Figure 6 (
a)” and “Figure 3” on page 15, line 4 was changed to “Figure 3.
Figures (a) to <e>" were corrected, and the fifth line of the same page was also corrected to "Figures (a) to <e>.
Figure 4j is corrected to ``Figure 4 (a) to (e)''. 11. In the same book, page 18, line 16, before “1/50,000” there is “
Figure 6 (as shown in ω) is added. 12. Correct "neck" on page 19, line 11 of the same book to "neck." 13. "Figure 6" on page 19, line 20 of the same book. [Figure 6 (
+1) Correct to J. Applicants: Tomo, Chika Setsu, Takayoshi, Dan Rokube Osamu

Claims (1)

[Claims] 4n (n is a positive integer of 2 or more) rectangular mesh division areas are formed corresponding to a predetermined mesh division level, and two vertical and horizontal sides outside the outline of this formed part are formed corresponding to the mesh division level. A binary barcode pattern is formed, and the barcode pattern corresponding to a desired specific area in the plurality of rectangular mesh division areas is read as a binary value and converted to a decimal value, thereby forming the desired specific area. A method for encoding divided area values, characterized in that a calling code is entered using a corresponding decimal value.