JP4101644B2 - Parent-child clock system and parent clock used therefor - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention generally relates to a parent-child clock system for correcting the time of a child clock. More particularly, the present invention relates to a parent-child clock system capable of wire-transmitting standard time information to a parent clock of another parent-child clock system and a parent clock in the parent-child clock system that performs time adjustment wirelessly and in a relay manner. .
[0002]
[Prior art]
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. Since this wireless parent-child clock system does not require a wire for relay transmission of time information, a plurality of child clocks that display times that coincide with the time of the parent clock are arranged relatively freely on the premises or on the premises. It is suitable for.
[0003]
For example, even in a wireless parent-child clock system installed in a relatively large site or in a complex building, the parent clock can relay the reference time information to the child clock, and the position of the child clock can be relatively Patent Document 1 discloses one that can be freely selected or changed.
[0004]
[Patent Document 1]
JP 2002-148371 A
[0005]
[Problems to be solved by the invention]
In the parent-child clock system described in Patent Document 1, since time information is transferred in a relay manner in the system, a wireless parent-child clock system can be installed in a relatively large site or a complex building. The position of the child clock can be selected or changed relatively freely. However, in the conventional parent-child clock system, the parent clock either receives the standard time information by radio waves or acquires the standard time information by wire, and if it fails to receive the standard time information, it again until the reception is successful. There was a problem of having to try. Furthermore, since the conventional parent-child clock system is configured to transmit the time information between the child clocks in the system by a relay system, there is a problem that the number of child clocks is limited due to an accumulated error caused by the relay-type transmission. there were. For this reason, the installation range of the parent-child clock system has been limited to a limited area.
[0006]
[Means for Solving the Problems]
  Accordingly, an object of the present invention is to solve the problems of the prior art described above.
  In order to achieve this object, the present invention according to claim 1Including a plurality of sub-clocks that receive time information wirelessly and adjust the time,From parent clockFrom the child clock of the first rank to the child clock of the second rank, the time information is sequentially transferred to the child clock of the lower rank.Relay time informationintroduceA parent-child clock system,
  The parent clock includes a receiving unit capable of receiving standard time information, a correcting unit correcting the own time based on the received standard time information, and the system in the system based on the corrected own time. Transmitting means for creating time information for correcting the time of the slave clock and transmitting the information to the slave clock in the system wirelessly;SelfTime as other standard time informationSaidMeans for transmitting to the parent clock of the parent-child clock system;WithA parent-child clock system is provided.
[0007]
  Further, the receiving means can acquire standard time information by radio and wire, and the receiving means usually receives standard time information by an external radio wave other than the parent-child clock system, but the standard time information by the radio wave is not received. If it cannot be received, it is switched to the standard time information transmitted via wired communication from the parent clock of the other parent-child clock system, and the correction means receives the parent clock of the other parent-child clock system received. Correct your time based on standard time information.
[0008]
  In the present invention, with the above configuration, the parent clock of the parent-child clock system can transmit its own time information as the standard time information to the parent clock of another parent clock system. On the other hand, the parent clock of another parent clock system can selectively acquire the standard time information or the time information from another parent clock by the receiving means, and can have the selectivity of the time information acquisition method of the parent clock. . In addition, another parent-child clock system connected by communication with one parent-child clock system can be provided, and the number of accompanying child clocks can be increased. The communication may be wired communication such as dedicated parallel communication for a watch system, general-purpose parallel communication such as GP-IB, dedicated serial communication, general-purpose serial communication such as RS232C, RS-422 / 485, or wireless communication. In this way, it is possible to synchronize the times of the parent clocks of a plurality of parent-child clock systems.
[0009]
  Also,The master clock usually receives standard time information by radio waves such as GPS or JJY. However, if reception of standard time information by radio waves is difficult for some reason, the master clock of another parent clock system is used. By receiving the standard time information transmitted via wired communication, the parent clock of the parent-child clock system can reliably acquire the standard time information.
[0010]
  Claim2The parent and child clock system according to claim 1 provides the parent and child clock system according to claim 1, wherein the means for transmitting by wired communication is the Internet or an intranet.
[0011]
According to the present invention, the parent clocks of a plurality of parent-child clock systems can communicate with each other via the Internet or an intranet. Therefore, the parent clock and the parent-child clock system can be managed and monitored via the Internet or an intranet. The master clock may have, for example, wired communication means using Ethernet (registered trademark).
[0012]
  Claim3The present invention described in claim1 or 2In the parent-child clock system according to claim 1, the parent clock has an IP address of the parent clock itself and a local IP address of the child clock in the parent-child clock system, and the child clock is accessible via the parent clock. A parent-child clock system is provided.
[0013]
According to the above configuration, the present invention can access the parent clock and the child clock of the parent-child clock system via the Internet or an intranet.
[0014]
  Claim4The present invention as described in claim 1 to claim 1 to3In the parent-child clock system according to any one of the above, the child clock includes a receiving unit that wirelessly receives time information, a correcting unit that corrects its own time based on the received time information, and a corrected own time Time information for correcting the time of other child clocks based on the time information, and rank information to be distinguished from the time information received by the receiving means is attached to the time information to the lower rank child clocks in the system There is provided a parent-child clock system characterized by having a transmission means for transmitting in a relay manner.
[0015]
According to the above configuration, the present invention can wirelessly transmit time information to a slave clock in the master-slave clock system wirelessly.
[0016]
  Claim5The present invention described in claim4In the parent-child clock system according to claim 1, the child clock further includes individual identification information control means for giving the individual identification information to the means for transmitting the individual identification information for transmitting the individual identification information for identifying the self clock to the transmitted time information. A parent-child clock system is provided.
[0017]
According to the present invention, each child timepiece transmits individual identification information for identifying itself to the time information according to the above configuration. Therefore, the child timepiece that receives the transmitted time information and uses it for time correction has its time information The source of
[0018]
  Claim6The present invention described in the above is a parent clock for a parent-child clock system that corrects the time by transmitting time information from the parent clock in a relay manner to the child clock,
  The parent clock includes a receiving unit capable of receiving standard time information, a correcting unit correcting the own time based on the received standard time information, and the system in the system based on the corrected own time. Transmitting means for creating time information for correcting the time of the slave clock and transmitting the information to the slave clock in the system wirelessly;selfOther time as standard time informationSaidMeans for transmitting to the parent clock of the parent-child clock system;, And the receiving means can acquire standard time information by radio and wire, and the receiving means usually receives standard time information by an external radio wave other than the parent-child clock system, but the standard time by the radio wave When the information cannot be received, it is switched to the standard time information transmitted via wired communication from the parent clock of the other parent-child clock system, and the correction means receives the parent of the received other parent-child clock system. Correct your time based on the standard time information of the clockA parent clock is provided.
[0019]
  According to the present invention, the parent clock of the parent / child clock system can transmit its own time information as standard time information to the parent clock of another parent clock system. On the other hand, the parent clock of another parent clock system can selectively acquire the standard time information by radio waves or the time information from another parent clock by the receiving means, and has the selectivity of the acquisition method of the standard time information of the parent clock. be able to. In addition, another parent-child clock system connected by communication with one parent-child clock system can be provided, and the number of accompanying child clocks can be increased.
  In the case of a master clock, the receiving means usually receives standard time information by radio waves such as GPS or JJY. However, if reception of standard time information by radio waves is difficult for some reason, the parent clock of another parent clock system is used. By receiving standard time information transmitted from the clock via wired communication, the master clock of the parent-child clock system can reliably acquire the standard time information.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 schematically shows three parent-child clock systems 11, 12 and 13 according to one embodiment of the present invention. The parent-child clock system 11 includes a parent clock 2, a first-rank child clock 3A1, and two second-rank child clocks 3B1 and 3B2. Similarly, the parent-child clock system 12 includes a parent clock 2 ', a first-rank child clock 3A1', and two second-rank child clocks 3B1 'and 3B2'. Similarly, the parent-child clock system 13 includes a parent clock 2 ″, a first-rank child clock 3A1 ″, and two second-rank child clocks 3B1 ″ and 3B2 ″. However, each parent-child clock system 11, 12, 13 is not limited to the above-described rank and child clock arrangement, and can have more ranks and more child clocks. Furthermore, it is possible to have a slave clock connected to the system via a repeater (not shown). Since the parent clock and the child clock constituting each parent-child clock system 11, 12, 13 are the same, only the parent clock 2 and the child clocks 3A1, 3B1, and 3B2 of the parent-child clock system 11 will be described below.
[0021]
In each parent-child clock system 11, 12, 13, a predetermined output is provided between the parent clock 2 and the first-rank child clock 3A1, and between the first-rank child clock 3A1 and the second-rank child clocks 3B1 and 3B2. And two-way communication using radio waves having a predetermined frequency. Accordingly, information including time information is transmitted bidirectionally in the systems 11, 12, and 13 in a bidirectional manner. The radio wave output and frequency are selected so as not to require a license or permission under legal regulations. The radio waves may have the same frequency.
[0022]
The parent clocks 2, 2 ′, 2 ″ of each parent-child clock system 11, 12, 13 are interconnected so as to be capable of two-way communication by means of parent clock communication means 7 by wired communication. Dedicated parallel communication for a clock system, general-purpose parallel communication such as GP-IB, dedicated serial communication, general-purpose serial communication such as RS232C, RS-422 / 485, etc., or Ethernet for constructing an intranet. The communication means 7 can transmit and receive time information for synchronizing the time of the parent clock 2 of the plurality of parent-child clock systems 11, 12, 13.
[0023]
The master clock 2 has the configuration shown in the block diagram of FIG. That is, the master clock 2 receives external standard time information radio waves (broadcast time signal, long wave standard radio waves, global positioning system (GPS) time information, etc.) by the antenna 20 and the receiver 21, and the decoder 22 Use the time code of the standard time information. Not limited to this, the master clock 2 may receive external standard time information via a telephone JJY. The time for the master clock 2 to receive the standard time information from the outside can be controlled in a predetermined time zone by the identification number control means 27 for controlling the power supply control means 29 for supplying power to the receiver 21. The received time code of the standard time information is sent to the time correction means 23 via the decoder 22. Then, based on the time code of the standard time information, the time correction means 23 creates correction information to be corrected so as to coincide with the standard time, and sends it to the time measuring means 24. The clock means 24 corrects the time display of the time display means 25 by correcting its own time so as to match the standard time. The time measuring means 24 sends reference time information for correcting the time of the child clock to the encoder 26 by transmitting it to the child clock. The encoder 26 receives data for identifying that it is information from the master clock 2 from the identification number control means 27, attaches it to the reference time information, and sends it to the transmitter 28.
[0024]
The transmitter 28 is supplied with power from the power supply control means 29 by the identification number control means 27 at a predetermined time when the master clock 2 transmits the reference time information. Then, the transmitter 28 attaches error information Δ1 and information for identifying information from the parent clock to the reference time information via the antenna 20, and uses a carrier wave having a predetermined frequency and output as a child in the parent-child clock system 1. Send to watch.
[0025]
The radio wave transmitted by the master clock 2 and the radio waves described later transmitted by each slave clock may have the same frequency. However, as will be described later, transmission is performed by shifting the time so that the transmission times of the master clock 2 and the slave clock do not match, thereby avoiding interference. Instead of this, interference may be avoided by setting the radio wave transmitted by the parent clock 2 and the radio wave transmitted by each child clock to different frequencies.
[0026]
The master clock 2 encodes the reference time information for the intranet by the internet protocol encoder 44, and adds the IP address of the master clock 2 from the IP address control means 46 by the internet protocol control means 43. Then, the data is output on the Ethernet of the communication means 7 between the master clocks via the Ethernet control means 42 and the Ethernet input / output means 41. The master clock 2 receives the reference time information transmitted from the master clock of another parent-child clock system through the Ethernet of the master-clock communication means 7 by the Ethernet input / output means 41 and the Ethernet control means 42, and receives the Internet protocol. The time code is converted by the control means 43 and the Internet protocol decoder 45. Based on the reference time information received from the other parent clock received by the communication means 7 between the parent clocks, as described above, the time of the own clock means 24 and the child clock in the own system as described above. The reference time information can be generated.
[0027]
For example, each of the parent clocks 2, 2 ′, 2 ″ of the parent-child clock systems 11, 12, 13 receives standard time information from the outside at the same time or different times, and if the standard time information is successfully received, for example. For example, the reference time information of the self is transmitted to the communication means 7 between the master clocks as described above, and the master clock that fails to receive the external standard time information is received via the communication means 7 between the master clocks. The reference time information from the parent clock is used to correct the time of itself and the child clock in its own system, and the parent clock that has successfully received the external standard time information passes through the communication means 7 between the parent clocks. The reference time information received from the other master clock may be used to synchronize with the own clock means or to know the accuracy of the own clock means. Reference time information self and self When used to correct the time of the child clock in the system, the IP address of the other parent clock, etc. In addition, the accuracy of its own clock when compared with the reference time information from the other parent clock Can be displayed.
[0028]
The clocking means 24 controls the power supply control means 29 in cooperation with the identification number control means 27 for identifying the master clock 2 as described above, and transmits the predetermined reference time information transmission time or the radio wave from the slave clock. Only during the reception time, power is sent to the transmitter 28, the receiver 21, and other necessary circuits to save power consumption.
The parent clock 2 may receive information on time information received by each child clock for time adjustment from the respective child clocks in the system 1 via the antenna 20, the receiver 21, and the decoder 22. it can. The information from each child clock can be displayed by the display means 22A as needed, and the administrator of the parent / child clock system can use it for managing and maintaining the system. Furthermore, the administrator may be able to use the system for managing and maintaining the system via the parent-clock communication means 7.
[0029]
FIG. 3 shows a configuration of the first rank child clock 3A1 and the second rank child clocks 3B1 and 3B2 of each parent child clock system 11, 12, 13 as the child clock 3. Each child clock has the same configuration, and can communicate bidirectionally with the parent clock 2 and other child clocks in each system by the antenna 30, the receiver 31, and the transmitter 38.
[0030]
The configuration of the child clock 3 in FIG. 3 will be described by taking the first rank clock 3A1 as an example. The slave clock 3 wirelessly receives the reference time information from the parent clock 2 by the antenna 30 and the receiver 31, converts the reference time information to a time code by the decoder 32, and then sends it to the time correction means 33. Further, the decoder 32 detects that the reference time information is transmitted from the parent clock 2 and sends it to the rank control means 37A. If the reference time information has been successfully received, the rank control means 37A stops the power supply from the power supply control means 39 to the receiver 31 and other circuits for a predetermined time until the reception of the next reference time information. , Stop receiving.
[0031]
If the decoder 32 cannot restore the time information sent from the parent clock 2 (or another child clock) to the time code, the time adjustment by the time adjustment means 33 is stopped. Then, it instructs the time information not to be sent to other slave clocks. Further, the decoder 32 notifies the rank control means 37A that the acquisition of time information has failed, and the time information is received by the master clock 2 via the encoder 36, the transmitter 38, and the antenna 30 wirelessly at the time of uplink. Notify the failure.
[0032]
The time correction means 33 creates correction information for correcting its own time based on the reference time information received from the parent clock 2, corrects the time of the time measuring means 34, and matches the time of the parent clock 2. Then, the time measuring means 34 corrects the time display on the time display 35. Then, based on the time of the time measuring means 34, reference time information of the first rank for correcting the time of the child clock 3B1 of the second rank is created and sent to the encoder 36. The reference time information of the first rank is transmitted at a predetermined transmission time of a child clock 3A1 of the first rank described later. The reference time information of the first rank is time information of the time measuring means 34 corresponding to a predetermined transmission time of the child clock 3A1 of the first rank, and is different from the reference time information from the parent clock 2 and is a time more than that. This is later time information.
[0033]
The encoder 36 further adds data for distinguishing from the reference time information of the parent clock to the reference time information of the first rank. Based on the information from the decoder 32, the rank control means 37A sends data indicating that the time information to be transmitted is the reference time information of the first rank to the encoder 36. The individual identification number control means 37 gives the encoder 36 data for identifying the child clock 3A from other child clocks in the parent-child clock system 1. The encoding 36 includes data indicating that it is the first rank reference time information from the rank control means 37 </ b> A in the first rank reference time information from the time measuring means 34 and a specific child from the individual identification number control means 37. The data indicating the clock 3A is added and sent to the transmitter 38.
[0034]
The transmitter 38 transmits information to another child clock via the antenna 30 at a predetermined transmission time. This predetermined transmission time is determined as will be described later, so that it does not overlap with the transmission time of the parent clock 2 and other child clocks using the same transmission frequency, thereby avoiding interference. The transmission time of each child clock is the rank of the child clock, that is, the first rank child clock 3A that directly receives the reference time information from the parent clock 2, and the first rank reference time from the first rank child clock. The second rank child clock 3B that receives the information and the third rank child clock 3C that receives the second rank reference time information from the second rank child clock are sequentially shifted so as to be delayed. ing. Further, there are a plurality of sub-clocks (for example, sub-clocks 3A1 and 3A2 in the first rank, sub-clocks 3B1 and 3B2 in the second rank, and sub-clocks 3C1, 3C2, and 3C3 in the third rank). In order to obtain this, each child clock is further subdivided according to the individual identification number of the child clock and transmitted at the transmission time assigned.
[0035]
The power supply control means 39 obtains its own rank from the rank control means 37A, obtains its own individual identification number from the individual identification number control control means 37, and is assigned based on its own rank and individual identification number. Knowing that the predetermined time has been reached from the time measuring means 34, power is supplied to the transmitter 38 and transmission is performed.
[0036]
The power supply control means 39 starts to supply power to the receiver 31 during the transmission time of the time information from the parent clock 2 and the child clock higher than its own rank, receives the time information, and receives the time information after the reception. The supply of power to 31 is stopped. Here, since the first slave clock 3A1 has the highest rank, the receiver 31 is operated during the transmission time of the master clock 2. As a result, power consumption for reception can be saved. In addition to this, the reception of the first or second rank reference time information transmitted by other child clocks is prevented, thereby preventing repeated correction of time and transmission of reference time information again.
[0037]
Further, as described above, the slave clock 3 transmits information such as whether or not the time information has been successfully received and the received error information to the master clock 2 at a predetermined uplink time. As will be described later, this predetermined uplink time is a time zone different from the time information transmission time, and a different time is allocated for each rank and for each individual identification number. When the power supply control means 38 knows that the predetermined time has come from the time counting means 34, the individual identification number control means 37, and the rank control means 37A, it receives information on its own individual identification number and time information. Electric power is supplied to the transmitter 38 in order to uplink transmit information including availability and the like to the master clock 2.
[0038]
Further, the child clock 3A1 transmits the uplink lower-rank child clock, for example, the second-rank child clock 3B to the parent clock 2 by transmitting information about its own individual identification number and whether or not the time information can be received. When doing so, relay radio waves. For this reason, the child clock 3A supplies power to the receiver 31 in a time zone in which the child clock of the lower rank transmits reception information to the parent clock, and receives radio waves from the child clock of the lower rank.
[0039]
The second rank child clocks 3B1 and 3B2 have the same configuration as the first child clock 3A1 and perform similar operations. The child clock 3B of the second rank analyzes that the reference time information of the first rank from the child clock 3A of the first rank has been received by the decoder 32 and notifies the rank control means 37A. The rank control means 37A identifies itself as a child clock of the second rank, sends data indicating that the time information transmitted by itself is the reference time information of the second rank to the encoder 36, and further In order to perform reception and transmission at the reception time and transmission time assigned to the child clock of the rank, the time of power supply to the receiver 31 and the transmitter 38 is instructed via the power supply control means 39. After receiving the reference time information of the first rank, the receiver 31 stops receiving for a certain time until the reception time of the next reference time information of the first rank, and receives the time information transmitted by the child clocks of other ranks. To prevent.
[0040]
In the above description of the operation, the child clock 3B of the second rank has been described as being in a state where it cannot receive the reference time information transmitted from the parent clock 2, but if it can receive the reference time information from the parent clock 2. In this case, it operates in the same way as the child clock 3A of the first rank, and the time information transmitted by itself can be used as the reference time information of the first rank. In this way, the child clock is generally in a state where it can be received when time information of a higher rank is transmitted, detects whether it can receive time information of a higher rank, and When information can be received, it may be switched to reception of the rank.
[0041]
The time correction means 33 corrects the time of its own time measurement means 34 based on the reference time information of the first rank, and corrects the time display of the time display means 35. Then, if there is a next third rank child clock, the second rank reference time information to be used for time correction by the child clock is sent to the encoder 36. The encoder 36 adds to the time information the information indicating the specific individual identification number of the child clock 3B from the individual identification number control means 37 and the reference time information of the second rank, and sends it to the transmitter 38. . The second rank reference time information transmitted by the second rank child clock 3B is time information at the transmission time assigned by the second rank and the individual identification number as will be described later.
[0042]
FIG. 1 shows the first rank child clock 3A1 to the second rank child clocks 3B1 and 3B2 of each parent child clock system 11, 12, 13; It can be connected so that it can communicate bidirectionally with radio waves.
[0043]
Each child clock 3 has its own individual identification number in the individual identification number control means 37, but otherwise has the same configuration. When the basic time information from the parent clock 2 is received by the rank control means 37A, the first rank When the child clock 3A receives the first rank reference time information from the child clock 3A of the first rank, the child clock 3B of the second rank is automatically ranked. As a result, the sub-clocks can be exchanged.
[0044]
Next, time allocation for downlink transmission of time information for time correction from the parent clock to the child clock will be described with reference to FIG. In addition, in each parent-child clock system 11, 12, 13, you may carry out by changing the frequency of the radio wave to use, respectively, and when each parent-child clock system 11, 12, 13 is spaced apart and does not interfere, the same frequency is used. May be. Downlink transmission is performed, for example, once a day using 1 hour at 2am, but the time required for each child clock to receive and transmit time information is the allocated time, In the example, it takes 1 second. Once the slave timepiece receives the time information, it is possible to prevent unnecessary power consumption because the receiver is turned off as described above. Subsequent reception of time information is not performed after the reception by the receiver is stopped, so that repeated time correction and transmission can be prevented. Each child clock gives priority to time information that is higher in rank, that is, closer to the parent clock among time information such as receivable reference time information, first rank reference time information, and second rank reference time information. And is configured to receive.
[0045]
Note that downlink transmission is not limited to once a day. If downlink transmission is performed once every two to three hours, the accumulated error of the clock in the system can be further suppressed. In addition, some low-accuracy watches have an error of about 1 second per day due to the effects of quality and temperature changes in the installation environment. Since there is a possibility of deviating from the method of completing communication within one second of the example system, it is difficult to adopt it for the child watch. For this reason, if the system performs downlink transmission once every two to three hours, the accumulated error of the clock in the system can be suppressed, and even a low-precision clock can be adopted as a child clock. A system can be constructed at low cost.
[0046]
As shown in FIG. 4, downlink transmission of time information of the first rank child clock 3A in which 1 minute from 2:00 am to 2:01 am is rank 1, that is, reference time information of the first rank It is a time zone. This one-minute time zone is further subdivided into 60 time zones at 1-second intervals, and assigned in correspondence with the individual identification number of the first child clock 3A (specific number between 1 and 60). Downlink transmission is performed in 1 second of the specified time zone. One minute from 2:01 to 2: 2 is the downlink transmission time zone of the time information of the second rank child clock 3B having rank 2, that is, the second rank reference time information. This one-minute time zone is further subdivided into 60 time zones at 1-second intervals, and assigned corresponding to the individual identification number of the second rank child clock 3B (specific number between 1 and 60). The downlink transmission is performed for 1 second in the designated time zone. The same applies when there are child clocks of the following ranks. In this way, even if radio waves having the same frequency are used, there is no interference.
[0047]
Next, with reference to FIG. 5, uplink time allocation for transmitting information indicating the reception status of each child clock from the first to fifth rank child clocks to the parent clock 2 by radio waves will be described. In addition, in each parent-child clock system 11, 12, 13, you may carry out by changing the frequency of the radio wave to use, respectively, and when each parent-child clock system 11, 12, 13 is spaced apart and does not interfere, the same frequency is used. May be. The information from each child clock includes the individual identification number of the child clock, the availability of reception of time information for time correction, and the rank of the received time information (that is, reference time information, reference time information of the first and second ranks). And the individual identification number of the transmission source of the received time information. The uplink is performed, for example, once a day using 1 hour at 3am. However, the time required for each sub-clock to transmit information is the allocated time, 1 second in this example. Therefore, useless power consumption can be prevented. At the start of the uplink, the reception operation for relay is started in each slave clock. As described above, the uplink collects accumulated error information related to the time information received by each slave clock in the master clock, monitors the operation status of the entire system, uses it for maintenance work, and if necessary, repeaters It is also possible to change the position or change the position of the slave clock.
[0048]
As shown in FIG. 5, uplink transmission is started from a lower child clock in reverse to the downlink case. That is, one minute from 3 o'clock to 3 o'clock is the transmission time zone of information of the rank 60 slave clock. This 1-minute time zone is further subdivided into 60 time zones at 1-second intervals, and 1 second of the time zone assigned for each child clock individual identification number (specify a specific number between 1 and 60). To wirelessly. The radio wave transmitted by the slave clock is sequentially relayed by the host slave clock and sent to the master clock 2.
[0049]
One minute from 3:57 to 3:58 is a transmission time zone of information of a slave clock (not shown) whose rank is 3. This 1 minute time zone is further subdivided into 60 time zones at 1 second intervals as described above, and the third rank child clock (not shown) is a time zone assigned corresponding to its own individual identification number. Transmission is performed in 1 second. This information is received by the rank 2 child clock 3B1 or 3B2, and added to the information of the child clocks 3B1 and 3B2 and relayed when the child clocks 3B1 and 3B2 are uplinked.
[0050]
One minute from 3:58 to 3:59 is the transmission time zone of the information of the second rank child clocks 3B1 and 3B2 having rank 2. This 1 minute time zone is further subdivided into 60 time zones at 1 second intervals as described above, and the sub-clocks 3B and 3B2 are assigned their own individual identification numbers (specific numbers between 1 and 60). Transmission is performed in one second of the corresponding time zone. The information of the second rank child clocks 3B1 and 3B2 is received by the first rank child clock 3A1, added to the information of the child clock 3A1, relayed, and delivered to the parent clock 2.
[0051]
The first child clock 3A1 which is the first rank is directly informed to the parent clock 2 during one second assigned corresponding to the individual identification number within one minute from 3:59 to 4:00. Send. In this way, even if radio waves having the same frequency are used, there is no interference.
[0052]
In the master clock 2, information from all the slave clocks is received at 4 o'clock, and the received information is displayed on the display means 22A. From this displayed state, it is possible to confirm whether each slave clock has actually received time information and corrected the time, and the time information received by the slave clock. If necessary, replace the slave clock.・ Repair and improve the reliability of the parent-child clock system.
[0053]
FIG. 6 shows another embodiment of the present invention. The difference from the embodiment of FIG. 1 is that the Ethernet of the communication means 7 between the master clocks is connected to the intranet 8 and further connected to the Internet via a router (not shown). And 13 parent clocks 2, 2 ′, 2 ″ have IP addresses, for example, [192.168.200.1], [192.168.200.2], [192.168.200.3], etc. And can be accessed via the Internet or an intranet.
[0054]
Further, each parent clock 2, 2 ', 2 "is allocated corresponding to each child clock based on the identification number of each child clock 3A1, 3B1, 3B2, etc. in its own system 11, 12, 13 2 is provided in the IP address control means 36 of Fig. 2. As a result, each of the parent clock and the parent clock of the parent-child clock system is provided. Thus, each child clock can be accessed via the Internet or the intranet 8. Therefore, the administrator can manage and inspect the parent and child clock systems 11, 12, and 13 via the Internet or the intranet 8. As a result, It is possible to improve the efficiency of management and inspection of the parent-child clock system.
[0055]
In the above-described embodiment, the communication means 7 between the master clocks is described as wired communication. However, wireless communication may be used, and transmission / reception of the reference time information between the master clocks 2, 2 ', 2 " In the rank 1 transmission time zone, radio waves having the same frequency may be used.
[0056]
【The invention's effect】
According to the parent-child clock system of the present invention, since a plurality of parent-child clock systems can be installed and operated simultaneously, the number of child clocks installed in the wireless parent-child clock system is not limited. Further, the distance limitation of the system coming from the wireless communication reach of the wireless parent / child watch system is eliminated. Further, since the parent clock can be connected to a general-purpose Internet or intranet, a communication infrastructure such as Ethernet can be used as it is, and the laying cost of the parent-child clock system can be greatly reduced. Furthermore, since the master clock can be made Ethernet, it is possible to implement system monitoring / inspection, command control, data acquisition, etc. with a normal personal computer, which is excellent in convenience and economy. By connecting the intranet to the Internet through a router, the parent / child clock system can be connected to the Internet. Furthermore, the parent clock connected to the Internet sets not only the information of the parent clock itself but also the local IP address based on the identification number of the child clock connected to the local network in the parent / child clock system, All child clocks are indirectly assigned IP addresses and are connected to the Internet, and can be used for management and inspection of child clocks.
[Brief description of the drawings]
FIG. 1 is a schematic view of a parent-child clock system according to one embodiment of the present invention.
FIG. 2 is a block diagram of a parent clock of the parent-child clock system according to the embodiment of the present invention.
FIG. 3 is a block diagram of a child clock of the parent-child clock system according to the embodiment of the present invention.
FIG. 4 is a time chart showing time allocation for downlink transmission of time information for time correction in the parent-child clock system according to the embodiment of the present invention.
FIG. 5 is a time chart showing time allocation during uplink of child clock information in the parent-child clock system according to the embodiment of the present invention;
FIG. 6 is a schematic view of a parent-child clock system according to another embodiment of the present invention.
[Explanation of symbols]
11, 12, 13 Parent-child clock system
2, 2 ', 2 "parent clock
3A1, 3B1, 3B2 child clock
7 Communication between parent clocks
8 Internet or intranet
20, 30 Antenna
21, 31 Receiver
23, 33 Time correction means
24, 34 Timekeeping means
26, 36 Encoder
37 Individual identification number control means
37A rank control means
28, 38 Transmitter
41 Ethernet input / output means
42 Ethernet control means
43 Internet protocol control means
44 Internet Protocol Encoder
45 Internet Protocol Decoder
46 IP address control means

Claims (6)

A plurality of slave clocks that receive time information wirelessly and correct the time, and from the master clock to the slave clock of the first rank, the slave clocks of the second rank from the slave clock of the first rank; A parent-child clock system that relays the time information in a relay manner to the child clocks of the lower rank sequentially ,
The parent clock includes a receiving unit capable of receiving standard time information, a correcting unit correcting the own time based on the received standard time information, and the system in the system based on the corrected own time. transmission means for transmitting wirelessly to create the time information for correcting the time of the atomic clock toward the child clocks in the system, master clock of the other of said slave clock system its own time as standard time information Means for transmitting to , wherein the receiving means can acquire standard time information by radio and wire, and the receiving means normally receives standard time information by external radio waves other than the parent-child clock system, If the standard time information by the radio wave cannot be received, it is switched to the standard time information transmitted via wired communication from the parent clock of the other parent-child clock system, and the correction Slave clock system characterized <br/> modifying its own time based on the standard time information of master clock for other slave clock system that is the reception.   2. The parent-child clock system according to claim 1, wherein the means for transmitting by wired communication is the Internet or an intranet. 3. The parent-child clock system according to claim 1 or 2 , wherein the parent clock has an IP address of the parent clock itself and a local IP address of the child clock in the parent-child clock system, and the child clock passes through the parent clock. Parent-child clock system characterized by being accessible. The parent-child clock system according to any one of claims 1 to 3 , wherein the child clock includes a receiving unit that wirelessly receives time information, and a correcting unit that corrects its own time based on the received time information. A time information for correcting the time of another child clock based on the corrected self time is distinguished from the time information received by the receiving means, and the rank of the self from the parent clock And a transmission means for relaying the rank information indicating whether or not to the time information to a lower rank child clock in the system. 5. The parent-child clock system according to claim 4 , wherein the child clock provides the individual identification information to the transmitting means for transmitting the individual identification information for identifying the self to the time information to be transmitted. A parent-child clock system further comprising a control means. A parent clock for a parent-child clock system that corrects the time by transmitting time information from the parent clock to the child clock in a relay manner,
The parent clock includes a receiving unit capable of receiving standard time information, a correcting unit correcting the own time based on the received standard time information, and the system in the system based on the corrected own time. transmission means for transmitting wirelessly to create the time information for correcting the time of the atomic clock toward the child clocks in the system, master clock of the other of said slave clock system its own time as standard time information Means for transmitting to , wherein the receiving means can acquire standard time information by radio and wire, and the receiving means normally receives standard time information by external radio waves other than the parent-child clock system, If the standard time information by the radio wave cannot be received, it is switched to the standard time information transmitted via wired communication from the parent clock of the other parent-child clock system, and the correction Master clock, characterized in that to correct its own time based on the standard time information of master clock for other slave clock system that is the reception.

Images