JP2007187927A - Browse terminal and browse terminal program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a browse terminal achieving power-saving and a browse terminal program for the purpose of the power-saving of the browse terminal. <P>SOLUTION: A display element of an electrophoretic system by which display contents are held even if a power source is cut off is used and the information on an ID of a document displayed in the electrophoretic display element and a display page are memorized in an EEPROM which is a non-volatile memory. And when there is no key input for the prescribed time (5 seconds) (S11: YES), the power source over the entire part of the system of the browse terminal is cut off (S14), and when the key input is performed (S13: YES), the power source is connected (S14). <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a browsing terminal and a browsing terminal program, and more particularly, to a browsing terminal for saving power and a browsing terminal program for power saving of the browsing terminal.

Conventionally, in a device driven by a dry cell or a battery, it is required to increase the drive time. If a large-capacity dry cell or battery is used, the driving time becomes longer, but there is a problem that the apparatus becomes larger. Therefore, a method of extending the driving time by reducing power consumption can be considered. In the image display device according to the invention described in Patent Document 1, when the keyboard is not operated for a certain period of time, the image generation circuit and the image memory are turned off, and when a new keyboard input is made, the image generation circuit In addition, the power generation of the image memory and the image memory is reduced by performing control to reconnect and start the power source of the image memory.
JP-A-5-273950

  However, in the image display device of the invention described in Patent Document 1, only the power generated in the image generation circuit and the image memory is reduced, and the display device still consumes the same power as usual. There is a problem.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a browsing terminal for saving power and a browsing terminal program for saving power of the browsing terminal.

  In order to solve the above problems, the browsing terminal of the invention according to claim 1 is a browsing terminal that displays information, displays information, and non-volatile display means that does not erase the display content even when the power is turned off, An input means for inputting an instruction to the document browsing terminal, a first power supply switching means for switching connection / disconnection of power to the viewing terminal, and a non-input time measurement for measuring a time when no input is performed by the input means Means, a non-input time determining means for determining whether or not the non-input time measured by the non-input time measuring means has reached a predetermined time or more, and the non-input time by the non-input time determining means is a predetermined time or more The first power-off control means for disconnecting from the power supply by the power supply switching means, and when the input by the input means is performed after the power supply is cut off by the power-off control means First power connection control means for connecting a power supply by the power supply switching means, display state information that is information indicating a document area displayed on the non-volatile display means, and stored contents even when the power is turned off. Non-erasable nonvolatile first display state information storage means is provided.

  The browsing terminal of the invention according to claim 2 is a browsing terminal that displays information, displays information, and stores display information that is not erased even when the power is turned off, and a memory that stores information. Means, an input means for inputting an instruction to the document browsing terminal, a non-input time measuring means for measuring a time during which no input is made by the input means, and a non-input time measured by the non-input time measuring means Non-input time determination means for determining whether or not the predetermined time has elapsed, coordinate information conversion means for converting the information into coordinate information for display on the nonvolatile display means, and conversion by the coordinate information conversion means Coordinate information storage means for storing the coordinate information, and pixel information for converting the coordinate information stored in the coordinate information storage means into pixel information for display on the nonvolatile display means. Conversion means; pixel information storage means for storing pixel information converted by the pixel information conversion means; and display control means for displaying the pixel information stored in the pixel information storage means on the nonvolatile display means. A second display state information storage unit that stores display state information that is information indicating a document area displayed on the nonvolatile display unit, a storage power source that is a power source connected to the storage unit, and the storage power source Storage power switching means for switching connection / disconnection to / from the storage means, and when the non-input time becomes a predetermined time or more by the non-input time determination means, the storage power supply means switches the storage means to the storage power supply. Storage power-off control means for disconnecting from the storage power supply, and input by the input means after the storage power supply is disconnected from the storage means by the storage power-off control means A storage power connection control means for connecting the storage power to the storage means by the storage power switching means, and the storage means is connected to or disconnected from the storage power Maintenance means for maintaining the storage of the display state information by the second display state information storage means, and at least the coordinate information storage means is provided in the storage means.

  Moreover, in the browsing terminal of the invention according to claim 3, in addition to the configuration of the invention according to claim 2, the pixel information storage means is provided in the nonvolatile display means and is connected to the nonvolatile display means. A display power source, a display power source switching unit for switching connection / disconnection of the display power source to / from the non-volatile display unit, and a non-input time determination unit when the non-input time becomes a predetermined time or more. The display power switching control means for disconnecting the nonvolatile display means from the display power supply by the display power switching means, and the input means after the display power supply is disconnected from the nonvolatile display means by the display disconnection control means. When the input is performed and the coordinate information converted by the coordinate information conversion unit is stored in the coordinate information storage unit, the display power source switching unit may And a first display power source connection control means for connecting said display power source to nonvolatile display unit.

  In the browsing terminal of the invention according to claim 4, in addition to the configuration of the invention according to claim 2 or 3, when only a part of the content displayed on the nonvolatile display means is rewritten The display of the non-volatile display means is performed by changing the pixel information stored in the pixel information storage means without using the coordinate information conversion means, the coordinate information storage means, and the pixel information conversion means. A display content partial changing means for changing the content is provided.

  Moreover, in the browsing terminal of the invention according to claim 5, in addition to the configuration of the invention according to claim 2, the pixel information storage means is provided in the storage means, and a power source connected to the nonvolatile display means The display power supply, the display power supply switching means for switching connection and disconnection of the display power supply to the nonvolatile display means, and the display control means only when the pixel information is displayed on the nonvolatile display means. And second display power connection control means for connecting the display power supply of the nonvolatile display means by power supply switching means.

  Moreover, in the browsing terminal of the invention according to claim 6, in addition to the configuration of the invention according to any of claims 2 to 5, the same pixel information as the pixel information stored in the pixel information storage means is stored. Before the pixel information is converted by the pixel information conversion means and stored in the pixel information storage means, the pixel information stored in the pixel information storage means is converted to the previous pixel information. Pixel information transfer means for storing as previous pixel information in the storage means, and the display control means is configured to store the pixel information stored in the pixel information storage means and the previous information stored in the previous pixel information storage means. The pixel information is compared, and display control is performed based on the difference between the pixel information and the previous pixel information.

  Moreover, in the browsing terminal of the invention which concerns on Claim 7, in addition to the structure of the invention in any one of Claims 1 thru | or 6, the storage medium connection means which connects the removable storage medium which memorize | stores information, Storage medium connection detecting means for detecting that the storage medium is connected to the storage medium connecting means, storage medium disconnection detecting means for detecting that the storage medium is disconnected from the storage medium connecting means, and the storage medium The storage medium is connected by the storage medium connection detection means while the connection detection means does not detect that the storage medium is connected and after the storage medium disconnection detection means detects that the storage medium is disconnected. In the period until it is detected, the first power-off control means and the first power-supply connection control means, or the storage power-off control means and the storage power And a power-off control means that does not function the connection control means.

  Moreover, in the browsing terminal of the invention which concerns on Claim 8, in addition to the structure of the invention in any one of Claims 1 thru | or 7, the storage medium connection means which connects the removable storage medium which memorize | stores information, A storage medium connection detection unit that detects that the storage medium is connected to the storage medium connection unit; and a storage medium disconnection detection unit that detects that the storage medium is disconnected from the storage medium connection unit, The storage medium connection detection means includes an insertion detection switch that is turned on when the storage medium is installed at a position to which the storage medium connection means can be connected, a control means that controls the browsing terminal, and An unconnected monitoring switch connected to the insertion detection switch, and the storage medium disconnection detection means is inserted when the storage medium is not in a position where the storage medium connection means can be connected. A disconnection detection switch, a control means for controlling the browsing terminal and a connection time monitoring switch connected to the extraction insertion detection switch, and when the insertion detection switch is turned on, the unconnected time monitoring Detection control means for turning off the switch, turning on the connection monitoring switch, turning on the unconnected monitoring switch when the extraction detection switch is turned on, and turning off the connection monitoring switch. I have.

  Further, in the browsing terminal of the invention according to claim 9, in addition to the configuration of the invention according to any one of claims 1 to 8, the display status information is information other than the information displayed on the nonvolatile display means. And data file identification information to be identified, and display start information indicating the current display position in the information displayed on the non-volatile display means.

  A browsing terminal program according to a tenth aspect causes a computer to function as various processing means of the browsing terminal according to any one of the first to ninth aspects.

  In the browsing terminal according to the first aspect of the present invention, the non-volatile display means can display information and can continuously display the display contents without being erased even when the power is turned off. Then, the input means inputs an instruction to the document browsing terminal, the first power supply switching means switches between connection and disconnection of the power to the viewing terminal, and the non-input time measuring means does not perform input by the input means. Time is measured, the non-input time determination means determines whether or not the non-input time measured by the non-input time measurement means has become a predetermined time or more, and the first power-off control means is the non-input time determination means When the non-input time exceeds a predetermined time, the power supply switching means disconnects from the power supply, and the first power supply connection control means is input by the input means after the power supply disconnection control means is turned off. When the power is switched by the power source switching means, the first display state information storage means stores the display state information which is information indicating the document area displayed on the nonvolatile display means, and the power is cut off. Memory contents Not being able to non-volatile storage means. Therefore, even after the power is turned off by the power-off control unit, the display state information is stored in the first display state information storage unit, so that the input by the input unit is processed based on the display state information. It is possible to save power.

  Moreover, in the browsing terminal of the invention which concerns on Claim 2, a non-volatile display means can display information, and even if a power supply is cut off, a display content can be continuously displayed, without being erased. The storage means stores information, the input means inputs an instruction to the document browsing terminal, the non-input time measuring means measures a time when no input is made by the input means, and the non-input time determining means is Determining whether or not the non-input time measured by the non-input time measuring means has reached a predetermined time or more, the coordinate information converting means converts the information into coordinate information for display on the non-volatile display means, The information storage means stores the coordinate information converted by the coordinate information conversion means, and the pixel information conversion means converts the coordinate information stored in the coordinate information storage means into pixel information for display on the nonvolatile display means. The pixel information storage means stores the pixel information converted by the pixel information conversion means, the display control means displays the pixel information stored in the pixel information storage means on the non-volatile display means, and performs the second display. Condition The information storage means stores display state information which is information indicating the document area displayed on the nonvolatile display means, the storage power supply is a power supply connected to the storage means, and the storage power supply switching means The connection to the storage means is switched, and the storage power cut-off control means disconnects the storage means from the storage power supply by the storage power switch means when the non-input time is determined by the non-input time determination means to be a predetermined time or more. The storage power connection control means connects the storage power to the storage means by the storage power switching means when the input by the input means is performed after the storage power is disconnected from the storage means by the storage power disconnection control means, and the maintenance means The storage of the display state information by the second display state information storage unit can be maintained regardless of whether the storage unit is connected to or disconnected from the storage power source. The storage means can be provided with at least coordinate information storage means. Therefore, even after the power is turned off by the storage power cut-off control unit, the display state information is stored in the second display state information storage unit, so that the input by the input unit is processed based on the display state information. It is possible to save power.

  In the browsing terminal of the invention according to claim 3, in addition to the effect of the invention according to claim 2, the display power supply switching means switches connection / disconnection of the display power supply to / from the nonvolatile display means, The control means disconnects the non-volatile display means from the display power supply by the display power supply switching means when the non-input time becomes longer than a predetermined time by the non-input time determination means, and the first display power supply connection control means When the display power supply is disconnected from the non-volatile display means by the control means and input is performed by the input means, and the coordinate information converted by the coordinate information conversion means is stored in the coordinate information storage means, the display power supply switching means A display power supply can be connected to the non-volatile display means. Therefore, when the input by the input means is not performed, the display power source is cut off, so that power can be saved.

  Further, in the browsing terminal of the invention according to claim 4, in addition to the effect of the invention according to claim 2 or 3, the display content partial change means is only a part of the content displayed on the nonvolatile display means. Is rewritten, by changing the pixel information stored in the pixel information storage means without using the coordinate information conversion means, the coordinate information storage means, and the pixel information conversion means, the nonvolatile display means Display contents can be changed. Therefore, since there are few processing steps, the load on the browsing terminal can be suppressed and power saving can be achieved.

  In the browsing terminal of the invention according to claim 5, in addition to the effect of the invention according to claim 2, the display power supply switching means switches connection and disconnection of the display power supply to the non-volatile display means, and displays the second display. The power connection control means can connect the display power supply of the nonvolatile display means by the display power supply switching means only when the display control means displays the pixel information on the nonvolatile display means. Therefore, since the display power source is connected only when displaying the pixel information on the non-volatile display means, power saving can be achieved.

  Moreover, in the browsing terminal of the invention according to claim 6, in addition to the effect of the invention according to any one of claims 2 to 5, the previous pixel information storage means includes the pixel information stored in the pixel information storage means. The pixel information storage means stores the pixel information stored in the pixel information storage means before the pixel information is converted by the pixel information conversion means and stored in the pixel information storage means. It can be stored in the means as previous pixel information. The display control means compares the pixel information stored in the pixel information storage means with the previous pixel information stored in the previous pixel information storage means, and displays the pixel information based on the difference from the previous pixel information. Can be controlled. Therefore, since display control is not performed for all pixels, the load on the viewing terminal can be suppressed, and power saving can be achieved.

  In the browsing terminal of the invention according to claim 7, in addition to the effect of the invention according to any one of claims 1 to 6, the storage medium connecting means connects a removable storage medium for storing information, The storage medium connection detection means detects that the storage medium is connected to the storage medium connection means, and the storage medium disconnection detection means detects that the storage medium is disconnected from the storage medium connection means, and the power cut control means The storage medium is detected by the storage medium connection detection means while the storage medium connection detection means does not detect that the storage medium is connected and after the storage medium disconnection detection means detects that the storage medium is disconnected. The first power-off control unit and the first power-supply connection control unit, or the storage power-off control unit and the storage power-supply connection control unit may not function until the event is detected. That. Therefore, power saving can be achieved.

  Moreover, in the browsing terminal of the invention according to claim 8, in addition to the effect of the invention according to any one of claims 1 to 7, the storage medium connects the insertion detection switch of the storage medium connection detection means to the storage medium connection means. It can be turned on when the storage medium is installed at a possible position, and the unconnected monitoring switch is connected to the control means for controlling the viewing terminal and the insertion detection switch. The extraction detection switch of the storage medium disconnection detection means can be turned on when there is no storage medium at a position where the storage medium can be connected to the storage medium connection means. The connection monitoring switch includes a control means for controlling the browsing terminal, Connected to the sampling insertion detection switch. The detection control means turns off the unconnected monitoring switch when the insertion detection switch is turned on, turns on the connection monitoring switch, and monitors the unconnected state when the extraction detection switch is turned on. The switch can be turned on and the monitoring switch at connection can be turned off.

  Further, in the browsing terminal of the invention according to claim 9, in addition to the effect of the invention according to any one of claims 1 to 8, the display state information includes data file identification information and display start information. Even after the power is turned off, the input by the input means can be processed based on the display state information, and the power can be saved.

  Moreover, in the browsing terminal program of the invention which concerns on Claim 10, a computer can be functioned as various processing means of the browsing terminal in any one of Claims 1 thru | or 9.

  Hereinafter, a first embodiment to a fifth embodiment of the present invention will be described with reference to the drawings. In any of the embodiments, an electrophoretic display unit that retains display contents even when the power is turned off is used.

  In the first embodiment, the browsing terminal 1 when the entire browsing terminal is controlled by one power source will be described. In this browsing terminal 1, the document ID displayed on the electrophoretic display unit 4 and information on the display page (display state information) are stored in the EEPROM 11, which is a nonvolatile memory, and there is no key input for a predetermined time. When the power of the entire system of the browsing terminal is turned off and a key is input, the power is connected. It should be noted that the predetermined time may be a time that can be determined so that the operator is not operating, and is determined in advance. In the first embodiment, it is 5 seconds.

  In the second embodiment, the electrophoretic display unit 104 and the RAM 110 are separately provided in the browsing terminal, and the display data storage area for displaying information on the electrophoretic display unit is provided in the electrophoretic display unit 104. The browsing terminal 100 will be described. In the browsing terminal 100, the display state information is stored in the storage unit provided in the electrophoretic display unit 104 in the always-on RAM 111. Then, when there is no key input for a predetermined time, the electrophoretic display unit 104 and the RAM 110 are turned off. When the key input is performed, the RAM 110 and the electrophoretic display unit 104 are sequentially connected. The predetermined time may be a time that can be determined so that the operator is not operating, and is determined in advance. In the second embodiment, it is 5 seconds.

  In the third embodiment, the browsing terminal 200 in which the electrophoretic display unit 204 and the RAM 210 are separately provided in the browsing terminal, and the RAM 210 has a display data storage area for displaying information on the electrophoretic display unit. explain. In the browsing terminal 200, display state information is stored in the RAM 210. Then, the power source of the electrophoretic display unit 204 is connected only when the display content of the electrophoretic display unit 204 is updated, the power source is turned off when not updating, and when there is no key input for a predetermined time, the RAM 210 When the power is turned off and key input is performed, the power source of the RAM 210 is sequentially connected. The predetermined time may be a time that can be determined so that the operator is not operating, and is determined in advance. In the third embodiment, it is 5 seconds.

  In the fourth embodiment, in addition to the browsing terminal 100 of the second embodiment, the browsing includes an insertion detection sensor 322 and a sampling detection sensor 323 that detect connection and disconnection of a memory card 306 that is an external memory. The terminal 300 will be described. In the browsing terminal 300, when the memory card is not connected, the power of the RAM 310 and the electrophoretic display unit 304 is cut off because the display is not updated.

  In the fifth embodiment, a description will be given of a browsing terminal 400 that has a change in display state even when no operation from the user is performed in the browsing terminal 100 of the second embodiment. Specifically, the browsing terminal 400 performs cursor display that repeatedly blinks at regular intervals. In this browsing terminal 400, since the electrophoretic display unit 104 is provided with a display data storage area for displaying information on the electrophoretic display unit, the RAM 110 is turned off even if the blinking display of the cursor is updated. You can keep it.

  First, a first embodiment will be described with reference to FIGS. FIG. 1 is an external view of the browsing terminal 1, and FIG. 2 is a block diagram showing an electrical configuration of the browsing terminal 1. 3 is a front view of the electrophoretic display unit 4, FIG. 4 is a cross-sectional view taken along the line AA ′ (FIG. 3) of the electrophoretic display unit 4, and FIG. 5 is an electrophoretic display. FIG. 6 is a cross-sectional view in the direction of the arrow in line BB ′ (FIG. 3) of part 4. The upward direction in FIGS. 4 and 5 is the front of the viewing terminal 1. FIG. 6 is a flowchart showing the main operation of the browsing terminal 1, and FIG. 7 is a flowchart of processing corresponding to the key executed in the main operation.

  First, the external appearance of the browsing terminal 1 will be described with reference to FIG. As shown in FIG. 1, it has a substantially rectangular parallelepiped shape, and an electrophoretic display unit 4 is provided on the front surface thereof, and an upper key 81, a lower key 82, a left key 83, and a right key 84 are disposed below the electrophoretic display unit 4. An operation key 8 is provided. An insertion slot 80 for inserting the memory card 6 is provided on the right side.

  Next, the electrical configuration of the viewing terminal 1 will be described with reference to the block diagram of FIG. As shown in FIG. 2, the browsing terminal 1 is provided with a CPU 2 that controls the browsing terminal 1. The CPU 2 is connected to the electrophoretic display unit 4 and is connected to the display control unit 3 that controls display contents on the electrophoretic display unit 4 and a memory card interface that can connect a memory card 6 that is a portable external memory. Face (hereinafter abbreviated as I / F) 5, key I / F 7 connected to key 8 for controlling input from key 8, ROM 9 storing a program executed by CPU 2, and data temporarily A RAM 10 to be stored, an EEPROM 11 that can retain stored contents even when the power is turned off, and a power control unit 12 that manages on / off of the system power supply 30 that supplies power to the entire browsing terminal 1 by control of the system power switch 20. Connected. The power supply control unit 12 is supplied with power from a power supply (not shown) different from the system power supply 30 and is connected to the battery insertion sensor 13 and the key 8 for detecting battery insertion and removal. Thereby, the power supply control part 12 can detect battery insertion and key input. The system power supply is turned off when a battery is connected.

  Here, an outline of a physical configuration of the electrophoretic display unit 4 will be described with reference to the drawings. As shown in FIGS. 3 to 5, in the electrophoretic display unit 4, a lower substrate 50 provided on a lower surface portion thereof and an upper substrate 60 provided on an upper surface portion thereof are arranged to face each other, and the lower substrate 50 and the upper substrate 60 are A display unit 70 is provided between the two. The AA ′ line indicates a line parallel to the horizontal direction (left-right direction in FIG. 1) of the browsing terminal 1, and the BB ′ line indicates a line parallel to the vertical direction (vertical direction in FIG. 1). Show. 3 to 5, for ease of explanation, the number of pixels is 20 (5 × 4). However, in practice, the number of pixels can be provided as necessary.

  The lower substrate 50 includes a lower electrode 52 that generates an electric field in the display unit 70, a lower electrode protective film 51 that is an insulating film formed by applying an insulating material on the upper surface side of the lower electrode 52, and a lower surface of the lower electrode 52. And a housing support part 53 that is provided on the side and supports the viewing terminal 1. The lower electrode protective film 51 is formed of a material capable of exhibiting high insulation properties such as a resin film such as polyethylene terephthalate or silica, or an inorganic material such as glass. In the present embodiment, the lower electrode protective film 51 and the housing support part 53 are plastic substrates (resin films) made of flexible polyethylene terephthalate. The lower electrode 52 is a substrate having a plurality of electrodes in which linear electric conductors are arranged in parallel in the lateral direction (AA ′ line direction) so that a constant voltage is applied. .

  In the upward direction of the lower substrate 50 (the upward direction in FIGS. 3 and 3), the upper substrate 60 is provided facing the lower substrate 50 and at a predetermined interval in parallel. The upper substrate 60 includes an upper electrode 62 that generates an electric field in the display unit 70, an upper electrode protective film 61 that is an insulating film formed by applying an insulating material on the lower surface side of the upper electrode 62, and an upper surface of the upper electrode 62. A display layer 63 that is provided on the side and is configured by a transparent member and functions as a display screen. The upper electrode protective film 61 is formed of a material that can exhibit high transparency, such as polyimide, polyethylene terephthalate, or glass. The upper electrode 62 is a substrate having a plurality of electrodes in which linear electric conductors are arranged in parallel in the vertical direction (B-B ′ line direction) so that a constant voltage is applied. And made of a material capable of exhibiting high transparency. In the present embodiment, the upper electrode protective film 61 is a plastic substrate (resin film) made of polyethylene terephthalate. The upper electrode 62 is a transparent electrode formed of indium tin oxide (ITO), and the display layer 63 is a glass substrate. That is, since the upper substrate 60 is a transparent body, it functions as a display substrate that allows the user to visually recognize the display unit 70 from above the upper substrate 60 (upward in FIG. 2).

  Next, the display unit 70 will be described. A gap formed by the lower substrate 50 and the upper substrate 60 that are provided to face each other and the spacer 71 is the display unit 70. The spacer 71 is installed in a gap between the lower substrate 50 and the upper substrate 60, and the gap is equally divided into a lattice shape to form a plurality of small compartment cells, and supports the lower substrate 50 and the upper substrate 60. The spacer 71 is a flexible member configured as a plate-like member in which a plurality of through holes are formed in a lattice shape, and may be formed of a synthetic resin such as polyimide or polyethylene terephthalate.

  In addition, the display unit 70 is filled with charged particles 33 a and 33 b and a dispersion medium 34. The charged particles 33a and 33b are made of a material that can be charged in the dispersion medium 34, and are made of a pigment or dye made of an organic compound or an inorganic compound, or a pigment or dye wrapped with a synthetic resin. In the present embodiment, the charged particles 33a are a mixture of styrene resin and titanium dioxide, and have an average particle diameter of 5 μm (7 wt%), and the amount of titanium dioxide in the particles is 40 wt%. The charged particles 33b are a mixture of styrene resin and carbon black and have an average particle size of 5 μm (10 wt%), and the amount of carbon black in the particles is 30 wt%. Therefore, the charged particles 33a have a white color tone, and the charged particles 33b have a black color tone. The charged particles 33a and the charged particles 33b are charged so as to be different from each other positively or negatively. Here, it is assumed that the charged particles 33a are negatively charged and the charged particles 33b are positively charged.

  On the other hand, as the dispersion medium 34, alcohols, hydrocarbons, silicone oil, etc. that can exhibit high insulation properties and have low viscosity can be used. In the present embodiment, Isopar (73 wt%) manufactured by ExxonMobil, which is a paraffinic solvent, is used. In addition, ethanol (10 wt%) is added to the dispersion medium 34 as an additive.

  Further, on the upper surface of the upper substrate 60 (the surface that does not face the lower substrate 50), the mask portion 40 for concealing the peripheral portion of the display unit 70 where there is no small partition cell from the front view so that the user cannot see it. Is provided. The mask portion 40 is a square-shaped plate-like member provided with a constant width along the four sides of the upper substrate 60 and provided with a through-hole so that the user can visually recognize the display portion 70. Polyethylene terephthalate What is necessary is just to attach what colored synthetic resins, such as these, or to form with the ink layer printed on the surface of the display layer 63. FIG. When the electrophoretic display unit 4 is viewed from above, the display unit 70 can be viewed from the through hole provided in the mask unit 40.

  Next, storage areas provided in the RAM 10 and the EEPROM 11 will be described. The RAM 10 is provided with a previous display data storage area 1001, a current display data storage area 1002, a page data expansion area 1003, other storage areas 1004, and the like. The EEPROM 11 has a displayed document ID storage area 1108, a displayed page number storage area 1109, and the like.

  In the page data development area 1003, text, images, graphics, etc. of the document read from the memory card 6 are developed and stored as coordinate information. This coordinate information indicates the arrangement position of the text, image, figure, etc. in the electrophoretic display unit 4. Then, pixel information for controlling the electrophoretic display unit 4 based on the coordinate information is created and stored in the current display data storage area 1002. This pixel information is information for designating display (black) or non-display (white) for each small cell of the electrophoretic display unit 4. Before the pixel information is stored in the current display data storage area 1002, the pixel information stored in the current display data storage area 1002 is stored in the previous display data storage area 1001. The other storage area 1004 is used as a work storage area used in various processes performed in the browsing terminal 1.

  The display control unit 3 is instructed to control the voltage to each sub-compartment cell based on the pixel information stored in the previous display data storage area 1001 and the pixel information stored in the current display data storage area 1002. . Specifically, the previous display data storage area 1001 stores the pixel information of the contents currently displayed on the electrophoretic display unit 4, and the current display data storage area 1002 stores the contents to be displayed. Pixel information is stored. Therefore, in the pixel information currently stored in the display data storage area 1002, no instruction is given to the sub-compartment cell in which the previous pixel information is the same as the previous pixel information, and “display (black)” is displayed in the previous pixel information. ”And“ non-display (white) ”in the current pixel information, or“ non-display (white) ”in the previous pixel information, and“ display (black) ”in the current pixel information. In other words, an instruction is given to a small block cell in which the previous pixel information and the current pixel information are different. In the display control unit 3, the upper electrode 62 of the small partition cell designated as display (black) becomes positive and the charged particles 33b are charged to the upper electrode 62 side, and the small partition cell designated as non-display (white). The voltage control is performed such that the upper electrode 62 becomes negative and the charged particles 33a are charged to the upper electrode 62 side.

  Further, in the displayed document ID storage area 1108 of the EEPROM 11, an ID indicating a document displayed on the electrophoretic display unit 4 is stored as “data file identification information” of “display state information”. Based on the display state information, the document stored in the memory card 6 can be read. The displayed document ID is assigned to each document in advance, and data for displaying on the electrophoretic display unit 4 of the document is stored in the memory card 6 corresponding to the ID. The data of this document is organized in units of pages. Note that “data file identification information” of “display status information” is not an ID, but may be a file name of a document stored in the memory card 6, a path for specifying a file in the memory card 6, or the like. Good. The document displayed on the electrophoretic display unit 4 is not limited to the one stored in the memory card 6 but may be one stored in the EEPROM 11 or the ROM 9. The displayed page number storage area 1109 stores the page number of the document displayed on the electrophoretic display unit 4 as “display start information” of “display state information”.

  Next, with reference to FIG.6 and FIG.7, operation | movement of the browsing terminal 1 is demonstrated. This operation is started when a battery is connected to the browsing terminal 1. First, the system power switch 20 is turned on by the power controller 12 and the system power supply 30 is connected (S2). Then, the CPU 2 stores “1” in the displayed document ID storage area 1108 and “1” in the displayed page number storage area 1109 as initial values (S3). Are all set to “white” (S4), and an instruction is given to the display control unit 3 to set all the small cells in the electrophoretic display unit 4 to “white” (S5). Here, the value of the no-input time counter is initialized to “0”. This no-input time counter is a timer counter for measuring the time when the input to the key 8 is not performed, and is counted up based on a signal from a timer (not shown) connected to the CPU 2.

  Then, the CPU 2 reads out the data of the page number (1) stored in the displayed page number storage area 1109 of the document with the ID (1) stored in the displayed document ID storage area 1108 from the memory card 6. Then, the coordinate information is developed in the page data development area 1003 (S6). Then, the contents of the current display data storage area 1002 are copied to the previous display data storage area 1001 (S7), pixel information is created based on the coordinate information stored in the page data development area 1003, and the current display data storage It is stored in the area 1002 (S8). Then, an image of pixel information currently stored in the display data storage area 1002 in the CPU 2 is displayed on the electrophoretic display unit 4 (S9). Specifically, the pixel information stored in the current display data storage area 1002 and the pixel information stored in the previous display data storage area 1001 are compared, and the pixels in the current display data storage area 1002 are only for different small-partition cells. A control instruction based on the information is given to the display control unit 3.

  Then, the CPU 2 determines whether or not an input from the key 8 has been performed (S10). If the input from the key 8 has been performed (S10: YES), the CPU 2 performs a process corresponding to the key (S17, see FIG. 7).

  As shown in FIG. 7, in the process corresponding to the key, first, it is determined whether or not the up key 81 for giving an instruction to switch to the display of the previous document is pressed (S21). If the up key 81 is pressed (S21: YES), “1” is subtracted from the value of the display document ID storage area 1108, and “1” is stored in the displayed page number storage area 1109 (S22). Then, the value of the no-input time counter for measuring the time when the key 8 is not input is initialized to “0” (S29). Then, the process returns to the main operation. First, if the up key 81 for instructing to switch to the previous document display has not been pressed (S21: NO), it is determined whether or not the left key 83 for instructing to switch to the previous page display has been pressed. Is performed (S23). If the left key 83 is pressed (S23: YES), “1” is subtracted from the value of the displayed page number storage area 1109 (S24). Then, the value of the no-input time counter for measuring the time when the key 8 is not input is initialized to “0” (S29). Then, the process returns to the main operation.

  If the left key 83 for instructing to switch to the previous page is not pressed (S23: NO), it is determined whether the right key 84 for instructing to switch to the next page is pressed. (S25). If the right key 84 is pressed (S25: YES), “1” is subtracted from the value of the displayed page number storage area 1109 (S26). Then, the value of the no-input time counter for measuring the time when the key 8 is not input is initialized to “0” (S29). Then, the process returns to the main operation. If the right key 84 for instructing to switch to the next page is not pressed (S25: NO), it is determined whether or not the lower key 82 for instructing to switch to the next document is pressed. (S27). If the down key 82 is pressed (S27: YES), “1” is subtracted from the value of the displayed page number storage area 1109 (S28). Then, the value of the no-input time counter for measuring the time when the key 8 is not input is initialized to “0” (S29). Then, the process returns to S6 of the main operation.

  After returning to the main operation, the CPU 2 stores the page number data stored in the displayed page number storage area 1109 of the document having the ID stored in the displayed document ID storage area 1108, that is, the key 8. Is read from the memory card 6 and its coordinate information is expanded in the page data expansion area 1003 (S6), and the contents of the current display data storage area 1002 are stored in the previous display data storage area 1001. Copied (S7), pixel information is created based on the coordinate information stored in the page data development area 1003, stored in the current display data storage area 1002 (S8), and is stored in the current display data storage area 1002 in the CPU 2. An image of the stored pixel information is displayed on the electrophoretic display unit 4 ( 9).

  In the main operation, if the CPU 2 does not accept the input from the key 8 (S10: NO), the key input is performed for a predetermined time depending on whether the value of the no-input time counter is equal to or longer than a predetermined time (5 seconds). A determination is made as to whether or not (5 seconds) has elapsed (S11). If the no-input time counter is not greater than or equal to the predetermined time (5 seconds) (S11: NO), it is not determined that there has been no input for longer than the predetermined time (5 seconds), and the process returns to S10 and the input from the key 8 is determined. . In this way, the processes of S10 and S11 are repeatedly performed, and when the time when there is no input from the key 8 exceeds a predetermined time (5 seconds) (S11: YES), the system power supply 30 is sent from the CPU 2 to the power control unit 12. The power control unit 12 turns off the system power switch 20 and disconnects the system power supply 30 (S12). This processing is the main part of the present invention. If the key 8 is not input for a predetermined time (5 seconds) or longer, it is considered that the operator of the browsing terminal 1 is not operating the browsing terminal 1. That is, if the key operation is not performed, the display content of the electrophoretic display unit 4 is not switched. And the display part of the browsing terminal 1 is an electrophoretic display part which can hold | maintain a display content even if a power supply is cut off. Therefore, even if the system power supply 30 is turned off, no problem arises for the operator who is viewing the displayed information. Furthermore, since the document ID being displayed and the number of pages being displayed are stored in the EEPROM 11, which is a non-volatile memory that can retain the stored contents even when the power is turned off, the next time the system power is turned on, It is possible to recognize which ID of which document is currently stored. Therefore, when there is no key input for a predetermined time (5 seconds) or more (S11: YES), the system power supply 30 is turned off (S12).

  When the power controller 12 detects an input from the key 8 (S13: YES), the system power switch 20 is turned on and the system power supply 30 is connected (S14). Then, each function including the CPU 2 is activated, and the page number data stored in the displayed page number storage area 1109 of the document of the ID stored in the displayed document ID storage area 1108 in the CPU 2 is stored in the memory card. 6 and the coordinate information is developed in the page data development area 1003 (S15). In the CPU 2, pixel information is created in the page data development area 1101 based on the coordinate information stored in the page data development area 1003 and stored in the current display data storage area 1002 (S 16). In this way, when the key 8 is operated, power is supplied to the entire system of the viewing terminal 1, and processing corresponding to the key operation is performed.

  Then, processing corresponding to the input of the key 8 detected in S13 is performed (S17, see FIG. 4), the process returns to S6, and the page of the document instructed by the input of the key 8 is displayed on the electrophoretic display unit 4. It will be displayed (S6-S9).

  Since the above processing is repeatedly performed and the system power is turned off when no key operation is performed, power saving can be achieved. Further, information indicating which page of which document is displayed when power is supplied again is stored in the nonvolatile EEPROM 11 and is currently displayed on the electrophoretic display unit 4. The next document, previous document, next page, and previous page can be displayed on the data.

  The electrophoretic display unit 4 of the above embodiment corresponds to “nonvolatile display means”, the key 8 corresponds to “input means”, and the power control unit 12 and the system power switch 20 correspond to “first power supply switching means”. The no-input time counter corresponds to “non-input time measuring means”, the CPU 2 that executes the process of S11 corresponds to “non-input time determination means”, and the CPU 2 that executes the processes of S11 and S12. The power control unit 12 corresponds to the “first power-off control unit”, the power control unit 12 that executes the processes of S13 and S14 corresponds to the “first power connection control unit”, and the EEPROM 11 corresponds to the “display state information storage unit”. ", The system power supply 30 corresponds to" power supply ", the displayed document ID and the number of displayed pages correspond to" display status information ". The previous display data storage area 1041 corresponds to the “previous pixel information storage unit”, and the CPU 2 that performs the process of S7 of the main operation shown in FIG. 6 corresponds to the “pixel information transfer unit”.

  Next, a second embodiment will be described with reference to FIGS. FIG. 8 is a block diagram showing an electrical configuration of the browsing terminal 100, FIG. 9 is a flowchart showing a main operation of the browsing terminal 100, and FIG. 10 is a flowchart of a display process performed in the main operation. It is. In addition, since the external appearance of the browsing terminal 100 of this Embodiment is the same as the external appearance of the browsing terminal 1 of 1st Embodiment, it abbreviate | omits and quotes FIG. 1 and description. 1, the browsing terminal 1 is the browsing terminal 100, the electrophoretic display unit 4 is the electrophoretic display unit 104, the key 8 is the key 108, the upper key 81 is the upper key 181, the lower key 82 is the lower key 182, and the left key 83. Is the left key 183 and the right key 84 is the right key 184. Further, for the processing corresponding to the key executed in the flowchart of the main operation shown in FIG. 9, the flowchart of FIG. 7 used in the first embodiment is cited.

  First, the electrical configuration of the browsing terminal 100 according to the second embodiment will be described with reference to FIG. As shown in FIG. 8, the browsing terminal 100 is provided with a CPU 102 that controls the browsing terminal 100. The CPU 102 is connected to the electrophoretic display unit 104, and is connected to a display control unit 103 that controls display contents on the electrophoretic display unit 104, and a memory card interface that can connect a memory card 106 that is a portable external memory. A face (hereinafter abbreviated as I / F) 105, a key I / F 107 connected to the key 108 for controlling input from the key 108, a ROM 109 storing a program executed by the CPU 102, and data temporarily. A RAM 110 to be stored and a constantly operating RAM 111 are connected.

  Here, a power supply system in the browsing terminal 100 will be described. The electrophoretic display unit 104 is supplied with power from the display unit power supply 130, the RAM 110 is supplied with power from the RAM power supply 131, and other devices such as the CPU 102 and the constantly operating RAM 111 are connected to the system power supply. Power is supplied from (not shown). The electrophoretic display unit 104 is connected to a display unit power supply 130 via a display unit power switch 120, and the display unit power switch 120 is turned on and off under the control of the CPU 102. The RAM 110 is connected to a RAM power supply 131 via a RAM power switch 121. The RAM power switch 121 is also turned on and off under the control of the CPU. The display unit power switch 120 and the RAM power switch 121 are turned off when a battery is connected.

  The electrophoretic display unit 104 is provided with a previous display data storage area 1041 and a current display data storage area 1042, and the RAM 110 is provided with a page data development area 1101 and other storage areas 1102. The operation RAM 111 is provided with a displayed document ID storage area 1111 and a displayed page number storage area 1112. The contents stored in each storage area are the same as in the first embodiment, and the devices provided with the storage area are different.

  Next, the operation of the browsing terminal 100 will be described with reference to FIGS. 9 and 10. This operation is started in the CPU 102 when power is supplied from the system power supply when a battery is connected to the viewing terminal 100. First, the RAM power switch 121 is turned on and the RAM power supply 131 is connected (S101). Then, “1” is stored as an initial value in the currently-displayed document ID storage area 1111 and “1” is stored in the currently-displayed page number storage area 1112 of the always-on RAM 111 (S102). In S104 and S105, it is necessary to activate the electrophoretic display unit 104 in order to display “white” on the electrophoretic display unit 104. Therefore, the display unit power switch 120 is turned on and the display unit power supply 130 is connected (S103). Then, the previous display data storage area 1041 and the current display data storage area 1042 provided in the electrophoretic display unit 104 are all set to “white” (S104). Then, an instruction to set all the small compartment cells of the electrophoretic display unit 104 to “white” is given to the display control unit 103 (S105). Here, the value of the no-input time counter is initialized to “0”. This no-input time counter is a timer counter for measuring a time during which no input to the key 108 is performed, and is counted up based on a signal from a timing means (not shown) connected to the CPU 102.

  Then, display processing is performed (S106, see FIG. 10). As shown in FIG. 10, in the display process, the page number (1) data stored in the displayed page number storage area 1112 of the document with ID (1) stored in the displayed document ID storage area 1111 is stored. The data is read from the memory card 106, and the coordinate information is expanded in the page data expansion area 1101 (S121). Then, the contents of the current display data storage area 1042 are copied to the previous display data storage area 1041 (S122), pixel information is created based on the coordinate information stored in the page data development area 1101, and the current display data storage is stored. It is stored in the area 1042 (S123). Then, an image of pixel information currently stored in the display data storage area 1042 is displayed on the electrophoretic display unit 104 (S124). Specifically, the pixel information stored in the current display data storage area 1042 and the pixel information stored in the previous display data storage area 1041 are compared, and the pixels of the current display data storage area 1042 are only for different small-partition cells. A control instruction based on the information is given to the display control unit 103. Then, the process returns to the main operation.

  Then, it is determined whether or not an input from the key 108 has been performed (S110). If input from the key 108 has been performed (S110: YES), processing corresponding to the key is performed (S118, see FIG. 4). Since the process corresponding to the key is the same as that of the first embodiment, the description thereof is omitted. However, in the second embodiment, the display document ID storage area 1111 and the displayed page number storage area 1112 are provided in the always-on RAM 111.

  After returning to the main operation, the page number data stored in the displayed page number storage area 1112 of the document having the ID stored in the displayed document ID storage area 1111, that is, the key 108 is input. Is read from the memory card 106, its coordinate information is expanded in the page data expansion area 1101 (S121), and the contents of the current display data storage area 1042 are copied to the previous display data storage area 1041. (S122), pixel information is created based on the coordinate information stored in the page data development area 1101, stored in the current display data storage area 1042 (S123), and stored in the current display data storage area 1042. An image of pixel information is displayed on the electrophoretic display unit 104 (S124). .

  Further, in the main operation, if the input from the key 108 is not accepted (S110: NO), the key input is performed for a predetermined time (5 seconds) depending on whether the value of the no-input time counter is equal to or longer than the predetermined time (5 seconds). ) A determination is made as to whether or not the above has occurred (S111). If the no-input time counter is not greater than or equal to the predetermined time (5 seconds) (S111: NO), it is not determined that there has been no input for longer than the predetermined time (5 seconds), and the process returns to S110 to determine the input from the key 108. . In this way, the processes of S110 and S111 are repeatedly performed, and when the time when there is no input from the key 108 exceeds a predetermined time (5 seconds) (S111: YES), the RAM power switch 121 is turned off. Thus, the RAM power 131 is disconnected, and the display power switch 120 is turned off to disconnect the display power 130 (S112). This processing is the main part of the present invention. If the key 108 is not input for a predetermined time (5 seconds) or longer, it is considered that the operator of the viewing terminal 100 is not operating the viewing terminal 100. That is, if the key operation is not performed, the display content of the electrophoretic display unit 104 is not switched. The display unit of the viewing terminal 100 is an electrophoretic display unit that can retain display contents even when the power is turned off. Therefore, even if the display unit power supply 130 is turned off, no problem arises for the operator who is viewing the displayed information. In addition, since the display is not switched, power is supplied to the RAM 110 provided with the page data development area 1101 used when displaying information on the electrophoretic display unit 104 and the electrophoretic display unit 104 itself. There is no need to be. Therefore, when there is no key input for a predetermined time (5 seconds) or more (S111: YES), the RAM power supply 131 is disconnected (S112).

  When an input from the key 108 is detected (S113: YES), the RAM power switch 121 is first turned on and the RAM power supply 131 is connected (S114). As described above, when the key input is not performed, the RAM power supply 131 is cut off, so that power saving can be achieved. Then, the RAM 110 in which the page data development area 1101 and other storage areas 1102 are provided rises and is stored in the displayed page number storage area 1112 of the document with the ID stored in the displayed document ID storage area 1111. The data of the number of existing pages is read from the memory card 106, and the coordinate information is expanded in the page data expansion area 1101 (S115). Then, the display unit power switch 120 is turned on, and the display unit power supply 130 is connected (S116). Then, pixel information is created based on the coordinate information stored in the page data development area 1003 and stored in the current display data storage area 1002 (S117).

  Then, processing corresponding to the input of the key 108 detected in S118 is performed (S117, see FIG. 4), and the process returns to S106, and the page of the document instructed by the input of the key 108 is displayed on the electrophoretic display unit 104. It is displayed (S118, display process).

  The processing as described above is repeatedly performed, and the RAM power source 131 and the display unit power source 130 are turned off when not necessary, so that power saving can be achieved. Furthermore, since information on which page of which document is displayed when power is supplied again is stored in the always-on RAM 111 to which power is supplied from the system power supply, The next document, previous document, next page, and previous page can be displayed on the data displayed on the electrophoretic display unit 4.

  The electrophoretic display unit 104 corresponds to “nonvolatile display means”, the RAM 110 corresponds to “storage means”, the key 108 corresponds to “input means”, and the no-input time counter corresponds to “non-input time measurement means”. The CPU 102 that executes the process of S111 of the main operation shown in FIG. 9 corresponds to “uninput time determination means”. The CPU 102 that performs the processing of S121 of the display process shown in FIG. 10 and the process of S115 of the main operation shown in FIG. The CPU 102 that performs the processing of S123 of the display processing shown in FIG. 10 and the processing of S117 of the main operation shown in FIG. 9 corresponds to “pixel information conversion means”, and present display data storage provided in the electrophoretic display unit 104 The area 1042 corresponds to “pixel information storage unit”. The CPU 102 that performs the process of S105 of the main operation shown in FIG. 9 and the process of S124 of the display process shown in FIG. 10 corresponds to the “display control means”, and the currently-displayed document ID storage area 1111 and The displayed page number storage area 1112 corresponds to “display state information storage unit”.

  The RAM power 131 corresponds to “storage power”, the RAM power switch 121 corresponds to “storage power switching means”, and the CPU 102 that performs the processing of S111 and S112 of the main operation shown in FIG. Means that the CPU 102 performing the process of S114 corresponds to “storage power connection control means”, and that the constantly operating RAM 111 is connected to the system power supply corresponds to “maintenance means”, and the display unit power supply 130 Corresponds to “display power supply”, the display unit power switch 120 corresponds to “display power supply switching means”, and the CPU 102 performing the process of S112 of the main operation shown in FIG. 9 corresponds to “display power supply cut-off control means”. The CPU 102 that performs the process of S116 corresponds to “display power connection control means”. The previous display data storage area 1041 corresponds to the “previous pixel information storage unit”, and the CPU 102 that performs the processing of S7 of the display process illustrated in FIG. 10 corresponds to the “pixel information transfer unit”.

  Next, a third embodiment will be described with reference to FIGS. FIG. 11 is a block diagram showing an electrical configuration of the browsing terminal 200, FIG. 12 is a flowchart showing a main operation of the browsing terminal 200, and FIG. 13 shows a no key input process performed in the main operation. It is a flowchart of. In addition, since the external appearance of the browsing terminal 200 of this Embodiment is the same as that of the browsing terminal 1 of 1st Embodiment, it abbreviate | omits referring FIG. 1 and description. In FIG. 1, the browsing terminal 1 is the browsing terminal 200, the electrophoretic display unit 4 is the electrophoretic display unit 204, the key 8 is the key 208, the upper key 81 is the upper key 281, the lower key 82 is the lower key 282, and the left key 83. Is the left key 283, and the right key 84 is the right key 284. Also, for the processing corresponding to the key executed in the flowchart of the main operation shown in FIG. 12, the flowchart of FIG. 7 used in the first embodiment is cited.

  First, the electrical configuration of the browsing terminal 200 according to the third embodiment will be described with reference to FIG. As shown in FIG. 11, the browsing terminal 200 is provided with a CPU 202 that controls the browsing terminal 200. The CPU 202 is connected to the electrophoretic display unit 204, and a memory card interface that can connect a display control unit 203 that controls display contents on the electrophoretic display unit 204 and a memory card 206 that is a portable external memory. A face (hereinafter abbreviated as I / F) 205, a key I / F 207 connected to the key 208 and controlling input from the key 208, a ROM 209 storing a program executed by the CPU 202, and data temporarily A RAM 210 to be stored and a constantly operating RAM 211 are connected.

  Here, a power supply system in the browsing terminal 200 will be described. In the browsing terminal 200 of the third embodiment, the electrophoretic display unit 204 is supplied with power from the display unit power supply 230 and the RAM 210 is the RAM power source 231, as with the browsing terminal 100 of the second embodiment. The other devices such as the CPU 202 and the constantly operating RAM 211 are supplied with power from a system power supply (not shown). The electrophoretic display unit 204 is connected to a display unit power source 230 via a display unit power switch 220, and the display unit power switch 220 is turned on and off under the control of the CPU 202. The RAM 210 is connected to the RAM power source 231 via the RAM power switch 221. The RAM power switch 221 is also turned on and off under the control of the CPU 202. The display unit power switch 220 and the RAM power switch 221 are turned off when a battery is connected.

  The RAM 210 is provided with a previous display data storage area 2101, a current display data storage area 2102, a page data expansion area 2103, and other storage areas 2104. A middle page number storage area 2112 is provided. The contents stored in each storage area are the same as in the first embodiment, and the devices provided with the storage area are different.

  Next, the operation of the browsing terminal 200 will be described with reference to FIGS. As in the second embodiment, this operation is also started by the CPU 202 when power is supplied from the system power supply when a battery is connected to the viewing terminal 200. First, the RAM power switch 221 is turned on and the RAM power source 231 is connected (S202). Then, “1” is stored as an initial value in the currently displayed document ID storage area 2111 and “1” is stored as an initial value in the currently displayed page number storage area 2112 (S203). Then, the previous display data storage area 2101 and the current display data storage area 2102 provided in the electrophoretic display unit 204 are all set to “white” (S204). In step S <b> 206, the electrophoretic display unit 204 needs to be activated in order to display “white” on the electrophoretic display unit 204. Therefore, the display unit power switch 220 is turned on and the display unit power source 230 is connected (S205). Then, the display control unit 203 is instructed to set all the small division cells of the electrophoretic display unit 204 to “white” (S206). Since the display operation on the electrophoretic display unit 204 is completed, the display unit power switch 220 is turned off and the display unit power source 230 is cut off (S207). As described above, the display unit power supply 230 is connected only when the electrophoretic display unit 204 is operated. Therefore, the display unit power supply 230 is disconnected when the electrophoretic display unit 204 is not operated, and power saving can be achieved. Here, the value of the no-input time counter is initialized to “0”. This no-input time counter is a timer counter for measuring a time during which no input to the key 208 is performed, and is counted up based on a signal from a timing means (not shown) connected to the CPU 202.

  Then, the data of the page number (1) stored in the displayed page number storage area 2112 of the document with ID (1) stored in the currently displayed document ID storage area 2111 of the always-on RAM 211 is read from the memory card 206. The coordinate information is read out and developed in the page data development area 2103 (S208). Then, the contents of the current display data storage area 2102 are copied to the previous display data storage area 2101 (S209), pixel information is created based on the coordinate information stored in the page data development area 2103, and the current display data storage It is stored in the area 2102 (S210). Then, since information is displayed on the electrophoretic display unit 204, the display unit power switch 220 is turned on and the display unit power source 230 is connected to activate the electrophoretic display unit 204 (S211). Then, an image of pixel information currently stored in the display data storage area 2102 is displayed on the electrophoretic display unit 204 (S212). Specifically, the pixel information stored in the current display data storage area 2102 and the pixel information stored in the previous display data storage area 2101 are compared, and the pixels in the current display data storage area 2102 are only for different small-partition cells. A control instruction based on the information is given to the display control unit 203. Since the display operation on the electrophoretic display unit 204 is completed, the display unit power switch 220 is turned off and the display unit power source 230 is disconnected (S213). Also here, the display unit power supply 230 is connected only when the electrophoretic display unit 204 is operated. Therefore, the display unit power supply 230 is disconnected when not operating, and power saving can be achieved.

  Then, it is determined whether or not an input from the key 208 has been performed (S214). If input from the key 208 has been performed (S214: YES), processing corresponding to the key is performed (S217, see FIG. 7). Since the process corresponding to the key is the same as that of the first embodiment, the description thereof is omitted. However, in the third embodiment, the display document ID storage area 2111 and the displayed page number storage area 2112 are always provided in the operation RAM 211.

  After returning to the main operation, the page number data stored in the displayed page number storage area 2112 of the document having the ID stored in the displayed document ID storage area 2111, that is, the key 208 is input. Is read from the memory card 206, the coordinate information is expanded in the page data expansion area 2103 (S208), and the contents of the current display data storage area 2102 are copied to the previous display data storage area 2101. (S209), pixel information is created based on the coordinate information stored in the page data development area 2103, stored in the current display data storage area 2102 (S210), the display unit power switch 220 is turned on, and display is performed. The unit power supply 230 is connected (S211), and the current display data storage area 21 Image pixel information stored is displayed on the electrophoretic display unit 204 in 2 (S224). Since the display operation on the electrophoretic display unit 204 is completed, the display unit power switch 220 is turned off and the display unit power source 230 is disconnected (S213).

  In the main operation, if the input from the key 208 is not accepted (S214: NO), the key input is performed for a predetermined time (5 seconds) depending on whether the value of the no-input time counter is equal to or longer than the predetermined time (5 seconds). ) A determination is made as to whether or not the above has occurred (S215). If the no-input time counter is not greater than or equal to the predetermined time (5 seconds) (S215: NO), it is not determined that there has been no input for longer than the predetermined time (5 seconds), and the process returns to S214 to determine input from the key 208 . In this manner, the processes of S214 and S215 are repeatedly performed, and when the time when there is no input from the key 208 is equal to or longer than the predetermined time (5 seconds) (S211: YES), the process without key input is performed (S216, (See FIG. 13).

  In the no key input process, as shown in FIG. 13, first, the RAM power switch 221 is turned “off” and disconnected from the RAM power source 231 (S221). This processing is the main part of the present invention. If the key 208 is not input for a predetermined time (5 seconds) or longer, it is considered that the operator of the browsing terminal 200 is not operating the browsing terminal 200. That is, if no key operation is performed, the display content of the electrophoretic display unit 204 is not switched. Therefore, it is not necessary to supply power to the RAM 210 provided with the page data development area 2103 used when displaying information on the electrophoretic display unit 204. Therefore, when there is no key input for a predetermined time (5 seconds) or more (S215: YES), the RAM power source 231 is disconnected (S221).

  When an input from the key 208 is detected (S222: YES), the RAM power switch 221 is first turned on and the RAM power supply 231 is connected (S223). As described above, when the key input is not performed, the RAM power source 231 is disconnected, so that power saving can be achieved. Then, the RAM 210 in which the page data development area 2103 and the other storage area 2104 are provided rises and is stored in the displayed page number storage area 2112 of the document with the ID stored in the displayed document ID storage area 2111. The data of the number of existing pages is read from the memory card 206, and the coordinate information is expanded in the page data expansion area 2103 (S224). Then, pixel information is created based on the coordinate information stored in the page data development area 2103 and stored in the current display data storage area 2101 (S225).

  Then, processing corresponding to the input of the key 208 detected in S218 is performed (S217, see FIG. 4), the process returns to S206, and the page of the document instructed by the input of the key 208 is displayed on the electrophoretic display unit 204. It is displayed (S206, display process).

  The processing as described above is repeatedly performed, and when not necessary, the RAM power source 231 and the display unit power source 230 are cut off, so that power saving can be achieved. Furthermore, since the information indicating which page of which document is displayed when power is supplied again is stored in the always-on RAM 211 to which power is supplied from the system power supply, The next document, the previous document, the next page, and the previous page can be displayed on the data displayed on the electrophoretic display unit 204.

  In addition, the electrophoretic display unit 204 of the above embodiment corresponds to “nonvolatile display means”, the RAM 210 corresponds to “storage means”, the key 208 corresponds to “input means”, and the page data development area of the RAM 210. Reference numeral 1201 corresponds to “coordinate information storage means”, current display data storage area 2102 provided in the RAM 210 corresponds to “pixel information storage means”, and currently displayed document ID storage area 2111 provided in the constantly operating RAM 211. The displayed page number storage area 2112 corresponds to “display state information storage means”. The RAM power source 231 corresponds to “storage power source”, the RAM power switch 221 corresponds to “storage power source switching unit”, the display unit power source 230 corresponds to “display power source”, and the display unit power switch 220 corresponds to “display power source”. Corresponding to “power switching means”, connecting the constantly operating RAM 211 to the system power supply corresponds to “maintaining means”, and the no-input time counter corresponds to “non-input time measuring means”.

The CPU 202 that executes the process of S215 of the main operation shown in FIG. 12 corresponds to the “uninput time determination means”. The process of S208 of the main operation shown in FIG. 12 and the process of S224 of no key input shown in FIG. The CPU 202 to perform corresponds to “coordinate information conversion means”, and the CPU 202 that performs the processing of S210 of the main operation shown in FIG. 12 and S225 of no key input processing shown in FIG. 13 corresponds to “pixel information conversion means”. The CPU 202 that performs the process of S212 of the main operation shown in FIG. The CPU 202 that performs the processing of S215 of the main operation shown in FIG. 12 and the processing of S221 of the display processing shown in FIG. 13 corresponds to the “storage power cut-off control means”, and the CPU 202 that performs the processing of S223 is “storage power connection control means”. The CPU 202 that performs the processes of S205, S207, S211 and S213 of the main operation shown in FIG. 12 corresponds to “display power connection control means”. The previous display data storage area 2101 corresponds to the “previous pixel information storage unit”, and the CPU 202 that performs the process of S209 of the main operation illustrated in FIG. 12 corresponds to the “pixel information transfer unit”.

  Next, a fourth embodiment will be described with reference to FIGS. FIG. 14 is a block diagram showing an electrical configuration of the browsing terminal 300, and FIG. 15 is a circuit diagram showing the insertion detection sensor 322 and the sampling detection sensor 323. FIG. 16 is a flowchart showing the main operation of the browsing terminal 300, and FIG. 17 is a flowchart of preprocessing performed in the main operation. In addition, since the external appearance of the browsing terminal 300 of this Embodiment is the same as the external appearance of the browsing terminal 1 of 1st Embodiment, it abbreviate | omits referring FIG. 1 and description. 1, the viewing terminal 1 is the viewing terminal 300, the electrophoretic display unit 4 is the electrophoretic display unit 704, the key 8 is the key 308, the upper key 81 is the upper key 381, the lower key 82 is the lower key 382, and the left key 83. Is the left key 383, and the right key 84 is the right key 384. In addition, for the processing corresponding to the key executed in the flowchart of the main operation shown in FIG. 16, the flowchart of FIG. 7 used in the first embodiment is cited, and the display processing is the second implementation. Reference is made to the flowchart of FIG.

  First, the electrical configuration of the browsing terminal 300 according to the fourth embodiment will be described with reference to FIG. The browsing terminal 300 of the fourth embodiment has substantially the same configuration as the browsing terminal 100 of the second embodiment. The difference is that an insertion detection sensor 322 for detecting insertion of the memory card 306 and a removal detection sensor 323 for detecting removal of the memory card 306 are provided in the memory card I / F 305. As shown in FIG. 14, the browsing terminal 300 is provided with a CPU 302 that controls the browsing terminal 300. The CPU 302 is connected to the electrophoretic display unit 704 and can be connected to a display control unit 303 that controls display contents on the electrophoretic display unit 704 and a memory card 306 that is a portable external memory. A face (hereinafter abbreviated as I / F) 305, a key I / F 307 that is connected to the key 308 and controls input from the key 308, a ROM 309 that stores programs executed by the CPU 302, and data temporarily A storage RAM 310 and a constant operation RAM 311 are connected.

  Here, a power supply system in the browsing terminal 300 will be described. As in the second embodiment, the electrophoretic display unit 704 is supplied with power from the display unit power supply 330, and the RAM 310 is supplied with power from the RAM power supply 331, and includes the CPU 302 and the constantly operating RAM 311. The other devices are supplied with power from a system power supply (not shown). The electrophoretic display unit 704 is connected to the display unit power source 330 via the display unit power switch 320, and the display unit power switch 320 is turned on and off under the control of the CPU 302. The RAM 310 is connected to a RAM power source 331 via a RAM power switch 321, and this RAM power switch 321 is also turned on and off under the control of the CPU 302. Further, the insertion sensor 322 and the extraction sensor 323 that detect insertion / extraction of the memory card 306 are connected to the unconnected monitoring power supply 332 and the connected monitoring power supply 333, respectively (see FIG. 15). The display unit power switch 320 and the RAM power switch 321 are turned off when a battery is connected.

  The electrophoretic display unit 704 is provided with a previous display data storage area 3041 and a current display data storage area 3042, and the RAM 310 is provided with a page data expansion area 3101 and other storage areas 3102. The operation RAM 311 is provided with a displayed document ID storage area 3111 and a displayed page number storage area 3112. The contents stored in each storage area are the same as in the first embodiment, and the devices provided with the storage area are different.

  Next, the insertion detection sensor 322 and the extraction detection sensor 323 will be described with reference to FIG. As shown in FIG. 15, the insertion detection sensor 322 is provided with two switches, a non-connection monitoring switch 341 and an insertion detection switch 342, and the extraction detection sensor 323 includes a connection monitoring switch 351 and a extraction detection Two switches 352 are provided. The insertion detection switch 342 is turned on when the memory card 306 is inserted into the insertion slot 80 of the memory card 306, and is turned off when the memory card 306 is not inserted. The memory card 306 is turned on when the memory card 306 is not inserted into the insertion slot 80 of the 306, and is turned off when inserted. The unconnected monitoring switch 341 and the connected monitoring switch 351 are on / off controlled by the CPU 302 and are connected to the unconnected monitoring power supply 332 and the connected monitoring power supply 333, respectively.

  The unconnected monitoring switch 341 is turned on when the memory card 306 is not inserted, that is, when the insertion detection switch 342 is off and the extraction detection switch 352 is on. The connection monitoring switch 351 is turned on when the memory card 306 is inserted, that is, when the insertion detection switch 342 is on and the extraction detection switch 352 is off. That is, when the memory card 306 is not inserted, the unconnected monitoring switch 341 is turned on and the unconnected monitoring power supply 332 is connected, so that the insertion detection switch 342 is enabled. On the other hand, the connection monitoring switch 351 is off, and the connection monitoring power supply 333 is disconnected, so that the sampling detection switch 352 is disabled. When the memory card 306 is inserted, the unconnected monitoring switch 341 is turned off, the unconnected monitoring power supply 332 is disconnected, and the insertion detection switch 342 is disabled. Turned on and connected to the monitoring power supply 333 at the time of connection, the sampling detection switch 352 becomes effective. With such a configuration, insertion and removal of the memory card 306 can be detected. The example shown in FIG. 15 is a state where the memory card 306 is not inserted.

  Next, the operation of the browsing terminal 300 will be described with reference to FIGS. 16 and 17. This operation is started in the CPU 302 when electric power is supplied from the system power supply when a battery is connected to the viewing terminal 300. First, the unconnected monitoring switch 341 is turned on, and the connected monitoring switch 351 is turned off (S302). Then, since the insertion detection switch 342 becomes valid, it is determined whether or not the memory card 306 is inserted based on whether or not the insertion detection switch 342 is on (S303). If the memory card 306 is not inserted, information to be displayed on the electrophoretic display unit 704 cannot be read, and thus it is not necessary to connect the display unit power supply 330 and the RAM power supply 331. Therefore, if the insertion detection switch 342 is off and the memory card 306 is not inserted (S303: NO), the process returns to S303 and waits for the insertion of the memory card 306.

  When the insertion detection switch 342 is on and the memory card 306 is inserted (S303: YES), the unconnected monitoring switch 341 is turned off to switch the monitoring state of the memory card 306. The connection monitoring switch 351 is turned on (S304). Then, preprocessing is performed (S305, see FIG. 17). As shown in FIG. 17, first, the RAM power switch 321 is turned on and the RAM power source 331 is connected (S321). Then, “1” is stored as an initial value in the currently displayed document ID storage area 3111 of the always-on RAM 311 and “1” is stored as an initial value in the displayed page number storage area 3112 (S322). In S304 and S305, the electrophoretic display unit 704 needs to be activated in order to display “white” on the electrophoretic display unit 704. Therefore, the display unit power switch 320 is turned on and the display unit power source 330 is connected (S323). Then, the previous display data storage area 3041 and the current display data storage area 3042 provided in the electrophoretic display unit 704 are all set to “white” (S324). Then, the display control unit 303 is instructed to set all the small division cells of the electrophoretic display unit 704 to “white” (S305). Here, the value of the no-input time counter is initialized to “0”. This no-input time counter is a timer counter for measuring the time when the input to the key 308 is not performed, and is counted up based on a signal from a timing unit (not shown) connected to the CPU 302.

  Then, display processing is performed (S306, see FIG. 10). As shown in FIG. 10, in the display process, the page number (1) data stored in the displayed page number storage area 3112 of the document with ID (1) stored in the displayed document ID storage area 3111 is stored. The data is read from the memory card 306, and the coordinate information is expanded in the page data expansion area 3101 (S121). Then, the contents of the current display data storage area 3042 are copied to the previous display data storage area 3041 (S122), pixel information is created based on the coordinate information stored in the page data development area 3101, and the current display data storage It is stored in the area 3042 (S123). Then, an image of pixel information currently stored in the display data storage area 3042 is displayed on the electrophoretic display unit 704 (S124). Specifically, the pixel information stored in the current display data storage area 3042 and the pixel information stored in the previous display data storage area 3041 are compared, and the pixels in the current display data storage area 3042 are only for different small-partition cells. A control instruction based on the information is given to the display control unit 303. Then, the process returns to the main operation.

  Then, it is determined whether or not an input from the key 308 has been performed (S307). If input from the key 308 has been performed (S307: YES), processing corresponding to the key is performed (S316, see FIG. 7). Since the process corresponding to the key is the same as that of the first embodiment, the description thereof is omitted. However, in the fourth embodiment, the display document ID storage area 3111 and the displayed page number storage area 3112 are provided in the always-on RAM 311. Then, after returning to the main operation, display processing is performed (S306, see FIG. 10).

  Further, in the main operation, if the input from the key 308 is not accepted (S307: NO), the key input is performed for a predetermined time (5 seconds) depending on whether the value of the no-input time counter is equal to or longer than the predetermined time (5 seconds). ) A determination is made as to whether or not the above has occurred (S308). If the no-input time counter is not greater than or equal to the predetermined time (5 seconds) (S308: NO), it is not determined that there has been no input for longer than the predetermined time (5 seconds), and the process returns to S307 to determine the input from the key 308. . In this manner, the processes of S307 and S08 are repeatedly performed, and when the time when there is no input from the key 308 exceeds a predetermined time (5 seconds) (S308: YES), the RAM power switch 321 is turned off. Then, the RAM power source 331 is disconnected, and the display unit power switch 320 is turned off to disconnect the display unit power source 330 (S309).

  Next, it is determined whether or not the memory card 306 has been removed (S310). Here, the unconnected monitoring switch 341 is turned off, the connected monitoring power supply 333 is turned on, and the extraction detection switch 352 that is turned on when the memory card 306 is extracted is valid. If the extraction detection switch 352 is on and the memory card 306 has been extracted (if not inserted) (S310: YES), the information displayed on the electrophoretic display unit 704 is switched in response to an input from the key 308. Therefore, the process returns to S302, the unconnected monitoring switch 341 is turned on, the connected monitoring power supply 333 is turned off (S302), and the insertion of the memory card 306 is awaited (S303).

  If the extraction detection switch 352 is not turned on and the memory card 306 has not been extracted (if inserted) (S310: NO), it is determined whether or not an input from the key 308 has been performed (S310: NO). S311). If there is no key input (S311: NO), the process returns to S310 and the memory card 306 is confirmed (S310). When an input from the key 308 is detected (S311: YES), the RAM power switch 321 is first turned on and the RAM power 331 is connected (S312). Then, the RAM 310 provided with the page data development area 3101 and the other storage area 3102 rises and is stored in the displayed page number storage area 3112 of the document with the ID stored in the displayed document ID storage area 3111. The data of the number of existing pages is read from the memory card 306, and the coordinate information is expanded in the page data expansion area 3101 (S313). Then, the display unit power switch 320 is turned on, and the display unit power source 330 is connected (S314). Then, pixel information is created based on the coordinate information stored in the page data development area 3101 and stored in the current display data storage area 3041 (S315).

  Then, processing corresponding to the input of the key 308 detected in S311 is performed (S316, see FIG. 4), the process returns to S306, and the page of the document instructed by the input of the key 308 is displayed on the electrophoretic display unit 704. It is displayed (S306, display process).

  Since the above processing is repeatedly performed and the key input is not performed for a predetermined time or the memory card 306 is not inserted, the RAM power source 331 and the display unit power source 330 are cut off. Can be achieved. Furthermore, since information on which page of which document is displayed when power is supplied again is stored in the always-on RAM 311 to which power is supplied from the system power supply, The next document, previous document, next page, and previous page can be displayed on the data displayed on the electrophoretic display unit 4.

  In the above embodiment, the electrophoretic display unit 704 corresponds to “nonvolatile display means”, the RAM 310 corresponds to “storage means”, the key 308 corresponds to “input means”, and the no-input time counter indicates “ Corresponds to “uninput time measuring means”. The RAM power source 331 corresponds to “storage power source”, the RAM power switch 321 corresponds to “storage power source switching unit”, the display unit power source 330 corresponds to “display power source”, and the display unit power source switch 320 corresponds to “display power source”. Corresponding to “power switching means”, connecting the always-on RAM 311 to the system power supply corresponds to “maintaining means”. The page data development area 3101 of the RAM 310 corresponds to “coordinate information storage means”, the current display data storage area 3042 provided in the electrophoretic display unit 704 corresponds to “pixel information storage means”, and the always-on RAM 311 is operated. The displayed document ID storage area 3111 and the displayed page number storage area 3112 provided in FIG. The memory card I / F 305 corresponds to “storage medium connection means”, the insertion detection sensor 322 corresponds to “storage medium connection detection means”, the insertion detection switch 342 corresponds to “insertion detection switch”, and is not connected. The time monitoring switch corresponds to “unconnected monitoring switch”, the extraction detection sensor 323 corresponds to “storage medium disconnection detection means”, the extraction detection switch corresponds to “extraction detection switch”, and the connection time monitoring switch “ Corresponds to "Monitoring switch at connection". The previous display data storage area 3041 corresponds to the “previous pixel information storage unit”, and the CPU 202 that performs the process of S122 of the display process illustrated in FIG. 10 corresponds to the “pixel information transfer unit”.

  The CPU 302 that executes the process of S311 of the main operation shown in FIG. 16 corresponds to the “non-input time determination means”, and the CPU 302 performs the process of S121 of the display process shown in FIG. 10 and the process of S313 of the main operation shown in FIG. Corresponds to “coordinate information conversion means”, and the CPU 302 that performs the processing of S123 of the display process shown in FIG. 10 and S315 of the main operation shown in FIG. 16 corresponds to “pixel information conversion means”. S325, the CPU 102 that performs the process of S124 of the display process shown in FIG. 10 corresponds to the “display control means”. The CPU 302 that performs the processes of S308 and S309 of the main operation shown in FIG. 16 corresponds to the “storage power cut-off control means”, and the CPU 302 that performs the process of S312 corresponds to the “storage power connection control means”. The CPU 302 that performs the processes of S308 and S309 of the main operation shown corresponds to the “display power supply cut-off control means”, and the CPU 302 that performs the process of S314 corresponds to the “display power supply connection control means”, and the main operation S303 shown in FIG. The CPU 302 that performs the process corresponds to “power-off control means”, and the CPU 302 that performs the processes of S302, S303, and S304 corresponds to “detection control means”.

  Next, a fifth embodiment will be described with reference to FIGS. FIG. 18 is a flowchart showing the main operation of the browsing terminal 400, and FIG. 19 is a flowchart of the no key input process performed in the main operation. In addition, since the external appearance of the browsing terminal 400 of this Embodiment is the same as the external appearance of the browsing terminal 1 of 1st Embodiment, it abbreviate | omits and quotes FIG. 1 and description. Further, since the electrical configuration is the same as that of the second embodiment, reference is made to FIG. The browsing terminal 1 in FIG. 1 and the browsing terminal 100 in FIG. 8 are the browsing terminal 400 in this embodiment, and the electrophoretic display unit 4 in FIG. 1 is the electrophoretic display unit 104 as in FIG. Key 8 is key 108, upper key 81 is upper key 181, lower key 82 is lower key 182, left key 83 is left key 183, and right key 84 is right key 184. Further, the processing according to the key executed in the flowchart of the main operation shown in FIG. 18 is cited from the flowchart of FIG. 7 used in the first embodiment, and the display processing is the second implementation. Reference is made to the flowchart of FIG.

  Next, the operation of the browsing terminal 100 will be described with reference to FIGS. 7, 10, 18 and 19. This operation is started in the CPU 102 when power is supplied from the system power supply when a battery is connected to the viewing terminal 100. First, the RAM power switch 121 is turned on and the RAM power supply 131 is connected (S402). Then, “1” is stored as an initial value in the currently displayed document ID storage area 1111 and “1” is stored in the displayed page number storage area 1112 of the always-on RAM 111 (S403). In S405 and S406, it is necessary to activate the electrophoretic display unit 104 in order to display “white” on the electrophoretic display unit 104. Therefore, the display unit power switch 120 is turned on, and the display unit power supply 130 is connected (S404). Then, the previous display data storage area 1041 and the current display data storage area 1042 provided in the electrophoretic display unit 104 are all set to “white” (S405). Then, the display control unit 103 is instructed to set all the small compartment cells of the electrophoretic display unit 104 to “white” (S406). Here, the value of the no-input time counter is initialized to “0”. This no-input time counter is a timer counter for measuring a time during which no input to the key 108 is performed, and is counted up based on a signal from a timing means (not shown) connected to the CPU 102.

  Then, display processing is performed (see S407, FIG. 10). As shown in FIG. 10, in the display process, the page number (1) data stored in the displayed page number storage area 1112 of the document with ID (1) stored in the displayed document ID storage area 1111 is stored. The data is read from the memory card 106, and the coordinate information is expanded in the page data expansion area 1101 (S121). Then, the contents of the current display data storage area 1042 are copied to the previous display data storage area 1041 (S122), pixel information is created based on the coordinate information stored in the page data development area 1101, and the current display data storage is stored. It is stored in the area 1042 (S123). Then, an image of pixel information currently stored in the display data storage area 1042 is displayed on the electrophoretic display unit 104 (S124). Specifically, the pixel information stored in the current display data storage area 1042 and the pixel information stored in the previous display data storage area 1041 are compared, and the pixels of the current display data storage area 1042 are only for different small-partition cells. A control instruction based on the information is given to the display control unit 103. Then, the process returns to the main operation.

  Then, it is determined whether or not an input from the key 108 has been performed (S409). If input from the key 108 has been performed (S409: YES), processing corresponding to the key is performed (S418, see FIG. 7). Since the process corresponding to the key is the same as that of the first embodiment, the description thereof is omitted. However, in the second embodiment, the display document ID storage area 1111 and the displayed page number storage area 1112 are provided in the always-on RAM 111. Then, after returning to the main operation, the information on the number of pages stored in the displayed page number storage area 1112 of the document having the ID stored in the displayed document ID storage area 1111 in the display process is electrophoretically displayed. Displayed on the unit 104 (see S407, FIG. 10).

  If the input from the key 108 is not accepted in the main operation (S409: NO), it is determined whether or not the cursor is displayed on the electrophoretic display unit 104 (S410). As to whether or not the information is information for displaying a cursor, when the coordinate information is stored in the page data development area 1101 in S121 of the display process shown in FIG. Is set. In the embodiment after this subject, the cursor is displayed when “1” is stored in the cursor flag and turned on, and the cursor is displayed when “0” is stored and turned off. It is assumed that it is not displayed.

  When the cursor flag is on and the cursor is displayed (S409: YES), a cursor blinking process is performed (S410). In this cursor blinking process, the display of the cursor display position is switched between “white” and “black” every second. For this purpose, a switching counter, which is a timer counter for switching, and a black and white flag indicating whether the currently displayed cursor is white or black are provided. This switching counter is counted up based on a signal from a timing means (not shown) connected to the CPU 102. The black and white flag indicates “black” when “1” is stored, and “white” when “0” is stored. The initial value is “0” and white is displayed. In the cursor blinking process, it is determined whether or not 1 second has elapsed by this switching counter. If it has elapsed, the value of the monochrome flag is “1” if it is “0”, and “1” if it is “1”. For example, the display is switched to “0” and the display is updated based on the value of the black and white flag. Then, the value of the switching counter is cleared. If 1 second has not elapsed, no special processing is performed.

  Next, a determination is made as to whether or not the key input has not been performed for a predetermined time (5 seconds) or not based on whether or not the value of the no-input time counter is equal to or longer than the predetermined time (5 seconds) (S411). If the no-input time counter is not greater than or equal to the predetermined time (5 seconds) (S411: NO), it is not determined that there has been no input for longer than the predetermined time (5 seconds), and the process returns to S408 and the input from the key 108 is determined. . In this manner, the processing of S408 to S411 is repeatedly performed, and when the time when there is no input from the key 108 is equal to or longer than the predetermined time (5 seconds) (S411: YES), the processing without key input is performed (S412, (See FIG. 19).

  In the no key input process, as shown in FIG. 19, it is first determined whether or not the cursor is displayed (S421). If the cursor flag is off and the cursor display is not performed (S421: YES), the RAM power switch 121 is turned off and the RAM power supply 131 is cut off, and the display unit power switch 120 is turned off. Thus, the display unit power supply 130 is cut off (S422). Then, it is determined whether or not an input from the key 108 is detected (S423). If no key input is detected (S423: NO), the process waits until there is an input from the key 108 (S423: NO, S423). When an input from the key 108 is detected (S423: YES), the RAM power switch 121 is first turned on and the RAM power supply 131 is connected (S424). Then, the RAM 110 in which the page data development area 1101 and other storage areas 1102 are provided rises and is stored in the displayed page number storage area 1112 of the document with the ID stored in the displayed document ID storage area 1111. The data of the number of existing pages is read from the memory card 106, and the coordinate information is expanded in the page data expansion area 1101 (S425). Then, the display unit power switch 120 is turned on, and the display unit power supply 130 is connected (S426). Then, pixel information is created based on the coordinate information stored in the page data development area 1003 and stored in the current display data storage area 1002 (S427). Then, the process returns to the main operation.

  If the cursor is displayed (S421: NO), first, the RAM power switch 121 is turned off to disconnect from the RAM power 131 (S432). When the cursor is displayed, the electrophoretic display unit 104 is not disconnected because it needs to be connected to the display unit power supply 130. Then, it is determined whether or not an input from the key 108 is detected (S33). If no key input is detected (S433: NO), a cursor blinking process is performed (S434), the process returns to S433, and the input from the key 108 is waited (S433: NO, S434). The cursor blinking process here is the same as the cursor blinking process of S410.

  When an input from the key 108 is detected (S433: YES), the RAM power switch 121 is first turned on and the RAM power supply 131 is connected (S434). Then, the RAM 110 in which the page data development area 1101 and other storage areas 1102 are provided rises and is stored in the displayed page number storage area 1112 of the document with the ID stored in the displayed document ID storage area 1111. The data of the number of existing pages is read from the memory card 106, and the coordinate information is expanded in the page data expansion area 1101 (S435). Here, since the display unit power switch 120 remains on, there is no need to control the display unit power switch 120. Then, pixel information is created based on the coordinate information stored in the page data development area 1003 and stored in the current display data storage area 1002 (S437). Then, the process returns to the main operation.

  Then, processing corresponding to the input of the key 108 detected in S438 is performed (S437, see FIG. 4), and the process returns to S406, and the page of the document designated by the input of the key 108 is displayed on the electrophoretic display unit 104. It is displayed (S406, display process).

  The processing as described above is repeatedly performed, and the RAM power source 131 and the display unit power source 130 are turned off when not necessary, so that power saving can be achieved. Furthermore, since information on which page of which document is displayed when power is supplied again is stored in the always-on RAM 111 to which power is supplied from the system power supply, The next document, previous document, next page, and previous page can be displayed on the data displayed on the electrophoretic display unit 4. Further, even if simple display switching such as cursor display is performed, the RAM power supply 131 is disconnected, so that power saving can be achieved.

  Note that the CPU 102 that performs the process of S112 of the main operation shown in FIG. 9 of the fifth embodiment corresponds to the “display power cut-off control unit”, and the CPU 102 that performs the process of S116 corresponds to the “display power connection control unit”. Applicable. The electrophoretic display unit 104 corresponds to “nonvolatile display means”, the RAM 110 corresponds to “storage means”, the key 108 corresponds to “input means”, and the no-input time counter corresponds to “non-input time measurement means”. It corresponds to. The page data development area 1101 of the RAM 110 corresponds to “coordinate information storage means”, the current display data storage area 1042 provided in the electrophoretic display unit 104 corresponds to “pixel information storage means”, and the always-on RAM 111 The displayed document ID storage area 1111 and the displayed page number storage area 1112 provided in FIG. The RAM power 131 corresponds to the “storage power”, the RAM power switch 121 corresponds to the “storage power switching means”, the display power 130 corresponds to the “display power”, and the display power switch 120 corresponds to the “display power”. Corresponding to “power supply switching means”, connecting the constantly operating RAM 111 to the system power supply corresponds to “maintaining means”.

  The CPU 102 that executes the process of S111 of the main operation shown in FIG. 9 corresponds to “non-input time determination means”, and the CPU 102 performs the process of S121 of the display process shown in FIG. 10 and the process of S115 of the main operation shown in FIG. Corresponds to “coordinate information conversion means”, and the CPU 102 that performs the processing of S123 of the display process shown in FIG. 10 and S117 of the main operation shown in FIG. 9 corresponds to “pixel information conversion means”, and the main operation shown in FIG. The CPU 102 that performs the processes S22, S24, S26, and S28 corresponding to the keys shown in FIG. 7 corresponds to the “display control unit”. The CPU 102 that performs the process of S410 of the main operation shown in FIG. 18 and the process of S43 of the no key input process shown in FIG. 19 corresponds to “partial display content changing means”, and the process of S112 of the main operation shown in FIG. The CPU 102 that performs the processing corresponds to “storage power supply cut-off control means”, and the CPU 102 that performs the process of S114 corresponds to “storage power supply connection control means”. The previous display data storage area 1041 corresponds to the “previous pixel information storage unit”, and the CPU 102 that performs the processing of S7 of the display process illustrated in FIG. 10 corresponds to the “pixel information transfer unit”.

  It should be noted that the browsing terminal and browsing terminal program of the present invention are not limited to the above-described embodiments, and it goes without saying that various changes can be made without departing from the scope of the present invention. In the first to fifth embodiments, four types of keys, the up key, the down key, the right key, and the left key, can be obtained. Although a page display instruction and a next page display instruction are given, other keys may be provided to perform other processes.

  In the first to fifth embodiments, the electrophoretic display unit 4 is used as the non-volatile display means. However, the display contents are not limited to the electrophoretic method and can be maintained even when power is not supplied. Any non-volatile display unit may be used. For example, a display unit of another type such as a magnetophoretic method or a cholesteric liquid crystal method may be used. Further, the electrophoretic display portion may be configured using microcapsules.

  The browsing terminal and browsing terminal program of the present invention can be applied to a display device including an electrophoretic display unit.

1 is an external view of a browsing terminal 1. FIG. 3 is a block diagram showing an electrical configuration of the browsing terminal 1. FIG. 3 is a front view of an electrophoretic display unit 4. FIG. FIG. 6 is a cross-sectional view in the direction of the arrows along the line AA ′ (FIG. 2) of the electrophoretic display unit 4. It is arrow sectional drawing in the BB 'line (FIG. 2) of the electrophoretic display part 4. FIG. 4 is a flowchart showing a main operation of the browsing terminal 1. It is a flowchart of the process according to the key implemented in main operation | movement. 2 is a block diagram showing an electrical configuration of a browsing terminal 100. FIG. 3 is a flowchart showing a main operation of the browsing terminal 100. It is a flowchart of the display process implemented in main operation | movement. 3 is a block diagram showing an electrical configuration of a browsing terminal 200. FIG. 5 is a flowchart showing a main operation of the browsing terminal 200. It is a flowchart of the process without key input performed in the main operation. 3 is a block diagram showing an electrical configuration of a browsing terminal 300. FIG. It is a circuit diagram which shows the insertion detection sensor 322 and the extraction detection sensor 323. 5 is a flowchart showing a main operation of the browsing terminal 300. It is a flowchart of the pre-processing implemented in main operation | movement. 5 is a flowchart showing a main operation of the browsing terminal 400. It is a flowchart of the process without key input performed in the main operation.

Explanation of symbols

1 Reading terminal 2 CPU
3 Display control unit 4 Electrophoresis display unit 11 EEPROM
12 RAM power control unit 13 battery insertion sensor 20 system power switch 30 system power supply 100 browsing terminal 102 CPU
103 Display Control Unit 104 Electrophoresis Display Unit 110 RAM
111 Always-on RAM
120 Display Unit Power Switch 121 RAM Power Switch 130 Display Unit Power Supply 131 RAM Power Supply 200 Browsing Terminal 202 CPU
203 Display control unit 204 Electrophoresis display unit 210 RAM
211 Always-on RAM
220 Display Power Switch 221 RAM Power Switch 230 Display Power 231 RAM Power 300 Viewing Terminal 302 CPU
303 Display Control Unit 311 Normal Operation RAM
320 Display unit power switch 321 RAM power switch 322 Insertion sensor 322 Insertion detection sensor 323 Extraction sensor 323 Extraction detection sensor 323 Detection sensor 330 Display unit power supply 331 RAM power supply 332 Unconnected monitoring power supply 333 Connection monitoring power supply 341 Unconnected monitoring power switch 341 342 Insertion detection switch 351 Connection monitoring switch 352 Extraction detection switch 400 Viewing terminal 704 Electrophoresis display unit 1001 Previous display data storage area 1002 Current display data storage area 1003 Page data development area 1041 Previous display data storage area 1042 Current display data storage area 1101 Page data expansion area 1108 Displayed document ID storage area 1109 Displayed page number storage area 1111 Displayed document ID storage area 1112 Displayed page number storage Rear 1201 Page data development area 2101 Previous display data storage area 2102 Current display data storage area 2103 Page data development area 2111 Displayed document ID storage area 2112 Displayed page number storage area 3041 Previous display data storage area 3042 Current display data storage area 3101 Page data development area 3111 Displayed document ID storage area 3112 Displayed page number storage area

Claims (10)

A viewing terminal that displays information,
Non-volatile display means for displaying information and displaying contents not being erased even when the power is turned off;
An input means for inputting an instruction to the document browsing terminal;
First power source switching means for switching between connection and disconnection of the power source to the viewing terminal;
A non-input time measuring means for measuring a time during which no input is made by the input means;
A non-input time judging means for judging whether or not the non-input time measured by the non-input time measuring means has become a predetermined time or more;
A first power-off control means for disconnecting from a power source by the power source switching means when the non-input time is a predetermined time or more by the non-input time judging means;
A first power supply connection control means for connecting a power supply by the power supply switching means when an input is made by the input means after the power supply is cut by the power supply cutoff control means;
A display state information that is information indicating a document area displayed on the nonvolatile display means, and a nonvolatile first display state information storage means that does not erase the stored contents even when the power is turned off. A viewing terminal characterized by A viewing terminal that displays information,
Non-volatile display means for displaying information and displaying contents not being erased even when the power is turned off;
Storage means for storing information;
An input means for inputting an instruction to the document browsing terminal;
A non-input time measuring means for measuring a time during which no input is made by the input means;
A non-input time judging means for judging whether or not the non-input time measured by the non-input time measuring means has become a predetermined time or more;
Coordinate information converting means for converting the information into coordinate information for displaying on the nonvolatile display means;
Coordinate information storage means for storing the coordinate information converted by the coordinate information conversion means;
Pixel information conversion means for converting the coordinate information stored in the coordinate information storage means into pixel information for display on the nonvolatile display means;
Pixel information storage means for storing pixel information converted by the pixel information conversion means;
Display control means for displaying the pixel information stored in the pixel information storage means on the nonvolatile display means;
Second display state information storage means for storing display state information which is information indicating a document area displayed on the nonvolatile display means;
A storage power supply that is a power supply connected to the storage means;
Storage power switching means for switching connection and disconnection of the storage power to the storage means;
A storage power cut-off control means for disconnecting the storage means from the storage power supply by the storage power supply switching means when the non-input time becomes a predetermined time or more by the non-input time determination means;
A storage power supply connection for connecting the storage power supply to the storage means by the storage power supply switching means when an input is made by the input means after the storage power supply is disconnected from the storage means by the storage power supply cut-off control means Control means;
Maintenance means for maintaining storage of the display state information by the second display state information storage means regardless of whether the storage means is connected to or disconnected from the storage power source;
A browsing terminal, wherein the storage means is provided with at least the coordinate information storage means. The pixel information storage means is provided in the nonvolatile display means,
A display power source that is a power source connected to the nonvolatile display means;
Display power supply switching means for switching connection and disconnection of the display power supply to the nonvolatile display means;
When the non-input time is determined by the non-input time determination means to be a predetermined time or more, display power-off control means for disconnecting the non-volatile display means from the display power by the display power switching means;
After the display power source is disconnected from the non-volatile display unit by the display cutting control unit, input by the input unit is performed, and the coordinate information converted by the coordinate information conversion unit is stored in the coordinate information storage unit. The browsing terminal according to claim 2, further comprising first display power connection control means for connecting the display power to the non-volatile display means by the display power switching means.   When only a part of the contents displayed on the nonvolatile display means is rewritten, the pixel information storage is performed without using the coordinate information conversion means, the coordinate information storage means, and the pixel information conversion means. 4. The browsing terminal according to claim 2, further comprising a display content partial changing means for changing the display content of the nonvolatile display means by changing the pixel information stored in the means. . The pixel information storage means is provided in the storage means,
A display power source that is a power source connected to the nonvolatile display means;
Display power supply switching means for switching connection and disconnection of the display power supply to the nonvolatile display means;
A second display power supply connection control means for connecting the display power supply of the nonvolatile display means by the display power supply switching means only when the pixel information is displayed on the nonvolatile display means by the display control means. The browsing terminal according to claim 2 characterized by things. Previous pixel information storage means for storing the same pixel information as the pixel information stored in the pixel information storage means;
Before the pixel information is converted by the pixel information conversion means and stored in the pixel information storage means, the pixel information stored in the pixel information storage means is stored as previous pixel information in the previous pixel information storage means. Pixel information transfer means for
The display control means includes
The pixel information stored in the pixel information storage means is compared with the previous pixel information stored in the previous pixel information storage means, and the display of the pixel information is based on the difference from the previous pixel information. Control is performed, The browsing terminal in any one of Claim 2 thru | or 5 characterized by the above-mentioned. Storage medium connection means for connecting a removable storage medium for storing information; and
Storage medium connection detection means for detecting that the storage medium is connected to the storage medium connection means;
Storage medium disconnection detection means for detecting that the storage medium has been disconnected from the storage medium connection means;
The storage medium connection detection unit detects the storage medium connection while the storage medium connection detection unit detects that the storage medium is disconnected, and after the storage medium disconnection detection unit detects that the storage medium is disconnected. The first power-off control unit and the first power-supply connection control unit, or the storage power-off control unit and the storage power connection control unit are not allowed to function until it is detected that the medium is connected. The browsing terminal according to claim 1, further comprising a power-off control unit. Storage medium connection means for connecting a removable storage medium for storing information; and
Storage medium connection detection means for detecting that the storage medium is connected to the storage medium connection means;
Storage medium disconnection detection means for detecting that the storage medium has been disconnected from the storage medium connection means,
The storage medium connection detecting means is
An insertion detection switch that is turned on when the storage medium is installed at a position where the storage medium connecting means can connect the storage medium;
A control means for controlling the browsing terminal and an unconnected monitoring switch connected to the insertion detection switch,
The storage medium disconnection detecting means is
A sampling detection switch that is turned on when the storage medium is not in a position where the storage medium connecting means can connect the storage medium;
A control means for controlling the browsing terminal and a monitoring switch at connection connected to the sampling insertion detection switch,
When the insertion detection switch is turned on, the unconnected monitoring switch is turned off, when the connection monitoring switch is turned on, and when the extraction detection switch is turned on, the unconnected monitoring is performed. The browsing terminal according to any one of claims 1 to 7, further comprising detection control means for turning on the switch and turning off the connection monitoring switch.   The display status information includes data file identification information for identifying the information displayed on the nonvolatile display means from other information, and a display start indicating the current display position in the information displayed on the nonvolatile display means The browsing terminal according to claim 1, further comprising information.   The browsing terminal program for functioning a computer as various processing means of the browsing terminal in any one of Claims 1 thru | or 9.

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