JP2009150727A - Electronic device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To more easily execute control of various processing operations including the reception operation of standard radio waves. <P>SOLUTION: The electronic device includes: a time measuring part 201 for measuring time; a time memory part 202 for storing information on a predetermined time; a comparison part 203 for comparing the time measured by the time measuring part 201 with the time relating to the information stored by the time memory part 202 and then outputting a coincidence signal when the two times match; a processing part 204 for executing predetermined processing to achieve a predetermined function when the coincidence signal output by the comparison part is input; and a processing execution control part 205 for controlling execution of the predetermined processing by changing the information on the predetermined time stored in the time memory part 202. The processing execution control part 205 controls various processing operations by changing only execution disclosure time information on various processes stored in the time memory part 202. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an electronic device that includes timekeeping means and realizes various functions, and more particularly to a portable electronic device including a wristwatch.

  2. Description of the Related Art Conventionally, there is a technique for extending a battery life by performing a scheduled reception in a radio-controlled timepiece and setting a power saving state depending on a usage state of a user (see, for example, Patent Document 1 below). In Patent Document 1, for example, in FIG. 7, a reception time storage circuit (401), a time counter (402), a reception time comparison circuit (403) and an inventory status comparison circuit (709) are provided.

  In such a circuit configuration, when the values of the reception time storage circuit (401) and the time counter (402) match, the signal (E) output from the reception time comparison circuit (403) and the inventory status comparison circuit ( 709) is input to the reception start determination circuit (410), and it is determined whether or not the reception of the standard radio wave is started by these signals, and the signals (E) and (F) When the inverted signal is AND, the receiving circuit (711) is activated. Further, the forced reception at the time of canceling the power saving state is realized by the forced reception start circuit (713).

JP-A-7-159555

  However, in the prior art according to Patent Document 1, the reception circuit (711) is not always operated by the reception start determination circuit (410) in the stock state. Nevertheless, the reception time comparison circuit 403 has a problem that unnecessary comparison processing is performed.

  Further, in the prior art according to Patent Document 1, not only a forced reception start circuit (713) for starting forced reception is separately required, but also the circuit configuration becomes complicated for each specification change. There was a problem that it was.

  An object of the present invention is to provide an electronic apparatus that can more easily execute operation control of various processes including a reception operation of a standard radio wave in order to solve the above-described problems caused by the related art.

  In order to solve the above-described problems and achieve the object, an electronic device according to the present invention includes a time measuring means for measuring time, a time storage means for storing information relating to a predetermined time, and a time measured by the time measuring means. And a comparison means for outputting a coincidence signal when both times coincide, and a coincidence signal output by the comparison means is input. In addition, processing means for executing a predetermined process for realizing a predetermined function, and process execution control for controlling execution of the predetermined process by changing information related to the predetermined time stored in the time storage means Means.

  In the electronic device according to the present invention, in the above invention, the process execution control unit changes the information about the predetermined time stored in the time storage unit to information that does not output the coincidence signal in the comparison unit. It is characterized by that.

  Further, in the electronic device according to the present invention, in the above invention, the processing execution control means may be a time at which the information related to the predetermined time stored in the time storage means cannot be measured by the time measuring means. It is characterized by changing.

  Further, in the electronic device according to the present invention, in the above invention, the process execution control unit may set the information related to the predetermined time stored in the time storage unit to a past time already counted by the time measuring unit. It is characterized by changing.

  Further, in the electronic device according to the present invention, in the above invention, the processing unit corrects the time measured by the receiving unit receiving the standard radio wave including time information and the time measured by the time measuring unit based on the standard radio wave. And the process execution control unit causes the reception process by the reception unit and the time correction process by the time correction unit to be executed at a time related to the information stored in the time storage unit. Features.

  In the electronic device according to the present invention, the electronic device according to the present invention is changed from a normal operation state to a power saving state in which execution of a predetermined process of the processing means for realizing a predetermined function is stopped based on a predetermined condition. And a power saving state control means for outputting a power saving control signal to the process execution control means so that the process execution control means receives the predetermined power stored in the time storage means when the power saving control signal is input. It is characterized in that the information regarding the time of is changed.

  Further, in the electronic device according to the present invention, in the above invention, when the processing execution control unit releases the power saving state, the time storage is performed so that a time obtained by adding a predetermined time to the released time is obtained. The information regarding the predetermined time memorize | stored in the means is changed, It is characterized by the above-mentioned.

  The electronic device according to the present invention is characterized in that, in the above invention, the processing means includes notification means for notifying that the predetermined time has come.

  In the electronic device according to the present invention as set forth in the invention described above, the notification means includes a sound generation means, a vibration means, and a display means.

  In the electronic device according to the present invention, in the above invention, when the process execution control unit changes information related to a predetermined time stored in the time storage unit, the information before the change is stored in a predetermined storage area. It is characterized by storing.

  According to the present invention, since the operation of various processes is controlled only by changing the execution start time information of various processes, an electronic apparatus that can more easily execute the operation control of various processes including the reception operation of the standard radio wave is provided. The effect is obtained.

  Embodiments of an electronic apparatus according to the present invention will be described below in detail with reference to the accompanying drawings (FIGS. 1 to 11).

(Configuration of electronic equipment)
FIG. 1 is an explanatory diagram showing a hardware configuration of an electronic device according to an embodiment of the present invention. In FIG. 1, the electronic device main body includes a microcomputer IC 100, a RAM 101, a ROM 102, a motor drive circuit 103, a motor 104 (104a, 104b, 104c), a train wheel 105 (105a, 105b, 105c), a reference Signal generating unit 106, counter unit 107, antenna 108, tuning circuit 109, receiving circuit 110, switch unit 111, switch control circuit 112, solar cell 113, secondary battery 114, and charging control circuit 115 A liquid crystal screen 116, a liquid crystal drive circuit 117, an LED 118, an LED drive circuit 119, an alarm 120, an alarm drive circuit 121, and a vibrator 122.

  The microcomputer IC 100 controls the entire electronic device main body and individually controls various components and circuits. The RAM 101 stores various data such as time data including time information or calendar information. The ROM 102 stores various control programs.

  The motor driving circuit 103 drives three independent motors 104 (104a, 104b, 104c), and guides (day plate, day plate) not shown through the train wheel 105 (105a, 105b, 105c). Are independently driven. The number of motors 104 is not limited to three, and may be two or less, or four or more, depending on the function of the electronic device.

  The reference signal generation unit 106 is composed of, for example, an oscillation circuit, and generates a signal having a predetermined frequency that serves as a reference for time measurement processing. The counter unit 107 outputs a signal having a predetermined frequency generated from the reference signal generation unit 106 to the microcomputer IC 100.

  The tuning circuit 109 tunes with the antenna 108 and tunes the antenna 108 to a frequency such as 60 kHz (US), 77.5 kHz (Germany), 40 kHz, 60 kHz (Japan), for example, by switching the capacitance of the capacitor. The receiving circuit 110 detects a standard radio wave from the signal received by the antenna 108 and outputs it to the microcomputer IC 100.

  The switch unit 111 inputs an operation instruction from the operator. Specifically, it is constituted by a crown, an operation button or the like. The switch control circuit 112 transmits an input related to an operation instruction from the operator to the microcomputer IC 100 based on a signal from the switch unit 111.

  The charge control circuit 115 converts the light received by the solar cell 113 into electric power and stores it in the secondary battery 114. The charge control circuit 115 also has a voltage detection function for detecting the voltage (value) of the secondary battery 114, a power generation detection function for detecting whether the solar cell 113 is in a power generation state or a non-power generation state, and the like. And the signal regarding a detection result is output with respect to microcomputer IC100 by these functions.

  The liquid crystal driving circuit 117 drives the liquid crystal screen 116 to display various information. Specifically, the liquid crystal screen 116 and the liquid crystal driving circuit 117 are, for example, a ferroelectric liquid crystal or an electrophoretic display element. These are preferred because they do not consume power while displaying a screen with the same content.

  Further, the LED drive circuit 119 drives the LED 118 to illuminate the liquid crystal screen 116 as a backlight, or outputs a warning light. Instead of the LED 118, an EL (Electroluminescence), a lamp, or the like may be used. The alarm driving circuit 121 drives a piezoelectric element (not shown) mounted on the alarm 120 and outputs an alarm (buzzer) 120. At that time, the alarm drive circuit 121 changes the type of sound, the height, the volume, and the like depending on the type of notification. Furthermore, you may provide the vibrator 122 which generate | occur | produces a vibration.

  2 and 3 are explanatory diagrams showing a functional configuration of the electronic apparatus according to the embodiment of the present invention. FIG. 2 shows a functional configuration in the case of time correction processing as the predetermined processing. In FIG. 2, the electronic device includes a timekeeping unit 201, a time storage unit 202, a comparison unit 203, a processing unit 204, a process execution control unit 205, a power saving state control unit 206, and a predetermined storage area (evacuation area). 207 and an input unit 208 are included.

  The timekeeping unit 201 measures the current time (specifically, the time required for local time such as Japan time, UTC, etc.) and other time (or time), and outputs information related to the current time to the comparison 203. The time measuring unit 201 may output information related to the current time measured to the process execution control unit 205 (the process execution control unit 205 stores the information in the time storage unit 202 based on the input information related to the current time). Information on the current time may be changed). Specifically, the time measuring unit 201 can realize its function by, for example, the reference signal generating unit 106 and the counter unit 107 shown in FIG.

  The time storage unit 202 stores information regarding a predetermined time (for example, time correction start time). Specifically, the time storage unit 202 realizes its function by, for example, the RAM 101 and the ROM 102 shown in FIG.

  The comparison unit 203 compares the time counted by the time counting unit 201 with the time concerning the information stored in the time storage unit 202, and outputs a coincidence signal to the processing unit 204 when both times coincide. Specifically, for example, the microcomputer IC 100 shown in FIG. 1 realizes its function by executing a program stored in the RAM 101 and the ROM 102. Further, the comparison unit 203 receives the information output from the time measuring unit 201, extracts the information extracted from the time storage unit 202, compares the two information, and realizes its function by a comparison circuit (not shown). You may do it.

  The processing unit 204 executes predetermined processing (for example, time correction processing) for realizing a predetermined function when the coincidence signal output from the comparison unit 203 is input. Specifically, the processing unit 204 realizes its function by, for example, the microcomputer IC 100 illustrated in FIG. 1 executing programs stored in the RAM 101 and the ROM 102. Details of the processing unit 204 will be described later.

  The process execution control unit 205 stores the time storage unit 202 based on, for example, input of various operation instructions such as a reception prohibition instruction received by the input unit 208 or input of a power saving control signal from the power saving state control unit 206. The execution of various predetermined processes (for example, time correction process) in the processing unit 204 is controlled by changing the stored information on the predetermined time. Specifically, the process execution control unit 205 realizes its function by, for example, the microcomputer IC 100 illustrated in FIG. 1 executing programs stored in the RAM 101 and the ROM 102.

  The process execution control unit 205 controls the execution of various predetermined processes by changing the information related to the predetermined time stored in the time storage unit 202 to information that does not output a coincidence signal in the comparison unit 203. Any information may be used as long as the coincidence signal is not output in the comparison unit 203.

  For example, the process execution control unit 205 changes the information related to a predetermined time stored in the time storage unit 202 so that the time cannot be measured by the time measuring unit, so that the comparison unit 203 outputs a coincidence signal. (For example, see FIG. 4 or FIG. 5 described later). Further, the process execution control unit 205 changes the information related to the predetermined time stored in the time storage unit 202 so as to be a past time (or a distant future time) that has already been measured by the time measuring unit 201, It is possible to prevent the coincidence signal from being output in the comparison unit 203 (see, for example, FIG. 6 described later).

  The processing unit 204 includes a standard radio wave reception unit 211 and a time correction unit 212. Here, the standard radio wave receiver 211 receives a standard radio wave including time information. Specifically, the standard radio wave reception unit 211 realizes its function by, for example, the reception circuit 110 shown in FIG. That is, the standard radio wave receiver 211 includes, for example, an amplifier, a filter, a detector, an AD converter, a gain controller, and the like. Since each of these components can be realized by the conventional technology, the description thereof is omitted.

  The time correcting unit 212 corrects the time measured by the time measuring unit 201 based on the standard radio wave. Therefore, when the standard radio wave receiving unit 211 fails to receive the standard radio wave, the timekeeping time is not corrected. Specifically, the time correction unit 212 realizes its function by, for example, the microcomputer IC 100 illustrated in FIG. 1 executing a program stored in the RAM 101 and the ROM 102.

  Then, the process execution control unit 205 causes the standard radio wave reception unit 211 to execute the reception process by the standard radio wave reception unit 211 and the time correction process by the time correction unit 212 at the time related to the information stored in the time storage unit 202. Here, the process execution control unit 205 does not directly transmit a process execution start signal to the standard radio wave reception unit 211 and the time correction unit 212, but is set by the process execution control unit 205 and stored in the time storage unit 202. The comparison unit 203 compares the stored time with the time measured by the time measuring unit 201, the comparison unit 203 compares the time based on the comparison result, and outputs a coincidence signal to the processing unit 204. When the coincidence signal is input, the standard radio wave reception unit 211 starts a standard radio wave reception process. Then, when the standard radio wave is successfully received, the time correction unit 212 performs time correction processing.

  Based on a predetermined condition, the power saving state control unit 206 controls the power saving so as to shift from a normal operation state to a power saving state in which execution of a predetermined process of the processing unit 204 for realizing a predetermined function is stopped. The signal is output to the process execution control unit 205.

  The predetermined condition is, for example, the case where power generation by the solar cell 113 shown in FIG. 1 is not performed, or the case where the remaining charge of the secondary battery 114 becomes a predetermined value or less. These can be determined based on the state of charge of the secondary battery 114 by the charge control circuit 115 and the measurement result of the voltage value of the secondary battery.

  The process execution control unit 205 changes the information related to a predetermined time stored in the time storage unit 202 when a power saving control signal is input. In addition, when the power saving state is canceled, the process execution control unit 205 changes the information related to the predetermined time stored in the time storage unit 202 so as to be a time obtained by adding the predetermined time to the released time. . The time obtained by adding a predetermined time to the canceled time may be, for example, the next minute minutes. That is, if the released time (return time) is “5:25:36”, the next minute is “5: 26: 0” (see, for example, FIG. 7).

  The predetermined storage area (save area) 207 stores the information before the change when the information related to the predetermined time stored in the time storage unit 202 is changed based on the control by the process execution control unit 205. By doing so, while the information related to the time in the time storage unit 202 is changed, the information before the change is retained, and if necessary, the information before the change is output to the time storage unit 202 to obtain the time. In the storage unit 202, it is possible to return to the information before the change.

  The input unit 208 accepts input, change, deletion, and the like of information related to the time stored in the time storage unit 202. The input unit 208 accepts input of various operation instructions such as a forced reception instruction and a reception prohibition instruction. Specifically, the function of the input unit 208 is realized by, for example, the switch unit 111 and the switch control circuit 112 shown in FIG.

  FIG. 3 shows a functional configuration in the case of the notification process as the predetermined process. In FIG. 3, the electronic device includes a timekeeping unit 201, a time storage unit 202, a comparison unit 203, a processing unit 204, a process execution control unit 205, a predetermined storage area (evacuation area) 207, and an input unit 208. The notification unit 301 is included.

  As in FIG. 2, the timer 201 measures the current time and other times (or times), and outputs information related to the measured current time to the comparator 203 (the process execution control unit 205 inputs the current time The information on the time stored in the time storage unit 202 may be changed based on the information on the time). The time storage unit 202 stores information related to a predetermined time (for example, notification start time). As in FIG. 2, the comparison unit 203 compares the time counted by the time counting unit 201 with the time concerning the information stored in the time storage unit 202, and if both times match, the comparison signal is processed. To 204.

  The process execution control unit 205 changes the information related to a predetermined time stored in the time storage unit 202 based on, for example, input of various operation instructions such as a notification on / off instruction by the input unit 208. The execution (for example, notification process) of various predetermined processes in the unit 204 is controlled. The process execution control unit 205 controls the execution of various predetermined processes by changing the information related to the predetermined time stored in the time storage unit 202 to information that does not output a coincidence signal in the comparison unit 203.

  The processing unit 204 executes predetermined processing (for example, notification processing) for realizing a predetermined function when the coincidence signal output from the comparison unit 203 is input. The processing unit 204 includes a notification unit 301. The notification unit 301 includes a sound generation unit 311, a vibration unit 312, and a display unit 313 that notify that a predetermined time has come.

  Specifically, the sound generation unit 221 realizes its function by, for example, the alarm 120 and the alarm drive circuit 121 shown in FIG. Specifically, the vibration unit 222 realizes its function by the vibrator 122 shown in FIG. 1, for example. Specifically, the display unit 313 realizes its functions by the liquid crystal screen 216 and the liquid crystal driving circuit 117, the LED 118, the LED driving circuit 119, and the like shown in FIG.

  The display unit 313 realizes a display function by, for example, the motor drive circuit 103, the motor 104, the train wheel 105 shown in FIG. 1, each pointer (not shown) (including date and day plates) and a dial. It may be. At that time, the function as the notification unit 301 can be achieved by a method such as changing a method of moving the pointer.

  Here, the process execution control unit 205 does not directly transmit a process execution start signal to the notification unit 301 (the sound generation unit 311, the vibration unit 312, and the display unit 313), but is set by the process execution control unit 205. The comparison unit 203 compares the time stored in the time storage unit 202 with the time measured by the time measuring unit 201, the comparison unit 203 compares the time based on the comparison result, and the coincidence signal is processed by the processing unit. To 204. The notification unit 301 starts notification processing (for example, alarm sound generation processing, vibration processing, display processing, etc.) when the coincidence signal is input.

  Similar to FIG. 2, the predetermined storage area (reservation area) 207 stores the information before the change when the information related to the predetermined time stored in the time storage unit 202 is changed based on the control by the process execution unit 205. To do. The input unit 208 accepts input, change, deletion, and the like of information related to the time stored in the time storage unit 202. The input unit 208 accepts input of various operation instructions such as a notification on / off instruction.

(Data structure of time storage unit 202 and save area 207)
4 to 9 are explanatory diagrams showing data configurations of the time storage unit 202 and the save area 207. FIG. In FIG. 4, time information “02:00” and “04:00” is normally stored in the time storage unit (time storage circuit) 202. In this case, a coincidence signal is output from the comparison unit 203 at 2:00 am and 4:00 am, and the processing unit 204 executes a predetermined process.

  Then, the process execution control unit 205 saves the time information “02:00” and “04:00” in the save area 207, and adds “24 (hours)” to the normal time information as new time information. Update the stored value and store it. Therefore, “02:00” is changed to “26:00” and “04:00” is changed to “28:00”. In the time measuring unit 201, after counting to “23:59”, since it returns to “00:00”, it does not become “24:00” or more. Therefore, by adding the numerical value “24 (hours)”, the comparison unit 203 does not coincide with the measured time, and the coincidence signal from the comparison unit 203 is not output.

  FIG. 5 shows a state in which, instead of adding “24 (hours)” to the current time, the time is changed to a value that is not counted by the time measuring unit 201 regardless of the current time. That is, in FIG. 5, as in FIG. 4, the time information “02:00” and “04:00” are saved in the save area 207, and new data is emptied or the specific data “FF” : FF "is stored. Even in this case, the comparison unit 203 does not output a coincidence signal.

  In FIG. 6, the time storage unit 202 stores date information in addition to the time information, and the comparison unit 203 compares the information measured by the time measuring unit 201 including the date. Here, it is normally stored in the time storage unit 202 so that the processing is performed at the same time “02:00 (2:00 AM)” every day. Then, the process execution control unit 205 saves the information stored in the time storage unit 202 to the save area 207, and the information in the time storage unit 202 is changed to a date before the previous day. At that time, the time information may be left as it is without being changed.

  If the current time is “September 25, 1:59 (1:59 am)”, a match signal is output from the comparison unit 203 one minute later, but the date is one day before ( September 24), the coincidence signal is not output from the comparison unit 203 after one minute. Thus, by outputting only the date / time information without changing the time information, the output of the coincidence signal from the processing unit 207 can be easily prohibited.

  FIG. 7 shows the return time (“05: 25′36” (5:25 am) when the processing prohibition release (return) is made in the state where the time information “02:00” is saved in the save area 207. Minute 36 seconds) ”) is acquired from the time measuring unit 201, and the next correct minute (“ 05: 26′00 ””) of the time is stored in the time storage unit 202. By doing so, especially in the time correction process (standard radio wave reception process), the automatic reception process of the standard radio wave can be executed in the shortest and efficient manner. Thereafter, the time information “02:00” saved in the save area 207 is stored in the time storage unit 202 in place of the above “05: 27′00”, so that “02:00” is set again from the next day. (Time correction) processing is executed.

  In FIG. 8, the time storage unit 202 stores interval (various intervals including standard radio wave reception intervals) information in addition to time (various times including standard radio wave reception times) information. Then, by changing only the interval information without changing the time information, the processing (various processing including standard radio wave reception processing) interval can be made longer than usual. That is, the interval information is normally “1 day”, and in this normal state, the timer 201 measures whether 24 hours have passed since the previous reception, so that the process is executed every day at 2 am. By changing the interval information from “1 day” to “7 days (1 week)”, the comparison unit 203 outputs a coincidence signal unless the time measuring unit 201 has elapsed 24 hours × 7 days = 168 hours. You can avoid it. In this way, it is possible to easily control the processing interval to be long by changing only the interval information.

  In FIG. 9, a predetermined process (various processes including a standard radio wave reception process) is normally executed twice daily at 2 am and 4 am. The process execution control unit 205 performs time information (“20:00”, “21:00”, “22:00”) different from the normal time information (“02:00”, “04:00”). The time storage unit 202 can be changed so as to increase the number of times the time information is processed from 2 times to 5 times. As a result, the processing frequency per day can be increased. Although illustration is omitted, the daily processing frequency can be reduced by deleting the normal time information.

(Operation details of the process execution control unit)
Next, the operation content of the process execution control unit 205 will be described. 10 and 11 are flowcharts (part 1) showing the operation content of the process execution control unit 205. In the flowchart of FIG. 10, the process execution control unit 205 determines whether there is an instruction to stop processing such as time correction processing from the power saving state control unit 206 or the input unit 208 (step S1001).

  In step S1001, the process waits for an instruction to stop the process, and if there is an instruction (step S1001: Yes), saves the time information stored in the time storage unit 202 to the save area 207 (step S1001). S1002). Then, a time change process is performed so as to replace the time information with a predetermined numerical value (see FIGS. 4 to 9) (step S1003).

  Thereafter, it is determined whether or not there is an instruction to restore the time information saved in the save area 207 (for example, when a transition is made from the power saving state to the normal state) (step S1004). Then, after waiting for a return instruction, if there is a return instruction (step S1004: Yes), the time information saved in the save area 207 is returned to the time storage unit 202 (step S1005). The process returns to step S1001. Thereafter, the processes in steps S1001 to S1005 are repeated.

  The flowchart of FIG. 11 shows the operation contents when performing automatic reception when returning from the processing stop. In the flowchart of FIG. 11, steps S1101 to S1104 are the same processing contents as steps S1001 to S1004 of the flowchart of FIG.

  In step S1104, after waiting for a return instruction, if there is a return instruction (step S1104: Yes), the time (return time) at which the return instruction is given is acquired (step S1105). Next, the next minute (0 second) of the return time is calculated (step S1106). And the time memory | storage part 202 is changed so that it may become the time (calculation time) calculated in step S1106 (step S1107). Thus, predetermined processing (for example, standard radio wave reception processing) is immediately started at the next minute.

  Then, after waiting for the calculation time to elapse (step S1108: Yes), the time information is restored (step S1109). That is, the calculated time stored in the time storage unit 202 is changed to the time information saved in the save area 207. Thereafter, the process returns to step S1101. Thereafter, the processes of steps S1101 to S1109 are repeated.

  As described above, in the present embodiment, the time measuring unit 201 that measures time, the time storage unit 202 that stores information related to a predetermined time, the time counted by the time measuring unit 201, and the time storage unit 202 The time required for the stored information is compared. When both times coincide, the comparison unit 203 that outputs a coincidence signal, and when the coincidence signal output by the comparison unit 203 is input, the predetermined function is A processing unit 204 that executes a predetermined process for realizing; and a process execution control unit 205 that controls execution of the predetermined process by changing information related to a predetermined time stored in the time storage unit 202. Therefore, the process execution control unit 205 controls the operation of various processes by changing only the execution disclosure time information of the various processes stored in the time storage unit 202. It is possible to execute the operation control of various processes including the receiving operation more easily.

  In the above embodiment, the electronic device has been described by taking a wristwatch as an example. However, the electronic device includes all types of watches such as a wristwatch, a pocket watch, a wall clock, and a table clock. In addition, portable information terminal devices such as cameras, digital cameras, digital video cameras, game machines, mobile phones, PDAs (Personal Digital Assistants), notebook personal computers, etc., which have a pointer-type display function, and home Electronic devices including electrical appliances and automobiles may be used.

  As described above, the present invention is useful for an electronic device including a time measuring means, and is particularly suitable for a portable electronic device such as a wristwatch.

It is explanatory drawing which shows the hardware constitutions of the electronic device concerning embodiment of this invention. It is explanatory drawing (the 1) which shows the functional structure of the electronic device concerning embodiment of this invention. It is explanatory drawing (the 2) which shows the functional structure of the electronic device concerning embodiment of this invention. FIG. 6 is an explanatory diagram (part 1) illustrating a data configuration of a time storage unit and a save area. FIG. 6 is an explanatory diagram (part 2) illustrating a data configuration of a time storage unit and a save area. FIG. 10 is an explanatory diagram (part 3) illustrating a data configuration of a time storage unit and a save area. It is explanatory drawing (the 4) which shows the data structure of the time memory | storage part 202 and the save area 207. FIG. 10 is an explanatory diagram (part 5) illustrating the data configuration of the time storage unit 202 and the save area 207; It is explanatory drawing (the 6) which shows the data structure of the time memory | storage part 202 and the save area 207. 6 is a flowchart (part 1) showing operation contents of a process execution control unit 205; 12 is a flowchart (part 2) showing the operation content of the process execution control unit 205;

Explanation of symbols

100 Microcomputer IC
101 RAM
102 ROM
106 Reference signal generator 107 Counter 113 Solar cell 114 Secondary battery 115 Charge control circuit 116 LCD screen 118 LED
DESCRIPTION OF SYMBOLS 120 Alarm 122 Vibrator 201 Time measuring part 202 Time storage part 203 Comparison part 204 Processing part 205 Process execution control part 206 Power-saving state control part 207 Predetermined storage area (evacuation area)
208 Input unit 211 Standard radio wave reception unit 212 Time correction unit 301 Notification unit 311 Sound generation unit 312 Vibration unit 313 Display unit

Claims (10)

A time measuring means for measuring time;
Time storage means for storing information relating to a predetermined time;
A comparing means for comparing the time measured by the time measuring means with the time for the information stored by the time storage means, and outputting a coincidence signal when both times coincide;
Processing means for executing a predetermined process for realizing a predetermined function when there is an input of a coincidence signal output by the comparison means;
Process execution control means for controlling execution of the predetermined process by changing information on the predetermined time stored in the time storage means;
An electronic device characterized by comprising:   The electronic apparatus according to claim 1, wherein the processing execution control unit changes information related to a predetermined time stored in the time storage unit to information that does not output the coincidence signal in the comparison unit.   3. The electronic device according to claim 2, wherein the processing execution control unit changes the information related to the predetermined time stored in the time storage unit so that the time cannot be measured by the time measuring unit. machine.   3. The electronic device according to claim 2, wherein the processing execution control unit changes the information related to the predetermined time stored in the time storage unit so as to become a past time already measured by the time measuring unit. machine. The processing means includes
A receiving means for receiving a standard radio wave including time information;
Correcting the time measured by the time measuring means based on the standard radio wave,
5. The process execution control unit according to claim 1, wherein the reception process by the reception unit and the time correction process by the time correction unit are executed at a time related to information stored in the time storage unit. The electronic device as described in any one. Based on a predetermined condition, the power saving control signal is sent to the process execution control means so as to shift from a normal operation state to a power saving state in which execution of the predetermined process of the processing means for realizing a predetermined function is stopped. Power saving state control means for outputting,
The electronic apparatus according to claim 5, wherein the processing execution control unit changes information regarding a predetermined time stored in the time storage unit when the power saving control signal is input.   The process execution control means changes the information related to the predetermined time stored in the time storage means so as to be a time obtained by adding a predetermined time to the released time when the power saving state is released. The electronic apparatus according to claim 6.   The electronic device according to claim 1, wherein the processing unit includes a notification unit that notifies that the predetermined time has been reached.   9. The electronic apparatus according to claim 8, wherein the notification means includes sound generation means, vibration means, and display means.   The said process execution control means preserve | saves the information before a change in a predetermined storage area, when changing the information regarding the predetermined time memorize | stored in the said time storage means. The electronic device as described in one.

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