JP2017194877A - Display control apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To allow a scroll operation to stop naturally at a position appropriate for a user.SOLUTION: An image generation apparatus (display control apparatus) which scrolls a display object on the basis of a flick operation, to be displayed in a display frame of a display operation panel includes: a stop position calculation unit 905 which calculates a stop position of the display object, as a calculated stop position, upon detection of a flick operation, on the basis of an initial speed of the flick operation, a lower limit speed for stopping the scroll, and acceleration, to determine a stop candidate position closest to the calculated stop position, as a target stop position, from a plurality of stop candidate positions determined at predetermined intervals; and a display control unit 906 which scrolls a button so as to successively reduce the speed to the lower limit speed in the stop position.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a display control device that realizes a scrolling operation that stops by a natural movement at an appropriate position by a flick operation.

  Some smartphones and tablet terminals enable the display screen to be scrolled by a flick operation in which the screen is flicked after the screen is pressed with a finger.

  Recently, some multi-function printers can input by this flick operation. Since the flick operation can be performed, there is no screen transition, so that it is easy for the user to search for the target function and the target function button or the like can be displayed with a small number of operations.

  With respect to such a flick operation, Patent Document 1 discloses a control (inertial scroll) that scrolls the screen with a vector equal to or proportional to the change vector based on the input coordinate change vector immediately before the coordinate input due to the touch on the touch panel disappears. ) Has been disclosed.

  Further, Patent Document 2 discloses a technique related to a mobile terminal that, when a stop instruction is transmitted during scrolling, performs reverse scrolling from the data position at that time by an adjustment amount calculated according to the scroll speed at that time. It is disclosed.

Japanese Patent Laid-Open No. 10-161628 JP 2010-55417 A

  However, in the inertial scroll technique disclosed in Patent Document 1, the scroll is controlled based on the input coordinate change vector immediately before the coordinate input due to the touch on the touch panel disappears. In some cases, scrolling stopped.

  There is no problem when scrolling stops when the operation button is displayed so that the user can operate it, and scrolling stops when the end of the operation button is displayed to the extent that it can be operated only a little. In this case, there is no problem because the user can recognize that scrolling is possible.

  On the other hand, when the operation button is displayed in a large size within the range where it cannot be operated, the user is using the display area of the display panel wastefully even though the operation button cannot be operated. In the case of the display screen of a multifunction printer, it is necessary to display operation buttons on a relatively small display panel. Therefore, if the display area of the display panel is used wastefully, the user will need to perform more flick operations and the operability will be reduced. To do.

  In addition, according to the technique disclosed in Patent Document 2, when the user stops, the user scrolls backward by the amount of adjustment calculated according to the scroll speed, and thus the user may feel unnatural movement of the reverse scroll. .

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a display control device that realizes a scroll operation that stops by natural movement at an appropriate position by a flick operation.

In order to achieve the above object, a first feature of the display control device according to the present invention is a display control device that scrolls a display target based on a flick operation and displays the display target in a display frame of a display operation panel,
When the flick operation is detected, the stop position of the display target is calculated as the calculated stop position based on the detected initial speed of the flick operation, the lower limit speed and the acceleration at which the scroll is stopped, and at predetermined intervals. Stop position calculating means for determining a stop candidate position closest to the calculated stop position as a target stop position from a plurality of determined stop candidate positions;
Display control means for scroll-displaying the display object so as to continuously decelerate to the lower limit speed at the determined target stop position.

In order to achieve the above object, a second feature of the display control device according to the present invention is as follows:
The display control unit corrects the acceleration based on the initial speed and the lower limit speed so that the display target stops at the determined target stop position, and scrolls the display target using the corrected acceleration. It is to be displayed.

In order to achieve the above object, the third feature of the display control device according to the present invention is:
The display control unit corrects the initial speed based on the acceleration and the lower limit speed so that the display target stops at the determined target stop position, and uses the corrected initial speed to display the display target. There is a scroll display.

In order to achieve the above object, a fourth feature of the display control apparatus according to the present invention is as follows.
The stop position calculation means determines the target stop position of the display target as a position to be displayed within the display frame by a predetermined range from the end of the display target in the scroll direction, and the calculated calculation stop position is the When it is within a predetermined range before and after the target stop position, the stop candidate position closest to the calculated stop position is determined as the target stop position.

  According to the first feature of the display control device according to the present invention, since the target stop position is calculated first, the display target is scroll-displayed so as to continuously decelerate to the lower limit speed at the stop position. It is possible to realize a scroll operation that stops at a natural position with natural movement.

  According to the second feature of the display control device according to the present invention, the acceleration is corrected based on the initial speed and the lower limit speed so that the display object is stopped at the target stop position determined, and the corrected acceleration is used. Scroll the display target.

  Therefore, since the initial speed is constant according to the speed of the flick operation, it is possible to realize a scroll operation that stops with natural movement from the initial speed when the user performs the flick operation.

  According to the third feature of the display control device according to the present invention, the initial speed is corrected based on the acceleration and the lower limit speed so that the display object stops at the target stop position determined, and the corrected initial speed is Use to scroll the display object.

  Therefore, since the acceleration is always constant, the scroll speed can be reduced more naturally.

  According to the fourth feature of the display control apparatus of the present invention, the target stop position of the display target is determined as a position to be displayed in the display frame by a predetermined range from the end of the display target in the scroll direction, and the calculation is performed. When the calculated stop position is within a predetermined range before and after the target stop position, the stop candidate position closest to the calculated stop position is determined as the target stop position.

  For this reason, it is possible to prevent the buttons from being displayed in a large range that cannot be operated, and thus it is possible to prevent the display area of the display panel from being used wastefully.

1 is an explanatory diagram illustrating a schematic configuration of a printer network system including an image generation apparatus according to a first embodiment of the present invention. It is a block diagram which shows the internal structure virtually constructed | assembled on CPU which the image generation apparatus which concerns on 1st Embodiment of this invention has. It is the figure which showed an example of the display screen of the display operation panel which the image generation apparatus which concerns on 1st Embodiment of this invention has. It is the flowchart which showed the process sequence of the image generation apparatus which concerns on embodiment of this invention. It is a figure explaining the predetermined range in the image generation apparatus which concerns on embodiment of this invention. (A) shows the relationship between the position and speed when the stop position of distance X0 exceeds the stop target position, and (b) is a display screen when the stop position of distance X0 exceeds the stop target position. An example is shown. (C) shows the relationship between the position and speed when the stop position at the distance X0 does not reach the stop target position, and (d) shows that the stop position at the distance X0 does not reach the stop target position. The example of a display screen at the time of stopping is shown. (E) shows the relationship between the position and speed when the distance X0 is corrected to the correction distance X1, and (f) shows an example of a display screen when the distance X0 is corrected to the correction distance X1. It is explanatory drawing explaining the scroll operation | movement by the flick operation in the image generation apparatus which concerns on embodiment of this invention.

  Hereinafter, embodiments of a display control device according to the present invention will be described in detail with reference to the drawings. The embodiment described below exemplifies an apparatus or the like for embodying the technical idea of the present invention, and the technical idea of the present invention is the material, shape, structure, The layout is not specified as follows. The technical idea of the present invention can be variously modified within the scope of the claims.

[First Embodiment]
(Configuration of display control device)
Hereinafter, a display control apparatus according to a first embodiment of the present invention will be described in detail with reference to the accompanying drawings.

(Overall configuration of printer network system)
FIG. 1 is an explanatory diagram showing a schematic configuration of a printer network system having a display control apparatus according to the first embodiment of the present invention, and FIG. 2 is provided in the image generation apparatus 2 according to the first embodiment of the present invention. It is a block diagram which shows the internal structure virtually constructed | assembled on CPU.

  As shown in FIG. 1, the printer network system according to the present embodiment has an image generation device 2 that has various processing functions such as print processing and also functions as a display control device according to claims, and generates an image via a network LAN. A plurality of client terminals 1 (only one client terminal 1 is shown in FIG. 1 as a representative) connected to the apparatus 2.

  The network LAN is a wireless network such as a local network (LAN) or a wireless LAN (WLAN) such as 10BASE-T or 100BASE-TX using the communication protocol TCP / IP. For example, a home network based on peer-to-peer Simple networks such as are also included.

  Each client terminal 1 is constituted by a general-purpose computer such as a PC (personal computer). The client terminal 1 includes a CPU 16 that executes various processes based on a control program. The CPU 16 is connected to a RAM 18 that functions as a working area, a ROM 17 that stores data, and the like, and is connected to various devices through various interfaces. Specifically, the CPU 16 has an input unit 19 composed of a keyboard, a mouse, etc., an output unit 20 composed of a liquid crystal display, an external storage device 21 such as a large-capacity storage device, etc. A disk drive 22 for reading data recorded in the recording medium 50 and writing predetermined data to the external recording medium 50 is connected.

  The external storage device 21 has a storage area for application programs for generating document data including print images such as documents and images, a storage area for printer driver programs of the image generation apparatus 2, and a storage area for various other application programs. Has been.

  The CPU 16 is an arithmetic device configured by a processor, a memory, and other peripheral devices, and activates an application program in the external storage device 21 in accordance with an activation request input from the input unit 19. Further, the CPU 16 generates image data indicating an image instructed by parameter input from the input unit 19 on the activated application program. The generated image data is displayed and output at the output unit 20, and is stored in the database area of the external storage device 21 when a save request is input from the input unit 19.

  The image data stored in the database area of the external storage device 21 is read from the external storage device 21 when a read request is input from the input unit 19 while the application program is activated. The print image of the read image data can be displayed and output on the output unit 20, or can be processed on the application program and regenerated as new image data.

  The CPU 16 virtually constructs the printer driver 11 on the CPU by executing the printer driver program on the CPU 16 when a print request for the original data generated by the original application program or the like is input. Then, the printer driver 11 causes the image generation apparatus 2 to output a print job. The printer driver 11 is a data conversion program executed on the client terminal 1 in order to control the image generation apparatus 2 connected to the client terminal 1. When the user performs an operation for requesting printing, the printer driver 11 acquires image data including a print image generated by an original application or the like, and generates a print job according to predetermined print setting information. Then, the generated print job is output from the external interface unit 15 to the image generation apparatus 2.

  On the other hand, the image generating apparatus 2 includes a plurality of ink heads having a large number of nozzles, and discharges black or color ink from each of the ink heads to perform printing in units of lines. This is an ink jet type color printer that forms the images in such a manner as to overlap each other.

  In the present embodiment, the image generating apparatus 2 prints out image information on a document and an external interface unit 94 to which the external interface units 15 of the plurality of client terminals 1 are connected via the local area network LAN. And a printer unit 96 that prints (records) a print image on printing paper (one side or both sides) based on the image signal output from the scanner unit 98, and the image generation device 2 A display operation panel 97 that is a display unit that displays information related to operations on the display, and a control unit 90 that performs display control of the display operation panel 97 and controls the entire image generation apparatus.

  From each client terminal 1, the control unit 90 receives a print job of a print image. The control unit 90 generates raster data of the print image based on the received print job. The image generation apparatus 2 causes the printer unit 96 to print a print image on a print sheet under the conditions specified in the print job.

  The control unit 90 is connected to a display operation panel 97 including an operation screen and a touch panel covering the operation screen. As shown in FIG. 2, the display operation panel 97 includes a pressure-sensitive or electrostatic transparent touch panel 97a disposed on the front surface, and a liquid crystal display panel disposed on the back surface of the touch panel 97a for displaying various display screens. 97b. The user can press various buttons displayed on the display screen by directly touching the surface of the touch panel 97a with a finger or the like while viewing the display screen of the liquid crystal display panel 97b. In addition, the display operation panel 97 detects a flick operation for moving the display screen so that the display screen is flicked or a swipe operation for moving the display screen so that the display screen is swept in a certain direction with the finger pressed.

  FIG. 3 is a diagram showing an example of a display screen of the display operation panel 97 included in the image generation apparatus 2 according to the first embodiment of the present invention.

  As shown in FIG. 3, the display operation panel 97 is provided with a touch panel 97a overlapping the liquid crystal display panel 97b.

  A function button scroll area 97b1 is provided on the display screen displayed on the liquid crystal display panel 97b. In the function button scroll area 97b1, for example, a plurality of buttons such as a button for designating a document setting direction and a button for designating a document size are displayed to be scrollable in the left-right direction.

  The user can scroll the buttons displayed in the function button scroll area 97b1 in the left-right direction by performing a flick operation. At this time, as will be described later, a scroll operation is realized in which the buttons are scrolled with natural movement and stopped at an appropriate position.

  The control unit 90 of the image generation apparatus 2 that causes the printer unit 96 to perform a printing operation includes a CPU 95. The CPU 95 is an arithmetic processing constituted by a processor such as a CPU or DSP (Digital Signal Processor), memory, hardware such as other electronic circuits, software such as a program having the function, or a combination thereof. Device. The CPU 95 virtually constructs various functional modules by appropriately reading and executing the program, and performs processing related to image data, operation control of each unit, and various processing for user operations. Further, the CPU 95 controls the operation of the scanner unit 98 and the printer unit 96 according to the contents input and set from the display operation panel 97 based on the program and setting information stored in the ROM 91.

  The control unit 90 is provided with a RAM 92, and the RAM 92 temporarily stores data necessary for the CPU 95 to execute each process.

  Further, the control unit 90 is provided with an external storage device 93, and this external storage device 93 is connected to the CPU 95.

(Configuration on CPU 95)
Next, an internal block on the CPU 95 will be described.

  As shown in FIG. 2, the control unit 90 is connected to an external interface unit 94, a display / operation panel 97, and a printer unit 96, and includes a CPU 95 and a print job storage unit 93a. Here, the print job storage unit 93 a is provided as a storage area of the external storage device 93 and stores the print job received by the print job receiving unit 901. The “module” used in the present embodiment is configured by hardware such as an apparatus or device, software having the function, or a combination thereof, and a functional unit for achieving a predetermined operation. Indicates.

  The print job storage unit 93a stores the print job received by the print job reception unit 901.

  On the CPU 95, a print job reception unit 901, an operation signal acquisition unit 903, a print control unit 911, a stop position calculation unit 905, and a display control unit 906 are provided.

  The print job receiving unit 901 is a module that receives a print job and stores the received print job in the print job storage unit 93a. For example, a print job including image data is input from a user terminal (not shown) connected through the external interface unit 94 and stored in the print job storage unit 93a.

  The operation signal acquisition unit 903 acquires an operation signal detected by the touch panel 97a when the user performs a pressing operation or a flick operation of a button displayed on the touch panel 97a, and the operation signal is received by the print control unit 911 or the stop. The data is transmitted to the position calculation unit 905.

  The print control unit 911 is a module that controls the driving of the inkjet heads of each color and the operation of the driving unit of the conveyance path and controls the entire image forming process, and forms an image at a timing and a printing speed according to the scheduling. More specifically, the print control unit 911 performs the operation on the conveyed paper based on the operation signal acquired by the operation signal acquisition unit 903 and the image data included in the print job stored in the print job storage unit 93a. The ink jet heads 96C, 96M, 96Y, and 96K print the ink in units of lines by ejecting ink at a drop number of 0 to 7 drops.

  When detecting the flick operation, the stop position calculation unit 905 calculates the stop position of the display target as the calculated stop position based on the detected initial speed of the flick operation, the lower limit speed for stopping the scroll, and the acceleration. This is a module for determining a stop candidate position closest to a calculated stop position as a target stop position from a plurality of stop candidate positions determined at predetermined intervals.

  The display control unit 906 is a module that scrolls and displays buttons so as to continuously decelerate to the lower limit speed at the target stop position determined by the stop position calculation unit 905.

<Operation of Image Generation Device>
Next, the operation of the image generation apparatus 2 according to the embodiment of the present invention will be described.

  FIG. 4 is a flowchart showing a processing procedure of the image generation apparatus 2 according to the embodiment of the present invention.

  As shown in FIG. 4, when the user performs a flick operation on the touch panel 97a (step S101; YES), an operation signal detected by the touch panel 97a is acquired and the operation signal is transmitted to the stop position calculation unit 905. .

  The stop position calculation unit 905 determines the initial speed V0 based on the received operation signal (step S103). Here, the initial speed V0 is a speed at the moment when the finger leaves the display screen when the user flicks and moves the display screen by pressing the finger with a finger.

  Next, based on the initial speed V0 of the flick operation determined in step S103 and the lower limit speed V at which the scrolling is stopped, the stop position calculation unit 905 uses, for example, the following (Formula 1) to scroll left and right A distance X0 from the flicked position in the direction to the stop position is calculated (step S105).

^{X0 = (V 2 -V0 2)} / 2a 0 ( Equation 1)

Here, a ₀ is a default acceleration, and a predetermined value such as −10 (mm / s ² ) is used, for example. Also, when we are decelerated by the acceleration a _0, a distance to a complete stop and X0, to the lower limit speed V may be set to 0 (mm / s), it is decelerated by the acceleration a ₀ Alternatively, for example, 10 (mm / s) may be set as the lower limit speed V, which is a speed at which the scroll speed is forcibly set to 0 (mm / s) before completely stopping.

  Next, the display control unit 906 determines whether or not the stop position (calculated stop position) of the calculated distance X0 is within the predetermined range d (step S107).

  FIG. 5 is a diagram illustrating the predetermined range d.

  As shown in FIG. 5, the buttons 971 to 974 displayed in the function button scroll area 97b1 displayed on the liquid crystal display panel 97b of the display operation panel 97 are displayed so as to be scrollable in the horizontal direction.

  Then, a candidate of a target position that is desired to be stopped at the right end of the frame of the function button scroll region 97b1 of the liquid crystal display panel 97b by scrolling is set as a stop candidate position T. A plurality of candidate stop positions T are provided at predetermined intervals as positions slightly shifted to the right from the boundary between the button 972 and the button 973 so that the user can recognize that scrolling is possible. Then, as will be described later, a stop candidate position T that is closest to the calculated stop position among the plurality of stop candidate positions T is determined as the target stop position S. A range that is a predetermined distance away from the target stop position S in the left-right direction is a predetermined range d.

  When the stop position (calculated stop position) of the calculated distance X0 is within the predetermined range d, the display control unit 906 does not operate the button from the right end of the frame of the display screen of the liquid crystal display panel 97b. Will be displayed larger. If the button is displayed in this way, the user is wasting the display area of the display panel even though the user cannot operate the operation button. In particular, since the display screen of the liquid crystal display panel 97b of the image generating apparatus 2 has a relatively small size, if the display area of the liquid crystal display panel 97b is used unnecessarily, the user needs to perform further flick operations. It will decline.

  Therefore, when it is determined that the calculated stop position of the distance X0 (calculated stop position) is within the predetermined range d (step S107; YES), the display control unit 906 displays the stop position of the calculated distance X0 (calculated stop position). The correction distance X1 is calculated by correcting the distance X0 so that becomes the target stop position S (step S109). At this time, as described above, since a plurality of stop candidate positions T are provided at predetermined intervals, the stop candidate position T closest to the calculated stop position among the plurality of stop candidate positions T is determined as the target stop position S. Is done. Therefore, the display control unit 906 calculates a correction distance X1 from the position where the flick operation is performed in the left-right direction of scrolling to the determined target stop position S.

  FIG. 6 is an explanatory diagram for explaining the correction of the distance X0. (A) shows the relationship between the position and speed when the stop position (calculated stop position) at the distance X0 exceeds the target stop position S, and (b) shows the stop position (calculated stop position) at the distance X0. Shows an example of a display screen when the target stop position S is exceeded. (C) shows the relationship between the position and speed when the stop position (calculated stop position) at the distance X0 does not reach the target stop position S and (d) shows the stop position (calculated at the distance X0). An example of a display screen when the stop position is not reached the target stop position S and is stopped is shown. (E) shows the relationship between the position and speed when the distance X0 is corrected to the correction distance X1, and (f) shows an example of a display screen when the distance X0 is corrected to the correction distance X1.

  As shown in FIGS. 6A and 6B, the stop position (calculated stop position) R1 of the distance X0 exceeds the target stop position S, and the calculated stop position R1 is within the predetermined range d. In this case, a part of the left side of the button 973 from the right end of the frame of the function button scroll area 97b1 of the liquid crystal display panel 97b is displayed large. However, since a part on the right side of the button 973 is outside the frame of the display screen, the user cannot operate the button 973. Therefore, the function button scroll area 97b1 of the liquid crystal display panel 97b is wasted.

  Further, as shown in FIGS. 6C and 6D, the stop position (calculated stop position) R2 of the distance X0 does not reach the target stop position S, and the calculated stop position R2 is within the predetermined range d. If it is within, a part of the left side of the button 972 is enlarged from the right end of the frame of the function button scroll area 97b1 of the liquid crystal display panel 97b. However, since a part on the right side of the button 972 is outside the frame of the display screen, the user cannot operate the button 972. Therefore, similarly, the function button scroll area 97b1 of the liquid crystal display panel 97b is wasted.

  On the other hand, as shown in FIGS. 6E and 6F, when the distance X0 is corrected to the correction distance X1, the calculated stop position R3 coincides with the target stop position S. Therefore, as shown in FIG. 6F, a part of the left side of the button 973 from the right end of the frame of the function button scroll area 97b1 of the liquid crystal display panel 97b is displayed a little. Therefore, the user can recognize that it is possible to further scroll in the same direction, so that the function button scroll area 97b1 of the liquid crystal display panel 97b is effectively utilized.

  Next, the display control unit 906 calculates the acceleration a based on the distance X0 or the correction distance X1 (step S111). Specifically, when the calculated stop position (calculated stop position) of the distance X0 is outside the predetermined range d (step S107; NO), the display control unit 906 calculates the acceleration a using the following (Formula 2). calculate.

a = (V ² −V 0 ² ) / 2X0 (Formula 2)

  On the other hand, when the calculated stop position of the distance X0 (calculated stop position) is within the predetermined range d and the corrected distance X1 is calculated by correcting the distance X0 (step S107; YES, step S109), the display control unit 906 The acceleration a is calculated using the following (Equation 3).

^{a = (V 2 -V0 2)} / 2X1 ( Equation 3)

  Thereby, since the acceleration a is calculated, the display control unit 906 scrolls the button on the display screen d of the liquid crystal display panel 97b so as to decelerate based on the acceleration a from the initial speed V0 (step S113). ).

  FIG. 7 is an explanatory diagram illustrating a scroll operation by a flick operation in the image generation apparatus 2 according to the embodiment of the present invention.

  As shown in FIG. 7A, a flick operation for moving the function button scroll area 97b1 displayed on the liquid crystal display panel 97b so as to flip in the direction of the arrow (left direction) after the user presses the display screen with a finger. If it does, as shown in FIG.7 (b), the button displayed in the display frame of the function button scroll area 97b1 will be scroll-displayed to the left side.

  Then, as shown in FIG. 7C, when the scroll operation is stopped, the left side of the button 973 from the right end of the function button scroll area 97b1 of the function button scroll area 97b1 displayed on the liquid crystal display panel 97b. The part is displayed a little. Thereby, the user can recognize that it is possible to further scroll in the same direction.

  As described above, according to the image generation device 2 according to the embodiment of the present invention, when the stop position calculation unit 905 detects a flick operation, the detected initial speed of the flick operation and the lower limit speed at which scrolling is stopped. The stop position of the button is calculated as the calculated stop position based on the acceleration and the acceleration, and the stop candidate position T closest to the calculated stop position is determined as the target stop position S from the plurality of stop candidate positions T determined at predetermined intervals. Then, the display control unit 906 scrolls the display target so as to continuously decelerate to the lower limit speed at the determined target stop position S.

  Thus, the target stop position S is determined first, and then the button is scroll-displayed so as to continuously decelerate to the lower limit speed at the target stop position S, so that the user stops at a proper position for the user with natural movement. A scroll operation can be realized.

  Further, the stop position calculation unit 905 determines that the target stop position of the button is displayed within the frame of the function button scroll region 97b1 by a predetermined range from the end of the button in the scroll direction, and calculates the calculated stop position (calculated stop position). ) Is within a predetermined range before and after the target stop position S, the candidate stop position T closest to the calculated stop position is determined as the target stop position S.

  This prevents the buttons from being displayed in a large range that cannot be operated, so that it is possible to prevent the function button scroll area 97b1 of the display panel from being used wastefully.

  In the image generating apparatus 2 according to the embodiment of the present invention, as shown in step S111 of the flowchart, the acceleration a is calculated using (Expression 2) or (Expression 3), and the acceleration a is changed from the initial speed V0. Based on the display screen d of the liquid crystal display panel 97b, the buttons were scrolled so as to decelerate based on this.

However, not limited thereto, the display control unit 906, as with the following (Equation 4) to calculate the initial velocity V1, decelerates based from initial speed V1 calculated for default acceleration a _0, a liquid crystal display The buttons may be scrolled on the display screen d of the panel 97b.

  In the image generation apparatus 2 according to the embodiment of the present invention, a button is described as an example of a display target. However, the display target is not limited to a button and may be an icon or the like.

  In the embodiment of the present invention, the image generation apparatus 2 is used as an example of the display control apparatus. In this case, the CPU 16 includes a print job reception unit 901, an operation signal acquisition unit 903, a print control unit 911, a stop position calculation unit 905, and a display control unit 906. That is, the present invention can be applied to all devices that include a display operation panel and allow a user to perform a flick operation from a touch panel.

DESCRIPTION OF SYMBOLS 1 ... Client terminal 2 ... Image generation apparatus 11 ... Printer driver 15 ... External interface part 16,95 ... CPU
17, 91 ... ROM
18,92 ... RAM
DESCRIPTION OF SYMBOLS 19 ... Input part 20 ... Output part 21, 93 ... External storage device 22 ... Disk drive 50 ... External recording medium 90 ... Control unit 93a ... Print job storage part 94 ... External interface part 96 ... Printer part 96C ... Inkjet head 96K ... Inkjet Head 96M ... Inkjet head 96Y ... Inkjet head 97 ... Display / operation panel 97a ... Touch panel 97b ... Liquid crystal display panel 97b1 ... Function button scroll area 98 ... Scanner unit 901 ... Print job reception unit 903 ... Operation signal acquisition unit 905 ... Stop position calculation unit 906: Display control unit 911 ... Print control unit

Claims (4)

A display control device that scrolls a display target based on a flick operation and displays the display target within a display frame of a display operation panel,
When the flick operation is detected, the stop position of the display target is calculated as the calculated stop position based on the detected initial speed of the flick operation, the lower limit speed and the acceleration at which the scroll is stopped, and at predetermined intervals. Stop position calculating means for determining a stop candidate position closest to the calculated stop position as a target stop position from a plurality of determined stop candidate positions;
Display control means for scroll-displaying the display object so as to continuously decelerate to the lower limit speed at the determined target stop position;
A display control apparatus comprising: The display control means includes
The acceleration is corrected based on the initial speed and the lower limit speed so that the display target stops at the determined target stop position, and the display target is scroll-displayed using the corrected acceleration. The display control apparatus according to claim 1. The display control means includes
Correcting the initial speed based on the acceleration and the lower limit speed so that the display object stops at the determined target stop position, and scrolling the display object using the corrected initial speed. The display control apparatus according to claim 1, wherein: The stop position calculation means determines the target stop position of the display target as a position to be displayed within the display frame by a predetermined range from the end of the display target in the scroll direction, and the calculated calculation stop position is the The display control device according to claim 1, wherein a stop candidate position closest to the calculated stop position is determined as the target stop position when the target stop position is within a predetermined range before and after the target stop position.

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