JP4763903B2 - Electronic clock with pointer stop function - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electronic timepiece with a pointer stop function.
[0002]
[Prior art]
An electronic timepiece with a power generation detection function that has a power generation means such as a solar cell and that saves power during non-power generation is already a well-known technique, and is a specially known document that discloses this technique. No. 5-60075 is cited.
[0003]
In this publication, the brightness hitting the watch is detected by an illuminance detection circuit (power generation detection circuit), and when it is dark, the hands are stopped to reduce power consumption, and the time is counted only by the circuit. A timepiece having a so-called power saving function of returning is disclosed.
[0004]
[Problems to be solved by the invention]
By the way, the latest solar watch adopts the power save function that stops the second hand, the hour and minute hands, and the date plate when light does not shine for a long time. Watches are commercialized.
However, if the mechanical mechanism is stopped without moving it for a long time, such as several years, due to the power saving function, the oil that lubricates the moving parts will be depleted during the stopping, and the moving parts will be smooth when returning from power saving. As a result, there is an increased possibility of time skew.
[0005]
SUMMARY OF THE INVENTION An object of the present invention is to solve the above problems and to provide a specific hand operating system for an electronic timepiece with a pointer stop function.
[0006]
[Means for Solving the Problems]
In order to achieve the above object, the present invention provides an electronic timepiece having an oscillation circuit, a frequency dividing circuit, a time counter, a power source, a pointer, and a pointer stop means for controlling the stop of the pointer. The present invention is characterized in that a hand movement control means for controlling the hand movement means and the above-mentioned smoothing movement means for every predetermined period is provided.
[0007]
Voltage detection means for detecting the voltage of the power source is provided, and the leveling control means is controlled by the voltage detection means.
[0008]
The power source includes power generation means and power storage means.
[0009]
The power generation detection unit includes a power generation detection unit that detects a power generation state of the power generation unit, and the pointer stop unit is controlled by the power generation detection unit.
[0010]
The power generation means is a solar cell.
[0011]
The pointer has at least a second hand.
[0012]
The pointer is composed of a plurality of pointers driven by a plurality of motors.
[0013]
The pointer has at least a second hand and an hour / minute hand.
[0014]
It is characterized in that the pointer for leveling when the pointer is stopped is switched according to the stop period.
[0015]
It is characterized in that the manner in which the needle is moved during the stop of the pointer is switched according to the stop period.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of an electronic timepiece according to the invention will be described below. 1 is a circuit block diagram of an embodiment of the present invention, FIG. 2 is a detailed view of a second counter which is one of the circuit components of the present invention, and FIG. 3 is an hour / minute counter which is one of the circuit components of the present invention. FIG. 4 is a detailed view of a day counter which is one of the circuit components of the present invention.
[0017]
In FIG. 1, 1 is an oscillation circuit, 2 is a frequency dividing circuit, 3 is a second counter, 4 is an hour / minute counter, 5 is a day counter, 6 is a second leveling means, 7 is a time leveling means, and 8 is a date. , 9 is a pointer stop means, 10 is a leveling operation control means, 11, 12 and 13 are OR gates, 14, 15 and 16 are waveform shaping circuits, 17, 18 and 19 are driver circuits, 20 is a power generation means, 21 Is a power generation detection means, 22 is a backflow prevention means, 23 is a power storage means, 24 is a voltage detection means, 25 is a conversion circuit, 100 is a display means, 101 is a second hand, 102 is a minute hand, 103 is an hour hand, 104 is a date display is there.
[0018]
The oscillation circuit 1 generates 32,768 Hz as a time reference source. The frequency dividing circuit 2 creates a 1 Hz signal S1, a 64 Hz signal S64, and a signal group S200. The 1 Hz signal S1 is input to the B input of the second counter 3, and the 64 Hz signal S64 is input to the second counter 3, the hour / minute counter 4, and the day counter 5, respectively. On the A input, the signal group S200 is supplied to the second leveling means 6, the hour / minute leveling means 7, the date leveling means 8, and the waveform shaping means 14, 15, 16.
The second counter 3 inputs the 1 Hz signal S1 from the frequency divider 2 to the B input, the 64 Hz signal S64 from the frequency divider 2 to the A input, and the second hand stop signal S93 from the pointer stop means 9 to the C input. The second hand movement signal P35 is output from the O1 output, the one-minute signal S31 is output from the O2 output, and the current second counter information J31 is output from the O3 output.
The hour / minute counter 4 inputs the 1-minute signal S31 from the O2 output of the second counter 3 to the B input, the 64 Hz signal S64 from the frequency dividing circuit 2 to the A input, and the time from the pointer stop means 9 to the C input. The minute hand stop signal S94 is input, the hour / minute hand movement signal P45 is output from the O1 output, the one-day signal S41 is output from the O2 output, and the current hour / minute counter information J41 is output from the O3 output.
The day counter 5 inputs the 1-day signal S41 from the O2 output of the hour / minute counter 4 to the B input, the 64 Hz signal S64 from the frequency dividing circuit 2 to the A input, and the date from the pointer stop means 9 to the C input. The plate stop signal S95 is input, the date hand movement signal P55 is output from the O1 output, and the current day counter information J51 is output from the O3 output.
A second hand movement signal P35 from the second counter 3 is supplied to the second hand 101 via the OR gate 11, the waveform shaping circuit 14, and the driver circuit 17. The hour / minute hand movement signal P45 from the hour / minute counter 4 is supplied to the minute hand 102 and the hour hand 103 via the OR gate 12, the waveform shaping circuit 15, and the driver circuit 18. A date hand signal P55 from the date counter 5 is supplied to the date plate 104 via the conversion circuit 25, the OR gate 13, the waveform shaping circuit 16, and the driver circuit 19.
The pointer stop means 9 includes a power generation detection signal S21 from the power generation detection means 21, the current second counter information J31 from the second counter 3, the current hour / minute counter information J41 from the hour / minute counter 4, and the current date from the day counter 5. When the counter information J51 is input, the L level power generation detection signal S21 is input from the power generation detection means 21, and when a predetermined count value is reached, the H level second hand stop signal S93, hour / minute pointer stop signal S94, date plate stop signal S95 and the power generation detection permission signal S921 are output.
The leveling movement control means 10 sends the second hand stop signal S93 from the hand stop means 9, the hour / minute hand stop signal S94, the date stop signal S95, the current second counter information J31 from the second counter 3, and the current hand from the hour / minute counter 4. The hour / minute counter information J41 and the current day counter information J51 from the day counter 5 are input, and the second hand stop signal S93, hour / minute pointer stop signal S94, and date plate stop signal S95 are output from the pointer stop means 9 at a predetermined count. It outputs a second-hand movement permission signal S106, hour / minute movement permission signal S107, and day-hour movement permission signal S108.
The second-hand movement means 6, the hour-minute movement means 7, and the day-hand movement means 8 are the second-hand movement permission signal S106, the hour-minute movement movement permission signal S107, and the day-hour movement from the respective movement-hand movement control means 10. When the hand movement permission signal S108 is input, the second hand movement signal P6, the hour / minute hand movement signal P7, and the day movement hand movement signal P8 are output, respectively, and the OR gates 11, 12, 13, and the waveform shaping circuits 14, 15, 16, It is supplied to the second hand 101, the minute hand 102, the hour hand 103 and the date plate 104 via the driver circuits 17, 18 and 19.
The power generation detection unit 21 detects the state of the power generation unit 20 when the power generation detection permission signal S921 is input from the pointer stop unit 9, and stops the power generation detection signal S21 at the L level when non-power generation is detected and at the H level when power generation is detected. It outputs to the means 9. The voltage detection means 24 detects the state of the power storage means 23 and supplies the voltage drop detection signal S24 at the L level during normal operation and the H level voltage drop detection signal S24 during detection of the voltage drop to the hand movement control means 10.
[0019]
FIG. 2 is a detailed block diagram of the second counter 3. 31 is a current second counter, 32 is a mismatch circuit, 33 is a second hand position counter, 34 and 36 are AND gates, 35 is a selector, and 37 is an inverter.
The current second counter 31 is a 60-digit counter that receives a 1 Hz signal S1 from the B input and outputs a 1 minute signal S31 from the O2 output. The second hand position counter 33 is also a 60-digit counter and outputs a second hand movement signal P35 from the Q output of the selector 35. When the mismatch circuit 32 detects a mismatch between the current second counter information J31 of the current second counter 31 and the second hand position counter information J33 of the second hand position counter 33, the mismatch circuit 32 outputs an H level mismatch detection signal S32. The selector 35 inputs the 1 Hz signal S1 from the frequency dividing circuit 2 via the AND gate 34 to the B input, the 64 Hz signal S64 from the frequency dividing circuit 2 to the A input, and the AND input 36 via the AND gate 36. When the second hand stop signal S93 from the pointer stop means 9 is input, the B input is selected when the L level signal is input to the Φ input, and the A input is selected when the H level signal is input to the Φ input. It outputs as a hand movement signal P35.
[0020]
FIG. 3 is a detailed block diagram of the hour / minute counter 4. 41 is a current second counter, 42 is a mismatch circuit, 43 is an hour / minute hand position counter, 44 and 46 are AND gates, 45 is a selector, and 47 is an inverter.
The current hour / minute counter 41 is a 60 × 24-ary (1440) counter, which receives the one-minute signal S31 from the second counter 3 and outputs the one-day signal S41 from the O2 output. The hour / minute hand position counter 43 is also a 60 × 24 (1440) counter and outputs the hour / minute hand movement signal P45 from the Q output of the selector 45. When the mismatch circuit 42 detects a mismatch between the current second counter information J41 of the current hour / minute counter 41 and the hour / minute hand position counter information J43 of the hour / minute hand position counter 43, the mismatch circuit 42 outputs an H level mismatch detection signal S42. The selector 45 inputs the 1-minute signal P31 from the second counter 3 via the AND gate 44 to the B input, inputs the 64 Hz signal S64 from the frequency dividing circuit 2 to the A input, and passes the AND gate 46 to the Φ input. When the hour / minute hand stop signal S94 from the pointer stop means 9 is input, the B input is selected when the L level signal is input to the Φ input, the A input is selected when the H level signal is input to the Φ input, and the O1 output is selected. Output as hour / minute hand movement signal P45.
[0021]
FIG. 4 is a detailed block diagram of the day counter 5. 51 is a current day counter, 52 is a mismatch circuit, 53 is a date hand position counter, 54 and 56 are AND gates, 55 is a selector, and 57 is an inverter.
The current day counter 51 is a 31-digit counter, and receives the 1-day signal S41 from the hour / minute counter 4. The date hand position counter 53 is also a 31-adic counter and outputs a date-hand movement signal P55 from the Q output of the selector 55. When the mismatch circuit 52 detects a mismatch between the current date counter information J51 of the current date counter 51 and the date hand position counter information J53 of the date hand position counter 53, the mismatch circuit 52 outputs an H level mismatch detection signal P52. The selector 55 inputs the 1-day signal S41 from the hour / minute counter 4 via the AND gate 54 to the B input, inputs the 64 Hz signal S64 from the frequency dividing circuit 2 to the A input, and passes the AND gate 46 to the Φ input. When the date stop signal S95 from the pointer stop means 9 is input, the B input is selected when the L level signal is input to the Φ input, the A input is selected when the H level signal is input to the Φ input, and the O1 output Is output as a date-hand movement signal P55.
[0022]
Next, the operation will be described. Originally, it is necessary to initialize the count value of each counter and the needle position of each pointer first, but since it is not directly related to the contents of the present invention, the description is omitted here.
[0023]
First, the normal state will be described.
In the second counter 3, the 1 Hz signal S1 from the frequency dividing circuit 2 is inputted to the B input, the 64 Hz signal S64 is inputted to the A input, and the second pointer stop signal S93 of L level is inputted to the C input. In the normal state, the current second count information J31 of the current second counter 31 and the count value of the second hand position counter information J33 of the second hand position counter 33 match, and the mismatch circuit 32 outputs an L level mismatch signal S32. . Since the AND gate 36 receives the L level mismatch signal S32, the output becomes the L level, and the selector 35 selectively outputs the B input. The B input of the selector 35 is connected to the output of the AND gate 34. Since the second pointer stop signal S93 is at the L level, the input on one side of the AND gate 34 via the inverter 37 becomes the H level. The signal S1 is supplied to the B input of the selector 35 as it is. A 1 Hz signal S1 is selectively output from the Q output of the selector 35, and the 1 Hz signal S1 is input to the second hand position counter 33 and also output as the second hand movement signal P35 from the O1 output. The second hand movement signal P35 is supplied to the display means 100 via the OR gate 11, the waveform shaping circuit 14, and the driver 17, and the second hand 101 performs one second hand movement.
Similarly, the hour / minute counter 4 inputs the 1 minute signal S31 from the second counter 3 to the B input, and the O1 output outputs the hour / minute hand movement signal P45 every minute, and the hour / minute hand movement signal P45 is the OR gate 12. The minute hand 102 and the hour hand 103 (the hour hand and the minute hand are interlocked with each other by the mechanism) are moved for one minute by the waveform shaping circuit 15 and the driver 18.
Further, the day counter 5 inputs the 1-day signal S41 from the hour / minute counter 4 to the B input, and from the O1 output, the day operation signal P55 is output every day, and the date operation signal P55 is converted into the conversion circuit 25 and the OR gate 13. The date plate 104 is supplied to the display means 100 via the waveform shaping circuit 16 and the driver 19, and the date plate 104 performs one-day operation. In the present embodiment, one day movement signal P55 is converted into 240 day movement pulses P25 by the conversion circuit 25. This is because the date plate 104 is not directly connected to a motor (not shown) but is decelerated by a train wheel (not shown), and 240 shots are required to feed one day.
[0024]
Next, the transition from the normal state to the stopped state will be described.
The power generation detection means 21 outputs an L level power generation detection signal S21 when the power generation means 20 enters a non-power generation state.
The pointer stopping means 9 further detects a predetermined count value (in this embodiment, 00: 00: 00: 00 regardless of the date) while receiving the L level power generation detection signal S21 from the power generation detection means 21. , H level second pointer stop signal S93, hour / minute pointer stop signal S94, and date plate stop signal S95, respectively.
The H level second pointer stop signal S93 is input to the AND gate 34 via the inverter 37 in the second counter 3. Since one input of the AND gate 34 is L level, the 1 Hz signal S1 from the second counter 3 is stopped, and the second hand movement signal P35 is stopped.
Similarly, the hour / minute pointer stop signal S94 at H level is input to the AND gate 44 via the inverter 47 in the hour / minute counter 4. Since one input of the AND gate 44 becomes L level, the 1-minute signal S31 from the hour / minute counter 4 is stopped, and the hour / minute hand movement signal P45 is stopped.
Similarly, the H level date stop signal S95 is input to the AND gate 54 via the inverter 57 in the date counter 5. Since one input of the AND gate 54 is L level, the 1-day signal S41 from the day counter 5 is stopped, and the date-hand movement signal P55 is stopped.
As described above, the second hand 101, the minute hand 102, the hour hand 103, and the date plate 104 are stopped.
Note that the current second counter 31 in the second counter 3, the current hour / minute counter 41 in the hour / minute counter 4, and the current day counter 51 in the day counter 5 continue to count regardless of the stop of each pointer. ing. Accordingly, H level mismatch signals S32, S42 and S52 are output from the mismatch circuits 32, 42 and 52, respectively.
[0025]
Next, the leveling operation in the stopped state will be described.
The leveling movement control means 10 further inputs a predetermined count value (monthly in this embodiment every month) while inputting the H level second pointer stop signal S93, hour / minute pointer stop signal S94, and date dial stop signal S95 from the pointer stop means 9. If it is detected as 00:00 AM 0 seconds on the 1st), an H level second-hand movement permission signal S106, hour / minute hand movement permission signal S107, and day-warming hand movement permission signal S108 are output.
The second-hand movement means 6, the hour-minute movement means 7, and the day-hand movement means 8 are the second-hand movement permission signal S106, the hour-minute movement movement permission signal S107, and the day-hour movement from the respective movement-hand movement control means 10. When the hand movement permission signal S108 is input, the second hand movement signal P6, the hour / minute hand movement signal P7, and the day movement hand movement signal P8 are output, respectively, and the OR gates 11, 12, 13, and the waveform shaping circuits 14, 15, 16, It is supplied to the second hand 101, the minute hand 102, the hour hand 103 and the date plate 104 via the driver circuits 17, 18 and 19.
[0026]
When the second hand movement signal P6 is output, in this embodiment, the second hand 101 is fast-forwarded with 60 forward rotations. Since the second display is 60 rounds per round, the hand position of the second hand 101 does not change before and after leveling.
When the hour / minute hand-handling signal P7 is output, in this embodiment, the hour / minute hands 102 and 103 are rotated forward 15 times instead of 720 (= 60 × 12) which is one rotation of the hour / minute display. Fast forward with 30 shots and 15 forward rotations. Since + 15-30 + 15 = 0, the hand positions of the hour / minute hands 102 and 103 do not change before and after leveling, and the total number of shots is as small as 60, which is advantageous in terms of power consumption and time.
Similarly, when the day-warming hand movement signal P8 is output, in this embodiment, instead of 7440 (= 240 × 31) which is one turn of the date display, the date plate 104 is forwardly rotated 15 times and reversely 30 times. Fast forward with 15 forward rotations. Since + 15-30 + 15 = 0, the date plate 10 has no hand position and the total number of shots is as small as 60, which is advantageous in terms of power consumption and time.
In this embodiment, the second leveling means 6, the hour / minute leveling means 7, and the date leveling means 8 are operated simultaneously. However, even if the three are operated separately, they are divided into one and two. May be operated.
[0027]
Next, the stop state at the time of voltage drop will be described.
The voltage detection means 24 detects the state of the power storage means 23 and supplies the voltage drop detection signal S24 at the L level during normal operation and the H level voltage drop detection signal S24 during detection of the voltage drop to the hand movement control means 10.
When the leveling hand movement control means 10 receives the H level voltage drop detection signal S24 from the voltage detection means 24, the H level second pointer stop signal S93 or the H level hour / minute pointer stop signal S94 or the H level date plate. Even when the stop signal S95 is inputted and the predetermined count value is reached (in this embodiment, 00: 00: 00: 00 on the first day of every month), the second hand movement permission signal S106, the hour / minute hand movement Neither the permission signal S107 nor the day-warming hand movement permission signal S108 is output.
As described above, when the voltage drops, the leveling is not performed to extend the battery life.
[0028]
Next, release from the stopped state (transition from the stopped state to the normal state) will be described.
The power generation detection means 21 outputs an H level power generation detection signal S21 when the power generation means 20 enters a power generation state.
In response to the H level power generation detection signal S21 from the power generation detection means 21, the pointer stop means 9 turns the second pointer stop signal S93, the hour / minute pointer stop signal S94, and the date plate stop signal S95 to L level.
The L level second hand stop signal S93 is input to the AND gate 34 and the AND gate 36 via the inverter 37 in the second counter 3. Since one input of the AND gate 34 becomes H level, the 1 Hz signal S1 from the frequency dividing circuit 2 is permitted. Since the AND gate 36 has both inputs at the H level, the output is at the H level. The selector 35 selects the 64 Hz signal S64 from the frequency dividing circuit 2 on the A input side, and the second hand movement signal P35 is output at 64 Hz to return. To do. When the current second counter 31 and the second hand position counter 33 match, the output of the mismatch circuit 32 becomes L level and the output of the AND gate 36 also becomes L level. Therefore, the selector 35 selects the 1 Hz signal S1 on the B input side, and moves the second hand. The signal P35 starts moving for 1 second.
Similarly, the hour / minute pointer stop signal S 94 at the L level is input to the AND gate 44 and the AND gate 46 via the inverter 47 in the hour / minute counter 4. Since one input of the AND gate 44 becomes H level, the one-minute signal S31 from the second counter 3 is permitted. Further, since both inputs of the AND gate 46 are at the H level, the output becomes the H level, and the selector 45 selects the 64 Hz signal S64 on the A input side, and the hour / minute hand movement signal P45 is output at 64 Hz to return. When the current hour / minute counter 41 and the hour / minute hand position counter 43 match, the output of the mismatch circuit 42 becomes L level and the output of the AND gate 46 also becomes L level. Therefore, the selector 45 selects the 1 minute signal S31 on the B input side. Then, the hour / minute hand movement signal P45 starts to move one minute.
Similarly, the L-level date dial pointer stop signal S95 is input to the AND gate 54 and the AND gate 56 via the inverter 57 in the date counter 5. Since one input of the AND gate 54 becomes H level, the 1-day signal S41 from the hour / minute counter 4 is permitted. Since both the inputs of the AND gate 56 are at the H level, the output is at the H level, the selector 55 selects the 64 Hz signal S64 on the A input side, and the date-hand movement signal P55 is output at 64 Hz to return. When the current date counter 51 and the date hand position counter 53 match, the output of the mismatch circuit 52 becomes L level and the output of the AND gate 56 also becomes L level, so the selector 55 selects the 1-day signal S41 on the B input side. The date-hand movement signal P55 starts one-day movement.
[0029]
As described above, in the first embodiment, when the second hand 101, the hour / minute hands 102 and 103, and the date plate 104 are stopped, the second-handing means 6, the hour / minute-handing means 7, and the day-warming hand-operating means 8 are each hand-operated. When a second leveling movement permission signal S106, hour / minute leveling movement permission signal S107, and date leveling movement permission signal S108 from the control means 10 are input, the second leveling movement signal P6, the hour / minute leveling movement signal P7, and the date, respectively. The hand movement signal P8 is output and supplied to the second hand 101, the minute hand 102, the hour hand 103, and the date plate 104 via the OR gates 11, 12, 13, waveform shaping circuits 14, 15, 16, and driver circuits 17, 18, 19. However, the present invention is not limited to this, and the present invention can be achieved as long as at least one of them is provided.
[0030]
Next, a second embodiment will be described. In the second embodiment, the operation of leveling is different between the first power save and the second power Cebu. In addition, the second power save is a time factor and the form of the leveling is different.
FIG. 5 is a circuit block diagram of another embodiment of the present invention, FIG. 6 is an operation flowchart of another embodiment, FIG. 7 is an operation flowchart of a normal state subroutine shown in FIG. 6, and FIG. FIG. 9 is an operation flowchart of the subroutine in the power save 2 state shown in FIG. 6, and FIG. 10 is an operation flowchart of another subroutine in the power save 2 state shown in FIG. .
[0031]
FIG. 5 shows a clock constituted by a microcomputer, 200 is a switch, 201 is a ROM, 202 is a RAM, 203 is a CPU, 204 is a clock, 100 is a display means, 101 is a second hand, 102 is a minute hand, 103 is an hour hand, 104 Is a date display part.
[0032]
FIG. 6 is an operation flowchart of the state selection. When the halt release (step 1003) is performed from the halt state (step 1002), first, it is determined whether or not it is the normal state (step 1004). Whether or not is determined (step 1006). In accordance with the determined result, the process jumps to a normal state subroutine (step 1005), a power save 1 state subroutine (step 1007), or a power save 2 state subroutine (step 1008). (Step 1001 to Step 1008)
[0033]
In a normal state, the second hand 101 moves one second every second, and the hour / minute hands 102 and 103 move 15 seconds every 15 seconds.
The power save 1 state is the first stage of entering power save from the normal state. The second hand 101 stops moving, only counts the second counter, and the hour / minute hands 102 and 103 move 15 seconds every 15 seconds. Therefore, the current consumption corresponding to the second hand movement is saved.
The power saving 2 state is a second stage of power saving that enters from the power saving 1 state. The hour and minute hands 102 and 103 are stopped together with the second hand 101, and the second counter is switched to a two-hour counter. Therefore, the current consumption for the hour and minute hands and the current consumption for the circuit are saved together with the current consumption for the second hand movement.
In the present embodiment, the transition from the normal state to the power save 1 state and the transition from the power save 1 state to the power save 2 state are not directly related to the contents of the present invention, and thus description thereof is omitted here. .
[0034]
FIG. 7 is an operation flowchart of a subroutine in a normal state, in which it is determined whether or not the cause of halt release is 0.5 seconds (step 1102), and in the case of YES, whether or not it is a positive second is determined (step 1103). In this case, the second counter is incremented (step 1104), and then the second hand is moved for one second (step 1105), followed by a discrimination of 15 seconds (step 1106). Is counted up (step 1107), then the hour / minute hand is moved for 15 seconds (step 1108), and the process returns to the main program in the return subroutine (step 1109).
Further, in determining whether the cause of the halt release is 0.5 second (step 1102), in the case of NO, it is determined whether it is a switch (step 1110), and in the case of YES, a switch process (step 1111) is performed. (Step 1101 to Step 1111)
[0035]
FIG. 8 is an operation flowchart of the subroutine in the power save 1 state, in which it is determined whether or not the cause of halt release is 0.5 seconds (step 1202). In the case of YES, the second counter is counted up (step 1204), followed by a determination of positive 15 seconds (step 1205). In the case of YES, the hour / minute counter is counted up (step 1206). The hour / minute hand is moved for 15 seconds (step 1207), and the process returns to the main program in the return subroutine (step 1208).
Further, it is determined whether or not the cause of the halt release is 0.5 second (step 1202). If NO, it is determined whether or not it is a switch (step 1209). If YES, the power save 1 state is released (step 1210). )I do.
In addition, it is determined whether or not the cause of the halt release is a switch (step 1209). If NO, it is determined whether or not it is photovoltaic (step 1211). If YES, the power save 1 state is canceled (step 1212). Do. (Step 1201 to Step 1212)
[0036]
FIG. 9 is an operation flowchart of the subroutine in the power save 2 state. It is determined whether or not the cause of halt release is 2 hours (step 1302). If YES, the 2-hour counter is counted up (step 1303). Whether or not it is the beginning of the month is determined (step 1304). If YES, a smoothing operation (step 1305) is performed, and the process returns to the main program in a return subroutine (step 1306).
Further, it is determined whether or not the cause of the halt release is 2 hours (step 1302). If NO, it is determined whether or not it is photovoltaic power generation (step 1307). If YES, the power save 2 state is canceled (step 1308). I do.
In this embodiment, the second hand 101 is fast-forwarded with 60 forward rotations, and the hour / minute hands 102 and 103 are fast-forwarded with 15 forward rotations, 30 reverse rotations, and 15 forward rotations. The plate 104 is fast-forwarded with 15 forward rotations, 30 reverse rotations, and 15 forward rotations. Therefore, the stop positions of the second hand 101, the minute hand 102, the hour hand 103, and the date plate 104 do not change before and after the leveling operation. (Step 1301 to Step 1308)
[0037]
FIG. 10 is an operation flowchart of a subroutine representing another embodiment in the power save 2 state. It is determined whether or not the cause of halt release is 2 hours (step 1402). If YES, the 2-hour counter is incremented (step 1403), and then it is determined whether or not the voltage has dropped (step 1404). If YES, then it is determined whether or not it is the beginning of the month (step 1405). It is determined whether or not every month (step 1406). If YES, the leveling operation 2 (step 1407) is performed, and the process returns to the main program in the return subroutine (step 1408).
Further, in the determination of whether or not every six months (step 1406), in the case of NO, the leveling hand movement 1 (step 1409) is performed.
In addition, it is determined whether or not the cause of the halt release is 2 hours (step 1402). If NO, it is determined whether or not it is photovoltaic (step 1410). If YES, the power save 2 state is canceled (step 1411). I do.
In this embodiment, the leveling hand 1 (step 1409) is fast-forwarded with 60 forward rotations of the second hand 101, and the hour / minute hands 102 and 103 are fast-forwarded with 15 forward rotations, 30 reverse rotations, and 15 forward rotations. The date plate 104 is fast-forwarded with 15 forward rotations, 30 reverse rotations, and 15 forward rotations.
In this embodiment, the leveling hand 2 (step 1407) is fast-forwarded with 60 forward rotations, the hour / minute hands 102 and 103 are forwarded with 720 forwards, and the date plate 104 is fast-forwarded with 7440 forward rotations. The That is, not only the second hand 101 but also the hour / minute hands 102 and 103 and the date plate 104 are all rotated once. Of course, the stop positions of the second hand 101, the minute hand 102, the hour hand 103, and the date plate 104 do not change before and after the leveling operation. (Step 1401 to Step 1411)
[0038]
As described above, in the second embodiment, the leveling operation is performed at the beginning of the month (0:00 am on the first day) in the power save 2 state (when the second hand 101, the hour / minute hands 102 and 103, and the date plate 104 are stopped). Furthermore, every six months, it is switched to the form of the leveling movement that is different from usual (for example, it moves more than one lap). Once every six months, the turn-off and time will increase, but on average there will be no effect.
The difference between the leveling hand 2 (step 1407) and the leveling hand 1 (step 1409) is not limited to this embodiment, and any one of the target, the number of driving strokes, the driving direction (polarity), etc. Any difference is acceptable.
Even in the power save 2 state, when the voltage drops, the running-in is not performed to extend the battery life.
Furthermore, the leveling is not limited to being performed at the beginning of the month.
[0039]
【The invention's effect】
As described above, according to the present invention, the mechanical mechanism unit is provided by providing the leveling means for operating the time display means when the pointer is stopped and the leveling control means for controlling the leveling means at every predetermined period when the pointer is stopped. However, it is now possible to move smoothly from the pointer stop state and return without any error.
[Brief description of the drawings]
FIG. 1 is a circuit block diagram of an embodiment of the present invention.
FIG. 2 is a detailed view of a second counter which is one of the circuit components of the present invention.
FIG. 3 is a detailed view of an hour / minute counter which is one of the circuit components of the present invention.
FIG. 4 is a detailed view of a day counter which is one of the circuit components of the present invention.
FIG. 5 is a circuit block diagram of another embodiment of the present invention.
FIG. 6 is an operation flowchart of another embodiment of the present invention.
7 is an operation flowchart of a subroutine in a normal state shown in FIG. 6. FIG.
FIG. 8 is an operation flowchart of a subroutine in a power save 1 state shown in FIG. 6;
9 is an operation flowchart of a subroutine in a power save 2 state shown in FIG. 6. FIG.
10 is an operation flowchart of a subroutine of another embodiment of the power save 2 state shown in FIG. 6; FIG.
[Explanation of symbols]
1 Oscillator circuit
Divide-by-2 circuit
3-second counter
4 hour counter
5 day counter
6 seconds smoothing
7 hours leveling
8 days running
9 Pointer stop means
10 Leveling control means
20 Power generation means
21 Power generation detection means
22 Backflow prevention means
23 Power storage means
24 Voltage detection means
25 Conversion circuit

Claims (7)

In an electronic timepiece having an oscillation circuit, a frequency dividing circuit, a time counter, a power source, a pointer, and a pointer stop means for stopping and controlling the pointer,
Leveling means for operating the pointer when the pointer stops ,
Providing a calibrated hand movement control means for controlling the conditioned hand movement means at predetermined intervals ,
Furthermore, a voltage detection means for detecting the voltage of the power supply is provided,
The electronic timepiece with a pointer stop function, wherein the leveling control means is controlled by the voltage detection means . The pointer is composed of a plurality of pointers driven by a plurality of motors ,
The electronic timepiece with a pointer stop function according to claim 1, wherein a pointer for smoothing the hand when the pointer is stopped is switched according to a stop period . In an electronic timepiece having an oscillation circuit, a frequency dividing circuit, a time counter, a power source, a pointer, and a pointer stop means for stopping and controlling the pointer,
Leveling means for operating the pointer when the pointer stops,
Providing a calibrated hand movement control means for controlling the conditioned hand movement means at predetermined intervals,
Further, the pointer is composed of a plurality of hands driven by a plurality of motors,
The leveling needle movement control means switches a pointer for leveling when the pointer is stopped depending on a stop period.
An electronic timepiece with a pointer stop function. The electronic timepiece with a pointer stop function according to any one of claims 2 to 3, wherein a hand movement mode of the pointer that performs leveling when the pointer is stopped is switched according to a stop period. In an electronic timepiece having an oscillation circuit, a frequency dividing circuit, a time counter, a power source, a pointer, and a pointer stop means for stopping and controlling the pointer,
Leveling means for operating the pointer when the pointer stops,
Providing a calibrated hand movement control means for controlling the conditioned hand movement means at predetermined intervals,
The pointer has at least a second hand,
The electronic timepiece with a pointer stop function , wherein the leveling control unit switches a mode of a pointer that performs leveling when the pointer is stopped depending on a stop period . Wherein the power source have a a power generation unit storage means, further,
Power generation detection means for detecting the power generation state of the power generation means,
The electronic timepiece with a pointer stop function according to any one of claims 1 to 5, wherein the pointer stop means is controlled by the power generation detection means . The electronic timepiece with a pointer stop function according to claim 6 , wherein the power generation means is a solar cell.

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