JP2000075071A - Method and device for supplying coordinate universal time and storage for storing program for supplying coordinate universal time - Google Patents

Abstract

PROBLEM TO BE SOLVED: To continuously supply time coincident with coordinate universal time (UTC) by requiring fixed time from time when leap second correction should be made to that when time is allowed to coincide with the UTC with fixed accuracy, and by using time being calculated according to a clock signal supply device with an accurate frequency for a fixed amount of time up to time when the coincidence with the UTC is completed. SOLUTION: In a UTC supply system, a UTC supply device 100 and an upper UTC supply device 200 are connected to a network 300. The UTC supply device 100 is provided with a system timer 110, a time supply device 120, and the like. The time supply device 120 supplies UTC to the supply device 120 based on time being calculated from a clock signal being obtained from a clock signal supply device 130 while the error of the system timer 110 from the clock of the upper UTC supply device is eliminated with sufficient accuracy. Also, after the above, certain amount of time passes, the time supply device 120 supplies the UTC again based on the time being supplied by the system timer 110.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and an apparatus for supplying Coordinated Universal Time and a storage medium storing a Coordinated Universal Time supply program, and more particularly to a method for obtaining a system timer by integrating clock signals. Network Ti
The agreement to provide the correct Coordinated Universal Time by using the time calculated from the clock signal to correct the difference from the Coordinated Universal Time when the leap second of the computer system timer is corrected using the The present invention relates to a universal time supply method and apparatus, and a storage medium storing a universal time supply program.

[0002]

2. Description of the Related Art In order to keep the system timer of a computer accurate, the time can be adjusted to a more accurate clock connected to a network using NTP. This method has a problem that a difference of up to one second from the Coordinated Universal Time occurs at the time of correction by addition or deletion of leap seconds. In UNIX, which is widely used as a computer OS, the system timer can be accurately maintained by NTP.

First, a description will be given of a case where leap seconds are inserted by the above method. FIG. 6 shows the relationship between the Coordinated Universal Time when a leap second is inserted and the system timer. In the figure, when Coordinated Universal Time represents 60 seconds due to the insertion of leap seconds, the system timer already represents 00: 00: 00: 00. Thereafter, until the time t ₁ , the system timer delays the advance of the time, and at the time t ₁ , it represents the same time as the Coordinated Universal Time.

Next, a description will be given of the case of deleting leap seconds.
FIG. 7 shows the relationship between the Coordinated Universal Time and the time supplied by the system timer when deleting leap seconds. In the figure,
00:00:00 the next day due to the deletion of leap seconds in Coordinated Universal Time
In seconds, the system timer is set to 1
It represents 1:59:59. After that, until the time t ₁ , the system timer advances the time in advance, and at the time t ₁ , it represents the same time as the Coordinated Universal Time.

There are also services such as Telephone JJY which provide Coordinated Universal Time using a telephone line.

[0006]

However, in the above-described conventional method using NTP, the 60-second notation for adding the leap second added when a leap second is added is not performed. Skips 59 seconds to display 0 seconds. For this reason, after the leap second correction is performed in the Coordinated Universal Time, a process of gradually adjusting the system timer to the Coordinated Universal Time is performed for a while so that the time does not return. During this time, accurate Coordinated Universal Time cannot be supplied.

Further, the service provided by the telephone JJY has a problem that it cannot be provided by a computer having no built-in modem connected to a telephone line. As described above, the computer system is often based on the time calculated from the clock supply device inside the computer, and irregularly corrects the leap second at the end of June or the end of December (Coordinated Universal Time). Time:
UTC) is often not supported.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described circumstances, and has a time disorder that occurs for a while after a leap second correction using a leap second correction instruction signal supplied from the outside and clock information independently provided by a computer. Except for, an agreement that realizes a system timer that supplies the exact universal time even when the leap second is corrected, and that can always provide the time that matches the universal time with the precision of the time interval of the computer system timer It is an object of the present invention to provide a universal time supply method and apparatus, and a storage medium storing a universal time supply program.

[0009]

FIG. 1 is a diagram for explaining the principle of the present invention. The present invention (Claim 1) is a method for supplying Coordinated Universal Time which provides an accurate Coordinated Universal Time, wherein a leap second correction is performed from a time at which leap second correction is to be performed until a leap second correction. Provide the time of the system timer that requires a certain time to set the time with the accuracy of (Step 1), and provide a clock signal with an accurate frequency during the fixed time until the end of the time adjustment from Coordinated Universal Time The time is supplied by calculating the Coordinated Universal Time using the time calculated from the supply device (step 2), and after a lapse of time capable of supplying the time based on the Coordinated Universal Time with a certain accuracy, the system The time of the timer is provided (step 3).

According to the present invention (claim 2), the clock of the system timer is adjusted to the clock time of the upper coordinated universal time supply device connected to the network using a network time protocol (NTP). At the same time, a leap second correction instruction is output based on a second designation signal obtained from the higher-order UTC supply device. According to the present invention (claim 3), the tendency of the time lag calculated from the clock signal supply device with respect to the time of the system timer is determined from the time when the leap second correction instruction is received from the leap second correction instruction device. Based on the time information measured up to this point, estimation is performed using the least squares method, and the time obtained from the clock signal supply device is corrected based on the estimation result.

According to the present invention (claim 4), it takes a certain period of time to shift from the time of the system timer to the time calculated by the clock signal supply device, and gradually reduces the ratio of the time of the system timer, By gradually increasing the ratio of the time calculated by the signal supply device, the time is gradually switched from the time of the system timer to the time obtained by the clock signal supply device.

According to the present invention (claim 5), it takes a certain period of time to shift from the time calculated by the clock signal supply device to the time of the system timer, and the ratio of the time calculated by the clock signal supply device is gradually increased. By gradually increasing the ratio of the time of the system timer, the time is gradually switched from the time calculated by the clock signal supply device to the time of the system timer.

FIG. 2 is a diagram showing the principle of the present invention. The present invention (claim 6) is a Coordinated Universal Time supply device for providing accurate Coordinated Universal Time, wherein a leap second correction instruction for instructing to perform leap second correction a predetermined time before leap second correction. Means 140, a system timer 110 which requires a certain time from the time when leap second correction is to be performed to the time adjustment with a certain precision in Coordinated Universal Time, and a clock signal supply means 130 for supplying a clock signal having an accurate frequency.
Until the leap second correction time, the time of the system timer 110 is provided, and for a certain period of time until the end of time adjustment with the Coordinated Universal Time, the time calculated from the clock signal supply means 130 is used. And a time supply means for providing the time of the system timer 110 after a lapse of a time capable of supplying the time based on the Coordinated Universal Time with a certain accuracy.

According to the present invention (claim 7), the leap second correction instructing means 140 adjusts the clock of the system timer 110 to the clock of the UTC time supply means connected to the network using NTP, Means for outputting a leap second correction instruction based on a second designation signal obtained from the upper universal time coordinate supply device.

The present invention (claim 8) provides a system timer 1
The tendency of the time lag calculated from the clock signal supply means 130 with respect to the time of 10 is calculated by calculating the time information measured from the time when the leap second correction instruction is received from the leap second correction instruction means to the time when the leap second correction is performed. Originally, there is further provided a shift tendency estimating means for estimating using the least squares method, and a shift correcting means for correcting the time obtained from the clock signal supply means based on the result estimated by the shift tendency estimating means.

According to the present invention (claim 9), the time supply means 12 is provided.
At 0, it takes a certain period of time to shift from the time of the system timer 110 to the time calculated by the clock signal supply means 130, and gradually reduces the ratio of the time of the system timer 110. Includes means for gradually increasing the ratio of the calculated time to gradually switch from the time of the system timer 110 to the time obtained from the clock signal supply means 130.

According to the present invention (claim 10), the time supply means 1 is provided.
At 20, it takes a certain time to shift from the time calculated by the clock signal supply means 130 to the time of the system timer 110, and gradually reduces the ratio of the time calculated by the clock signal supply means 130. By gradually increasing the time ratio of the timer 110,
A means for gradually switching from the time calculated by the clock signal supply means 130 to the time of the system timer 110 is included.

The present invention (Claim 11) is a storage medium storing a Coordinated Universal Time supply program for providing accurate Coordinated Universal Time,
Leap second correction process in which a leap second correction is instructed a predetermined time before leap second correction, a clock signal supply process for supplying a clock signal having an accurate frequency, and a leap second correction process. Until the time of correction, provides the system timer time that requires a certain time from the time when leap second correction should be performed until the time is adjusted with a certain degree of accuracy in Coordinated Universal Time, and provides a fixed time until the end of time adjustment with Coordinated Universal Time During the time, the time is supplied by calculating the Coordinated Universal Time using the time calculated from the clock signal supply process, and after the time has elapsed in which the time based on the Coordinated Universal Time can be supplied with a certain accuracy Has a time supply process for providing the time of the system timer.

According to the present invention (claim 12), in the second correction instructing process, the time of the system timer is adjusted to the time of the clock of the upper universal time supply process connected to the network using NTP, and the leap second correction is performed. Outputting an instruction based on a second designation signal obtained from the upper coordinated universal time supply device.

According to the present invention (claim 13), the tendency of the time lag calculated from the clock signal supply process with respect to the time of the system timer is indicated by a leap second correction instruction from the leap second correction instruction process. Based on the time information measured up to the second correction time, the shift tendency estimation process that estimates using the least squares method, and the time obtained from the clock signal supply process based on the result estimated by the shift tendency estimation process. It further includes a shift correction process for correcting.

According to the present invention (claim 14), in the time supply process, it takes a certain time to shift from the time of the system timer to the time calculated by the clock signal supply process, and the ratio of the time of the system timer is gradually increased. And gradually increasing the ratio of the time calculated from the clock signal supply process to gradually switch from the time of the system timer to the time obtained from the clock signal supply process.

According to the present invention (claim 15), in the time supply process, it takes a certain time to shift from the time calculated by the clock signal supply process to the time of the system timer, and the time is calculated from the clock signal supply process. Includes a process of gradually reducing the time ratio and gradually increasing the time ratio of the system timer to gradually switch from the time calculated by the clock signal supply process to the time of the system timer.

As described above, the present invention uses a leap second correction instruction signal provided from the outside and clock information independently provided by a computer to correct the leap second and remove the time turbulence occurring for a while after the leap second correction. In addition, it is possible to realize a system timer that supplies accurate Coordinated Universal Time even during leap second correction. Further, the time supply means supplies the time supplied by the system timer until the time before the leap second correction time of the day, and uses the time provided by the deviation correction means until it can supply the Coordinated Universal Time. Can be provided.

[0024]

DESCRIPTION OF THE PREFERRED EMBODIMENTS First, the outline of the present invention will be described.
The present invention corrects (inserts or deletes) the difference from the Coordinated Universal Time when the leap second of the computer system timer is corrected. FIG. 3 shows the configuration of the Coordinated Universal Time supply system of the present invention.

The coordinated universal time supply system shown in FIG.
0 is a configuration connected to the network 300. The UTC supply device 100 includes a system timer 110, a time supply device 120, a clock signal supply device 130, and a leap second correction instruction device 140. The universal time supply device 10 in the universal time supply system shown in FIG.
0 sets the clock of the system timer 110 to the network 30
In addition to using NTP to match the time of the clock of the upper coordinated universal time supply device 200 connected to 0, a leap second instruction is given based on the second designation signal obtained from the upper coordinated universal time supply device 200. The correction instruction device 140 outputs a leap second correction instruction.

The operation of the above configuration will be described below.
Until there is a leap second correction instruction from the leap second correction instruction device 140, the time supply device 120 receives the time supplied by the system timer 110 that has been corrected using NTP and supplies the coordinated universal time. When the leap second correction instruction device 140 receives a leap second correction instruction by NTP from the UTC supply device 200 connected to the network 300, the leap second correction instruction device 140 sends the leap second correction instruction to the time supply device 120. Do.

The time supply device 120 has a system timer 1
The clock signal supply device 13 is connected to the clock of the higher coordinated universal time supply device 200 connected to the network 300 for a certain period of time until the error disappears with sufficient accuracy.
Based on the time calculated from the clock signal obtained from 0,
The universal time is supplied to the time supply device 120. And
After the elapse of the above-mentioned certain time, the Coordinated Universal Time is supplied again based on the time supplied by the system timer 110.

FIG. 4 shows a configuration in which a corrected UTC supply apparatus is used in the UTC supply system of the present invention. The system shown in the figure has a configuration in which a corrected type universal coordinated time supply device 400 and a higher-order coordinated universal time supply device 200 are connected to a network 300. Amended Coordinated Universal Time Supply Device 4
00 is a system timer 410, a time supply device 420,
It comprises a clock signal supply device 430, a shift correction device 440, a shift tendency estimation device 450, and a leap second correction instruction device 460. System timer 410, time supply device 4
20, the clock signal supply device 430, and the leap second correction instruction device 460 are the same as those in FIG.

The shift tendency estimating device 450 of the corrected type universal time supply device 400 having the above-described configuration is adapted to calculate the tendency of the time shift calculated from the clock signal supply device 430 with respect to the time of the system timer 410 by a leap second correction instruction device. Based on the time information measured from the time when the leap second correction instruction is received from 460 to the time when the leap second correction is performed, estimation is performed using the least squares method.

The shift correction device 440 is based on the estimation result of the shift tendency estimating device 450 and outputs the clock signal supply device 43.
Correct the time required from zero. Until there is a leap second correction instruction from the leap second correction instruction device 460, the time supply device 420 performs the same operation as in FIG. The leap second correction instruction signal by the NTP is 23 of the leap second correction time.
The time is set from 59 minutes before, 0 am the day after the leap second correction
The setting is canceled at 0 hour. Therefore, after 23 hours and 59 minutes before the leap second correction time, the higher-order UTC supply device 20
When communication is performed by NTP to 0, a leap second correction instruction is sent with distinction between insertion and deletion.

When the leap second correction instruction device 460 obtains a leap second correction instruction signal, the leap second correction instruction device 460
Sends a leap second correction instruction to the time supply device 420 and the deviation tendency estimation device 450. When the time supply device 420 receives the leap second correction instruction signal, the time supply device 420 supplies the time supplied by the system timer 410 until time t ₀ before the leap second correction time of the current day. Thereafter, the system timer 410
Until a certain time t ₁ at which the system supplies the Coordinated Universal Time with the same accuracy as before the leap second correction, the time supply device 42
0 supplies the Coordinated Universal Time corrected using the time supplied from the shift correction device 440, without using the time provided by the system timer 410.

The shift tendency estimating device 450, which has received the leap second correction instruction from the leap second correction instruction device 460, determines the time calculated from the clock signal supply device 430 and the system timer corrected by NTP until t ₀ of the current day. 410
Error information is collected from the clock signal supply device 430 for the system timer 410, and the tendency of the clock advance calculated by the clock signal supply device 430 is estimated using the least squares method. On the basis of the estimated progress, the shift correction device 440 corrects the time calculated from the clock signal acquired from the clock signal supply device 430. At t ₀ on the day of the leap second correction, the shift correction device 440 provides the time supply device 420 with the coordinated universal time based on the corrected time.

Thus, the time supply device 420 can supply the corrected time to the computer.

[0034]

Embodiments of the present invention will be described below with reference to the drawings. In the Coordinated Universal Time supply system of FIG. 4, it takes a certain time to shift from the time of the system timer 410 to the time calculated by the clock signal supply device 130, and gradually reduces the ratio of the time of the system timer 410 to the clock. By gradually increasing the ratio of the time calculated by the signal supply device 140, the time is gradually switched from the time of the system timer 410 to the time obtained by the clock supply device 430.

It takes a certain period of time to shift from the time calculated by the clock signal supply device 430 to the time of the system timer 410, and
By gradually decreasing the ratio of the time calculated from the above and gradually increasing the ratio of the time of the system timer 410,
The time is gradually switched from the time calculated by the clock signal supply device 430 to the time of the system timer 410.

The following describes a method of gradually switching from the supply time of the system timer 410 when a leap second is inserted to a time calculated from the clock supply device 430, and a system based on the time calculated from the clock supply device 430 when a leap second is inserted. The case of gradually switching to the supply time of the timer 410 will be described. FIG. 5 shows a method of calculating the time when leap seconds are inserted according to an embodiment of the present invention.

In the figure, s1 is the time provided by the time supply unit 420 when gradually switching from the supply time of the system timer 410 to the time calculated by the clock supply unit 430 when the leap second is inserted, and s2
Is the time provided by the time supply device 420 when gradually switching from the time calculated by the clock supply device 430 when the leap second is inserted to the supply time of the system timer 410.

At time t ₀ , as described above, after 23 hours 59 minutes 59 seconds before the insertion of leap seconds, the deviation tendency estimating apparatus 450 can estimate the deviation tendency with necessary and sufficient accuracy by t ₀ . Indicates the time before leap second insertion. Time t
₂ is a time after time t _{0 and} before the insertion of leap seconds. At this time, the time is between time t ₀ and time t ₂ t _a
The time s ₁ provided by the time supply device 420 at s is s
Is the time represented by the system timer 410, and c is the time based on the time calculated by the clock supply device 430, and s ₁ = α × c + β × s. Here, α = (t _a −t ₀ ) ÷ (t ₂ −t ₀ ) and β = (t ₂ −t _a ) ÷ (t ₂ −t ₀ ).

As described above, the time t ₁ represents the time at which the system timer 410 supplies a time that matches the Coordinated Universal Time with the accuracy before the insertion of the leap second. At this time, t
Indicates that the switching from the time based on the time calculated from the clock supply device 430 to the time supplied by the system timer 410 until ₁ after time t _3. Time s ₂ for time supply unit 120 at time t _b of middle of performing the switching is provided, as described above, the time representing the system timer 410 s, the clock supply device c 43
If 0 is a time based on the calculated time, then s ₂ = γ × s + δ × c. Here, γ = (t _b −t ₁ ) ÷ (t ₃ −t ₁ ) and δ = (t ₃ −t _b ) ÷ (t ₃ −t ₁ ).

In the above description, the case of inserting a leap second has been described, but the method of deleting a leap second can also be gradually switched in the same manner as described above. Although the above description has been made based on the configurations in FIGS. 3 and 4, the coordinated universal time supply device 100 and the corrected Coordinated Universal Time supply device 400 are constructed as programs, and Disk device, floppy disk, CD connected to a computer used as a universal coordinated time supply device
-The present invention can be easily realized by storing the program in a portable storage medium such as a ROM or the like and installing it when implementing the present invention.

It should be noted that the present invention is not limited to the above-described embodiment, but can be variously modified and applied within the scope of the claims.

[0042]

As described above, according to the present invention, a computer connected to a network communicates with an upper-coordinated universal time supply device connected to the network by NTP, so that it is usually very accurate. Can supply Coordinated Universal Time. The clock error immediately after the leap second correction is NT
The system using P is not specified, and usually performs an operation of gradually adjusting the system timer to the universal time. In the present invention, the time error in the process of gradually adjusting the system timer is always adjusted to the universal time by using a clock signal that is originally obtained by the computer or obtained by adding it later. Can be supplied.

[Brief description of the drawings]

FIG. 1 is a diagram for explaining the principle of the present invention.

FIG. 2 is a principle configuration diagram of the present invention.

FIG. 3 is a configuration diagram of a coordinated universal time supply system of the present invention.

FIG. 4 is a configuration diagram using a corrected UTC supply device in the UTC supply system of the present invention.

FIG. 5 is a diagram showing a method of calculating time when leap seconds are inserted according to an embodiment of the present invention.

FIG. 6 is a diagram illustrating a relationship between a coordinated universal time and a system timer when a leap second is inserted.

FIG. 7 is a diagram showing the relationship between the Coordinated Universal Time and the system timer when a leap second is deleted.

[Explanation of symbols]

 REFERENCE SIGNS LIST 100 Coordinated Universal Time supply device 110 System timer 120 Time supply means, Time supply device 130 Clock signal supply means, Clock signal supply device 140 Leap second correction instruction means, Leap second correction instruction device 200 Higher Coordinated Universal Time supply device 300 Network 400 Correction Coordinated Universal Time supply device 410 System timer 420 Time supply device 430 Clock signal supply device 440 Deviation correction device 450 Deviation tendency estimation device 460 Leap second correction instruction device

Claims (15)

[Claims] 1. Accurate Coordinated Universal Time
sal time), a system that requires a certain amount of time from when the leap second correction should be performed to when the time is adjusted with a certain degree of precision in Coordinated Universal Time until the leap second correction Provide the time of the timer, and for a certain period of time until the end of the time adjustment with the Coordinated Universal Time, calculate the Coordinated Universal Time using the time calculated from the clock signal supply device having the correct frequency, and set the time. And supplying the time of the system timer after a lapse of a time capable of supplying the time based on the Coordinated Universal Time with a certain precision. 2. A network time protocol (Network Time Protocol) is added to the time of a clock of a higher-order universal time supply device connected to a network.
2. A method according to claim 1, wherein the adjustment is performed by using a protocol (NTP) and a leap second correction instruction is output based on a second designation signal obtained from the upper coordinated universal time supply device. 3. A tendency of a time lag calculated from the clock signal supply device with respect to a time of the system timer from a time when a leap second correction instruction is received from the leap second correction instruction device to a time when a leap second correction time is received. 3. The UTC supply method according to claim 2, wherein the time is estimated using a least squares method based on the time information measured during the period, and the time obtained from the clock signal supply device is corrected based on the estimation result. 4. It takes a certain period of time to shift from the time of the system timer to the time calculated by the clock signal supply device, and gradually reduces the ratio of the time of the system timer. The method according to claim 1, wherein the time is gradually switched from a time of the system timer to a time obtained from the clock signal supply device by gradually increasing a ratio of the calculated time. 5. A certain period of time is required to shift from the time calculated by the clock signal supply device to the time of the system timer, and the ratio of the time calculated by the clock signal supply device is gradually reduced; 2. The system timer according to claim 1, wherein a time ratio of the system timer is gradually increased to gradually switch from a time calculated by the clock signal supply device to a time of the system timer.
Coordinated universal time supply method as described. 6. A leap second correction instructing means for instructing to perform leap second correction a predetermined time before leap second correction, the leap second correction indicating means comprising: A system timer that requires a certain time from the time when the second correction should be performed to the time adjustment with a certain precision in Coordinated Universal Time, a clock signal supply unit that supplies a clock signal with an accurate frequency, and a leap second correction Provides the time of the system timer, and calculates the Coordinated Universal Time using the time calculated from the clock signal supply means for a fixed time until the end of the time adjustment with the Coordinated Universal Time, and calculates the time. And a time supply means for providing the time of the system timer after a lapse of time capable of supplying the time based on the Coordinated Universal Time with a certain accuracy. Coordinated Universal Time (UTC) supply apparatus according to claim. 7. The leap second correction instruction means adjusts the time of the system timer to the time of a clock of a higher-order universal time supply means connected to a network using NTP, and issues a leap second correction instruction to the higher-order time. 7. The Coordinated Universal Time supply device according to claim 6, further comprising means for outputting based on a second designation signal obtained from the Coordinated Universal Time supply device. 8. A tendency of a time lag calculated by the clock signal supply means with respect to a time of the system timer from a time when a leap second correction instruction is received from the leap second correction instruction means to a time when a leap second correction time is received. Based on the time information measured during the period, the deviation tendency estimating means for estimating using the least squares method, and the time obtained from the clock signal supply means is corrected based on the result estimated by the deviation tendency estimating means. 8. The UTC supply apparatus according to claim 7, further comprising a shift correction unit. 9. The time supply means takes a certain period of time to shift from the time of the system timer to the time calculated by the clock signal supply means, and gradually reduces the time ratio of the system timer.
7. The UTC power supply according to claim 6, further comprising means for gradually increasing the ratio of the time calculated by said clock signal supply means to gradually switch from the time of said system timer to the time obtained by said clock signal supply means. apparatus. 10. The time supply means takes a certain period of time to shift from the time calculated by the clock signal supply means to the time of the system timer, and calculates the ratio of the time calculated by the clock signal supply means. 7. Coordinated universal time according to claim 6, further comprising means for gradually decreasing the time of the system timer and gradually increasing the time ratio of the system timer from the time calculated by the clock signal supply means to the time of the system timer. Feeding device. 11. Coordinated Univ.
a leap second correction instruction process for instructing that a leap second correction be performed a predetermined time before a leap second correction, and a precise frequency. A clock signal supply process for supplying a clock signal having the following, and a leap second correction instruction process, until a leap second correction is performed, a certain time from when the leap second correction should be performed to when the time is adjusted with a certain precision in Coordinated Universal Time. The time of the system timer is provided, and the time is calculated by calculating the Coordinated Universal Time using the time calculated from the clock signal supply process for a certain period of time until the end of time adjustment with the Coordinated Universal Time. After a lapse of time capable of supplying the time based on the Coordinated Universal Time with a certain accuracy, the time of the system timer is provided. A storage medium storing a Coordinated Universal Time supply program, comprising: 12. The leap second correction instructing process includes: setting a clock of the system timer to an NTP time of a clock of a higher coordinated universal time supply process connected to a network.
12. The storage medium storing the universal time supply program according to claim 11, further comprising a process of adjusting by using the above and outputting a leap second correction instruction based on a second designation signal obtained from the upper universal time coordinate supply device. 13. The method according to claim 1, wherein a tendency of a time difference calculated from the clock signal supply process with respect to a time of the system timer is changed from a time when a leap second correction instruction is received from the leap second correction instruction process to a time when a leap second correction time is received. Based on the time information measured during, a shift tendency estimation process of estimating using the least squares method, and correcting the time obtained from the clock signal supply process based on the result estimated in the shift tendency estimation process 13. The storage medium storing the universal time supply program according to claim 12, further comprising a shift correction process. 14. The time supply process takes a certain period of time to shift from the time of the system timer to the time calculated by the clock signal supply process, and gradually reduces the ratio of the time of the system timer. 12. The Coordinated Universal Time supply according to claim 11, comprising a process of gradually increasing the ratio of the time calculated from the clock signal supply process to gradually switch from the time of the system timer to the time obtained from the clock signal supply process. A storage medium that stores programs. 15. The time supply process may take a certain period of time to shift from the time calculated by the clock signal supply process to the time of the system timer, and determine a ratio of the time calculated by the clock signal supply process. 12. The Coordinated Universal Time according to claim 11, further comprising a process of gradually switching from a time calculated by the clock signal supply process to a time of the system timer by gradually decreasing the time ratio of the system timer. A storage medium storing a supply program.