JP5329605B2 - Printer and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve the usability of a printer. <P>SOLUTION: The printer includes a printing and conveying unit, an error detection means, a reception means, and a restarting means. The printing and conveying unit executes the printing and conveying operation for conveying paper sheets, and printing the paper sheets. The error detection means detects errors on the printing and conveying operation according to the preset error detection condition. The reception means interrupts the printing and conveying operation and receives the change of the error detection condition when the error detection means detects the error. The restarting means restarts the printing and conveying operation when the reception means receives the change of the error detection condition. <P>COPYRIGHT: (C)2013,JPO&amp;INPIT

Description

  Embodiments described herein relate generally to a printer and a program.

  Conventionally, as a printer that prints on paper such as forms, if a paper skew error (state where the paper is skewed with respect to the specified posture) is detected for the paper sucked from the paper feed port, the paper is fed. In addition to returning to the mouth, an error screen that prompts the user to reset the paper in the paper feed opening is known. In this printer, it is possible to set one of a plurality of error detection accuracies of the paper skew.

  In such a printer, there is a case where it is desired to print and issue a form quickly even if the paper is slightly inclined. However, in the above printer, when a paper skew error occurs, the user repeats the paper setting operation until the paper can be correctly set, or cancels the printing process (program) to change the error detection accuracy to a lower level and prints again. It is necessary to execute the process, which is not convenient.

  The printer according to the embodiment includes a print transport unit, an error detection unit, a reception unit, and a restart unit. The print transport unit performs a print transport operation for transporting paper and printing on the paper. The error detection unit detects an error related to the print transport operation according to a set error detection condition. When the error detection unit detects the error, the reception unit interrupts the print transport operation and receives a change in the error detection condition. The resuming unit resumes the print transport operation when the receiving unit receives a change in the error detection condition.

  Further, the program according to the embodiment includes a printer computer including a print transport unit that performs a print transport operation for transporting a sheet and printing on the sheet, the error detection unit, the reception unit, and the restart unit. And let it function as.

FIG. 1 is a perspective view showing an office machine according to an embodiment. FIG. 2 is a side view showing the office machine according to the embodiment, and is a view showing a part in cross section. FIG. 3 is a plan view showing the paper detection sensor of the office machine according to one embodiment together with the cut sheet paper. FIG. 4 is a block diagram illustrating an electrical connection of the office machine according to the embodiment. FIG. 5 is a diagram illustrating a functional configuration of the office machine according to the embodiment. FIG. 6 is a flowchart showing the flow of the form issuing process executed by the CPU of the office machine according to the embodiment. FIG. 7 is a diagram illustrating an issue confirmation screen according to an embodiment. FIG. 8 is a diagram illustrating a transition example of the error screen according to the embodiment. FIG. 9 is a plan view showing a sheet position detection sensor according to a modification of the embodiment together with a cut sheet. FIG. 10 is a diagram illustrating a transition example of the error screen according to the modification of the embodiment.

  Hereinafter, an embodiment will be described in detail with reference to the drawings.

  FIG. 1 is a perspective view illustrating an office machine according to an embodiment. The office machine 101 includes a housing 102 that accommodates each part. The housing 102 is formed in a trapezoidal shape when viewed from the side. A keyboard 103 is integrally provided at the front lower portion of the housing 102. A display 104 is attached to the front surface of the housing 102 at a position above the keyboard 103. The display 104 is a liquid crystal display, for example. Between the display 104 and the keyboard 103, a paper insertion slot 107 for inserting a cut sheet 401, which is an example of paper, is provided. The cut sheet 401 is, for example, a form sheet. Further, the office machine 101 has a paper discharge tray 111 at the rear thereof. The office machine 101 has a mouse 108.

  FIG. 2 is a side view showing the office machine according to the present embodiment, and is a view partially showing a cross section. The office machine 101 includes a printer 118. The printer 118 performs printing by conveying the cut sheet 401 inserted in the guide path 115 by the print conveying unit 130.

  The guide path 115 is provided inside the housing 102. The guide path 115 accepts the insertion of the cut sheet 401 from the sheet insertion port 107 and guides the inserted cut sheet 401. The guide path 115 is composed of a plurality of sets of a pair of guide plates 113 arranged to face each other with a predetermined gap. One end of the guide path 115 communicates with the paper insertion port 107 and the other end communicates with a paper discharge port 116 formed on the upper surface of the housing 102. It is connected to the curved shape. The paper discharge tray 111 described above is provided so as to hold the paper insertion opening 107 discharged from the paper discharge opening 116 and the like.

  The print transport unit 130 performs a print transport operation for transporting the cut sheet 401 along the guide path 115 and printing on the paper. The print transport unit 130 is a roller pair composed of a pair of transport rollers 119 and a pinch roller 120 arranged to face each other via the guide path 115 as a structure (transport section) for transporting the paper inserted into the guide path 115. A plurality of 131 is provided. The transport roller 119 is rotationally driven by a drive motor 132 that is a drive source. The pinch roller 120 is urged toward the conveyance roller 119 via the guide path 115 and is driven by the conveyance roller 119. The roller pair 131 sandwiches and conveys the cut sheet 401.

  The print transport unit 130 has a print head 117 as a print head for printing on the cut sheet 401. As the print head 117, for example, a serial impact dot printer head is used. Accordingly, the print head 117 is slidably attached to the carrier shaft 121 and mounted on a carriage 122 that can reciprocate. The reciprocating direction of the carriage 122 is the width direction of the guide path 115 orthogonal to the paper transport direction. The print head 117 constitutes a printing unit together with a platen 123 described later.

  The printer 118 includes a platen 123 and an ink ribbon mechanism (not shown) in order to realize printing in a serial wire dot matrix system using the print head 117. The platen 123 is disposed to face the front end surface of the print head 117 via the guide path 115, and is positioned at a position where a front end portion of a wire (not shown) fed out from the front end surface of the print head 117 can collide. The ink ribbon mechanism supplies an ink ribbon (not shown) between the front end surface of the print head 117 and the guide path 115.

  The printer 118 also includes a sheet detection sensor 133 that detects a sheet and a sheet position detection sensor 134 that detects the position of the edge of the cut sheet 401 being conveyed along the guide path 115. ing.

  FIG. 3 is a plan view showing the paper detection sensor of the office machine according to the present embodiment together with the cut sheet paper. Two paper detection sensors 133 are provided. These sheet detection sensors 133 are disposed downstream of the uppermost roller pair 131 in the sheet conveyance direction. These paper detection sensors 133 are arranged at intervals in the width direction (direction indicated by arrow W in FIG. 3) of the guide path 115 orthogonal to the paper conveyance direction (direction indicated by arrow F in FIG. 3). Has been. The positions of the two paper detection sensors 133 in the paper conveyance direction of the guide path 115 are the same position. The paper detection sensor 133 is an optical sensor having a light emitting element and a light receiving element. As the optical sensor, there are a reflection type and a transmission type, but an example of a transmission type optical sensor is shown in the drawing.

  Returning to FIG. 2, the paper position detection sensor 134 is disposed downstream of the uppermost roller pair 131 in the paper transport direction and downstream of the paper detection sensor 133. The paper position detection sensor 134 is, for example, a reflective line sensor having a plurality of LEDs (light emitting elements) (not shown), a plurality of light receiving elements, and a control circuit.

  In FIG. 2, a tractor 124 is disposed below the back surface of the housing 102. Arranged in the center of the back surface of the housing 102 is a continuous paper holder 125. The tractor 124 feeds a tractor sheet (not shown) to the middle portion of the guide path 115 via the second guide path. The tractor paper fed to the guide path 115 is printed by the print head 117 and discharged from the paper discharge port 116 by the transport operation of the tractor 124. As described above, the office machine 101 can perform printing using the print head 117 on tractor paper as continuous paper in addition to the cut sheet 401 and the like.

  FIG. 4 is a block diagram showing an electrical connection of the office machine according to the present embodiment. The office machine 101 has a microcomputer 201 as a control unit. The microcomputer 201 is configured by connecting a ROM 203 and a RAM 204 to a CPU 202 via a bus line 205. The CPU 202 executes various arithmetic processes and controls each unit in an integrated manner. The ROM 203 stores a program executed by the CPU 202 and the like. The RAM 204 stores data in a rewritable manner and functions as a work area for the CPU 202. The display unit 104, the keyboard 103, the mouse 108, the drive motor 132, the print head 117, the paper detection sensor 133, and the paper position detection sensor 134 are connected to the microcomputer 201 via the bus line 205. Further, a communication interface 141 that executes communication with an external device and an HDD 142 that stores various types of information are also connected to the microcomputer 201 via a bus line 205. The microcomputer 201 constitutes a control unit of the printer 118.

  Next, a form issuing process executed by the CPU 202 will be described. FIG. 5 is a diagram illustrating a functional configuration of the office machine according to the present embodiment. The CPU 202 functions as an error detection unit 301, a reception unit 302, and a resumption unit 303 by operating according to a program.

  The error detection unit 301 detects an error related to the print transport operation of the print transport unit 130 according to the set error detection condition. The error includes a sheet oblique error in which the cut sheet 401 is oblique with respect to the specified posture. As shown by a solid line in FIG. 3, the prescribed posture of the cut sheet 401 is the axial direction of the transport roller 119 in which the front edge of the cut sheet 401 in the sheet transport direction is orthogonal to the transport direction (in FIG. 3). In the direction of arrow W). In FIG. 3, the cut sheet 401 in an oblique state with respect to the specified posture is indicated by a one-dot chain line.

  The error detection unit 301 detects a skewed paper sheet 401 error using the two paper detection sensors 133. The two sheet detection sensors 133 detect the front end portion of the conveyed cut sheet 401 in the sheet conveyance direction. If the cut sheet 401 is inclined with respect to the specified posture, the two sheets are detected. A difference occurs in the detection timing of the detection sensor 133, that is, there is a difference in detection timing of the two paper detection sensors 133. Therefore, the error detection unit 301 calculates an angle with respect to the prescribed posture of the cut sheet 401 using the time difference between detection times of the two sheet detection sensors 133 and the conveyance speed of the cut sheet 401 by the drive motor 132. To do. Here, the error detection condition for the skewed paper error includes the accuracy of error detection and the presence / absence of execution of error detection processing (valid or invalid). There are standard and high precision in error detection. High accuracy has higher detection accuracy than standard. For example, when the standard error detection accuracy is an accuracy that causes an error when the cut sheet 401 is tilted by 4 degrees or more with respect to the prescribed posture, the high accuracy error detection accuracy is that the cut sheet 401 is in the prescribed posture. On the other hand, the accuracy is an error when tilted by 2 degrees or more.

  When the error detection unit 301 detects an error, the reception unit 302 interrupts the print transport operation of the print transport unit 130 and receives a change in the error detection condition.

  The resuming unit 303 resumes the print transport operation of the print transport unit 130 when the receiving unit 302 receives a change in the error detection condition.

  Here, when the error detection unit 301 detects an error after the resuming unit 303 restarts the print conveyance operation, the receiving unit 302 receives the change of the error detection condition again. When such a process is repeatedly performed, that is, when the number of error detections by the error detection unit 301 reaches a predetermined number of times (for example, three times), the reception unit 302 changes the error condition. The print transport operation of the print transport unit 130 is continued without accepting it.

  Next, the flow of the form issuing process will be described with reference to FIG. FIG. 6 is a flowchart showing the flow of the form issuing process executed by the CPU of the office machine according to the present embodiment.

  When the CPU 202 receives an instruction to start the form issuing process by a predetermined operation, the CPU 202 displays a guidance screen on the display unit 104 (step S1). Here, FIG. 7 shows an example of the guidance screen 501. The guidance screen 501 displays guidance for prompting setting of the cut sheet 401 (“Please set the delivery note” in the drawing), a first button 501a, and a second button 501b. The first button 501a is displayed as printing, and the second button 501b is displayed as printing stop (end). At this time, the user inserts the cut sheet 401 into the guide path 115 from the sheet insertion port 107, and presses the front edge portion of the cut sheet 401 against the uppermost roller pair 131. Set. Thereafter, the user selects the first button 501 a on the guidance screen 401 with the mouse 108 or presses the enter key on the keyboard 103.

  When the first button 501a on the guidance screen 401 is selected by the mouse 108 or when the enter key of the keyboard 103 is pressed, the CPU 202 determines that the processing is instructed (Yes in step S2). Then, the printing conveyance unit 130 is caused to start conveying the cut sheet 401 (step S3). Specifically, the CPU 202 drives the drive motor 132 in the normal direction.

  Then, the CPU 202 operates as the error detection unit 301, performs processing for detecting a skewed sheet 401 error using the two sheet detection sensors 133, and there is no sheet skewed error of the cut sheet 401. If it is determined that the slip sheet 401 is transported in a prescribed posture and there is no sheet skew error of the cut sheet 401 (No in step S4), the print transport unit 130 causes the cut sheet 401 to print. (Step S5). The cut sheet 401 on which printing has been performed is issued from the paper discharge port 116 by the print transport unit 130.

  On the other hand, if the CPU 202 operates as the error detection unit 301 and determines that a paper skew error has occurred in the cut sheet 401 (Yes in step S4), then the CPU 202 operates as the reception unit 302 and It is determined whether the number of detected paper skew errors in the issuing process has reached a specified number (for example, 3 times) (step S6). Here, the RAM 204 is formed with a number storage area for storing the number of times that the sheet skew error detection of the cut sheet 401 by the CPU 202 is detected. When the CPU 202 detects a sheet skew error of the sheet sheet 401, the number storage area of the RAM 204 is stored. Update the value of. Then, the CPU 202 compares the value in the number storage area of the RAM 204 with the specified number of times. If the CPU 202 determines that the number of error detections has not reached the specified number (No in step S6), the CPU 202 proceeds to step S7.

  In step S <b> 7, the CPU 202 operates as the reception unit 302 to display an error screen 601 (see FIG. 8A) on the display unit 104 and to control the print conveyance unit 130 to convey the cut sheet 401. The cut sheet 401 is returned to the sheet insertion slot 107. Specifically, the CPU 202 stops the drive motor 132 that has been normally rotated, and then performs reverse rotation.

  Here, FIG. 8 is a diagram illustrating a transition example of the error screen according to the embodiment. As shown in FIG. 8A, the error screen 601 displays an error display 601a indicating that an error has occurred, a setting unit 601b that receives various settings, and a setting state display unit 601c that indicates various setting states. ing. The error screen 601 is displayed as a pop-up, for example. The display content of the error screen 601 changes to the content shown in FIG. 8B when a predetermined key is pressed in the state of FIG. In FIG. 8A and FIG. 8B, the contents of the setting unit 601b are different.

  As an example of the error display 601a, in FIGS. 8A to 8D, “the sheet is bent and sucked. Set the sheet again and press the clear key” is shown.

  As shown in FIG. 8B, the setting unit 601b is provided with a condition change receiving area 601d for receiving a change in error detection condition for a sheet oblique error of the cut sheet 401. In the condition change acceptance area 601d, an identification number (“6” in the drawing) is displayed, and a display object 601e indicating “invalid”, “standard”, and “high accuracy” is displayed as an error detection condition next to the identification number. Yes. These display objects 601e can be selected by the keyboard 103 or the mouse 108. “Invalid” indicates that error detection processing is not performed (invalidated). “Standard” indicates that error detection is performed (valid) with standard error detection accuracy. “High accuracy” indicates that error detection is performed with high accuracy of error detection (effective). The selection of these display objects 601e can be changed each time a predetermined key (“6” key in the present embodiment) on the keyboard is pressed. In FIG. 8B, “standard” is selected (set) as an error detection condition (in the drawing, “diagonal detection” is indicated) in the drawing sheet oblique error of the cut sheet 401. From this state, “6” is selected. When the key is pressed, as shown in FIG. 8C, “high precision” is selected (set) as the error detection condition of the sheet oblique error of the cut sheet 401, and the “6” key is again set. When the button is pressed, “invalid” is selected (set) as the error detection condition of the sheet oblique error of the cut sheet 401 as shown in FIG. Thus, each time the “6” key is pressed, the selection of the display object 601e is changed, and the CPU 202 sets an error detection condition corresponding to the selected display object 601e. In other words, the CPU 202 changes the operation mode to a mode in which an error detection condition corresponding to the selected display object 601e is set. When a predetermined key (in this embodiment, a clear key) on the keyboard 103 is pressed, the CPU 202 deletes the error screen 601 and returns to step S3 to resume transporting the cut sheet 401. Therefore, if it is desired to print even slightly obliquely, the print transport operation can be continued if the error detection condition is set to “invalid”.

  On the other hand, if the CPU 202 determines in step S6 that the number of error detections has reached the specified number (Yes in step S6), the CPU 202 proceeds to step S5 and continues the print transport operation without accepting the error condition. Thus, the printing conveyance unit 130 performs printing on the cut sheet 401. Even in this case, the print conveying operation can be continued.

  If the second button 501b is selected in step S2 (No in step S2), the CPU 202 ends the form issuing process.

  When the error detection condition is changed in the above process, the error detection condition used in the next process may be the same as that changed in the current process or may be set in advance before the current process. You may return to.

  As described above, in this embodiment, when the error detection unit 301 detects an error, the reception unit 302 interrupts the print transport operation of the print transport unit 130, receives a change in the error detection condition, and receives the reception unit. When 302 receives the change of the error detection condition, the restarting unit 303 restarts the print transport operation of the print transport unit 130. Therefore, according to the present embodiment, when a paper skew error occurs, the error detection condition can be changed without stopping the form issuing process (print transport operation). Can be improved.

  Further, in the present embodiment, when the number of error detections by the error detection unit 301 reaches a predetermined number of times, the reception unit 302 performs the print conveyance operation of the print conveyance unit 130 without accepting the change of the error condition. Let it continue. Therefore, according to the present embodiment, when the paper skew error occurs a predetermined number of times, the print conveyance operation is continued as it is, and the cut sheet 401 is issued. It can suppress becoming longer.

  Next, a modification of this embodiment will be described. In the present modification, the error relating to the print transport operation of the print transport unit 130 includes a paper position error in which the cut sheet 401 is located outside the specified region.

  A paper position error will be described. FIG. 9 is a plan view showing the sheet position detection sensor according to this modification together with the cut sheet. The printable area of the print conveyance unit 130 in the width direction (direction indicated by arrow W in FIG. 9) of the guide path 115 orthogonal to the paper conveyance direction (direction of arrow F in FIG. 9) is a predetermined width. The left end is indicated by a line A in FIG. On the other hand, the area B where the sheet position can be detected by the sheet position detection sensor 134 includes the left side of the limit position (line A) on the left side of the printable area of the print transport unit 130. In this case, if the left edge of the cut sheet 401 is located in the area A where the sheet position detection sensor 134 can detect the sheet position and is located in the printable area of the print transport unit 130, Printing on the paper 401 is performed appropriately. However, for example, even if the left edge of the cut sheet 401 is located in the area A where the sheet position detection sensor 134 can detect the sheet position, it is more than the left end (line A) of the printable area of the print conveyance unit 130. If it is shifted to the left side, the printing start position on the cut sheet 401 may be shifted from the proper position to the right side. This is an example of the sheet position error of the cut sheet 401.

  In this modification, the error detection unit 301 detects a sheet position error of the cut sheet 401 using the sheet position detection sensor 134. Here, the error detection conditions for the paper position error include the accuracy of error detection and the presence / absence of execution of error detection processing (valid or invalid). There are standard and high precision in error detection. High accuracy has higher detection accuracy than standard. For example, when the standard error detection accuracy is an accuracy that causes an error when the position of the left edge of the cut sheet 401 is shifted by 5 mm or more to the left of the left edge (line A) of the printable area of the print conveyance unit 130 The high-precision error detection accuracy is an accuracy in which an error occurs when the position of the left end of the cut sheet 401 is shifted by 1 mm or more to the left of the left end (line A) of the printable area of the print transport unit 130.

  FIG. 10 is a diagram illustrating a transition example of the error screen according to the present modification. Since the basic flow of the form issuing process in this modification is the same as the flow shown in the flowchart of FIG. 6, the error screen 601 will be described in detail here. Similarly to the error screen 601 shown in FIG. 8, the error screen 601 of this modification shown in FIG. 10A is also an error display 601a indicating that an error has occurred, a setting unit 601b that receives various settings, A setting state display unit 601c indicating the setting state is displayed.

  As an example of the error display 601a, in FIGS. 10A to 10D, “the position error of the left end of the sheet has occurred. Please set the sheet again and press the clear key” is shown.

  As shown in FIG. 10B, the setting unit 601b is provided with a condition change receiving area 601f for receiving a change in error detection condition for a sheet position error of the cut sheet 401. In the condition change acceptance area 601f, an identification number (“7” in the drawing) is displayed, and a display object 601g indicating “invalid”, “standard”, “high accuracy” is displayed as an error detection condition next to the identification number. Yes. The selection of these display objects 601g can be changed each time a predetermined key (“7” key in this embodiment) of the keyboard is pressed. In FIG. 10B, “standard” is selected (set) as the error detection condition for the sheet position error of the cut sheet 401. From this state, when the “7” key is pressed, FIG. As shown in (c) of FIG. 10, when “high precision” is selected (set) as the error detection condition for the sheet position error of the cut sheet 401, and the “7” key is pressed again, ( As shown in d), “invalid” is selected (set) as the error detection condition for the sheet position error of the cut sheet 401. Thus, every time the “7” key is pressed, the selection of the display object 601g is changed, and the CPU 202 sets an error detection condition corresponding to the selected display object 601g. Then, the CPU 202 detects a sheet position error of the cut sheet 401 in accordance with the set error detection condition.

  The processing after detecting the paper position error is the same as the case of the paper skew error. That is, when the error detection unit 301 detects an error, the reception unit 302 interrupts the print conveyance operation of the print conveyance unit 130 and receives a change in the error detection condition, and the reception unit 302 receives a change in the error detection condition. In such a case, the resuming unit 303 resumes the print transport operation of the print transport unit 130. Therefore, according to this modification, the usability of the printer 118 can be improved.

  The program executed by the office machine 101 of the above embodiment is an installable or executable file, and is a computer such as a magnetic disk, CD-ROM, CD-R, DVD (Digital Versatile Disk). The information may be provided by being recorded on a recording medium that can be read by the user.

  In addition, the program executed by the office machine 101 according to the above embodiment may be provided by being stored on a computer connected to a network such as the Internet and downloaded via the network. Further, the program executed by the office machine 101 according to the above embodiment may be configured to be provided or distributed via a network such as the Internet.

  In the above embodiment, an example of a serial impact dot printer head has been described as the print head 117, but the present invention is not limited to this. The print head 117 may be, for example, a thermal head or an ink jet head.

  Moreover, although the said embodiment demonstrated the example in which both error detection precision and the presence or absence of execution of an error detection process were included in error detection conditions, it is not restricted to this. For example, the error detection condition may include only one of error detection accuracy and whether or not error detection processing is executed. That is, the error detection condition may include at least one of the accuracy of error detection and the presence / absence of execution of error detection processing.

  As described above, according to the embodiment, the usability of the printer can be improved.

  Although the embodiment of the present invention has been described, the above embodiment is presented as an example, and is not intended to limit the scope of the invention. The novel embodiment can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. The above-described embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and equivalents thereof.

DESCRIPTION OF SYMBOLS 118 ... Printer 130 ... Print conveyance part 201 ... Microcomputer 301 ... Error detection part 302 ... Reception part 303 ... Resumption part 401 ... Single sheet paper

JP 2008-213235 A

Claims (6)

A print transport unit that performs a print transport operation for transporting paper and printing on the paper;
An error detection means for detecting an error relating to the print transport operation according to the set error detection condition;
When the error detection unit detects the error, a reception unit that interrupts the print conveyance operation and receives a change in the error detection condition;
Resuming means for resuming the print transport operation when the accepting means accepts the change of the error detection condition;
With printer.   The printer according to claim 1, wherein the error detection condition includes at least one of error detection accuracy and presence / absence of execution of error detection processing.   The printer according to claim 1, wherein the error includes a paper oblique error in which the paper is oblique with respect to a specified posture.   The printer according to claim 1, wherein the error includes a paper position error in which the paper is located outside a predetermined area.   5. The reception unit according to claim 1, wherein, when the number of detections of the error by the error detection unit reaches a predetermined number of times, the reception unit continues the print transport operation without performing the reception. 6. Printer. A printer computer having a print transport unit that performs a print transport operation for transporting paper and printing on the paper;
An error detection means for detecting an error relating to the print transport operation according to the set error detection condition;
When the error detection unit detects the error, a reception unit that interrupts the print conveyance operation and receives a change in the error detection condition;
Resuming means for resuming the print transport operation when the accepting means accepts the change of the error detection condition;
Program to function as.

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