JPH07110847A - Big bang code system and reader therefor - Google Patents

Abstract

PURPOSE:To provide a big bang code high in recording density and capable of being accurately read in a spot-like state. CONSTITUTION:A big bang code 31 recording optically readable bit information in intersections between circumferential lines forming polar coordinates and radial lines is read out by a big bang code reader 51 having a light emitting element 53 for projecting light rays forwards in a state opposed to almost the center of the circumferential lines and plural light receiving elements 54 for receiving bit information existing in an optical path by the existence of reflected light so as to distinguish it from others. Consequently the big bang code 31 improving the recording density of bit information per unit area can be accurately read in the spot-like state.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a big bang code system for recording optically readable bit information on a polar coordinate chart and a big bang code reader for reading a big bang code.

[0002]

2. Description of the Related Art Bar codes attached to the packaging of various products represent 13-digit numbers using four types of lines and blank spaces. Displayed by code data. However, the barcodes used around the world have a small amount of information that can be displayed by themselves, require high printing quality, are vulnerable to dirt and damage, and cannot print in small spaces. There are drawbacks. In addition to these drawbacks, problems such as impairing the aesthetic appearance of printed products have been pointed out, and various two-dimensional codes have been proposed as next-generation codes that replace bar codes. Currently used 2
There are two-dimensional codes such as a multi-stage type in which fine barcodes are stacked and a matrix type in which fine black and white squares are drawn in a square, both of which store information not only horizontally but also vertically. By doing so, a device for increasing the information density per unit area has been made. Therefore, in the case of this type of two-dimensional code, the amount of information that can be carried by one code data reaches approximately 1000 to 2000 characters, and there are many that are superior in visual design to bar codes.
The advantages such as not significantly detracting from the aesthetics of the product are also welcomed.

In the two-dimensional code shown in FIG. 6, four squares with a cross line, which is the minimum unit of the information code, are filled in by 16 ways, and one square has a number from 0 to 15. It is a code called Kalura code that can be expressed. As shown in FIG. 7, this carula code is a square with four divisions divided by crosshairs as information codes 2 ₁ , 2 ₂ , ... And a plurality of these are arranged on the sheet 1 at a constant pitch. By arranging them side by side, the binary coded decimal code is displayed. Specifically, the information codes 2 ₁ , 2 ₂ , ...
4 segments 2 obtained by dividing the square carrying
^0, 2 ^{1, 2} 2, 2 ^3, assigned the decimal 1,2,4,8, each segment 2 ^0, 2 ^{1, 2} 2, 2 ^3, "white"
When "black paint" and "black paint" are black-painted in an appropriate combination corresponding to "0" and "1" of bit information, the bit information is listed in order of each segment 2 ⁰ , 2 ¹ , 2 ² , 2 ^3. In 2
The base number is displayed, and each segment 2 ⁰ , 2 ¹ , 2 ² , 2 ³
The decimal numbers are displayed by adding the black-painted numbers.

The information code reader 3 for reading the Carula code is constructed by providing sensor plates 4 ₁ , 4 ₂ , ... Corresponding to the respective information codes 2 ₁ , 2 ₂ ,. sensor plate 4 _1, 4 _2, the ... information code 2
Four light receiving elements 5 ₀ , 5 ₁ , 5 ₂ , 5 ₃ are arranged corresponding to the four segments 2 ⁰ , 2 ¹ , 2 ² , 2 ³ of ₁ , 2 ₂ , .... At the center of the four light receiving elements 5 ₀ , 5 ₁ , 5 ₂ , 5 ₃ , there are arranged light sources 6 ₁ , 6 ₂ , ... such as light emitting diodes for each sensor plate 4 ₁ , 4 ₂ ,. This light source 6 ₁ ,
6 ₂ , ... Rays emitted from the segments 2 ⁰ , 2 ¹ ,
2 ² and 2 ³ corresponding to the black and white light receiving elements 5 ₀ , 5 ₁ ,
5 _2, is a light receiving or non received by _3, the read data decoder 7 decodes each information code.

[0005]

In the above-mentioned conventional Carula code, a plurality of information codes 2 ₁ , 2 ₂ , ... Are arranged side by side, and code data in which a plurality of numbers are collected is displayed as a whole. Since a plurality of information codes 2 ₁ , 2 ₂ , ... Each having a minimum unit of two-division or four-division squares are arranged side by side, the amount of information that can be displayed increases, but an increase in the display area cannot be avoided. Aesthetically, it had the drawback that it was the same size as the barcode. Further, since one code data is displayed as a set of a plurality of information codes recorded on the sheet in a horizontally long or vertically long shape, it is absolutely impossible to read it in a circular spot. Even if it is recorded, careful attention is required in the reading posture of the information code reader 3 with respect to the code data, and in many cases, skill is required in reading the code data. When reading the Kalura code recorded on the wrapping paper that forms a curved surface along the shape of the product to be wrapped, there were problems such as the entire code was curved and often it could not be read accurately. .

Therefore, it is an object of the present invention to provide a big bang code system and a big bang code reader which are capable of increasing the recording density of bit information per unit area and enabling accurate reading in a spot manner. .

[0007]

According to the present invention, a polar coordinate chart formed by a plurality of concentric circular lines and a plurality of radial lines radially extending from the center of the circumferential line is used as a recording surface. A big bang code method characterized by recording optically readable bit information at the intersection of the circular line and the radiation on the polar chart, or the area divided by the radial line and the radiation on the polar chart The above object is achieved by a big bang code method characterized in that optically readable bit information is recorded on the.

Further, the present invention is a big bang code reader for reading a big bang code in which optically readable bit information is recorded on a polar coordinate chart, in a state of being opposed to substantially the center of the circumferential line. And a big bang code reader characterized by comprising a light emitting element for projecting a light beam forward, and a light receiving element for discriminating and receiving the bit information existing in the optical path from the other by the presence or absence of reflected light or transmitted light, or The above object is achieved by a big bang code reader or the like, which is equipped with an image sensor for imaging a big bang code by two-dimensional scanning and a decoder for decoding the output of the image sensor by pattern recognition.

[0009]

According to the present invention, optically readable bit information is recorded at the intersection of the circumferential line on the polar coordinates and the radiation or on the area defined by the circumferential line and the radiation, and the information is collected on a recording surface having a small area. It is converted into a display to enable spot-like code reading.

[0010]

Embodiments of the present invention will be described below with reference to FIGS. 1 and 2 are plan views showing respective embodiments of code data recorded according to the Big Bang code system of the present invention, and FIGS. 3 and 4 are schematic perspective views showing respective embodiments of the Big Bang code reader of the present invention. FIG.

The big bang code 11 shown in FIG. 1 has a polar coordinate chart 12 defined by a plurality of concentric circular lines and a plurality of radial lines radially extending from the center of the circumferential line as a recording surface. Bit information 13 is recorded at the intersection of the circumference line and the radiation on the chart 12. However, a circular mark area, which is the minimum required for optical reading of information, is defined at the intersection of the circular line of the polar coordinate chart 12 and the radiation. By filling this circular mark area with a black dot, Bit information "1" can be written in a specific location on the polar coordinates defined by a line and radiation. Further, here, in order to show the starting line that defines the reference of polar coordinates, at least one reference line that blackens all intersection points on the radiation is always provided, but the bit information on the reference line is the bit information of the code data. It can be arbitrarily excluded from the data content.

[0012] A plurality of intersections of the circumference line of radius Ri (where i is a positive integer) of the polar chart and the radiation of angle θj (where j is a positive integer) clockwise from the reference line of radiation. Bit information b11 to bij of "1" or "0" is given to each of (R1, θ1) to (Ri, θj). Therefore, it is possible to display 2ij power information as a whole from the combination of a total of i × j bit information. That is, for example, a large number of information codes that have been displayed by the conventional vertically or horizontally long two-dimensional code can be collectively displayed in a small circle having a diameter of about 5 mm.
Further, the center point of polar coordinates, that is, the pole point (R0, θ0) is
For example, a diameter of about 20% of the maximum code diameter Ri can be always designated as a black dot, or a white dot having an increased light reflectance for easy reading as described later.

Further, ij pieces of bit information b11 to bij written at the intersections of the i circumferential lines and the j radial lines.
Is the simplest b11, b12, ... b1j, b
, B22, ..., B2j, ..., Bij are sequentially arranged from the bit information on the innermost circumference side to form one code data as a whole, for example, 101100011 ... 011. Therefore, it is also possible to divide the thus obtained 1-code data into blocks of, for example, 4 bits each from the beginning and convert each block into a hexadecimal number. In addition, when 4 bits are set as one block, for example, only 4 radiations intersecting at right angles with a plurality of circumferential lines are intersected with each other, and 4 radiations from one circumferential line are always used.
It can be configured so that only bits can be read. Further, it is also possible to limit the number of circumferential lines to four and adopt a method of reading 4 bits arranged on the same radiation among a plurality of radiations as one block.

As described above, since the big bang code 11 records the optically readable bit information 13 at the intersection of the radial line and the radial line forming the polar coordinate chart 12,
For example, the bit information 13 is arranged concentrically with respect to the polar coordinate center (the origin of the big bang) in the circumferential direction from the inner circumference side to the outer circumference side or vice versa, or radiation extending in all directions from the coordinate center. By arranging the bit information 13 in the radial direction in the clockwise or counterclockwise order,
A plurality of bit information 13 can be arranged according to a certain rule, and the code data expressed as a set of arranged bit information 13 are all housed inside the circumference of the maximum diameter centering on the center point of polar coordinates. Therefore, as will be described later, the code data can be read spot-wise with the circumferential line having the maximum diameter as the spot diameter.

In the above embodiment, the big bang code 11 in which bit information is recorded at each intersection of the circumference line and the radiation on the polar coordinate chart is taken as an example. However, like the big bang code 21 shown in FIG. It is also possible to employ a code in which bit information 23 is recorded in a region defined by the circumferential line and the radiation on 22. However, the big bang code 21 in which the bit information 23 is recorded in the area demarcated by the circumference line and the radiation is also different in some reading technology, but the bit information is recorded at the intersection of the circumference line and the radiation. It can be considered that the display content is substantially the same as that of the big bang code 11.

Big Bang code reader 5 shown in FIG.
1 reads the big bang code 31 recorded on a polar coordinate chart composed of four circumferential lines and eight radiations, and the big bang code 3 is read in the reader body 52.
1. A light emitting element 53 that projects a light beam forward while facing the center point of 1, and four light receiving element rows 54 ₁ , 54 ₂ , 54 ₃ , 54 arranged so as to surround the light emitting element 53 in a concentric ring shape. _It consists of _four . Each light receiving element array 54 ₁ , 54 ₂ , 54 ₃ , 54 ₄ is
A plurality of light-receiving elements 54 for discriminating and receiving the bit information from the other depending on the presence or absence of the reflected light are arranged in an annular shape with a constant pitch for each column. The reader body 52 is
It is a contact reading type configuration in which the big bang code 31 is brought into close contact with the recorded sheet for reading, and as shown in FIG. 4, the cylindrical open end surface is pressed against the big bang code 31 to perform reading. To do. However, some ingenuity has been made so that reading can be performed when the light emitting element 53 is directly facing the center point of the big bang code 31.

That is, a reflective dot 31a such as a silver foil having a high light reflectance is formed at the center point of the big bang code 31, and the positioning light receiving element 55 is laid on the light emitting element 53 so that the light beam projected from the light emitting element 53. Is reflected by the reflective dot 31a in the center of the big bang code 31 and is received by the positioning light receiving element 55, the lamp 56 provided in the reader main body 52 is made to blink, and the blinking is visually confirmed and read. Reading is performed by pressing a push button 57 provided on the side surface of the container body 52. Therefore, at the time of reading, the light emitting element 53 always faces the center point of the big bang code, and the light rays projected from the light emitting element 53 toward the four circumferential lines are reflected by the sheet surface, Four light-receiving element rows 54 ₁ , 54 ₂ , 54 ₃ , 5 arranged in four concentric annular shapes
It is incident on the corresponding light receiving element 54 of 4 ₄ accurately.

As described above, the big bang code reader 51 is arranged in a concentric arrangement according to a polar coordinate chart formed by a plurality of concentric circular lines and a plurality of radial lines radially extending from the center of the circumferential line. Since a plurality of light receiving elements 54 are arranged at equal intervals on the circumferential lines having different diameters with the pitch necessary for identifying and receiving the bit information, the bit information is emitted from the light emitting element 53 arranged at the center of the concentric circle. The light beam reflected by can be accurately received. In addition, since the centers of the big bang code 31 and the big bang code reader 51 are made to face each other at that time, even if the big bang code reader 51 is twisted in a phase around the line connecting the centers, there is no problem in reading. Therefore, even though it is a two-dimensional array, it can be read accurately and easily by spot-like alignment.

Further, in the above embodiment, it is also possible to use a two-dimensional image sensor in which image pickup elements are vertically and horizontally arranged, instead of using the two-dimensional image sensor in which a plurality of light receiving elements 54 are concentrically distributed. The big bang code reader 61 shown in FIG. 5 has a focusing lens 63 that focuses a light beam from an imaging target in a reader body 62, and a big bang code 41 that is focused by the focusing lens 63 by two-dimensional scanning. CCD image sensor 64 for
It has a built-in decoder 65 that decodes the output of the CCD image sensor 64 by pattern recognition, operates with a battery 66 as a power source, and has a cordless type configuration that wirelessly transmits the decoding result instead of wire. That is, when the front surface of the reader body 62 faces the big bang code 41 and the push button 67 provided on the side surface of the reader body 62 is pressed, the CCD image sensor 64 and the decoder 65 operate, and at the same time, the decoder 65 decodes them. The code data is output from the light emitting diode 68 to the outside. The data output by the light emitting diode 68 is remotely received by an optical receiver (not shown) installed in a place apart from the reader main body 62.

As described above, since the big bang code reader 61 reads the big bang code 41 by using the two-dimensional image pickup technique, the facing relationship between the CCD image sensor 64 and the big bang code 41 is strictly center-to-face. As long as the big bang code 41 is included in the image frame of the CCD image sensor 64 without being bound by such a severe condition, it is possible to take an image without misreading all bit information without reading errors, and the image data is pattern recognized. Since the bit information is decoded by, the bit information arranged on the circular coordinates can be accurately recognized and decoded as image data.

In both of the above embodiments, the reflection type big bang code readers 51 and 61 for receiving the light rays reflected by the bit information are taken as an example, but the transmissive reading for receiving the light rays passing through the bit information is taken. It can also be configured as an expression. It is also possible to print the big bang code on the sheet surface with a special fluorescent material that is invisible to the human eye and project the infrared rays to read the code.

[0022]

As described above, according to the big bang code system of the present invention, it is possible to optically read the intersection of the circumferential line forming the polar coordinates and the radiation or the area defined by the circumferential line and the radiation. Since the bit information is recorded, the bit information is arranged concentrically with respect to the polar coordinate center (the origin of the big bang), for example, from the inner circumference side to the outer circumference side or vice versa in the circumferential direction. Alternatively, by arranging the bit information in the radial direction in the order of clockwise or counterclockwise on the radiation extending in all directions from the coordinate center, a plurality of bit information can be arranged according to a certain rule. The code data represented as a set of bit information that is stored is contained inside the circumference of the maximum diameter around the center point of the polar coordinates, so the circumference of the maximum diameter is used as the spot diameter. The data can be read in spots, and information can be displayed as a power of 2 at the number of intersections of the circumference and the radiation. Therefore, the information density per unit area is extremely high. The information that was displayed by the vertically or horizontally long conventional two-dimensional code can be aggregated and displayed in the small circles, and it can be read in spots. For example, a wrap for packaging uneven products. Even if it is recorded on paper, it can be read accurately and easily without error, and since the big bang code is not a special shape that gives the viewer a sense of discomfort, it has an excellent effect such as being aesthetically pleasing. Play.

The big bang code reader of the present invention includes a light emitting element which projects a light beam forward in a state of being opposed to substantially the center of the circumference of the big bang code, and the bit information existing in the optical path, which is reflected light or A polar coordinate formed by a plurality of concentric circles arranged circumferentially and a plurality of radial rays radially extending from the center of the circumference line, because a light receiving element for discriminating light from the other depending on the presence of transmitted light is provided. According to the chart, by arranging a plurality of light receiving elements at equal intervals on the circumferential lines of different diameters arranged concentrically at the pitch necessary for the identification and reception of bit information, the light emitting elements arranged at the center of the concentric circle The emitted light beam can accurately receive the light beam reflected by the bit information, and at that time, the centers of the big bang code and the big bang code reader are correctly aligned. Therefore, even if the big bang code reader is twisted topologically around the line connecting the centers, there is no problem in reading, so even though it is a two-dimensional array, it is possible to read accurately and easily with spot alignment. There is an effect such as being able to.

Furthermore, the big bang code reader of the present invention is provided with an image sensor for picking up a big bang code by two-dimensional scanning and a decoder for decoding the output of the image sensor by pattern recognition. Since the big bang code is read using imaging technology, the facing relationship between the image sensor and the big bang code is not restricted by the strict condition that the centers strictly face each other, and the big bang code is even included in the image sensor frame. By doing so, all bit information can be imaged without leaking finely without reading errors, and the bit information is decoded by pattern recognition in the imaged data, so the bit information arranged on the circular coordinates is accurately recognized as image data. It has the effect that it can be decrypted.

[Brief description of drawings]

FIG. 1 is a plan view showing an example of code data recorded according to a big bang code system of the present invention.

FIG. 2 is a plan view showing another embodiment of code data recorded according to the Big Bang code system of the present invention.

FIG. 3 is a schematic perspective view showing an embodiment of a big bang code reader of the present invention.

FIG. 4 is a vertical sectional view of the big bang code reader shown in FIG.

FIG. 5 is a schematic perspective view showing another embodiment of the big bang code reader of the present invention.

FIG. 6 is a diagram showing a correspondence table of Kalura codes and ideographic numerals.

FIG. 7 is a schematic perspective view showing an example of a conventional Carula code reader.

[Explanation of symbols]

 11, 21, 32, 42 Big bang code 12,22 Polar coordinate chart 13,23 Bit information 51,61 Big bang code reader 53 Light emitting element 54 Light receiving element 64 CCD image sensor 65 Decoder

Claims (4)

[Claims] 1. A polar coordinate chart formed by a plurality of circumferential lines arranged concentrically and a plurality of radial lines radially extending from the center of the circumferential line is a recording surface, and the circumference on the polar coordinate chart is a recording surface. A big bang code method that records optically readable bit information at the intersection of a line and radiation. 2. A polar coordinate chart formed by a plurality of circumferential lines arranged concentrically and a plurality of radial lines radially extending from the center of the circumferential line is used as a recording surface, and the circumference on the polar coordinate chart is a recording surface. A big bang code method, which records optically readable bit information in an area divided by lines and radiation. 3. A big bang code reader for reading a big bang code in which optically readable bit information is recorded on a polar coordinate chart, and a light beam is projected forward in a state of being opposed to substantially the center of the circumferential line. A big bang code reader, comprising: a light emitting element; and a light receiving element for discriminating the bit information existing in the optical path from the other by the presence or absence of reflected light or transmitted light. 4. A big bang code reader for reading a big bang code in which optically readable bit information is recorded on a polar coordinate chart, and an image sensor for imaging the big bang code by two-dimensional scanning.
A big bang code reader, comprising: a decoder for decoding the output of the image sensor by pattern recognition.