DE69021651T2 - Information display system, suitable for compact electronic devices with various display formats. - Google Patents

Description

The present invention relates generally to a display system for a compact electronic device. More particularly, the present invention is directed to an information display system used with such compact electronic devices equipped with display units having different display sizes and capable of correctly displaying display information received from the same display information source.

In general, conventional compact electronic devices for displaying characters use dot matrix type liquid crystal display devices as display units. The data to be displayed, such as character codes, is converted into image data or bit patterns, and the converted display data is stored in the screen memory corresponding to the dots constituting the liquid crystal display panel, and then the display operation is performed according to the contents of this screen memory.

On the other hand, since consumers have expressed a desire for more viewable display screens, the sizes of existing display screens are modified to increase them without changing the basic functions of the display system. In such a case, although the arithmetic and memory control remain unchanged, either the control unit or the large-scale integrated devices used in the electronic device must be discretely prepared to accommodate the changes in the display device. Therefore, there is a problem affecting the cost that the structure of the large-scale integrated devices used in the display device must be changed to accommodate such a slight change in the size of the display screen.

Furthermore, an information processing device which can execute a program already stored in an external storage medium such as an IC card while connecting the IC card to this information processing device has recently been offered on the market.

According to such an information processing apparatus, when the program stored in the IC card, e.g., an information display program, is executed, the display data is received from the IC card together with the information on the number of rows and the number of columns for the purpose of display, and the display data is displayed only at the specified position of the display unit.

However, there are various information processing devices of the same line but of different types. For example, if a program for displaying data of a display unit of 3 lines x 5 columns is stored in an IC card, the entire screen of this display unit can be effectively used to display this display data only if the screen size of the display unit is 3 lines x 5 columns. In contrast, if other different types of display units, for example, a screen size of 4 lines x 10 columns instead of the screen size of 3 lines x 5 columns described above, and the IC card described above are used, the display data is displayed only in a display area of 3 lines x 5 columns. This may result in insufficient display of the effective display area of the display unit and in poorer displayed appearance of the display data.

A similar problem concerns the correct setting of the display format and size, CGA or EGA, of display devices, depending on the application program being executed. A display system that automatically, manually or semi-automatically adjusts to the required display format, CGA or EGA, is known from EP-A-0295691. However, this document does not provide any information on how to display display characters stored in a memory device in correspondence with arbitrary screen sizes so that the display data is satisfactorily displayed within the effective display area of the display system.

The present invention has been made in an effort to overcome the above-described problems of conventional information display devices, and its object is to provide an information display system capable of correctly displaying information even when the compact electronic devices use a display unit having different specifications.

An information processing system according to the present invention comprises a portable electronic device and a storage device. The portable electronic device comprises a display device having a display screen capable of displaying a plurality of lines and also a plurality of characters thereon, a display storage device having a storage capacity corresponding to a size of the display screen for storing display data to be displayed on the display screen, a setting device for setting the position of the display storage device into which data is written; and a storage device for storing information on the size of the display screen. The storage includes: a storage device for storing character information to be displayed on the display screen; a device for sequentially transferring the character information from the storage device of the memory to the portable electronic device, and a writing position control device for sequentially updating the writing position of the display storage device which is set by the setting device. The portable electronic device further comprises: a writing device for writing each character information from the storage devices to the location of the display storage device which is designated by the designating device; and detecting means for detecting that the writing position updated by the writing position controlling means exceeds a storage area corresponding to the display screen. The memory further comprises: controlling means for controlling the operation of the designating means and the writing means according to the detection result of the detecting means.

The present invention will now be described in more detail by way of example and with reference to the accompanying drawings, in which:

Fig. 1 shows a perspective view of a compact electronic device to which the present invention has been applied;

Fig. 2 is a schematic block diagram showing a circuit configuration of the compact electronic device to which the present invention has been applied;

Fig. 3 shows the contents of a display form storage unit used in the compact electronic device shown in Fig. 1;

Fig. 4 shows display information stored in a memory of an IC card;

Fig. 5 is a flowchart for explaining a main display operation of the compact electronic device;

Fig. 6 is a start-up diagram for explaining an operation executed by a program stored in the IC card;

Fig. 7 is a flow chart for explaining an operation of various circuits of the compact electronic device during the display operation;

Figs. 8 to 11 show different display states of the display unit.

STRUCTURE OF THE COMPACT ELECTRONIC DEVICE

Referring now to the figures, a compact electronic device in which an information display system according to a first preferred embodiment of the present invention is used will be described.

Fig. 1 is a perspective view of the first compact electronic device. In Fig. 1, reference numeral 1 denotes a device housing consisting of a main body 1a and a cover 1b hingedly attached thereto. On the surface of this main body 1a, a keyboard 2, a power ON switch 3a and a power OFF switch 3b are formed, and a card loading unit 5 is formed on a side surface of the main body 1a (on the right side in the view of Fig. 1), into which an IC (integrated circuit) card 4 is loaded. On an inner surface of the cover 1b, there are provided in the form of a panel a map (CAD) key 7 for setting a map mode, a TEL key 8 for setting a telephone mode, a MEM key 9 for setting a memo mode, a Sch key 10 for setting a schedule mode, and a TIM key 11 for setting a time mode, and a liquid crystal display panel 12 for displaying various data thereon. Furthermore, cursor keys 13 composed of four switch pieces are provided beside the various function setting keys. An "I" key 13a and an "O" key 13b indicate the direction of scrolling the display in the map mode.

OVERALL CIRCUIT ARRANGEMENT

Fig. 2 shows the overall circuit arrangement of the compact electronic device shown in Fig. 1. This circuit is made up of a central processing unit (CPU) 14, to which a key input unit 15, a ROM (read only memory) 16, a RAM (random access memory) 17, a display control unit 18, a read control unit 19 and a housing connector 20 are connected.

It should be noted that the key input unit 15 described above corresponds to the keyboard 2, cursor key 13 and various keys 7 to 11 already explained. A program for controlling various functions of the device and a conversion table for converting a character code into a character pattern are prestored in the ROM 16. In the RAM 17, there are provided areas capable of storing various data, a display head line pointer (n) 171, a display line pointer (in) 172 and a character pointer (p) 173; the RAM 17 further comprises the area T(1), T(2), ..., 172 for buffering character pointer data of the head character of each line; and a display character code register (CHR) 175. The data stored in the RAM 17 is used to control the displays of various data transmitted from the IC card 4.

The compact electronic device shown in Fig. 1 further comprises a display unit 21. The display unit 21 consists of an LCD panel 12, an LCD driver 211 for driving the LCD panel 12, a VRAM 212 and a display form memory 213. The VRAM 212 stores image data for display on the LCD panel 12.

The function of the display form storage unit 213 is to store a form or specifications of this display unit 21. In Fig. 3, the contents of the memory of various Display types, ie A type and B type, are shown. The data of the character to be displayed and the address data are different depending on the size of the display field 12.

The display control unit 18 includes a storage unit 183. A top address of the VRAM, an end address of the VRAM, and a dot number in the vertical direction of the LCD panel 12 are written into the memory areas A, B, and C of the display form storage unit 213. Based on the written data, the display control unit 18 executes both the data writing control and the display control with respect to the display unit 21. Furthermore, under the control of the display control unit 18, both the digit designation value (XI) and the line designation value (YI) used for writing the character data into the VRAM 212 are stored in a digit position memory 181 and a line position memory 182, respectively. These digit designation value (XI) and line designation value (YI) are transmitted to the read control unit 19.

The reading control unit 19 has a memory 191 for storing a digit number value (Xc) of the display unit 21 and a memory 192 for storing a line number value (Yc), and further comparator units 193, 194 and error flag memories (EX) 195 and (EY) 196.

Then, the position setting value (XI) and the line setting value (YI) are transmitted to the comparator units 193 and 194. The first comparator unit 193 compares the position number value (Xc) stored in the memory 191 with the position setting value (XI) stored in the position position memory 181. If a comparison result shows that XI>Xc, a flag is stored in an error flag memory (EX) 195. The second comparator unit 194 compares the line number value (Yc) stored in the memory 192 with the line setting value stored in the line position memory 182. (YI). If the comparison results in YI> Yc, another flag is set in another error flag memory (EY) 196.

The IC card 4 in turn consists of a ROM 31 and a card connector 32. Note that, for example, display information as shown in Fig. 4 is stored in the ROM 31, and a program by which such display information can be displayed is also pre-stored therein. The card connector 32 is used to connect the IC card 4 to the housing 1 via the housing connector 20.

It should also be noted that a symbol shown in Fig. 4 indicates a line feed code.

OVERALL OPERATION OF THE COMPACT ELECTRONIC DEVICE

Referring to Figs. 1 to 4 in conjunction with a flow chart shown in Fig. 5, it will now be described how, when the IC card 4 is loaded in the casing 1, the information stored in the IC card 4 (see Fig. 4) is displayed on the display panel 12 of the compact electronic device. In this preferred embodiment, it is to be noted that the display unit 21 uses a type "A" display form as shown in Fig. 3. In this display unit 21, a 48X64 dot matrix is used as the LCD ("liquid crystal display") panel 12. One character is made up of a pattern of 16x8 dots and a character display is produced by 3 rows x 8 columns. Accordingly, VRAM 212 has a storage capacity of 48 x 64 bits. In this VRAM 212, a top address "0000" defines a region of VRAM 212 corresponding to the first 8 bits of a first row and a first column of the display field, and an end address "017F" (hexadecimal notation) defines a region of VRAM 212 corresponding to the sixteenth 8 bits of a third row and an eighth column of the display field.

The display is shown in accordance with the flow chart in Fig. 5.

In a step S1 of this flow chart, the top VRAM address "0000", the VRRM end address (017F) and the dot number "48" in the vertical direction of the LCD panel 12 are read out from the display form memory 213 of the display unit 21 and then stored in corresponding storage areas of the memory 183 in the display control unit 18. Then, the display digit number "8" and the display line number "3" are read out from the display form memory 213 and then stored in the memory 191 and the memory 192 of the reading control unit 19, respectively, in a step S2.

Then, the display process proceeds to a next step S3, the LCD panel 12 is operated under the control of the CPU 14 in a duty ratio I/C, the duty ratio being 1/48 in this preferred embodiment. As will be described in detail, the display information is read out from the IC card 4 in a step S4 and displayed in a subsequent step S5.

The display information reading operations defined in step S4 will now be explained in detail with reference to the flow charts shown in Figs. 6 and 7.

Fig. 6 is a flow chart showing such a program by which the display information shown in Fig. 4 on the IC card per se is transmitted to the body 1. Fig. 7 is another flow chart for explaining a process for performing the display operations on the device body 1.

PROGRAM FOR TRANSMITTING DISPLAY INFORMATION

In the flow chart shown in Fig. 6, a "1" is entered in the display start line pointer (n) 171 used in the RAM 17. is set in the display start line pointer (n) 171 and in the character pointer (p) 173 thereof to initialize this transfer program in a step A1. The display start line pointer (n) indicates the line number of which the information or characters are displayed on the first line of the display panel 12 when the current display of the entire information occupies several lines. The character point (p) indicates a position of the corresponding character data shown in Fig. 4. Then, the display data transfer process proceeds to a step A2, the value "n" of the display start line pointer (n) 171, that is, "1" in this stage, is written in the display line pointer (m) 172 and further, "1" is written in the line position memory 182 for storing the line designation value (YI) so that a first line of the display unit 21 is designated. Next, this process proceeds to step A3, the value "p" of the character pointer (p) 173, i.e., "1" in this case, is written into the head character position buffer T(1). This implies that the buffer T(1) stores such that the head character of the first line corresponds to the "N" of the character string "NUMBER". Further, "1" is written into the digit position memory 181 for storing the digit designation value (XI) thereby designating the first digit of the first column. Then, the process proceeds to a step A4 at which a decision is made as to whether or not the character corresponding to the character pointer (p) 173 is equal to the line feed code. In this case, since the first character of the display character data shown in Fig. 4 corresponds to "N" and not the line feed code, the decision result becomes "NO" and the process proceeds to a next step AS.

In this step AS, the p-th character code is written into the display character code register (CHR) 175 used in the RAM 17. Thereafter, the process proceeds to a step A6. In this step A6, a display BIOS program shown in Fig. 7 prestored in the ROM 16 of the device body 1 is executed.

DISPLAY BIOS PROGRAM

In a flow chart shown in Fig. 7, in a step B1, both the error flag memory (EX) 195 and the error flag memory (EY) 196 are reset to "0".

Next, the program proceeds to a step B2 where a check is made as to whether the digit setting value (XI) of the memory 181 is greater than the display digit number value (Xc). At this stage, the display process proceeds to a step B3 since XI=1 and Xc=8 and therefore the decision result is NO. In this step B3, a further decision is made as to whether the line setting value (YI) of the memory 182 exceeds the display line number value (Yc). At this stage, since YI=1 and Yc=3 and therefore the decision result is NO, the display process proceeds to a step B4. At this step B4, the dot pattern of the character "N" written in the display character code register (CHR) 175 is accordingly written in the storage area of VRAM 212 corresponding to a first digit position in a first line of the display panel 12 as shown in Fig. 8. Then, this display process returns to the flow chart shown in Fig. 6 again. Assuming that a decision of either XI>Xc or YI>Yc is made in step B2 or B3, this suggests that the character to be displayed is written outside the display panel 12, so that an error flag is set in step B5 or B6 and then the process returns to the flow chart shown in Fig. 6.

In Fig. 6, the display process returns to a step A7. At step A7, a decision is made as to whether or not a "1" has been set in the error flag memory (EY) 196. In this case, since a "1" is not set and therefore the decision result becomes "NO", the process proceeds to a step A8. At step A8, a further check is made as to whether or not a "1" has been set in the error flag memory (EX) 195. Similarly, since a "1" has been set in this error flag memory (EX) 195 is not set and therefore the decision result is NO, the process also proceeds to another step A9.

In this step A9, the content of the digit position memory 181 for storing the digit setting value (XI) is incremented by 1 to set the next position in the X direction, and the character pointer (p) 173 is incremented by "1" to set the next character.

Then, the process returns to step A4. The processes defined in step A4 to step A9 are repeatedly executed for each character of the remaining characters "NUMBER". As a result, the dot pattern of "Number" is written into the VRAM 212, which corresponds to the first display line.

If the character pointer (p) 173 is at "7" and the line feed code is set, the decision result in step A4 becomes "YES" and the process proceeds to a step A10.

In this step A10, the character pointer (p) is incremented by "+1", namely, set to "8", and thus the process proceeds to a step All. In this step All, both the line designation value (YI) and the display line pointer (in) are set to "+1", respectively. As a result, the character writing operation goes to the second display line of the display panel 12. Then, the process returns to step A3.

In this step A3, the value "p" of the character pointer (p) 173, namely "8" at this stage, is written into the head character position buffer T(2), and such a memory content in which the head character located on the second line corresponds to "0" is stored. Also, "1" is written into the position position memory 181 for storing the position setting value (XI) to set the first position of the display field. As described above, the various operations defined after step A4 are carried out.

When steps A4 to A9 are repeatedly performed and "01234567" is written in the second line of the display, "p" becomes 16 and the process returns to step A4. At this time, XI has become "9". Since a character "8" is designated by the character pointer (p=16), the character code of "8" is written in the CHR 175 in step AS. However, in step A6, i.e., step B2 of the flow chart shown in Fig. 7, a decision is made that XI=9>Xc=8 and "1" is set in the error flag memory (EX) 195. Since the decision result in step A8 becomes YES, the process proceeds to step A11. In this step A11, the line designation value (YI) of the memory 182 is incremented by "1" and thus the third line is designated. Furthermore, the content of the display line pointer (m) 172 is set to "+1", thereby writing "3". The process returns to step A3, in which the value "p" of the character pointer 173, namely "16", is written into the head character position buffer T(3) as character position information. As a result, it is stored that the head character in the third line corresponds to the character "8", and "1" is written into the position position memory 181 for storing the position designation value (XI) for designating the first position. Then, the process operations defined after step A4 are carried out accordingly.

After the processes defined in steps A4 to A9 are performed, the characters "8" and "9" are written in the third line. When the second line feed code is read from the character pointer 173 (p=18), the process proceeds to steps A4, A10 and A11 so that "YI" is equal to "4". As a result, the decision in step B3 of the flow chart shown in Fig. 7 is "YES" and the process then proceeds to step B6 where "1" is written into the error flag memory. (EY) 196 is set. Thus, in step A7, the decision result is "YES" and the process proceeds to a step A12. In this step A12, the character writing operation is stopped once, the content of VRAM 212 is displayed, and the key input is awaited. The display screen at this time is shown in Fig. 8.

SCROLLING OPERATION

Then, when the key input operation is performed by operating the key unit 15, decisions are made as to whether the "I" key 13a or the "O" key 13b of the cursor key 13 is operated in steps A13 or A14. Note that this state is maintained unless a key input is made via the key input unit 15. When the "O" key 13b is operated, a decision result becomes "YES" in step A14 and the process proceeds to a next step A15. In this step A15, the display start line pointer (n) 171 used in RAM 17 is incremented by "1" and thus "2" is written. Then the process proceeds to a step A16, the stored value "8" is read out from the head character position buffer T(2) and then set as the value "p" of the character pointer (p) 173.

Then, the process returns to the previous step A2. In this step A2, the value "n" of the display start line pointer (n) 171, namely "2" at this stage, is written into the display line pointer (in) 172, "1" is written into the line position memory 182 for storing the line designation value (YI) to designate the first line of the display.

Then, the processes defined in step A3 as well as the subsequent steps are carried out in a similar manner to the previous process operation. In other words, when the "O" key 13b is pressed, a screen relating to the data display after the second line is redisplayed. As a result, as shown in Fig. 9, a character "0" corresponding to "8" of the character pointer (p) 173 is displayed at the head position of the first line. Then, the character is displayed on the display panel 12 constructed of 3 rows x 8 columns based on the display character values shown in Fig. 4.

On the other hand, when the "I" key 13a is operated, the decision result in step A13 is "YES" and the process proceeds to a step A17. In this step A17, a check is made as to whether the content of the display header pointer (n) 171 of the RAM 17 corresponds to "1". If "n" is equal to "1" since no scrolling in the reverse direction is performed, the process returns to step A2 to form the same display.

If "n" is any number other than "1" and the decision result is "NO", the process proceeds to another step A18. In this step A18, the display header pointer (n) 171 used in the RAM 17 is decremented by 1. At this stage, assuming that the content of the display header pointer (n) becomes "2" by operating the "O" key, this content becomes "1" again and is then written into the display header pointer (n) 171. Then, the process proceeds to a step A16 in which the value "1" of the header character position buffer (1) is set to the value "p" of the character pointer (p) 173. In this state, the process returns to the previous step A2. A display screen can be formed by scrolling the characters in the reverse direction after step A2.

TYPE "B" DISPLAY OPERATION

Next, in case another display unit capable of displaying 4 rows x 16 columns, ie a display of type "B" (see Fig. 3), is used as the display panel 12 of the apparatus body 1, (Xc) is set to "16" and (Yc) is set to "4". As a result, when the information shown in Fig. 4 is displayed on this "B" type display unit, the various operations defined in the same flow charts as described above are carried out so that the characters "NUMBER", "0-9", "ALPHABET" and "AP" are written in the corresponding lines after being processed by the line feed codes and finally displayed in the manner shown in Fig. 10.

As a result of using this display system, even if the dimension of the display area for the display panel 12 is changed due to a change of some kind of the display unit 21 used in the equipment body 1, the characters from the IC card are written into the VRAM 212, while it is decided on the basis of the display column number (Xc) and the display line number (Yc) whether the display data exceeds the display area of the display panel 12, whereby the data display is performed by effectively using the entire screen (or its area) of the display panel 12. Therefore, the display area of the display unit can be effectively used, and compared with the conventional display system in which the data is displayed on only a part of the display unit when the display area is changed, even when the display area of the display panel is changed, a better appearance of the displayed data is achieved.

The present invention is not limited to the preferred embodiments described above, but modifications, substitutions and changes can be made thereto without departing from the technical scope of the present invention.

In the preferred embodiments described above, both the display column number (Xc) and the display line number (Yc) were fixed in accordance with the display area of the display panel 12. Alternatively, these display numbers (Xc) and (Yc) may be set as variable numbers in the case where, for example, a display other than the display information of the IC card such as a function display is created on the display screen. That is, when the function display is created as shown in Fig. 11, (Yc) is set to "2", whereas when the function display is erased, (Yc) is set to "3". Consequently, the display can be changed without performing a specific operation on the IC card 4. It is also possible to apply the display method of the present invention to any display unit having dimensions other than 3 lines x 8 columns and 4 lines x 16 columns.

Claims (1)

1. Information processing system with a portable electronic device (1) and a memory (4), characterized in that 1) the portable electronic device (1) contains: a display device (21) having a display screen (12) capable of displaying a plurality of lines and also a plurality of characters thereon ; a display storage device (212) having a storage capacity corresponding to a size of the display screen for storing display data to be displayed on the display screen, a setting device (181, 182) for setting the position in the display storage device (212) into which data is written; and a memory device (191; 192) for storing information about the size of the display screen; 2) wherein the memory (4) contains: a storage device (31) for storing character information to be displayed on the display screen; a device (31, 14) for sequentially transferring the character information from the storage device (31) of the memory (4) to the portable electronic device; and a writing position control device (31, 14) for sequentially updating the writing position of the display storage device (212) set by the setting device (181, 182); 3) wherein the portable electronic device (1) further comprises: a writing device (18) for writing each character information from the storage device to the location of the display storage device (212) specified by the specifying device (181, 182); and a detecting device (193, 194) for detecting that the writing position updated by the writing position control device (31, 14) exceeds a memory area corresponding to the display screen; and 4) the memory (4) further comprising: a control device (31, 14) for controlling the operation of the setting device and the writing device according to the detection result of the detecting device 2. An information processing system according to claim 1, characterized in that the display device (21) includes a dot matrix type liquid crystal display device. 3. Information processing system according to claim 2, characterized in that the memory (4) contains a memory card device with an IC memory chip provided therein, and the portable electronic device (1) is equipped with a memory card device charging unit (5). 4. Information processing system according to claim 1, characterized in that the display storage device has a storage area consisting of a plurality of rows and a plurality of columns for storing display character data ; the designating means comprises a column designating means (181) having a column counter for designating the column of the display storage means according to the count value of the column counter, and a row designating means (182) having a row counter for designating the row of the display storage means according to the count value of the row counter; wherein the writing position control device (31, 14) comprises means for updating the row and column counters of the row and column setting devices; wherein the writing device (18) comprises a device for writing data into the storage area of the display storage device which is defined by the counter values of the row and column counters; wherein the detecting means (193, 194) comprises means for detecting that the column count of the column counter exceeds the number of columns of the display storage device and that the row count of the row counter exceeds the number of rows of the display storage device; and wherein the control device (31, 14) comprises means for resetting the row counter and incrementing the column counter in response to detecting that the column count exceeds the number of columns, and means for interrupting the writing operation of the writing device (18) in response to detecting that the row count exceeds the number of rows.