JPH0712999U - Radio wave correction clock - Google Patents

Abstract

(57) [Summary] [Purpose] Not affected by the broadcast content or the environment of the installation location,
Realize a radio-controlled clock that can reliably correct the time. [Structure] The receiving circuit 3, the PLL synthesizer circuit 4, the waveform shaping circuit 5, the time signal detection circuit 6 and the control circuit 7 select the first NHK from the next hour after the initial correction to the 24th hour. Then, the hourly signal is detected every hour from the signal from the NHK No. 1, and data “1” and “0” are stored in the area A1 of the time memory according to the success or failure of the hourly signal detection.
Is written, and from the next hour until the 24th hour, the NHK No. 2 is selected, the hourly signal is detected every hour from the signal from the NHK No. 2, and the time signal is detected in success or failure. Data "1" and "0" are written in area A2 of the time memory, and data "1" that can detect the time signal after the next hour
Is selected and the time of the clock unit 8 is corrected based on the time signal received from the selected broadcast station.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a radio-controlled timepiece that corrects the time by receiving a time signal transmitted from a radio station or the like.

[0002]

[Prior art]

 The radio-controlled timepiece has a function of receiving a time signal signal of a predetermined frequency transmitted from a radio station and performing so-called zeroing based on the received signal. Such a radio-controlled timepiece is equipped with a channel selection device that uses a frequency synthesizer, etc., and is configured to automatically select the channel in which the broadcast signal exists, and receive signals from the selected station. The time adjustment operation is performed based on the.

As a channel selection device for AM radio waves, for example, a command signal from a control circuit to a PLL synthesizer circuit for increasing (or decreasing) the value of the local oscillation frequency by one channel at a predetermined repetition cycle. Is output, and in the receiving circuit and the PLL synthesizer circuit, the intermediate frequency (IF) level and the IF count value of the received AM wave are obtained and compared with the preset values to determine the IF level and the IF count value. Is within the set range, it has been proposed that the output of the command signal is stopped assuming that the desired station is selected (see, for example, Japanese Patent Publication No. 2230/1990). In a radio-controlled timepiece using this device, the time adjustment operation is performed based on the hourly sound of the audio signal as the time signal included in the broadcast reception signal of the selected station.

[0004]

[Problems to be solved by the device]

 However, due to changes in the broadcast contents and changes in the installation environment, the time period during which the time signal can be detected is limited during the day, and as a result, only the time signal from one broadcasting station is received and the time is adjusted. The conventional radio wave correction timepiece configured to perform the above has a problem that it is not possible to perform highly accurate time correction.

The present invention has been made in view of such circumstances, and an object of the present invention is to provide a radio-controlled timepiece capable of surely adjusting the time without being influenced by the broadcast contents or the environment of the installation place. .

[0006]

[Means for Solving the Problems]

 In order to achieve the above-mentioned object, the tuning device of the radio-controlled timepiece of the present invention selects at least two specific broadcasting stations by automatic tuning, and the hourly signal of every hour from the transmission signals from these broadcasting stations. The time signal signal detecting means for detecting the time, the memory means, and the time when the time signal is detected by the time signal signal detecting means for each broadcasting station selected for 24 hours after the channel selection is stored in the memory means. From the next hour, there is a control means for selecting a time at which the time signal can be detected based on the stored information in the storage means and for adjusting the time of the clock section based on the time signal received at that time.

[0007]

[Action]

 According to the present invention, in the time signal signal detecting means, first, the first broadcasting station is automatically selected, and the hourly signal signal at every hour is detected from the signal from the automatically selected first broadcasting station. Done. The detection result of the time signal detection means is output to the control means. In the control means, for 24 hours immediately after the selection of the first broadcasting station, the time when the time signal is detected is stored in the storage means based on the detection result of the time signal detecting means. Next, the second broadcasting station is automatically selected, and the hourly signal at every hour is detected from the signal from the automatically selected second broadcasting station. The detection result of the time signal detection means is output to the control means. In the control means, the time when the time signal is detected is stored in the storage means for 24 hours immediately after the selection of the second broadcasting station based on the detection result of the time signal detection means. Then, from the next hour, the time at which the time signal can be detected is selected based on the information stored in the storage means, and the time of the clock section is corrected based on the time signal received at that time.

[0008]

【Example】

FIG. 1 is a block diagram showing an embodiment of a radio-controlled timepiece according to the present invention. In FIG. 1, 1 is an antenna unit, 2 is a local oscillator constant setting unit, 3 is a receiving circuit, 4 is a PLL (Phase Locked Loop) synthesizer circuit, 5 is a waveform shaping circuit, 6 is a time signal detection circuit, and 7 is control. A circuit, 8 is a clock section, V _CC is a power supply voltage, and SSW is a start switch.

The antenna unit 1 is composed of a variable capacitance diode D1, a capacitor C1, a resistance element R1, and coils L1 and L2, and is tuned to, for example, a broadcast radio wave transmitted from an AM radio broadcasting station to receive a specific frequency band in a receiving circuit. Output to 3.

The constant setting unit 2 of the local oscillator is composed of a variable capacitance diode D2, a capacitor C2, a resistor element R2 and a coil L3, and is set according to the channel output from the PLL synthesizer circuit 4 Receiving the voltage LV, the receiving circuit 3 generates a local oscillation signal LS having a frequency corresponding to each channel.

The receiving circuit 3 converts the AM wave from the antenna unit 1 input from the terminal AMIN into an intermediate frequency signal IF based on the local oscillation signal LS from the local oscillator 2 generated at the terminal OSC, and the conversion level is set in advance. When the value is higher than the value, a high level “H” signal is output from the terminal IFV to the PLL synthesizer circuit 4, an intermediate frequency of 450 kHz is output from the terminal IFF to the PLL synthesizer circuit 4, and the terminal AFO outputs the intermediate frequency. For example, the audio signal S ₃ as shown in FIG. 2A is output to the waveform shaping circuit 5. Note that, as shown in FIG. 2, the audio signal as the time signal, for example, has an advance sound of 880 Hz transmitted after three waveforms of advance sound of 440 Hz are transmitted at predetermined intervals (for example, one second interval). Is coming.

The PLL synthesizer circuit 4 receives a command signal S ₇ from the control circuit 7 for changing the value of the local oscillation frequency for each channel, and generates a local VCO voltage LV at a level according to the command. Then, when the signal is output from the terminal VOSC to the constant setting unit 2 of the local oscillator and the high level signal from the receiving circuit 3 is received from the terminal IFL, the intermediate frequency input from the terminal IFC is counted and the IF count value is preset. If it is within the range, the stop signal S ₄ for stopping the output of the command signal S ₇ is output to the control circuit 7. Further, the PLL synthesizer circuit 4 supplies the antenna tuning voltage AV 1 to the antenna unit 1 from the terminal VANT.

The waveform shaping circuit 5 receives the voice signal S ₃ from the receiving circuit 3 and shapes it into a pulse-like waveform having a predetermined width as shown in FIG. 2B, and outputs the signal S ₅ as a time signal signal detection circuit. Output to 6. FIG. 3 is a block diagram showing a configuration example of the waveform shaping circuit 5. As shown in FIG. 3, it comprises an amplifier (AMP) 51, a low-pass filter (LPF) 52, a comparator (CMP) 53, an integrator 54 and a shaper 55. In such a configuration, for example, the audio signal S ₃ of about 200 mVp-p is amplified by the amplifier 51 with a predetermined gain, passes through the low-pass filter 52 of fc = 1 kHz, and is then set to a threshold value TH (preset by the comparator 53. For example, 0.8 V). Then, when the output of the low-pass filter 53 is equal to or higher than the threshold value TH, the output of the comparator 53 is input to the integrator 54 at a high level. The integrator 54 is composed of, for example, an npn-type transistor, a resistance element, and a capacitor, and a high-level input of the comparator 53 causes a rapid rise and then a gradual discharge to shape the waveform to the lower right. It is input to the device 55, where it is shaped into a rectangular pulse waveform.

[0014] ping signal detection circuit 6 receives the output pulse signal S ₅ of the waveform shaping circuit 5, detects the hour sound after detecting three times warning sound at intervals of one second, the success or failure of the detection result (detection ) to the control circuit 7 a detection signal S ₆ indicating the.

When the start switch SSW is turned on, the control circuit 7 repeats predetermined values of a plurality of local oscillation frequencies f (k Hz) preset according to the oscillation frequency of the station for tuning. The command signal S ₇ for increasing (or decreasing) one channel at a time is output, and when the signal S ₄ from the PLL synthesizer circuit 4 is received, the output of the command signal S ₇ is stopped, and the selected broadcast The frequency of a station, for example, NHK first broadcast or NHK second broadcast is set in a tuning memory (not shown). In addition, the control circuit 7 includes an area A1 and an area A2 for storing the detection results of 24 time signal signals of two broadcasting stations as shown in FIG. 4, for example, NHK first broadcasting and NHK second broadcasting. The time memory TMRY having

The control circuit 7 after output stop command signal S _7, the first 24 hours upon receiving the output signal S ₆ of the ping signal detection circuit 6, send a first tuned the NHK first broadcast Whether or not the incoming time signal is detected is stored in the storage areas M0 to M23 of the area A1 of the time memory TMRY provided for the hour of 24. Then, when the second NHK second broadcast is selected, 24 hours after receiving the output signal S ₆ of the time signal detection circuit 6, the first NHK second broadcast is transmitted. Whether or not the incoming time signal is detected is stored in the storage areas M0 to M23 of the area A2 of the time memory TMRY provided for 24 hour correspondence. Specifically, as shown in FIG. 4, when the time signal is not detected, the data is stored in the time memory TMRY as data “0” and detected. In this case, the data is stored as “1”. Further, when the storage operation of the data of the first and second NHK for 48 hours in total is completed, the control circuit 7 starts the next hour from the time when the time signal is detected, that is, the data “1 , Which has been stored, is selected, and the time adjustment signal S ₈ is output to the clock unit 8 based on the detection of the time signal from the broadcast station to adjust the time to the hour. When data "1" is set in the storage areas corresponding to the same time in area A1 and area A2, NHK first broadcast is selected preferentially.

Next, the correction time selection operation and the normal time correction operation with the above configuration will be described with reference to the flowcharts of FIGS. 5 and 6. Note that FIG. 5 shows the flow of the correction time selection operation, and FIG. 6 shows the flow of the normal time correction operation. The symbol “S” is used for each step in FIG. 5, and each step in FIG. The symbol "ST" is used for.

First, as shown in FIG. 5, when the start switch S SW is set to the ON state (S2) after the initial setting of the timepiece (S2), the first channel is set in the control circuit 7. A command signal S _{7 for} instructing to set the local oscillation frequency to the frequency corresponding to the channel is output to the PLL synthesizer circuit 4.

The PLL synthesizer circuit 4 receives the command signal S ₇ from the control circuit 7 for changing the value of the local oscillation frequency for each channel, and generates the local oscillator VCO voltage LV corresponding to the command. It is output from the terminal VOSC to the constant setting unit 2 of the local oscillator. The local oscillator receives the local VCO voltage LV, generates a local oscillation signal LS, and outputs it to the receiving circuit 3. At this time, the AM wave transmitted from the AM radio broadcasting station received by the antenna unit 1 is input to the receiving circuit 3.

In the receiving circuit 3, the AM wave from the antenna unit 1 input from the terminal AMIN is converted into an intermediate frequency signal IF based on the local oscillation signal LS from the local oscillator generated at the terminal OS C, and the conversion level (IF level ) Is greater than or equal to the preset value. Further, the audio signal S ₃ is output to the waveform shaping circuit 5 from the terminal AFO of the receiving circuit 3. Here, if it is determined that the IF level is equal to or higher than the set value, a signal of high level “H” is output from the terminal IFV of the receiving circuit 3 to the PLL synthesizer circuit 4, and at the same time, 450 kHz is output from the terminal IFF. Is output to the PLL synthesizer circuit 4.

The PLL synthesizer circuit 4 receives a high-level signal from the receiving circuit 3 and, when an intermediate frequency is input, counts the input intermediate frequency (IF count), and the IF count number is a preset value. (450 kHz)), and whether or not it is within its neighborhood value is determined. If it is determined that the IF count value is within the predetermined range, the stop signal S ₄ for stopping the output of the command signal S ₇ is output to the control circuit 7. In the control circuit 7, when the stop signal S ₄ is input, the output of the command signal S ₇ is stopped, and the frequency of the selected broadcasting station, for example, NHK first broadcasting is set in a tuning memory (not shown) ( S3). At this time, the receiving circuit 3 is once turned off, and the area A 1 of the time memory TMRY is set (S4).

In the waveform shaping circuit 5, the audio signal S _{3 from the} receiving circuit 3 is shaped into a pulse-shaped waveform having a predetermined width, and the signal S ₅ is output to the time signal signal detection circuit 6. In time signal detection circuit 6 receives the output pulse signal S ₅ of the waveform shaping circuit 5, if detected the hour sound after detecting three times pre Tsugeoto at 1 second intervals, the detection signal S ₆ child Control It is output to the circuit 7.

When the NHK first broadcast is set in the tuning memory, the normal time adjustment interrupt operation shown in FIG. 6 is performed, for example, once every (1/32) seconds. In the normal time adjustment, the hour, minute and second counters of the hexadecimal counter are counted up (ST1), whereby the hour hand, minute hand and second hand (not shown) of the clock section 8 are normally fed and the time is counted. . Next, it is determined whether or not the modification prohibition flag that prohibits modification is set (ST2). Here, since the correction prohibition flag has not been set yet, a negative determination result is obtained, and it is next determined whether or not it is 5 minutes before the hour (ST3). When it is determined in step ST3 that it is five minutes before the hour, the receiving circuit 3 is turned on (ST4).

At this time, also in the correction time selection flow shown in FIG. 5, it is determined whether it is 5 minutes before the hour (S5). If it is determined in step S5 that the time is 5 minutes before the hour, reception data is set from the tuning memory (not shown), and the time signal signal detection circuit 6 detects the time signal from the NHK first broadcast from the received audio signal. is performed for detection (S6), the detection result is output as a signal S ₆ to the control circuit 7.

In parallel with this, in the normal time adjustment operation flow, if the time signal is detected based on the output signal S ₆ of the time signal detection circuit 6, the minute hand can be adjusted (ST5). ). On the other hand, if the time signal is not detected, the minute hand is not corrected. If then performed a determination is made whether the hour 30 seconds before (ST6), as long obtain affirmative determination result is based on the output signal S ₆ of the ping signal detection circuit 6, is detected in the time signal has been performed For example, the second hand can be corrected (ST7). On the other hand, if the time signal is not detected, the second hand is not corrected.

Next, it is determined whether 5 minutes have passed since the hour (ST8). If it is determined in step ST8 that 5 minutes have not passed, it is determined whether or not the minute correction has been completed (ST9), and if it is determined that the minute correction has been performed, it is determined whether or not the second correction has been completed. Whether or not is determined (ST10). If it is determined in step ST10 that the second correction has been performed, it is determined whether or not writing to the time memory TMRY has been performed, and if a negative determination result is obtained, area A1 of the time memory TMRY is obtained. Data "1" indicating that the time signal has been detected at the correct time and the time has been corrected is written in the area of address M0 of (ST12). When the writing of the data “1” to the time memory TMRY is completed, the time memory address in the area A1 is incremented by “+1” (ST13), the correction flag is further initialized (ST14), and the receiving circuit 3 is turned off. Then, (ST15), the operation from step ST1 described above is repeated.

If a negative determination result is obtained in steps ST2, ST3 and ST6 described above, the second hand and the minute hand are normally fed (ST16, ST17). Further, in step ST8, it is determined that 5 minutes have passed from the hour, and at this time, if the minute correction and the second correction are not performed and the data is not written in the time memory TMRY (ST18). In the area of the address M0 of the time memory TMRY, for example, the time signal is not detected at the correct time, and the data “0” indicating that the time could not be adjusted is written (ST19). Transition. The above normal time adjustment operation is performed as an interrupt operation at intervals of (1/32) seconds.

On the other hand, in the correction time selection operation flow, as shown in FIG. 5, it is determined whether or not the above-described writing of data to the area A1 of the time memory TMRY has been performed 24 times (S7), When a negative determination result is obtained, the process proceeds to step S10, and it is determined whether or not it is the 48th time. When a negative determination result is obtained, the operation returns to step S5, and steps S5, S6 and S10 are performed. A series of operations is performed. Here, if a positive determination result is obtained in step S7, the NHK second channel is automatically selected by the same operation as the NHK first channel selection operation described above, and its frequency is stored in the channel selection memory (not shown). It is set (S8). At this time, the receiving circuit 3 is once turned off, this time the area A2 of the time memory TMRY is set (S9), and the operation returns to the step S5.

At this time, in the normal time adjustment operation shown in FIG. 6, which is performed at intervals of (1/32) seconds as the interrupt operation, the operations of steps ST1 to ST19 are performed on the area A2 of the time memory TMRY. Done. That is, for 24 hours after the NHK No. 2 channel is selected, the hourly signal is detected every hour from the automatically selected NHK No. 2 broadcast signal, and the success or failure of the detection at each time is detected by the data "0. Or "1" is written in the 24 storage areas M0 to M23 of the area A2 of the time memory TMRY.

The above series of operations for the areas A1 and A2 are continuously performed for 48 hours, and when a positive determination result is obtained in step S10, the time memory write end flag is set (S11), and subsequently, , The initial address M0 of the time memory TMRY is set (S12). Next, it is judged whether it is 5 minutes before the hour (S13), and if a positive judgment result is obtained, the areas A1 and A2 of the time memory TMRY are read (S14). Then, first, it is determined whether or not the read data in the area A1 is "1", that is, whether or not the NHK first time signal can be received (S15). If a positive determination result is obtained in step S15, the NHK first frequency is set in a tuning memory (not shown) (S16), and reception data is set from a tuning memory (not shown) (S17). From the received voice signal, the time signal signal detection circuit 6 detects the time signal signal by NHK first broadcasting, and the detection result is output to the control circuit 7 as a signal S ₆ , and based on the time signal signal at this time, The time correction signal S ₈ is output to the clock unit 8 to correct the time to the hour.

When a negative determination result is obtained in step S15, the read data in the area A1 is “0”, so that the read data in the area A2 at the same time is “1”. ", That is, whether the NHK second time signal can be received is determined (S18). If a positive determination result is obtained in step S18, the NHK second frequency is set in a tuning memory (not shown) (S19), the operation proceeds to step S17, and the time signal signal detection circuit detects from the received audio signal. 6, a time signal is detected by NHK No. 2 broadcast, and the detection result is output as a signal S ₆ to the control circuit 7. Based on the time signal, the time adjustment signal S ₈ is sent to the clock unit _8. Is output and the time is adjusted to the hour.

Further, when a negative determination result is obtained in step S18, the read data in the areas A1 and A2 is “0”, and therefore correction is made at this time because it is difficult to detect the time signal. The prohibition flag is set (S20), and the time is not adjusted.

After the time is corrected in step S17 or the time is not corrected and the correction prohibition flag is set in step S20, the address next to the time memory address is read (S21), and this operation is performed. Whether or not it has been performed 24 times is determined (S22). If the 24th time has not been reached, the operation returns to step S13, and if the 24th time has been reached, the operation returns to step S12. A series of operations is performed.

As described above, according to the present embodiment, the reception circuit 3, the PLL synthesizer circuit 4, the waveform shaping circuit 5, the time signal detection circuit 6 and the control circuit 7 cause the next hour after the initial correction. From the 24th hour until the 24th hour, the 1st broadcasting station (for example, NHK No. 1) is automatically selected, and the hourly signal is detected every hour from the signal from the 1st broadcasting station. Data "1" is written in the area A1 of the time memory TMRY at a certain time, and data "0" is written when it is undetectable. Further, from the next hour until the 24th hour, the second broadcasting station. (For example, NHK No. 2) is automatically tuned to detect the hourly signal of the hour from the signal from the second broadcasting station, and when the hourly signal can be detected, data is stored in the area A2 of the time memory TMRY. Write "1" and check When it is impossible to output, write the data “0”, and after the next hour, select the broadcasting station that stores the data “1” that can detect the time signal and select the time signal received from that broadcasting station. Since the time of the clock unit 8 is adjusted based on this, the time can be surely adjusted without being affected by the broadcast contents or the environment of the installation site.

In this embodiment, the broadcasting station in which the data “1” is set is searched and selected for each hour, and the time is corrected. However, the data “1” is set. Any time may be set from the time of both broadcasting stations and the time may be adjusted at the set time. In this case, the time can be adjusted exactly the set number of times a day without being affected by the contents of the broadcast or the environment of the installation location, and the current consumption can be reduced, downsizing, and longer life can be achieved. Can be achieved.

Further, in the present embodiment, the configuration is such that the success / failure data of the time signal detection is collected in the first 48 hours after the initial setting, and the time for correction is set from the data. If the clock was replaced in a different location, or if the time signal could not be detected several times at the time when the data "1" was set, re-acquire data sampling. Various modes are possible. Furthermore, in the present embodiment, the description has been made by specifying two broadcasting stations, but it goes without saying that the present invention can be applied to the case of three or more broadcasting stations.

[0037]

[Effect of device]

 As described above, according to the present invention, the time can be adjusted accurately without being affected by the broadcast contents or the environment of the installation location, and a highly accurate radio-controlled timepiece can be realized.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of a channel selection device in a radio-controlled timepiece according to the present invention.

2A and 2B are diagrams showing a configuration example of a voice signal as a time signal, FIG. 2A is a diagram showing an example of a transmission waveform, and FIG. 2B is a diagram showing a pulse waveform after the waveform of FIG.

FIG. 3 is a block diagram showing a configuration example of a waveform shaping circuit according to the present invention.

FIG. 4 is a diagram showing a configuration example of a time memory according to the present invention.

5 is a flow chart for explaining a correction time selection operation in FIG.

6 is a flowchart for explaining a normal time adjustment operation in FIG.

[Explanation of symbols]

1 ... Antenna part 2 ... Local oscillator constant setting part 3 ... Reception circuit 4 ... PLL synthesizer circuit 5 ... Waveform shaping circuit 51 ... Amplifier 52 ... Low pass filter 53 ... Comparator 54 ... Integrator 55 ... Shaper 6 ... Time signal detection circuit 7 ... Control circuit 8 ... Clock section TMRY ... Time memory V _CC ... Power supply voltage SSW ... Start switch

Claims (1)

[Scope of utility model registration request] 1. A radio-controlled timepiece that adjusts the time of a clock unit by receiving a time signal transmitted from a broadcasting station, wherein at least two specific broadcasting stations are selected by automatic tuning, and Time signal signal detecting means for detecting hourly signal from the transmission signal every hour, storage means, and for each broadcasting station selected, the time when the time signal signal is detected by the time signal signal detecting means for 24 hours from the selection. Is stored in the storage means, the time when the time signal can be detected is selected based on the storage information of the storage means from the next hour, and the time of the clock section is corrected based on the time signal received at that time. A radio-controlled timepiece having a control means.