JP3936898B2 - Time information acquisition method and radio-controlled clock - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an improved method and apparatus for acquiring time information by selectively receiving one frequency from a plurality of frequencies including time information.
[0002]
[Prior art]
Currently, in Japan, the Communications Research Laboratory of the Ministry of Internal Affairs and Communications transmits and operates long-wave standard radio waves including time information using two transmission frequencies of 40 kHz (Fukushima station) and 60 kHz (Fukuoka station). The signal of time information included in this long wave standard radio wave is a binary code containing information such as minute information, hour information, date information from January 1, last 2 digits year information, etc. Sending serially. Specifically, using rectangular pulses in a 1-second cycle frame, 1-bit information “0” and “1” are represented by rectangular pulse widths (durations) of 800 ms and 500 ms, and marker P information is the same. A rectangular pulse having a pulse width of 200 ms in a one-second period frame is used.
[0003]
When the time information is updated by receiving such a long wave standard radio wave, accurate time update can be performed. Therefore, a radio wave correction watch using a device that periodically receives and corrects the long wave standard radio wave including the time information is manufactured. Yes. In this case, since there are a plurality of radio waves including the time information having the transmission frequencies of 40 kHz and 60 kHz, the probability that the radio-controlled timepiece can receive the time information increases accordingly. That is, if one of a plurality of radio waves having a transmission frequency of 40 kHz and 60 kHz including time information is selectively received and the time information is acquired and used for time correction, The radio-controlled watch can be used in a wide range of uses and applications.
[0004]
In Japanese Patent Application No. 2001-99859 filed on March 30, 2001, before receiving the time information, the reception status of each of the two radio waves of 40 kHz and 60 kHz including the time information is compared. Thus, a time information acquisition method and apparatus for performing reception by selecting a frequency that is easier to receive (that is, selecting a station) have been proposed. As another example, when reception is successful once at one frequency, the same frequency (that is, the same station) is used thereafter until station selection is performed after reception of this frequency has failed a predetermined number of times. There is something to continue receiving.
[0005]
[Problems to be solved by the invention]
However, before receiving the time information, if the operation of selecting and receiving the frequency that is easier to receive by comparing the reception states of the two radio waves of 40 kHz and 60 kHz including the time information is performed, The reception time becomes longer by the time required for receiving the radio wave and comparing, selecting and receiving the reception state. For this reason, when power is consumed and a battery is used, the battery life is shortened.
[0006]
In addition, when the reception is successful once at one frequency, the reception is performed at the same frequency until the reception fails continuously for a predetermined number of times. If the predetermined number of times is too large, power can be saved, but it is difficult to acquire time information and correct the time. Conversely, if the predetermined number of times is too small, power cannot be saved.
The present invention aims to solve the above problems.
[0007]
[Means for Solving the Problems]
The present invention described in claim 1 intermittently performs a reception operation of selectively receiving a radio wave of one frequency from radio waves including standard time transmitted at a plurality of frequencies, and during the reception operation, A time information acquisition method for acquiring the standard time information from the radio wave that has been successfully received, only receiving a radio wave of one frequency during one reception operation, and failed to receive the radio wave of the one frequency In this case, a time information acquisition method for receiving only radio waves having a frequency different from the frequency at which reception failed in the previous reception operation at the next reception operation is provided.
[0009]
Claim 1 In the present invention described in the above, a reception operation for selectively receiving a radio wave of one frequency from radio waves including a standard time transmitted at a plurality of frequencies is intermittently performed, and the reception is successful during the reception operation. In the time information acquisition method for acquiring the standard time information from the radio wave, when only one frequency radio wave is received during one reception operation and the radio wave reception of the one frequency fails, the next time When the reception operation time is a predetermined time, the radio waves of the plurality of frequencies are received, the reception states are compared, the radio waves of the one frequency are selected and received, and the next reception operation time is the predetermined time A time information acquisition method is provided that receives only radio waves having a frequency different from the frequency at which reception failed in the previous reception operation.
[0010]
Claim 1 According to the present invention described in the above, when only one frequency radio wave is received during one reception operation and reception of the one frequency radio wave fails, the next reception operation time is a predetermined time. In this case, the radio waves of the plurality of frequencies are received, the reception states are compared, the radio waves of the one frequency are selected and received, and if the next reception operation time is different from the predetermined time, the previous reception Only radio waves having a frequency different from the frequency at which reception failed due to the operation are automatically selected and received. This is not done unnecessarily by comparison of reception conditions with large power consumption, but for example, at a predetermined time such as midnight, when there are relatively few noise sources and radio wave reception is good. To improve the possibility of acquiring time information, and for other time periods, automatically select a different frequency using an empirical rule that the frequency of the previous reception failure is likely to fail the next time. This avoids wasting power. According to this method, for example, by selecting a time with less noise source and selecting and receiving a radio wave reception state at least once a day, it is possible to save power battery and save time information. Improve the chance of acquisition.
[0011]
Claim 2 In the present invention described in the above, a reception operation for selectively receiving a radio wave of one frequency from radio waves including a standard time transmitted at a plurality of frequencies is intermittently performed, and the reception is successful during the reception operation. A time information acquisition method for acquiring the standard time information from the radio wave, wherein the radio wave of the plurality of frequencies is received during one reception operation, and the reception states of the respective frequencies are compared to obtain the radio wave of the one frequency. When performing a reception operation to select and receive, if any of the frequencies is determined to be reception failure due to the comparison result and reception fails, the frequency is selected in advance from among a plurality of selectable frequencies during the next reception operation. A time information acquisition method for receiving only radio waves of a specific frequency is provided.
[0012]
Claim 2 According to the present invention described in the above, if any frequency is not received even if the reception state comparison operation is performed, the comparison operation is not performed at the next reception operation, and a specific frequency, for example, 40 kHz, is not detected. Try to receive radio waves. If reception of any frequency fails in the operation of selecting and receiving the better one by comparing the reception states of radio waves of multiple frequencies, for example, there is a noise source that emits strong noise nearby or multiple There is a possibility that the propagation status of both radio waves is poor, and the next reception operation is also close to the previous time in time, so the same state continues, even if the comparison selection operation Similarly, there is a high possibility that reception will fail. Therefore, in such a case, the comparison / selection operation that consumes a large amount of power is stopped, and radio waves of a specific frequency are received until reception is successful. In this way, wasteful power consumption due to wasteful comparison / selection reception operation is avoided, and over time, the radio wave propagation state is restored or the noise source disappears, enabling reception of radio waves of a specific frequency. Waiting to become successful in receiving and acquiring time information.
[0013]
Claim 3 In the present invention described in the above, when reception of the radio wave of the specific one frequency out of a plurality of selectable frequencies fails, the last selected out of the plurality of selectable frequencies during the next reception operation The time information acquisition method according to claim 3, wherein only a radio wave having a frequency different from the specific one frequency is received.
[0014]
Claim 3 According to the present invention described in the above, if any of the frequencies cannot be selectively received even if the reception state comparison operation is performed, the reception operation after the next time is performed once without performing the comparison operation. The radio wave is received by changing the frequency alternately. If reception of any frequency fails in the operation of selecting and receiving the radio wave of multiple frequencies and selecting the better one, for example, a noise source that emits strong noise nearby is used as described above. There is a possibility that it is present or the propagation state of multiple radio waves is both bad, and since it is close in time when performing the next periodic reception operation, the same state continues, Even if a comparison / selection operation is performed, there is a high possibility that reception will similarly fail. Therefore, in such a case, the comparison / selection operation with large power consumption is stopped, and the reception operation is performed by alternately changing the frequency every time the reception operation is performed until the reception is successful. In this way, wasteful power consumption due to unnecessary comparison and selection operations can be avoided, and over time, the radio wave propagation state can be restored or the noise source can disappear, and radio waves of any frequency can be received. Waiting to become successful in receiving and acquiring time information.
[0015]
Claim 4 The invention described in claim 1 3 In the case where the reception operation for receiving only one frequency radio wave in a single reception operation has failed continuously for a predetermined number of times, the next reception operation receives the radio waves of the plurality of frequencies and sets each reception state. A time information acquisition method for selecting and receiving radio waves of the one frequency in comparison is provided.
[0016]
Claim 4 According to the present invention described in the above, when a reception operation for receiving only one frequency radio wave in a single reception operation fails for a predetermined number of times, the radio waves of the plurality of frequencies are transmitted during the next reception operation. By receiving and comparing the respective reception states and selecting and receiving the radio waves of the one frequency, it is possible to escape from the situation where radio waves of any frequency cannot be received due to periodic radio wave conditions.
[0017]
Claim 5 The present invention as described in claim 1 to claim 1 to 4 A time information acquisition device that implements the time information acquisition method according to any one of the above, a time counter that measures time, and a time measurement time of the time counter based on the standard time information acquired by the time information acquisition device Provided is a radio wave correction clock including a time correction unit to be corrected.
[0018]
Claim 5 According to the present invention described in claim 1, the radio-controlled timepiece is claimed in claims 1 to 4 By including the time information acquisition device that implements the time information acquisition method described in any of the above, it is possible to reliably correct the time by radio waves and to extend the battery life by minimizing the waste of power due to the channel selection operation. .
[0019]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, about the same structure in an accompanying drawing, the same referential mark is attached | subjected and duplication description is abbreviate | omitted.
[0020]
FIG. 1 is a block diagram schematically showing the configuration of a radio-controlled timepiece 1 according to an embodiment of the present invention. The radio-controlled timepiece 1 receives long-wave standard time (JJY) radio waves including time information transmitted at a plurality of frequencies, 40 kHz and 60 kHz, by the antenna 2. The antenna 2 selects and receives one of the long wave standard time radio waves having a frequency of 40 kHz or 60 kHz by the frequency selection means 3.
[0021]
The frequency selection means 3 is, for example, a tuning circuit as shown in FIG. 2, and a coil L, a capacitor C1, and a capacitor C2 are connected in parallel, and according to the frequency selection method of the present invention described in detail below. The switch SW is turned on or off by the frequency switching signal f from the control unit 4 in FIG. 1, the tuning frequency is switched to either 40 kHz or 60 kHz, and the reception frequency is selected. .
[0022]
A description will be given with reference to FIG. 1 again. A long standard time radio wave having a frequency of 40 kHz or 60 kHz selectively received by the frequency selection means 3 is output to the radio wave reception block 5. The radio wave receiving block 5 detects the received long wave standard time radio wave and outputs the included time code to the control unit 4.
[0023]
FIG. 3 shows the detected time code. The time code is represented by a binary code of one minute cycle. Each binary code is represented using a rectangular pulse within a one second period frame. The falling edge of this rectangular pulse (or the rising edge when the polarity of the rectangular pulse is reversed) is synchronized in time with the start of each second. “0” or “1” of 1-bit information is represented by whether the width (duration) of the rectangular pulse is 800 ms or 500 ms. The marker P information is represented using a rectangular pulse having a pulse width of 200 ms within the same 1-second cycle frame.
[0024]
At the beginning and end of each minute, there are marker signals M and P0 each having a width of 200 ms. Therefore, when the two marker signals P0 and M are continuous, the falling edge of the second marker signal M represents the beginning of every minute. A binary code represented by a rectangular pulse from the start of every minute to the next marker signal P1 represents a code of minute information. A rectangular pulse up to the next marker signal P2 represents a time information code. The rectangular pulses up to the next two marker signals P3 and P4 represent the total date and parity code from January 1, and the rectangular pulses up to the next marker signal P5 represent the last two digits of the year. The last marker signal P0 represents the day of the week and leap second code.
[0025]
Again, a description will be given with reference to FIG. The control unit 4 reads the falling edge of the detected rectangular pulse of the time code, and determines whether the interval between the falling edges is within a predetermined range (in this embodiment, for example, 1 second ± 5 ms). If it is determined to be input, an OK signal is output to the reception state storage means 6. If not, an NG signal is output to the reception state storage means 6. The interval between the falling edges of the rectangular pulses is exactly 1 second if the reception state of the long wave standard radio wave is good. However, if the reception state is poor due to noise or the like, this interval varies from 1 second. The reception state storage means 6 has an OK counter and an NG counter that respectively count the number of OK signals and NG signals separately from the reception frequency, 40 kHz or 60 kHz. The predetermined range can be changed as appropriate.
[0026]
The control unit 4 alternately switches the frequency switching signal f to the frequency selecting means 3, selectively receives one of the long frequency standard time radio waves having a plurality of frequencies of 40 kHz and 60 kHz, and receives the received radio wave as a radio wave reception block. As a result of detecting the interval of the falling edge of the rectangular pulse of the time code detected for a predetermined time for each frequency, the count of the OK counter for each frequency in the reception state storage means 6 is relatively large. It is possible to determine that the reception state of the radio wave of one frequency is good, or to determine that the reception state of the radio wave of the frequency having a relatively small count of the NG counter for each frequency is good.
[0027]
The control unit 4 further determines the interval between the falling edges of the rectangular pulses of the time code detected for a predetermined time with respect to the received radio wave. As a result, the number of OK counters in the reception state storage means 6 is determined. If the number of NG counters is greater than or equal to the predetermined number, or if the number of NG counters is less than or equal to the predetermined number, it may be determined that the radio wave has been successfully received from the transmitting station that is transmitting the frequency, that is, the station has been successfully selected. it can. If the OK counter is less than or equal to the predetermined number, or if the number of NG counters is greater than or equal to the predetermined number, it can be determined that reception, that is, station selection has failed. Even if it is determined by the above comparison method that the reception state is relatively better than radio waves of other frequencies, it may be insufficient to actually receive and acquire time information. After determining whether the number of OK counters is equal to or larger than a predetermined number (or the number of NG counters equal to or smaller than a predetermined number), it is determined whether station selection is successful.
[0028]
When the control unit 4 selects the frequency with the better reception state as described above and determines that the radio wave is suitable for reception for acquiring time information, that is, the station selection has been successful, The frequency selection result, 40 kHz or 60 kHz, is sent to the frequency selection result storage means 7 to store the frequency.
[0029]
When the control unit 4 selects the frequency with the better reception state as described above and determines that the radio wave is not suitable for reception for acquiring time information, that is, the station selection has failed. Similarly, the frequency selection result (frequency with better reception state), 40 kHz or 60 kHz, is sent to the frequency selection result storage means 7. Then, 1 is added to the number n of the counters in the reception result storage means 8.
[0030]
The control unit 4 sends a frequency switching signal f to the frequency selection means 4 so as to continuously receive a radio wave of a frequency determined to have been successfully selected for a predetermined time, for example, 4 minutes, and the radio wave of that frequency is predetermined. The time code is continuously received and detected, and the time code shown in FIG. 3 is read. If the time code is successfully read at least twice during the predetermined reception time and there is no contradiction between the time codes, it is determined that the time information has been successfully acquired. It is necessary to read the time code at least twice, and it is necessary to read the time code only once, and verify that there is no contradiction compared with the time code read at least once again. Because it is necessary to do.
[0031]
If acquisition of the time information is successful, the control unit 4 resets the number n of the counters in the reception result storage means 8 to zero as reception success. Based on the acquired time information, the internal clock 9 is corrected, and the analog display or digital display of the time by the time display block 10 is corrected.
[0032]
If the time code reading is not successful within a predetermined time, the control unit 4 adds 1 to the number n of the counters in the reception result storage means 8 assuming that the reception has failed.
[0033]
Next, with reference to FIG. 4, the first time adjustment operation of the radio-controlled timepiece 1 of the present embodiment, that is, the operation at the time of resetting such as battery replacement will be described. When a reset button (not shown) of the clock 1 is pressed (step 40), the clock 1 is forcibly entered into the station selection mode. That is, the watch 1 starts to alternately receive radio waves having a plurality of frequencies of 40 kHz and 60 kHz (step 41), compares the reception states (for example, compares the number of OK counters within a predetermined time), and A radio wave having a better frequency (for example, one having a larger number of OK counters) is selected (step 42). If the radio wave of the frequency selected as being in good reception is suitable for acquiring time information (for example, the number of OK counters within a predetermined time is equal to or greater than the predetermined number, step 43), the station-selected frequency of 40 kHz Alternatively, 60 kHz is stored in the frequency selection result storage means 7 (step 44), and the time code of the radio wave of the frequency selected by the station is received for a predetermined time (step 45).
[0034]
If the radio wave of the frequency selected as good reception is not suitable for acquiring time information (for example, the number of OK counters within a predetermined time is less than the predetermined number, step 43), the radio wave for station selection Is notified or displayed (step 46). If the time code is successfully read from the radio wave of the frequency selected by the station (for example, when the time code can be read at least twice within a predetermined time without any contradiction, step 47), the reception result storage means 8 is reset to zero (step 48), the time of the internal clock 9 of the clock 1 is corrected, and the time display is also corrected (step 49). Then, the reception ends (step 50). If reading of the time code from the radio wave of the frequency selected by the station has failed (for example, if the time code cannot be read twice consistently within a predetermined time, step 47), notification that the radio wave reception has failed Alternatively, display is made (step 46), and reception is terminated (step 50).
[0035]
Next, a frequency selection method according to an embodiment of the present invention after the radio-controlled timepiece 1 is reset will be described with reference to FIG. The radio-controlled timepiece 1 is reset and periodically, for example, in the present embodiment, every one hour, one of a plurality of standard time radio waves having a frequency of 40 kHz and 60 kHz is selected and received to obtain time information. Acquire and correct the time.
[0036]
Periodically, for example, every other hour, reception is started (step 51), and the content n of the count counter in the reception result storage means 8 is read to determine whether n is less than 24 (step). 52). If the content n of the count counter is less than 24, it means that the time has been successfully acquired and the time has been corrected within the past 24 hours. Thus, if n is less than 24, the operation of receiving, comparing, and selecting radio waves of multiple frequencies is not performed. Next, it is determined whether n = 0 (step 53). If n = 0, it means that the time adjustment has been performed successfully by acquiring the previous time information, so the frequency selected immediately before stored in the frequency selection result storage means 7 is read ( Step 54), receiving radio waves of that frequency. If n = 0 is not satisfied, it means that acquisition of at least the previous time information has failed, so that it is different from the frequency (for example, 40 kHz) selected and received immediately before stored in the frequency selection result storage means 7. A frequency (for example, 60 kHz) is selected and stored in the frequency selection result storage means 7 (step 55). Then, the selected frequency stored in the frequency selection result storage means 7 is read (step 54), and radio waves of that frequency are received over a predetermined time (several minutes, for example, 5 minutes). In other words, the radio wave of the frequency that succeeded in acquiring the previous time information has a high probability of succeeding this time, so select that frequency, and the radio wave of the failed frequency has a high probability of failing this time, so select another frequency. .
[0037]
The time code (shown in FIG. 3) is detected by detecting the radio wave received during the predetermined time (step 56), and the time code is consistent at least twice within a predetermined time (for example, 5 minutes) from the radio wave. It is determined whether or not the reception is successful (step 57). If the reception is successful, the content n of the count counter in the reception result storage means 8 is reset to zero (step 58), and the reception ends (step 60). The time is corrected based on the acquired time code. If reception of the time code has failed, 1 is added to the content n of the count counter in the reception result storage means 8 (step 59), the reception is terminated (step 60), and the time is not corrected.
[0038]
If it is determined in step 52 that the content n of the count counter is 24 or more, it means that time information acquisition and time adjustment have not been performed within the past 24 hours, go to step 61, and Then, it is determined whether the internal time of the current clock 1 (the time of the internal clock 9) is from 2 o'clock to 5 o'clock or from 14 o'clock to 17 o'clock. If it is 2 o'clock to 5 o'clock or 14 o'clock to 17 o'clock, the station selection operation of step 42 is executed (the same operation as the station selection step 42 described in FIG. 4). This is the time zone from 2 o'clock to 5 o'clock is midnight or dawn, and it is considered that there are few noise radio sources due to the sun and human activities, and the radio wave reception state is relatively good. From 17:00 to 17:00, there is a difference of 12 hours from this time zone, and it is selected because of the difference of 12 hours.
[0039]
In the next step 43, it is determined whether or not the station selection has succeeded (the same operation as the station selection success determination step 43 described above in FIG. 4). If it is determined in step 43 that station selection has failed, the frequency with the better reception state is stored in the frequency selection result storage means 7 (step 64), and the count counter in the reception result storage means 8 1 is added to the content n (step 59), and the reception is terminated (step 60). In this case, the time is not corrected. If it is determined in step 43 that the station has been successfully selected, the frequency of the selected station is stored in the frequency selection result storage means 7, and the selected frequency is received for a predetermined time (step). 54). In step 56, the received radio wave is detected in the same manner as described above to read the time code. Thereafter, step 57, step 58 or 59, and step 60 are performed in the same manner as described above.
[0040]
If it is determined in step 61 that the current time is not 2 o'clock to 5 o'clock or 14 o'clock to 17 o'clock, the station switching operation in step 55 is executed and stored in the frequency selection result storage means 7. The selected frequency, for example, 40 kHz, is selected, for example, 60 kHz, and in step 54, the frequency selection result storage means 7 newly stores a different frequency, for example, 60 kHz. This is because a frequency different from the frequency that failed to be acquired in the previous time information is selected and received in the subsequent step 56. Steps 57, 58 or 59, 60 are performed in the same manner as described above.
[0041]
FIG. 6 illustrates a frequency selection method after resetting the radio-controlled timepiece 1 according to another embodiment. In the frequency selection method of FIG. 6, the same parts as those of the method described in FIG. 6 is different from FIG. 5 in the case where it is determined in step 61 that it is outside the time between 2 o'clock and 5 o'clock and between 14 o'clock and 17 o'clock, the process goes to step 65 and the current time is even. It is determined whether the time is an odd time. If it is an even time (including 0), go to step 66 and select a frequency of 60 kHz. If it is an odd time, go to step 67 and select a frequency of 40 kHz. The frequency selected in this way is stored in the frequency selection result storage means 7. In step 54, the selected frequency stored in the frequency selection result storage means 7 is read out, and radio waves of the selected frequency are received for a predetermined time (for example, 5 minutes) in order to acquire time information.
[0042]
FIG. 7 illustrates a frequency selection method after resetting the radio-controlled timepiece 1 according to still another embodiment. In this embodiment, reception is started periodically, for example, every hour (step 71), and the content n of the counter in the reception result storage means 8 is read so that n is less than 22 or not. It is determined whether or not (step 72). If the content n of the count counter is less than 22, it means that the time has been successfully acquired and the time has been corrected within the past 22 hours. Thus, if n is less than 22, the operation of receiving, comparing, and selecting radio waves of multiple frequencies is not performed. Next, it is determined whether n = 0 (step 73). If n = 0, it means that the time adjustment has been performed successfully by acquiring the previous time information, so the frequency selected immediately before stored in the frequency selection result storage means 7 is read ( Step 74), receiving radio waves of that frequency. If n = 0 is not satisfied, it means that acquisition of at least the previous time information has failed, so that it is different from the frequency (for example, 40 kHz) selected and received immediately before stored in the frequency selection result storage means 7. A frequency (for example, 60 kHz) is selected and stored in the frequency selection result storage means 7 (step 75). Then, the newly selected frequency stored in the frequency selection result storage means 7 is read (step 74), and radio waves of that frequency are received for a predetermined time (for example, 5 minutes). In other words, the radio wave of the frequency that succeeded in acquiring the previous time information has a high probability of succeeding this time, so select that frequency, and the radio wave of the failed frequency has a high probability of failing this time, so select another frequency. .
[0043]
Whether the time code (shown in FIG. 3) was detected by detecting the radio wave received during the predetermined time (step 76), and the time code without any contradiction was successfully received from the radio wave at least twice within the predetermined time. (Step 77), if successful, the count n of the count counter in the reception result storage means 8 is reset to zero (step 78), the reception is terminated (step 80), and the acquired time Correct the time based on the code. If reception of the time code has failed, 1 is added to the content n of the count counter in the reception result storage means 8 (step 79), the reception is terminated (step 80), and the time is not corrected.
[0044]
If it is determined in step 72 that the content n of the count counter is 22 or more, it means that the acquisition of time information and the time adjustment have not been performed within the past 22 hours, and the process goes to step 81. Then, it is determined whether n = 24. If n = 24, it indicates that acquisition of time information has failed over the past 24 hours. Therefore, go to step 82, reset n to zero, and set n = 0. Then, it goes to step 42 for station selection. If n = 24 in step 81, it indicates that 24 hours have not elapsed since the previous time acquisition and time correction. Then, the operation goes to step 42 to execute the station selection operation (the same operation as the station selection step 42 described in FIG. 4).
[0045]
This method means that station selection operations with large power consumption are continuously performed 22 hours after successful acquisition of the previous time information, up to 3 times a day. This means that the last successful time zone means that the radio wave reception status is the best time zone during the day. Aims to limit consumption and succeed in obtaining time information.
[0046]
In the next step 43, it is determined whether or not the station selection has succeeded (the same operation as the station selection success determination step 43 described above in FIG. 4). If it is determined in step 43 that station selection has failed, the frequency with the better reception state is stored in the frequency selection result storage means 7 (step 83), and the count counter in the reception result storage means 8 1 is added to the content n (step 79), and the reception is terminated (step 80). In this case, the time is not corrected. If it is determined in step 43 that the station has been successfully selected, the frequency of the selected station is stored in the frequency selection result storage means 7, and the selected frequency is stored for a predetermined time (for example, 5 minutes). (Step 74). In step 76, the received radio wave is detected and the time code is read in the same manner as described above. Thereafter, step 77, step 78 or 79, and step 80 are performed in the same manner as described above.
[0047]
FIG. 8 illustrates a frequency selection method according to still another embodiment. In the frequency selection method of FIG. 8, the same parts as those of the method described in FIG. 8 differs from FIG. 7 in step 84 in which it is determined whether n is less than 5. n indicates the number of times of continuous failure after acquisition of time information from the received radio wave, or after failure of station selection of the received radio wave after 24 consecutive failures to acquire time information. If n is less than 5, go to step 74 and use the frequency selected for the previous reception stored in the frequency selection result storage means 7 as it is for a predetermined time (for example, 5 minutes). Receive and get the time code. If n is 5 or more at step 84, go to step 75, select a frequency different from that stored in the frequency selection result storage means, and select the selected frequency in the frequency selection result storage means 7. To remember. In step 74, the selected frequency stored in the frequency selection result storage means 7 is read out, and radio waves of the selected frequency are received for a predetermined time (for example, 5 minutes) in order to acquire time information. In this method, immediately after succeeding in acquiring time information or immediately after failing in station selection, a predetermined number of times (for example, 4 times) is fixed at the same frequency as the time information acquisition succeeded or station selection failed last time. By receiving, if it fails due to a short-term event, we expect that if this short-term event stops, the reception can be successful.
[0048]
【The invention's effect】
As described above, according to the present invention, in a method of selectively selecting and receiving radio waves including time information transmitted at a plurality of frequencies, the operation of comparing and receiving radio waves that consume power is reduced. While receiving radio waves reliably, it is possible to acquire time information. Therefore, it is possible to prevent consumption of the power battery and correct the time accurately by radio waves.
[0050]
Claim 1 According to the present invention described in the above, the selection operation based on the comparison of the reception state with large power consumption is not performed unnecessarily, for example, at midnight when there are relatively few noise sources in the day and the reception state of the radio wave is good. The frequency of acquisition of time information is improved by performing it at a predetermined time, etc., and at other times, different frequencies are used by using an empirical rule that the frequency that failed in the previous reception is high in the probability of failure in the next time. By automatically selecting, you avoid wasting power. According to this method, for example, by selecting a time with less noise source and selecting and receiving a radio wave reception state at least once a day, it is possible to save power battery and save time information. Improve the chance of acquisition.
[0051]
Claim 2 According to the present invention described in the above, if reception of any frequency fails in the operation of selecting and receiving the better one by comparing the reception states of radio waves of a plurality of frequencies, for example, strong noise nearby There is a possibility that there is a noise source that emits noise, or the propagation state of multiple radio waves is both bad, and the same state continues because the next reception operation is close to the previous time in time. Therefore, even if the comparison / selection operation is performed, there is a high possibility that reception will similarly fail. Therefore, in such a case, the comparison / selection operation that consumes a large amount of power is stopped, and radio waves of a specific frequency are received until reception is successful. In this way, wasteful power consumption due to wasteful comparison / selection reception operation is avoided, and over time, the radio wave propagation state is restored or the noise source disappears, enabling reception of radio waves of a specific frequency. Waiting to become successful in receiving and acquiring time information.
[0052]
Claim 3 According to the present invention described in the above, when reception of any frequency fails in an operation of selecting and receiving a radio wave having a plurality of frequencies, whichever is better, for example, as described above, There is a possibility that there is a noise source that emits strong noise nearby, or the propagation state of multiple radio waves is both bad, and it is close in time during the next periodic reception operation The same state continues, and even if a comparison / selection operation is performed, there is a high possibility that reception will similarly fail. Therefore, in such a case, the comparison / selection operation with large power consumption is stopped, and the reception operation is performed by alternately changing the frequency every time the reception operation is performed until the reception is successful. In this way, wasteful power consumption due to unnecessary comparison and selection operations can be avoided, and over time, the radio wave propagation state can be restored or the noise source can disappear, and radio waves of any frequency can be received. Waiting to become successful in receiving and acquiring time information.
[0053]
Claim 4 According to the present invention described in the above, when a reception operation for receiving only one frequency radio wave in a single reception operation fails for a predetermined number of times, the radio waves of the plurality of frequencies are transmitted during the next reception operation. By receiving and comparing the respective reception states and selecting and receiving the radio waves of the one frequency, it is possible to escape from the situation where radio waves of any frequency cannot be received due to periodic radio wave conditions.
[0054]
Claim 5 According to the present invention described in claim 1, the radio-controlled timepiece is claimed in claims 1 to 4 By including the time information acquisition device that implements the time information acquisition method described in any of the above, it is possible to reliably correct the time by radio waves and to extend the battery life by minimizing the waste of power due to the channel selection operation. .
[Brief description of the drawings]
FIG. 1 is a block diagram schematically showing a radio-controlled timepiece according to one embodiment of the present invention.
FIG. 2 is a diagram showing a circuit of frequency selection means in FIG. 1;
FIG. 3 is a pulse timing chart showing a time information code included in a time standard radio wave.
FIG. 4 is a flowchart showing a method for correcting a time by comparing and selecting a radio wave including time information of two frequencies when the radio wave reception clock is reset.
FIG. 5 is a flowchart illustrating a method for correcting a time by periodically selecting and receiving one of radio waves including time information of two frequencies, according to an embodiment of the present invention.
FIG. 6 is a flowchart showing a method of correcting a time by a radio wave reception clock according to another embodiment of the present invention by periodically selecting and receiving one of radio waves including time information of two frequencies.
FIG. 7 is a flowchart showing a method of correcting a time by periodically selecting and receiving one of radio waves including time information of two frequencies according to another embodiment of the present invention.
FIG. 8 is a flowchart showing a method for correcting the time by periodically selecting and receiving one of radio waves including time information of two frequencies, according to another embodiment of the present invention.
[Explanation of symbols]
1 Radio correction clock
2 Antenna
3 Frequency selection means
4 Control unit
5 radio wave reception block
6 Reception status storage means
7 Frequency selection result storage means
8 Reception result storage means
9 Internal clock
10 Time display block

Claims (5)

  The standard time information is obtained from the radio wave that has been successfully received during the reception operation by intermittently performing a reception operation of selectively receiving a radio wave of one frequency from radio waves including a standard time transmitted at a plurality of frequencies. Is a time information acquisition method for acquiring a radio wave of only one frequency during a single reception operation, and if reception of the radio wave of the one frequency fails, the next reception operation time is a predetermined time. In the case of receiving the radio waves of the plurality of frequencies, comparing each reception state, selecting and receiving the radio wave of the one frequency, and when the next reception operation time is different from the predetermined time, A time information acquisition method, wherein only a radio wave having a frequency different from a frequency at which reception has failed in a reception operation is received.   The standard time information is obtained from the radio wave that has been successfully received during the reception operation by intermittently performing a reception operation of selectively receiving a radio wave of one frequency from radio waves including a standard time transmitted at a plurality of frequencies. A reception operation for receiving radio waves of the plurality of frequencies at one reception operation, comparing the reception states of the radio waves, and selecting and receiving the radio waves of the one frequency. In the case where any of the frequencies is judged to be poorly received due to the comparison result of the plurality of frequencies when the reception is failed, a specific one preselected among the plurality of frequencies that can be selected at the next reception operation is performed. A time information acquisition method characterized by receiving radio waves of one frequency. If reception of the radio wave of the specific one frequency among the selectable frequencies fails, the specific one frequency selected last time among the selectable frequencies during the next reception operation is The time information acquisition method according to claim 2 , wherein any one of the different frequencies is received. In claim 3 , when a reception operation for receiving only one frequency radio wave in a single reception operation fails for a predetermined number of times, the next reception operation receives radio waves of the plurality of frequencies and A time information acquisition method comprising: comparing reception states and selecting and receiving radio waves of the one frequency. A time information acquisition device that implements the time information acquisition method according to any one of claims 1 to 4 , a time counter that measures time, and the time measurement based on the standard time information acquired by the time information acquisition device. A radio-controlled timepiece comprising a time correction unit that corrects the timekeeping time of the unit.

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