JP6880676B2 - Program and image forming equipment - Google Patents

Description

The present invention relates to a program of an information processing terminal that edits a character string input by a user into a desired layout.

For example, in Patent Document 1, the document type of the input document data is determined, and the appearance of the document data (for example, font, size, thickness, or arrangement of characters) according to the document structure information set in advance for each document type. Information processing terminals that can be arranged are disclosed.

Japanese Unexamined Patent Publication No. 2009-110497

However, in the information processing terminal described in Patent Document 1, the document data can be edited only within the range of the preset sentence structure information. That is, there is a problem that the degree of freedom in editing document data is low.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a program of an information processing terminal capable of flexibly and easily laying out a character string input by a user.

Various disclosures are made herein. The program, which is one of the disclosure examples, can be read by an information processing terminal including a display having a display surface and an input interface. The input interface outputs position information indicating a position on an operation surface where the input medium is touched, and pressure information indicating a pressing force of the input medium on the operation surface. The program receives a user operation for inputting a character string through the input interface, a first display process for displaying the character string input in the reception process on the display, and outputs from the input interface. Based on the position information, a specific process for specifying a target character displayed at a position on the display surface corresponding to the position indicated by the position information, and a movement of the input medium on the operation surface, and the first. 1. Among the character strings displayed in the display process, the information includes a deformation process in which the target character specified in the specific process is deformed according to the movement of the specified input medium and the pressing force indicated by the pressure information. Let the processing terminal execute it.

According to the above configuration, the target character displayed at the position on the display surface corresponding to the touch position is deformed according to the position, movement, and pressing pressure of the input medium touched on the operation surface. As a result, the character string can be laid out flexibly and easily.

FIG. 1 is a block diagram of the system 100 according to the embodiment. FIG. 2 is a diagram showing an example of locus information. FIG. 3 is a flowchart of the communication surface editing process. FIG. 4 is a flowchart of the text composition process. FIG. 5 is a flowchart of layout processing. FIG. 6 is a flowchart of the text transformation process. 7A and 7B are display examples of the display 53, in which FIG. 7A shows a template selection screen and FIG. 7B shows a template editing screen. 8A and 8B are display examples of the display 53, in which FIG. 8A is a text input screen in which the [A] icon 131 is selected, and FIG. 8B is a text input in which the first character string “Thank you” is input. Show the screen. 9A and 9B are display examples of the display 53. FIG. 9A is a text input screen in which the [~] icon 132 is selected and a locus is input, and FIG. 9B is a text input screen in which the first character string “Thank you” is displayed. The text input screen arranged along the locus is shown. 10A and 10B are display examples of the display 53, in which (A) is a text input screen in which the second character string “Congratulations” is arranged along a trajectory, and (B) is a composite of the second character string “Congratulations”. The template edit screen including the template image 121 is shown. FIG. 11 is a diagram for explaining a process of extracting a target point by using the Ramer-Douglas-Pucker algorithm. FIG. 12 is a diagram for explaining a method of projective transformation of the character “ku”.

Hereinafter, embodiments of the present invention will be described with reference to the drawings as appropriate. It goes without saying that the embodiments described below are merely examples of the present invention, and the embodiments of the present invention can be appropriately changed without changing the gist of the present invention.

FIG. 1 is a schematic view of the system 100 according to the present embodiment. The system 100 shown in FIG. 1 is composed of an MFP (abbreviation of Multi-Function Peripheral) 10 and an information processing terminal 50. Further, the system 100 may include a printer single-purpose machine instead of the MFP 10. The MFP 10 and the information processing terminal 50 are configured to be able to communicate with each other through the communication network 101. Specific examples of the communication network 101 are not particularly limited, but may be, for example, the Internet, a wired LAN, a wireless LAN, or a combination thereof. Alternatively, the MFP 10 and the information processing terminal 50 may be connected by a USB cable or the like.

As shown in FIG. 1, the MFP 10 mainly includes a printer 11, a scanner 12, a display 23, an input I / F 24, a communication I / F 25, a CPU 31, a memory 32, and a communication bus 33. .. The components constituting the MFP 10 are connected to each other through the communication bus 33.

The printer 11 executes a printing operation of recording an image represented by image data on a sheet. As the recording method of the printer 11, a known method such as an inkjet method or an electrophotographic method can be adopted. The scanner 12 executes a scanning operation of reading an image recorded on a document and generating image data. However, the scanner 12 can be omitted.

The display 23 is a liquid crystal display, an organic EL display, or the like, and includes a display screen for displaying various information.

The input I / F 24 is a user interface that accepts input operations by the user. Specifically, the input I / F 24 has a button, and outputs various operation signals associated with the pressed button to the CPU 31. Further, the input I / F 24 may have a film-like touch sensor superimposed on the display surface of the display 23. The operation of designating an object displayed on the display surface of the display 23 and the operation of inputting a character string or a number string are examples of user operations. The “object” is, for example, a character string, an icon, a button, a link, a radio button, a check box, a pull-down menu, or the like displayed on the display 23.

The input I / F24 realized as a touch sensor outputs position information indicating a position on the display surface touched by the user. The term "touch" in the present specification includes all operations of bringing the input medium into contact with the display surface. Further, even if the input medium does not touch the display surface, the "hover" or "floating touch" that brings the input medium close to the position where the distance from the display surface is very small is adopted as the above-mentioned concept of "touch". May be included. Further, the input medium may be a user's finger, a touch pen, or the like. The tap operation for the position of the object displayed on the display 23 is an example of the designation operation for designating the object.

The communication I / F 25 is an interface capable of communicating with an external device through the communication network 101. That is, the MFP 10 transmits various information to the external device through the communication I / F25, and receives various information from the external device through the communication I / F25. The specific communication procedure of the communication I / F 25 is not particularly limited, but for example, Wi-Fi (registered trademark) can be adopted. When the MFP 10 and the information processing terminal 50 are connected by a USB cable, the communication I / F 25 may be a USB interface to which the USB cable can be attached and detached.

The CPU 31 controls the overall operation of the MFP 10. The CPU 31 acquires various programs described later from the memory 32 and executes them based on various information output from the input I / F 24, various information received from the external device through the communication I / F 25, and the like. The CPU 31 and the memory 32 form an example of the controller.

The memory 32 stores the OS 34 and the device program 35. The device program 35 may be a single program or a collection of a plurality of programs. Further, the memory 32 stores data or information necessary for executing the device program 35. The memory 32 is composed of, for example, a RAM, a ROM, an EEPROM, an HDD, a portable storage medium such as a USB memory attached to and detached from the MFP 10, a buffer included in the CPU 31, or a combination thereof.

The memory 32 may be a computer-readable storage medium. A computer-readable storage medium is a non-transitory medium. In addition to the above examples, the non-transitory medium also includes a recording medium such as a CD-ROM or a DVD-ROM. The non-transitory medium is also a tangible medium. On the other hand, the electric signal that carries a program downloaded from a server on the Internet is a computer-readable signal medium, which is a kind of computer-readable medium, but is a storage that can be read by a non-transitory computer. Not included in the medium. The same applies to the memory 62 of the information processing terminal 50, which will be described later.

As shown in FIG. 1, the information processing terminal 50 mainly includes a display 53, an input I / F 54, a communication I / F 55, a CPU 61, a memory 62, and a communication bus 63. The display 53, the input I / F 54, the communication I / F 55, the CPU 61, the memory 62, and the communication bus 63 included in the information processing terminal 50 are the display 23, the input I / F 24, the communication I / F 25, the CPU 31, and the communication bus 63 included in the MFP 10. Since the configuration is the same as that of the memory 32 and the communication bus 33, the description thereof will be omitted. The CPU 61 and the memory 62 are examples of the controller. The information processing terminal 50 is, for example, a mobile phone, a smartphone, a tablet terminal, a PC, or the like.

The input I / F 54 of the information processing terminal includes a position sensor that outputs position information indicating the position on the operation surface to which the input medium is touched, and a pressure sensor that outputs pressure information indicating the pressing force of the input medium on the operation surface. Be prepared. As an example, the operation surface of the input I / F 54 may be superimposed on the display surface of the display 53. That is, the display 53 and the input I / F 54 may constitute a touch panel display. Then, the position information in this case indicates the position on the display surface touched by the input medium. This is an example of a position on the display surface corresponding to the touch position on the operation surface.

As another example, the operation surface of the input I / F 54 may be provided on a touch pad different from the display 53. The input I / F 54 in this case is a touch pad having a position sensor and a pressure sensor. As yet another example, the operating surface of the input I / F 54 may be any surface such as a desk or floor. The input I / F 54 in this case is a touch pen which is an input medium having a position sensor and a pressure sensor. Further, the OS 64 in this case causes the display 53 to display a pointer image (for example, an image representing an arrow) that moves on the display surface following the input medium that moves on the operation surface. Then, the position information in this case indicates the position on the display surface on which the pointer image is displayed. This is another example of a position on the display surface that corresponds to a touch position on the operating surface.

Hereinafter, the user operation of separating the input medium that is brought into contact with the operation surface with a pressing force lower than the first pressure before the lapse of a predetermined time is referred to as "tap operation". Further, the user operation of separating the input medium that is brought into contact with the operation surface by the pressing force of the first pressure or more and less than the second pressure before the lapse of a predetermined time is referred to as "peak operation". Further, a user operation in which the input medium brought into contact with the operation surface by a pressing force equal to or higher than the second pressure is separated before a predetermined time elapses is referred to as a "pop operation". That is, the first pressure <the second pressure.

Further, the user operation of moving the input medium in contact with the operation surface is referred to as "swipe operation". The swipe operation is a user operation capable of moving the input medium in any direction while changing the pressing force of the input medium. More specifically, the user performing the swipe operation can move the input medium on the operation surface so as to draw a locus of an arbitrary shape (for example, a straight line, an arc, or a combination thereof). Further, the user who performs the swipe operation can increase or decrease the pressing force of the input medium on the operation surface.

Further, a user operation of linearly moving the input medium in contact with the operation surface while continuously reducing the pressing force is referred to as a "sweep operation". That is, the sweep operation is common to the swipe operation in that the position on the operation surface indicated by the position information changes continuously. On the other hand, the sweep operation is different from the swipe operation in that the direction of movement of the input medium is linear and the pressing force is monotonically reduced.

Although not shown, the memory 62 can store a plurality of template image data. The template image data is data indicating a template image recorded on the communication surface of the postcard. In this embodiment, an example of a template image recorded on the communication surface of a New Year's card will be described, but the use of the template image is not limited to this, and can be applied to, for example, summer greeting cards, Christmas cards, and the like. The template image data may be stored in a server (not shown) on the Internet instead of the memory 62.

[Operation of system 100]
The operation of the system 100 according to the present embodiment will be described with reference to FIGS. 3 to 6.

The flowchart of the present specification basically shows the processing of the CPUs 31 and 61 according to the instructions described in the program. That is, the processes such as "judgment", "extraction", "selection", "calculation", "determination", "specification", and "control" in the following description represent the processes of the CPUs 31 and 61. The processing by the CPUs 31 and 61 also includes hardware control via the OSs 34 and 64. Further, the "data" in the present specification is represented by a bit string that can be read by a computer. Then, data having the same substantial meaning and contents but different formats are treated as the same data. The same applies to "information" in the present specification.

First, the terminal program 65 of the information processing terminal 50 causes the template selection screen shown in FIG. 7A to be displayed on the display 53 in response to being activated by the OS 64 according to the user's instruction (S11). The template selection screen includes a plurality of template icons 111, 112, 113, 114. The template icons 111 to 114 correspond to one of a plurality of template image data stored in the memory 62. Then, the terminal program 65 accepts the user operation for the template selection screen through the input I / F 54 (S12).

Next, the terminal program 65 receives the template image data associated with the designated template icon 113 in response to receiving, for example, a tap operation for the position of the template icon 113 through the input I / F 54 (S12: Yes). , Read from memory 62. Next, the terminal program 65 causes the template editing screen shown in FIG. 7B to be displayed on the display 53 instead of the template selection screen (S13). The process of S13 is an example of the second display process. Then, the terminal program 65 accepts the user operation on the template edit screen through the input I / F 54 (S14 to S16).

The template editing screen includes a template image 121, a [text] icon 122, and a [print] icon 123. The template image 121 is an image indicated by the template image data read from the memory 62. The [text] icon 122 corresponds to an instruction for synthesizing a character string with the template image 121. The [Print] icon 123 corresponds to an instruction to record the template image 121 edited by the process described later on the communication surface of the postcard.

The terminal program 65 executes the text composition process in response to the reception of the tap operation for the position of the [text] icon 122 through the input I / F 54 (S14: Yes), for example (S17). The text composition process is a process of synthesizing a character string input by the user on the template image 121 in a layout specified by the user. The details of the text composition process will be described with reference to FIG.

First, the terminal program 65 causes the text input screens shown in FIGS. 8 and 9 to be displayed on the display 53 instead of the template editing screen (S21). The text input screen includes a template image 121, an [A] icon 131, a [~] icon 132, and a [genus] icon 133. Then, the terminal program 65 accepts the user operation on the text input screen through the input I / F 54 (S22, S23). On the text input screen, one of the [A] icon 131, the [~] icon 132, and the [genus] icon 133 is in the selected state, and the others are in the non-selected state.

The terminal program 65 selects the [A] icon 131 and selects the [~] icon 132 and the [genus] icon 133 in response to the reception of the tap operation for the position of the [A] icon 131 through the input I / F 54. Make it unselected. Then, the terminal program 65 causes the text box 134 and the software keyboard 135 to be displayed on the text input screen as shown in FIG. 8 (A). By selecting the [A] icon 131, a character string can be input through the text input screen.

Further, the terminal program 65 selects the [~] icon 132 in response to the reception of the tap operation for the position of the [~] icon 132 through the input I / F 54, and sets the [~] icon 132 to the selected state, and the [A] icon 131 and the [genus] icon. Set 133 to the non-selected state. Then, the terminal program 65 displays the [Done] icon 136 on the text input screen as shown in FIG. By selecting the [~] icon 132, the layout of the character string input through the software keyboard 135 can be specified.

Further, the terminal program 65 selects the [genus] icon 133 in response to receiving the tap operation for the position of the [genus] icon 133 through the input I / F 54, and sets the [genus] icon 133 to the selected state, and sets the [A] icon 131 and the [~] icon. 132 is in the non-selected state. Then, the terminal program 65 displays an unillustrated object that accepts the designation of the character string attribute (for example, font type, font size, color, etc.) on the text input screen. Then, the terminal program 65 changes the attribute of the character string input through the software keyboard 135 to the attribute received through the object.

The terminal program 65 performs, for example, an input operation of the first character string “regards” including N (= 4) characters and a tap operation for the [confirm] position through the software keyboard 135 shown in FIG. 8 (A). Accept (S22: Yes). This process is an example of a reception process. Further, the process of accepting the input of the character string in a state where the locus information described later is not stored in the memory 62 is an example of the first acceptance process. Next, the terminal program 65 secures an array “character [i]” whose number of elements matches the number of input characters N (= 4) in the memory 62. Then, the terminal program 65 stores the character codes of the input characters "yo", "ro", "shi", and "ku" in the character [i] in the input order (S24).

Further, the terminal program 65 responds that the locus information is not stored in the memory 62 (S25: No), and the display position of the text box 134 on the template image 121 (hereinafter, referred to as “initial position”). Is combined with the input character image indicating the first character string "Thank you" (S26). Then, as shown in FIG. 8B, the terminal program 65 causes the display 53 to display a text input screen including the template image 121 in which the first character string “regards” is synthesized at the initial position (S21). ..

Next, the terminal program 65 receives, for example, a tap operation for the position of the [~] icon 132 in FIG. 8 (B) through the input I / F 54 (S22: No & S23: layout) on the software keyboard 135. Instead, the [Done] icon 136 is displayed on the text input screen. Further, the terminal program 65 secures an array “trajectory [i]” for storing locus information in the memory 62. The locus [i] stores a set of position information and pressure information output from the position sensor and the pressure sensor at the same timing. That is, the locus information includes a plurality of sets of position information and pressure information. The number of elements of the locus [i] is set to a sufficient number to store a set of position information and pressure information in S27 described later.

Next, the terminal program 65 accepts a swipe operation through the input I / F 54 on the template image 121 of the text input screen in which the [~] icon 132 is selected (S28: No). Then, as shown in FIG. 2, for example, the terminal program 65 stores a set of position information and pressure information output from the input I / F 54 at predetermined time intervals during the swipe operation in the locus [i] in the order of output. (S27). The processes of S27 and S28 are examples of specific processes for specifying the locus of the input medium moving on the operation surface based on the change in the position information.

Further, as shown in FIG. 9A, for example, the terminal program 65 follows the input medium moving on the operation surface by the swipe operation, and positions the locus image 137 showing the locus at the corresponding position on the display surface. Display it. The locus image 137 is a line connecting the positions on the display surface indicated by the position information in the locus information shown in FIG. Further, the locus image 137 is a line drawn thicker as the pressing force indicated by the corresponding pressure information is larger, and thinner as the pressing force indicated by the corresponding pressure information is smaller.

Next, the terminal program 65 executes the layout process (S29) in response to the determination that the swipe operation is completed (S28: Yes). The end of the swipe operation can be determined by the fact that the input medium is separated from the operation surface, and more specifically, the position information and the pressure information are no longer output from the input I / F 54. The layout process is a process of synthesizing the first character string “regards” input through the software keyboard 135 with the template image 121 along the movement locus of the input medium indicated by the locus information stored in S27. The details of the layout process will be described with reference to FIG.

In the present embodiment, in S27 which is repeatedly executed, it is assumed that a set of position information and pressure information is stored in the loci [1] to [200] as shown in FIG. Further, in the present embodiment, it is assumed that the sweep operation is performed diagonally downward to the right at the end of the locus shown in FIG. 9 (A).

First, the terminal program 65 extracts a set of numbers matching the number of characters N input through the software keyboard 135 from the set of position information and pressure information included in the locus information (S31 to S35). In other words, the terminal program 65 repeatedly executes the extraction process (S31, S34) for extracting the points on the trajectory of the swipe operation as the target points until N target points are extracted. In the present embodiment, the Ramer-Douglas-Pucker algorithm is used to extract a target point on the trajectory of the swipe operation. A method of extracting four target points from the trajectory of the swipe operation will be described with reference to FIG.

As shown in FIG. 11A, the terminal program 65 extracts the start point and the end point of the locus as target points (S31). That is, the terminal program 65 is displayed on the display surface represented _{by the position information (x 1} , y ₁ ) which is an element of the locus [1] _{and the position information (x 200} , y ₂₀₀ ) which is an element of the locus [200]. Is extracted as a target point. Then, the terminal program 65 temporarily stores the indexes "1" and "200" of the array "trajectory [j]" indicating the target points in the memory 62. Then, the terminal program 65 sets 2 in the variable i indicating the number of extracted feature points (S32). The process of S31 is an example of the first extraction process.

Next, the terminal program 65 repeatedly executes the processes of S34 and S35 until the variable i reaches the number of characters N (S33: No). More specifically, the terminal program 65 extracts the point on the locus farthest from the virtual line connecting the already extracted target points as the target point (S34). Then, the terminal program 65 adds 1 to the variable i (S35). The process of S34 is an example of the second and subsequent extraction processes.

First, as shown in FIG. 11B, the terminal program 65 extracts the target point indicated by the locus [72] as the point on the locus farthest from the broken line connecting the two target points, and the index “72”. Is temporarily stored in the memory 62. Further, as shown in FIG. 11C, the terminal program 65 extracts the target point indicated by the locus [38] as the point on the locus farthest from the broken line connecting the three target points, and the index “38”. Is temporarily stored in the memory 62. As a result, for example, the N point of the start point, the end point, the inflection point, and the midpoint of the straight line having the threshold length or more is extracted as the target points. An inflection point is, for example, a point where the direction of a locus changes significantly (for example, a point where a U-turn is made, a point where an acute angle is turned), and generally refers to a point called an "edge" or a "corner". In addition, points corresponding to mathematical inflection points, maximum points, minimum points, and the like may be included in the music points.

Next, the terminal program 65 sets the target points indicated by the loci [1], [200], [72], and [38] according to the fact that the variable i reaches the number of characters N (S33: Yes). Sort along the direction of (S36). More specifically, the terminal program 65 secures an array “target point [i]” in the memory 62 whose number of input characters N (= 4) and the number of elements match. Then, the terminal program 65 temporarily stores a set of position information and pressure information, which are elements of the loci [1], [200], [72], and [38], in the ascending order of the index [1], which is temporarily stored in the memory 62. The target points [1] to [4] are stored in [38], [72], and [200].

Next, the terminal program 65 sets the initial value (= 1) in the variable i (S37). Then, the terminal program 65 repeatedly executes the processes of S38 and S39 for the character indicated by the character [i] while incrementing the variable i (S40: No → S41). S38 is a text transformation process that transforms the characters arranged at the target point [i] according to the pressing force and movement of the input medium at the target point [i]. S39 is a process of synthesizing the characters transformed in S38 at the positions on the template image 121 indicated by the target point [i]. First, the details of the text transformation process will be described with reference to FIG.

As an example, the terminal program 65, the target point [1], in response to the pressing force indicated by the pressure information _{P 1, P 72} of [3] determines that it more second pressure (S51: Yes), the character The characters "yo" and "shi" indicated by [1] and [3] are resized to the first size (S55). As another example, the terminal program 65 is indicated by the letter [2] in response to the determination that the pressing force indicated by _{the pressure information P 38 at the target point [2] is less than the first pressure (S53: Yes).} Resize the character "ro" to the third size (S57). The first size> the second size> the third size. That is, the terminal program 65 increases the characters to be displayed at the position on the display surface corresponding to the target point as the pressing force corresponding to the target point increases, and decreases as the pressing force on the target point decreases.

As yet another example, the terminal program 65 determines the direction of the sweep operation and the sweep operation in response to the determination that the sweep operation has been performed toward the target point [4], which is the end point of the locus (S54: Yes). The moving speed of the input medium to be used is specified (S58). The direction and moving speed of the sweep operation can be specified, for example, based on the change in the position information of the loci [190] to [200] corresponding to the sweep operation. Further, the terminal program 65 may specify the reduction speed of the pressing force in the sweep operation based on the change in the pressure information of the loci [190] to [200] corresponding to the sweep operation.

Then, the terminal program 65 projects and transforms the character "ku" represented by the character [4] based on the direction and the moving speed of the specified sweep operation to generate a character image (S59). First, consider the four vertices 141, 142, 143, 144 of the square surrounding the default shape letter "ku", as shown in FIG. 12 (A). Then, as shown in FIG. 12B, the terminal program 65 moves the vertex 144 closest to the arrow extending in the direction of the sweep operation from the center of the character “ku” having the default shape in the direction of the arrow. The amount of movement of the apex 144 increases as the moving speed of the sweep operation increases, and decreases as the moving speed of the sweep operation decreases. The amount of movement of the apex 144 may be controlled according to the rate of decrease in the pressing force in the sweep operation.

Next, as shown in FIG. 11B, the terminal program 65 is subjected to the character "ku" represented by the character [4] on the rectangle composed of the four vertices 141, 142, 143, and 144 after the movement. Is projected to generate a character image "ku". The projective transformation is realized using a well-known projective transformation matrix. As a result, the character "ku" in the default shape is extended in the moving direction of the sweep operation by a distance corresponding to the moving speed of the sweep operation or the decreasing speed of the pressing force.

Next, returning to FIG. 5, the terminal program 65 has the first size indicated by the character [1] at the position on the template image 121 indicated by _{the position information (x 1} , y _{1) of the target point [1].} The character "yo" is synthesized (S39). Further, the terminal program 65 synthesizes the third size character "ro" indicated by the character [2] at the position on the template image 121 indicated by _{the position information (x 38} , y ₃₈ ) of the target point [2]. (S39). Further, the terminal program 65 synthesizes the first size character "" indicated by the character [3] at the position on the template image 121 indicated by _{the position information (x 72} , y ₇₂ ) of the target point [3]. (S39). Further, the terminal program 65 puts the projected character image “ku” indicated by the character [4] at the position on the template image 121 indicated by _{the position information (x 200} , y ₂₀₀ ) of the target point [4]. Synthesize (S39).

Next, returning to FIG. 4, the terminal program 65 is a text input screen including the template image 121 in which the first character string “regards” is synthesized along the trajectory of the swipe operation, as shown in FIG. 9 (B). Is displayed on the display 53 (S21). This process is an example of the first display process. Further, the terminal program 65 displays the software keyboard 135 in response to the reception of the tap operation for the position of the [A] icon 131 shown in FIG. 9 (B) through the input I / F 54.

Next, the terminal program 65 accepts, for example, a user operation for changing the already input first character string "Thank you" to the second character string "Congratulations" through the software keyboard 135 (S22: Yes). The number of characters N (= 4) of the first character string "Thank you" before the change and the number of characters M (= 5) of the second character string "Congratulations" after the change may be the same or different. May be good. However, M and N are integers of 2 or more. The process of accepting the input of the character string while the locus information is stored in the memory 62 is an example of the second acceptance process.

Next, the terminal program 65 enters each of the input characters "o", "me", "de", "in the array" character [i] "where the number of input characters M (= 5) and the number of elements match. The character codes of "and" and "u" are stored in the input order (S24). Further, the terminal program 65 arranges the input second character string "Congratulations" along the movement locus according to the locus information shown in FIG. 2 stored in the memory 62 (S25: Yes). The layout process is executed (S29). Hereinafter, the detailed description of the common points with the above-mentioned processing will be omitted, and the differences will be mainly described.

First, the process of extracting the points indicated by the loci [1], [200], [72], and [38] as target points is common to the above description. Further, as shown in FIG. 11D, the terminal program 65 extracts the target point indicated by the locus [125] as the point on the locus farthest from the broken line connecting the four target points, and the index “125”. Is temporarily stored in the memory 62. The process of extracting the five target points is an example of the re-extraction process. Next, the terminal program 65 receives the position information of the loci [1], [200], [72], [38], and [125] according to the fact that the variable i reaches the number of characters M (S33: Yes). The pressure information is stored in the index ascending order [1], [38], [72], [125], [200] at the target points [1] to [5] (S36).

Further, the terminal program 65 determines _{that the pressing force indicated by the pressure information P 125} at the target point [4] is equal to or greater than the first pressure and less than the second pressure (S52: Yes), and the characters [4 ] Is resized to the second size (S56). The conversion method of the characters "o", "me", "de", and "u" indicated by the characters [1], [2], [3], and [5] is the same as the above example. Then, the terminal program 65 is placed at the position on the template image 121 indicated by the position information of the target points [1] to [5], and the transformed characters “O” and “O” indicated by the characters [1] to [5]. Combining "me", "de", "to", and "u" (S39).

Next, returning to FIG. 4, the terminal program 65 has a text input screen including a template image 121 in which the second character string “Congratulations” is synthesized along the trajectory of the sweep operation, as shown in FIG. 10 (A). Is displayed on the display 53 (S21). This process is an example of the redisplay process. Further, the terminal program 65 ends the text composition process in response to receiving the tap operation for the position of the [Done] icon 136 shown in FIG. 10A through the input I / F54 (S22: No & S23: Done). To do.

Next, returning to FIG. 3, the terminal program 65 has a template editing screen including a template image 121 in which the second character string “Congratulations” is synthesized along the trajectory of the sweep operation, as shown in FIG. 10 (B). Is displayed on the display 53 instead of the text input screen (S13). Next, the terminal program 65 accepts a user operation (for example, a tap operation, a peak operation, a pop operation, a sweep operation) with respect to the position of the character synthesized in the template image 121 through the input I / F 54 (S15).

Next, the terminal program 65 executes the text transformation process in response to receiving the user operation for the position of the template image 121 through the input I / F 54 (S15: Yes) (S18). In other words, the terminal program 65 executes the text transformation process in response to the fact that the input medium is touched at the position of the template image 121 and the input medium is separated from the display surface (S18). Hereinafter, the detailed description of the common points with the above-mentioned processing will be omitted, and the differences will be mainly described.

First, the terminal program 65 is based on the position information output from the input I / F 54, the target character displayed at the position on the display surface corresponding to the position on the operation surface indicated by the position information, and the operation surface. The movement of the input medium in the above is specified (S51 to S54). More specifically, the terminal program 65 determines the movement of the target character and the input medium based on a plurality of position information output from the input I / F 54 from the time when the input medium is brought into contact with the display surface until it is separated from the display surface. Identify. The processes S51 to S54 are examples of specific processes.

Next, the terminal program 65 resizes the target character according to the pressing force indicated by the pressure information in response to specifying the pop operation, peak operation, or tap operation with respect to the position of the target character (S55 to S57). .. Further, the terminal program 65 projects and transforms the target character according to the identification of the sweep operation with the position of the target character as the base point (S58, S59). The processing of S55 to S59 is an example of the deformation processing. Although not shown, the terminal program 65 causes the display 53 to display a template editing screen including the template image 121 in which the deformed target characters are combined (S13).

Further, the terminal program 65 receives the tap operation for the position of the [print] icon 123 shown in FIG. 10B through the input I / F54 (S16: Yes), and sends the MFP10 to the MFP10 through the communication I / F55. The print instruction information is transmitted (S19). The print instruction information is information for causing the MFP 10 to execute a print operation of recording the edited template image 121 on the communication surface of the postcard. The print instruction information includes template image data indicating the edited template image 121. The processing of S19 is an example of output processing. The specific example of the output process is not limited to this, and the template image data may be stored in a predetermined area of the memory 62, or may be uploaded to a server (not shown) on the Internet.

On the other hand, although not shown, the apparatus program 35 of the MFP 10 receives print instruction information from the information processing terminal 50 through the communication I / F 25. Then, the device program 35 causes the printer 11 to execute a print operation according to the received print instruction information. That is, the printer 11 prints the template image 121 indicated by the template image data included in the print instruction information on the communication surface of the postcard.

[Action and effect of this embodiment]
According to the above embodiment, the target character displayed at the position on the display surface corresponding to the touch position is deformed according to the position, movement, and pressing pressure of the input medium touched on the operation surface. As a result, the character string can be laid out flexibly and easily. As a result, the input character string can be laid out flexibly and easily by an intuitive user operation. As an example, the size of the target character can be changed by adjusting the force of pressing the input medium against the operation surface. As another example, the target character can be distorted into a desired shape by a sweep operation in which the pressing force is continuously reduced while linearly moving the input medium on the operation surface.

The position, movement, speed, and part or all of the pressing force of the input medium touched on the operation surface are specified by the OS64 that has acquired the position information and the pressure information from the input I / F54, and the specified position and movement. , Speed, and pressing force may be notified from the OS 64 to the terminal program 65. That is, for example, the OS 64 acquires the position information and the pressure information shown in FIG. 2 from the input I / F 54, analyzes the acquired information, and analyzes and analyzes the position, movement, speed, and pressing force of the input medium. The result may be notified to the terminal program 65. The "analyzed result" may be, for example, an operation ID for identifying an operation using an input medium (for example, a pop operation, a peak operation, a tap operation, a sweep operation).

Further, according to the above embodiment, the first character string "regards" is arranged on the template image 121 along the locus drawn by the user on the operation surface using the input medium. That is, the first character string "regards" of the layout corresponding to the locus drawn by the user on the operation surface is combined with the template image 121. As a result, the input character string can be laid out flexibly and easily by an intuitive user operation.

Further, according to the above embodiment, if the character string to be combined with the template image 121 is modified from the first character string "regards" to the second character string "congratulations", it matches the number of characters in the modified second character string. The target points are re-extracted, and each corrected character is recombined with the re-extracted target points. This eliminates the need to draw a locus on the operation surface each time the character string is modified, so that the character string can be laid out more flexibly and easily.

Further, according to the above embodiment, a desired locus can be drawn on the operation surface while checking the locus image 137 on the display 53. As a result, the character string can be laid out more flexibly and easily.

Further, according to the above embodiment, by drawing a locus on the operation surface while increasing or decreasing the pressing force, the characters changed according to the pressing force are arranged along the locus. As an example, the font size of each character can be increased or decreased according to the magnitude of the pressing force. As another example, the last character can be distorted by performing a sweep operation at the end of the trajectory. As a result, the character string can be laid out more flexibly and easily. The operation that triggers the processing of S58 and S59 can be replaced by a flick operation or the like instead of the sweep operation.

As in the above embodiment, the character string can be appropriately arranged on the locus by extracting the target point from the locus using the Ramer-Douglas-Pucker algorithm. However, the method of extracting the target points is not limited to this. As another example, the terminal program 65 may extract the N point of the boundary whose locus is equally divided by (N-1) by the moving distance or moving time of the input medium as the target point.

In the above embodiment, an example (S28: Yes → S29) of executing the process of extracting the target point after the swipe operation is completed has been described, but the timing of extracting the target point is not limited to this. As another example, the terminal program 65 determines the detected target points in response to the detection of target points such as the start point, end point, inflection point, and midpoint of a straight line having a threshold length or more during the swipe operation. The input characters may be arranged in the input order. That is, the input characters may be arranged in the input order following the movement of the input medium on the display surface.

Further, in the above embodiment, as shown in FIGS. 9B and 10A, an example has been described in which the vertical direction of each character laid out on the locus is unified in the longitudinal direction of the display 53. However, the layout of each character on the trajectory is not limited to this. As another example, the terminal program 65 sets each character "o", "me", "de", "to", and "u" shown in FIG. 10A, for example, in the vertical direction and the target point of the character. It may be rotated in a direction that coincides with the normal direction of the locus in the above and combined with the template image 121. That is, according to the example of FIG. 10A, the letters "o" and "me" are rotated clockwise, and the letters "de", "to" and "u" are rotated counterclockwise. It is displayed on the display 53.

Further, in the above embodiment, an example of laying out or transforming the characters to be combined with the template image 121 recorded on the communication surface of the New Year's card has been described, but the application of the present invention is not limited to this. Other examples include sewing machines that sew threads into fabric according to embroidery data, label printers that record character strings on labels, label printers that record disk-shaped images on the surface of CD-ROMs, and garment printers that record images on fabrics. Etc., the input characters may be laid out or transformed according to the user operation on the operation surface.

Further, in the MFP 10 and the information processing terminal 50 of the above embodiment, each process executed by the controller of the present invention is realized by executing various programs stored in the memories 32 and 62 by the CPUs 31 and 61. Explained. However, the configuration of the controller is not limited to this, and a part or all of the controller configuration may be realized by hardware such as an integrated circuit.

Further, the present invention can be realized not only as the MFP 10 and the information processing terminal 50, but also as a program for causing the MFP 10 and the information processing terminal 50 to execute processing. Then, the program may be recorded and provided on a non-transitory recording medium. The non-transitory recording medium may include a memory mounted on a server that can be connected to the MFP 10 and the information processing terminal 50 through the communication network 101, in addition to a CD-ROM, a DVD-ROM, and the like. Then, the program stored in the memory of the server may be distributed as information or a signal indicating the program through a communication network 101 such as the Internet.

10 ... MFP
11 ... Printer 50 ... Information processing terminal 53 ... Display 54 ... Input I / F
55 ... Communication I / F
61 ... CPU
62 ... Memory 65 ... Terminal program

Claims (6)

A program that can be read by an information processing terminal having a display having a display surface and an input interface.
The input interface outputs position information indicating a position on an operation surface to which the input medium is touched and pressure information indicating a pressing force of the input medium on the operation surface.
The program
Reception processing that accepts user operations for inputting character strings through the input interface,
The first display process of displaying the character string input in the reception process on the display, and
Based on the position information output from the input interface, the target character displayed at the position on the display surface corresponding to the position indicated by the position information and the movement of the input medium on the operation surface are specified. Specific processing to be done and
Among the character strings displayed in the first display process, the transformation process of deforming the target character specified in the specific process according to the movement of the specified input medium and the pressing force indicated by the pressure information. is performed to the information processing terminal,
In the deformation process when the movement of the input medium linearly moving on the operation surface is specified by the specific process and the pressing force indicated by the pressure information is continuously reduced, the target character is projected. The character image obtained by conversion is displayed on the display in place of the target character.
In the transformation process, among the four vertices of the square surrounding the target character, the vertex closest to the movement locus of the input medium is moved in the movement direction of the input medium, and a rectangle composed of the four vertices after the movement. A program for displaying the character image on which the target character is projected on the display in place of the target character. The program increases the target character as the pressing force increases in the deformation process when the movement of separating the input medium touching the operation surface by the elapse of a predetermined time is specified by the specific process. The program according to claim 1, wherein the smaller the pressing force is, the smaller the target character is. The program according to claim 1 or 2 , wherein in the deformation process, the larger the moving speed of the input medium or the decreasing speed of the pressing force, the larger the moving amount of the apex. The program
The information processing terminal is made to execute the second display process of displaying the template image to be recorded on the communication surface of the postcard on the display.
The program according to any one of claims 1 to 3 , wherein in the first display process, the character string received in the reception process is superimposed and displayed on the template image. The program causes the information processing terminal to execute an output process for outputting layout image data indicating a layout image, and the layout image is an image including a character string transformed by the transformation process according to claims 1 to 4 . The program described in either. A display with a display surface and
Input interface and
Image forming part and
An image forming apparatus including a controller.
The input interface outputs position information indicating a position on an operation surface to which the input medium is touched and pressure information indicating a pressing force of the input medium on the operation surface.
The controller
Reception processing that accepts user operations for inputting character strings through the input interface,
The first display process of displaying the character string input in the reception process on the display, and
Based on the position information output from the input interface, the target character displayed at the position on the display surface corresponding to the position indicated by the position information and the movement of the input medium on the operation surface are specified. Specific processing to be done and
Among the character strings displayed in the first display process, the transformation process of deforming the target character specified in the specific process according to the movement of the specified input medium and the pressing force indicated by the pressure information.
An image forming process for forming a layout image on the image forming unit is executed, and the layout image is an image including a character string deformed by the deformation process.
In the deformation process when the movement of the input medium linearly moving on the operation surface is specified by the specific process and the pressing force indicated by the pressure information is continuously reduced, the target character is projected. The character image obtained by conversion is displayed on the display in place of the target character.
In the transformation process, among the four vertices of the square surrounding the target character, the vertex closest to the movement locus of the input medium is moved in the movement direction of the input medium, and a rectangle composed of the four vertices after the movement. An image forming apparatus that displays the character image on which the target character is projected on the display in place of the target character.

Images