JP2004257977A - Radio correction watch and control method thereof - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a radio correction watch for improved workability in manufacture as well as productivity at a lower cost for easy operation. <P>SOLUTION: If a user pulls a crown 212 while a second hand points 0 o'clock to change a display time to such state as 0 o'clock is pointed as an initial state, and then presses in the crown 212, an input operation recognizing means 460 recognizes it as a prescribed operation. A pointer position data initializing circuit 447 resets the counter value of a pointer position counter 446 to the initial value of 0 o'clock 0 minute 0 second. A reception means receives a long frequency standard radio to obtain a time code. Based on the reference signal outputted from a dividing circuit 444 at the oscillation signal from a quartz oscillation circuit 443, a time data comparing circuit 448 counts a current time from the time code, and compares it with the initial value to recognize a difference from the count value. Based on the difference, a pulse control circuit 445 makes correction for a current time. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a radio-controlled timepiece and a control method of the radio-controlled timepiece.
[0002]
[Background Art]
2. Description of the Related Art In recent years, a radio-controlled timepiece that receives a radio wave (a long-wave standard radio wave) including time information and automatically corrects and displays the time based on the time information has been used. In particular, conventional radio-controlled timepieces have mainly been clocks (table clocks and wall clocks), but have recently been incorporated in portable watches (watches, etc.).
In the pointer-type radio-controlled timepiece, for example, the pointer position is changed to a predetermined initial position, for example, 12:00, and the counter value is set to an initial value by a predetermined operation of initial setting. Then, the initial value and the time information based on the long-wave standard radio wave are compared, and the pointer position is corrected so that the initial value becomes the time information. Various methods are adopted as a method of setting the initial position of the pointer at the time of the initial setting (for example, see Patent Document 1).
[0003]
In the method of setting the initial position described in Patent Document 1, a hole is provided in each of the gears for moving the hour, minute, and second hands, and the hour, minute, and second hand points to 12 o'clock in a state where each hole is located on a straight line. Make up. Then, a configuration is adopted in which light from the light source passes through a hole located on a straight line between the light source and the light receiving sensor and is detected by the light receiving sensor to recognize that the pointer position is at 12:00.
However, with the configuration described in Patent Document 1, the work of providing holes in a small and sophisticated gear used for a watch, for example, is extremely complicated. In addition, the work of providing holes and the assembling work in a state where the holes of the respective gears are located in a straight line with the hour, minute, and second hands pointing to 12 o'clock are extremely complicated. For this reason, it is not possible to improve manufacturing workability, productivity, and cost. Further, the light source and the light receiving sensor must be arranged to face each other in the stacking direction of the overlapping gears, so that the size cannot be reduced. In addition, power consumption for operating the configuration for recognizing the pointer position by operating the light source and the light receiving sensor is also required separately, and when a battery is used as the power source, the usable time may be shortened.
[0004]
In addition, as a method of setting the initial position, a method using button input is also conceivable. According to the button input method, the user inputs and sets that the initial position is to be set by operating a predetermined button. Then, another predetermined button is pushed to operate the stepping motor to move the hour / minute / second hand to a predetermined hand position. Thereafter, the initial position of the hour, minute, and second hand is set by, for example, pressing another button or pressing a button for setting an initial position for a predetermined time or more.
However, this button input method requires a plurality of buttons, and the appearance is complicated. For example, when there are other buttons for operating various functions such as a stopwatch function and a backlight function, the appearance becomes particularly complicated, and the button arrangement becomes difficult, so that productivity is improved and cost is reduced. I can't. In addition, there is a risk of erroneous operation due to a plurality of buttons. In particular, since the button arrangement differs for each model and the operation method may also differ, the user must confirm the operation content for each model so as not to make an erroneous operation, and the use may be complicated. There is also.
[0005]
[Patent Document 1]
JP-A-5-209970 (page 3, left column-page 5, right column)
[0006]
[Problems to be solved by the invention]
As described above, in the method of setting the initial position in the conventional radio-controlled timepiece as described in Patent Document 1, it is necessary to assemble the gears for moving the hour, minute and second hands with high accuracy by providing holes. Therefore, it is not possible to improve the manufacturability and reduce the cost, and it is not possible to reduce the size due to restrictions on the configuration. Further, there is a possibility that the power consumption increases and the usable time cannot be shortened.
Further, in the method using button input, a plurality of buttons are required, so that it is not possible to improve the productivity and reduce the cost, and there is a risk of erroneous operation. Furthermore, the appearance may be complicated.
[0007]
SUMMARY OF THE INVENTION In view of the foregoing, it is an object of the present invention to provide a radio-controlled timepiece that can improve manufacturing workability and productivity, reduce costs, and is easy to operate, and a control method thereof.
[0008]
[Means for Solving the Problems]
A radio-controlled timepiece according to a first aspect of the present invention includes a receiving unit that receives a standard radio wave including time information, a clock unit that measures time based on a reference signal from a reference signal source, a hand that displays the time, Drive means for moving the hands based on time, storage means for storing the time, a crown that can and cannot change the display time displayed by the hands by a predetermined input operation, The input operation recognizing means for recognizing the predetermined input operation, and the input operation recognizing means recognizing a predetermined input operation for switching the display time by the crown from a changeable state to a non-changeable state. Setting means for storing a predetermined time in the means.
[0009]
In the present invention, the display time displayed by the hands with respect to the time measured by the timekeeping means based on the reference signal from the reference signal source can and cannot be changed by a crown in response to a predetermined input operation. Make it possible. A predetermined input operation for switching the display time from a state in which the display time can be changed to a state in which the display time cannot be changed by the crown is recognized by the input operation recognition means. With this recognition, the predetermined time is stored in the storage means for storing the time by the setting means.
[0010]
Then, in order to correct the time displayed by the hands based on the standard radio wave, it is necessary to recognize the state of the hands. For example, by setting a pointer state at a predetermined display time to a predetermined initial state, and setting an initial value corresponding to the initial state, the display time of the initial state displayed by the pointer is correctly corrected to the current time. Becomes possible. As the setting of the initial state, an initial value corresponding to the initial state is set at the time of a predetermined input operation of a commonly used crown that is operated to change the display time to a predetermined time by hands. As a result, the display time can be easily recognized as an initial state corresponding to the initial value without providing a special configuration, and the display time can be corrected to the current time based on the standard time signal. The operability and cost can be easily improved, and the initial state can be easily set by an operation such as changing the display time, so that the operability is improved.
[0011]
Here, in the first invention, it is preferable that the predetermined time stored in the storage means is a count value corresponding to a pointer position of 00:00:00.
[0012]
In such a configuration, a configuration that uses a count value corresponding to a pointer position of 00: 00: 00: 00, which is normally used as a configuration for correcting the display time to the current time, can be diverted, and cost can be reduced. In addition, the operability is further improved by setting the count value corresponding to, for example, 0:00 (12:00), at which the display time changed at the crown is easy, as the initial value.
[0013]
Further, when the input operation recognizing unit recognizes the predetermined input operation for changing the display time by the crown from the state in which the display time can be changed to the state in which the display time cannot be changed, the control unit controls the receiving unit to receive the standard radio wave. Receiving control means, and a comparing means for recognizing a difference situation between a current time based on the received standard time signal and a predetermined time stored in the storage means when the reception of the standard time signal is successful by the receiving means. It is preferable that the information processing apparatus further includes a time correcting means for changing the display time to the current time based on the difference situation recognized by the comparing means.
[0014]
Here, in the first invention, when the input operation recognizing means recognizes the predetermined input operation for changing the display time by the crown from a state in which the display time is changeable to a state in which the display time is not changeable, Reception control means for controlling reception of a standard radio wave, and comparison means for recognizing a difference between a current time based on the received standard radio wave and the initial value by recognizing the predetermined input operation by the input operation recognition means. And a time adjusting means for changing the display time to the current time based on the difference status recognized by the comparing means.
[0015]
In such a configuration, when the input operation recognizing unit recognizes a predetermined input operation of the crown that changes the display time from the state in which the display time can be changed to the state in which the display time cannot be changed, the reception control unit transmits the standard radio wave including the time information to the receiving unit. , And the comparison means recognizes the difference between the current time based on the successfully received standard time signal and the predetermined time stored in the storage means by a predetermined input operation. Then, the display time is changed to the current time based on the recognized difference situation. As a result, based on a predetermined input operation of the crown to change the display time to the pointer position corresponding to the predetermined time, a standard radio wave is acquired, and the display time is corrected based on a difference from the current time. The time is easily and correctly corrected to the current time.
[0016]
Then, the time adjusting means drives the driving means to move the hands, and changes the display time to the current time until the predetermined time stored in the storage means becomes the same as the current time. Is preferred.
[0017]
In such a configuration, the display time is changed to the current time by driving the driving means and moving the hands by the time correcting means until the predetermined time stored in the storage means becomes the same as the current time. This makes it possible to easily correct the display time to the current time with a simple configuration.
[0018]
Further, it is preferable that the reception control means stops the hand movement by the driving means when the reception means receives the standard radio wave.
[0019]
In such a configuration, when the reception control means causes the receiving means to receive the standard radio wave, the hand movement of the hands by the driving means for displaying the display time by the hands is stopped. This prevents interference with reception due to hand movement, for example, due to the generation of a magnetic field accompanying the driving of a step motor or the like, and facilitates reception of standard radio waves.
[0020]
It is preferable that the reception control means stop or continue the hand movement by the driving means when the reception of the standard radio wave by the reception means fails.
[0021]
In such a configuration, when the reception control unit fails to receive the standard time signal, the driving unit stops or continues the hand movement by the driving unit. As a result, since the hand movement is not started, for example, the user can recognize that the reception has failed without using a separate configuration.
[0022]
Further, it is preferable that the input operation recognizing means starts the hand movement by the driving means by recognizing a predetermined input operation for changing the display time by the crown from a changeable state to a non-changeable state.
[0023]
In such a configuration, when the input operation recognizing means recognizes a predetermined input operation for changing the display time of the crown from a changeable state to a non-changeable state, the movement of the hands by the driving means is started. Thus, the display time is corrected to the current time and the hand movement is started. After the correction, the display of the current time is continued, and the accurate time can be displayed. Also, for example, even if the display time cannot be corrected to the current time due to a failure to receive the standard time signal, by changing the display time to the current time by performing a crown input operation, a predetermined input operation can be performed. The hand movement is continued from that point in time, and the inconvenience that the time cannot be displayed is also prevented.
[0024]
Further, the reception control means, when the reception of the standard radio wave by the reception means fails, the input operation recognition means sets the display time by the crown from a changeable state to a non-changeable state. It is preferable that by recognizing the input operation, the hand operation by the driving means is started, and the reception of the standard radio wave by the receiving means is stopped until the input operation recognizing means recognizes the predetermined input operation again.
[0025]
In such a configuration, when the receiving unit fails to receive the standard radio wave, the input operation recognizing unit recognizes a predetermined input operation that changes the display time of the crown from the state in which the display time can be changed to the state in which the display time cannot be changed. Then, the hand control by the driving means is started by the reception control means. Further, the reception control means stops the reception of the standard radio wave by the reception means until the input operation recognition means recognizes the predetermined input operation again. This makes it possible to function as a clock even when the current time cannot be recognized due to the failure to receive the standard time signal, and until the pointer position is initialized by a predetermined input operation again. Is not started, and the hand position is corrected by correcting the hand position by receiving the standard radio wave in a state where the initial setting of the hand position is not performed.
[0026]
The storage means includes a hand position counter for storing the time as a count value corresponding to a pointer position, and the time keeping means outputs a 1 Hz pulse signal based on a signal output from the reference signal source to the hand. A pulse control circuit that outputs the count value to the position counter and adds the count value for each second, and the setting unit sets the count value corresponding to the pointer position as the predetermined time stored in the storage unit. A hand position data initializing circuit, wherein the input operation recognizing means recognizes a predetermined input operation for switching the display time from a changeable state to a non-changeable state by the crown, and the hand position data initializing circuit; It is preferable to include a crown operation recognizing means for setting the count value stored in the storage means to the count value.
[0027]
In such a configuration, when the crown operation recognition unit of the input operation recognition unit recognizes a predetermined input operation for switching the display time from the state in which the display time can be changed to the state in which the display time cannot be changed, the needle position data of the setting unit is initialized. The count value corresponding to the pointer position stored in the needle position counter of the storage means is set by the conversion circuit. This simplifies the configuration for correcting the display time to the current time by correcting the count value corresponding to the pointer position as the count value corresponding to the current time.
[0028]
A time data storage circuit for storing information on a time received based on the standard radio wave received by the receiving means, wherein the storage means stores the time as a count value corresponding to a pointer position; A position control unit, wherein the timing unit includes a pulse control circuit that outputs a 1-Hz pulse signal to the hand position counter based on a signal output from the reference signal source and adds the count value for one second. The comparing means includes a current time counter that stores a count value corresponding to the time stored in the time data storage circuit, and calculates a time difference between the count value of the current time counter and the count value of the hand position counter. It is preferable to recognize.
[0029]
In such a configuration, a count value corresponding to the time stored in the time data storage circuit based on the standard time signal received by the receiving means is stored in the current time counter of the comparing means, and the count value of the current time counter is stored by the comparing means. The time difference between the count value to be executed and the count value of the hand position counter is recognized. As a result, the display time can be correctly corrected to the current time with a simple configuration.
[0030]
Further, the setting means recognizes a predetermined input operation for changing the display time to a predetermined time by the crown and switching the display time to a state in which the display time cannot be changed, and the input means recognizes the storage means. Preferably, a predetermined time is stored in the storage area.
[0031]
In such a configuration, when the input operation recognizing means recognizes a predetermined input operation for changing the display time to the predetermined time by the crown and switching the display time to an unchangeable state, the predetermined time is stored in the storage means. Let it. Thus, the display time is changed at a predetermined time at the crown, and a predetermined input operation for switching to a state in which the display time cannot be changed easily matches the predetermined time stored in the storage means for correcting the time. can get.
[0032]
A method for controlling a radio-controlled timepiece according to a second invention is a control method for a radio-controlled timepiece that corrects a measured time based on a standard time signal including time information at which a display time indicated by a hand is received. Recognize a predetermined input operation for changing the display time from a changeable state to a non-changeable state of the crown, which is changeable and non-changeable by a predetermined input operation, and counts the time by recognizing the predetermined input operation. The time is set to a predetermined time.
[0033]
A method for controlling a radio-controlled timepiece according to a third aspect of the present invention is a control method for a radio-controlled timepiece that corrects a measured time based on a standard radio wave including time information at which a display time indicated by a pointer is received. By recognizing a predetermined input operation for changing the display time to a state in which the display time cannot be changed after the display time is changed to a predetermined time by the operation of the crown, the time to be measured is set to the predetermined time. It is a feature.
[0034]
According to the control methods of the radio-controlled timepiece of the second and third inventions, the same operation and effect as those of the first invention can be obtained.
[0035]
In the second invention, it is preferable that the predetermined set time is a count value corresponding to a pointer position of 00:00:00.
Further, when the predetermined input operation for changing the display time from the state in which the display time can be changed to the state in which the display time cannot be changed by the crown is recognized, the standard radio wave is received. It is preferable that a difference situation between a time and the set predetermined time is recognized, and the display time is changed to the current time based on the recognized difference situation.
Further, it is preferable that the display time is changed to the current time by moving the hands until the predetermined time to be set becomes the same as the current time.
Then, it is preferable to stop the movement of the hands when receiving the standard radio wave.
Further, when the reception of the standard radio wave fails, it is preferable to stop or continue the movement of the hands.
In addition, it is preferable to start the hand operation by recognizing a predetermined input operation by the crown to change the display time from a changeable state to a non-changeable state.
Then, the time to be measured is stored as a count value corresponding to the pointer position, and the stored count value is counted by adding 1 second at a time with a 1 Hz pulse signal, and the display time by the crown can be changed. It is preferable that the predetermined time is set by resetting a count value by recognizing a predetermined input operation for switching to an unchangeable state.
Further, the time to be measured is stored as a count value corresponding to the pointer position, and the stored count value is counted by adding 1 second at a time with a 1 Hz pulse signal, and the time received based on the standard radio wave and the 1 Hz are counted. It is preferable to count the current time on the basis of the pulse signal and to recognize the time difference between the current time to be counted and the count value corresponding to the pointer position.
Furthermore, when the reception of the standard radio wave fails, the hand movement is started by recognizing a predetermined input operation for changing the display time from a changeable state to a non-changeable state, and the predetermined input operation is performed again. It is preferable to stop receiving the standard radio wave until the recognition.
When the display time is changed by the crown and a predetermined input operation for switching to a state where the display time cannot be changed is recognized, it is preferable that the time to be measured is set to a predetermined time.
[0036]
According to such a configuration, the same operation and effect as those of the other aspects of the first invention described above can be obtained.
[0037]
BEST MODE FOR CARRYING OUT THE INVENTION
[First Embodiment]
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings.
In the first embodiment, a so-called analog timepiece that has an hour hand, a minute hand, and a second hand and displays the time by a hand will be described. However, the present invention does not have a second hand or has a calendar function. The present invention can be applied to a device having a clock, and can be applied to both a clock and a watch.
[0038]
[Configuration of radio-controlled watch]
FIG. 1 is a partially cutaway plan view showing a state in which a crown of a radio-controlled timepiece 100 according to a first embodiment of the present invention is depressed. FIG. 2 is a partially enlarged view of FIG. FIG. 3 is a partially cutaway plan view showing a state in which the crown of the radio-controlled timepiece 100 is pulled out. FIG. 4 is a partially enlarged view of FIG.
1 and 3, reference numeral 100 denotes a radio-controlled timepiece, and the radio-controlled timepiece 100 includes a case (not shown). The case body includes a main plate 110, a dial (not shown) attached to the main plate 110 covering the front of the main plate 110, a glass case not shown attached to the main plate 110 covering the dial, and a main plate covering the rear surface of the main plate 110. And a lid (not shown) attached to the main body 110. The dial is not limited to the one on which the numerical value representing the time is displayed, but may be any one such as a plain one having no numerical value, a one on which various characters are printed, and the like. Furthermore, a configuration without a dial may be used.
[0039]
In addition, a battery accommodating space 112 in which, for example, a button battery 111 serving as a power supply is detachably provided is provided in the base plate 110 of the case body. The battery accommodating space 112 is opened facing the outside with the lid removed and the back surface of the base plate 110 opened.
Further, a circuit board on which an IC (Integrated Circuit) constituting various control means (not shown) for controlling the operation of the entire radio-controlled timepiece 100 and various electric components are provided in the case body.
Further, a step motor 120 as a driving means is disposed in the case body. The drive of the step motor 120 is controlled by being connected to a circuit board. The step motor 120 includes a coil block 121, a motor stator 122, and a motor rotor 123. The coil block 121 includes a magnetic core 121A and a coil 121B wound around the magnetic core 121A. The motor stator 122 has a substantially plate-like shape connected to both ends of the coil block 121 in the axial direction, and has a cylindrical rotor arrangement hole 122A at a substantially center. The motor rotor 123 is made of a permanent magnet magnetized to two poles, and is disposed in the rotor arrangement hole 122A of the motor stator 122.
Further, an antenna 130 for receiving a long-wave standard radio wave on which time information is superimposed is arranged in the case body. As the antenna 130, for example, a ferrite antenna formed by winding a coil around a ferrite rod is used. The antenna 130 is connected to a circuit board.
[0040]
Further, a drive transmission means 140 for transmitting the drive of the step motor 120 to the hour hand 117, the minute hand 118 and the second hand (not shown) serving as hands is provided in the case body. The drive transmission means 140 includes a fifth wheel & pinion 141, a fourth wheel & pinion 142, a third wheel & pinion 143, a second wheel & pinion 144, an hour wheel 145, and a minute wheel & pinion 146.
The fifth wheel & pinion 141 is engaged with the pinion 123A of the motor rotor 123. The fourth wheel & pinion 142 is engaged with the pinion 141A of the fifth wheel & pinion 141. A second hand is attached to the fourth wheel & pinion 142 to move the second hand. The third wheel & pinion 143 engages with the pinion 142A of the fourth & fourth wheel & pinion 142. The center wheel & pinion 144 is coaxially supported with the center wheel & pinion and engages with the pinion 143A of the center wheel & pinion 143. A minute hand is attached to the second wheel & pinion 144, and the fourth wheel & pinion 142 makes one rotation so as to rotate 6 ° via the third wheel & pinion 143, that is, to move the minute hand by one minute. The hour wheel & pinion 145 is coaxially supported with the fourth wheel & pinion 142 and the second wheel & pinion 144, and has an hour hand attached thereto. The minute wheel & pinion 146 is engaged with the pinion 144A of the center wheel & pinion 144, and the pinion 146A is engaged with the hour wheel 145. Then, when the second wheel & pinion 144 makes one rotation, the hour wheel 145 rotates 30 ° via the minute wheel 146, that is, the hand moves for one hour.
[0041]
Further, a display time changing unit 200 is provided in the case body. The display time changing means 200 changes the display time as the time displayed by the hour and minute hands by a predetermined input operation. The display time changing means 200 has an external operation member 210 and an operation transmitting means 220 for transmitting an input operation of the external operation member 210 to the hour and minute hands.
The external operating member 210 has a substantially elongated rod-shaped winding stem 211. The winding stem 211 is provided with a crown (not shown) having a large diameter at one end in the axial direction and having irregularities on the peripheral surface. The external operation member 210 is disposed on the main plate 110 so as to be able to push and pull along the axial direction with the crown positioned outside the main plate 110.
[0042]
The operation transmitting means 220 includes a setting 221, a latch 222, a latch presser 223, a ratchet wheel 224, a small iron wheel 225, and a minute wheel 226.
The posterior 221 is rotatably disposed on the main plate 110 by a shaft member 221 </ b> A, and one end of the pivoting end is engaged with the stem 211 of the external operation member 210. That is, it rotates in response to the push / pull operation of the winding stem 211. Further, a positioning pin 221B and an engaging pin 221C are protruded from the posterior 221.
[0043]
The latch 222 is rotatably disposed on the main plate 110 in correspondence with the grip 221 on the shaft member 221A. The latch 222 is provided with two engagement recesses 222A1 and 222A2 to which the positioning pin 221B of the lever 221 can be disengaged. That is, when the positioning pin 221B is engaged with the engagement recess 222A1, the winding stem 211 of the external operation member 210 is in a pushed-in state shown in FIGS. Further, in a state in which the winding stem 211 is engaged with the engaging recess 222A2, the winding stem 211 is in a pulled-out state shown in FIGS. As described above, the winding stem 211 can be operated in two stages, and gives a click feeling to the user who operates when changing the engagement state.
When the radio-controlled timepiece 100 has a calendar function, for example, another engaging recess may be provided so that the winding stem 211 can be operated in three stages.
[0044]
The latch retainer 223 is rotatably disposed on the main plate 110 with a shaft pin 223A. The latch retainer 223 is provided with a plate spring-shaped urging portion 223B that abuts against the base plate 110 at one end side that rotates and urges the one end side in a direction to be separated from the base plate 110. The other end of the latch presser 223 is rotatably contacted with the other end of the pivoting lever 221 so as to be able to contact and separate from the other end, and is rotated against the urging of the urging portion 223B. By the urging of the urging portion 223B, the winding stem 211 is kept in the pushed-in state shown in FIGS. 1 and 2 at all times.
[0045]
The ratchet wheel 224 is formed in a cylindrical shape into which the winding stem 211 of the external operation member 210 is slidably fitted. That is, the pinwheel 224 is disposed so as to be movable in the axial direction of the winding stem 211 and rotate with the rotation of the winding stem 211. The pawl wheel 224 is engaged with the other end of the latch pusher 223 that rotates. Then, the pinwheel 224 is moved to a state where the winding stem 211 is pulled out, and the grip 221 is rotated, and the latching presser 223 abuts on the rotating weight 221 to rotate. Moved to the opposite side of the crown.
[0046]
The small wheel & pinion 225 is engaged with the moving wheel & pinion 224 by the operation in the state shown in FIGS. 3 and 4 in which the winding stem 211 is pulled out. Thus, the small iron wheel 225 is rotated by the continuous wheel 224 that rotates with the rotation of the winding stem 211 by the rotation operation of the crown.
[0047]
The minute wheel & pinion 226 is engaged with the small wheel & pinion 225, and is rotated by the rotation of the winding stem 211 via the continuous wheel & pinion wheel 225 and the small wheel & pinion 225. The minute wheel & pinion 226 engages with the minute wheel & pinion 146, rotates the hour wheel 145 and the second wheel & pinion 144 via the minute wheel & pinion 146, and rotates the minute hand and the hour hand. That is, when the winding stem 211 is rotated in the pulled-out state, the hour and minute hands are rotated, and the displayed time is changed. In the state where the winding stem 211 is pushed in, the engagement between the small iron wheel 225 and the continuous wheel 224 is released, so that even if the winding stem 211 is rotated, the displayed time, which is the pointer state by the hour and minute hands, is not changed. .
[0048]
The operation transmitting means 220 is provided with a reset lever 300. The reset lever 300 is rotatably supported on the main plate 110 by a shaft 301. Further, the reset lever 300 is provided with a guide groove 300 </ b> A on one end side on which the engagement pin 221 </ b> C of the fastening 221 is engaged. Then, the reset lever 300 is turned by the turning of the pushing lever 221. A terminal portion 300B is provided on the other end of the reset lever 300 that rotates. The reset lever 300 is disposed in a state where the terminal portion 300B is inserted into the hole 115 formed in the main plate 110 with its tip inserted into the hole 115. The reset lever 300 is rotated to one edge 115A or the other edge 115B of the hole 115. Contact. An electrode (not shown) connected to the circuit board is provided in the hole 115 of the base plate 110, and the contact state of the terminal 300B of the reset lever 300 can be detected. The drawer state can be detected.
The reset lever 300 and the electrodes arranged in the hole 115 of the main plate 110 constitute a crown operation detecting means described later.
[0049]
[Internal configuration of radio-controlled watch]
Next, the internal configuration of the radio-controlled timepiece 100 described above, that is, the configuration of various circuits mounted on a circuit board will be described with reference to the drawings. FIG. 5 is a block diagram showing the internal configuration of the radio-controlled timepiece 100. FIG. 6 is a block diagram showing a detailed configuration of the control circuit.
[0050]
5 and 6, reference numeral 400 denotes control means mounted on a circuit board. The control means 400 performs time measurement and time correction of the radio-controlled timepiece 100. The control means 400 includes a motor drive circuit 410, a reception circuit 420, a time data storage circuit 430, and a control circuit 440.
[0051]
The motor drive circuit 410 controls the drive of the step motor 120. The motor drive circuit 410 is connected to the control circuit 440 and is controlled by the control circuit 440.
Specifically, a pulse signal is output from the control circuit 440 at a timing of, for example, 1 Hz, and the step motor 120 is driven based on the pulse signal. By the step motor 120 driven at the timing of 1 Hz, the second hand, minute hand 118 and hour hand 117 (not shown) move, that is, the second hand rotates by 6 °, which is one second and minute, via the drive transmitting means 140 and corresponds to the second hand. The minute hand 118 and the hour hand 117 are also driven to rotate.
When a fast-forward pulse signal of, for example, 128 Hz is output from the control circuit 440, the step motor 120 is driven based on the fast-forward pulse signal. The step motor 120 driven and controlled by the motor drive circuit 410 which has received the fast-forward pulse signal moves the hands in the fast-forward state.
[0052]
The receiving circuit 420 includes a tuning circuit (not shown) including a tuning capacitor and the like. The receiving circuit 420 is configured to cause the antenna 130 to receive the long-wave standard radio wave of the frequency set by the tuning circuit. For example, in Japan, the long-wave standard radio waves to be received include a standard radio wave output station of Otakadoyama (East Japan) with a transmission frequency of 40 kHz and a standard radio wave output station of Haganeyama (West Japan) with a transmission frequency of 60 kHz. There are two types of frequencies.
The receiving circuit 420 includes an amplifying circuit, a band-pass filter, a demodulating circuit, a decoding circuit, and the like (not shown), and extracts time information, that is, time code, which is digital data, from the received long-wave standard radio wave. The extracted time code is output to the time data storage circuit.
Then, the antenna 130 and the receiving circuit 420 constitute the receiving means 450 of the present invention.
[0053]
The time data storage circuit 430 stores, for example, a time code output from the reception circuit 420 using a memory or the like. The time data storage circuit 430 is connected to the control circuit 440, and stores the time code so that the control circuit 440 can read out the time code as appropriate. As the storage of the time code, for example, the reception circuit 420 receives the time code a plurality of times, for example, three times every one minute, obtains the time code, and compares the times of the obtained time codes so that they all match or are set. The current time is recognized based on the coincidence of times exceeding a certain probability, and the current time is stored as time data such as 時 hour ○ minute 秒 second.
[0054]
The control circuit 440 controls the clock to be measured by the radio-controlled timepiece 100 and also controls the time as appropriate. The control circuit 440 includes a crown operation recognition means 441, a reception control circuit 442, a crystal oscillation circuit 443, a frequency dividing circuit 444, a pulse control circuit 445, a needle position counter 446 as storage means, and needle position data as setting means. An initialization circuit 447 and a time data comparison circuit 448 as comparison means are provided.
[0055]
The crown operation recognizing unit 441 is connected to the above-described reset lever 300 and the crown operation detecting unit 461 configured by an electrode disposed in the hole 115 of the main plate 110. Then, the crown operation recognition unit 441 recognizes the operation state of the crown 212 detected by the crown operation detection unit 461, and outputs a predetermined signal corresponding to the operation state of the crown 212.
Specifically, the state shown in FIGS. 3 and 4 in which the crown 212 of the external operation member 210 is pulled and the winding stem 211 is pulled out, that is, the hands are moved by rotating the crown 212 and the display time can be changed. 1 and FIG. 2 in which the crown 212 has been pressed and the winding stem 211 has been pressed, that is, the state in which the display time cannot be changed by operating the crown 212, and a predetermined operation is performed. The signal is output to the reception control circuit 442 and the pulse control circuit 445.
The crown operation recognizing means 441 and the crown operation detecting means 461 constituted by an electrode (not shown) provided in the hole 115 and a reset lever 300 which rotates in response to the operation of an external operation member are provided by the present invention. The input operation recognition means 460 is configured.
When the radio-controlled timepiece 100 is provided with a calendar function and the crown 212 can be operated in three stages, for example, the calendar displayed by the calendar function can be changed by one stage and the pointer position can be changed by two stages. Is changeable, the crown operation recognizing unit 441 recognizes that the display time can be changed when the display time is changed by two steps. In addition, the crown operation recognizing means 441 recognizes that the pointer position is not changed in a state where the pointer is not pulled or in a state where it is pulled one step, so that the state cannot be changed.
[0056]
The reception control circuit 442 controls the reception circuit 420 to receive the long-wave standard time signal and extract the time code. Further, the reception control circuit 442 performs control to store the time code acquired by the reception circuit 420 in the time data storage circuit 430.
[0057]
The crystal oscillation circuit 443 is connected to a reference signal source 443A such as a crystal oscillator. Then, the crystal oscillation circuit 443 causes the reference signal source 443A to oscillate at high frequency, and outputs an oscillation signal generated by the high frequency oscillation to the frequency dividing circuit 444.
[0058]
The frequency dividing circuit 444 is connected to the crystal oscillation circuit 443 and receives an oscillation signal output from the crystal oscillation circuit 443. Then, the frequency dividing circuit 444 divides the frequency of the received oscillation signal and outputs it to the pulse control circuit 445 and the time data comparing circuit 448 as a predetermined reference signal, for example, a signal of 1 Hz.
[0059]
The pulse control circuit 445 is connected to the frequency dividing circuit 444 and receives the reference signal output from the frequency dividing circuit 444. Then, the pulse control circuit 445 outputs a 1 Hz pulse signal to the motor drive circuit 410 in accordance with the received reference signal. The output of the pulse signal drives the motor drive circuit 410 to drive the step motor 120. Further, the pulse control circuit 445 can output a fast-forward pulse signal as described above.
Further, the pulse control circuit 445 outputs a pulse signal and a fast-forward pulse signal to the hand position counter 446. The process of driving the motor driving circuit 410 with the output of the pulse signal and the fast-forward pulse signal of the pulse control circuit 445 to move the hands is performed by the reception control circuit 442 when the reception means 450 receives the long-wave standard radio wave. , Control is performed so that the hand operation is stopped without outputting the pulse signal and the fast-forward pulse signal when receiving the long-wave standard radio wave.
Further, the pulse control circuit 445 recognizes that the crown 212 has been pulled out by the crown operation recognition means 441 and that the crown 212 has been pulled out as shown in FIGS. 3 and 4, and that the predetermined signal has been output. I do. With this recognition, the pulse control circuit 445 stops outputting the pulse signal to the motor drive circuit 410. That is, the step motor 120 is not driven when the crown 212 is pulled.
[0060]
The hand position counter 446 is formed of, for example, a memory, and is connected to the pulse control circuit 445. The hand position counter 446 stores the time measured based on the pulse signal and the fast-forward pulse signal from the pulse control circuit 445, for example, as a count value such as 時 hour 分 minute 秒 second.
Then, a clock means 470 in which the time is measured by the crystal oscillation circuit 443, the frequency dividing circuit 444, the pulse control circuit 445, and the hand position counter 446 is configured.
[0061]
The needle position data initialization circuit 447 is connected to the crown operation recognition means 441 and the needle position counter 446. The hand position data initialization circuit 447 receives the operation signal output from the crown operation recognition means 441, and upon receiving the operation signal, causes the hand position counter 446 to output an initial value as a count value corresponding to a predetermined time, for example, The hand position counter 446 stores 00:00:00 corresponding to the pointer position of 0 o'clock (12:00), that is, clears the count value. Note that the initial value is not limited to 00:00:00 corresponding to 0:00 (12:00), but may correspond to a pointer position such as 6:00, which is easy to adjust the time, such as 06:00:00. It may be a count value at a predetermined time.
[0062]
The time data comparison circuit 448 is connected to the hand position counter 446, the time data storage circuit 430, and the frequency dividing circuit 444. The time data comparison circuit 448 includes a current time counter 448A. The current time counter 448A is set as a count value such as, for example, 時 hour 分 minute 秒 second, corresponding to the time code based on the long-wave standard radio wave of the time data storage circuit 430.
Then, the time data comparison circuit 448 recognizes a difference situation that is a difference between the count value of the current time set by the current time counter 448A and the count value of the hand position counter 446, that is, a time difference. A difference status signal corresponding to the recognized time difference is output to the pulse control circuit 445. The pulse control circuit 445, which has recognized the difference status signal, causes the hand position counter 446 and the motor drive circuit 410 to output a fast-forward pulse signal corresponding to the difference status signal, as described above. To fast-forward. This fast-forward pulse signal is output until the count value of the hand position counter 446 becomes substantially the same as the count value of the current time recognized by the current time counter 448A. The pointer position displayed by the fast-forward of the pointer is moved to the pointer position corresponding to the current time and corrected.
As described above, the pulse control circuit 445 and the motor drive circuit 410 constitute the time adjustment means 480 of the present invention.
The time data comparison circuit 448 obtains a 1-Hz reference signal from the frequency dividing circuit 444 and performs a process of adding the count value of the current time counter 448A for one second, thereby always indicating the current time. Has become.
[0063]
[Operation of radio-controlled watch]
Next, the operation of time correction in the radio-controlled timepiece 100 having the above-described configuration will be described with reference to the drawings. FIG. 7 is a flowchart showing the operation of the time adjustment of the radio-controlled timepiece 100.
[0064]
When correcting the time, the hour hand 117, the minute hand 118, and the second hand are corrected so that the displayed time, which is the displayed time, is at a predetermined time, for example, an initial position where the pointer points to 0:00 (12:00). Specifically, first, the user pulls the crown 212 of the external operation member 210 to bring the winding stem into the pulled-out state shown in FIGS. The time can be corrected, for example, in the initial stage of using the radio-controlled timepiece 100, or after the button battery has been replaced, the hand position has changed due to a shock due to a fall or the like, and the hand position and the hand position counter are changed. The operation is performed in a state where the counter value 446 does not correspond to the counter value.
This pulling operation of the crown 212 is performed at the moment when the second hand points to “12” when the second hand is at the 0 o'clock position, that is, when the numerical value of “1” to “12” is printed on the dial. Stops at the position indicating “12”.
[0065]
Due to the pulling operation of the crown 212, the butting 221 whose one end is engaged with the winding stem 211 rotates about the shaft member 221A as a rotation axis. By the rotation of the lever 221, the other rotating end of the lever 221 comes into contact with the latch presser 223, and the latch presser 223 is rotated against the urging of the urging portion 223 </ b> B of the latch presser 223.
Further, by the rotation of the setting lever 222, the latch 222 also rotates in conjunction with the shaft member 221A as a rotation axis. Then, by the rotation of the latch 222, the positioning pin 221 </ b> B of the posterior 221 shifts from the state of engagement with the engagement recess 222 </ b> A <b> 1 of the latch 222 to the state of engagement with the engagement recess 222 </ b> A <b> 2.
[0066]
Further, with the rotation of the setting lever 221, the engagement pin 221 </ b> C relatively slides in the guide groove 300 </ b> A of the reset lever 300 with which the engagement pin 221 </ b> C is engaged, and the reset lever 300 rotates about the shaft 301 as a rotation axis. Due to the rotation of the reset lever 300, the terminal portion 300B comes into contact with the other edge 115B from one edge 115A of the hole 115 of the main plate 110.
When the terminal portion 300B of the reset lever 300 comes into contact with the other edge 115B, as shown in FIG. 7, the crown operation detecting means 461 detects the contact state. Then, the crown operation recognizing unit 441 of the control circuit 440 recognizes, based on the signal from the crown operation detecting unit 461, that the crown 212 is pulled out and the winding stem 211 is pulled out as shown in FIGS. (Step S1).
[0067]
When the crown operation recognizing unit 441 recognizes that the crown 212 has been pulled, the pulse control circuit 445 stops outputting the pulse signal to the motor drive circuit 410 and stops the hand operation by driving the step motor 120. (Step S2).
[0068]
Further, when the latch presser 223 is rotated by the pulling operation of the crown 212, the pinwheel 224 engaging with the latch presser 223 moves to the tip end side opposite to the crown 212 along the axial direction of the winding stem 211. Is done. This movement of the ratchet wheel 224 causes the ratchet wheel 224 to engage with the small iron wheel 225.
In this state, when the user rotates the crown 212, the small iron wheel 225 rotates via the squeegee wheel 224 together with the winding stem 211. Then, due to the rotation of the small wheel & pinion 225, the minute wheel 146 is rotated via the minute wheel 226, and the hour hand 117 and the minute hand 118 are rotated. The display time is changed to the initial position indicating 12 o'clock by the hands of the hour hand 117 and the minute hand 118, and the crown 212 is brought into the normal depressed state shown in FIGS.
[0069]
When the crown 212 is pushed in, the stroller 224 is separated from the small iron wheel 225 in the opposite direction to the above-described operation, and the display time cannot be changed as shown in FIGS. 1 and 2. Further, the reset lever 300 rotates again, and the terminal portion 300B comes into contact with one edge 115A from the other edge 115B of the hole 115.
When the contact state of the terminal portion 300B of the reset lever 300 is switched from the other edge 115B to the one edge 115A, as shown in FIG. 7, the crown operation recognition means 441 of the control circuit 440 pushes the crown 212 and the winding stem 211 is pushed. It is determined that the state has been switched to the pressed state shown in FIGS. 1 and 2 (step S3).
[0070]
When the crown operation recognition means 441 determines that the winding stem 211 has been pressed, the needle position data initialization circuit 447 of the control circuit 440 sets the needle position counter 446 to 0 (12:00) of the initial state. The counter value is reset to the corresponding counter value of 00:00:00 (step S4).
Further, the control circuit 440 controls the reception control circuit 442 so that the reception circuit 420 receives the long-wave standard radio wave (step S5). At the time of this reception, for example, a pulse signal is output from the pulse control circuit 445 to the motor drive circuit 410 to stop the process of moving the hand (continuation of the stop state), thereby preventing a reception failure due to the movement of the hand.
[0071]
Then, the control circuit 440 determines whether or not the data has been correctly received (step S6). Whether the reception is correct or not can be determined by, for example, recognizing that the time code has been output from the reception circuit 420, recognizing that the time code has been stored in the time data storage circuit 430 that stores the time code, The time is determined a plurality of times, for example, three times every one minute, and the time is determined by recognizing a match or a match of data exceeding a certain probability. As a specific method of recognizing the time coincidence by receiving three times, for example, the time obtained by receiving three times every other minute and the time obtained by adding two minutes to the first time, A method of comparing the time obtained by adding one minute to the second time with the third time and recognizing whether or not they match can be used.
Upon recognizing that the signal has been correctly received in step S6, the time data comparing circuit 448 determines the difference between the count value corresponding to the current time set by the current time counter 448A and the reset count value of the hand position counter 446. Recognize.
[0072]
Then, the time data comparison circuit 448 outputs a difference status signal corresponding to the difference from the count value to the pulse control circuit 445, and causes the pulse control circuit 445 to output a predetermined fast-forward pulse signal to the motor drive circuit 410. The motor drive circuit 410 that has obtained the fast-forward pulse signal drives the step motor 120 as appropriate, moves the hands through the drive transmission means 140, and corrects the display time to the position of the hands. In other words, the pointer pointing to 0:00 (12:00), which is the initial position, is moved to the displayed time of the pointer position corresponding to the count value corresponding to the current time.
Thereafter, the pulse control circuit 445 outputs a 1 Hz pulse signal to the motor drive circuit 410 based on the reference signal output from the frequency dividing circuit 444, and causes the timekeeping, that is, the second hand to move one second at a time (step S7). . At this time, since the 1 Hz signal from the frequency dividing circuit 444 is also output to the time data comparing circuit 448 and the hand position counter 446, the count value of the current time counter 448A and the count value of the hand position counter 446 are also one. Each second is added and counted to a count value corresponding to the pointer position and corresponding to the same time.
[0073]
On the other hand, when recognizing that the long-wave standard radio wave has not been correctly received in step S6, the reception control circuit 442 performs a process of continuing the stop of the hand operation by the step motor 120 (step S8). That is, the 1 Hz pulse signal is not output from the pulse control circuit 445, and the pointer remains at 0:00 (12:00) changed by operating the crown 212.
As a result, since the hand movement is not started, the user can easily recognize that the reception has failed without using a separate configuration. It can be suggested that the correction is made correctly by repeating the operation. Then, the user shifts to step S1 by the operation of pulling the crown 212 again, and the above-described processing is repeated.
[0074]
After the above-described processing is completed, the reception control circuit 442 causes the reception circuit 420 to periodically receive the long-wave standard radio wave, and compares the current time with the hand position counter 446 based on the received long-wave standard radio wave. The comparison is performed by the circuit 448. The fast-forward pulse signal is output from the pulse control circuit 445 by the compared difference amount to change the pointer position and correct the time. That is, the time is adjusted by a general radio-controlled timepiece.
[0075]
[Operation and Effect of First Embodiment]
As described above, according to the first embodiment, the following effects can be obtained.
[0076]
(1) Switch from the state shown in FIGS. 3 and 4 in which the winding stem 211 whose display time can be changed by the crown 212 is pulled out to the state shown in FIGS. 1 and 2 in which the unchangeable winding stem 211 is pushed in. When the operation is recognized by the input operation recognition means 460, the time stored by the hand position data initialization circuit 447 in the hand position counter 446 is reset to an initial value corresponding to 0:00 (12:00) which is a predetermined time. A counter value of a certain 00:00:00 is stored. Therefore, to adjust the display time to the current time based on the standard time, the count value to be compared with the current time is set to an initial value, and as a time alignment operation for setting the pointer corresponding to this initial value to the initial position, Since the operation of the crown 212, which is generally used, is performed, there is no need to provide a special configuration such as providing a hole in the gear constituting the drive transmission means 140 and recognizing the state of the pointer with an optical sensor. By using a commonly used configuration without using buttons or the like, it is possible to easily correct the pointer state at the current time easily, and to easily improve manufacturing workability, productivity and cost, There is no design restriction and the appearance can be improved. Further, the user can change the pointer state to the initial position state by the general operation of the crown 212, and the operability can be improved.
[0077]
(2) When the input operation recognizing unit 460 recognizes a predetermined operation of the crown 212 that changes the display time from the state in which the display time can be changed to the state in which the display time cannot be changed, the reception control circuit 442 transmits the long-wave standard radio wave including the time information. The time data comparison circuit 448 controls the reception at 420 and compares the counter value difference between the current time counted based on the long wave standard radio wave and the initial value stored in the hand position counter 446 by a predetermined operation. Then, based on the difference between the counter values, the pulse control circuit 445 controls the motor drive circuit 410 to control the drive of the step motor 120, and moves the hands to the position corresponding to the current time to correct the hands. Therefore, the display time can be easily corrected to the current time easily.
Furthermore, the difference between the initial position of the hands and the current time is recognized using the counter value. Therefore, the difference situation can be easily recognized with a simple configuration, and the circuit configuration can be simplified and the processing efficiency can be easily improved.
[0078]
(3) The time data comparison circuit 448 recognizes the display time at a predetermined time as an initial value and compares it with the current time based on the long-wave standard radio wave. For this reason, since the operation of adjusting the time at 0:00 (12:00) is easy, for example, the time at which the pointer state changed at the crown 212 is the state of the initial position, the operability is further improved. Since the initial state is 00:00:00 corresponding to 0:00 (12:00), the initial state indicates 0:00 (12:00) which is the display time of the pointer state corresponding to this initial value. Is particularly easy to operate, and the operability can be further improved. Further, a configuration in which the display time is corrected to the current time in a normal radio-controlled timepiece can be applied to the configuration in which the pointer position is set to the count value of 00:00:00 as the initial value, and the cost can be easily reduced. I can do it.
[0079]
(4) The pulse control circuit 445 drives the stepping motor 120 to move the hands to 00:00 (00:00), which is a count value of the initial value corresponding to 0:00 (12:00) when the hands are in the initial position. A fast-forward pulse signal is output so that the count value of the second is the same as the count value of the current time to be counted, that is, the hour, minute, and second, and the count value of the hand position counter 446 is fast-forwarded. Under the control, the step motor 120 is appropriately driven, and the hand is moved at a rapid traverse for correction. Therefore, the display time can be easily corrected to the correct current time with a simple configuration.
[0080]
(5) When the reception control circuit 442 causes the reception circuit 420 to receive the long-wave standard radio wave, the hand operation by the step motor 120 due to the output of the pulse signal from the pulse control circuit 445 is stopped. For this reason, it is possible to prevent reception disturbance due to hand movement based on a magnetic field or the like generated when the step motor 120 is driven, to improve the reception of long-wave standard radio waves, and to satisfactorily correct the time.
[0081]
(6) With the configuration shown in FIGS. 3 and 4 in which the display time can be changed by pulling the crown 212 while the second hand points to 0:00 (12:00), the position of the second hand is initialized. , The time can be corrected to the correct current time in seconds.
[0082]
[Second embodiment]
Next, a second embodiment of the present invention will be described with reference to the drawings.
Note that the second embodiment has the same structure as the above-described first embodiment, and in step S6 in the first embodiment, when the reception unit 420 fails to receive the long-wave standard radio wave, As shown in FIG. 8, instead of the configuration in which the hand movement is stopped, the hand movement process is performed to start normal timekeeping. FIG. 8 is a flowchart showing an operation of time adjustment of the radio-controlled timepiece according to the second embodiment of the present invention. In FIG. 8, the same operations as those in the first embodiment shown in FIG. 7 are denoted by the same reference numerals, and description thereof will be omitted.
[0083]
That is, as shown in FIG. 8, when the reception of the long-wave standard radio wave by the receiving means 420 fails in step S6, the control circuit 440 causes the pulse control circuit 445 to output a fast-forward pulse signal and move the hands at the current time. Without executing the process, a 1-hour pulse signal is simply output to start a hand-handling process for starting timekeeping by hand-handing (step S11). For example, the time data comparison circuit 448 generates a signal indicating that reception was not possible. Then, a pulse signal of 1 Hz is output from the pulse control circuit 445 to the motor drive circuit 410 to operate the hands.
[0084]
As a result, even if the crown 212 is pushed as a pointer position indicating 0:00 (12:00) by operating the crown 212, the second hand moves by one second without being corrected at the correct time. For this reason, the user can easily recognize that the reception has not been performed correctly without using a separate configuration. Therefore, the user again operates the crown 212 to set the needle position to the initial position, rotates the crown 212 at a time recognized by the user according to a time signal, changes the pointer position, and pushes the crown 212 down. This operation is recognized by the input operation recognition means 460, and an operation signal is generated. The pulse control circuit 445 outputs a 1 Hz pulse signal to the motor drive circuit 410 to operate the hands based on the generated operation signal and the signal indicating that reception was not possible, as described above. As a result, even if the long-wave standard radio wave cannot be received, the hands are operated with the accuracy of a normal quartz watch, and thus can function as a normal quartz watch.
[0085]
Then, since the user can easily determine that the point where the current time adjustment is being performed is a point where the reception of the long-wave standard time signal cannot be correctly performed, the user moves from the place and adjusts the time again from step S1. Operate to receive the long wave standard radio wave correctly. If the signal has been received correctly, the signal indicating that the signal has not been received is deleted.
[0086]
In addition, as described above, when the time cannot be received correctly and the user manually changes the time so as to function as a clock, and when the time is periodically corrected by receiving the long-wave standard radio wave, the crown 212 Since the pointer position has already been changed by the user by the operation, the correction is made in a state where the count value of the hand position counter 446 does not match the time of the actual pointer position, and thus the correction is not performed correctly. Therefore, when the hand is moved by outputting the pulse signal from the pulse control circuit 445 after changing the pointer position based on the reacquired long-wave standard radio wave, a signal indicating that the signal cannot be received correctly has already been generated. For example, a predetermined pulse signal is output to advance the second hand every two seconds for two seconds. Thus, the user can recognize that the initial setting of the pointer position, that is, the processing from step S1 which is the processing for matching the pointer position with the count value of the hand position counter is necessary. Therefore, as described above, the user can correctly receive the long-wave standard radio wave and correct the current time.
[0087]
In addition, when the time cannot be received correctly and the user manually changes the time to function as a clock, and when the time is periodically corrected by receiving the long-wave standard time signal, the second hand is moved every two seconds. The configuration is not limited to this. For example, the hands may be moved every three seconds. Further, as in step S8 of the first embodiment, the hand may be stopped without moving. Further, the user may be notified by moving the hand every normal second and emitting an LED (Light Emitting Diode) or the like provided separately to display the fact that the signal cannot be received correctly. Further, when the hands are moved as in a normal quartz watch, for example, the second hand may be moved for two seconds every two seconds. According to this configuration, it is possible to easily recognize that the reception has failed.
If a signal indicating that the signal cannot be received correctly is generated, the process of receiving the long-wave standard time signal and correcting the time may be prohibited. According to such a configuration, the inconvenience that the position of the hands is changed despite the fact that the long-wave standard time signal is received again and the time is manually corrected to function as a normal quartz watch occurs. Can also be prevented. In this case, the hands may be moved, for example, every two seconds as described above. With this configuration, the user can easily recognize that the time has not been correctly corrected although the long-wave standard time signal is newly received and corrected.
Further, when the predetermined operation of the crown 212 is recognized again, the long wave standard radio wave is correctly received, and the initial setting of the pointer position can be executed, the reception of the already prohibited regular long wave standard radio wave is resumed. You may make it do. With this configuration, it is possible to function as a radio-controlled timepiece 100 from a state in which it functions as a normal quartz timepiece.
[0088]
As described above, in the configuration in which the hands are moved in step S11, when the input operation recognizing unit 460 recognizes a predetermined operation for changing the display time of the crown 212 from a changeable state to an unchangeable state, the hour hand 117 is driven. Then, the hand movement by the step motor 120 for moving the minute hand 118 and displaying the display time by the hands is started. For this reason, the display time is corrected to the current time and the hand movement by clocking is started. After the correction, the display of the current time can be continued, and the accurate time can be easily displayed.
Further, for example, even if the display time cannot be corrected to the current time due to a failure to receive the long-wave standard time signal, by performing a predetermined operation to change the display time to the current time by operating the crown 212, The hand movement is continued from that point of time, so that the inconvenience that the time cannot be displayed can be prevented, and the function as a clock can be secured.
[0089]
[Other embodiments]
The present invention is not limited to the first embodiment and the second embodiment, but includes modifications and improvements as long as the object of the present invention can be achieved. .
That is, the radio-controlled timepiece 100 of the present invention may be any timepiece having no second hand or a function having a calendar function, as described above. Further, the radio-controlled timepiece 100 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.
In addition, although the description has been made by driving with the button battery 111, any configuration can be used as the driving source, such as a configuration using a solar cell or body temperature. In the case of the mainspring type, since a shortage of electromotive force for receiving the long-wave standard radio wave is considered, a battery type which can provide sufficient power and can be used as a watch is preferable.
[0090]
The circuits and means shown in FIGS. 5 and 6 mounted on the circuit board for executing the operation shown in FIG. 7 and the operation shown in FIG. 8 are not limited to those constituted by hardware such as various logic elements. , A computer including a CPU (Central Processing Unit), a memory (storage device), etc., is provided in the radio-controlled timepiece 100, and a predetermined program and data (data stored in each storage unit) are installed in the computer. It may be configured to realize the means and means.
For example, a CPU or a memory is arranged in the radio-controlled timepiece 100 so that it can function as a computer, and a predetermined control program or data is stored in the memory by a 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, to operate a CPU etc. by this installed program, and to correct time by operating the crown 212 appropriately.
In order to install a predetermined program or the like in the radio-controlled timepiece 100, a memory card, a CD-ROM, or the like is directly inserted into the radio-controlled timepiece 100. It may be connected to the correction clock 100. Further, a LAN cable, a telephone line, or the like may be connected to the radio-controlled timepiece 100 to supply and install a program or the like by communication. Since the antenna 130 is provided, a program may be supplied and installed wirelessly. You may.
[0091]
By incorporating such a recording medium or a control program provided by communication means such as the Internet into the radio-controlled timepiece 100, 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 100 having different control formats can be manufactured only by changing the program, so that parts can be shared and the manufacturing cost at the time of developing variations can be greatly reduced.
[0092]
The functions of the radio-controlled timepiece 100, that is, the respective components such as the time measuring means 470, the receiving means 450, the drive transmitting means 140, and the display time correcting means 200 are not limited to those of the above-described embodiment, but may be a conventionally known radio-controlled timepiece. Each means of the clock is available. That is, the train wheel operated at the time to be counted is not limited to the first embodiment. Further, the crown 212 can be operated in two stages, but as described above, a configuration in which three or more stages can be operated, for example, one having a calendar function can be operated in three stages is also applicable.
Further, in the first embodiment, the number of receiving target stations, a specific country (region), and the like may be set as appropriate for implementation.
[0093]
As the radio-controlled timepiece 100 having the hour hand 117, the minute hand 118 and the second hand, the time is adjusted by a predetermined input operation in which the second hand pulls the crown 212 at a position corresponding to a predetermined initial position, that is, a position pointing to 0 o'clock (12:00). Although the configuration has been described, the same can be applied to the radio-controlled timepiece 100 having no second hand. In a configuration in which the position of the second hand can be changed by operating the crown 212, the second hand may be adjusted to the initial position. Further, in the configuration having the calendar mechanism, the content of the calendar displayed by the calendar mechanism may be modified by the step motor 120 or the like based on the time code.
[0094]
Furthermore, although the description has been made by resetting the crown 212 to the initial value when the crown 212 is depressed, the timing for resetting can also be when the crown 212 is pulled.
[0095]
Further, the configuration in which the hand movement is stopped during the process of receiving the long-wave standard radio wave has been described, but the hand movement may be performed. In this case, the counter values of the hand position counter 446 and the current time counter 448A are also counted up based on the 1 Hz reference signal from the frequency dividing circuit 444 to correspond to the hand movement. Then, a fast-forward pulse is output from the pulse control circuit 445 so that the count value of the hand position counter 446 that has been counted up by this hand movement becomes the counter value of the current time counter 448A, and the pointer position is set to the pointer position corresponding to the current time. To be corrected. That is, since the count value is once reset to match the pointer position with the count value, the time can be accurately corrected even if the hands are moved.
In this way, when the hand is not operated after the initialization is set, the reset count value at the time of the initialization is compared with the count value corresponding to the current time. And the count value corresponding to the current time may be compared.
[0096]
In addition, specific structures and procedures for implementing the present invention can be appropriately changed to other structures or the like as long as the object of the present invention can be achieved.
[0097]
【The invention's effect】
As described above, according to the radio-controlled timepiece and the control method thereof of the present invention, at the time of a predetermined input operation of a commonly used crown that is operated to change the display time, an initial state corresponding to the initial state is performed. Since the value is set, the display time can be easily recognized as the initial state corresponding to the initial value without providing a special configuration, and the display time can be corrected to the current time based on the standard radio wave. Improvement, productivity improvement, and cost reduction can be easily achieved, and the initial state can be easily set by an operation such as changing the display time, so that the operability can be improved.
[Brief description of the drawings]
FIG. 1 is a partially cutaway plan view showing a state in which a winding stem of a radio-controlled timepiece according to a first embodiment of the present invention is depressed.
FIG. 2 is a partially enlarged view of FIG.
FIG. 3 is a partially cutaway plan view showing a state where the winding stem of the radio-controlled timepiece is pulled out.
FIG. 4 is a partially enlarged view of FIG. 3;
FIG. 5 is a block diagram showing an internal configuration of the radio-controlled timepiece.
FIG. 6 is a block diagram showing a detailed internal configuration of a control circuit.
FIG. 7 is a flowchart showing an operation of time correction of the radio-controlled timepiece.
FIG. 8 is a flowchart illustrating an operation of time correction of a radio-controlled timepiece according to a second embodiment of the present invention.
[Explanation of symbols]
100: radio-controlled timepiece; 117, hour hand as a pointer; 118, minute hand as a pointer; 120, a step motor as driving means; 212, a crown; 442, a reception control circuit as reception control means; 443A; 446: Needle position counter as storage means, 447 ... Hand position data initialization circuit as setting means, 448 ... Time data comparison circuit as comparison means, 450 ... Receiving means, 460 ... Input operation recognition means, 470 ... Clocking Means, 480: Time correction means

Claims (13)

Receiving means for receiving a standard time signal including time information;
Clocking means for measuring the time based on a reference signal from a reference signal source;
A pointer for displaying the time,
Driving means for moving the hands based on the time,
Storage means for storing the time;
A crown that can and cannot change the display time displayed by the pointer by a predetermined input operation,
Input operation recognizing means for recognizing the predetermined input operation of the crown;
Setting means for storing a predetermined time in the storage means when the input operation recognizing means recognizes a predetermined input operation for switching the display time from a changeable state to a non-changeable state by the crown,
A radio-controlled timepiece characterized by comprising: The radio-controlled timepiece according to claim 1,
The predetermined time stored in the storage means is a count value corresponding to a pointer position of 00:00:00. The radio-controlled timepiece according to claim 1 or 2,
When the input operation recognizing means recognizes the predetermined input operation for changing the display time from the state in which the display time can be changed to the state in which the display time cannot be changed, the receiving means controls the receiving means to receive the standard radio wave. Control means;
When the receiving unit successfully receives the standard radio wave, a comparing unit that recognizes a difference between a current time based on the received standard radio wave and a predetermined time stored in the storage unit.
Time correction means for changing the display time to the current time based on the difference status recognized by the comparison means. The radio-controlled timepiece according to claim 3,
The time correction means drives the driving means to move the hands and move the display time to the current time until a predetermined time stored in the storage means becomes the same as the current time. Radio-corrected clock that was. The radio-controlled timepiece according to claim 3 or claim 4,
The radio-controlled timepiece according to claim 1, wherein the reception control means stops the hand movement by the driving means when the reception means receives a standard radio wave. The radio-controlled timepiece according to any one of claims 3 to 5,
A radio-controlled timepiece according to claim 1, wherein said reception control means stops or continues to stop hand movement by said driving means when said reception means fails to receive said standard radio wave. The radio-controlled timepiece according to any one of claims 2 to 6,
The input operation recognizing means starts a hand operation by the driving means by recognizing a predetermined input operation by the crown to change the display time from a changeable state to a non-changeable state. Correction clock. The radio-controlled timepiece according to any one of claims 3 to 5,
The reception control means, when the reception of the standard radio wave by the reception means fails, a predetermined input operation for changing the display time by the input operation recognition means from the state in which the display time can be changed to the state in which the display time cannot be changed. By recognizing that, the hand operation by the driving means is started, and the reception of the standard radio wave by the receiving means is stopped until the input operation recognizing means recognizes the predetermined input operation again. Correction clock. The radio-controlled timepiece according to any one of claims 1 to 3,
The storage means includes a hand position counter that stores the time as a count value corresponding to the pointer position,
The time counting means includes a pulse control circuit that outputs a 1-Hz pulse signal to the hand position counter based on a signal output from the reference signal source and adds the count value for one second,
The setting means includes a hand position data initialization circuit for setting a hand position as a count value corresponding to the pointer position as the predetermined time stored in the storage means,
The input operation recognizing means recognizes a predetermined input operation for switching the display time from a state in which the display time can be changed to a state in which the display time cannot be changed by the crown, and is stored in the storage means by the needle position data initialization circuit. A radio-controlled timepiece comprising a crown operation recognizing means for setting the count value to the count value. The radio-controlled timepiece according to any one of claims 3 to 6,
A time data storage circuit that stores information about the time received based on the standard radio wave received by the receiving unit,
The storage means includes a hand position counter that stores the time as a count value corresponding to the pointer position,
The time counting means includes a pulse control circuit that outputs a 1-Hz pulse signal to the hand position counter based on a signal output from the reference signal source and adds the count value for one second,
The comparing means includes a current time counter that stores a count value corresponding to the time stored in the time data storage circuit, and recognizes a time difference between the count value of the current time counter and the count value of the hand position counter. Radio-controlled watch characterized by doing. The radio-controlled timepiece according to any one of claims 1 to 10,
When the input operation recognizer recognizes a predetermined input operation for changing the display time to a predetermined time by the crown and switching the display time to a state in which the display time cannot be changed, the setting unit stores a predetermined input operation in the storage unit. A radio-controlled timepiece characterized by storing the time of day. A method of controlling a radio-controlled timepiece that corrects a measured time based on a standard time signal including time information at which a display time indicated by a pointer is received,
Recognizing a predetermined input operation that switches the display time from a changeable state of the crown to be changeable and non-changeable by a predetermined input operation to a non-changeable state,
A method for controlling a radio-controlled timepiece, wherein the time to be measured is set to a predetermined time by recognizing the predetermined input operation. A method of controlling a radio-controlled timepiece that corrects a measured time based on a standard time signal including time information at which a display time indicated by a pointer is received,
Setting the time to be measured to a predetermined time by recognizing a predetermined input operation for switching the display time to a state in which the display time cannot be changed after the display time is changed to a predetermined time by a crown operation. A method for controlling a radio-controlled timepiece, comprising the steps of:

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