JP4964182B2 - Radio clock - Google Patents

Description

  The present invention relates to a standard radio wave receiving method for receiving a standard radio wave including time information, a radio timepiece for correcting time based on time information included in the received standard radio wave, and an electronic device incorporating the radio timepiece.

  In countries such as Germany, the United Kingdom, the United States, and Japan, so-called long-wave standard radio waves that transmit time information using a frequency of about several tens of kHz as a carrier wave are transmitted. In recent years, radio-controlled watches using this standard radio wave have become widespread. . In the long wave standard radio wave, the frequency of the carrier wave and the pulse waveform representing “0”, “1”, etc. of the data differ from country to country except that the data is transmitted in binary.

  For example, Patent Document 1 below discloses a timepiece with a radio wave correction function that receives a long wave standard radio wave and corrects the time as a conventional radio wave correction clock. As shown in Patent Document 1, it operates at regular time intervals and periodically receives a standard radio wave to correct the time. Specifically, the receiving means for receiving the time information receives the standard radio wave under the timing control of the reception permission signal based on the reception operation signal output from the time measuring means.

  FIG. 9 is an explanatory view showing the contents of the format of transmission data of standard radio waves (Japan). In FIG. 9, time data is transmitted at 1 bit / second as one frame. Within this frame, “minute”, “hour”, “integrated date” from January 1, “year” 2 It contains information such as digits and "day of the week".

  The transmitted data includes a marker “P” code in addition to “0” and “1”. Each waveform is as shown in FIGS. There are several “P” codes in one frame, and appear at the minute (0 seconds), 9 seconds, 19 seconds, 29 seconds, 39 seconds, 49 seconds, and 59 seconds. The “P” code appears only once at 59 seconds and 0 seconds in one frame, and the position where this “P” code appears is the minute position. That is, the time data such as the minute / hour data has a position in the frame determined based on the position of the minute, so that in order to extract the time data, it is necessary to first detect the minute position. Thereafter, for each bit transmitted every second, it is detected which of the three types of waveforms shown in FIGS.

To determine the three waveforms shown in FIGS. 10 to 12 performs sampling at two time points (T _A, T _B) as indicated by the broken line in the figure, or "High" at each time point The conventional method is to check the “Low” state. Specifically, T _A and T _B is, if each "High" and "High", the waveform of which "0" shown in FIG. 10, T _A and T _B are each "High" and If “Low”, the waveform is “1” as shown in FIG. 11. If T _A and T _B are “Low” and “Low”, respectively, “P” as shown in FIG. It becomes a waveform.

  FIG. 13 is an explanatory diagram showing the contents of the standard radio wave (US) transmission data format. Compared to the format of Japanese standard radio wave transmission data shown in FIG. 9, “minute”, “hour”, and “integrated date” are the same format. The same applies to the “P” code.

Moreover, FIGS. 14-16 has each shown three types of waveforms of the US standard radio wave, and it turns out that it is different compared with three types of waveforms of the Japanese standard radio wave. However, as shown by the broken lines in the figure, sampling at two time points (T _A , T _B ) is performed, and the state of “High” or “Low” at each time point is examined, so that it is the same as Japanese standard radio waves In addition, three types of waveforms can be discriminated.

Specifically, if T _A and T _B are “High” and “High”, respectively, the waveform is “0” as shown in FIG. 14, and T _A and T _B are respectively “Low” and “Low”. if "High", the waveform of which "1" shown in FIG. 15, T _a and _B, if each "Low" and "Low", the waveform of as "P" shown in FIG. 16 It becomes.

  Further, a method for extracting time data based on the determined “0”, “1”, “P” is disclosed in, for example, the following Patent Document 2 by the same applicant as the applicant of the present invention. ing.

JP-A-8-201546 Japanese Patent Laid-Open No. 11-304973

The present invention provides the user with the superiority or inferiority of the reception environment as early as possible by displaying the reception status (reception level) display at the beginning of reception, and stable by displaying the environmental changes during reception. The purpose is to let you know if you are receiving.

To achieve the above object, a radio timepiece according to the present invention receives a standard radio wave including time information, outputs a received signal, a time measuring means for measuring time, and displays information of the time measuring means. Time information display means, reception status determination means for determining the reception status at the reception means, and reception status display means for displaying the determination result of the reception status determination means, and at least of the time information display means A part is also used as the reception status display means. Further, the reception status display means is constituted by a pointer .

The radio timepiece according to the present invention is characterized in that, in the above invention, the display content of the reception status display means is updated at a predetermined cycle. Specifically, the predetermined period is 1 minute .

The radio timepiece according to the present invention is characterized in that, in the above invention, the time information display means other than that used as the reception status display means updates the time information display at the predetermined period .

The radio timepiece according to the present invention is characterized in that, in the above invention, the reception status display means displays the reception status by indicating a specific position in the time information display. Specifically, the reception status is displayed at a position from 0 o'clock to 3 o'clock .

In the radio timepiece according to the present invention as set forth in the invention described above, the reception status display means is a second hand .

The radio timepiece according to the present invention is configured such that, in the above invention, the second hand as the reception status display means and the time information display means other than the reception status display means operate in conjunction with each other . The display of time information is also updated by the time information display means other than that used as the reception status display means when updating the display contents of the reception status display means .

Further, the radio timepiece according to the present invention has the time information display means linked to the second hand as the time information display means in the above invention, and has at least a minute hand, and the time information of the minute digit or more when updating the display contents of the reception status display means The display is updated.

As described above, according to the present invention, it is possible to provide the user with the superiority or inferiority of the reception environment as early as possible by displaying the display of the reception status (reception level) at the beginning of reception, and during reception. By displaying the environmental change, there is an effect that it can be known whether stable reception is possible .

  Exemplary embodiments of a radio timepiece, a standard radio wave receiving method, and an electronic device according to the present invention will be explained below in detail with reference to the accompanying drawings.

(Configuration of radio clock)
First, the configuration of the radio timepiece according to the embodiment of the present invention will be described. FIG. 1 is a block diagram showing a configuration of a radio timepiece according to the embodiment of the present invention. In FIG. 1, reference numeral 1 denotes an antenna that receives a standard radio wave including time information. Reference numeral 2 is a reception that amplifies the standard radio wave received by the antenna 1 when a reception start / stop unit 3 (to be described later) issues a reception start command and demodulates the standard radio wave by processing such as a filter circuit, a rectifier circuit, and a detection circuit. Circuit.

  3 indicates that the receiving circuit 2 is set in a receiving state at a time determined by the contents of the time measuring circuit 11 or when a receiving start command is issued by the switch 4 described later, and a counter in the error counting unit 13 described later is cleared. At the same time, it is a reception start / stop unit that puts the reception circuit 2 into a reception stop state when a reception stop command is issued from a later-described decode circuit 8 or timing circuit 11, and implements the function of the reception start / stop means. A switch 4 is pressed when the operator desires forced reception. When the switch 4 is pressed, a reception start command is transmitted from the switch 4 to the reception start / stop unit 3.

  Reference numeral 5 denotes a sampling unit including a sampling circuit 5a and a sampling counter 5b, and realizes a function as sampling means. Here, the sampling circuit 5 a samples the demodulated waveform output from the receiving circuit 2 with the clock output from the frequency dividing circuit 10. The sampling counter 5b receives a count start command from the sampling circuit 5a, counts the clock of the frequency dividing circuit 10, and clears the counter every second.

  Reference numeral 6 denotes a smoothing unit that divides the output of the sampling circuit 5a to provide several sections, that is, sections of a predetermined plurality of cycles, and determines each section as one of High, Low, and error. Realize the function. Reference numeral 7 denotes a waveform discriminating unit that discriminates “0”, “1”, “P”, or other (error otherwise) based on the result of each section of the smoothing unit 6, and waveform discriminating means As a function.

  Reference numeral 8 denotes a decoding circuit that decodes the discrimination data for each bit output from the waveform discrimination section 7 and realizes a function as time information specifying means. The decode circuit 8 clears a counter in an error counter 13 (to be described later) at the time of detecting the head of the frame and whenever it reaches the start position of the frame, and outputs a reception end signal to the reception start / stop unit 3 at the end of decoding. . Further, 9 is an oscillation circuit, 10 is a frequency dividing circuit, and 11 is a time measuring circuit that realizes a function as time measuring means for measuring time. The smoothing unit 6 and the waveform discriminating unit 7 are separate constituent units, but the smoothing process of the smoothing unit 6 and the waveform discriminating process of the waveform discriminating unit 7 may be performed in one constituent unit.

  Reference numeral 12 denotes a display unit that displays time information and information on the radio wave reception status, and realizes a function as a display unit. An error counter 13 includes two counters, an error A counter 13a and an error B counter 13b, and realizes a function as an error counter.

  In addition, the standard radio wave receiver 14 is composed of the components of the receiving circuit 2, the reception start / stop unit 3, the sampling unit 5, the smoothing unit 6, the waveform discriminating unit 7, and the decoding circuit 8 surrounded by a dotted line. .

  In the present embodiment, the reception level has three levels: Hi (good), Mid (some errors), and Low (bad). Further, as shown in FIG. 17 or FIG. 18, the error is an error having a shape clearly different from 0, 1, or P, that is, an error determined by the waveform determination unit 7 (hereinafter referred to as “error A”). 19, an error that can be determined as 0, 1, and P as shown in FIG. 19 but a spike-like short pulse-shaped error waveform 1900 is generated, that is, an error determined by the smoothing unit 6 (hereinafter referred to as “error B”). Assuming type. This is mainly because the number of occurrences of error A and error B is different under the same reception situation due to hardware characteristics.

(Contents of time correction processing)
Next, the contents of the time correction process of the radio timepiece according to the embodiment of the present invention will be described. FIG. 3 is a flowchart showing the contents of the time correction processing of the radio timepiece according to the embodiment of the present invention. In the flowchart of FIG. 3, it is first determined whether or not a predetermined time has come or whether or not the forced reception switch 4 has been pressed (steps S301 and S302). Then, when either the predetermined time is reached (step S301: Yes) or the switch 4 is pressed (step S302: Yes), the reception start / stop unit from the timing circuit 11 or the switch 4 is used. A reception start command signal is transmitted to 3.

  As a result, the reception start / stop unit 3 sets the reception circuit 2 in the standard radio wave reception state (step S303), and at the same time, the error A counter 13a and the error B error B count unit (counter) 13b of the error count unit 13. To clear. At this time, the display unit 12 shown in FIG. 2 confirms that the second hand is being received by sending it to the “REC” position of 00 seconds by fast-forwarding from the 1-second hand-operated state, stopping on the spot, and holding that state. Show.

  Next, it is determined whether or not the reception process has been completed normally (step S304). Whether or not the reception process has been normally completed is determined, for example, by whether or not the time information has been specified in the decoding circuit 8. A method for specifying time information will be described later. Here, when the reception process is normally completed (step S304: Yes), the standard radio wave reception process is terminated. Specifically, a reception stop command signal is transmitted from the decode circuit 8 to the reception start / stop unit 3.

  Then, the time information acquired by the normal end is transmitted to the time measuring circuit 11, and the time measuring circuit 11 corrects the time based on the received time information (step S309). The corrected time information is displayed on the display unit 12 (step S310). Here, before displaying the corrected time information, the second hand moves from the “REC” position at 00 seconds to the “Hi” position to indicate that the radio wave reception status is “good”. The time information corrected after a predetermined time (for example, about 10 seconds) has elapsed may be displayed. As a result, a series of processing ends.

  On the other hand, if the reception process has not ended normally in step S304 (step S304: No), it is determined whether or not a predetermined time, for example, 10 minutes has elapsed since the start of the reception process (step S305). . This is done by the timer circuit 11. If the predetermined time has not yet elapsed (step S305: No), the process returns to step S303 to continue the reception process. Then, when the predetermined time has not elapsed and the normal radio wave reception process has not been completed (step S304: No), the standard radio wave reception process ends. Specifically, a reception stop command signal is transmitted from the timer circuit 11 to the reception start / stop unit 3.

  Then, for example, an error is displayed by moving the second hand from the “REC” position of 00 seconds to the “Mid” or “Low” position (step S306). Then, waiting for a predetermined time (for example, about 10 seconds) to elapse in the error display state (step S307), and when the predetermined time has elapsed (step S307: Yes), the standard radio wave reception process is started. The previous original time is displayed (step S308), and the series of processing ends.

(Contents of standard radio wave reception processing)
Next, the contents of the standard radio wave reception process will be described. FIG. 4 is a flowchart showing an example of the standard radio wave reception process of the radio timepiece according to the embodiment of the present invention. In the flowchart of FIG. 4, first, the standard radio wave received by the antenna 1 is received (step S401). The receiving circuit 2 demodulates and outputs a demodulated waveform to the sampling circuit 5a of the sampling unit 5 (step S402). As shown in FIG. 5, the sampling circuit 5a starts sampling the demodulated waveform with a clock of 32 Hz that is a predetermined plurality of cycles supplied from the frequency dividing circuit 10 in this embodiment (step S403). That is, the demodulated waveform for 1 second is divided into 32, and High and Low at each divided timing are detected.

  When starting sampling, first, the rising edge that is the beginning of the waveform is detected. This rising edge appears every second when normal demodulation is output from the receiving circuit 2. The details of the method for detecting the rising edge are not directly related to the present invention, and therefore detailed description thereof is omitted. When the detection is completed, an instruction to start counting is output from the sampling circuit 5a to the sampling counter 5b. In response to this signal, the sampling counter 5b starts counting a 32 Hz clock. The sampling counter 5b can count up to 31 and clears its counter when it reaches the maximum. That is, the counter is cleared every second.

  Next, the smoothing unit 6 detects the output of the sampling circuit 5a in a section where the value of the sampling counter 5b is 1 to 5 (this section is referred to as section A). That is, it is determined whether or not the sampling of the specific section (section A) has been started (step S404). If the sampling has started (step S404: Yes), the output result is counted (step S405). Then, when the number of “High” in the counted sampling data of the output result is detected to be a predetermined number, for example, four or more (step S406: Yes), the entire A section is determined to be “High” (step S407). Then, the process proceeds to step S411.

  On the other hand, if the number of “High” does not reach the predetermined number in step S406 (step S406: No), it is next determined whether or not the specific section has ended (step S408), and has not ended. In the case (step S408: No), the process returns to step S405. When the specific section is completed (step S408: Yes), it is determined whether or not the number of “High” is a predetermined number, for example, 2 or less (step S409).

  Here, when the number of “High” is equal to or less than the predetermined number (step S409: Yes), the entire section A is determined to be “Low” (step S410), and the process proceeds to step S411. In step S411, the determined determination signals are transmitted to the waveform determination unit 7. On the other hand, when the number of “High” is not less than or equal to the predetermined number (step S409: No), specifically, when there are three “High”, it is determined as “Error” (step S412), and the error signal is an error. The data is transmitted to the counting unit 13 (step S413). The error counter 13 increments the counter of the error B counter 13b by one based on the received error signal.

  Note that the determination method is not limited to the above method, and may be another method. For example, “High” is detected, but “Low” may be detected instead. Although not shown, the number of “High” or “Low” may be verified after the counting of the specific section is completed.

  In this process, sampling is performed in the same manner, and “High”, “Error”, and “Low” are determined in the section 8 to 13 (section B) under the same conditions as the section A. The same determination is performed for the sections 18 to 23 (section C). In the case of this embodiment, it is divided into sections A to C as described above. On the way, the cases where the sampling counter values are 6, 7, and 14 to 17 are not included, but this is due to the fact that the falling position of the signal varies in consideration of the characteristics of the receiving circuit, and is relatively unstable. These parts are intentionally removed to increase the accuracy of received data extraction. Thus, it is desirable that the specific sections are separated by at least one period.

  Further, when the value of the sampling unit 5 is 24 or more, it is not necessary to distinguish between “0”, “1”, and “P”. That is, these three waveforms are “Low” at 24 or more. Therefore, sampling is not performed.

  However, by providing, for example, a section (D section) of 27 to 31 during this period, sampling is performed by detecting “High” even though the D section normally has to be “Low”. It can be recognized more reliably that the data is an error.

  As described above, the specific section may be at least two of the B section and the C section, and may be three including the A section or four including the D section. However, in consideration of the stability of the operation, It is best to carry out by three sections, A section, B section, and C section.

(Contents of waveform discrimination processing)
Next, the contents of the waveform discrimination process by the waveform discrimination unit 7 will be described. Through the above processing, each of the sections A, B, and C is determined to be “High”, “Low”, or “Error”. The waveform discriminating unit 7 performs waveform discrimination processing using this result. In Japanese standard radio waves, when A: B: C = “High”: “High”: “High”, “0”, A: B: C = “High”: “High”: “Low” Is “P” when A: B: C = “High”: “Low”: “Low”. If the pattern is other than that, it is determined as a miss waveform and is not used in the decoding circuit 8 but is output to the error A counting unit 13a. In addition, as shown in FIG. 5, when the normal waveform that is not affected by noise or the like is output from the receiving circuit 2, the sampling data is only “High” or only “Low”, as shown in FIG. It is. However, if both “High” and “Low” are included and are approximately the same number, the smoothing unit 6 considers that there is an error as shown in FIG. 19 and outputs it to the error B counting unit 13b.

  FIG. 6 is a flowchart showing an example of waveform determination processing (Japan) of the radio timepiece according to the embodiment of the present invention. In the flowchart of FIG. 6, it is determined whether or not the A section, the B section, and the C section are errors (“E”). If they are errors (step S601: Yes, step S603: Yes, step S608: Yes). Determines that the bit is an error (step S613), transmits an error signal to the error A counting unit 13a (step S614), and terminates the processing related to the bit.

  Further, since the section A should always be “High”, if it is “Low” (step S602: No), it is determined that the bit is an error (step S613). Similarly, if the A section is “High” and the B section is “Low”, the C section should always be “Low”. Therefore, in the case of “High” (step S606: Yes), the bit is It is determined that an error has occurred (step S613).

  If A: B: C = “High”: “High”: “High” (step S609: Yes), it is determined as “0” (step S611), and A: B: C = “High”: When “High”: “Low” (step S609: No), it is determined as “1” (step S610), and when A: B: C = “High”: “Low”: “Low” (step S606). : No) is determined as “P” (step S607). Then, the determined signal is transmitted to the decode circuit 8 (step S612), and the waveform determination process related to the bit ends. Note that this flowchart is an example, and the waveform may be determined by another method.

  FIG. 7 is an explanatory diagram showing the contents of sampling (USA), and FIG. 8 is a flowchart showing an example of the waveform discrimination processing (USA) of the radio clock according to the embodiment of the present invention. As shown in FIG. 7, the specific section may be at least two of the B section and the C section, and may be three including the A section or four including the D section. Considering this, it is best to use three sections, A section, B section, and C section. In the flowchart of FIG. 8, it is determined whether the A section, the B section, and the C section are in error (“E”). If there is an error (step S801: Yes, step S803: Yes, step S808: Yes). Determines that the bit is an error (step S813), transmits an error signal to the error A counting unit 13a (step S814), and terminates the processing related to the bit.

  In addition, since the A section should always be “Low”, if it is “High” (step S802: No), it is determined that the bit is an error (step S813). Similarly, if the A section is “Low” and the B section is “High”, the C section should always be “High”. Therefore, in the case of “Low” (step S806: Yes), the bit is It is determined that an error has occurred (step S813).

  If A: B: C = “Low”: “Low”: “Low” (step S809: Yes), it is determined as “P” (step S811), and A: B: C = “Low”: If “Low”: “High” (step S809: No), it is determined as “1” (step S810), and A: B: C = “Low”: “High”: “High” (step S806). : No) is determined to be “0” (step S807). Then, the determined signal is transmitted to the decode circuit 8 (step S812), and the waveform determination process regarding the bit is completed. This flowchart is also an example, similar to FIG. 6, and the waveform may be determined by another method.

(Contents of reception status display processing)
The display of the reception status (reception level) is displayed at the initial stage of reception, and the first purpose is to provide the user with superiority or inferiority of the reception environment as early as possible, and stable reception is possible by displaying the environmental change during reception. There is a second purpose to let you know if it is done. Therefore, for the first purpose, in this embodiment, an error for 10 seconds is counted after the end of detection of the rising edge of the waveform, and the latter is counted every minute after detection of two consecutive Ps that are the heads of data. I have to. Here, the display processing of the second purpose reception status will be described. For the first purpose, the method itself is the same as the second purpose, and only the threshold value for level discrimination is different, so that the description is omitted.

  As described above, during the error counting period, when the error B is detected by the smoothing unit 6 and the error A is detected by the waveform discriminating unit 7, the number of errors is counted by the error A counting unit 13a and the error B counting unit 13b, respectively. The count is started when the decoding circuit 8 detects the beginning of the frame. At this time, the decode circuit 8 outputs a signal for clearing the counter in the error counter 13. Table 1 shows an example of an association table of error A count values and reception levels, and Table 2 shows an example of an association table of error B count values and reception levels. Based on either the association table of Table 1 or the association table of Table 2, the reception status is determined.

  Further, the reception status may be determined based on both the number of errors A and the number of errors B. In that case, in Tables 1 and 2, the priority of level display is “Low” being the highest and “Hi” being the lowest. For example, in this embodiment, when four errors A (Low) and three errors B (Mid) occur, “Low” of error A is given priority. Further, as can be seen from the flowcharts shown in FIGS. 6 and 8, if one error B occurs, one or more errors A are always generated. If one error B occurs, “Hi When there are three or more errors B, the number of errors A is three or more, so it is always “Low”.

  When the reception status is determined, the second hand in FIG. 2 fast-forwards from “REC” to “Low” at the 15-second position. Here, in the case where the clock hand is operated by one motor with the second minute hour hand, since the minute hand cannot be moved when the second hand is stopped, the time of the second digit or more in the time counting circuit 11 is adjusted. By moving the second hand at forward rotation every minute and displaying the reception level, at least the hour and minute hands can display the time in the timer circuit 11.

  The second hand moves fast to the “Low” position and stops on the spot, indicating that the reception status is not good. Until the reception end output is received from the decoding circuit 8, the counter in the error counting unit 13 is cleared by the decoding circuit 8, and then the error is counted again for one minute, and the reception level determination and display processing described above is performed. And update the level display position. The same processing is repeated and the error count value is updated every minute to display the reception status.

  Note that the occurrence of error A reflects the fact that there was a mistake in the determination of the signal level in the smoothing unit 6, and is therefore more important than the error B in the reception status determination. Therefore, if even one error A occurs, the reception level is set to “Mid”.

  In this way, the number of bits of the received signal in which an error is detected (number of errors A) and the number of sampling results in which errors are detected (number of errors B) are counted, and the number of errors A counted and The standard radio wave reception status can be determined based on at least one of the number of errors B.

(Contents of time information identification process)
Next, the contents of the time information specifying process by the decoding circuit 8 will be described. The decode circuit 8 extracts time information based on “0”, “1”, “P” determined by the waveform determination unit 7.

  The time information is extracted by setting the 0 second bit as the first bit, the 1 second bit as the second bit, and the 59 second bit as the 60th bit. As shown in FIGS. 9 and 13, each bit is associated with corresponding time information. For example, the second bit is a bit indicating “40 (minutes)”, the third bit is a bit indicating “20 (minutes)”, and the fourth bit is a bit indicating “10 (minutes)”. , The fifth bit is a bit indicating “0 (minute)”, the sixth bit is “8 (minute)”, the seventh bit is “4 (minute)”, and the eighth bit is “2 (minute)”. The 9th bit is “1 (minute)”.

  For example, when “1 minute” is indicated, among the 2nd to 9th bits, the 5th and 9th bits are “1”, and the remaining bits are all “0”. When “57 minutes” is indicated, the second bit, fourth bit, seventh bit, eighth bit, and ninth bit are “1”, and the remaining third bit, fifth bit, and sixth bit are It becomes “0”.

  Therefore, for example, the second bit (40 (minutes)) and the third bit (20 (minutes)) are not simultaneously “1”. This is because the minute is displayed from 0 to 59 and never exceeds 60. As described above, when an impossible combination of “1” bits is generated, the decoding circuit 8 determines that a reception error has occurred and fails to extract received data.

  When the extraction of the time data is completed, the decode circuit 8 outputs the received data to the timer circuit 11, and the timer circuit 11 updates the time held in the timer circuit 11. At the same time, the counter of the frequency dividing circuit 10 is also reset at the timing of reception seconds. In this way, the display unit 12 moves the hands by fast-forwarding and displays the time when it is quickly received.

  On the other hand, if the reception data extraction fails, the time counting circuit 11 counts the elapsed time during reception, so that the time is corrected by fast-forwarding at that time and the time is displayed. At the end of reception, a reception stop signal is transmitted to the reception start / stop unit 3 and the operation of each circuit / component related to the reception process of the standard radio wave receiver 14 is stopped.

  As described above, according to the present embodiment, even when a waveform including noise or the like is obtained in the demodulation result of the receiving circuit, a mistake in sampling the waveform is provided by providing a process for removing the noise portion. Prevention in advance, which increases the reliability of the received waveform. For this reason, the reception success rate is increased, and it is possible to prevent the wrong data from being acquired. In addition, since accurate data can be acquired quickly, the reception time can be shortened and the power consumption can be reduced.

  In the above embodiment, the radio timepiece has been described. However, the radio timepiece includes all types of timepieces such as a wristwatch, a wall clock, and a table clock. The present invention is not limited to a radio timepiece, and is a portable information terminal device such as a mobile phone, a PDA (Personal Digital Assistant), a notebook personal computer, and the It may be an electronic device including an automobile.

It is a block diagram which shows the structure of the radio timepiece concerning this Embodiment of this invention. It is explanatory drawing which shows an example of the display content of the display part of the radio timepiece concerning this Embodiment of this invention. It is a flowchart which shows the content of the time correction process of the radio timepiece concerning this Embodiment of this invention. It is a flowchart which shows an example of the standard radio wave reception process of the radio timepiece concerning this embodiment of this invention. It is explanatory drawing which shows the content (Japan) of sampling. It is a flowchart which shows an example of the waveform discrimination | determination process (Japan) of the radio timepiece concerning this Embodiment of this invention. It is explanatory drawing which shows the content (USA) of sampling. It is a flowchart which shows an example of the waveform discrimination | determination process (USA) of the radio timepiece concerning this Embodiment of this invention. It is explanatory drawing which shows the content of the format of the transmission data of a standard radio wave (Japan). It is explanatory drawing which shows the content of the waveform of "0" which is transmission data of a standard radio wave (Japan). It is explanatory drawing which shows the content of the waveform of "1" which is transmission data of a standard radio wave (Japan). It is explanatory drawing which shows the content of the waveform of "P" which is transmission data of a standard radio wave (Japan). It is explanatory drawing which shows the content of the format of the transmission data of a standard radio wave (USA). It is explanatory drawing which shows the content of the waveform of "0" which is transmission data of a standard radio wave (USA). It is explanatory drawing which shows the content of the waveform of "1" which is transmission data of standard radio waves (USA). It is explanatory drawing which shows the content of the waveform of "P" which is transmission data of standard radio waves (USA). It is explanatory drawing which shows an example of the error of the transmission data of a standard radio wave (Japan). It is explanatory drawing which shows another example of the error of the transmission data of a standard radio wave (Japan). It is explanatory drawing which shows another example of the error of the transmission data of a standard radio wave (Japan).

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Antenna 2 Receiving circuit 3 Reception start / stop part 4 Switch 5 Sampling part 5a Sampling circuit 5b Sampling counter 6 Smoothing part 7 Waveform discrimination part 8 Decoding circuit 11 Timekeeping circuit 12 Display part 13 Error counting part 14 Standard radio wave receiving part 1900 Spike shape Short pulse shape miss waveform

Claims (5)

Receiving means for receiving a standard radio wave including time information and outputting a received signal;
A time measuring means for measuring time;
Time information display means for displaying information of the time measuring means;
Reception status determining means for determining the reception status at the receiving means;
Reception status display means for displaying the determination result of the reception status determination means,
At least part of the time information display means also serves as the reception status display means ,
Update in which the second hand as the reception status display means and the time information display means other than the reception status display means operate in conjunction with each other, and the display contents of the reception status display means are updated at a predetermined cycle. A radio-controlled timepiece characterized in that the time information display means is also updated by the time information display means other than being used as the reception status display means . As the time information display means interlocked with the second hand, having at least a minute hand,
The radio timepiece according to claim 1 , wherein when updating the display contents of the reception status display means, display update of time information of minute digits or more is performed. The radio timepiece according to claim 1 or 2 , wherein the predetermined period is one minute. The radio wave timepiece according to any one of claims 1 to 3 , wherein the reception status display means displays a reception status by indicating a specific position in time information display. The radio timepiece according to claim 4 , wherein the specific position is implemented at a position from 0:00 to 3:00 in the time information display.

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