JP4542801B2 - Timing device, timing system, and timing method - Google Patents

Description

  The present invention relates to a timing device and a timing system using the timing device, and more particularly to a timing device having a function of distributing time data, a timing system using the timing device, and a timing method.

  The parent clock transmits the reference time information wirelessly, such as radio waves, and the child clocks placed around it receive this and correct the time based on the reference time information of the parent clock to match the time of the parent clock A wireless parent-child clock system is known. The reference time of the parent clock is generated by receiving radio waves from an external standard time information source.

  In this wireless parent-child clock system, when the parent clock uses a relatively large output radio wave to transmit the reference time information, it is subject to legal restrictions and requires a procedure such as a license. In addition, a large-scale transmitter is required for the parent clock.

  For this reason, it is conceivable to transmit the reference time information from the parent clock to the child clock using a weakly output radio wave with lenient or no legal restrictions. However, in this case, the effective range of radio waves of the parent clock is limited. Therefore, the arrangement range of the child clock that can be covered by one parent clock is limited, and the child clock cannot be arranged so far away from the parent clock.

In order to solve this problem, Patent Document 1 discloses that a plurality of clocks are hierarchized, and time information is sequentially transmitted from an upper hierarchy clock to a lower hierarchy clock to perform time correction. A possible watch system is disclosed.
JP 2002-148371 A

  In the timekeeping system described in Patent Document 1, the user must set the link relationship, whether the master device is different from the slave device, or the like using a switch or the like. This can be cumbersome and cumbersome for the user. Also, it is not easy to construct an optimal link relationship.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a timing device, a timing system, a timing method, and the like that can automatically construct an appropriate link relationship.

In order to achieve the above object, a time measuring device according to the first aspect of the present invention provides:
The device that receives the standard time information transmitted from the standard time information source and corrects the time data based on the standard time information is defined as the highest layer, and the time data is hereinafter represented according to the time information transmitted from the upper level to the lower level. It includes hierarchical data for positioning a device to be corrected in the lower layer one by one, time information, reliability data indicating the reliability of the time information, and communication channel data indicating a communication channel, time information, reliability Receiving means for receiving reference time information in which data, hierarchical data, and communication channel data are associated with each other;
Timekeeping means,
Correction means for correcting time data of the time measuring means based on time information included in the received reference time information ;
Storage means for storing the reliability data and its hierarchical data indicating the reliability of the time data by the time counting means,
A transmission means for transmitting its own reference time information through its own transmission channel;
With
It said modifying means comprises: a reliability data and the hierarchical data contained in the reference time information received by the receiving means, based on the self-confidence data and the hierarchical data stored in the storage means, the reference time information It is determined whether or not to perform time correction based on the time information included in the time information, and based on the time information included in the reference time information, the time measurement data by the time measuring means is corrected, and the reference time information used for the correction is Modify your own hierarchy data to indicate a hierarchy one level lower than the hierarchy indicated by the included hierarchy data,
The transmission means is one level higher than the hierarchy indicated by its own time information based on the timing data of the corrected timing means, reliability data indicating the reliability of the time information, and hierarchy data of the reference time information used for the correction. Own reference time information including hierarchy data indicating a lower hierarchy and channel data indicating a communication channel other than the communication channel indicated by the communication channel data associated with the time information used for correction. Send in,
It is characterized by that.

It said correcting means, for example, when performing a time correction by the time information included in the reference time information received, to update the self-confidence data stored in the storage means.

For example, when the receiving unit receives the reference time information from a plurality of devices, the correcting unit is configured to measure the time based on the time information included in the reference time information including the reliability data having the highest reliability. Correct the timing data.

For example, the correction unit ignores the reference time information having a reliability lower than the reliability of its own timing data among the reference time information received by the reception unit.

  The reliability data may include information indicating an elapsed time since the time was corrected.

  The reliability data includes, for example, information determined based on an elapsed time since the time was corrected and an error of time measurement data per unit time.

For example, when the reference time information from a plurality of devices can be acquired, the correction unit corrects the time based on the reference time information from the device higher than the own layer and the highest layer.

  For example, when manual correction means for correcting time data of the time measuring means is arranged according to manual operation and the time is corrected by the manual correction means, the transmission means substantially trusts its own reliability data. Information indicating that the degree is the lowest may be used.

The communication channel is prepared by dividing a predetermined time range into a plurality of times, and the receiving means receives the reference time information from another device in the predetermined time range at a predetermined timing, and thereafter The reference time information may be received through a communication channel from a device with the highest reliability.

Is constructed by combining a plurality of the above-described timing device, transmits sequentially the reference time information to the lower layer side from the upper layer side, so that it can correct the kept time based on the time information each time measurement device is included in the reference time information It is also possible to construct a simple timing system.

In order to achieve the above object, a timing method according to the second aspect of the present invention is as follows:
The device that receives the standard time information transmitted from the standard time information source and corrects the time data based on the standard time information is defined as the highest layer, and the time data is hereinafter represented according to the time information transmitted from the upper level to the lower level. It includes hierarchical data for positioning a device to be corrected in the lower layer one by one, time information, reliability data indicating reliability of the time information, and communication channel data indicating a communication channel, and includes time information and reliability data. A reception step of receiving, from the other device, reference time information in which the hierarchical data and the communication channel data are associated with each other;
A timing step for generating timing data by means of timing;
A correction step of correcting time data of the time measuring means based on time information included in the received reference time information by a correction means;
A storage step of storing the reliability data indicating the reliability of the time measurement data by the time measurement means and the own hierarchical data in the storage means;
A transmission step of transmitting the own reference time information through the own transmission channel by the transmission means;
With
The correction step is based on the reliability data and hierarchy data included in the reference time information received by the receiving means, and the own reliability data and hierarchy data stored in the storage means. It is determined whether or not to perform time correction based on the time information included in the time information, and based on the time information included in the reference time information, the time measurement data by the time measuring means is corrected, and the reference time information used for the correction is The own hierarchy data is corrected so as to indicate a hierarchy that is one hierarchy lower than the hierarchy indicated by the included hierarchy data,
The transmission step includes the own time information based on the time data of the corrected time measuring means, the reliability data indicating the reliability of the time information, and the hierarchy indicated by the hierarchy data included in the reference time information used for the correction. One's own reference time information including hierarchical data indicating a lower hierarchy and channel data indicating a communication channel other than the communication channel indicated by the communication channel data associated with the time information used for correction Which is sent on the communication channel,
It is characterized by that.

  According to the above configuration, since the link relationship is set based on the reliability data, it is possible to automatically configure a link network that can provide more accurate time.

  Hereinafter, a timepiece system according to an embodiment of the present invention will be described. In the following, a “clock” system will be described. However, the present invention is not limited to a so-called “clock” having a time display function, but is a device / element (IC (Integration Chip) or tag having a timekeeping function). And widely applicable to systems.

Clock system of this embodiment, as shown schematically in FIG. 1, the clock unit 11 ₀ Layer 0, a clock unit 11 ₁ of the layer 1, the clock unit 11 ₂ of the layer 2,. . . And a clock unit 11 _m of layer m, below, along with modifying its own time by receiving the standard time information in the clock unit 11 ₁ of the layer 0, the reference time information (time watch device 11 ₁ of successively lower layers 1 Correction information) is sequentially transmitted to correct the time so that the accurate time can be maintained and managed as a whole system.

When the long-wave radio waves (Coordinated Universal watch device 11 ₀ Layer 0, including a standard time information UTC, JJY (JST (40kHz) , JST (60kHz)) to receive, own clocked time (year, month, day, hour, minute, and second day of the week, etc.) the modified to fit the standard time. further, clock unit 11 ₀ is transmitted by the transmitting channel a arbitrarily selected shorter the reference time information of a format as illustrated in FIG.

  As shown in FIG. 2, the reference time information includes layer information, transmission channel information, time information indicating year / month / day / hour / minute / second / day of the week, freshness information, station information, and other information.

The reference time information is information for specifying the layer in which the clock device 11 that has transmitted the reference time information is located, and has a range of, for example, 00 to 99. Since clock unit 11 ₀ This example is located at the 0th layer, a 00 showing the zeroth layer.

  The transmission channel information is information for specifying a communication channel through which the reference time information is transmitted. In this example, the transmission channel information is information for specifying A. For example, when 60 communication channels are prepared, for example, a value corresponding to the communication channel is set among the values of 00 to 59.

The time information is information indicating the time of year, month, date, hour, minute, second, day of the week, and the like.
The freshness information is information corresponding to the elapsed time since the time information is corrected using the standard time information, and indirectly indicates the reliability of the time information. This freshness information is, for example, data immediately after correction by standard time information, incremented by +1 every time 1 hour thereafter, and has 99 as a maximum value (lowest freshness). When the time is adjusted manually (manual adjustment), it is automatically set to the lowest rank of 99.

  The station information is information indicating from which information source the time information has been corrected based on the standard radio wave. For example, UTC, JST (40 kHz; East / Fukushima Transmitting Station), JST (60 kHz, West / Kyushu Transmission) ) And manual adjustment).

  Further, as other information, for example, information for changing the transmission channel and information for specifying the communication channel after the change are arranged in the transmission channel area or the additional data area as necessary.

  Each communication channel for transmitting and receiving the reference time information is obtained by sharing a carrier of a specific frequency in a time-sharing manner, for example, 1 second is defined as one communication channel.

Clock unit 11 ₁ of the layer 1 in FIG. 1 receives the reference time information from the clock unit 11 ₀ Layer 0, and modified to suit its own time to the reference time, further, the reference time information, own clocked generated based on the information, the clock unit 11 ₀ of the upper layer is transmitted by different transmission channel B transmission channel a being used.

Hereinafter, similarly, the clock device 11 _k of each layer k (k is an integer of 2 or more ₎ receives the reference time information from the clock device 11 _(k−1) of the layer (k−1), and receives its own time. Is adjusted to match the reference time, and the reference time information indicating its own clock time is transmitted using a transmission channel different from the transmission channel of the clock device 11 _(k-1) of the layer (k-1).

  Each layer 2, 3... M below layer 1 (m = 3 in FIG. 1) has a function of receiving the reference time information from the clock device 11 of the higher layer and correcting the time measurement data. However, the timepiece device 12 that does not have the function of transmitting the reference time information to a layer lower than itself is also appropriately arranged as necessary.

  Thus, the timepiece devices 11 and 12 constitute a time measuring system that measures and uses (not limited to display) an accurate time as a whole.

  Each timepiece device 11, 12 automatically selects and sets the layer in which it is located and the communication channel used for transmission / reception according to the arrival status of radio waves. In other words, the clock device 11 that can receive the radio wave standard signal is located in the highest layer 0 and functions as a master device, and the other clock devices 11 have the most accurate time (freshness information and the smallest layer; freshness information). Priority) Relay device that automatically determines the clock device 11, receives a reference time signal from the clock device 11, corrects its own clock data, and transmits the time reference signal to the clock device 11 lower than itself Alternatively, it functions as a slave device.

  The clock device 12 functions as a slave device that receives the reference time signal from the host device and corrects its own time measurement data.

  As shown in FIG. 3, each timepiece device 11 constituting the timepiece system includes a long wave receiving circuit 201, a power supply circuit 202, a connector 203, a main device 204, and a display device 205.

The long wave reception circuit 201 receives and demodulates a long wave radio wave (UTC, standard radio wave signal JJY) of standard time information, and outputs digital reception information to the main device 204 via the connector 203.
The power supply circuit 202 includes an AC (alternating current) adapter connection plug 211 and a battery 212, and supplies DC power from the AC adapter or the battery 212 to the main device 204 via the connector 203.

  The display device 205 includes a display panel having a segment configuration as shown in FIG. 4 (for example, a liquid crystal display panel), and displays information such as time information and radio wave transmission / reception status under the control of the main device 204.

  As shown in the figure, this display panel includes an AM display segment 221, an PM display segment 222, a TL mark segment 223, a time display segment 224, a separator segment 225, a minute display segment 226, a second display segment 227, a WAVE mark segment 228, W (West station) mark segment 229, E (east station) mark segment 230, antenna mark segment 231, reception level segment 232, battery mark segment 233, month display segment 234, day display segment 235, and day display segment 236.

The morning / afternoon display segments 221 and 222 display whether the morning and afternoon are different when the time is displayed for 12 hours.
The TL mark segment 223 is a display segment for displaying that a reference time signal can be received from a host device. In addition, by switching the display mode of the TL mark segment 223, it is displayed that it is being received and is being transmitted.
The time display segment 224, the delimiter segment 225, the minute display segment 226, and the second display segment 227 display the current time in the format of hour: minute second.

A WAVE mark segment 228, and the W mark segment 229, and Higashikyoku segment 230, whether the clock unit 11 ₀ Layer 0 is receiving the standard radio wave signal within a predetermined time, if that received Indicates whether it is a west or east office. For example, when JST 40 kHz is received and used for time adjustment within 24 hours, WAVE mark segment 228 and east station segment 230 are lit, and JST 60 kHz is received and used for time adjustment. The WAVE mark segment 228 and the W mark segment 229 are turned on. When the UTC signal is received and used for time adjustment, the WAVE mark segment 228 is turned on.
The antenna mark segment 231 and the reception level segment 232 are segments for displaying the intensity of the received radio wave.
The battery mark segment 233 is a segment for displaying the voltage state of the battery 212.
The month display segment 234, the day display segment 235, and the day of the week display segment 236 are segments for displaying the month, day, and day of the week.

  The main device 204 shown in FIG. 3 includes a voltage detector 213, a regulator 214, a switch group 215, an RF (high frequency) circuit 216, a crystal resonator 217, and a control unit 218.

The voltage detector 213 detects the output voltage of the power supply circuit 202 and supplies the detected value to the control unit 218.
The regulator 214 stabilizes the voltage supplied from the power supply circuit 202 and supplies it to the main device 204.
The switch group 215 includes a plurality of switches such as a reset switch RESET, a TRANS switch used for switching a transmission mode, a RECV switch used for switching a reception mode, and the like. Various information and instructions are supplied to the control unit 218 in accordance with the length of the off and on times.

The RF (Radio Frequency) circuit 216 receives and demodulates the reference time information (FIG. 2) from the clock device 11 _{(k−1) of the} upper layer under the control of the control unit 218 and controls the control unit 218. 2) The reference time information (FIG. 2) is transmitted to the clock device 11 _{(k + 1)} of the lower layer using a transmission channel different from the reception channel.

  The crystal resonator 217 oscillates at a predetermined oscillation frequency and supplies an oscillation signal to the control unit 218.

  The control unit 218 controls the entire operation of the timepiece device 11, and is roughly 1) a time measurement operation based on the oscillation signal of the crystal resonator 217, and 2) a reception signal of the long wave reception circuit 201 or the RF circuit 216. Time data correction operation based on (standard radio wave signal or reference time signal) 3) Transmission of reference time information based on the corrected time data via the RF circuit 216 4) Display control of various information on the display device 205 5) A process for responding to an operation input of the switch group 215 is performed.

  In order to perform these controls, the control unit 218 includes a register group 301, a processor 302, a display control unit 303, a timer unit 304, an encoder 305, a decoder 306, a key input unit, as shown in FIG. 307 and a voltage data input unit 308.

  The register group 301 includes a timing data register 311, a reception channel register 312, a transmission channel register 313, a layer register 314, a freshness data register 315, a continuous reception failure count register 316, and an error register 317.

  The time data register 311 stores the current month / day / hour / minute / second / day of the week which is being measured by the clock device 11.

  The reception channel register 312 stores reception channel designation data (for example, any one of the above-described values 00 to 59), received data, and the like that designate a communication channel that receives reference time information from an upper layer. In the case of the layer 0 timepiece device 11 in which there is no higher layer, the type of standard radio wave (UTC, JST East transmission station, JST West transmission station, etc.) is stored.

  The transmission channel register 313 stores transmission channel designation data (for example, any one of the above-described values 00 to 59) that designates a transmission channel for transmitting the reference time information to the lower layer. The channel designation data stored in the transmission channel register 313 is transmitted as information indicating the transmission channel in the reference time information in the format shown in FIG. When the transmission channel designation data is changed by a transmission channel changing operation described later, the transmission channel designation data can be transmitted at least once or twice as a change notice before the transmission channel is actually changed. Further, after the change, it is possible to transmit information indicating the change on the original transmission channel. In this way, the receiving side can increase the chance of detecting the update of the communication channel, and can more reliably follow the channel change on the transmitting side.

  The layer register 314 stores layer data (for example, any one of the above-described values of 00 to 99) indicating which layer of the plurality of layers (multi-layer) shown in FIG. .

  The freshness data register 315 indicates the elapsed time after the month, date, hour, minute, and second stored in the timekeeping data register 311 are corrected using the standard time information in the layer 0 master device. The freshness data indicated by (for example, any one of the above-mentioned values of 00 to 99) is stored. For example, when the processor 302 determines that one hour has passed since the last update timing, the processor 302 increments the stored data by one.

  The continuous reception failure number register 316 stores the number of times that the reference time information from the upper layer cannot be received continuously. In the case of the layer 0 timepiece device 11 in which no upper layer exists, the number of times that the standard radio wave signal cannot be continuously received is stored.

  The error register 317 stores error data indicating an error Δ (for example, 1.0 second per day; 1/24 per hour) of the time measuring operation by the time measuring unit 304 using the crystal resonator 217. The error data is set, for example, at the manufacturing / inspection stage of the timepiece device 11.

  The display control unit 303 controls the display device 205 to display various information under the control of the processor 302.

  The timekeeping unit 304 counts the oscillation signal from the crystal resonator 217, acquires timekeeping data at regular time intervals (for example, every 100 ms), and outputs a timekeeping interrupt signal to the processor 302.

The encoder 305 encodes data to be transmitted supplied from the processor 302, for example, reference time information, generates a baseband signal, and supplies the baseband signal to the RF circuit 216.
The decoder 306 decodes the reception signals of the long wave reception circuit 201 and the RF circuit 216, for example, demodulates a baseband signal of standard time information or reference time information, and supplies the demodulated signal to the processor 302.

The key input unit 307 decodes the on / off signal input in accordance with the operation of the switch group 215 illustrated in FIG. 3 and supplies the decoded signal to the processor 302.
The voltage data input unit 308 outputs the voltage value detected by the voltage detector 213 to the processor 302.

  The processor 302 includes a CPU, a RAM, a ROM, and the like. A) Timekeeping operation, b) Update of various data accompanying timekeeping, c) Timekeeping data correction operation based on a received signal of the long wave receiving circuit 201 or the RF circuit 216, d ) Generation of reference time information based on the corrected timing data and transmission via the RF circuit 216, e) Display control of various information on the display device 205, f) Adjustment of link relation between the clock devices 11, g), etc. I do. Details of the control operation will be described later.

  Next, a description will be given of an operation for configuring the time measuring system as shown in FIG. 1 and performing the time measuring process by combining the timepiece device 11 having the above configuration with reference to FIGS.

  As a premise, a communication channel that shares a carrier in time division is used for communication between the timepiece device 11 and / or the time measuring device 12. Specifically, 60 communication channels of 1 second each are prepared, and 60 seconds from 30:00 to 31 minutes per hour are assigned to 60 channels as 1 channel 1 second. Therefore, for example, communication is performed between each hour 30 minutes and 01 seconds on the 0th channel, and communication is performed between each time 30 minutes and 01 seconds to 02 seconds on the first channel.

(Arrangement)
The user arranges a plurality of timepiece devices 11 constituting the timing system within a distance range in which communication by the RF circuit 216 is possible, and turns on the power.

(Initial operation)
Each timepiece device 11 starts processing shown in the flowchart of FIG. 6 together with other initialization operations when the power is turned on, and specifies the position occupied by itself in the hierarchical structure shown in FIG.

  First, the processor 302 controls the long wave reception circuit 201 to receive a standard radio wave broadcast at 60 kHz from the JST Kyushu transmitting station for a predetermined time, for example, 30 seconds, and capture the received information (step S101). .

  Subsequently, the processor 302 controls the long wave receiving circuit 201 to receive a standard radio wave broadcast at 40 kHz from the Fukushima transmitting station for a predetermined time, for example, 30 seconds, and receives the received information and the like via the decoder unit 306. Information indicating the radio wave intensity is captured (step S102).

  Subsequently, it is determined whether the standard radio wave of any frequency has been received (steps S103 to S105).

If both 60 kHz and 40 kHz standard radio waves can be received and a decoded signal can be obtained (step S103; Yes), one transmitting station is selected according to a predetermined standard (step S106).
On the other hand, when the standard radio wave of 60 kHz can be received but the standard radio wave of 40 kHz cannot be received (step S104; Yes), the west transmitting station (Kyushu) is selected (step S107).
In addition, when the standard radio wave of 40 kHz is received but the standard radio wave of 60 kHz cannot be received (step S105; Yes), the east transmission station (Fukushima) is selected (step S108).

  When the transmitting station is selected, the processor 302 sets the timing data based on the received standard radio wave in the time data register 311, and the reception channel register 312 stores information indicating that the time type is the standard radio wave and the east-west transmitting station. Then, layer 0 is set in the layer register 314, the freshness data register 315 is reset to set the freshness data to the minimum value “01”, and the continuous reception failure frequency register 316 is reset. Further, the display device 205 is controlled via the display control unit 303 to display information indicating the time data stored in the time data register 311, the reception state, and the battery state (step S 109). The display contents in this case are, for example, morning / afternoon display by segments 221, 222, year / month / day / hour / minute / second display by segments 224 to 227 and 234 to 236, WAVE mark segment 228, W or E mark segment 229, 230, the reception status of the standard radio wave by the reception intensity segment 232, the display of the power state based on the detection value of the voltage detector 213 taken in via the voltage data input unit 308, and the like.

  On the other hand, when the standard radio wave cannot be received, UTC from a GPS satellite or the like is received (step S110). If the UTC is received (step S111; Yes), the time data based on the received UTC is set in the time data register 311 in step S109, and the time channel information is shown in the reception channel register 312 as UTC. Is set, layer 0 is set in the layer register 314, the freshness data register 315 is reset to set the freshness data to "01", the continuous reception failure number register 316 is reset, and the corresponding display is performed (step S109). The display contents in this case are, for example, morning / afternoon display by segments 221, 222, year / month / day / hour / minute / second display by segments 224 to 227 and 234 to 236, standard radio wave by WAVE mark segment 228 and reception intensity segment 232, for example. Reception status display, power supply status display based on the detection value of the voltage detector 213 fetched via the voltage data input unit 308, and the like.

  On the other hand, when neither the standard radio wave nor UTC can be received (step S111, No), the processor 302 activates the RF circuit 216, performs a reception operation for a maximum of one hour, and the reference time information output by the other clock device 11 Is received (step S112).

This reception operation will be described with reference to the flowchart of FIG.
First, the processor 302 activates the RF circuit 216 (step S201) and waits for reception of a shortwave signal having a predetermined wavelength until a predetermined time, for example, 1 hour elapses (steps S202 and 203). Here, the reason why the predetermined time is set to 1 hour is that in this embodiment, a communication channel is arranged around 30 minutes per hour, and any communication can be received after waiting for 1 hour.

  If no reference time signal can be received for a predetermined time, a time-out process is executed (step S204), and for example, the user is notified that radio waves cannot be received.

  On the other hand, when the reference time signal from any of the clock devices 11 is received, the time measurement / display is started based on the received reference time signal (step S205). However, the reception state is continued for at least a predetermined time (1 minute in the present embodiment) corresponding to the period in which the communication channel is allocated (steps S206 and S207).

  When the predetermined time has elapsed (step S207), the clock device 11 having transmitted the received reference time signal and having the smallest freshness data and layer is selected as the higher-level device (step S208). That is, the clock device 11 having the small freshness data, that is, the data immediately after being updated using the long wave signal is selected and linked as the clock data (the reference time signal output by the clock device 11 is received). Such reception channel specifying data for specifying the reception channel is set in the reception channel register 312).

  Then, the time data received from the clock device 11 is set in the time data register 311. Also, reception channel designation data for specifying the transmission channel of the linked clock device 11 is set in the reception channel register 312. Further, the own layer is set in the layer register 314 as a value obtained by adding +1 to the layer (determined from the layer information included in the reference time information) of the linked clock device 11 (higher-order device). In addition, a transmission channel is randomly selected from communication channels (empty communication channels) other than one or a plurality of communication channels that have received the reference time signal, and is set in the transmission channel register 313. Further, the freshness data included in the received reference time signal (when the host device is the master device (layer 0), the received freshness data + 1) is set in the freshness data register 315 as the freshness data of this device. . Further, the type of the reference information signal is set in the freshness data register 315 for each of UTC, east transmitting station, and west transmitting station. Further, the continuous reception failure frequency register 316 is reset to 0 (step S209).

  Thereafter, the reference time signal is transmitted for a predetermined period, for example, 30 minutes, “one time every 60 seconds” in seconds corresponding to the transmission channel registered in the transmission channel register 313 (step S210). This is to form a link in a short time.

(Normal operation)
During a normal operation, the timekeeping unit 304 of each timepiece device 11 counts a timed interrupt signal for updating the timed time every time a certain time (for example, 50 ms) is measured using the oscillation signal of the crystal resonator 217. Is output to the processor 302. In response to this timing signal, the processor 302 starts the process shown in FIG.

  First, the processor 302 updates the current time information stored in the time measurement data register 311 (step S301). Further, it is determined whether or not one hour has passed since the previous update timing of the freshness data stored in the freshness data register 315. If one hour has passed, the freshness data is incremented by one (step S302). However, “99” is the upper limit.

Subsequently, processing such as updating of display information is executed (step S303).
The processor 302 repeats such processing, and always keeps the timekeeping time and display in an appropriate state.
The interrupt period is not limited to 50 ms and is arbitrary.

  In addition, the timekeeping unit 304 of each clock device 11 sends a timekeeping interrupt signal for receiving the reference time information to the processor 302 every time a predetermined time (for example, 500 ms) has elapsed.

In response to this timing interrupt signal, the processor 302 starts the process shown in FIG.
First, the control processor 302 indicates whether or not the number of times that the reference time information from the host clock device 11 has not been received is a predetermined number of times (here, 6 times: 6 hours) or more continuously. It discriminate | determines from the content of 316 (step S311).

  If it is determined that the number of times is less than six (step S311; No), it is determined whether or not the timing corresponds to the reception channel specified by the reception channel designation data stored in the reception channel register 312 (step S311; No). Step S312). If it is the timing (step S312; Yes), the reference time signal from the host device is received (step S313).

  If normal reception is possible, the time freshness stored in the received reference time signal is smaller (fresh) than the freshness data stored in its own freshness data register 315, and the host clock device 11 that has received the reference time signal It is determined whether or not the current layer is higher than the self layer by comparing the content of the reference time signal with the information stored in the self register group 301 (step S314). If the received reference time information is fresher and is in an upper layer (step S314; Yes), a) the time measurement data (time data) stored in the time measurement data register 311 is included in the received reference time information. B) update the freshness data and type / station data stored in the freshness data register 315 to the received freshness data, type / station data, and c) the number of consecutive reception failures. The continuous reception failure data stored in the register 316 is reset to 0 (step S315).

  On the other hand, when the freshness of the received reference time information or the layer is lower than the freshness data of the timekeeping data held by itself or the own layer (step S314; No), the timekeeping data is not updated. In this case, the reception period may be sequentially extended by “one communication channel period” to receive the reference time information transmitted on the next communication channel. If a plurality of communication channels are detected, the clock device 11 is linked to the freshness data and the layer with the smallest layer (the timing data is fresh and the layer is higher). When data is detected within the reception period, the last data is received and a determination is made. Furthermore, if the reception channel is the same as its own transmission channel, it is ignored.

  On the other hand, if it is determined in step S311 that the number of times the reference time information has not been received from the host device is consecutively greater than or equal to the predetermined number (here, 6 times), the reception time of 1 second is usually The reception timing is corrected by enlarging by n seconds (step S316). This is because there is a possibility that a time difference is caused by the time measuring unit 304 during a period in which the reference time signal cannot be continuously received, and the reference time signal is received by complementing the time difference.

  The processor 302 obtains the product Δ · T of the error per unit time stored in the error register 317 and the period T during which the reference time signal from the host device cannot be received, and this Δ · T (= n) Increase the channel period back and forth. For example, for a channel between the hour 30 minutes 15 seconds and 16 seconds (the 16th channel), the channel period is 30 minutes 15 seconds-Δ · T to 30 minutes 16 seconds + Δ · T.

  Thereafter, the process proceeds to step S312 and subsequent steps. As a result, the reference time signal can be reliably received regardless of the error of the crystal resonator 217.

  On the other hand, when the current time comes to the start timing of the communication channel specified by the transmission channel designation data stored in the transmission channel register 313 (step S317), the processor 302 combines the reference time information shown in FIG. Transmission is performed from the RF circuit 216 via 305 (step S318). As a result, the reference time signal can be transmitted to the timepiece device 11 that is lower than the timepiece device 11.

  Note that the correction of the reception timing in step S316 can also be performed based on the freshness data. For example, the freshness data S indicating the approximate elapsed time from the correction of the timekeeping data based on the standard radio wave, and the time difference Δ measured by the crystal unit 217 per unit time are read from the freshness data register 315 and the error register 317, and May be used to obtain the amount of time difference n = S · Δ, and the start time of each communication channel may be advanced by n and the end time may be delayed by n.

  Note that the interrupt period of the process in FIG. 8B is not limited to 500 ms, and may be arbitrary, and may be the same as the interrupt period of the process in FIG.

(Transmission channel automatic change operation to prevent interference)
Each processor 302 receives transmission data of each communication channel once a day, for example, in a time zone in which a communication channel of a predetermined time is set randomly or pseudo-randomly, and is used by itself. It is determined whether or not there is a clock device 11 that is transmitting using the same communication channel as the channel. The random data generation means is arbitrary, but for example, the reception operation of the RF circuit 216 may be performed at a predetermined time to determine a random value from the reception data. Each clock device 11 may perform this process at a timing determined based on a certain standard (for example, every day).

  First, as shown in FIG. 9, the processor 302 refers to the freshness data register 315 and the error register 317 to obtain a product S · Δ of the freshness data S and the error Δ (step S401). This S · Δ is an amount that is expected to be shifted in time due to an error of the crystal resonator 217.

  Next, the RF circuit 216 and the decoder 306 are connected between “start time−S · Δ” and “end time + S · Δ” in the time zone in which the communication channel is set (30:00 to 21:00). Receive data via At this time, not only the carrier is detected, but all or a part of the data is received / decoded to detect (search) a transmission channel actually used as a transmission channel for the reference time signal (step S402).

  Next, when data is detected on the same communication channel as the transmission channel set in its own transmission channel register 313, an arbitrary one of the communication channels (empty channels) from which no data is detected is randomized. Alternatively, it is arbitrarily selected by generating a pseudo random number (step S403).

  In the slave mode (layer 1 or higher) (step S404: Yes), the freshness data and the upper clock device 11 having the lowest layer are re-linked (step S405). That is, the clock data register 311 is updated based on the time information, the transmission channel is set in the reception channel register 312, the freshness data and the time type / station information are set in the freshness data register 315, and the continuous reception failure frequency register 316 is reset.

  With such a configuration, a channel that collides with a channel used by another device is gradually moved to an empty channel, and interference can be prevented.

  In addition, when the transmission channel is changed in step S403, “changed transmission channel” and “specified transmission channel after change” in the transmission channel before the change several times (for example, 2 to 3 times) after the change. To send data. As a result, the clock device 11 linked to the clock device 11 whose transmission channel has been changed in step S403 (having received the reference time signal output by the clock device 11) can recognize the transmission channel after the change, The receiving channel can be changed.

  In addition, before changing the transmission channel, in the reference time information shown in FIG. 2, changing the transmission channel, the changed transmission channel, the change timing, etc. are transmitted in advance, and the processor 302 on the receiving side. It is also possible to receive this information and change the reception channel at the notified timing.

(Display control operation)
The processor 302 executes the display control process shown in FIG. 10 by, for example, a periodic interrupt process every 500 ms.
First, as usual, information such as AM / PM, year / month / day / hour / minute / second, day of the week, etc. is displayed on the display device 205 via the display control unit 303 (step S501).

  Subsequently, it is determined by referring to, for example, the continuous reception failure frequency register 316 whether or not the reference time information is received from the higher-order clock device 11 within a predetermined time, for example, 24 hours (step S502). If the reference time information can be received within 24 hours (step S502; Yes), the TL mark 223 is turned on via the display control unit 303 (step S503). If the reference time information has not been received within 24 hours (step S502; No), the TL mark 223 is turned off by skipping step S503.

  Subsequently, by determining the contents of the freshness data register 315, it is determined whether the freshness data is 24 or less (step S504). As described above, since the freshness data is counted up by one per hour, the fact that the freshness data is 24 or less means that the standard radio wave can be received within approximately 24 hours. Therefore, if it is determined in step 504 that the freshness data is 24 or less (step S504; Yes), the WAVE mark segment 228 is turned on. When the west station of JJY is received, the W mark segment 229 indicating “west” is turned on. When the east station of JJY is received, the E mark segment 230 indicating “east” is lit, and the UTC In this case, only the WAVE mark segment 228 is turned on (step S505).

  On the other hand, if it is determined in step 504 that the freshness data is greater than 24 (step S504; No), step S505 is skipped to turn off the WAVE mark segment 228, W mark segment 229, and E mark segment 230.

  By adopting such a configuration, for example, when normal (accurate) time display cannot be performed due to a combination of lighting / extinguishing of the TL mark segment 223, the WAVE mark segment 228, the W mark segment 229, the E mark segment 230, and the like. Therefore, it can be easily determined whether the standard radio wave itself is not obtained or the link between the timepiece devices 11 is not established. It is also possible to determine the reception state at that time.

Further, the processor 302 executes the process shown in FIG. 11A when the RF circuit 216 is performing a receiving operation in accordance with the notification from the RF circuit 216, and as shown in FIG. The display is driven so as to flow from 223 to the left (step 601), and is repeated until the reception process is completed (step S602). Further, when the RF circuit 216 is performing a transmission operation in accordance with the notification from the RF circuit 216, the processor 302 executes the process shown in FIG. 11B, and as shown in FIG. The display is driven so as to flow from 223 to the right (step 611), and is repeated until the transmission process is completed (step S612).
With such display driving, it can be determined that transmission processing and reception processing are being performed.

In the case of transmission display, the processor 302 or the display control unit 303 may display the transmission state when the RF circuit 216 is actually outputting a carrier by a transmission control signal from the RF circuit 216. Good.
On the other hand, the processor 302 or the display control unit 303 detects not only that the RF circuit 216 detects the carrier but also that the decoded data matches the format shown in FIG. 2 based on the reception control signal from the RF circuit 216. The reception display may be performed only when it is performed.

(Manual timing process)
As shown in FIG. 12, the timepiece devices 11 and 12 of this embodiment can adjust the time by operating the switch group 215 in the same manner as a normal timepiece device (steps S701 and S702). In this case, the processor 302 sets time data corresponding to the input operation in the time data register 311. However, in this case, the processor 302 sets the freshness data (99) of the lowest rank in the freshness data register 315 (step S703). Thereby, the situation where the other timepiece devices 11 and 12 are linked to the timepiece device 11 manually adjusted can be prevented. However, processing such as transmission of reference time information is performed in the same manner as the above-described processing.

  In the timepiece system configured as described above, when each timepiece device 11, 12 reaches, for example, a predetermined time (about 3 to 4 times a day), the standard radio wave reception process (step S 101-1) similar to the process of FIG. 6 is performed. It is desirable to execute the process of receiving the reference time information (step S112) when the process cannot be received after executing (S111). The radio wave reception status changes depending on the day / night, weather, ambient environment, etc., so by trying standard radio wave reception operation at such a frequency, the reception probability of standard radio waves improves, and accurate timekeeping is possible. It becomes possible. In this case, the selection of the transmitting station in step S107 is preferably, for example, the station selected immediately before.

  As described above, according to this embodiment, by properly arranging the timepiece device 11, the timepiece device 11 itself receives standard radio waves (UTC, JJY, etc.) or links with other timepiece devices 11. To form a hierarchical network. In addition, even when the configuration changes or some devices fail, an appropriate link network can be formed. Moreover, interference can be prevented. Furthermore, by devising the display, it is possible to easily determine whether the reason why the accurate time cannot be measured is the reception of the standard radio wave or the problem with the link.

  In addition, this invention is not limited to the said embodiment, A various deformation | transformation and application are possible.

  For example, the freshness data update method can be changed as appropriate. For example, it is also possible to add date / time / minute / second in which time data is corrected using standard radio waves to the freshness data, and to update the freshness data every time a certain period elapses from this date / time / minute / second.

In the above embodiment, the freshness data corresponding to the elapsed time after the correction is used as the data indicating the reliability of the time data. However, other data can be used. For example, it is possible to use an integral value of a product of the corrected elapsed time and the error data Δ.
For example, after M0 time has elapsed in layer 0 clock device 11 with error Δ0, the reference time signal is transmitted to the device in layer 1 with error Δ1, and when M1 time has elapsed, Δ0 · M0 + Δ1 · M1 It is also possible to use such data as data indicating the degree of error.

  The type of carrier shown in the actual form can also be arbitrarily changed. For example, the long wave is exemplified as the communication carrier for the standard signal and the short wave is exemplified as the communication carrier between the timepiece devices 11, but radio waves of other arbitrary frequencies can be used. Furthermore, it is also possible to use light as a carrier for wireless communication, and the reference time information and the like may be exchanged through communication using the generally known light modulation.

  It is also possible to perform the above processing by connecting the clock device 11 with a wired cable. That is, the present invention can be applied to any configuration in which a signal transmitted from an arbitrary timing device 11 can be transmitted to other timepiece devices 11 within a certain range and can sequentially transmit signals from upstream to downstream.

  Further, the data format, the number of communication channels, the frequency, the interrupt cycle, etc. are merely examples, and can be changed as appropriate.

  The slave dedicated device can be easily manufactured by removing the long wave receiving circuit 201 from the connector 203 shown in FIG. 3, for example. For the reception-only device, the function of the transmission part may be removed from the function of the control unit 218.

  Further, as described above, the present invention is not limited to the timepiece device, and the data format, the number of communication channels, the frequency, the interrupt cycle, and the like are merely examples, and can be appropriately changed.

  Furthermore, as described above, the timepiece devices 11 and 12 are shown as examples. However, the present invention is not limited to the timepiece, and the device has a function of measuring and correcting the date, time, etc. regardless of whether or not the timepiece is displayed. It can be widely applied to systems, devices and elements.

It is a lineblock diagram of the timepiece system in an embodiment of the invention. It is a figure for demonstrating the example of a format and communication channel of the reference time information (time correction information) transmitted between the timepieces shown in FIG. It is a block diagram which shows the structure of the timepiece device shown in FIG. It is a figure which shows the structural example of a display apparatus. It is a block diagram which shows the structural example of the control part shown in FIG. It is a flowchart for demonstrating the operation | movement at the time of power activation. 7 is a flowchart for explaining a reception operation in the RF circuit of FIG. 6. (A) Timekeeping processing at normal time, (b) is a flowchart for explaining processing for time correction. It is a figure for demonstrating the transmission channel setting process for preventing interference. It is a figure for demonstrating a display control process. It is a figure for demonstrating a display control process. It is a flowchart for demonstrating a manual timing process.

Explanation of symbols

11… Clock device (with transmission function)
12 ... Clock device (without transmission function)

Claims (11)

The device that receives the standard time information transmitted from the standard time information source and corrects the time data based on the standard time information is defined as the highest layer, and the time data is hereinafter represented according to the time information transmitted from the upper level to the lower level. It includes hierarchical data for positioning a device to be corrected in the lower layer one by one, time information, reliability data indicating the reliability of the time information, and communication channel data indicating a communication channel, time information, reliability Receiving means for receiving reference time information in which data, hierarchical data, and communication channel data are associated with each other;
Timekeeping means,
Correction means for correcting time data of the time measuring means based on time information included in the received reference time information ;
Storage means for storing the reliability data and its hierarchical data indicating the reliability of the time data by the time counting means,
A transmission means for transmitting its own reference time information through its own transmission channel;
With
It said modifying means comprises: a reliability data and the hierarchical data contained in the reference time information received by the receiving means, based on the self-confidence data and the hierarchical data stored in the storage means, the reference time information It is determined whether or not to perform time correction based on the time information included in the time information, and based on the time information included in the reference time information, the time measurement data by the time measuring means is corrected, and the reference time information used for the correction is Modify your own hierarchy data to indicate a hierarchy one level lower than the hierarchy indicated by the included hierarchy data,
The transmission means is one level higher than the hierarchy indicated by its own time information based on the timing data of the corrected timing means, reliability data indicating the reliability of the time information, and hierarchy data of the reference time information used for the correction. Own reference time information including hierarchy data indicating a lower hierarchy and channel data indicating a communication channel other than the communication channel indicated by the communication channel data associated with the time information used for correction. Send in,
A timing device characterized by that. The said correction | amendment means updates the reliability data of the self memorize | stored in the said memory | storage means, when performing the time correction by the time information contained in the received reference | standard time information. Timing device. When the receiving means receives the reference time information from a plurality of devices, the correcting means is based on the time information included in the reference time information including the reliability data having the highest reliability. to correct, timing device according to claim 1 or 2, characterized in that. Said correction means, of the reference time information received by the receiving means ignores the reference time information with lower reliability than the reliability of the own clocked data, any of claims 1 to 3, characterized in that Or a timing device according to claim 1. The reliability data includes information indicating the elapsed time since the correct time, timing device according to any one of claims 1 to 4, characterized in that. The reliability data and the elapsed time since the correct time, including information determined on the basis of the error of the time data per unit time, any one of claims 1 to 4, characterized in that 1 Timekeeping device according to item. When the reference time information from a plurality of devices can be acquired, the correction means performs time correction based on the reference time information from a device that is higher than the own hierarchy and higher in the hierarchy. The timekeeping device according to any one of claims 1 to 6 . Manual correction means for correcting the time measurement data of the time measurement means according to manual operation, and when the time measurement data is corrected by the manual correction means, the transmission means is substantially the most reliable of its own reliability data. The time measuring device according to claim 1 , wherein the time measuring device is information indicating low. The communication channel is prepared by dividing a predetermined time range into a plurality of times,
The receiving means receives the reference time information from another device at a predetermined timing within the predetermined time range,
Thereafter, the reference time information is received through a communication channel from a device having the highest reliability.
The time measuring device according to any one of claims 1 to 8 , wherein A combination of a plurality of timing devices according to any one of claims 1 to 9 , wherein reference time information is sequentially transmitted from an upper layer side to a lower layer side, and each timing device is based on time information included in the reference time information. A timekeeping system characterized in that the timekeeping time can be corrected. The device that receives the standard time information transmitted from the standard time information source and corrects the time data based on the standard time information is defined as the highest layer. It includes hierarchical data for positioning a device to be corrected in the lower layer one by one, time information, reliability data indicating reliability of the time information, and communication channel data indicating a communication channel, and includes time information and reliability data. And receiving step of receiving, from the other device, reference time information in which the hierarchical data and the communication channel data are associated with each other,
  A timing step for generating timing data by a timing means;
  A correction step of correcting time data of the time measuring means based on time information included in the received reference time information by a correction means;
  A storage step of storing the reliability data indicating the reliability of the time measurement data by the time measurement means and the own hierarchical data in the storage means;
  A transmission step of transmitting own reference time information by the transmission means through the own transmission channel;
With
  The correction step is based on the reliability data and hierarchy data included in the reference time information received by the receiving means, and the own reliability data and hierarchy data stored in the storage means. It is determined whether or not to perform time correction based on the time information included in the time information, and based on the time information included in the reference time information, the time measurement data by the time measuring means is corrected and the reference time information used for the correction is The own hierarchy data is corrected so as to indicate a hierarchy that is one level lower than the hierarchy indicated by the included hierarchy data,
  The transmission step includes the own time information based on the time data of the corrected time measuring means, the reliability data indicating the reliability of the time information, and the hierarchy indicated by the hierarchy data included in the reference time information used for the correction. One's own reference time information including hierarchical data indicating a lower hierarchy and channel data indicating a communication channel other than the communication channel indicated by the communication channel data associated with the time information used for correction Which is transmitted on the communication channel,
Timekeeping method characterized by that.

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