JPH04223558A - Scheduler - Google Patents

Abstract

PURPOSE:To prevent a system from automatically starting without fail at some one of the data until the time set up to alarm more than one month ahead from the current time. CONSTITUTION:In an English language word processor equipped with a setting data memory for storing data of a plurality of times set up to alarm, and a clock element for outputting a start signal to start a system, wherein the scheduler, when one of the plurality of set up times comes, is made to display a predetermined alarm screen and at the same time reads out data of the nearest set up time from the setting data memory and stores part of the read data in the internal memory of the clock element, if the nearest set up time read out from the setting data memory in order to store the time in the internal memory is the time of more than one month ahead (S32, S33: Yes), in an alarm permissible bit installed in the clock element, '0' is stored (S36) to set the clock element at the inhibit state that inhibits a start signal from being output.

Description

[Detailed description of the invention]

0001

[Industrial Application Field] The present invention relates to a scheduler, and in particular, when the set date and time for alarm is one month or more ahead of the current time, the timer is set to a state in which the output of a start signal for starting the system is prohibited. About what has been made possible.

0002

[Prior Art] Conventionally, electronic notebooks and other schedulers for setting and monitoring schedules have clock elements that are always backed up by a lithium battery and output real-time time signals consisting of year, month, day, day of the week, and time. (real-time clock element), a schedule function that stores calendar information and a large number of schedule information in correspondence with the calendar, and an alarm function that activates an alarm at the desired date and time you set. has been done. Recently, European language word processors, Japanese word processors, and the like have been put into practical use with additional functions of this scheduler.

[0003] In these word processors equipped with this scheduler function, the schedule information input using the schedule information input screen displayed on the display is stored in the schedule information memory in the control device, and the schedule information that is set to be alarmed is stored in the schedule information memory in the control device. The date and time is stored in the setting data memory as the year, month, day, day of the week, and time. At this time, one set date and time in the future that is closest to the current time is stored in an internal memory provided in the timekeeping element. While using a word processor, if the current time matches any of the multiple set dates and times stored in the setting data memory, an alarm screen will appear on the display and a buzzer will alert you. . On the other hand, when the word processor is not in use and the current time and the set date and time stored in the clock element match, the word processor is automatically powered on by the activation signal output from the clock element and a buzzer etc. is activated. It is designed to warn you.

[0004] By the way, some of these timekeeping elements have their internal memory stored with the year, month, day, day of the week, and time as the set date and time for the alarm, or some of them are stored with the date, day of the week, and time. It has been put into practical use.

[0005]

[Problems to be Solved by the Invention] As mentioned above, when storing the date, day of the week, and time as the set date and time for alarm in the internal memory of the timekeeping element, for example, as of January of a certain year, March 20th If you set 2:00 p.m. on the 20th (Saturday) as the date and time to alarm, and the set date and time data for 2:00 p.m. on the 20th (Saturday) is stored in the internal memory, each day and weekday of February and March Since each date and day of the week are the same,
There is a problem in that the alarm date and time match 2:00 pm on Saturday, February 20th, and the word processor is automatically turned on by mistake at a different date and time than the set date and time.

[0006] An object of the present invention is to reliably prevent the system from erroneously starting up automatically at any date and time between the current time and a set date and time at which an alarm is to be issued, which is more than one month in the future. The purpose is to provide a scheduler.

[0007]

[Means for Solving the Problems] A scheduler according to the present invention includes an input means for inputting character and symbol data and various command signals, a calendar memory storing calendar information, and a plurality of input and set alarms. a storage means comprising a setting data memory for storing data of the year, month, day, day of the week, and time of the set date and time to be set, and a schedule information memory for storing input schedule information in association with calendar information; A display means having a display for displaying calendar information and schedule information, and a display means for counting clock signals from an oscillation element to output a real-time time signal including the year, month, day, day of the week, and time, and for displaying a set of set date and time. A clock means has an internal memory for storing day, day of the week, hour and minute data, and outputs a start signal to start the system when the set date and time matches the current time, and a time signal and a set data memory. A clock means for displaying a predetermined alarm screen on the display means when the current time reaches any set date and time based on the set time data, and reading out the set date and time data of the nearest future from the set data memory and measuring a part of it. In the scheduler, when the set date and time is a date and time that is one month or more ahead of the current time based on the time signal and the set date and time data of the nearest future, A startup prohibition setting means is provided for setting a prohibition state in which the output of a startup signal is prohibited.

[0008]

[Operation] In the scheduler according to the present invention, a predetermined alarm screen is displayed on the display means when the current time reaches one of the set dates and times stored in the setting data memory by the control device, and the set date and time data of the nearest future is displayed. is read from the setting data memory, and when the day, day of the week, hour, and minute data of the set date and time are stored in the internal memory of the timekeeping means, the activation prohibition setting means reads the setting of the time signal and the nearest future setting. When the set date and time is one month or more later than the current time based on the date and time data, the timekeeping means is set to be in a prohibited state in which output of the activation signal is prohibited. In other words, even if there is a set date and time that is known to be the same day, day of the week, and time as the set date and time between the current time and the set date and time at which the alarm should be set more than one month later, the same set date and time may be mistakenly set. You can reliably prevent the system from starting automatically.

[0009]

Effects of the Invention According to the scheduler of the present invention, a startup prohibition setting means is provided, and a set date and time consisting of a date, a day of the week, and an hour stored in the internal memory of the timekeeping means is one month older than the current time. If the date and time is in the future, the timer is set to be in a prohibited state that prohibits the output of the start signal, so that between the current time and the set date and time when the alarm is to be alarmed, on the same day and day of the week as the set date and time. Even if there is a set date and time that is known as the time, it is possible to reliably prevent the system from being automatically started by mistake at the same set date and time.

0010

Embodiments Hereinafter, embodiments of the present invention will be described with reference to the drawings. This embodiment is a case where the present invention is applied to an English word processor having a function as a scheduler. As shown in FIG. 2, a keyboard 3 is disposed at the front of the body frame 2 of the word processor 1, and a daisy-wheel type printing mechanism PM is disposed within the body frame 2 behind the keyboard 3. At the rear of the is a liquid crystal display 1 that can display 14 lines of characters and symbols.
0 is set.

[0011] The keyboard 3 has character keys including alphabet keys, numeric keys, and symbol keys, a space key, a return key, cursor movement keys for moving the cursor on the display 10 in up, down, left, and right directions, and input of schedule information. a schedule key to set an alarm to occur at a desired date and time, an alarm setting key to set an alarm to occur at a desired date and time, a next key to display a calendar one month ahead of the calendar currently displayed on the display 10, and a pre key to display a calendar one month in advance. keys, an end key for ending various editing functions, etc. are provided in the same way as normal ones. Printing mechanism PM
It has a general configuration including a platen, carriage, and daisy wheel.

Next, the control system of the word processor 1 is shown in FIG.
It is configured as shown in the block diagram. Display mechanism D
M is a display controller 11 that includes a liquid crystal display 10, a display RAM for outputting display data to the display 10, and a character generator ROM that stores a large number of dot patterns such as characters and symbols.
It has a general configuration. Incidentally, the symbol AM indicates the buzzer 12 and the drive circuit 1 that makes the buzzer 12 sound.
It is an alarm mechanism equipped with 3.

Peripheral equipment such as the display mechanism DM, printing mechanism PM, and keyboard 3, and the CPUs 16 and R of the control device C
Each element such as OM17 and RAM20 is connected to a transistor T.
Drive voltage V from a power supply (not shown) supplied via R
It is driven by c. Also, a text memory 22 consisting of volatile memory, a schedule information memory 23, and a setting data memory 2
4 and the date stored in the memory 25 are stored and held by the drive voltage from the power supply supplied through the switch SW1 during the ON period of the power switch MS, and are stored and held by the drive voltage from the power supply supplied through the switch SW1 during the OFF period of the power switch MS. switch SW
The data is always stored and retained by a drive voltage of approximately 3V supplied from the lithium battery E via the lithium battery E via the memory. In addition, the power switch MS
In conjunction with the ON or OFF of the switch SW1, the switch SW1 is switched ON or OFF, and the switch SW2 is switched OFF or ON. Figure 3 shows how to turn on the power switch MS.
The switching states of switches SW1 and SW2 during the period are shown.

The comparator 19 compares the drive voltage of the lithium battery E with a set voltage value (for example, about 2.6V), and when the drive voltage of the lithium battery E is higher than the set voltage value, the comparator 19 outputs an "L" level. It outputs the weak voltage signal e of "H" level to the input/output interface 14 when the weak voltage is lower than the set voltage value.

The control device C includes a CPU 16, an input/output interface 14 connected to the CPU 16 via a bus 15 such as a data bus, a ROM 17, and a RAM 20, and a clock element (real time clock element) 18 that outputs a time signal. It is composed of. This timekeeping element 18 counts clock pulses from a built-in crystal oscillation element and outputs a real-time time signal including the year, month, day, day of the week, and time to the input/output interface 14, and also stores the date in an internal memory provided inside. It stores a set of alarm date and time data consisting of day of the week, hour, and minute, and alarm permission data, and outputs a start signal ST to start the system when the alarm date and time match the current time. .

By the way, when "1" is stored in the alarm permission bit as this alarm permission data, the timing element 18 is set to be in a permission state in which output of the start signal ST is permitted. When "0" is stored in the alarm permission bit, a prohibition state is set in which the output of the activation signal ST is prohibited.

Next, a general startup circuit for starting the system by turning on the power switch MS or by the startup signal ST from the time counting element 18 will be briefly described. The timekeeping element 18 sends an "H" level start signal ST when the alarm date and time in the internal memory and the current time do not match, and sends an "L" level start signal ST to the set terminal of the flip-flop circuit 50 when they match. Output each. On the other hand, when the power switch MS is turned on, an "H" level signal is sent to the flip-flop circuit 50, and when it is turned off, an "L" level signal is sent to the flip-flop circuit 50.
are output to the respective reset terminals. Here, this flip-flop circuit 50 is constructed as shown in FIG. 4, and its truth table is shown in Table 1 below.

[0018]

[Table 1]

Therefore, normally the flip-flop circuit 5
0 means that when an "H" level signal is input from the power switch MS to the reset terminal while the "H" level start signal ST from the timekeeping element 18 is input to the set terminal, "H" level power is output from the output terminal Q. Since the signal is output to the power supply IC chip 51, the power supply IC chip 51 supplies the clock signal to the base of the transistor TR via the resistor R1. At this time, the emitter-collector of the transistor TR becomes conductive at the falling timing of this clock signal, and the drive voltage Vc from the power supply is supplied to the peripheral equipment and the control device C, thereby starting the system.

However, the flip-flop circuit 50 is
When an "L" level signal is input from the power switch MS to the reset terminal, an "L" level power signal is output from the output terminal Q to the power supply IC chip 51, and at the same time, the power supply IC chip 51 outputs the "L" level power supply signal to the power supply IC chip 51. Since transistor TR is placed in a high impedance state, conduction between the emitter and collector of transistor TR is lost, and the system is stopped. Here, when the power switch MS is in the OFF state and the "L" level startup signal ST is supplied from the timing element 18 to the set terminal, the flip-flop circuit 5
0 outputs an "H" level power supply signal from the output terminal Q, so that the emitter and collector of the transistor TR are electrically connected and the system is activated.

A ROM (program memory) 17 includes a display control program that controls the display mechanism DM in response to code data input from the keyboard 3, and the code data is stored in a text memory 22 via a line buffer 21.
A control program that stores the time as document data in the input/output interface 14, a time display program that displays the time in a predetermined display area of the display 10 based on the time signal read through the input/output interface 14, and a time display program that corresponds to the document data in the text memory 22. A printing control program for controlling the printing mechanism PM, a control program for activation prohibition setting control to be described later, and the like are stored. A ROM (calendar information memory) 31 stores calendar information regarding calendars for about 10 years from the present.

The line buffer 21 of the RAM 20 stores one display line of data input from the keyboard 3 and displayed on the display 10, or multiple lines of document data read from the text memory 22 and displayed on the display 10. Of these, one display line of document data including the cursor is stored. The text memory 22 receives one line of data from the line buffer 21 one after another and stores document data. The schedule information memory 23 stores a large amount of input schedule information in association with calendar information. The setting data memory 24 stores five pieces of setting date and time data to be alarmed, each consisting of the year, month, day, day of the week, and time. The year, month, and day data corresponding to the current time are sequentially updated and stored in the year, month, and day memory 25 based on the time signal from the clock element 18.

Next, FIG.
〜Explained based on FIG. 11. In addition, in the figure, Si (i=1, 2
, 3...) are each step. This control is started at the same time as the power switch MS is turned ON or the system is started up via the start-up circuit by the “L” level start signal ST outputted from the timing element 18. First, the initial setting process control (FIG. 6 ) is executed (S1). When this control is started, software initialization and hardware initialization are executed for the RAM 20, display mechanism DM, keyboard 3, etc. (S10 and S11), and the weak voltage signal e input from the comparator 19 is set to "L". ” level (S12: No), alarm processing control (see Figure 7)
is executed (S13). However, when the driving voltage of the lithium battery E becomes a weak voltage and the weak voltage signal e is at the "H" level (S12: Yes), the data in the backup RAM such as the text memory 22 is cleared (S14).
, the alarm date and time data in the clock element 18 is cleared (S15).

When this alarm processing control is started, based on the time signal from the clock element 18, the set date and time data of the future closest to the current time is searched and read out in the set data memory 24 (S20). The current time and the set date and time in the near future are compared (S21), and if they do not match (S22: No), this control is ended and the process returns. However, when these match (S22
:Yes), a predetermined alarm screen is displayed on the display 10, and the buzzer 12 sounds for a predetermined time (for example,
(for about 10 seconds) (S23). For example, when the current time and the set date and time match and the word processor 1 is in use, an alarm screen will be displayed on a part of the display screen during document input and the buzzer 12 will sound as shown in FIG. is rung and also word processor 1
When activated, an alarm screen is displayed in a part of the main menu display screen as shown in FIG. 13, and the buzzer 12 sounds.

After that, when the end key is operated (S2
4.S25: Yes), the display of the alarm screen is erased (S26), and alarm date and time data update processing control (see FIG. 8) is executed (S27). When this control is started, first, if the setting date and time data exists in the setting data memory 24 (S31: Yes), the setting date and time data of the future closest to the current time is searched in the setting data memory 24 and read out. (S32). If the set date and time is within one month from the current time (S
33: No), among the set date and time data, alarm date and time data consisting of the day, day of the week, hour and minute is stored in the internal memory of the timekeeping element 18 (S34), and "1" is stored in the alarm permission bit, The timing element 18 is set to a permission state that allows output of the activation signal ST (S35), and this control ends. However, if the read setting date and time data is a date and time that is one month or more later than the current time (S33
:Yes), "0" is stored in the alarm permission bit, and the timing element 18 is set to a prohibited state in which output of the activation signal ST is prohibited (S36). Note that if the determination is No in S31, the process returns via S36. Therefore, for example, as of January of a certain year, March 20th (
If you set 2:00 p.m. on the 20th (Saturday) as the alarm date and time, and the alarm date and time data for 2:00 p.m. on the 20th (Saturday) is stored in the internal memory, each day and day of the week in February and each day in March will be set. Since the date and day of the week are the same, the alarm date and time match 2:00 p.m. on Saturday, February 20th, but since the clock element 18 is set to the disabled state, the system mistakenly uses the same set date and time. can be reliably prevented from starting automatically. Next, when the schedule key is operated to input or edit schedule information (S
3.S4: Yes), schedule processing control (see FIG. 9) is executed (S5). When this control is started, first, this month's calendar and its schedule information are displayed based on the current date data stored in the date memory 25 (S40), and while displaying these, alarm processing is performed. Control is executed (S41). When the previous key is operated (S42/S43: Yes), the calendar and schedule information from one month ago are displayed (S44). When the next key is operated (S42/S45: Yes), the calendar and schedule information for one month ahead will be displayed (S46)
. For example, as shown in FIG. 14, a calendar for the selected desired year and month is displayed, and the title of the schedule information is also displayed.

[0026] When the cursor movement key is operated to select a desired date (S42/S47
:Yes), cursor movement processing is executed (S48),
When the return key is operated (S42/S49:Y
es), schedule information update processing control (see FIG. 10) is executed (S50), but when the end key is operated (S
42/S51: Yes), processing for terminating this control is executed (S52), and the process returns. When the schedule information update control is started, first, a schedule information update screen regarding the date indicated by the cursor is displayed (S60).
. For example, as shown in FIG.
A schedule information update screen for "August 25, 1990" is displayed. Then, in response to the operation of the cursor movement key (S62
・S63: Yes), and cursor movement processing is executed (S63: Yes).
64), depending on the operation of the character keys (S62/S65: Y
es), character input processing is executed (S66), and in response to the operation of the return key (S62/S67: Yes),
Line feed processing is executed (S68). On the other hand, when the alarm setting key is operated (S62/S69: Yes)
, alarm setting/cancellation processing control (see FIG. 11) is executed (S70), but when the end key is operated (S
62/S69: Yes), processing for terminating this control is executed (S72), and the process returns. When the alarm setting/cancellation control is started, the designated date and time data consisting of the year, month, and day data displayed on the display 10 and the time data designated by the cursor position is stored in the setting data memory 24. It is searched to see if the same date and time data is stored (S80: No).
, and when additional storage is possible in the setting data memory 24 (S81: Yes), the specified date and time data is stored in the setting data memory 24 as setting date and time data, and the alarm mark M is displayed in the time column specified by the cursor ( S82), alarm date and time data update processing control is executed (S85), and this control ends. For example, Figure 15
As shown in , an alarm mark M is displayed in the time field indicated by the cursor. However, when the same date and time data as the date and time data indicated by the cursor is stored in the setting data memory 24 (S80: Yes), that date and time data is deleted from the setting data memory 24 and corresponds to the set date and time. The alarm mark M displayed in the time column of the display 10 is erased (S84), and S85
Return after. Incidentally, when the determination in S81 is No, an error message is displayed on the display 10 and this control is ended. As explained above, when the set of alarm date and time consisting of the date, day of the week, and hour stored in the internal memory of the timekeeping element 18 is a date and time that is one month or more ahead of the current time, the alarm permission bit is set to ``0''. ” is stored, and the timing element 18 is set to a prohibited state in which the output of the start signal ST is prohibited. Even if there is a set date and time that is known to be the same day, day of the week, and time as the set date and time, it is possible to reliably prevent a system from being automatically activated by mistake at the same set date and time.

Note that when the startup prohibition setting control is partially changed and the set date and time to be stored in the timekeeping element 18 is one month or more later than the current time, the output from the output terminal Q of the flip-flop circuit 50 is It is also possible to control the power supply signal through the input/output interface 14 so as to maintain it at the "L" level.

It goes without saying that the present invention can be applied to various schedulers such as Roman word processors, Japanese word processors, electronic notebooks, etc., which are equipped with a schedule function including an alarm function.

[Brief explanation of the drawing]

[Fig. 1] Functional block diagram showing the configuration of the present invention

[Figure 2] Perspective view of word processor

[Figure 3] Block diagram of word processor control system

[Figure 4
]Flip-flop circuit diagram

[Figure 5] Flowchart of the startup prohibition setting control routine

[Figure 6] Flowchart of initial setting process control routine

[Figure 7] Flowchart of alarm processing control routine

[Figure 8] Flowchart of alarm date and time data update processing control routine

[Figure 9] Flowchart of schedule processing control routine

FIG. 10: Flowchart of schedule information update processing control routine

[Figure 11] Flowchart of alarm setting/cancellation processing control routine

[Figure 12] Diagram showing an example of an alarm screen displayed while using a word processor

[Figure 13] Diagram showing a display example of the alarm screen displayed when the word processor is started

[Fig. 14] A diagram showing an example of a calendar displayed on the display.

[Figure 15] A diagram showing an example of a schedule information update screen displayed on the display.

[Explanation of symbols]

1. Word processor 3 Keyboard 10 Display 16 CPU 17 ROM 18 Clock element 20 RAM 23 Schedule information memory 24 Setting data memory 31 ROM C Control device DM Display mechanism

Claims (1)

[Claims] [Claim 1] Input means for inputting character and symbol data and various command signals, a calendar memory storing calendar information, and input means for inputting a plurality of set alarm dates and times, year, month, day and day of the week. a storage means comprising a setting data memory for storing time data and a schedule information memory for storing input schedule information in association with calendar information; and a storage means for displaying the calendar information and schedule information. A display means having a display, and outputting a real-time time signal including the year, month, day, day of the week, and time by counting the clock signal from the oscillation element, and outputting data of the day, day of the week, hour, and minute of a set of set date and time. a clock means having an internal memory for storing data and outputting a start signal for starting the system when the set date and time coincides with the current time; A control means for displaying a predetermined alarm screen on the display means when a set date and time comes, reads the set date and time data of the nearest future from the set data memory, and stores a part of it in the internal memory of the timekeeping means; In the scheduler, when the set date and time is one month or more ahead of the current time based on the time signal and the nearest future set date and time data, the timekeeping means is prohibited from outputting the activation signal. A scheduler characterized in that it is provided with a startup prohibition setting means for setting to a prohibited state.