JP2002514329A - Robust machine readable symbology, and method and apparatus for printing and reading based on the symbology - Google Patents

Abstract

(57) Summary The new barcode symbology in the illustrated embodiment uses three bars (and spaces) in nine modules, similar to code 93. 53 data characters including a plurality of special mode characters are defined. By using such special mode characters with a given routine, three symbolic characters can represent two 8-bit bytes or one 16-bit word. As a result, this symbology can efficiently encode 8-bit bytes for use in computer processing, or encode a 16-bit character set such as Unicode. This symbology encodes extended channel interpretation (ECI) numbers, provides multiple numerical compression modes, and provides structured additions using single mode characters as well as other features. Further, the symbology includes error correction, and a special function flag character indicates the use of error correction within the symbol.

Description

DETAILED DESCRIPTION OF THE INVENTION                   Robust machine readable symbology, and        Method and apparatus for printing and reading based on the symbol system Technical field   The present invention relates to a new machine readable symbology, and to reading symbols based on the symbology. Apparatus and method for printing or printing. Background of the Invention   The bar code symbology was first described by Kermode in US Pat. No. 5, issued shortly thereafter in the 1930s by Young, Expanded in 2020925 and assigned to Westinghouse. This Such early symbologies were separated by a highly reflective element or "space". Printed by creating a large number of low reflectance single width elements or "bars" Had been. One "element" is a bar or space. This early symbology Many of the “barcode symbologies” currently used by Rabi are called “linear symbologies”. Can be called. Because the data in a given symbol is one axis or one direction Because it is decoded along.   Symbolic systems, such as the linear symbology, use “data characters” (such as “symbol characters”). (For example, human-readable characters), which typically encodes certain data characters. Alternating bars and spaces to form unique pattern groups for encoding They are arranged in parallel. "Data characters" not only include human-readable characters, , A start character, a stop character, or a shift character to provide the given function data. Also includes special function characters. Each unique group of bars and spaces within a given width Group or pattern defines a particular symbolic character, and therefore one or more Define a specific data character for.   Known U.S.A. P. C. The symbol system is generally described as “n, k code” in (7, 2). Can be described. "N, k code" is a bar with "k" symbols Defined as a symbolic system that has spaces and whose total length is the length of the "n" module Have been. Therefore, U.S. P. C. The symbology is two bars in each symbol letter Encode two spaces, each symbolic character is 7 modules in length. "Moji "Tool" is the narrowest nominal unit of measure in bar code symbology (width Is 1 bar or space). "Nominal" refers to any Means the expected value of a given parameter. In a general counting technique, 7 modules There are 6 places where transitions can occur in the le, two bars and two spaces In this case, by recognizing that there are three internal transitions, Can be found. Therefore, U.S. P. C. Unique symbol characters for symbology Is simply six choices three, which corresponds to twenty. Similarly, the (11,3) symbol In the code 128 symbol system, 252 unique symbol characters are available. Yes (10 choices 5).   U. P. C. , EAN, Code 11, Barco known as Codabar Each of the punctuation schemes has a numeric data character and some characters, such as "+" and "-". It is a bar code symbol system standard that supports only special characters. U. P. C. symbol The scheme is based on the industry adoption of standard applications (consumer goods). It is an industry standard as well as a code standard. Code 39 which is a barcode standard Is the first alphanumeric barcode symbology standard developed. But this is 4 It was limited to three characters.   Code 93 is a modification of code 39. Code 93 has four elements A continuous barcode symbology that uses width. Each symbol of code 93 is black or 9 modules that can be either white (either a bar or a space) Have Each symbol of Code 93 has three bars and three spaces (six required And its total length is 9 modules long. Code 93 per symbol It has 9 modules and 3 bars and therefore has 56 characters (9, 3) Symbolic system (8 choices 5). For edge-to-edge decoding reasons, The 93 Code Standard defines only 48 unique symbols, and therefore Forty-seven characters in the character set and start / stop codes can be defined. This 4 The seven characters are the digits 0-9, the letters AZ, some additional symbols, and the four characters. Code.   The computer industry has a proprietary character encoding standard, the United States for information exchange. Standard code (ASCII) is used. ASCII is written as 128 characters. Define the character set that contains the number. Each ASCII character is converted to a unique 7-bit code Is represented by Codes 39 and 93 are limited to less than 50 characters These standards are inadequate to unambiguously represent each ASCII character. However, With four shift codes in code 93, this standard allows all 128 ASCI The I character can be unambiguously represented. One disadvantage is that it represents a single ASCII character Requires a series of two symbols in code 93. Therefore, AS Bar code labels that represent characters in the CII character set are in the character set with code 93 Is twice as long as the label representing the character   New codes such as code 128 to encode the complete ASCII character set Bar code symbology standards have been developed, and such standards represent certain characters. Given disadvantages, including the need for shift codes or other leading symbols to There is. All of these symbologies operate on the entire ASCII character set. The processing time and overhead required for   The computer industry has grown beyond the limits of the ASCII character set. Con As the pewter market grows, it is not defined by the ASCII character set. There is also a need to support additional languages. Dealing with groups of characters in related languages A new character set has been developed to do this. Original 7-bit ASCII character set Is expanded to 8 bits, thus providing an additional 128 character or data values are doing. This additional 128 sets of data values ("top 128" or "extended A" SCII ”) is the relevant Romance language to be represented (ie, French, German Language, Spanish, etc.).   The only linear symbology that can encode 8-bit data is code 128 and "code". 53, which is described in “Single Width Bar Cod”. e Symbolology With Full Character Set Utilizing Robust Start / Stop Character rs and Error Detection Scheme " This is described in the inventor's US Pat. No. 5,619,027. Code 128 and code Code 53 can be 8-bit by using single or dual function shift characters. Data, thus increasing processing time and overhead required I do. That is, do not analyze every byte value before encoding the data characters. Because it must be.   However, as the computer market grows internationally, more languages are written. It has to be included in the character set. Especially in the Asian market, thousands of unique Requested a character set available on the computer that supports characters. To clearly define each of these characters, a 16-bit coding standard was developed. Was needed.   Multiple 16 bits such as Unicode, JISC-6226-1983, etc. A coding standard has recently been developed. The Unicode character encoding standard has a unified fixed length A text character encoding standard. The Unicode standard allows up to 65536 characters Can currently include Greek, Hebrew, Latin, Japanese, Chinese, Over 28,000 mappings to scripts in the world including Korean and Taiwanese Contains characters. The Yuncode standard is modeled on the ASCII character set. Unicode character codes are consistently 16 bits long, regardless of language Therefore, when specifying any character in any language, escape sequences or No control code is required. With Unicode character encoding, various Symbols and English language symbols for simultaneous and equal ease of use in computer applications. Letters and ideographs are treated similarly. Use Unicode character encoding to represent characters Computer programs that do not display or print text Even if you introduce a script or character, it can survive without change.   New computer operating systems, for example, Redo, Washington WINDOWS NT, manufactured by Microsoft Corporation of Monde, provides such a package. It has begun to support the generic 16-bit code standard. But the data collection industry I couldn't keep up with the computer industry. 16-bit compilation Systems for easily encoding computer character codes into barcode symbols are currently available. Not at all. Therefore, the data collection industry, especially For such signal systems, such 16-bit computer character standards are supported. There is a need.   In addition, it is used to encode a long series of numbers or lowercase alphabetic characters. In most cases, most alphanumeric barcode symbologies are inefficient. For example, code 93 If you encode a series of decimal numbers using Does not use the bar code symbol. Therefore, such an alphanumeric bar There is a need for code symbologies to be more efficient at representing long sequences of numbers. You. In addition, many symbologies do not have error correction capabilities.   One of the known symbologies, the IPC symbology, has other symbols adjacent to the IPC symbol. And, in some cases, whether to include data associated with the IPC symbol. IPC The parity arrangement in the symbology data set indicates the presence of such adjacent symbols. You. The IPC symbol system is a fixed width numerical symbol system. P. C. Symbolic field As used in Unified Code Council (UCC) applications. IPC symbol system Is a fixed width, so that only a fixed number of characters can be encoded in one symbol. No. In addition, such symbols can only encode numeric data characters. No. As a result, the IPC symbology is limited to only a few data collection applications. Summary of the Invention   The present invention solves the above problems and provides additional advantages. One of the present invention In embodiments, the group shift function allows lowercase letters, numbers, and other lowercase letters. A string composed of ASCII characters can be efficiently decoded. Was For example, in the case of a group consisting of 10 of these lowercase letters / numbers , Can be decoded within a range of 10.8 modules per symbol character.   In other embodiments, error correction or special function flags may be used to combine one symbol Can indicate the error correction character. Special function characters are in the middle range of the symbol Followed by a message length indicator character. In the illustrated embodiment, , A symbol that uses error correction contains five error correction characters, thereby providing two Errors or three erasures can be corrected in the symbol. In addition, the symbol You can correct the start or end, and code the symbol in half. To be able to.   In the symbolic scheme of other embodiments, a simple byte that works uniformly on any byte value By describing the coding mode, 8-bit and 16-bit data can be Avoid complex ways of coding. In the illustrated embodiment, the symbology is a code Similar to 93 symbology, so symbolic characters are only 9 modules long become. Three symbol characters encode two 8-bit bytes. Therefore, Regardless of the byte value, one byte requires about 13.5 modules. Example In some embodiments, a string of digits or base code 93 data characters For example, the number of modules for encoding data characters can be further reduced. It is possible.   In an embodiment of the present invention, the extended channel interpretation (ECI) number is formally coded. It is. As a result, the host computer system to which the reader can be coupled is Regardless of the underlying character set or application used by the computer, Coded messages can be clearly decoded anywhere in the world. 16 Bit characters are represented by three characters according to the exemplary symbology, two in other modes Are represented by three symbolic characters. Two 8-bits within three symbol letters The extended ASCII data characters as well as the ISO series Other relatively small international character sets such as 8859-1 to 8859-9 Can be hardened.   In a broad sense, the present invention implements a machine readable symbology having a plurality of symbolic characters. It is. This machine readable symbology uses fewer symbols in groups of symbolic characters. Error correction flag symbol statement indicating that at least one error correction symbol character is present Including characters.   Further, the present invention implements a machine readable symbol system having a plurality of symbol characters. And a group of a plurality of symbol characters forms a printable symbol. This machine The readable symbol system is a special function that indicates a first function at a first position in a printable symbol. Contains flag symbol characters. The special function flag symbol is placed in the second position in the printable symbol. A second function is shown. In addition, the symbology is based on the starting character of code 93 and Stop characters and symbols with character values that exceed those of the standard code 93 symbology Two unique start and stop characters to identify and a note with error correction And any related signs or accompanying notes, usually located adjacent to or near the current sign Combinations of symbols with symbols can be used. Further, various aspects according to the present invention , A method and apparatus for printing and reading machine readable symbols and other aspects of the invention The embodiments and aspects of the present invention are also implemented. BRIEF DESCRIPTION OF THE FIGURES   FIG. 1 illustrates human-readable characters that are printed or read according to one embodiment of the present invention. 5 is an example of a label having a bar code symbol character provided.   FIG. 2 is an exemplary symbology according to the present invention, where symbolic values, associated symbolic characters, and 6 is a table showing data characters.   FIG. 3 shows an exemplary symbolic character format.   FIG. 4 shows the bar code symbol of FIG. 1 in which each symbol character is identified by its associated data character. Is shown.   FIG. 5 illustrates a complete ASCII data character that can be encoded according to the symbology of FIG. It is a table shown.   FIG. 6 is a block diagram of the barcode symbol printing apparatus of the present invention.   FIG. 7 illustrates an example of the printing apparatus of FIG. 6 for printing barcode symbols according to one embodiment. 3 is a flowchart showing basic steps executed by the user.   FIG. 8 is a block diagram of the bar code symbol reading device of the present invention.   FIG. 9 is a diagram illustrating a reading device according to an embodiment of the present invention. 3 is a flowchart showing basic steps executed by the user.   FIG. 10 is a schematic diagram of a 93i symbol using an error correcting character.   FIG. 11 is a schematic diagram of a 93i symbol having adjacent associated symbols.   FIG. 12 is a block diagram of the 93i symbol and the associated two-dimensional symbol.   FIG. 13 is a block diagram of the 93i symbol and the accompanying RF tag.   FIG. 14 shows a 93i note where the accompanying PDF417 symbol is positioned over the 93i symbol. Number.   FIG. 15 shows a 93i symbol in which the associated code 49 symbol is positioned to the right of the 93i symbol. Is shown. DETAILED DESCRIPTION OF THE INVENTION   In general, the following definitions apply herein. "Data characters" are symbols, Human readable, including numbers, alphabetic characters, and ideographic characters Characters and unreadable data such as function calls and shift codes . "Numeric string" refers to a sequence of numbers, usually decimal digits. "Letter A "code" is a set of character codes and data in corresponding data characters such as ASCII. A code that points to a data character, usually a number. In this case, "8-bit code" , An extended ASCII code corresponding to an ASCII standard data character, "16 The “bit code” or “16-bit character code” is a code such as Unicode. Refers to the hexadecimal or decimal representation of the data characters of the 6-bit character encoding standard. "Barcode symbology" means a set of machine-readable characters that uniquely represent a set of data characters Refers to possible characters or symbolic characters. “Symbol value” refers to the data in the barcode symbology. Refers to codes, such as ordinal numbers, that represent data characters. “Symbol character” refers to a specific data character The unique geometry or bar and bar and symbology used in the barcode symbology to represent And space pattern. “Barcode standard” is recognized in data collection applications. Refers to barcodes that are known or commonly used (eg, C mode128, Code93). "Count" is data in bar code symbology A unique set of electrical signals generated when reading a symbol character corresponding to a character You.   For example, in the 16-bit character encoding standard Unicode, the data character "A ] Is represented by a 16-bit code “0041” in hexadecimal notation, and in decimal notation. Is represented by "65". The data character "A" is a bar code symbology Code 9 3 has a symbolic value of "10". The symbol value 10 of Code93 is 2 module width Bar followed by single module width space, single module width bar, single Module width space, single module width bar, and 3 module width space Corresponding to the symbol character having the pattern   The count associated with printing this symbol is generally unique to each printer and In the case of multiple printers, when the thermal paper exceeds the heating element of the printer, Represents the time interval between transitions between bars and spaces for proper activation. this In that case, the bar is positioned perpendicular to the direction of the label passing through the printer. Alternative And the count is when the bar is parallel to the direction of the label passing through the printer It can indicate which dot or thermal print element is to be activated.   A new bar code symbology or linear symbology according to embodiments of the present invention In the description, this is generally called “93i”, and each of 16 bits in a 16-bit character code is used. Efficiently encode data bytes and words to uniquely represent bit codes And encode the ECI characters, as well as additional features described in detail herein. Execute. FIG. 1 is printed or read according to the 93i symbology. An example of a label 101 is shown below. As shown in FIG. 1, a label 101 is composed of data characters. A series of barcode symbols to be coded and the human being printed by the barcode symbols Contains the corresponding characters that can be read.   The 93i symbology is similar to Code93. As a result, the 93i symbol system Encodes numbers, alphanumerics, and all 128 ASCII characters. Also, 93 The i symbology consists of extended ASCII characters and character sets represented by 16-bit character codes. Encode all international character sets, such as The 93i symbology is continuous And this scheme has six bars per symbol, including three bars and three spaces. The following symbolic structure with three elements is used.   Characters based on the 93i symbology are not self-checked and the symbol length is variable. 93i The coding scheme uses two symbol check characters or optional error correction characters. 93 The i symbology uses the equivalent of 37 modules as non-data overhead I do. Importantly, the 93i symbology has 5.4 modules per number, 9 modules per symbol character of alphanumeric data, (ISO8859 8 bits Full (as defined by the single-byte coded graphic character set standard) 13.5 modules for ASCII and extended ASCII, lower case and Up to 10.5 modules for other ASCII lowercase strings, and 27 modules per Asian or 16-bit character code character To allow data character densities such as Also, this symbology is Supports the Interpretation (ECI) protocol (described below) and uses the existing Code93 symbology Fully compatible with.   FIG. 2 shows the symbol character assignment for each data character in the 93i symbology. Figure The “value” column of 2 represents the symbol value for each symbol character. As described herein In addition, the symbolic value is only used to calculate the check character or error correction character. Instead, it is also used in various data compression methods. The “character” column in FIG. Is a column that lists alternating bar space patterns for "1". In this case, "1" Corresponds to one module, "2" corresponds to two modules, and so on. is there. Each letter starts with a bar. The “data” column in FIG. 2 shows the base corresponding to each symbol character. Indicates the function of this data character or symbol character. As shown in FIG. 46, and the corresponding symbol characters and data characters are in Code 93 symbol system. Corresponding symbolic value, symbolic character, and data character, and starting symbolic character and Matches a stop sign character.   The 93i symbology also uses unique start and stop characters. Start statement The characters consist of bar and space patterns 2,1,3,1,1,1. With an additional two-width bar at the end, That is, 2,1,3,1,1,1,2. Such alternating characters and stops Stop characters distinguish this symbology from the Code93 symbology, facilitating out-of-focus decoding. For example, a character having a width element at a start position and an end position of the character is formed. Place In some cases, and more importantly, the two available start and stop characters are Allows four different types of characters to be valid.   The first valid symbol type begins with a Code93 start character and a Code93 stop. Include all symbolic characters ending with a stop character and having a character value less than 47 The data character sets A, B,. . . , Followed by the character value in Z . The second valid symbol type begins with a Code93 starting character and is greater than 46 At least one character value or at least one shift character followed by A, B,. . . , Z, a character having a value smaller than 47, for example, Code 93 includes an undefined character string and ends with a 93i stop character.   The third valid symbol type begins with the 93i starting character and is based on the 93i symbology. The special function flag (described later) is included in the center of the symbol End with a Code93 stop character. The third valid symbol is a 93i error correction symbol is there. A fourth type of valid symbol begins with a 93i start character and a 93i stop character. End, including any data character combination, but this start / stop character combination Indicates that the symbol is present. For example, 93i start character and 93i stop character The 93i symbol has a line at or adjacent to the 93i symbol. Indicate to the reader that a scannable symbol is located, typically within a 93i symbol. Contains coded data for the coded data. About the usage of comparison symbols Will be described more fully below.   The following table summarizes the start / stop character combinations based on the 93i symbology. You. In the table below, “C93” refers to the Code93 start / stop character, “EC” indicates error correction.   Adjacent tag indicating function (to be described later) can be used with any 93i start / stop character combination. Please note that All character sets not explicitly defined in this specification The match or mode value is invalid and causes the decoding operation to fail.   Unique start and stop characters in 93i symbology and Code93 symbology By using characters having character values that exceed the character values of the system, At least two pattern changes are required to confuse the standard Code93 symbol. You. For example, a 93i start character or a 93i stop character, and greater than 46 Characters with values are Code93 start / stop characters, and values less than 46 Must be interpreted as having Also, check characters are usually 93i symbols Must be misinterpreted as being interpreted as a standard Code93 symbol.   Unlike the Code 93 symbology, the 93i symbology uses 53 symbol values. You. In contrast, the Code 93 symbology uses 47 symbol values. Ingredient Physically, the 93i symbology adds a symbolic value 47-52 and two starting characters. . The first start character starting with the bar space bar pattern 2,1,3,1,1,1 is , This symbol is a 93i symbol, and therefore can include symbol values 47-52. Show that you can. 93i two characters separated by a single width space within the start character By using a wide bar, the reader is resolved to a single width space Determining whether a symbol is in focus by determining whether it can. If the reader identifies a five-width bar within the 93i start character, the reader will: Since the one-width space is not resolved, it is determined that this symbol is likely to be out of focus. You.   Another starting character is the same as the starting symbol in the Code93 symbology, and is a valid Co Use only the de93 symbol character to indicate that this symbol is coded. Evenly Code 9 for mixed alphanumeric messages using only uppercase letters The three symbology provides the most efficient character density, and therefore Preferable.   As shown in FIG. 3, the symbol character structure for each symbol character in the 93i symbol system is Nine modules use three bars and three spaces. Each bar or The width of the space is one module, two modules, three modules, or four modules. C As in the case of the ode93 symbology, the 93i symbology is equivalent to ten times the X dimension. Head zone (QZ) with the largest width, one of the two start symbol characters, Or multiple symbol character coded data characters, two symbol check characters ("C" and "K"). ), A stop symbol character, and a terminal quiescent zone. The symbols are described below. The error correction flag or special function flag and message length Indicator and five error correcting characters. Figure 4 shows each symbol letter Individual vertical lines, with a short vertical line between them and the corresponding data character for each symbolic character. The symbol character (without error correction) of the label 101 analyzed into the symbol character is shown.   As pointed out above, each 93i symbol consists of the two immediately preceding stop symbol characters. Including the check character. The check algorithm uses mod for all symbol values in a symbol. 53 sum is used.   As in the Code93 symbology, the check character "C" is the symbolic value shown in FIG. Is calculated based on the value obtained by multiplying the modulo sum of the product of Immediately before Weighted sequence from right to left (stop symbol character to start symbol character) starting with letter Are repeated sequences 1, 2, 3,. . . , 20, 1, 2, 3,. . . , 20 , 1, 2,. . . ,. The check character "K" is the modulo sum of the product of the symbol values and Generated based on different weighted sequences, in this case starting with the check character "C". The right-to-left weighting is repeated sequence 1, 2, 3,..., 15, 1, 2, 3,. .., 15, 1, 2,. . . It is. Start as in Code93 symbology Symbol characters and stop symbol characters are not included in the check character calculation.   For example, given the symbols in FIG. 4, the data characters are from left to right, 9, 3, i, [ ECI16], {30908}. "[ECI16]" is the ECI value 0000 16, "{30908}" is a Unicode standard 16 bit Asian characters (pronounced approximately "MA") You. In this specification, the term “symbol” used alone alone is indicated on label 101. Refers to a set of such symbolic characters. Numeric data characters "9" and "3" The data character "i" is encoded with a shift character (as described below). Must be changed. As used herein, the term "letter" used alone Refers to a data character or its corresponding symbolic value. [ECI16] Data character Is formed by two symbolic characters, whereas the Asian character {30908} Use word mode.   Simply put, the value 30908 is the formula (16 * 43^Two) + (30 * 43) +34 Coded by This results in symbolic characters that encode the data. The symbol values of the character string obtained by [09] [03] [46] [18] [47] [1 6] [50] [16] [30] [34]. Check character algorithm above When used, with the appropriate weights, the total for the right-to-left check character "C" is used. The calculation is as follows.   “C” = (10 × 9 + 9 × 3 + 8 × 46 + 7 × 18 + 6 × 47 + 5 × 16 + 4 × 50 + 3 × 16 + 2 × 30 + 34) mod 53         = 1315mod53         = 43 Similarly, the check character “K” is calculated from the weight including “C”.   “K” = (11 × 9 + 10 × 3 + 9 × 46 + 8 × 18 + 7 × 47 + 6 × 16 + 5 × 50 + 4 × 16 + 3 × 30 + 2 × 34 + 43) mod 53         = 1627 mod 53         = 37   As mentioned above, the 93i symbology uses some special characters. Code As with the 93 symbology, the 93i symbology has symbolic values 43-46 shown in FIG. Are used for the four shift characters [S1]-[S4]. Symbolic value of 10-35 The preceding shift character is a single full ASCII data statement as shown in the table of FIG. Character. Character combinations [S3] A to [S3] Z in the second column of FIG. 5 are valid. And the 93i symbology uses the ASCII character associated with the single character shown Can be used to generate. For example, the data character "Q" It can be represented by a symbol value [81] or two symbol values [S3] [81]. X, All character pairs [S2] with Y or Z code ASCII value DEL (deleted). Be converted.   A shift character [S1]-[S4] followed by a symbol value 0 to 9 or 36 to 46 A sequence of 3 to 23 shift characters based on a particular initial shift character A string or sequence is shown. As shown in FIG. 5, character spaces (sp), ＄, %, +,-,. , /, And the numbers 0-9 are not shifted, Not used to form. Thus, such a character would have character values 0-9 And 36-46 to implement an additional function, the group shift function. Can be used. The number of characters shifted in the group is shown based on the table below. Is done.In this case, "[S?]" Corresponds to one of shift characters [S1]-[S4]. Word In other words, one of the four shift characters [S1]-[S4] and the subsequent symbol value 0-9 or 36-46 implement a latch function for a predetermined number of subsequent characters, Characters are latched into corresponding shifted values based on the initial shift character . For example, when encoding the data “Modulo53”, the 93i characters “M [S4] [S2] ODULO [sp] 53 "are used, and these characters are symbolic values "22, 46, 02, 24, 13, 30, 21, 24, 38, 05, and 03 ".   (1) when shifting one subsequent character based on the preceding shift character, or Or (2) the characters are now grouped into the same set as the set indicated by the initial shift character. Shifts one subsequent character to the basic 93i character set if it has been shifted Sometimes a single shift character can be used within a group of shifted characters . Both the shift character and one subsequent character in the character to be shifted are included in the group length in Table 1. I will. The “shifted character string” and “shifted character” are shown in the table of FIG. Data obtained using one of the shift characters [S1]-[S4] based on Refers to a character string or individual data characters.   For example, when encoding a data message "Module53Math" In this case, the following 93i characters are used.     "M [S4] [37] ODULO [sp] 53 [sp] [S4] MATH"   Character value [37] is based on Table 1 above, and the following 14 characters are added to the table of FIG. Note that it indicates that it is shifted. Shift character [S4] is 14 This shift character in this group because it is contained within the string of characters to be shifted. Characters immediately after are not shifted or matched to the basic 93i data character set. Respond. If shift characters [S1]-[S3] are used instead, Characters according to the table in FIG. 5 based on which of the three shift characters was used. Is shifted. Character value 0-9 (corresponding to data characters 0-9) or (data Character-,. , Sp, ＄, /, +,%) character values 36-42 are shifted Such character values are shifted if they appear within a symbol surrounded by Note that it is encoded directly as part of the character. The string to be shifted You can use numeric mode characters or function 1 (FNC1) characters (described below) within Use ECI, byte-mode, and word-mode characters (described below). Cannot be used.   The 93i symbology is a defined meaning of bytes or subsequent data within a given symbol. Uses ECI character [47] with symbolic value 47, which encodes information about the taste I do. The AIMI ECI Assignments document contains the number of ECIs and the ECI Assign byte or data meanings based on numbers. Is the number of ECIs 0,000,000 511799. For example, one ECI number is the international character set Represents the encoding. The 93i symbology places the ECI number anywhere in the symbol, 1, 2, 3, or 4 symbol values selected from symbol values 0-51 of 2 The ECI number is coded by placing it after the CI number.   The backlash character "@" (reverse hatching) has an ASCII value of 92 (see FIG. 5). ), Transmitted before the 6-digit ECI value. Backlash characters, symbols are read A host computer that receives a string of symbolic values or data generated when taken Serves as an escape character to the computer or system. In coded data When placing a backlash character in a file, use a single backlash instead of the ECI value. Two backlash statements in the symbol so that the host knows that a character is needed Characters must be coded. Similarly, you need two backlash characters In some cases, the host must know that two backlash characters are needed. One backlash character must be encoded. 93i symbology Table 2 below shows the rules for encoding the ECI number by using the following method.   Briefly, for ECI numbers 0-899, such a number of subsequent bytes or Is directly coded even if the data can be compressed in other ways. And For example, the ECI number 89 can represent the start position of a specific type of encrypted data. You. Subsequent encrypted data is compressible but directly encoded. I But encode a digit or all ASCII characters after the ECI number 0-899 In this case, use numerical mode or byte mode (described below), thereby The 128 lower ASCII values shown and the corresponding symbol values can be used . ECI in the string of data characters encoded in word mode (described below) When encoding a number, all 128 ASCII values are added to the 8 Used with zero. ECI characters 900-81799 are the most efficient mode And the word mode characters ([50]) are prohibited. Was For example, for the ECI number 950, a string of 93i symbol values 0-9 is encoded. If required, the value of the data character must be in the mode specified by ECI 950. The numeric mode is used even if it does not correspond to the number used in.   Table 2 below shows the rules for encoding ECI values according to the 93i symbology. It is a summary. In Table 2 below, “div” refers to the integer division operator, On the other hand, “mod” indicates a modulo division operator. "C1" is the highest position , Whereas “C4” refers to the lowest position.  For example, when encoding the ECI value 000020, [47] [20] One string is used, where [47] is the ECI symbol value 47 and [20] ] Is a 93i character “K”.   When encoding the ECI value 002000, the following three steps are taken. You get the characters you need.   [47] [45] [(ECI_val-96) div 52] [(ECI_v al-96) mod 52] =   [47] [45] [1904 div 52] [1904 mod 52] =   [47] [45] [36] [32]   Finally, when encoding the ECI value 200000, follow these steps: To get the four required characters.   [47] [(ECI_val-2801) div 140608 + 46] [(( ECI_val-2801) div 2704) mod 52] [((ECI_val-2801) val-2801) div 52) mod 52] [(ECI_val-280) 1) mod 52] =   [47] [197199 div 140608 + 46] [197199 d iv 2704 mod 52] [197199 div 52 mod 52 ] [197199 mod 52] =   [47] [1 + 46] [72 mod 52] [3792 mod 52] [ 15] =   [47] [47] [20] [48] [15]   The symbolic value 48 is the number of Code 93 symbologies referred to herein as "numerical mode". Indicates the value calculation mode. In numeric mode, five numbers are compressed into three symbolic characters You. Therefore, use the 5/3 numeric mode to compress a sequence of five or more digits. Should be reduced. The numeric mode character, symbol value 48, is a 5/3 numeric compression mode. Mode and end this mode. Similarly, byte mode characters and And word mode characters, ie, numbers using the symbolic values 49 and 50, respectively. You can also exit the mode. If the symbol ends during numeric mode, There is no need for a terminating character.   In numeric mode, five numbers are represented by three symbolic characters, in this case the symbolic characters Have symbol values in the range 0-47. These five character strings are Is generated by the following equation.         A * 48^Two+ B * 48 + C (1)   In the above equation, A, B, and C are 93i symbol values. Greater than 5 but 5 When encoding a string of numbers that is not an exact multiple of Should be applied. First, a single number greater than a multiple of 5 in a string is simply Coded directly by one symbol character (symbol values 00-99). Second, this If the numeric string contains two numbers greater than a multiple of five, the last seven numbers , A set of four numbers, followed by a set of three numbers. these The numbers are represented as described by the third and fourth rules, respectively, below. You. Third, if this numeric string contains three numbers greater than a multiple of five, the statement The three numbers at the end of the string are represented by two symbolic characters according to the following formula: You.                 48 * A + B (2)   Again, A and B are 93i symbol values. Fourth, this numeric string is 5 If there are four numbers that are greater than a multiple of ) Into three symbolic characters, in which case the result of equation (1) The values obtained are between 100,000 and 109999. Table 3 is from 12345 Exemplary 5, 6, 7, 8, 9, and 1 in the range 123456789 Zero number strings and the optimal resulting Indicates the symbolic value.   The ECI value is used as part of the numerical mode, where the symbolic value [47] is Does not invoke the ECI protocol, but instead is used in the 5/3 numerical compression method . The ECI value [47] follows the string of numbers coded by the numeric mode If so, you must first exit numeric mode before using the ECI value. Absent.   Symbol value 49 is a byte in the 93i symbology referred to herein as "byte mode". Indicates the mode. In byte mode, the 93i symbology is either full ASCII data or Efficiently encode character strings of extended ASCII data or straight byte data Be converted. "Byte" typically refers to an 8-bit data set. The following equation (3) ), Double bytes or two 8-bits for each of the three symbolic characters The bytes are coded.               A * 43^Two+ B * 43 + C (3) Where A, B, and C are 93i symbol values between 0 and 42.   In equation (3), there are two bytes with a combination value between 0 and 65535 (Ie, 2¹⁶= 65536). 65536 The resulting value of equation (3) between , Whereas the values 75535 to 76535 encode three numbers . As a result, the byte mode realizes a 3-digit and 4-digit numerical compression method, and the byte mode To improve the information density when encoding a character string of numbers in between. 76536 and The value resulting from equation (3) between 79506 is not defined and is Causes decoding to fail and an error signal to be output.   Use byte mode symbolic characters with symbolic value 49, as in numeric mode To enter byte mode and exit this mode. Byte mode is word Use mode symbol character (symbol value 50) or numeric mode symbol character (symbol value 48) By doing so. Also, shift characters [S1]-[S4] Has the symbolic values 43-46, causes the reader to exit byte mode, and Is added to the symbol value of. Therefore, after exiting the byte mode, the extended AS CII characters can be efficiently encoded. Similarly, 1 is placed at the end of the symbol. If one character remains and at the same time the previous character is in byte mode, the last character Is decoded with its symbolic value plus 128 (as in extended ASCII). It is. If the symbol ends during byte mode, the last byte mode symbol character (notation Existing mode characters, such as code value 49), are not required. Two characters at the end of the symbol If so, these two characters are replaced by their basic description, as if exiting byte mode. It is decoded with the signal value.   In the 93i symbol system, the symbol / character encoding efficiency is improved in the byte mode. Several coding schemes are allowed. For example, in byte mode, two extensions Encode Zhang ASCII data characters as a single group of three symbolic characters be able to. Even all ASCII data statements ending with an extended ASCII data character Characters or extended ASCII data characters in byte mode in the 93i symbology , A group consisting of three symbolic characters is used. Ends with an extended ASCII data character, Odd number data mixed with all ASCII data characters and extended ASCII data characters In the case of characters, an even number of characters is represented by a group of three symbolic characters, (Or only) data characters are encoded in one of two ways. First, If the last symbol character is an extended ASCII character, this symbol character is Is encoded as the full ASCII character following the shift character. Second, the last If the character is a single all-ASCII character, this character is directly coded and Followed by a byte mode character. In both cases, the last character has a symbol value of 128 To the basic character or shift character (symbol value 00-46 as shown in FIG. 2). It has the given value.   Table 4 below shows the optimal encoding of various strings of data characters in byte mode. Is shown. The symbolic value [49] points to the byte mode value, whereas [S? ]But, Recall that it represents one of four shift characters having symbolic values 43-46. I want to. In the third column of Table 4 below, the letters "A" through "F" are represented by the symbolic values 00-4 in FIG. Refers to any data character having a 2.   Numeric data character strings can be used between all ASCII data characters or extended ASCII When encoding between II data characters, the 93i symbology uses the symbol character density Additional coding schemes can be used to increase One or two Numeric data characters between all ASCII data characters or extended ASCII data When encoding between characters, the one or two numeric data characters A single total A with ASCII values 48 to 57 as shown in FIG. It is considered an SCII character. All ASCII characters from 3 to 9 numeric data characters When encoding between characters or between extended ASCII characters, 3 and 4 by the values 65536-75535 and 75536-76535 A group of two numbers is compressed. In other words, byte mode is used for all ASCI For 3- to 9-digit numeric strings in I or extended ASCII strings And perform sufficient numerical compression. However, when using a character string of 10 or more numbers, Exit byte mode and simply enter all ASCII characters or extended ASCII characters Numeric mode should be entered by supplying a numeric mode character [48] in the column is there.   One, two, three, or all characters in a string of all ASCII characters or extended ASCII characters Or encode four standard 93i data characters or basic 93i data characters In such cases, such elementary data characters are considered bytes. However, all ASCII Encode 5 or more elementary data characters in the middle of a character or extended ASCII character The byte mode character by first encoding the byte mode character [49]. End code, directly encode 5 or more elementary data characters, and then It is more efficient to re-enter byte mode using the code character [49]. below Table 5 shows the numbers arranged in the string of all ASCII characters or extended ASCII characters. Here is an example of a character string. In Table 5 below, character types are separated by hyphens. ing.   The symbol value 50 is a word in the 93i symbology referred to herein as "word mode". Indicates the mode. In word mode, three symbolic characters are replaced by three corresponding characters. Signal values are grouped to encode a single 16-bit value. Therefore The three symbolic characters encode Asian characters or 16-bit character codes Can be. Character codes up to 65536 are coded by the above equation (3). Is done.   The end of the word mode is determined by the word mode character [50] and the byte mode character [49]. ] Or numerical mode character [48]. In the case of byte mode, As before, the shift characters [S1]-[S4], followed by a single basic character, Or word mode ends with single symbol character and word mode character Then, 128 is added to the value of the single character. If the symbol ends during word mode No end character is required. If the previous symbol character is coded in word mode, The two symbol characters at the end of the symbol are decoded with their base values. Host is 8 When using the packet processing architecture, the byte mode reader has two Transmit consecutive bytes. However, if the host uses a 16-bit architecture ( (For example, double bytes are processed in parallel), the reader will Transmission of a single double byte of 16 bytes to the host using load mode Can You.   Also in this case, in the 93i symbol system, the coding efficiency is improved in the word mode. Several schemes are acceptable. For example, a sentence coded in word mode Numeric character strings surrounded by characters are processed in the same manner as in the byte mode described above. However, the value The string with 76536 through 76635 encodes two numbers. single If the number is surrounded by word mode characters, this single character is represented by [43] N. You. In this case, [43] is the first shift character S1, and N is a number. Wah Two, three, or four numbers enclosed in mode characters are for byte mode Is represented by an appropriate word mode value. Surround 5 numbers with word mode characters The word mode and simply encode the numeric mode character [48]. You should enter numeric mode with Single basic ASCII character, all ASCII When enclosing II characters or extended ASCII characters in word mode characters, This basic ASCII character, all ASCII characters, Or an extended ASCII character is represented. 2 or more full ASCII characters or extensions Exit word mode if encoding ASCII characters into word mode characters In this case, too, the byte mode is simply inserted by inserting the byte mode character [49]. Should enter the code. Table 6 shows numbers in word mode according to the 93i symbology. Here are some examples of efficiently encoding strings of other data characters. In Table 6 below, the values “25543” and “18776” are two different Unic ode 16-bit code. Character types in the second column are separated by a hyphen .   In the present invention, any standard 16 bit data character encoding standard, such as Uni code, JISC-6226-1983, Big Five (BF), KSC 5609-1987 can be used. JISC-6226-19 Reference numeral 83 denotes a Japanese Industrial Standard character set, which includes kanji data characters and katakana data. Map characters as 16-bit codes. This data character standard pointed out above As described above, Unicode including especially kanji data characters and katakana data characters Similar to e. However, each data character of JISC-6226-1983 has Different 16-bit codes for the corresponding data characters of the Unicode standard Hit.   The symbol value 51 represents a function 1 (FNC1) character of the 93i symbology. Number in the symbol The FNC1 character in the first, second, or third position, as known to those skilled in the art, Indicates that this symbol meets certain applicable standards. Position before FNC1 character Valid prefix character combinations are 0-9, AZ, 10-99, and az ([S4] A- [S4] Z). FNC1 statement at fourth or subsequent position The characters correspond to the group separator (<GS>) characters to be transmitted. FNC1 Appears in the symbol, and at the same time, the symbol is in numeric mode, byte mode, or word mode. Mode, exits numeric, byte, or word mode and returns The loop separator <GS> character is transmitted, and then the previous mode is entered again. That is, as in numeric, byte, or word modes), FNC1 characters are interpreted.   When printing symbols with leading spaces (symbol value 38), the reader will Until it encounters a symbol without a pace, it reads the symbol it reads, Is stored in the buffer together with the symbol. When you encounter a symbol without a leading space In the same manner as in the Code 93 symbol system, the entire contents of the buffer, All the symbols read in the buffer are transmitted. As a result, the long symbol Several (each except the last symbol) each with a leading space data character It can be divided into small symbols. Without calling the "Add leading space" function If it is necessary to give a leading space as the first data character in the symbol, the byte Mode should be used.   Read 93i symbol characters as described with respect to the exemplary decoding routine below. Reading / Decoding Reader Does Not Transmit Start, Stop, or Error Correcting Characters . As in the Code93 symbology, all characters are transmitted, whereas The character pair starting with one of the shift characters [S1]-[S4] is the single character pair in FIG. Only ASCII characters are transmitted. The 93i code system uses Asian character codes and The reader can encode other 16-bit character codes, so A 16-bit word is transmitted in the word mode. The reader is the word in the symbol Mode character [50] followed by all ASCII characters or extended ASCII sentence Characters or 93i data characters, all ASCII values 0-255 are downloaded. Transmitted as a bull byte, the first byte of eight zeros. to this In contrast, the second byte represents the coded ASCII data. Sign word The reader is configured to transmit double bytes without using the mode character [50] If not, all data in the 93i symbol will be Characters are read and transmitted as bytes. Therefore, the transmitted data When using a single byte, if the reader uses an 8-bit architecture , 93i symbology allows more efficient coding and transmission within this reader It is done automatically. When the ECI character [47] exists in the symbol, the word mode The same procedure is performed as for a character, except that one or more words Executed only in ECI data characters including mode characters.   The 93i symbology preferably uses a symbology identifier. 93i symbol system The symbology identifier is transmitted according to the nature of the data encoded in the symbol. This is the data prefix. In other words, the system identifier is read Options to be set for a particular symbology and reader, and It is a uniform way to report other features of this symbology and meet. AIM USA Symbolic Identity Guideline is a symbolic system The identifier is described in detail. The reader is transmitted from the reader itself Provision to add a symbology identifier prefix to a given data message. G can be. The specific coding system identifier for the 93i coding system is Cod This is the same as the symbol system identification for e93, that is, "JG". Otherwise Therefore, the 93i symbology can use unique symbology identifiers such as "ji". You. In this case, modifier data characters are added according to the following rules shown in Table 7 below. It is.  The modifier letter "m" corresponds to a particular applicable standard used and registered in the AIM . The modifier letter "m" is used because the FNC1 character is in the second or third position. Only when there is.   If the FNC1 character is encoded with a one digit prefix character followed by a second digit, Following the symbol identifier, 0, an ASCII value of 48, then an ASCII value of 48 to A byte of the encoded digit having 57 is transmitted. FNC1 character is a 2-digit prefix When encoded in the third digit following the hex character, the byte value of the two digits is the symbol in Table 7. Sent following the identifier. FNC1 letters are uppercase alphabetic letters AZ When encoded with the second digit following the prefix, one byte of alphabetic characters The value, i.e. the ASCII value 65-90, follows the symbolic identifier. FNC1 character is Encoded with the third digit following the uppercase letter [S4] and uppercase alphabetic characters And a small sentence having this pair of character ASCII values 97-122 in the first and second digits This one-byte value is transmitted following the symbol identifier. You.   The symbol value 52 is corrected for errors in the symbol according to the placement of special function flag characters in the symbol. Indicates a special function flag character that indicates the use of regular characters or a structured additional function. Special features If the flag character is centered on the symbol, the special function flag character is incorrect in the symbol Indicates the use of correction characters. The symbol immediately after the special function flag character is the message length of the symbol Is shown. In general, the 93i symbology has five error-correcting characters with symbol values 0-52. Use 93i symbol system is basic modulus 2 Galois field GF (53) , And generates a polynomial in which the error correction character is determined by the following expansion expression Use an error correction method.     (X-2) (x-4) (x-8) (x-16) (x-32)   Symbols that use error correction have a maximum length of 53 symbols, excluding start and stop characters. Character. The 93i symbology uses modulo 53 arithmetic, so Since symbols with more than three characters cannot be used, 46 Only data characters are allowed. Five characters correspond to error correction characters, and two characters Only 46 data characters correspond to the message length indicator and special function flags. Remains.   Use a printer, computer, or other The device can determine the message length L of the optimized message (various numbers under the 93i symbol system) Character, byte, word, and other modes) must be determined first. Message length L is start and stop characters, special function flag characters, message length characters , As well as the total length of the data message except for the five error correction characters. Special The special function flag character is placed in the digit following digit (L + 2) / 2. A message immediately after that A message length character having a symbol value L-1 indicating the length (1 to 46) is inserted. . Alternatively, the message length character has a value of L. Then, as shown in FIG. , Printer, computer or device computes five error correcting characters and produces five Two characters EC1 and EC2 of the generated error correction characters are placed after the start character. And the remaining three error correction characters EC3, EC4, and EC5 before the stop character. Put. Therefore, the resulting encoded symbol is the 93i start character, EC1, EC2, data (1 to 23 data characters), special function flag character SFlag, Message length character MsfLength, data character (0 to 22 data characters), E C3, EC4, EC5, and the stop character.   Examples of symbols using error correction characters are shown below. If the character value is "9, 3, 46, 18 , 16, 30, and 34 ", such strings have a length L = 8. As a result, the special function flag character is after the fifth digit, ((8 + 2) / 2 = 5, ie, Inserted at the sixth digit. The message length character is followed by 7 (ie, 8-1 = 7) has the character value. The resulting encoded message produces the polynomial "9, 3, 46, 18, 50, 52, 7, 16, 30, 34".   9x^Five+ 3x⁶+ 46x⁷+ 18x⁸+ 50x⁹+ 52x^Ten+ 7x¹¹+ 16x¹²+ 30x¹³+ 34x¹⁴   This polynomial uses a modulo 53 operation, where multiplication, division, addition and subtraction Are always in the GF (53) field, which has values from 0 to 52. correct To obtain the result, perform the appropriate arithmetic operation, and if the result exceeds 52, Continue subtracting 53 until the result fits in the fields 0 to 52, and Is less than 0, add 53 until the result fits in the field. For example , (-123), (-17), (89), and (407) are modulo 53 operations Then all are equal to (36).   Using modulo 53 arithmetic, the generator polynomial is x^Five+ 44x^Four+ 21x^Three+ 44x^Two + 50x + 39. The generator polynomial is replaced by the above encoding polynomial (ie, 34x¹⁴ + 30x¹³+ 16x¹²+ 7x¹¹+ 52x^Ten+ 50x⁹+ 18x⁸+ 46x⁷+ 3x⁶ + 9x^Five+ 0x^Four+ 0x^Three+ 0x^Two+ 0x + 0), the remaining polynomial becomes 13 x^Four+ 17x^Three+ 24x^Two+ 12x + 28. The complement of the modulus modulo 53 is incorrect. The correction codewords E5 to E1 are respectively "40, 36, 29, 41". And 25 ". Therefore, the final encoded characters are “25, 41 (EC1 and And EC2), 9, 3, 46, 18, 50, 52 (special function flag), 7 (message Long letters), 16, 30, 34, 29, 36 and 40 (EC3, EC4 and And EC5).   Is the special function flag character 52 always at the exact center of the odd data character , For even-numbered data characters, to the left of the center. Error with only one data character The correction characters EC1 to EC5 are further divided within the symbol. For example, one data statement In the case of a symbol having only the letter "D", an encoding symbol without a start / stop character is "EC 1, EC2, D, [52], [message length], EC3, EC4, EC5 " You.   Error correction under the 93i symbology can be up to two wrong characters, one wrong character And one or two unknown characters (deleted) or up to three unknown characters can be recovered . Therefore, one vertical broad stroke covering three data characters is Will be corrected.   In addition, the special function flag character is in the center, so errors under the 93i symbology The corrective method is to recover the loss of the beginning or end of the symbol including the start or stop character. Wear. Symbols are halved by providing a special function flag character in the center of the symbol And thereby effectively double its vertical redundancy (the UPC symbology). As if).   Because the five error correcting characters are divided into two groups within the symbol (EC1 and And EC2 are placed at the beginning and EC3 to EC5 are placed at the end.) Signs are more resistant to damage. For example, if all the error correcting characters are on one end of the symbol All error-correcting characters are dropped if placed and their edges obscured There is.   Special function flag characters and message length characters provide important data for symbols, It further provides an indication that the symbol contains error correcting characters within the symbol length. Special function By placing the lag character in the center of the symbol, the reader can tell where the center of the symbol is. It can be determined whether one end of the signal is damaged or missing. Message length characters and The reader, together with the rest of the error correction characters, can correct such damage (error correction). If the damage is not greater than the correctable correct letter). The message length character is As with other purposes, the symbol length to facilitate error correction is immediately provided to the reader. Can be provided.   The special function flag character 52 is a single character that is concatenated or structured over multiple lines. Can also be used as a flag, or when placed in the first digit following a start character (c used to indicate the presence of a data carrier (eg, adjacent symbols) Is done. One or more character values following the first special function flag character in the first digit are: A glue of up to 15 distinct symbols that together make up a collective single symbol A "qualifier" character or one or more accompanying data that identifies the symbol as a member of the group Neighbors that provide specific reader information to support carrier encoding and data management This is the contact tag display value. The “tag display value” is set to the adjacent data carrier (detailed below). The value following the special function flag character indicating the information related to is 8, 14 to 17, 22 to 26, And 30-35 single characters. "Modifier" is one to five symbols A sentence not between 9 and 45 above indicating the structured additional group size between A single character with a character value. In other words, one to five additional symbols are Character values between 0 and 7 that form one larger symbol with the symbol, followed by Character values between 6 and 47 indicate a group size of 6 to 15 symbols as follows: You.   In addition to using the above 93i start and stop character combinations, special features A flag character followed by a tag value with a value of 8 is indicated by the symbol Indicates that it has a possible symbol (linear or stacked symbol). Special function flag statement The tag display value with the letter followed by the letter 8 also has 93i symbols using error correction Indicates that   Unlike currently available linear symbols, 93i symbols and their associated symbols Data sets can be encoded. For example, the accompanying symbols are product identification number, batch number, Purchase order numbers, lot numbers, and other customer-defined data sets and Other predefined data sets can be encoded. Such adjoint symbols are usually , The supplementary data associated with the accompanying 93i symbol. Reader is 93i 93i symbol with start and stop characters or 93i start character followed by special Scan or image a symbol consisting of a feature flag character and a modifier character with the value 8 Upon processing, the reader should have the associated symbol near the 93i symbol And try to collect data from the associated symbols.   For example, using a reader with a laser scanner, the laser scanner Remains on while Janna reads the data from the associated symbol. 2D imaging reader , The reading device scans its image memory and stores the image of the associated symbol. Identify the image or acquire a digital image of the area adjacent to the 93i symbol and add it Find the issue. As a result, by recognizing the presence of the associated symbol, The taker does not waste energy or performance.   Referring to FIG. 11, an exemplary 93i symbol 200 includes adjacent adjoining symbols 202. The associated symbol 202 is shown as a two-dimensional symbol, in particular a PDF417 symbol. " The term "two-dimensional symbol" generally refers to code 49 and PDF417 or area symbology. Include multiple lines such as CodeOne, MaxiCode, and Data Matrix Refers to a symbol selected from over or stack symbols. 93i symbol 200 is 93 i start and stop characters, 204 and 206, respectively, and special function flag character 2 08 and the tag display value 210. 93i reader with laser scanner Upon scanning the symbol 200, the reader will determine that the adjacent associated symbol 202 is present. Recognize and therefore collect data not only from 93i symbols but also from associated symbols Continue scanning so you can. Special function flag character 208 and tag display value 2 10 provides additional data for the reader as described below.   In FIG. 14, the accompanying PDF417 symbol has the 93i symbol placed next to and above the 93i symbol. Here is an example. FIG. 15 shows a 93i symbol having 49 associated codes. Code 49 The symbol is located to the right of the stationary area for the 93i symbol.   The terms "tag" and "data carrier" as generally used herein are interchangeable. Machine-readable symbols or devices that are used interchangeably to store or encode data Point to. For example, a data carrier or tag may be a radio frequency (RF) readable tag, a line Includes machine-readable symbols, including shapes and two-dimensional symbols.   When the reader detects a special function flag character in the first digit adjacent to the tag display value, Information from the tag information value assists the reader to encode the companion tag, Provides guidance for readers on what to do with the information encoded in. Value 1 Tag read value with 4 reads / writes data associated with the 93i symbol Instruct the reader or host to replace the data in the companion symbol according to the routine. Command. For example, the 93i symbol 200 in FIG. Record records that indicate a particular record or file stored in the A caterer name can be provided. When the tag display value 210 has the character value 14, 93i No. 200 is data in which the record indicated by the 93i symbol is encoded in the associated symbol 202 To the reading device. As a result, the 93i symbol 200 and accompanying The symbol 202 can replace data stored externally.   A tag display value having a value of 15 associates the data in the associated symbol with the 93i symbol. Command the reader or host to put it at the beginning of the read data record. on the other hand , The tag display value having the value 16 is the associated data Instruct the reader or host to place it at the end of the record. A tag with the value 17 Display values are not transmitted with the associated data, but instead read Command the reader or host to display the data on the local display device. You. The tag display value having the value 22-26 is the area symbol for which this is near the 93i symbol. Is not only an adjoining two-dimensional symbol such as Providing an indication of the position to the reader. The area symbol is usually the finder pattern (For example, code one or data matrix MaxiCode) Put Use an array of regular polygons. The reader identifies the area symbol for the 93i symbol Avoid using finder patterns for area symbols because they recognize the alignment of That can add to the space previously occupied by the finder pattern. Can provide data characters.   Referring to FIG. 11, the tag display value 210 can have the value 22, which Indicates to the reader that the associated symbol 202 is above the 93i symbol 200. That Other tag display values are associated symbols below, left or right or related to the 93i symbol. You can show that you are somewhere else. For example, referring to FIG. The 93i symbol 214 has an associated two-dimensional symbol 216. The right end 218 of the 93i symbol is The associated two-dimensional symbol 216 is aligned vertically with the left edge 220 of the associated symbol. Can be specifically aligned with the 93i symbol 214.   Tag display values with values 30-35 have associated tags and get information from the tags Tell the reader to provide instructions or indications about the method. For example, FIG. As shown in FIG. 3, the accompanying tag may be a radio frequency (RF) tag 226, The value of the tag reading value in number 224 is typed using a specific RF identification (RFID) code. To obtain the data stored in the group. Or 93i symbol The data encoded in H.224 may be used to provide a specific frequency, such as to provide a particular frequency. 26 can provide instructions to poll or acquire data.   The following table summarizes the tag display values and the corresponding display for the reader. The tag display value can indicate a particular accompanying tag. For example, tag display values 22 to 2 6 can indicate a particular two-dimensional symbology such as PDF417 or Code One. Wear. The specific instruction set used by the reader when it encounters a tag reading is Such that all readers perform the same action when such a symbol is encountered. It is preferably determined and standardized.   In short, the 93i symbol scheme continues scanning / image processing to look for associated symbols. Provided is a method of providing an instruction, such as an instruction to turn on / off, to a reading device. For example, The 93i symbol scheme uses start / stop characters to encode data that controls the reader. Use the method Start and stop character combinations are four types of valid notation. Provide an issue. The four types of valid symbols allow the reader to correct the error. Speed up reading or decryption processing by indicating whether or not it must be used I do. Further, in the 93i symbol system, the reader uses the tag display Data can be encoded to help retrieve data from symbols or tags.   If you refer to the modifier character that follows the special function flag character that indicates structured addition, the modifier character Is algorithmically generated based on the following rules. The first character is 9 to 45 If it has a value between, the character value is converted to 6 bits and the first 3 bits are The second three bits in the value are the group size. For example, 45 is 6 bits 1011 Corresponds to 01 or represents the fifth symbol of a group of five symbols. First qualification The character has a value between 0 and 7, and the immediately following character is between 6 and 47 If they have character values, the two characters are each converted to 6 bits and combined to form 12 To form a single string of consecutive bits. The first three bits and the eighth The bits are always zero bits, while 4 to 7 bits identify the number of sequence symbols, and 9 to Twelve bits represent the group size of the entire symbol. For example, 7 and 47 are 12 bit 4 to 7 bits correspond to the binary string 000111101111 11, 9-12 bits are 1111 and therefore the 15th of the 15 symbols Represents a symbol. As another example, Table 8 shows modifier characters according to 93i symbolic structured addition. Here is an example.  Help to ensure that groups of symbols are intended to be linked together Therefore, two check characters are included after n of the n characters. The first check character is Sum of the modulo 43 of the ASCII values of all data characters in the group of symbols (Special function flag character, modifier character, mode character, check or error correction) Does not include positive characters). Similarly, the second check character includes the first check character but is special. Feature flag character, modifier character, mode character, error correction character or other check character Of the ASCII value of all data characters in a group of symbols, not including Calculated as the difference of 43.   Each of the structured addition symbols can be scanned or image processed in any order, Symbols with corrected characters can be mixed with regular 93i symbols without error corrected characters. You. Data from all symbols is buffered at the reader and returned (CR ), Preamble and postamble in the reading device such as line feed (LF) Are sent in the correct order with the appropriate characters. Optionally, the reader is described herein. Can be configured to transmit individual symbols using a customized symbol identifier protocol. So No In such cases, the appropriate symbol identifier is followed by a two digit pair m, and the transmitted data for each symbol Is prepended before. For example, the data string "123" is one of two symbols. Within the first symbol, the data string 456 is within the second of the two symbols. The symbol value encoded in the first symbol is “52, 10, 1, 2, 3,” The symbol value encoded in the second symbol is “52, 18, 8, 4, 4, 5, 6”, Here, 8 = (49 + 50 + 51 + 52 + 53 + 54) mod 43 and 4 = (49− 50-51-52-53-54) mod 43. Data sent from the reader The data is transmitted as data strings 1, 2, 3, 4, 5, 6, CR, and LF. Reading The arrangement is configured to transmit individual structured supplementary symbols and the first of the two symbols If the symbol of 2 is scanned first, the reader will read the ASCII value sequence Then, "93, 71, 68, 48, 5, 0, 48, 50, 56, 52, 52, 53 And 54 "," [, G, D, 0, 2, 0, 2, 8, 4, 4, 5, 6 ". I will trust you.   In an alternative embodiment, each symbol in the group of structured supplementary symbols is the first and second Include file marker characters instead of check characters. Within a group of structured addition symbols Each symbol contains the same file marker character selected from any of the symbol values 0 to 42. (Data characters are 0 to%). The file marker character associates each symbol with it. Identified as corresponding to the selected group. Therefore, the difference between structured addition symbols A symbol in a group consisting of: It has different file marker characters to identify.   The printer does not need to enter a special mode, one symbol at a time and one feed at a time. File marker characters can be easily printed by the printer. It is easier. The file marker character is displayed when the user Has the benefit of allowing the matching of Or a simple software program running on the host computer. Performing such grouping is guaranteed. The file marker character is, for example, Placed after the special function flag character.   In another alternative embodiment, the special function flag is combined with one or more subsequent symbol values. Can be used within several separate symbols to specify a complete two-dimensional symbol. An example For example, a flag followed by a single character whose value consists of the position and size of the symbol Can be placed. The special function flag character 52 has one or more subsequent symbol values. Together with the exact location of each symbol in the two-dimensional area to effectively form a two-dimensional symbol I do. For example, four symbols together can form a single two-dimensional symbol having two rows. You. The special function flag character 52 is a two-dimensional code with one symbol together with the first subsequent symbol value. To form the upper left part of the signal, while the feature with the second symbolic value can be indicated. The special function flag symbol is that one of the four symbols forms the lower right part of the two-dimensional symbol. Indicates that The check character of the last symbol of the structured addition 2D symbol is the entire 2D symbol Is the check character. A given symbol indicates that the symbol contains an error correcting character in the center of the symbol. The special function flag character indicating the use of the structured additional function at the beginning of the symbol One can be included.   An example of data transmitted from the reading device based on the symbols in FIG. 1 is shown below. FIG. Encodes the string "9, 3, i, ECI 16, {30908}" The data sent is     ] G793i $ 000016 30908 And in byte display   93, 71, 55, 57, 51, 105, 92, 48, 48, 48, 48, 4 9, 54, 120, 128. Becomes The symbol identifier "] G7" transmitted first with the data has an ECI character in Table 7. The presence byte shall be transmitted with the "@NNNNNNNN" ECI value included in the transmission Note that it includes the modifier character "7" indicating If the reader is all It is configured to transmit one character as two bytes, and if the two-byte character does not change The symbol identifier changes to “] G8” and the next byte sequence is sent from the reader. Be trusted.   0,93,0,71,0,56,0,57,0,51,0,105,0,92 , 0,48,0,48,0,48,0,48,0,49,0, f, 120,18 8. Since symbols contain ECI characters, symbol identifiers must be used and Cannot decode the symbol without sending the symbol identifier character. Where E CI If the character "$ 000016" was not encoded in the symbol, the transmitted message Interpreting the page depends on the host receiving the data sent from the reader. You. In that case, the word mode character is encoded within the symbol, and the reader converts the symbol into two bytes. Must be sent as an The prefix becomes “] G4”. Similarly, word mode characters are present in symbols The reader did not convert every single byte to two bytes and every two bytes If configured to send byte characters as is, the symbolic identifier will still be " ] G4 ". Therefore, the encoded string "9, 3, i, {30908} Is     ] G493i @ 30908 And sent in bytes   0, 93, 0, 71, 0, 52, 0, 57, 0, 51, 0, 105, 120, 188. Becomes   FIG. 6 shows an exemplary symbol / character printing apparatus 100. The device 100 is a printer 102, Central processing unit (CPU) 104, memory 106, keyboard 107 and secondary description It consists of storage area 108. The printer 102 stores barcodes and human readable data. This is a generally known type that can print characters. One skilled in the art can use Any such printer can be selected. CPU 104 is port or line 1 09 to the host computer or other device or application. It is connected pneumatically. The CPU 104 controls the memory 106 and / or the secondary storage area 1 08 is executed, and the 16-bit data character code is programmed. It is converted into a count to be transmitted to the linter 102. The printer 102 uses these counters. Interprets them and converts them to printed symbolic characters, usually in the form of barcode labels. "Label" generally refers to one or more symbolic characters and / or data. Any paper, cloth, plastic, metal, or other material suitable for printing or forming on it Refers to other flexible or rigid materials. However, those skilled in the art refer to The term is used as a relief on a consumer product packaging or object. It will be understood that it also refers to any symbolic character printed on an object. Printed Labels contain both symbolic characters and their corresponding human-readable data characters be able to. The label 101 of FIG. 1 is printed or read in an embodiment of the present invention. It is an example of a label that is found.   FIG. 7 shows a bar code label having a number of symbol characters and corresponding data characters. Of the steps executed by the printing apparatus 100 of FIG. Here is an example.   At step 110, a data character is selected, entered or determined, eg, Input is performed using the keyboard 107. Host computer 10 5 can also be input to the CPU 104 via the line 109. Keyboard 10 When the key on 7 is pressed, the keystroke will be (For example, the printing apparatus 100 or the host computer 105). Is converted to a “scan code”. This scan code is pressed on the keyboard Data character set, such as ASCII or Unicode Does not relate to any particular character or value within.   In step 112, the CPU 104 converts the selected character into English characters, numerals, and 8-bit characters. A set of various data characters, such as bytes, 16-bit words or characters, Divide or analyze the data. Data analysis techniques are well-known in the art. S At step 114, the CPU 104 proceeds to any feature such as shift characters [S1] to "S4". Mode characters such as special characters and numbers, byte object word mode characters, etc. [48], [49] or [50]. Further, step 114 Then, the CPU 104 determines whether or not the ECI number is encoded in the symbol.   At step 116, CPU 104 optimizes based on the selected data character. Determine the symbol string. For example, if five consecutive data characters are numbers, C PU 104 uses the numeric mode to reduce the number of symbolic characters, thereby resulting in It is determined that the information density of the symbol obtained by the above is increased. CPU of step 116 104 uses the above rules and suggestions to increase the information density within the symbol (Tables 4-6) Shown).   In step 118, the CPU 104 determines a symbol value for each data character. FIG. Tables of data characters and their corresponding symbol values, such as the tables of It is stored in the secondary storage 108 together with the count of the corresponding symbol characters. preferable. Alternatively, the symbol value can be calculated automatically from knowledge of the data characters. Stay The CPU 104 in step 118, based on the appropriate routines described herein, The selected data character is encoded into the symbol character selected from the table of FIG. example For example, when CPU 104 encounters a three or five digit string, the CPU Equations (1) and (2) are used, respectively. When encoding bytes, CPU1 04 uses equation (3).   At step 120, CPU 104 determines whether the symbol uses error correcting characters. Set. When used, the CPU generates error correcting characters as described above. There CPU 104 uses check character algorithm described above to check character "C" And “K” are generated. In step 122, the CPU 104 determines the symbol character to be printed. Choose the appropriate X dimension of the symbol based in part on the number At step 124, The CPU 104 may perform other operations such as printing symbols with human-readable data characters. Format options or other format options known to those skilled in the art. Select an option. At step 126, CPU 104 determines the appropriate code and other To the printer 102, which then converts the symbol into a bar code As a series of symbolic characters forming a label (and possibly data characters) )Print.   The 93i symbol system is a bar code reading device such as a bar code reading device 140 shown in FIG. It can be read at any time using the device. The reader 140 is a standard bar code. The reader 142 is provided. Bar code reader 142 is a laser scanner, raster -Optical device 143, such as a laser or wand-based optical transducer including. Alternatively, the electro-optical device 143 in the reading device 142 may be one-dimensional or secondary. Source CCD, semiconductor array, vidicon, and received light It may include other area imaging to convert to air signals. Electricity in the reader 142 Optical device 143 may be an LED, flash valve, infrared light source, or other light emitting device. May also include elements. The term "reader" as generally used herein is Refers to any device that can convert modulated light received from a barcode into an electrical signal. Reading equipment The arrangement is known to those skilled in the art and any such readout suitable for use in the present invention. You can select the taking device. The data read from the bar code reader 142 is the CPU 1 44. Memory 146 and secondary storage 148 are coupled to CPU 144 You. The data input to the barcode reader 142 is processed by the CPU 144. And a host computer 147 or other device at port or line 109. Or output to the application. Alternatively, the data is transmitted over a wireless link Is output.   FIG. 9 is for reading a bar code symbol having a symbol character of the symbol system of the present invention. 8 shows the steps performed by the reader 140 of FIG.   In step 151, the barcode reader 142 displays the symbol character of the barcode label. Scan or image, for example, determine a series of counts to determine the width of each element To determine. As is known to those skilled in the art, the transition between symbol character bars and the reading A timer in location 140 determines the count of symbol characters read together. Then The count is used to determine the width of an element within a given symbol. In step 152, C PU 144 analyzes the counts to find stationary zones on either side of the symbol.   In step 154, the CPU 144 sets the first six counts representing the first six element widths. Select In step 156, the CPU 144 divides the first six counts by nine Then, normalize the result and estimate the width of each element. At step 158, the CP U144 sets the width of the first six elements to a string of Compare with the inverse string of width. The last six elements in the string are from the starting character Correspond to the six elements but in the opposite direction, the CPU 144 determines that the symbol Recognize that it will be scanned and therefore read out the symbols from right to left Recognize what to do (reverse to traditional left-to-right).   In step 160, the CPU 144 selects the next six elements, At 2, the sum of the elements (counts) is divided by 9 to normalize the result. Steps At 164, the CPU 144 determines the symbol values of the six selected elements. Steps At 166, the CPU 144 determines whether the label includes an additional element, If so, returning to step 160, all symbol characters are converted to symbol values. Steps 160 to 164 are repeated until it is completed.   In step 168, the CPU 144 generates an invalid / unencoded symbol character. It can also be determined whether or not it has been done. Some symbol characters are determined to be unencodable If so, the routine returns to step 160 and the CPU 144 returns to the individual Edge-to-edge (element pair) decoding for elements Perform other known decoding methods, such as encryption. Alternatively, step 16 At 8, the CPU 144 switches between bars and bars or spaces and bars as known to those skilled in the art. Perform a pace comparison or Factor R decoding method.   In step 168, the CPU 144 determines whether or not the symbol character is focused. Can be verified or determined. CPU 144 is a bar code library for symbol characters. The CPU generates a wide element (the wi). elements can be recognized, but one-wide elements (one-wi- It is determined whether or not (de element) cannot be recognized. One CPU 144 If the one-wide element cannot be recognized in multiple symbols, the CPU Abort the routine and provide the CPU with unfocused data. Perform other functions, such as notifying the user that the symbol is not focused. If the CPU 144 is well programmed, the inventor's U.S. Pat. No. 486689, No. 55154858, No. 5439191 and / or 19 No. 08 / 493,669, filed Oct. 12, 1996. Unfocused data can be decrypted.   Data where the symbol is focused or the CPU 144 is not focused , So that all symbol values are valid (ie, ), At step 170, the CPU calculates the check based on the last two symbol characters. Execute Alternatively, if the symbol includes an error correcting character, the CPU 144 Use error correction. Check character checking or error correction according to the above algorithm In step 171, the CPU 144 sets an appropriate data storage destination. Therefore, appropriate data characters can be retrieved from the memory 146 or the secondary storage area 148. Converts the symbolic value to a data character based on the look-up table. Then Data characters can be displayed or used in another application, or line 1 49 to the host computer 147.   In step 171, the CPU 144 also determines the number, byte and word, respectively. Interpret shift or mode symbol values, such as symbol values 48-50 for modes. CP U144 encounters a mode character or other special character (symbol values 43-52) Then, the CPU transitions to the appropriate mode or decodes the symbol value as described above. is there Alternatively, the CPU 144 simply sends the symbolic value to the host computer 147 via line 149. And the host computer 147 can then convert it to the corresponding data character. Execute.   The foregoing has been a description of specific embodiments of the present invention and examples thereof, by way of example. May implement various equivalent modifications without departing from the spirit and scope of the invention. Can be. For example, the memory 106 or 146 is used by the CPU 104 or 144 All data required to encode, decode, print or read barcode labels Secondary storage 108 or 148 is not needed if there is sufficient capacity to store Can be deleted. Alternatively, the data required by the CPU 104 or 144 is The secondary storage 108 or 148, including the mass memory 106 or 146 or Can eliminate the need for this memory itself.   Regarding the 93i symbol system, the symbol characters are different from the data characters described with reference to FIG. Data characters. FNC1 character 51 or special function flag Can be latched in a mode that encodes another data character set using the character 52. For example, Unicode characters can be encoded using word mode characters 50, and The special function flag character 52 is latched and the JISC-622-1 at the end of the symbol is latched. 983 characters can be encoded.   In another embodiment, the 93i symbology omits the special function flag character in the center of the symbol. it can. Instead, the symbols can always use error correcting characters. User, pudding Error correction if the computer or computer wants to generate shorter printed symbols You can simply suppress characters. As a result, the symbol is printed without five error correction characters .   Also, in other embodiments, the 93i symbology can use error correction level indicator characters. Wear. The error correction level indicator character is the level of error correction used by a given symbol or Indicates the amount. For example, the error correction level indicator character may be 3, 5, or Can have one of three values corresponding to the use of seven error correcting characters . Error correction level indicator characters may be special function flags, such as after the message length indicator character. G Preferably, it is placed near the character.   Further, in other embodiments, the special function flag character is placed in a different place than the center of the symbol. Can be placed on the table. For example, if the special function flag character is (L + 2) / 2 Can be placed in a position corresponding to In this case, replace the message length indicator character with a similar It can be placed at a spaced position, for example, at position (2L + 2) / 3. Special machine It is natural that the function flag character and the message length indicator character can be placed at different positions in the symbol. is there.   Further, the present invention is directed to U.S. patents that provide the additional advantages and features described herein. And / or incorporate the teachings of the patent application. U.S. Patents cited above And patent applications are incorporated herein by reference in their entirety. Of the present invention Features can be applied to other symbologies. For example, the use of special feature flags Code standard or machine readable symbology, and based on the position of such characters. Two different functions can be used. Further, the mode of the 93i symbol system is a linear bus. -Are generally described herein in an integrated manner in the code symbology. is there Alternatively, such an aspect of the 93i symbology is represented by a stack symbol such as PDF417. It can be used in a scheme or a domain symbol scheme such as Code One.   Other changes can be made to the invention based on the above detailed description. . In general, in the following claims, the term will describe the invention in the description and the claims. Without being limited to the particular embodiment shown, bytes of 8-bit configuration, 16 Various data characters such as bit character codes and ECI numbers should be directly encoded. It should be construed to include all devices, methods and symbologies. Therefore, the book The invention is not limited to the disclosed content, and the scope of the invention is defined by the claims set forth below. Is determined by the range of

[Procedure of Amendment] Article 184-8, Paragraph 1 of the Patent Act [Submission date] July 8, 1999 (1999.7.8) [Correction contents]                                The scope of the claims 55. A machine readable symbol having a plurality of symbol characters, wherein a start character, a stop character, With   Depending on the combination of the start character and the stop character, additional data carriers can be activated. Machine readable notation indicating carrying data associated with the machine readable symbol issue. 56. The combination of the start character and the stop character is located within the machine readable symbol. Additional data carrier with data carried in machine readable symbols 56. The machine of claim 55, indicating that data to be added is to be conveyed. Human readable symbols. 57. The combination of the start character and the stop character is located within the machine readable symbol. Request to indicate that an associated data carrier is present Item 55. The machine-readable symbol according to Item 55. 58. A machine-readable symbol system having a plurality of symbol characters, wherein a group of symbol characters is provided. Forming a printable symbol, said printable symbol being a data symbol in a second data carrier. It has a structured addition flag indicating that it contains data to be added together with the data. Machine-readable symbol system to be used as a reference. 59. The flag comprises a predefined pair of start and stop characters 59. The machine readable symbology of claim 58. 60. 59. The flag according to claim 58, wherein the flag comprises a flag symbol character. Machine readable symbol system shown. 61. The structured addition flag is positioned at a specific position in the printable symbol. 59. A special function flag symbol character is provided when performed. Machine readable symbol system shown. 62. The flag is positioned immediately after the start character in the printable symbol 59. The apparatus according to claim 58, further comprising a special function flag symbol character. Machine readable symbol system. 63. When the flag is positioned at a specific position within the printable symbol 59. The system of claim 58, further comprising a flag symbol character and a modifier symbol character. Machine readable symbol system. 64. The flag is positioned immediately after the start character in the printable symbol Sometimes a flag symbol character and a modifier symbol selected from a range of modifier symbol characters 59. The machine readable symbol system according to claim 58, comprising a character. 65. A machine readable symbol having a plurality of symbol characters, wherein at least a second Data contained in the machine-readable symbol should be added together with the data in the carrier. A machine-readable symbol comprising a flag to indicate that there is. 66. The flag comprises a predefined pair of start and stop characters 66. The machine readable symbol of claim 65. 67. The flag is positioned immediately after the start character in the machine readable symbol. And the modifier selected from the flag symbol character and a range of modifier symbol characters 66. The machine readable symbol of claim 65, comprising: a symbol character. 68. A machine-readable symbol system having a plurality of symbol characters, wherein a group of symbol characters is provided. Forms a printable symbol, and at least one associated data carrier comprises the printable symbol. A machine-readable symbol system comprising a flag indicating that the symbol is related. 69. Data encoded in the printable symbol and the associated data carrier At least one indicator value defining a relationship to data encoded within 70. The machine readable symbology of claim 68, further comprising symbolic characters. 70. At least defining the position of the associated data carrier with respect to said printable symbol 70. The apparatus of claim 68, further comprising one indicator value symbol character. The machine readable symbol system described. 71. Providing information for accessing data in the associated data carrier. The at least one indicator value symbol character further comprising 68. The machine readable symbol system of claim 68. 72. The printable symbol or the at least one accompanying data carrier is readable. Indicates to the reader that the reader should remain active 70. The machine readable symbology of claim 68. 73. A machine-readable symbol system having a plurality of symbol characters, wherein a group of symbol characters is provided. Forms a printable symbol and comprises at least two start characters and two stop characters. e,   At least one of the start character and the stop character is a first character in the printable symbol. The printable record when at least one of the Indicating information added to the end of the issue and the identifier of the machine-readable symbol system. Machine readable symbol system. 74. The predefined combination of the start character and the stop character is the printable symbol When positioned within the additional data carrier, the data associated with the printable symbol 74. The machine readable symbology of claim 73, indicating transport of the data. 75. The predefined combination of the start character and the stop character is the printable symbol Indicates that the printable symbol contains error correcting characters when positioned within 74. The machine readable symbology of claim 73. 76. The predefined combination of the start character and the stop character is the printable symbol When the printable symbol does not exceed a predetermined value when positioned within 74. The machine readable symbol of claim 73, indicating that it contains only a number character. formula.

────────────────────────────────────────────────── ─── Continuation of front page    (31) Priority claim number 09 / 021,608 (32) Priority date February 10, 1998 (1998.2.10) (33) Priority country United States (US) (81) Designated country EP (AT, BE, CH, CY, DE, DK, ES, FI, FR, GB, GR, IE, I T, LU, MC, NL, PT, SE), CN, JP, K R (72) Inventors Wiklov, Christopher, A.             United States 98208 Washington             Ibrit 99 T h street               South East 3531

Claims (1)

[Claims] 1. A method of converting data characters into machine-readable symbols, where each symbol has a dark shape. It has a pattern consisting of bright colored spaces between its shapes,   In the step of determining a plurality of character codes respectively corresponding to a plurality of data characters Wherein each character code has 8 bits;   Converting the plurality of character codes into a plurality of symbol values. Signal values selected from the set consisting of less than 256 symbol values;   Printing a plurality of symbol characters, wherein the plurality of symbols are the plurality of characters. Steps corresponding to the A method characterized by comprising: 2. Printing additional symbol characters, wherein the additional symbol characters are a plurality of characters. Indicating that the symbol character of the character corresponds to at least one 8-bit byte. The method of claim 1, further comprising: 3. Printing additional symbolic characters, wherein the additional symbolic characters are adjacent A symbol indicating that each group of symbolic characters corresponds to one 16-bit word. The method of claim 1, further comprising a step. 4. A first test if any of said plurality of symbol values has a value in a first range Using character mode;   A second check character if any of said plurality of symbol values has a value in a second range. Using a mode,   A first or second check character mode based on the plurality of symbol values; Also calculating a first test value; The method of claim 1, further comprising: 5. A method of converting data characters into machine-readable symbols, where each symbol has a dark shape. It has a pattern consisting of bright colored spaces between its shapes,   Determining a plurality of character codes respectively corresponding to a plurality of data characters; ,   Converting the plurality of character codes into a plurality of symbol values;   Calculating an error correction value based on at least a portion of the plurality of symbol values Steps and   Printing a plurality of symbol characters, the plurality of symbols comprising a plurality of symbol values. And the error correction value and the plurality of symbol characters correspond to at least one error correction value. Special function flag symbol character indicating that it contains at least one corresponding symbol character. With the corresponding steps A method characterized by comprising: 6. The printing step includes three shapes and nine modules per symbol character. Printing a plurality of symbol characters selected from the symbol system having A method according to claim 1 or 5, characterized in that: 7. The step of printing may include the step of correcting a plurality of symbol characters by at least one error correction. To indicate the first mode if it contains at least one symbol character corresponding to the value Printing a special function flag symbol character at a first position within the plurality of symbol characters; Special function flag symbol statement in a second position within the plurality of symbol characters to indicate mode 2 The method of claim 5, including printing a character. 8. The printing step includes a special function flag close to the center of the plurality of symbol characters. The method of claim 5 including printing a character symbol. 9. The step of printing includes printing a message length symbol character in a plurality of symbol characters. 6. The method according to claim 5, comprising printing. 10. Selecting a first number;   Converting the first number of digits into a second number of symbolic values; A step in which the number 2 is smaller than the first number;   Printing a second number of symbol characters corresponding to the second number of symbol values;   Printing additional symbol characters, wherein the additional symbol characters are at least Also indicating that the second number of symbol characters corresponds to a number; The method according to claim 1, further comprising: 11. Select a number that corresponds to the preselected data that can be interpreted by the computer. Steps   Converting the number into at least one selected symbol value;   At least one selected note corresponding to the at least one selected symbol value; Printing a number character;   Printing an additional symbol, wherein the additional symbol is at least one of Indicating that one selected symbol corresponds to one of a plurality of predetermined numbers; The method according to claim 1, further comprising: 12. Printing additional symbol characters, wherein the additional symbol characters are Multiple symbol characters correspond to selected positions in a structured set of multiple symbols. 6. A method according to claim 1, further comprising the step of indicating Law. 13. The step of printing is selected from a standard bar code symbology. 6. The method according to claim 1, further comprising the step of printing a plurality of symbols. Law. 14． The step of printing is a step of printing additional symbol characters. , The additional symbol character is a group consisting of a plurality of symbol characters forming one symbol Indicating that there is at least one adjoint symbol in the vicinity of A method according to claim 1 or 5, characterized in that: 15. A plurality of adjacently positioned bars having spaces between the bars, At least 50 groups of at least 3 bars and 3 spaces Defines one of the individual data characters, each group having a first and second width, respectively. At least three bars and three spaces selected from several different widths that are several times And each group is substantially equal to at least nine times the first or second width. A barcode structure having a width. 16. One of the groups represents a byte mode data character and the byte mode data character. Character corresponds to at least one character code whose subsequent group has 8 bits The barcode structure according to claim 14, wherein the barcode structure indicates that the barcode is to be processed. 17． One of the groups represents a word mode data character, and For data characters, subsequent groups correspond to at least one 16-bit character code The barcode structure according to claim 14, wherein the barcode structure indicates that the barcode is to be processed. 18. Some of the above groups are implemented with groups selected from symbolic standards. 15. The barcode structure according to claim 14, wherein the barcode structure is qualitatively the same. 19. A method of converting data characters into machine-readable symbols, where each symbol has a dark shape And a pattern consisting of light-colored spaces between the shapes,   Selecting a group of symbol values consisting of at least two symbol values;   Selecting a first or second symbolic value, wherein the first symbolic value is Indicating that the group of symbol values collectively corresponds to the first mode, The second symbolic value is a group of said symbolic values grouped into a second mode. Responding; and   Printing a plurality of symbols, wherein the plurality of symbols is a group of symbol values. And steps corresponding to the first or second symbolic value; A method characterized by comprising: 20. The step of selecting a group includes a symbol corresponding to a string of numbers. Selecting a group of values,   The step of selecting the first or second symbol value comprises the step of selecting a first or second numerical compression mode. The method of claim 18, including the step of selecting a code. 21. The step of selecting the first or the second includes the step of selecting a third symbol value. The third symbol value, wherein the group of symbol values has eight bits. A step of indicating that the character code corresponds to at least one character code. 19. The method according to claim 18, wherein 22. The step of selecting the first or the second includes the step of selecting a third symbol value. Wherein the third symbol value is that the group of symbol values is at least one one. Claims comprising the step of indicating corresponding to a 6-bit character code. Item 19. The method according to Item 18. 23. The step of selecting the first or the second includes the step of selecting a third symbol value. Wherein the third symbolic value is such that the group of symbolic values is Corresponding to at least one selected number corresponding to pre-selected data that can be interpreted 20. The method of claim 18, including the step of indicating. 24. The step of selecting the first or the second includes the step of selecting a third symbol value. Wherein the third symbol value includes at least one additional symbol near a plurality of symbols. 18. The method according to claim 18, further comprising the step of indicating that a symbol character is present. The method described. 25. The step of selecting the first or the second includes the step of selecting a third symbol value. Wherein the third symbol value is a group of symbol values in a two-dimensional symbol. 19. The method of claim 18, further comprising the step of indicating corresponding to the selected location. The method described. 26. A method of converting data characters into machine-readable symbols, where each symbol has a dark shape And a pattern consisting of light-colored spaces between the shapes,   Selecting a group of symbol values consisting of at least two symbol values;   Providing first and second symbolic values, wherein the first symbolic value is Indicating that the group of symbol values corresponds to a portion of a two-dimensional symbol; The value indicating a selected position of a group of symbol values within the two-dimensional symbol;   Printing a plurality of symbols, the plurality of symbols comprising a group of symbol values. And steps corresponding to the first and second symbol values; A method characterized by comprising: 27. The step of selecting the group comprises at least one of the groups for the two-dimensional symbol. 27. The method of claim 26, comprising calculating one check character. . 28. A method for decoding a barcode label formed on a surface,   Generate a signal representing each of a plurality of symbol characters by imaging the barcode label Steps to   Analyzing the signal to identify symbolic characters;   Converting each symbolic character to a corresponding symbolic value, the plurality of symbolic values being Are selected from the set of less than 256 symbol values, and a plurality of symbol values Represent together at least one character code having 8 bits. And A method characterized by comprising: 29. The converting step determines whether a check character in the plurality of symbol characters checks. The first feature is to determine whether or not to use an error-correcting character when not checking. 29. The method according to claim 28. 30. The step of converting includes a plurality of at least one error correction symbol character. A given one of a plurality of symbol values may be duplicated before being determined to be within the symbol character of First determining whether it is close to the center of the number symbol character. 29. The method according to claim 28. 31. A reading device for reading machine readable symbols,   Receiving light reflected from a plurality of symbols and generating a signal representing a plurality of symbol characters Optical receiver,   Coupled to an optical receiver for receiving the signal and converting a plurality of symbol characters to a plurality of symbol values; A processor for translating, wherein each of the plurality of symbol values is less than 256 symbol values. And each symbol value corresponds to one of a plurality of data characters; At least some of the data characters correspond to a plurality of character codes, respectively, and each character code is A processor having 8 bits; A reading device comprising: 32. A machine readable symbology having a plurality of symbolic characters, wherein at least one An error correction symbol indicating that the error correction symbol character is within the group of symbol characters. A machine-readable symbol system comprising a rag symbol character. 33. The error correction flag symbol character is a first character in the group of symbol characters. Indicates that an error correction symbol character is present when positioned at the second position; The group of symbolic characters is a set of printable symbols when positioned at 33. The machine of claim 32, wherein the machine corresponds to one selected from: Readable symbol system. 34. The error correction flag symbol character is near the center of the group of symbol characters. 33. The machine readable symbol of claim 32, wherein the symbol is positioned at a point of contact. formula. 35. Further comprising at least one check symbol character in the group of symbol characters. e,   The check character is an error correction code for generating at least one error correction symbol character. A contract that is generated based on an algorithm different from the algorithm The machine readable symbol system according to claim 32. 36. Further comprising a message length symbol character within the group of symbol characters;   The message length symbol character is the data to be encoded within the group of symbol characters. 33. A machine readable symbol according to claim 32, having a value indicating the number of characters. formula. 37. The error correction flag symbol character has a plurality of adjacent characters having spaces between bars. A bar positioned adjacently, said bar having at least two widths. 33. The machine readable symbology of claim 32 having one. 38. The error correction flag symbol character has a plurality of adjacent characters having spaces between bars. A bar positioned adjacently, said space being at least one of two widths 33. The machine readable symbology of claim 32, comprising one or both. 39. The error correction flag symbol character has a plurality of adjacent characters having spaces between bars. A bar positioned adjacently, said bar having at least two heights. 33. The machine readable symbology of claim 32, comprising: 40. A machine-readable symbol system having a plurality of symbol characters, wherein a group of symbol characters is provided. Forms a printable symbol,   Using error correction when positioned at a first position within the printable symbol. Indicating a second function when positioned at a second position within the printable symbol. A machine-readable symbol system characterized by a special function flag symbol character. 41. When the special function flag symbol character is positioned at the first position Indicates that the error correction symbol character is within that group of symbol characters, The group of symbolic characters is a printable symbol when positioned in the second position; 41. The method according to claim 40, wherein the information corresponds to one selected from a set of Machine readable symbol system shown. 42. The first position is close to the center of the group of symbolic characters; 41. The machine readable symbology of claim 40. 43. The special function flag symbol character positioned at the second position is printable Corresponds to one selected from a set of symbols, the group of symbol characters is printable Include selected symbolic characters that identify a group of symbolic characters with a set of symbols 41. The machine readable symbology of claim 40. 44. A printer device for printing machine readable symbols, comprising:   A processor for converting a plurality of character codes into a plurality of symbol values, wherein the plurality of statements Character code corresponding to each of a plurality of data characters, and at least one error correction symbol statement That the characters should be positioned within the printable symbol. A processor indicated by one;   A processor coupled to the processor for printing a plurality of symbol characters as printable symbols; A linter mechanism where multiple symbol characters correspond to multiple symbol values Printer mechanism and A printer device comprising: 45. A set of bar code symbols corresponding to the set of data characters, Comprising a plurality of adjacently positioned bars having a space between them;   The groups of bars and spaces are non-stacked printable notes. At least two bars and spaces in said printable symbol forming a symbol Group of barcode symbols characterized by error-correcting characters . 46. At least two groups of said bars and spaces are printable A predetermined group of bars and spaces to indicate that they are The set of bar code symbols according to claim 45, further comprising: 47. The predetermined group of bars and spaces is Position (L + 2) / 2, where L is the data to be encoded in the printable symbol. 47. The set of barcode symbols according to claim 46, wherein the number is a number of data characters. . 48. At least the first error correction character is located close to the beginning of the printable symbol. And at least a second error correction character is located adjacent to the end of the printable symbol. 47. The set of barcode symbols of claim 45, wherein the barcode symbols are positioned. 49. One of the group consisting of bars and spaces is error correction Represents a level indicator character, wherein the error correction level indicator character is: Error correction for groups of bars and spaces in printable symbols The set of barcode symbols according to claim 45, wherein the set indicates a level. 50. A set of machine-readable symbols corresponding to the set of data characters, wherein Comprising a plurality of adjacently positioned shapes having a space therebetween,   The groups of shapes and spaces form printable symbols, and At least first and second groups of shapes and spaces in possible symbols Are the first and second error correcting characters, and are the first and second characters composed of shapes and spaces. And the second group is positioned non-contiguously within the printable symbol. Of readable machine readable symbols. 51. Starting character with set of machine-readable symbols positioned at both ends of printable symbol And a stop character, wherein the first and second error correcting characters are a start character and The machine of claim 50, wherein the machine is positioned proximate each of the stop characters. Set of readable symbols. 52. Wherein said printable symbol includes said first and second error correcting characters. A predetermined group consisting of the shapes and spaces shown. 51. The set of machine readable symbols of claim 50. 53. A machine readable symbology having a plurality of symbolic characters, wherein at least one Indicates that the adjoint symbol is near a group of symbol characters forming one symbol A machine-readable symbol system characterized by having an associated symbol present symbol character. 54. The adjoining symbol present symbol character has at least a start within the group of symbol characters. 54. The machine readable symbol system according to claim 53, wherein the character is a stop symbol character.