阅读说明：本技术 用于检验打印标记的打印机检验器和系统以及方法 (Printer checker and system and method for checking printed indicia ) 是由 T·塞林德 H·S·阿克利 于 2017-12-19 设计创作，主要内容包括：用于检验打印标记的打印机检验器和系统以及方法。提供用于打印和检验打印标记的打印机检验器。打印机检验器包括：成像模块,其用于捕获打印介质上的打印标记的图像；存储器,其通信地耦合至成像模块并且被配置成存储打印质量检验程序；以及通信地耦合至存储器的处理器。通过打印质量检验程序将处理器配置成评估打印标记的打印质量,确定打印质量是否满足打印质量标准,当打印质量不满足打印质量标准时将打印介质上的打印标记作为被拒绝的打印介质予以拒绝,以及以下之一：输出关于被拒绝的打印介质的位置特定反馈或者向切割设备发送命令信号用来毁坏被拒绝的打印介质。位置特定反馈用与同打印机检验器相关联的语言相同的语言。还提供用于检验打印标记的打印机和方法。(A printer verifier and system and method for verifying printed indicia. A printer verifier is provided for printing and verifying printed indicia. The printer checker includes: an imaging module for capturing an image of a printed mark on a print medium; a memory communicatively coupled to the imaging module and configured to store a print quality inspection program; and a processor communicatively coupled to the memory. Configuring, by a print quality inspection program, the processor to evaluate a print quality of the printed mark, determine whether the print quality satisfies a print quality criterion, reject the printed mark on the print medium as a rejected print medium when the print quality does not satisfy the print quality criterion, and one of: position specific feedback about the rejected print media is output or a command signal is sent to the cutting device to destroy the rejected print media. The location specific feedback is in the same language as the language associated with the printer verifier. Printers and methods for verifying printed indicia are also provided.)

1. A printer verifier device, comprising:

an imaging sensor configured to capture an image of a printed mark on a print medium; and

a processor communicatively coupled to the imaging sensor and configured to:

evaluating a print quality of a printed mark from an image of the printed mark captured by an imaging sensor;

retrieving two or more messages from a plurality of messages stored in a memory based on at least a first language corresponding to a particular location of a printer verifier device and a second language corresponding to a language preferred by a printer user; and

causing the printer verifier device to print two or more messages on a rejected print medium, wherein the rejected print medium includes print indicia having an evaluated print quality that does not meet a print quality criterion, wherein the first language and the second language include a human language.

2. The printer verifier device of claim 1, further comprising an internal location database in the memory that includes at least one printer configuration setting, wherein the processor is configured to determine the first language and the second language from at least one of the internal location database or, if the printer verifier device is connected to a network, from location details of at least one of a local internet server, a local cell tower, and a GPS setting.

3. The printer verifier device of claim 1, wherein the two or more messages comprise an error message, an instruction message, or both an error message and an instruction message.

4. A printer verifier device according to claim 1, wherein the processor is further configured to send a command signal to the cutting device to cut rejected print media.

5. A printer verifier device according to claim 3, wherein the error message uses a first language and the instruction message uses a second language different from the first language.

6. A printer verifier device, comprising:

an imaging module configured to capture an image of a printed mark on a print medium;

a processor communicatively coupled to the imaging module and configured to:

evaluating a print quality of a printed mark from an image of the printed mark captured by an imaging module;

retrieving location-specific feedback from a plurality of location-specific feedbacks stored in a memory based on a language corresponding to a particular location of a printer verifier device; and

causing the location-specific feedback output to be audio feedback in the language, wherein the language comprises a human language.

7. A printer verifier device according to claim 6, wherein the location specific feedback comprises a language of the recording as audio feedback.

8. A printer verifier device according to claim 6, wherein the location specific feedback comprises a synthetic spoken language as audio feedback.

9. A printer verifier device according to claim 6, wherein the location specific feedback comprises a noise indication to alert a user.

10. The printer verifier device of claim 6, wherein the location-specific feedback comprises an error message, an instruction message, or both an error message and an instruction message.

Technical Field

The present invention relates to printers, and more particularly to a printer verifier and system and method for verifying printed indicia.

Background

Conventional label printers exist in a variety of forms. Such printers require a supply of print media to print indicia thereon. The tag has data encoded therein. The marks are optical representations of the data. There are many types of markers used for many applications. The indicia may be a one-dimensional bar Code (e.g., Universal Product Code, UPC) having dark lines (i.e., bars) and light lines (i.e., spaces) of different widths arranged along the scan axis. The marker may be a two-dimensional matrix symbol (e.g., Aztec code, data matrix, QR code, etc.) having a two-dimensional array of light, dark, and, in some cases, aligned features. Some markers may encode data using color, such as an Ultracode (Ultracode). Data encoded into printed indicia, such as a bar code, may be scanned (i.e., read) by a reader, which in the case of a bar code is read.

Printing errors may be introduced into printed indicia (e.g., barcodes) for a number of reasons. In the case of barcode printing, this printing error is a particularly serious problem because barcodes encode data in the width and spacing elements of the bars. A barcode is just one type of machine-readable printed mark where the tolerance of the printed mark is closely related to the ability of a machine reader to read the printed mark and correctly interpret the encoded data in a single scan. A printed mark including a printing error may be rejected by a verifier (verifier) separate from the printer during the verification process because the printing quality standard is not satisfied. The verifier may be attached to a printer or used as a stand-alone device to which the user brings printed indicia for verification. Conventional verifiers are not communicatively coupled with a printer.

Conventional verifiers automate the verification process by capturing an image of the printed mark and evaluating the printed mark in the image according to print quality criteria. The printer utilizes the word "void" to designate (brand) rejected print media (including print marks) indicating that the rejected print media is unusable due to the print marks failing to meet print quality standards. Unfortunately, the "abolish" indication is not globally recognized and understood by all printer users, especially because three quarters of the world population do not speak english. Further, in order to designate a rejected printing medium, the rejected printing medium must be retracted into the printer, and a revocation indication (void indication) is printed in a second printing pass, thereby reducing the printing throughput speed and reducing the ribbon life (ribbon life). After the designated rejected print media exits the printer (i.e., after the second print pass), a cutting device may be used to separate the designated rejected print media from the media roll.

Accordingly, there is a need for a printer verifier and system and method for verifying printed indicia. This need may be particularly present where the english word "abolish" may not be recognized and/or understood. There is also a need to increase print throughput speed and extend ribbon life.

Disclosure of Invention

According to various embodiments of the present invention, a printer verifier for printing and verifying printed indicia is provided. The printer checker includes: an imaging module for capturing an image of a printed mark on a print medium; a memory communicatively coupled to the imaging module and configured to store a print quality verification program; and a processor communicatively coupled to the memory. The processor is configured to evaluate a print quality of the print mark by a print quality inspection program, determine whether the print quality satisfies a print quality criterion, reject the print mark on the print medium as a rejected print medium when the print quality does not satisfy the print quality criterion, and one of: outputting position specific feedback about the rejected print media or sending a command signal to the cutting device to destroy the rejected print media. The location specific feedback is in the same language as the language associated with the printer verifier.

According to various embodiments of the present invention, a verifier is provided. The verifier includes an imaging module for capturing an image of the printed mark from a printer, and at least one of the verifier and printer includes a memory and a processor communicatively coupled to the memory. The memory is configured to store a print quality verification program and a local language response database including a plurality of location-specific messages. Each location specific message is in a location specific local language. The processor is configured by the print quality inspection program to evaluate a print quality of the print indicia, determine whether the print quality satisfies a print quality criterion, reject the print indicia printed on the print medium as rejected print medium when the print quality criterion is not satisfied, and cause the printer to print the location-specific message on the rejected print medium in a language that is the same as a language associated with the printer.

According to various embodiments, a method for verifying printed indicia is provided. The method comprises the following steps: the method includes evaluating print quality of a printed mark from an image captured by an imaging module communicatively coupled to a printer and determining whether the printed mark meets a print quality criterion. When the print quality criteria are not met, the print indicia is rejected as rejected print media. The location-specific message is printed on the rejected print media in the same language as the language associated with the printer.

According to various embodiments, a method for verifying printed indicia is provided. The method includes evaluating print quality of a printed mark from a captured image of the printed mark and determining that the printed mark does not meet a print quality criterion. The print mark is rejected as rejected print media. A command signal is transmitted to the cutting device to destroy the rejected print media.

The foregoing illustrative summary, as well as other exemplary purposes and/or advantages of the present invention, and the manner of attaining them, are further explained in the following detailed description and the accompanying drawings thereof.

Drawings

FIG. 1 graphically illustrates a portion of an exemplary printer that may be communicatively coupled to a verifier or imaging module used in a method for verifying printed indicia, with a cover of the printer removed (i.e., an open printer) to illustrate an interior of the printer, in accordance with various embodiments of the invention;

FIG. 2 schematically depicts a block diagram of a system for verifying printed indicia, illustrating an imaging module communicatively coupled to the exemplary printer of FIG. 1, in accordance with various embodiments of the present invention;

FIG. 3 schematically depicts a block diagram of the printer of FIG. 1 communicatively coupled to an exemplary verifier for capturing and verifying an image of a mark (e.g., the barcode in FIG. 3) printed on a print medium, in accordance with various embodiments of the present invention;

FIG. 4 graphically illustrates a portion of an exemplary printer verifier with a cover removed (i.e., an open printer verifier) to illustrate an interior of the printer of FIG. 1 including an imaging module (shown schematically in FIG. 4) and a cutting device that may be used in a method for verifying printed indicia according to various embodiments of the invention;

FIG. 4A schematically depicts a block diagram of the printer verifier of FIG. 4, illustrating an imaging module and cutting device therein, in accordance with various embodiments of the present invention, the printer verifier verifying an exemplary printed mark (e.g., a bar code) during a verification process;

FIG. 5 is a flow diagram of a method for verifying a print mark using location-specific feedback (location-specific feedback), in accordance with various embodiments of the invention;

FIG. 6 depicts an exemplary rejected print media on which location-specific feedback is printed, the location-specific feedback including a location-specific error message (INVALIDAR) printed in a native language on the rejected print media (Portuguese word INVALIDAR corresponds to the English word "abolish"), according to various embodiments of the invention;

FIG. 7 depicts the rejected print media of FIG. 6 with both an error message (INVALIDAR) and a location-specific instruction message printed thereon in a local language, the location-specific instruction message in the depicted embodiment including an instruction in the local language for the user to send (route … to) an unsuccessful label with print label (an exemplary rejected print media) to a Quality Assurance Department (Quality assessment Department), which in Portuguese is an Enviar a Garrantia de Qualidade, the depicted location-specific instruction message also including a timestamp and other printer-specific information; and

FIG. 8 is a flow diagram of a method for verifying printed indicia including transmitting a command signal to a cutting device to destroy rejected print media in accordance with various embodiments of the invention.

Detailed Description

Various embodiments relate to a printer verifier and system and method for verifying printed indicia. The printed mark can be verified using location specific feedback or by automatic destruction after rejection. Various embodiments provide user-friendly location-specific feedback, which may be in the same language as the current location of the printer or in a language configured by the user (which may be a local language for the current location of the printer). Various embodiments increase print throughput speed and extend ribbon life. The different embodiments are particularly helpful in non-english speaking countries. As used herein, the term "verify" or the like refers to: the rejection is followed by using position specific feedback to designate the rejected print media and the rejection is followed by using the cutting device to automatically destroy the rejected print media without first designating the rejected print media. As used herein, the term "location" refers to a place (locality) having a local language associated therewith, such as a region, country or ethnic group, state, county, town, parcel (plot), coordinates, and the like. As used herein, the term "local language" includes native languages associated with a location as well as non-native languages associated with a location. For example, spanish is a non-native language in the state within the united states and on the boundaries of mexico in the united states. In this example, both English and Spanish may be considered local languages. There may be one or more local languages associated with the location.

The different embodiments of the present invention will be described with respect to a thermal transfer printer. However, the present invention is equally applicable to other types and styles of printers (including printer verifiers) (e.g., direct transfer printers (direct transfer printers), laser toner printers (laser toner printers), inkjet printers (ink jet printers), etc.). As used herein, the term "printer" refers to a device that prints indicia, text, illustrations, and the like onto a print medium (e.g., labels, tickets, plain paper, receipt paper, plastic transparencies (plastic transparencies), and the like). The print media may be continuous or discontinuous. As used herein, the term "mark" (and the plural term "marks") refers to an optical representation of data that can be scanned (i.e., machine-read) by a machine reader (i.e., data is encoded into the mark). There are many types of markers used for many applications. The indicia may be a one-dimensional bar code (e.g., universal product code, UPC) having dark lines (i.e., bars) and light lines (i.e., spaces) of different widths arranged along the scan axis. The marker may be a two-dimensional matrix symbol (e.g., Aztec code, data matrix, QR code, OCR-B, etc.) having a two-dimensional array of light, dark, and, in some cases, aligned features. Some indicia may encode data using color (e.g., a super code). The indicia is printed on a print medium. Once printed on a print medium, a mark is referred to herein as "one printed mark (printed index)" or "printed marks (printed indices)", and the print medium on which the mark is printed is referred to herein as "print medium". The print medium may be affixed to an article. Typically, the encoded data is associated with the item(s) to which the print medium is applied. The terms "a marker" and "markers" may be used interchangeably herein.

Referring now to fig. 1 and briefly to fig. 2 and 3, a system 200 for verifying printed indicia is depicted in accordance with various embodiments. The system 200 generally includes a printer 30 (e.g., fig. 1) communicatively coupled to the imaging module 66. As described below, the imaging module 66 communicatively coupled to the printer 30 is a separate device (FIG. 2) or is disposed in a separate verifier 64 (FIG. 3). The verifier 64 may be attached to the printer 30 or may be a stand-alone device to which the user brings printed indicia for verification. In either case, the verifier 64 is communicatively coupled to the printer. As described below and in the various embodiments depicted in fig. 4, the printer may further include an imaging module (i.e., the imaging module 66 is provided in the printer, in which case the printer includes the printer verifier 36).

The imaging module 66 is configured to capture an optical image of a printed mark (e.g., the bar code 1 of fig. 2) within the field of view 7 using the image sensor 11. The mark is printed on the print medium 22, resulting in the print medium 6. The image sensor 11 uses an imaging lens (or lenses) to form a real image of the field of view 7 on a photosensor array (e.g., a linear or 2D array CCD, CMOS sensor, etc.). The electronic signals from the light sensors are used to generate gray scale or color images. The image may be stored in memory 52/152 and then recalled (recalled) by processor 33/133 for verification.

The partially illustrated exemplary printer 30 depicted in FIG. 1 is capable of printing indicia on print media 22. The depicted printer 30 has a body 32 for enclosing the interior of the printer. The printer 30 further includes a power source and a removable cover (removed for illustration purposes in fig. 1) for accessing the interior of the printer. In the case of a thermal transfer printer, there may be a ribbon supply spool 40 contained within the body 32. The ink ribbon supply roll 16 is configured to be disposed on an ink ribbon supply spool 40. The ink ribbon supply roll 16 includes an ink ribbon 12 wound on an ink ribbon supply spool 14. The ribbon supplies media (e.g., ink) that is transferred to a print medium. The printer 30 may further include a thermal print head 31 that is utilized to thermally transfer a portion of the ink from the ink ribbon 12 to the print media 22 when unwinding (unwound) the ink ribbon from the ribbon supply spool 14 along a ribbon path (arrow B in fig. 1) and unwinding the print media 22 from the media supply spool 24 along a media path (arrow C in fig. 1). The media supply roll 20 includes print media 22 wound on a media supply spool 24. A media supply spool 42 is contained within the main body 32 on which the media supply roll 20 is configured to be disposed. A ribbon rewind spool 44 on which unspooled ribbon is wound may also be included within the body 32. Although the ribbon take-up 15 on the ribbon rewind shaft 44 may not be necessary, the ribbon take-up 15 may be provided on the ribbon rewind shaft 44. The printer 30 may further include one or more motors (not shown) for rotating the ribbon supply spool 40 and ribbon roll 16 disposed thereon (if present) in either a forward (arrow a in fig. 1) or a rearward rotational direction (depending on the ink surface), for rotating the media supply roll 20 disposed on the media supply spool 42 in the forward rotational direction, and for rotating the ribbon rewind spool 44. In a direct transfer printer, the ribbon supply spool, ribbon rewind spool, and ribbon may be omitted, and the thermal paper 24 substituted for the print media.

Still referring to fig. 1, the printer 30 further includes a memory 52, a Central Processing Unit (CPU) 33 (herein "processor") communicatively coupled to the memory 52, and may further include a communication module 172, according to various embodiments of the present invention. The printer 30 may further include a graphical user interface (CUI) 34 for displaying visual and/or audible information and receiving (e.g., typed, touched, spoken, etc.) information from a user. The main body 32 of the printer may include a graphical user interface 43 having, for example, a display 35 and a keyboard 37 with function buttons 39. Other graphical user interfaces may be used as known in the art (if it happens at all).

The Central Processing Unit (CPU) is an electronic circuit within the computer that implements the instructions of the program by performing basic arithmetic, logical, control, and input/output (I/O) operations as specified by instructions as described below. The printer 30 may be communicatively connected to a computer or network 18 via a wired or wireless data link using the communication module 162. In a wireless configuration, the communication module 162 may communicate with the host device over the network 18 via a variety of communication protocols (e.g., WI-FI, Bluetooth, CDMA, TDMA, or GSM). In various embodiments of the invention as described hereinafter, the system 200 may further include a cutting device 70 disposed behind the printer 30 for purposes as described hereinafter.

According to various embodiments of the invention, the memory 52 of the printer 30 may be configured to store an internal localization database (internal localization database) 54, a print quality verification software program 56, and a Local Language Response Database (LLRD) 58. The memory 52 may be further configured to store a location-specific formatting database 60, as described below, having one or more location-specific formats for location-specific message(s) printed on rejected print media. The display format of the location-specific message may be defined by a location-specific format (differentiated). The memory 52 may be further configured to store a print quality criteria database 62 as described below.

The internal location database 54 includes printer configuration settings including configuration settings having a language associated with the printer, or if the printer is connected to the network 18, the language associated with the printer may be inferred from at least one of a local internet server, a local cell tower, and a GPS reading (reading). In various embodiments, the language may correspond to a local language associated with the current location of the printer. In different embodiments, the language associated with the printer may be in a different language than the language associated with the current location of the printer. The processor 33 of the printer 30 may receive configuration settings from, for example, a printer user (e.g., via a Graphical User Interface (GUI) 34 of fig. 1).

The LLRD 58 includes a plurality of location specific messages 74 (see, e.g., table 1 below and fig. 6 and 7). Each location-specific message 74 may be in a different language. Each location-specific message 74 may be in a location-specific local language. The location-specific messages 74 may be error messages 74a, instruction messages 74b, or both error messages 74a and instruction messages 74 b. The error message indicates that the print flag is unusable. The error message may be the word "VOID" or similar in the local language. For example, Table 1 below shows a plurality of exemplary error messages 74a, each in a local language. The error message may be in any local language and any word or phrase, etc. (i.e., a word does not necessarily have to correspond to a "VOID") that indicates that the print mark was rejected and is unusable. As previously indicated, there may be more than one local language for each location.

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According to various embodiments of the present invention, processor 33 is communicatively coupled to memory 52 and configured by a print quality verification program to perform the steps of: evaluating a print quality of a print mark from a captured image of the print mark, determining that the print mark does not meet a print quality criterion, rejecting a print medium (including the print mark) as rejected print medium, determining a language associated with a printer, retrieving from memory a location-specific message in the same language as the language associated with the printer, and causing the printer to output the location-specific message as location-specific feedback regarding the rejected print medium as described below. In various embodiments, location-specific feedback is conveyed to the user when processor 33 outputs location-specific feedback regarding the rejected print media (e.g., when the printer designates the rejected print media with a location-specific message in the same language as the language associated with the printer). In various embodiments, the processor 33 may alternatively or additionally output location-specific feedback via audio signals including recorded speech and/or synthesized spoken language. The location-specific feedback may be in the same language as the language associated with the current location of the printer. The location-specific feedback may be provided to the user through a GUI 34 communicatively coupled to the processor, if present.

According to various embodiments, the processor 33 is configured to determine the language associated with the printer from at least one of the configuration settings in the printer's internal location database 54, or if the printer is connected to the network 18, the processor 33 is configured to determine the language associated with the printer from the location details of at least one of the local internet server, the local cell tower, and the GPS readings. The processor 33 of the printer 30 may receive configuration settings (e.g., via a Graphical User Interface (GUI) 34 of fig. 1) from, for example, a printer user. The printer configuration settings and network 18 may be used as pointers (pointers) to location specific messages in a Local Language Response Database (LLRD) 58. As described below, the language of the location-specific feedback may be determined based on the current location of the printer as inferred or determined from local internet servers, local internet towers, GPS settings, and user input.

Again and referring now particularly to fig. 3, according to various embodiments, the imaging module 66 is communicatively coupled to the printer and may be disposed in a separate verifier 64. The separate verifier 64 may be attached to the printer 30 or may be a stand-alone device to which the user brings printed indicia for verification. In either case, the verifier 64 is communicatively coupled to the printer. The checker 64 may include a memory (checker memory 152) electrically connected to the imaging module 66 and a Central Processing Unit (CPU) (here "checker processor" 133). The checker 64 may further include an I/O module 134 and a checker communication module 172. The subsystems in the checker 64 of fig. 3 are electrically connected via couplers (e.g., wires, traces, etc.) to form an interconnect subsystem. The interconnect subsystem may include power buses or power lines, data buses, instruction buses, address buses, etc., which allow operation of and interaction between the modules/subsystems. The I/O module 134 may include a checker graphical user interface. In various embodiments, the verifier communication module 172 may be used to communicatively connect the verifier 64 to a computer or network 18 via a wired or wireless data link. In a wireless configuration, the communication module may communicate with the host device over a network via a variety of communication protocols (e.g., WI-FI, Bluetooth, CDMA, TDMA, or GSM).

Although fig. 3 suggests memory 52/152 and processor 33/133 in both printer 30 and verifier 64, it is to be understood that printer 30 alone or verifier 64 only communicatively coupled thereto may include a processor and memory for performing the steps as described below, i.e., at least one of the verifier and printer includes a memory communicatively coupled to the imaging module and a processor communicatively coupled to the memory. A memory in at least one of the printer and the verifier is configured to store a print quality verification program and a local language response database, the local language response database including a plurality of location-specific messages. Configuring, by a print quality inspection program, a processor in at least one of the printer and the verifier to evaluate a print quality of the print mark, determine that the print quality does not meet a print quality criterion, reject the print mark printed on the print medium as a rejected print medium, determine a language associated with the printer, recall from memory a location-specific message in a language that is the same as a language associated with the printer, and prompt the printer to print the location-specific message on the rejected print medium.

According to various embodiments of the invention, the verifier 64 attached to the printer may rely on the processor 33 and memory 52 of the printer 30 for performing the steps described below, while the verifier 64, being a stand-alone device, has its own processor 133 and memory 152 for performing the steps described below.

Referring now to fig. 4 and 4A, the printer 30 may further include an imaging module 66 (i.e., the imaging module 66 is disposed within the printer 30) (the printer 30 including the imaging module 66 is particularly referred to herein as a "printer verifier" 36 or printer 36) in accordance with various embodiments of the invention. The printer verifier 36 depicted in fig. 4 and 4A is configured to both capture and verify the depicted image of the mark printed on the print medium. In various embodiments, as described below, the printer verifier 36 may further include a cutting device 70 disposed along the media path after the printed mark is printed on the print medium/print media for purposes described below. The printer verifier 36 is the same as the printer 30 as previously described, except that it includes an imaging module and optionally a cutting device in the printer verifier 36. More specifically, the printer checker 36 includes: an imaging module 66 for capturing an image of the printed indicia on a print medium; memory 52 communicatively coupled to imaging module 66 and configured to store a print quality verification program; and a processor 33 communicatively coupled to the memory and configured by the print quality verification program to evaluate a print quality of the printed mark, determine that the print quality does not meet a print quality criterion, reject the printed mark on the print medium as a rejected print medium, and one of: either position specific feedback regarding the rejected print media (in the same language as that associated with the printer checker) is output or a command signal is sent to the cutting device 70 to destroy the rejected print media. The processor 33 of the printer verifier is further configured to determine the language associated with the printer verifier, recall from memory the location-specific message in the same language as the language associated with the printer verifier, and output the location-specific message as location-specific feedback in the same manner as the systems depicted in fig. 2 and 3.

Referring now to FIG. 5, a method 100 for verifying printed indicia using location-specific feedback, according to various embodiments, includes evaluating the print quality of printed indicia (e.g., barcode 1 of FIGS. 2, 3, and 4) in an image using print quality verification program 56 (step 150). As previously indicated, the print quality verification program may be stored in the memory 52 of the printer 30 of fig. 2, in the memory of at least one of the printer 30 or the verifier 64 (verifier memory) of fig. 3, or in the memory 52 of the printer verifier 36 of fig. 4 and 4A.

Still referring to FIG. 5, according to various embodiments, a method 100 for verifying a printed mark includes determining whether the printed mark meets one or more print quality criteria (step 155). As previously suggested, if the printed mark deviates from the print quality standard or an acceptable tolerance thereof, the processor 33 and/or the checker processor 133 configured by the print quality check program 56 determines that the printed mark does not meet the print quality standard. Exemplary print quality standards are set forth in the international organization for standardization/international electrotechnical commission (ISO/IEC) 15415, 30116, and 15416. The print quality criteria may be stored in a print quality criteria database 62 in the memory 52 of the printer 30 and/or in the verifier memory 152.

Still referring to fig. 5, according to various embodiments, a method 100 for verifying a printed mark includes rejecting the printed mark as rejected print media (step 160), e.g., as printed, whether the mark is part of the print media (e.g., paper) or affixed to a particular label of an item. Fig. 6 and 7, described below, depict a rejected print media 80.

Still referring to FIG. 5, according to various embodiments, a method 100 for verifying printed indicia includes determining a language associated with the printer 30/printer verifier 36 (step 165). Although depicted in fig. 5 as being performed after step 160, it is to be understood that step 165 may be performed before any of steps 150, 155, and 160 in method 100 for verifying printed indicia (i.e., the current location of printer 30/printer verifier 36 may be determined before step 150, between steps 150 and 155, between steps 155 and 160, or after step 160, as depicted). Processor 33 and/or verifier processor 133 (fig. 3) is configured to determine the language associated with printer 30/printer verifier 36 from at least one of the configuration settings in the internal location database 54 of printer 30/36 or, if printer 30/printer verifier 36 is connected to network 18, from the location details of at least one of a local internet server, a local cell tower, GPS readings, and a user. The printer configuration settings and network 18 may be used as indicators of location specific messages in the Local Language Response Database (LLRD) 58. The language of the location-specific feedback may be determined based on the current location of the printer 30/36, as described below.

Still referring to FIG. 5, according to various embodiments, the method 100 for verifying a printed mark includes recalling from the LLRD 58 a location-specific message associated with the language associated with the printer 30/printer verifier 36 (see, e.g., Table 1) (step 170). The language associated with the printer 30/printer verifier 36 may be associated with a particular location corresponding to the current location of the printer.

Still referring to FIG. 5, according to various embodiments, a method 100 for verifying a printed mark (e.g., barcode 1 of FIGS. 6 and 7) may include outputting location-specific feedback regarding rejected print media (step 175). Processor 33 and/or checker processor 133 (fig. 3) causes printer 30/printer checker 36 to print location-specific messages 74 as location-specific feedback on rejected print media 80 (see, e.g., fig. 6 and 7). The location-specific message may be printed, at least in part, on a printed mark (e.g., barcode 1 of fig. 6 and 7) having a print error.

As previously suggested, the location-specific feedback may include location-specific messages 74 that include error messages 74a, instruction messages 74b, or both error messages 74a and instruction messages 74 b. The error message 74a indicates that the print flag is unusable. The error message may be the word "VOID" or similar in the local language (see, e.g., Table 1).

The location-specific instructions message 74b may provide the printer user with custom instructions regarding disposal instructions (dispose instructions) for rejected print media 80. For example, an employer may wish to retain all rejected print media (e.g., unsuccessful labels) for further testing at a later time. In this example, the instruction message "reserve this flag for further analysis" or the like may be printed on the rejected print media 80. Other exemplary instruction messages include "retrieve the tag", "send to Garbage (Route to garpage)" and so on. The instruction message 74b may include any instruction. The instruction message 74b may be in a local language or may be in a different language.

Referring now specifically to fig. 6 and 7, in accordance with various embodiments of the present invention, fig. 6 depicts an exemplary rejected print medium/media 80 that includes indicia (e.g., barcode 1) printed on the print medium/media 22 having an exemplary location-specific error message (INVALIDAR) 74a (portuguese term INVALIDAR corresponding to the english term "VOID") printed thereon in a location-specific (in this case brazil) native language (portuguese), in accordance with various embodiments of the present invention. FIG. 7 depicts error message INVALIDAR 74a and instruction message 74b printed on rejected print media 80 of FIG. 7. The location specific instruction message in fig. 7 includes an instruction to the user in the local language (portuguese) to send the rejected print medium to the quality assurance department, which is Enviar a garrantia de qualidatad in portuguese. According to various embodiments of the invention, the instruction message may alternatively or additionally include a time stamp and/or a printer ID such as depicted in fig. 7. According to various embodiments, the method 100 provides user-friendly feedback that is recognized and understood. In different embodiments, the location-specific feedback may alternatively or additionally be provided as an audio signal to the user, such as in a voice recording and/or synthesized spoken language. The rejection may be accompanied by at least one of a ring tone, whistle, beep, chime, or the like to alert the user to the rejection of the printed indicia.

In some user environments, it may be beneficial to print an error message in a first language and an instruction message in a second language different from the first language. The instruction message may be in two or more languages. For example, in some locations, it may be common to have a large population of immigration workers whose first language is not the local language of the location (e.g., country) in which they reside. Having instruction messages in multiple languages may be beneficial to the employer in such situations.

Referring now to FIG. 8, a method 1000 for verifying a mark printed on a print medium begins in the same manner as method 100, according to various embodiments of the invention. Method 1000 for verifying a printed mark includes steps 1500 (evaluating print quality of a printed mark in a captured image), 1550 (determining whether the printed mark meets print quality criteria) and 1600 (rejecting the printed mark as rejected print media) (steps 1500, 1550 and 1600 correspond to steps 150, 155 and 160, respectively, of method 100). After step 1600, the method 1000 for verifying printed indicia continues by the processor of the printer 30/printer verifier 36 transmitting a command signal to the cutting device 70 to destroy the rejected print media (step 1605). The cutting apparatus destroys the rejected printing medium by cutting the rejected printing medium (more specifically, the print marks of the rejected printing medium) at least once through the print marks and up to (up to) and including the effective pulverization of the rejected printing medium.

The method 1000 for verifying a mark provides several benefits. Destruction of print media is a universally understandable event that is not dependent on the local language. Because the rejected print media may be destroyed by the cutting device, the rejected print media first does not have to be marked and then destroyed, thereby increasing print throughput speed and extending ribbon life.

From the foregoing, it will be appreciated that the different embodiments provide location-specific feedback in the same language as the language associated with the printer, thus making the feedback more user-friendly. Various embodiments may also increase print throughput speed and extend ribbon life.

Example embodiments

A1. A system for verifying printed indicia, comprising:

an imaging module for capturing an image of the printed indicia;

a printer communicatively coupled to the imaging module and comprising:

a memory configured to store a print quality inspection program; and

a processor communicatively coupled to the memory and configured by the print quality verification program to:

evaluating the print quality of a printed mark from the image;

determining whether the print quality meets a print quality criterion;

rejecting the print mark printed on the print medium as a rejected print medium when the print quality does not meet the print quality criteria;

and one of the following:

outputting location-specific feedback regarding rejected print media in the same language as that associated with the printer, or

A command signal is sent to the cutting device to destroy the rejected print media.

A2. The system of claim 1, wherein the memory is further configured to store a local language response database comprising a plurality of location-specific messages, each location-specific message in a different language, and the processor configured to output location-specific feedback is further configured to:

determining a language associated with the printer prior to outputting the location-specific feedback regarding the rejected print media;

recall from memory location specific messages in the same language as the language associated with the printer; and

causing the printer to print a location-specific message on the rejected print media, the location-specific message including location-specific feedback.

A3. The system of claim 1, wherein the language of the location-specific message is determined based on a current location of the printer.

A4. The system of claim 1, wherein the processor is configured to determine the language associated with the printer from at least one of configuration settings in an internal location database of the printer, or if the printer is connected to a network, location details of at least one of a local internet server, a local cell tower, and a GPS setting.

A5. The system of claim 1, wherein the location-specific message comprises an error message, an instruction message, or both an error message and an instruction message.

A6. The system of claim 1, wherein the error message is in a local language including a first language and the instruction message is in a second language different from the first language.

In the description and/or drawings, there have been disclosed typical embodiments of the invention. The present invention is not limited to such exemplary embodiments. Use of the term "and/or" includes any and all combinations of one or more of the associated listed items. The figures are schematic representations and are thus not necessarily drawn to scale. Unless otherwise indicated, specific terms have been used in a generic and descriptive sense only and not for purposes of limitation.