JP2004003929A - Radio wave corrected clock - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a wave corrected clock that can be reduced in power consumption by suppressing wasteful use of electric power. <P>SOLUTION: This wave corrected clock is provided with a power supply control means 43 for receiving section, which periodically actuates a reception power source circuit 24 for driving a receiving circuit 22 which receives radio waves, including time information. The control means 43 is provided with an elapsed-time detecting means 110 which finds the time elapsed after the last radio wave reception time, a reception schedule storing means 130 stored with the schedule information of power supply, and a schedule information setting means 120 which switches the schedule information to another schedule information B, having a power-supplying time interval longer than an initial set value A, when the elasped time becomes longer than a set value. The control means 43 is also provided with a power source circuit control means 140 which controls the actuation of the power source circuit 24, based on the schedule information. Power consumption of this wave-corrected clock can be reduced, because the frequency with which the radio waves is received is reduced, when the the time during which the radio wave cannot be received increases. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a radio-controlled timepiece.
[0002]
[Background Art]
2. Description of the Related Art A radio-controlled timepiece that receives a long-wave standard radio wave on which time information is superimposed and corrects the time is known (for example, see Patent Document 1). In addition to forced reception, in which the user operates the crown or button to forcibly receive the standard time signal, such a radio-controlled timepiece normally receives the standard time signal at the set reception time and automatically receives it. Is set to an automatic reception function to correct the time.
[0003]
[Patent Document 1]
Japanese Patent No. 2973303 ([0022] to [0027])
[0004]
[Problems to be solved by the invention]
By the way, a radio-controlled timepiece may not be able to receive radio waves due to the surrounding electric field condition, for example, the influence of a magnetic field, or the difficulty of radio waves reaching inside a building. In addition, there is a case where radio waves cannot be received due to staying in an area where standard radio waves cannot be received, such as an overseas business trip.
In these cases, even if the receiving operation is automatically performed by the automatic receiving function, the standard radio wave cannot be received, and the time is not corrected.
[0005]
In this case, the receiving operation is performed even though the radio wave cannot be received, so that power is wasted. In particular, since the receiving operation is the process that consumes the most power in a timepiece, there has been a problem that, for example, the life of the battery is shortened in a battery-driven wristwatch or the like.
[0006]
An object of the present invention is to provide a radio-controlled timepiece that can reduce wasteful power consumption and save power.
[0007]
[Means for Solving the Problems]
The radio-controlled timepiece of the present invention is a clock means for measuring the current time based on a reference clock, a current time display means for displaying the measured current time, and a receiving means for receiving a radio wave including time information, A radio wave comprising: a receiving power control means for periodically operating a receiving power means for driving the receiving means; and a current time correcting means for correcting the current time of the clock means based on the time information received by the receiving means. In the modified timepiece, the reception power control unit includes an elapsed time detection unit that determines an elapsed time from when a previous radio wave was received, and schedule information that defines an operation time interval when the reception power unit is periodically operated. Schedule information setting means for setting, and power supply means control means for controlling the operation of the reception power supply means based on the schedule information; Means for switching the schedule information to schedule information having an operation time interval longer than an initial set value when the elapsed time is equal to or longer than a set time, and the radio-controlled timepiece is adapted to switch the elapsed time obtained by the elapsed time detection means. Is displayed on the display unit.
[0008]
The radio-controlled timepiece of the present invention is a clock means for measuring the current time based on a reference clock, a current time display means for displaying the measured current time, and a receiving means for receiving a radio wave including time information, A radio wave comprising: a receiving power control means for periodically operating a receiving power means for driving the receiving means; and a current time correcting means for correcting the current time of the clock means based on the time information received by the receiving means. In the modified timepiece, the reception power control unit includes an elapsed time detection unit that determines an elapsed time from when a previous radio wave was received, and schedule information that defines an operation time interval when the reception power unit is periodically operated. Schedule information setting means for setting, and power supply means control means for controlling the operation of the reception power supply means based on the schedule information; Means is characterized in that the elapsed operating time intervals than the time the initial setting value the schedule information to be a set time or longer to switch to the long schedule information.
Here, as the radio wave including the time information, a so-called standard radio wave in which the time information is set in a predetermined format can be suitably used, but even if the radio wave has an undefined format, the time information is included. Any radio wave that can acquire time information by receiving the radio wave can be used.
[0009]
In such an embodiment of the present invention, in normal times, the clock means counts the reference clock to measure the current time, and the current time is displayed by the current time display means.
On the other hand, the receiving power control means operates the receiving power means periodically based on the schedule information to supply power to the receiving means and drive the receiving means. For example, when the initial setting value of the schedule information is one day, power is supplied to the receiving means every day (for example, every day at 2:00 am), and the receiving means operates periodically. During this operation, a radio wave including time information is received. If the radio wave is received and the time information is correct, the current time is corrected by the current time correction means based on the time information.
[0010]
On the other hand, if a radio wave including time information cannot be received during a regular reception operation, time correction is not performed.
If the reception failure state continues and the time since receiving the previous radio wave detected by the elapsed time detecting means has passed a set time (for example, 7 days) or more, the schedule information setting means sets the schedule information to The information is set to schedule information whose operation time interval (power supply time interval) is longer than the initial set value. For example, if the initial set value is one day, it is set to five days.
Therefore, thereafter, the receiving power control unit drives the receiving unit based on the schedule information (for example, 5 days) having a long operation time interval, and tries to receive radio waves.
[0011]
For this reason, for example, when a radio-controlled watch is left in a place where radio waves are difficult to receive, such as in a building, or when traveling overseas, staying on a business trip, etc. Is changed to receive once a day at intervals of five days, so that the number of radio wave receiving operations can be reduced and power consumption can be reduced accordingly. Therefore, the battery life can be prolonged in the case of battery drive, and energy saving can be achieved even when a commercial power supply from an outlet is used.
[0012]
Note that a plurality of the set times may be set, and the reception power control unit may further increase the periodical power supply to the reception unit each time the set time elapses. That is, the schedule information setting means may sequentially switch to the schedule information having a longer power supply time interval every time the elapsed time elapses each set time.
For example, if three types of set times are set, such as a set time of 7 days, a second set time of 20 days, and a third set time of 40 days, the schedule information is initialized when the elapsed time exceeds 7 days. The reception is set to a time interval longer than the set value, for example, once every five days. If the elapsed time is 20 days or more, the periodic power supply to the receiving means is set to the reception at a longer time interval, for example, once every 10 days. Further, after elapse of 40 days or more, the periodic power supply to the receiving means is set to the reception at a longer time interval, for example, once every 20 days. In this way, if a plurality of set times are set and the power supply interval is sequentially increased when each set time has elapsed, power consumption by the receiving operation is further reduced, and more energy saving can be achieved.
[0013]
Here, the reception power control unit includes a reception schedule storage unit in which the schedule information is stored, and the schedule information setting unit determines a schedule according to the elapsed time from a plurality of preset reception schedule information. Preferably, information is selected and stored in the reception schedule storage means, and the power supply control means controls the operation of the reception power supply means based on the schedule information stored in the reception schedule storage means.
The schedule information setting means may be, for example, a unit having a calculation unit in which a predetermined mathematical expression is set, and outputting the schedule information according to the elapsed time when the elapsed time is input. On the other hand, if a plurality of pieces of schedule information are set in advance and the selected schedule information is stored and controlled in the reception schedule storage means, the degree of freedom in setting the schedule is high and the setting can be easily performed. Can be.
[0014]
Here, it is preferable that the schedule information setting means sets the schedule information to an initial set value when the receiving means receives radio waves and correct time information is obtained.
With this configuration, even if the reception interval is long, when the radio wave is received, the schedule information is automatically returned to the initial set value, and thereafter, the radio wave is received at the interval of the initial set value. Return to the normal operating state. That is, once a radio wave can be received, there is a high possibility that the next radio wave can be received. Therefore, if the radio wave is successfully received once, it is possible to return to the original once-a-day reception. Since the time can be adjusted by receiving the radio wave, the time can be displayed with extremely high accuracy.
[0015]
Here, the power supply control means may stop the periodic operation of the reception power supply when the elapsed time becomes equal to or longer than a second set time longer than the set time.
For example, assuming that the set time is 7 days and the second set time is 20 days, if the elapsed time is 7 days or more, first the schedule information is longer than the initial set value (received once every 5 days). Is set to On the other hand, when the elapsed time has passed 20 days or more, the periodic operation of the receiving power supply unit is stopped, and the periodic power supply to the receiving unit is completely stopped. In this case, the receiving means is not operated until the user performs a predetermined operation to perform forcible reception, so that power consumption by the reception operation is eliminated and energy saving can be further achieved. Therefore, especially in the case of a battery-powered timepiece, the battery life can be extended.
[0016]
The radio-controlled timepiece of the present invention is a clock means for measuring the current time based on a reference clock, a current time display means for displaying the measured current time, and a receiving means for receiving a radio wave including time information, A radio wave comprising: a receiving power control means for periodically operating a receiving power means for driving the receiving means; and a current time correcting means for correcting the current time of the clock means based on the time information received by the receiving means. In the modified watch,
Power generation means for generating power from external energy, and power storage means for storing power generated by the power generation means, the reception power control means, power generation detection means for detecting the presence or absence of power generation in the power generation means, An elapsed time detecting means for obtaining an elapsed time from when the previous radio wave was received; a schedule information setting means for setting schedule information for setting an operation time interval when the reception power supply means is periodically operated; and Power supply control means for controlling the operation of the reception power supply means based on the information, wherein the schedule information setting means detects that the elapsed time is equal to or longer than a set time and that power generation has been performed once after the measurement of the elapsed time has started. If the schedule information is not set, the schedule information whose operation time interval is longer than the initial set value is set. And switches.
[0017]
Also in the present invention as described above, in normal times, the clock means counts the reference clock to measure the current time, and the current time is displayed by the current time display means.
On the other hand, the receiving power control means operates the receiving power means periodically based on the schedule information to supply power to the receiving means and drive the receiving means. During this operation, radio waves are received, and when the radio waves are received and the time information is correct, the current time is corrected by the current time correction means based on the time information.
On the other hand, if radio waves cannot be received during the regular reception operation, the time is not adjusted.
When the reception failure state continues, the time since receiving the previous radio wave detected by the elapsed time detecting means has elapsed for a set time or more, and no power generation has been detected since the start of the elapsed time measurement. Then, the schedule information setting means sets the schedule information to schedule information having an operation time interval (power supply time interval) longer than an initial set value. For example, if the initial set value is one day, it is set to five days. Therefore, thereafter, the receiving power control unit drives the receiving unit based on the schedule information (for example, 5 days) having a long operation time interval, and tries to receive radio waves.
[0018]
For this reason, when the power generation unit does not generate power and the radio wave reception is not successful, for example, when a watch equipped with a solar cell as a power generation unit is left in a drawer of a desk, the reception interval is long. Therefore, power consumption can be reduced accordingly. Therefore, the duration of the clock in a state where no power is generated can be extended. In addition, when power is being generated, the radio wave reception interval is maintained as usual, so that the probability of radio wave reception increases, and the time indication accuracy of the clock can be maintained high.
[0019]
Here, the reception power supply control unit includes a reception schedule storage unit in which the schedule information is stored, and the schedule information setting unit determines the elapsed time and the presence / absence of power generation from a plurality of preset reception schedule information. It is preferable that the schedule information is selected and stored in the reception schedule storage unit, and the power supply unit control unit controls the operation of the reception power supply unit based on the schedule information stored in the reception schedule storage unit. .
If a reception schedule storage unit is provided to store a plurality of pieces of schedule information, the degree of freedom in setting a schedule is high and the schedule can be easily set.
[0020]
Further, it is preferable that the schedule information setting means sets the schedule information to an initial set value when the receiving means receives a radio wave and correct time information is obtained.
When the radio wave is received, the schedule information is automatically returned to the default value.After that, the radio wave is received at the interval of the default value, so that it is possible to return to the normal operation state and receive the radio wave. Since the time can be adjusted by the user, the time can be displayed with extremely high accuracy.
[0021]
Further, the schedule information setting means may set the schedule information to an initial set value when the power generation detection means detects the presence of power generation.
If the presence of power generation is detected, the necessity for energy saving is reduced. Therefore, by performing radio wave reception at intervals of the initial setting value, it is possible to improve the time instruction accuracy.
[0022]
Further, the power supply control means may stop the periodic operation of the reception power supply when the elapsed time becomes equal to or longer than a second set time longer than the set time.
In this case, since the receiving unit is not operated, power consumption by the receiving operation is eliminated, and energy saving can be further achieved. Note that it is preferable that the stopped state of the receiving means is configured to be canceled when the user performs forcible reception or when power generation is detected.
[0023]
Preferably, the elapsed time detecting means resets the elapsed time and measures again when the power generation detecting means detects the presence of power generation.
If the elapsed time is reset and re-measured at the time of power generation detection, the period until the transition to the schedule change state is further extended, so that the reception processing in the initial schedule can be continued, and the time indication can be accurately performed. Can be maintained.
[0024]
The radio-controlled timepiece of the present invention is a clock means for measuring the current time based on a reference clock, a current time display means for displaying the measured current time, and a receiving means for receiving a radio wave including time information, A radio wave comprising: a receiving power control means for periodically operating a receiving power means for driving the receiving means; and a current time correcting means for correcting the current time of the clock means based on the time information received by the receiving means. In the modified timepiece, the reception power control unit includes an elapsed time detection unit that determines an elapsed time from when a previous radio wave was received, and schedule information that defines an operation time interval when the reception power unit is periodically operated. Schedule information setting means for setting, and power supply means control means for controlling operation of the reception power supply means based on the schedule information, wherein the power supply means control means Characterized by stopping the driving of said receiving means to stop regular operation of the reception power supply means and the elapsed time is equal to or greater than the set time.
[0025]
The radio-controlled timepiece of the present invention is a clock means for measuring the current time based on a reference clock, a current time display means for displaying the measured current time, and a receiving means for receiving a radio wave including time information, A radio wave comprising: a receiving power control means for periodically operating a receiving power means for driving the receiving means; and a current time correcting means for correcting the current time of the clock means based on the time information received by the receiving means. The modified timepiece has a power generating means for generating power from external energy, and a power storage means for storing the power generated by the power generating means, and the receiving power control means is configured to receive a signal from a time when a previous radio wave was received. An elapsed time detecting means for obtaining time, a power generation detecting means for detecting the presence or absence of power generation in the power generating means, and an operation time when the reception power supply means is periodically operated. Schedule information setting means for setting schedule information that determines the following: power supply means control means for controlling the operation of the reception power supply means based on the schedule information, the power supply means control means, the elapsed time is equal to or more than a set time And if the presence of power generation is not detected even once after the start of the measurement of the elapsed time, the periodic operation of the reception power supply unit may be stopped to stop the driving of the reception unit. .
Here, the power supply control means restarts the periodic operation of the reception power supply when the power generation is detected by the power generation means while the periodic operation of the reception power supply is stopped. Is preferred.
[0026]
In each of these inventions, for example, if the set time is 20 days, after 20 days or more, the receiving power supply unit stops, and the periodic power supply (power) to the receiving unit is completely stopped. Stopped. In this case, for example, the receiving means is not operated until the user performs a predetermined operation to perform forcible reception, or when the power generation means is provided, the power generation is detected. Power consumption due to operation is eliminated, and more energy saving can be achieved. Therefore, especially in the case of a battery-powered timepiece, the battery life can be extended.
[0027]
Here, the radio-controlled timepiece is provided with an external operation input unit for performing an external operation, and the reception power control unit is configured to receive the reception power when the forced reception is instructed by the operation of the external operation input unit. It is preferred to activate the means.
By operating such an external operation input unit to perform forced reception, even if the time interval of the reception operation is long or the reception means is completely stopped, the user can Radio wave reception can be performed. If the radio wave reception is successful, the elapsed time returns to the set time or less, so that the control mode for increasing the reception interval and the control mode for not performing any automatic reception are automatically canceled. Therefore, it is not necessary to separately perform the release operation, so that the operability can be improved.
[0028]
Further, the elapsed time detecting means may include an elapsed time measuring means for measuring an elapsed time from when the time information is received by the receiving means using the reference clock.
According to such a configuration, the elapsed time can be measured by counting the same reference clock as that of the clock means, so that the parts can be shared with the clock means and the elapsed time can be detected by the counter value for counting the reference clock. Since the calculation processing and the like are unnecessary, the elapsed time can be easily obtained.
[0029]
Further, the elapsed time detecting means includes a receiving time storing means for storing time information received by the receiving means, and a receiving time information stored in the receiving time storing means and a current time measured by the timing means. It is preferable that the information processing apparatus further includes an elapsed time calculation unit that calculates a time difference and calculates an elapsed time after the reception unit receives the time information.
According to such a configuration, the elapsed time can be calculated from the difference between the current time of the timer and the time at which the time information is received only when the reception processing is executed and the elapsed time needs to be obtained. The increase can be suppressed.
[0030]
A first control method for a radio-controlled timepiece according to the present invention includes a timekeeping step of measuring the current time based on a reference clock, a current time display step of displaying the measured current time, and a radio wave including time information. In a method for controlling a radio-controlled timepiece including a receiving step of receiving and a current time correction step of correcting the current time based on the time information received in the receiving step, the receiving step is periodically performed based on set schedule information. Receiving control step to perform the same, an elapsed time detecting step to determine the elapsed time from when the previous radio wave was received, and when the elapsed time is equal to or longer than a set time, the execution time interval of the schedule information is longer than an initial set value. And a schedule information setting step of switching to long schedule information.
[0031]
A second control method for a radio-controlled timepiece according to the present invention includes a timekeeping step of measuring the current time based on a reference clock, a current time display step of displaying the measured current time, and a radio wave including time information. A method for controlling a radio-controlled timepiece comprising a receiving step of receiving, and a current-time correction step of correcting a current time based on the time information received in the receiving step, wherein the radio-controlled timepiece generates power using external energy. Power generation means, and a power storage means for storing power generated by the power generation means, a reception control step of periodically executing the reception step based on set schedule information, and a previous radio wave. An elapsed time detecting step of obtaining an elapsed time from the time of reception, a power generation detecting step of detecting the presence or absence of power generation in the power generating means, and the elapsed time being longer than a set time. And a schedule information setting step of switching the schedule information to schedule information having an execution time interval longer than an initial set value when power generation is not detected once after the start of measurement of the elapsed time. Things.
[0032]
A third control method of the radio-controlled timepiece according to the present invention includes a timekeeping step of measuring the current time based on a reference clock, a current time display step of displaying the measured current time, and a radio wave including time information. In a method for controlling a radio-controlled timepiece comprising a receiving step of receiving and a current time correction step of correcting the current time based on the time information received in the receiving step, the receiving step is performed based on set schedule information. Reception control step, and an elapsed time detection step of obtaining an elapsed time from the time of receiving the previous radio wave, the reception control step, when the elapsed time exceeds a set time, the reception step The execution may be stopped.
[0033]
A fourth control method for a radio-controlled timepiece according to the present invention includes a timekeeping step of measuring the current time based on a reference clock, a current time display step of displaying the measured current time, and a radio wave including time information. A method for controlling a radio-controlled timepiece comprising a receiving step of receiving and a current-time correction step of correcting the current time based on the time information received in the receiving step, wherein the radio-controlled timepiece generates power from external energy A power generation means, and a power storage means for storing power generated by the power generation means, a reception control step of performing the reception step based on set schedule information, and a time when a previous radio wave is received. And a power generation detection step of detecting the presence or absence of power generation in the power generation means, wherein the reception control step includes: When the after starting the constant time or more to become and the elapsed time measurement is also available power once is not detected, may be characterized in that stops execution of the reception step.
[0034]
According to the first control method, the same operation and effect as the first aspect of the invention can be obtained. Further, according to the second control method, the same operation and effect as the fifth aspect of the invention can be obtained. According to the third control method, the same operation and effect as the above-mentioned invention can be obtained. Further, according to the fourth control method, the same function and effect as the twelfth invention can be obtained.
[0035]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
(1st Embodiment)
FIG. 1 is a diagram showing a configuration of a radio-controlled timepiece 1 according to the first embodiment.
The radio-controlled timepiece 1 is of an analog display type, and includes a receiving unit 2 as a receiving unit for receiving wireless information (standard radio wave) including time information, a reference signal generating unit 3 for generating a reference clock, and an entire apparatus. , A display unit 5 as current time display means for displaying time and the like, a drive control unit 6 for controlling the drive of the display unit 5 in response to a command from the control circuit 4, and an external operation And an external operation input unit 7 for performing the operation.
[0036]
The receiving unit 2 receives an antenna 21 that receives a standard radio wave including time information, a receiving circuit 22 that processes (amplifies, demodulates, etc.) the time information received by the antenna 21, and a time information based on the signal processed by the receiving circuit 22. And a reception power supply circuit 24 for supplying power to the reception circuit 22. Therefore, the receiving power supply circuit 24 drives the receiving section 2 as the receiving means, and the receiving power supply circuit 24 corresponds to the receiving power supply means of the present invention.
[0037]
The antenna 21 is constituted by a ferrite antenna or the like in which a coil is wound around a ferrite rod.
The receiving circuit 22 is configured to receive a radio wave with the antenna 21. The receiving circuit 22 includes an amplifying circuit, a band-pass filter, and a demodulating circuit (not shown). The receiving circuit 22 shapes the waveform of the received radio wave, demodulates the radio wave, and outputs it to the decoding circuit 23 as a rectangular pulse representing a time code. The decoding circuit 23 converts this pulse signal and outputs it to the control circuit 4 as time information (time code) composed of digital data.
[0038]
Here, as the standard radio wave including the time information, Japan's long wave standard radio wave (JJY) or the like can be used. In the time code format of the long-wave standard radio wave, one signal is transmitted every second, and one minute (60 seconds) is configured as one record (one frame). That is, one frame is 60-bit data. Further, the data items include the minute and hour of the current time, the total day from January 1 of the current year, the year (last two digits of the Christian era), the day of the week, and leap second. Note that there is no second item because the time information is time data of 0 seconds per minute. The value of each item is constituted by a combination of numerical values assigned for each second, and ON / OFF of this combination is determined from the type of signal.
[0039]
The reference signal generation unit 3 includes an oscillation circuit 31 including a crystal oscillator and the like, and a frequency division circuit 32 that divides a pulse from the oscillation circuit 31 to generate a reference clock (1 Hz or the like). ing. The generated reference clock is output to the control circuit 4.
[0040]
As shown also in FIG. 2, the control circuit 4 includes a current time information storage unit 41 as a clock unit, a current time correction unit 42 for correcting the current time of the clock unit, and a power supply of the receiving unit as a reception power control unit. The control means 43 is provided. That is, in the present embodiment, the receiving section power supply control means 43 corresponds to the reception power control means of the present invention.
[0041]
The current time information storage means 41 performs a clocking step of counting the reference clock generated by the reference signal generation unit 3 and measuring the current time. The current time measured by the current time information storage means 41 is output to the display unit 5 and displayed.
When the time information received by the receiving unit 2 is input, the current time correction unit 42 performs a current time correction step of correcting the current time based on the time information. At this time, the current time correction unit 42 determines whether the time information received by the receiving unit 2 is accurate. Whether or not the received time information is accurate is determined by, for example, receiving a plurality of frames (usually two to three frames) of the time information transmitted at one-minute intervals in the case of a long-wave standard radio wave. The determination is made based on whether or not the time information has a predetermined time difference. For example, when each piece of time information is received continuously, it is determined whether each piece of time information is time information at one-minute intervals.
If it is determined that the received time information is accurate, a new current time is obtained by adding the time elapsed from the time of reception to the time information, and the current time correction means 42 uses the current time to determine the current time. The current time in the time information storage means 41 is overwritten and corrected.
[0042]
The receiving section power supply control means 43 includes an elapsed time detection means 110, a schedule information setting means 120, a reception schedule storage means 130, and a power supply circuit control means 140.
[0043]
The elapsed time detecting means 110 includes an elapsed time measuring means 111 for measuring an elapsed time (elapsed days) after the time is adjusted by the current time adjusting means 42.
When the current time correction unit 42 corrects the time, the elapsed time measurement unit 111 starts measuring in response to the signal, and outputs one day (24 hours) from the current time information storage unit 41 at intervals of one day (24 hours). The elapsed time (elapsed days) is counted by a signal and measured. The counted number of the one-day signal is reset and re-counted by the time correction signal from the current time correction means 42, that is, the signal that the radio wave is successfully received. The elapsed time from the reception of the previous radio wave to the present is counted.
[0044]
The schedule information setting means 120 is configured to cause the reception schedule storage means 130 to store schedule information corresponding to the elapsed time obtained by the elapsed time detection means 110 from preset schedule information.
In this embodiment, as will be described later, schedule information A for receiving a standard radio wave once a day, schedule information B for receiving once every five days, and schedule information C for not receiving a radio wave are used. The type of schedule information is set.
Then, the schedule information setting means 120 selects the schedule information A as the initial set value and stores it in the reception schedule storage means 130, but the elapsed time obtained by the elapsed time detection means 110 is equal to the set time (first setting value). When the time becomes 7 days (168 hours) or more, the schedule information B is selected and stored in the reception schedule storage means 130. When the elapsed time becomes 20 days or more (480 hours) which is the second set time, The schedule information C is selected and stored in the reception schedule storage means 130.
[0045]
The reception schedule storage means 130 sets and stores each schedule information selected by the schedule information setting means 120, and maintains the schedule information unless new schedule information is reset by the schedule information setting means 120. It is configured.
In the initial setting, radio waves are received at 2:00 am, etc., when the operation of electric appliances is few and radio wave reception conditions are good. When schedule information A is set, radio wave reception is performed at 2:00 am every day. Is set to perform Similarly, when the schedule information B is set, it is set to receive radio waves at 2:00 am every five days.
[0046]
The power supply circuit control means 140 controls the operation of the reception power supply circuit 24 based on the schedule information stored in the reception schedule storage means 130, and controls the supply of power (electric power, electric energy) to the reception circuit 22. Therefore, the power supply circuit control means 140 corresponds to the power supply control means of the present invention. The schedule information is, specifically, information that defines an operation time interval when the reception power supply circuit 24 is periodically operated.
Note that the power supply circuit control means 140 is set so as to stop the reception power supply circuit 24 and end the reception operation after a predetermined time has elapsed after the operation of the reception power supply circuit 24. The time during which the reception power supply circuit 24 is operated and the radio wave is received may be set as appropriate for the implementation, but usually, in the standard radio wave which is one frame (one information) in one minute, each radio wave has noise. In order to judge whether or not the signal does not include an erroneous signal, time information of a plurality of frames of about 2 to 6 is received.
[0047]
The display unit 5 is an analog type and includes a dial 51 having a scale, an hour hand 52, a minute hand 53, and a second hand 54. The hour hand 52, the minute hand 53, and the second hand 54 are driven by drive means such as a stepping motor, and are driven and controlled by a command from the control circuit 4 via the drive control unit 6. The display unit 5 constitutes a current time display unit.
[0048]
The drive control unit 6 receives a command from the control circuit 4 and outputs a pulse signal for driving the hands (hour hand 52, minute hand 53, second hand 54) of the display unit 5; It comprises a hand position detecting circuit 62 for detecting the positions of the minute hand 53 and the second hand 54).
The drive control circuit 61 drives the stepping motor based on the motor drive pulse output from the current time information storage means 41 every time the current time in the current time information storage means 41 is counted up by one and added by one second. Then, each pointer is operated.
The external operation input unit 7 includes a crown 71 and a button switch 72. The operation of the crown 71 and the button switch 72 can be determined by the states of the switches RM1, RM2, and S1.
For example, when the crown 71 is at the 0th stage, both the switches RM1 and RM2 are open. In the first stage, the switch RM1 is set to GND (ground), and in the second stage, the switch RM1 is set to OPEN and the RM2 is set to GND. In the present embodiment, the crown 71 is set to a normal current time display at the 0th stage, and when the button switch 72 is turned on at the 0th stage, the standard radio wave is forcibly received by manual operation.
[0049]
The operation of the radio-controlled timepiece 1 having such a configuration will be described with reference to the flowcharts of FIGS.
The receiving section power supply control means 43 of the control circuit 4 determines whether or not there is an instruction for the reception processing of the standard radio wave during the normal operation and whether the instruction is the forced reception or the automatic reception in the flowchart of FIG. Is checked based on the mode determination process shown in FIG. That is, first, it is determined whether or not there is an instruction for forced reception by a button operation (Step 1, hereinafter, step is abbreviated as “S”).
Here, when there is no forced reception instruction ("No" in S1), it is determined whether the automatic reception flag is "1", that is, whether the automatic reception mode is set (S2). Note that the initial value of this automatic reception flag is “1”, and is set to “0” when reception is stopped in the flowchart of FIG. 4 described later.
If the automatic reception flag is "0", that is, if the reception is stopped, the mode determination process ends (S3).
On the other hand, if the automatic reception flag is "1" and the mode is the automatic reception mode, it is determined whether or not the time of the reception schedule set in the reception schedule storage means 130, that is, the automatic reception time has come (S4). Here, if it is not the automatic reception time, the mode determination processing ends (S3).
[0050]
When it is determined in S4 that the automatic reception time has come, and when it is determined in S1 that the forced reception instruction has been issued, the reception process shown in FIG. 4 is executed by the reception control process.
In the reception processing shown in FIG. 4, first, the reception power supply circuit 24 is operated by the power supply circuit control means 140, and the reception circuit 22 is turned on (S11).
When the receiving circuit 22 is operated, the standard time signal is received by the antenna 21, and the time data (time information) is stored in the current time correcting means 42 via the receiving circuit 22 and the decoding circuit 23 (S12). That is, the receiving step is performed.
When the power supply circuit control means 140 activates the reception circuit 22 for about three minutes and receives the time information of three frames, it stops the reception power supply circuit 24 and turns off the reception circuit 22 (S13).
[0051]
The current time correction means 42 checks whether the stored time information is accurate time data and determines whether the reception was successful (S14). Specifically, whether the stored time data is not a non-existent time or day such as 68 minutes, for example, and whether each time data represents the expected time, If the time data is received, it is predicted that the time data is every minute. Therefore, it is determined whether each data has such time. To determine whether the reception was successful.
[0052]
If the reception is determined to be successful in S14, a signal instructing the start of the elapsed time measurement is output from the current time correction unit 42 to the elapsed time measurement unit 111, and the elapsed time measurement unit 111 starts measuring the elapsed time and outputs the elapsed time. The detection step is started (S15).
Then, when the reception is successful, the schedule information A (once / one day) which is an initial setting value is set in the reception schedule stored in the reception schedule storage unit 130 (S16). In addition, in order to perform regular automatic reception of the standard radio wave, "1" is set to the automatic reception flag (S17).
The current time correction means 42 rewrites the contents of the current time information storage means 41 based on the time information of the received radio wave, corrects the current time display on the display unit 5 via the drive control circuit 61, and corrects the current time. The step is executed (S18).
Subsequent automatic radio wave reception is performed once a day based on the schedule information A. Then, when the radio wave reception fails in S14, such as when the radio wave reception state is deteriorated or when the radio wave correction clock 1 is placed in a place where the reception conditions are poor, the schedule information setting means 120 With reference to the elapsed time information counted by the elapsed time measuring means 111, it is determined whether or not the elapsed time from the reception of the radio wave is 20 days or more (S20).
[0053]
Here, if the elapsed time is less than 20 days, it is further determined whether or not the elapsed time is 7 days or more (S21). Here, when seven days or more have elapsed (that is, when the elapsed time is seven days or more and less than 20 days), the schedule information setting unit 120 sets the schedule information stored in the reception schedule storage unit 130 to the initial setting value ( The schedule information is updated from the schedule information A) to the schedule information B, and the schedule information setting step is executed (S22). This schedule information B is schedule information in which the power supply time interval is longer than the rate of radio wave reception once every five days, that is, the initial setting value.
For this reason, the radio wave automatic reception process that has been performed once a day is performed once every five days.
[0054]
If it is determined in S21 that less than seven days have elapsed, the schedule information is not updated, and the radio wave reception process is performed once a day.
Further, if it is determined in S20 that 20 days or more have elapsed, the automatic reception flag is set to "0", that is, the automatic reception stop mode is set (S23).
In the automatic reception stop mode, radio wave reception is not performed unless forced reception (S1) is instructed.
[0055]
To summarize the above reception processing, radio waves are received once a day during normal times, but radio waves are received once every five days if seven days have elapsed since the last reception without radio waves being received. . Further, if 20 days have elapsed since the last reception without receiving radio waves, the reception of radio waves is stopped.
The radio wave reception mode once every five days is canceled if the standard radio wave can be received at the time of the radio wave reception or the forced reception, and returns to the original once-a-day reception mode.
Further, the reception stop state is canceled when the user can perform the forced reception and receive the standard radio wave.
[0056]
According to this embodiment, the following effects can be obtained.
(1) The power supply circuit control means 140 that controls power supply to the receiving circuit 22 starts the radio wave reception process once a day when the elapsed time after receiving the standard radio wave exceeds the set time (7 days). Since the processing is changed to once every five days, the frequency of the reception processing can be reduced. If the radio wave cannot be received for 7 days, the radio wave correction clock 1 is usually left in a place where radio waves are difficult to receive, such as in a building, or when the radio wave cannot be received during overseas travel or business trip. Therefore, even if reception is continued once a day, the possibility of reception failure is high, and wasteful reception processing is performed and power is consumed.
On the other hand, in the present embodiment, radio waves are received once every five days and at five times the time interval, so that the frequency of the radio wave reception processing is reduced, and the power consumption can be reduced accordingly. For example, the wristwatch can greatly extend the battery life.
Note that the radio-controlled timepiece 1 performs the same hand movement control as a normal quartz watch during a time when radio waves cannot be received, so that accuracy of about ± 20 seconds per month can be normally secured. There is no problem with use. If a radio wave is received, the time can be adjusted to a more accurate time at that time, so that the accuracy can be further improved.
As described above, according to the present embodiment, the interval (frequency) of the reception processing can be changed depending on whether or not radio waves are received, so that it is possible to provide the radio-controlled timepiece 1 which is particularly excellent in energy saving and has a long battery life.
[0057]
(2) Further, when the elapsed time is equal to or longer than the second set time (20 days), the power supply circuit control means 140 stops the automatic reception of the standard radio wave and performs the radio wave reception processing until the forced reception by the manual operation is performed. Since it is not performed, the power consumption can be further suppressed, and the battery life can be further greatly extended especially in a battery-powered wristwatch or the like. Similarly, energy saving can be achieved in the case of a timepiece that uses commercial power from an outlet.
[0058]
(3) Since the elapsed time detecting means 110 is constituted by the elapsed time measuring means 111 which counts the reference clock from the time when the radio wave reception succeeds, the elapsed time information is always recorded in the elapsed time measuring means 111. That is, it is only necessary to directly check the data, so that the elapsed time can be easily checked.
[0059]
(2nd Embodiment)
Next, a second embodiment of the present invention will be described with reference to FIGS. The same or similar components as those of the first embodiment are denoted by the same reference numerals, and description thereof will be omitted or simplified.
The radio-controlled timepiece 1A according to the second embodiment is different from the radio-controlled timepiece 1 in that a power generation means 8 and a power storage means 9 are provided. The difference is that the control means 43 is provided. Other configurations are the same as those of the radio-controlled timepiece 1 of the first embodiment, and a description thereof will not be repeated.
[0060]
The power generation means 8 may be any device that generates electric power (electric energy) by generating electric power by using some external energy as an input. For example, a solar cell that converts solar energy into electric energy, and converts mechanical stress into electric energy. Piezoelectric elements (piezo elements), stray electric wave generators that convert stray radio waves to electric energy, thermoelectric generators that convert temperature differences to electric energy, electric generators that convert mechanical energy such as rotating weights and springs to electric energy, etc. Can be used.
The power storage means 9 is configured by a device capable of storing power such as a capacitor or a secondary battery.
[0061]
The power generation detection means 150 detects the presence or absence of a power generation state by detecting the voltage value of the power generation voltage of the power generation means 8, that is, the charging voltage of the power storage means 9, and generates power when the voltage of the power storage means is equal to or higher than the set voltage. (Power generation detection flag = 1).
[0062]
It should be noted that the power generation detection means 150 is not limited to the one that is determined based on the charging voltage of the power storage means 9. For example, the voltage generated by the power generation means 8 may be detected, and the determination may be made based on whether the voltage is equal to or higher than the set voltage. If the power generation state of the power generation means 8 is set to be equal to or longer than the set time for power generation detection within a predetermined period, for example, 24 hours (1 day) as the predetermined period and 10 minutes as the set time for power generation detection, 1 If there is a power generation state for 10 minutes or more per day, it may be determined that there is power generation, and if less than 10 minutes, it may be determined that there is no power generation. Note that the time (10 minutes) in the power generation state may be a continuous time, but usually may be a cumulative time.
Further, the presence or absence of power generation may be determined based on whether or not the charging voltage gradient = charging voltage / time is equal to or greater than a predetermined gradient.
In short, the power generation detection unit 150 can determine whether the radio wave reception schedule can be returned to the initial setting because the necessary power is obtained by the power generation unit 8 and the radio wave reception processing is not hindered. Just fine.
[0063]
The operation of the radio-controlled timepiece 1A according to this embodiment will be described with reference to the flowcharts of FIGS.
FIG. 7 is a flowchart of the mode determination process similar to FIG. 3 of the first embodiment. The receiving section power supply control means 43 of the control circuit 4 first determines whether or not there is an instruction for forced reception by operating a button, as in the first embodiment (S31).
[0064]
Here, when there is no forcible reception instruction, the power generation detecting means 150 executes a power generation detection step of determining whether or not there is power generation (S32). If it is determined that power generation is present, the automatic reception flag is set to "1" (S33), and the power generation detection flag is also set to "1" (S34). Note that, similarly to the first embodiment, the initial value of the automatic reception flag is “1”, and is set to “0” when reception is stopped in a flowchart of FIG. 8 described later. Therefore, even when the automatic reception flag is set to “0” and the reception stop mode is set, the mode is forcibly released when “power generation is detected” is detected, and the automatic reception mode (automatic reception flag = 1) is set. Move to
On the other hand, the power generation detection flag is initially set to “0” indicating no power generation, and is set to “1” when it is determined that power generation is performed. This power generation detection flag is returned to the initial value “0” when the measurement of the elapsed time starts, as described later.
[0065]
When it is determined in S32 that there is no power generation, it is determined whether the automatic reception flag is "1", that is, whether the automatic reception mode is set (S35). If the automatic reception flag is "0", that is, if the reception is stopped, the mode determination processing ends (S36).
On the other hand, if the automatic reception flag is determined to be "1" in S35, or if power generation is determined to be performed in S32, it is determined whether or not the automatic reception time has come (S37). Here, if it is not the automatic reception time, the mode determination processing ends (S36).
[0066]
When it is determined in S37 that the automatic reception time has come, and when it is determined in S31 that the forced reception instruction has been issued, the reception process shown in FIG. 8 is executed. In FIG. 8, the processes from the receiving circuit ON (S41) to the successful reception (S44) and the respective processes S45 to S48 when “Yes” is determined in S44 are the same processes as S11 to S18 in FIG. Therefore, the description is omitted.
In the present embodiment, when the reception is successful, the process of initializing the power generation detection flag (S49) is performed along with the processes of S45 to S48. In other words, the power generation detection flag indicates whether or not the presence of power generation has been detected after the start of the elapsed time measurement, and thus needs to be initialized each time the elapsed time measurement is restarted.
[0067]
On the other hand, if the radio wave reception has failed in S44, it is determined whether the power generation detection flag is “1” (S50).
Here, if it is determined that “power generation detection flag = 0 (no power generation)”, the schedule information setting unit 120 calculates the elapsed time information counted by the elapsed time measurement unit 111 as in the first embodiment. It is determined with reference to whether or not the elapsed time from the reception of the radio wave is 20 days or more (S51).
If the elapsed time is less than 20 days, it is determined whether the elapsed time is 7 days or more (S52), and if the elapsed time is 7 days or more (that is, the elapsed time is 7 days or more, 20 days) If less than the above, the schedule information setting means 120 updates the schedule information stored in the reception schedule storage means 130 from the initial set value (schedule information A) to the schedule information B as in the first embodiment (S53).
For this reason, the radio wave automatic reception process that has been performed once a day is performed once every five days.
[0068]
If it is determined in S52 that less than seven days have elapsed, the schedule information is not updated, and the radio wave reception process is performed once a day.
Further, if it is determined in S51 that 20 days or more have elapsed, the automatic reception flag is set to "0", that is, the automatic reception stop mode is set (S54).
In this automatic reception stop mode, except when the forced reception (S1) is instructed, or when the automatic reception flag is changed to 1 and the automatic reception stop mode is canceled by determining that "there is power generation" in S32, Radio wave reception will not be performed.
If it is determined in S50 that "power generation detection flag = 1 (power generation is present)", the elapsed time measuring means 111 restarts the measurement of the elapsed time (S55), and returns the power generation detection flag to "0". (S56).
[0069]
According to this embodiment, the same operation and effect as those of the first embodiment can be obtained.
Further, (4) the power generation means 8 and the power generation detection means 150 for detecting the presence or absence of power generation of the power generation means 8 are provided. If power generation is performed, the automatic reception flag is returned to "1" in S33 and received. If processing is performed and power generation occurs even when reception fails, the elapsed time measurement is restarted in S54, so that the reception schedule at regular one-day intervals can be continued. That is, if there is power generation, the necessity of extending the reception interval for energy saving is reduced, so that it is possible to give priority to improving the time accuracy by radio wave reception over energy saving, and to bring out the characteristics of the radio-controlled timepiece 1A. it can. On the other hand, when there is no power generation, for example, in a timepiece with a built-in solar cell, if it is placed in a desk and is not generating power, it automatically switches to the energy saving mode as in the first embodiment. Can be migrated. Therefore, when the required power is obtained by the power generation means 8, the time reception accuracy can be improved by giving priority to the radio wave reception processing. By extending the interval, the duration of the clock can be lengthened, and it is possible to provide a radio-controlled timepiece 1A having excellent time indication accuracy and duration.
[0070]
(5) In the first embodiment, when the automatic reception flag becomes “0”, the automatic reception stop mode cannot be canceled unless the forced reception is performed and the reception is successful. , S32, if it is determined that there is power generation, the automatic reception flag is set to “1”, and the reception stop mode can be released. For this reason, it is possible to automatically return to the automatic reception mode, and the radio-controlled timepiece 1A having excellent handleability can be obtained.
[0071]
Note that the present invention is not limited to each embodiment, and modifications, improvements, and the like within a range that can achieve the object of the present invention are included in the present invention.
For example, as shown in FIG. 9, the elapsed time detecting means 110 may calculate the difference between the reception time and the current time to obtain the elapsed time. That is, the reception time storage unit 112 that stores the reception time (correction time) input from the current time correction unit 42, the reception time stored in the reception time storage unit 112, and the current time from the current time information storage unit 41. The difference from the time information, that is, the elapsed time may be calculated by the elapsed time calculation means 113. In this case, the elapsed time calculation means 113 may be operated only when calculating the elapsed time, so that there is an advantage that power consumption can be reduced. That is, in the radio-controlled timepiece 1, since the reception is basically performed once a day, the schedule information setting unit 120 may also determine the elapsed time once a day. Therefore, the elapsed time calculation means 113 only needs to calculate the elapsed time once a day, and the power consumption can be reduced accordingly.
[0072]
In the above-described embodiment, when the elapsed time is equal to or longer than the second set time (20 days), the receiving circuit 22 is controlled to stop. However, the stop processing of the receiving circuit 22 is not provided. , 20 days or more, the reception mode may be continued, for example, once every five days. If the receiving circuit 22 is completely stopped, the power consumption will be reduced accordingly. However, if the radio wave reception is performed about once every five days, the power consumption can be reduced as compared with the case where the radio wave is received every day. Therefore, the effect of prolonging the battery life can be ensured to some extent. Also, since automatic reception is performed about once every five days, radio wave reception can be automatically resumed without any operation by the user, and operability can be improved accordingly.
[0073]
Further, in the above-described embodiment, only two types of schedule information for performing radio wave reception are set: schedule information A for once-a-day reception and schedule information B for once-a-day reception. Furthermore, schedule information of other time intervals, such as once every two days, once every seven days, once every ten days, etc., may be provided. Then, a plurality of set times are also provided, and when the elapsed time from the previous radio wave reception becomes equal to or longer than each set time, each schedule information may be sequentially switched to information having a longer time interval.
In particular, when the reception stop mode is eliminated, for example, when the elapsed time becomes 20 days or more, it is preferable to reduce the power consumption by setting a reception schedule once every 10 days.
In the above-described embodiment, the radio wave is received every day until seven days have elapsed. However, for example, the reception is changed to once every two days after three days, and once every five days after seven days. Alternatively, the reception interval may be changed.
[0074]
Further, as the schedule information set by the schedule information setting means 120, only two types of schedule information A, which is an initial set value, which is once / day, and schedule information C, which is a reception stop, can be set. Only when the elapsed time is 20 days or more (S20), the radio reception is stopped with the automatic reception flag = 0, and otherwise, the reception processing is performed based on the schedule information A for one time / one day. May be performed.
Also, the schedule information setting means 120 selects the schedule information according to the elapsed time and the presence or absence of power generation from a plurality of schedule information set in advance. It may have an operation unit for calculating schedule information.
[0075]
Further, the radio-controlled timepiece 1 may be provided with an elapsed time display means for displaying an elapsed time so that the user can grasp how long the user has been unable to receive the radio wave at present. As this elapsed time display means, for example, the mode is switched to the elapsed time display mode using a crown or a button, and the scale of the dial is indicated by the second hand 54 indicating that one second indicates the passage of one day. It suffices to provide a liquid crystal screen on the dial and display the elapsed days in numbers. If such elapsed time display means is provided, the user can easily grasp the number of days during which radio waves cannot be received, and the user has not adjusted the time by radio wave reception. There is an advantage that the point of accuracy can be grasped.
[0076]
Similarly to the second embodiment, the battery-powered time correction clock without the power generation means 8 is provided with the voltage detection means for detecting the voltage of the battery, and if the battery voltage is equal to or higher than the set voltage, the elapsed time measurement is restarted. It may start or return the automatic reception flag to “1”.
In the second embodiment, the power generation detecting means 150 is provided to detect the presence or absence of power generation by the power generation means 8. However, for example, the presence or absence of power generation is detected by detecting the external energy supplied to the power generation means 8 itself. May be detected. For example, in the case of a thermoelectric generator, the temperature difference may be detected by a thermometer or the like, and if the temperature difference is equal to or more than the predetermined temperature difference, it may be determined that predetermined power generation can be obtained and it may be determined that there is power generation. When mechanical energy such as a mainspring is input, the determination may be made according to the amount of winding of the mainspring.
[0077]
Each unit in the control circuit 4 is constituted by hardware such as various logic elements or a computer (microcomputer) having a CPU (central processing unit), a memory (storage device) and the like. 1, and may be configured such that a predetermined program or data (data stored in each storage unit) is incorporated in the computer to realize each unit.
For example, a CPU and a memory are arranged in the radio-controlled timepiece 1 so as to function as a computer, and a predetermined control program and data are stored in the memory in communication means such as the Internet, a CD-ROM, a memory card, or the like. What is necessary is just to install via a medium, operate a CPU etc. by this installed program, and implement each means.
In order to install a predetermined program or the like in the radio-controlled timepiece 1, a memory card, a CD-ROM, or the like may be directly inserted into the radio-controlled timepiece 1, or an apparatus for reading these storage media may be externally provided. May be connected to the radio-controlled timepiece 1. Further, a LAN cable, a telephone line, or the like may be connected to the radio-controlled timepiece 1 to supply and install a program or the like by communication, or since the antenna 21 is provided, a program may be supplied and installed wirelessly. Is also good.
[0078]
If the control program or the like provided by such a recording medium or communication means such as the Internet is incorporated in the radio-controlled timepiece 1, the functions of the inventions described above can be realized only by changing the program. The control program to be executed can be selected and incorporated. In this case, various radio-controlled timepieces 1 having different control formats can be manufactured only by changing the program, so that parts can be used in common and the like, and the manufacturing cost when developing variations can be greatly reduced.
[0079]
The functions of the radio-controlled timepiece, that is, the respective components such as the timekeeping means, the receiving means, and the time correction means are not limited to those of the above-described embodiment, and each means of the conventionally known radio-controlled timepiece can be used.
[0080]
Further, the radio-controlled timepiece 1 of the present invention is not limited to an analog timepiece, but may be a digital timepiece or a timepiece having both an analog display hand and a digital display liquid crystal display unit. Further, the radio-controlled timepiece 1 can be applied to various timepieces such as a portable timepiece such as a wristwatch and a pocket watch, and a stationary timepiece such as a wall clock and a table clock.
[0081]
[Other embodiments of the present invention]
Other aspects of the present invention are described below.
A control program for a radio-controlled timepiece according to a first aspect includes a clock unit for measuring a current time based on a reference clock, a current time display unit for displaying the measured current time, and a radio wave including time information. Receiving means for receiving, receiving power control means for periodically operating reception power means for driving the receiving means, and current time correction for correcting the current time of the clock means based on the time information received by the receiving means Means, a computer incorporated in the radio-controlled timepiece having the means, an elapsed time detecting means for obtaining an elapsed time from the time when the previous radio wave was received, and an operating time interval for periodically operating the receiving power supply means. In addition to setting schedule information to be determined, when the elapsed time is equal to or longer than a set time, the schedule information is set to schedule information having an operation time interval longer than an initial set value. Switching schedule information setting means, and power supply means control means for controlling the operation of the reception power supply means based on the schedule information, wherein the reception power control means comprises an elapsed time detection means, schedule information setting means, power supply means It is characterized by comprising a control means.
[0082]
A control program for a radio-controlled timepiece according to a second aspect includes a clock means for measuring the current time based on a reference clock, a current time display means for displaying the measured current time, and a radio wave including time information. Receiving means for receiving, receiving power control means for periodically operating reception power means for driving the receiving means, and current time correction for correcting the current time of the clock means based on the time information received by the receiving means Means for generating electric power from external energy, and a computer incorporated in a radio-controlled timepiece including power storage means for storing the power generated by the power generation means. Power generation detecting means, an elapsed time detecting means for calculating an elapsed time from when the previous radio wave was received, and an operation when the receiving power supply means is periodically operated. In addition to setting the schedule information that determines the interval, if the elapsed time is equal to or longer than the set time and the presence of power generation has not been detected once after the measurement of the elapsed time has been started, the schedule information is set to the operation time longer than the initial set value. Schedule information setting means for switching to schedule information having a longer interval; and power supply means control means for controlling the operation of the reception power supply means based on the schedule information. It is characterized by comprising a detecting means, a schedule information setting means, and a power supply controlling means.
[0083]
A control program for a radio-controlled timepiece according to a third aspect includes a clock means for measuring the current time based on a reference clock, a current time display means for displaying the measured current time, and a radio wave including time information. Receiving means for receiving, receiving power control means for periodically operating reception power means for driving the receiving means, and current time correction for correcting the current time of the clock means based on the time information received by the receiving means Means, a computer incorporated in the radio-controlled timepiece having the means, an elapsed time detecting means for obtaining an elapsed time from the time when the previous radio wave was received, and an operating time interval for periodically operating the receiving power supply means. Schedule information setting means for setting schedule information to be determined; controlling operation of the reception power supply means based on the schedule information; and setting the elapsed time. When the time is equal to or more than a predetermined time, the receiving power supply means is caused to function as a power supply control means for stopping the periodic operation of the reception power means and stopping the driving of the receiving means, and the reception power control means is provided with an elapsed time detecting means, a schedule information setting means. And a power supply control means.
[0084]
A control program for a radio-controlled timepiece according to a fourth aspect includes a clock means for measuring the current time based on a reference clock, a current time display means for displaying the measured current time, and a radio wave including time information. Receiving means for receiving, receiving power control means for periodically operating reception power means for driving the receiving means, and current time correction for correcting the current time of the clock means based on the time information received by the receiving means Means, a power generation means for generating power from external energy, and a computer incorporated in a radio-controlled timepiece having power storage means for storing the power generated by the power generation means. Elapsed time detecting means for determining elapsed time, power generation detecting means for detecting the presence or absence of power generation in the power generating means, and operation when the receiving power supply means is periodically operated. Schedule information setting means for setting schedule information for determining a time interval, and controlling the operation of the reception power supply means based on the schedule information, and wherein the elapsed time is equal to or longer than a set time and has never been measured after the start of measurement of the elapsed time. When the presence of power generation is not detected, the power supply control means stops the operation of the reception power supply means and stops the driving of the reception means, and the reception power supply control means functions as the power generation detection means. , An elapsed time detecting means, a schedule information setting means, and a power supply means controlling means.
[0085]
A computer-readable recording medium storing the control program for the radio-controlled timepiece according to the fifth to eighth aspects is characterized by recording the control program according to the first to fourth aspects. is there.
[0086]
【The invention's effect】
As described above, according to the radio-controlled timepiece of the invention, useless power consumption can be suppressed, and power can be saved.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration of a first embodiment of a radio-controlled timepiece according to the present invention.
FIG. 2 is a block diagram illustrating a configuration of a control circuit according to the first embodiment.
FIG. 3 is a flowchart illustrating an operation of a mode determination process at the time of radio wave reception according to the first embodiment.
FIG. 4 is a flowchart showing an operation of a radio wave reception process of the first embodiment.
FIG. 5 is a diagram showing a configuration of a second embodiment of the radio-controlled timepiece according to the present invention.
FIG. 6 is a block diagram illustrating a configuration of a control circuit according to the second embodiment.
FIG. 7 is a flowchart illustrating an operation of a mode determination process at the time of radio wave reception according to the second embodiment.
FIG. 8 is a flowchart showing an operation of a radio wave reception process of the second embodiment.
FIG. 9 is a block diagram illustrating a configuration of a control circuit according to a modification of the present invention.
FIG. 10 is a flowchart illustrating an operation of a radio wave reception process according to a modified example of the present invention.
[Explanation of symbols]
1. . . Radio wave correction clock, 2. . . 2. receiving unit (receiving means); . . 3. a reference signal generator; . . Control circuit; 5. . . 5. display unit (current time display means); . . 6. drive control section; . . 7. external operation input unit; . . Power generation means, 9. . . Power storage means, 21. . . Antenna, 22. . . Receiving circuit, 23. . . Decoding circuit, 24. . . 30. receiving power supply circuit (receiving power supply means); . . Oscillator circuit, 32. . . Divider circuit, 41. . . 42. current time information storage means (clocking means); . . Current time correction means, 43. . . Receiving part power supply control means (reception power control means), 51. . . Dial, 52. . . Hour hand, 53. . . Minute hand, 54. . . Second hand, 61. . . Drive control circuit, 62. . . Needle position detection circuit, 72. . . Button switch, 110. . . Elapsed time detecting means, 111. . . Elapsed time measuring means, 112. . . Receiving time storage means, 113. . . Elapsed time calculating means, 120. . . Schedule information setting means, 130. . . Receiving schedule storage means, 140. . . Power supply circuit control means (power supply means control means), 150. . . Power generation detection means.

Claims (1)

Clock means for measuring the current time based on a reference clock; current time display means for displaying the measured current time; receiving means for receiving a radio wave including time information; and a receiving power source for driving the receiving means In a radio-controlled timepiece having a receiving power control means for periodically operating the means, and a current time correcting means for correcting the current time of the clocking means based on the time information received by the receiving means,
The reception power supply control means includes an elapsed time detection means for determining an elapsed time from when a previous radio wave was received, and schedule information for setting schedule information for determining an operation time interval when the reception power supply means is periodically operated. Setting means, and power supply means control means for controlling the operation of the reception power supply means based on the schedule information,
The schedule information setting means switches the schedule information to schedule information having an operation time interval longer than an initial set value when the elapsed time is equal to or longer than a set time,
The radio-controlled timepiece includes an elapsed time display unit that displays the elapsed time obtained by the elapsed time detection unit.

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