JP2009053182A - Time adjustment device, time keeping device with time adjustment device, and time adjustment method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a time adjustment device capable of performing a time adjustment without increasing a power consumption, by efficiently receiving time data, within a shortened time period, at the proximity of a timing when a user wants to perform it. <P>SOLUTION: A wrist watch with GPS comprises: a reception initiation information setting program which establishes an initiation timing of reception by a receiving device, immediately or at a constant timing, based on reception indication data of an external operating part, so that Z count data of subframe data may be received from navigation message; and a time data memorizing part which memorizes Z count data as receiving time data. wherein internal time data is corrected based on the receiving time data. The watch is characterized in that starting reception by the receiving device commences at the time of the initiation timing. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a time adjustment device that performs time adjustment based on a signal from a position information satellite such as a GPS satellite, a time measuring device with a time adjustment device, and a time adjustment method.

A GPS (Global Positioning System) system, which is a system for positioning its own position, uses a GPS satellite having an orbit around the earth. This GPS satellite is equipped with an atomic clock. Such GPS satellites have extremely accurate time information (GPS time).
A time correction method using this time information, or a radio timepiece that corrects the display time by analyzing a time code included in a long standard wave instead of a GPS satellite is proposed (Patent Document 1). ).
In addition, the GPS satellite time information is updated at a predetermined cycle. Therefore, the time information after this predetermined period is predicted, the predicted time of the GPS satellite is calculated, and the position information of itself is obtained using the predicted time. For this reason, a method has been proposed that can be obtained even when the GPS satellite pseudorange and position measurement are not excellent in the reception environment (Patent Document 2).

On the other hand, a method for correcting the time using time information (GPS time) of a GPS satellite has been proposed (Patent Document 3).
According to this method, the navigation message is acquired at full power (the CPU is operated and the respective units are operating) immediately after the power is turned on. And the time information contained in the acquired navigation message is acquired, and time calculation is performed. Thereafter, the time is calculated from the relationship between the accuracy of the crystal that generates the reference clock signal of the apparatus and the accuracy of the required timepiece, and the next correction timing is obtained. That is, the time for acquiring the next navigation message (the CPU is in a stopped state and called sleep mode) is obtained. And a navigation message is acquired again after the elapsed time of this sleep mode. Then, the time is adjusted based on the time information from the navigation message.

In this method, the reception timing is determined by the apparatus, for example, immediately after the power is turned on.
However, for example, the user may want to perform time correction using GPS time. In such a case, it is necessary to adjust the reception timing so that reception can be performed and the time can be adjusted at a timing close to the timing at which the user wants to correct the time. In addition, in this way, even when a satellite signal from a position information satellite such as a GPS satellite is received and the time is corrected at a timing close to the timing when the user wants to correct the time, a small clock such as a clock is used. In equipment, it is necessary to reduce power consumption, so it is necessary to obtain information for time correction in a short time.

Japanese Patent Application Laid-Open No. 11-2111858 JP-A-11-125666 Japanese Patent Laid-Open No. 10-82875

  Therefore, the present invention provides a time correction device and a time correction device capable of receiving time data efficiently in a short time at a timing close to the timing at which the user wants to perform time correction, and correcting the time without increasing power consumption. An object is to provide a timekeeping device and a time correction method.

  According to the present invention, the above-described problem shows a time information generation unit that generates time information and generates time information, satellite time related information that is time related information of a position information satellite, and an operation state of the position information satellite. Each of the position information satellites for each subframe information unit, each unit including a plurality of subframe information units each including the satellite time information and at least one of the satellite health information. Based on the instruction information of the external input unit, a receiving unit that receives satellite signals transmitted in order from the outside, an external input unit that generates instruction information to instruct the receiving unit to receive by external input A reception start setting unit for setting a reception start timing of the reception unit so that the satellite signal is received immediately or at a fixed timing; A correction time information storage unit that stores the satellite time related information of the satellite signal as correction time information, and the generation time information is corrected based on the correction time information. This is achieved by a time adjustment device in which reception of the reception unit is started from the time when the start timing arrives.

According to the above configuration, the external input unit generates instruction information for instructing reception by the receiving unit based on an external input. The reception start setting unit instructs the reception unit to start reception so that the satellite signal is received immediately or at a certain timing based on the instruction information of the external input unit. The receiving unit receives a satellite signal transmitted from the position information satellite. The satellite time related information of the satellite signal received by the receiving unit is stored in the correction time information storage unit as correction time information. The generation time information is corrected based on the correction time information.
Therefore, the generation time information is corrected based on, for example, correction time information received by an input operation by a user or the like. Thus, the time adjustment device can correct the generation time information at a timing close to the timing at which the user wants to correct the time. In addition, since the time adjustment device starts reception by an input operation by a user or the like, for example, power consumption can be reduced as compared with automatic reception received at regular intervals.

  Preferably, the position information satellite is a GPS satellite, the satellite signal is in units of five subframe information units from subframe 1 to subframe 5, and the satellite health information is included in the subframe 1. The time correction device is characterized in that the receiving unit receives the satellite time related information and the satellite health information of the subframe 1.

According to the above configuration, in the time adjustment device, the position information satellite is a GPS satellite, the satellite signal is in units of five subframe information units from subframe 1 to subframe 5, and the satellite health information is subframe 1 The receiving unit receives the satellite time related information and the satellite health information of subframe 1.
Thereby, the time adjustment apparatus can receive satellite time related information and satellite health information by receiving the first subframe 1 of the subframe information unit, and can correct the time. For this reason, the time adjustment device can take a short time to receive and can reduce power consumption.

  Preferably, the reception unit includes a determination unit that determines whether the received satellite time related information is correct or not, and the correction time information is the satellite time related information determined to be correct by the determination unit. This is a characteristic time correction device.

  According to the above configuration, in the time adjustment device, the satellite time related information determined by the determination unit that determines whether the satellite time related information received by the reception unit is correct is used as the correction time information. From this, the time adjustment device corrects the time based on the satellite time related information determined to be correct, so that it is possible to correct the time accurately.

  Preferably, the current time correction amount, which is the time correction amount of the generation time information corrected based on the correction time information, is an elapsed time from the generation time information at the time of the previous correction of the generation time information. When the threshold deviation amount, which is a corresponding time deviation amount, is exceeded, the reception unit receives the satellite time related information of the plurality of subsequent subframe information units, and receives the received plurality of the subsequent subframes. The satellite time related information in a frame information unit is stored as satellite time data, and the difference between at least two satellite time data is between the subframe information units including the at least two satellite time data. And at least one of the at least two satellite time data substantially coincident with the difference between the generation time information and the generated time information. Is the time adjustment device also being modified on the basis of the time data.

According to the above configuration, when the time correction amount of the generation time information corrected based on the correction time information exceeds the threshold deviation amount, the time correction device receives a plurality of subsequent subframe information units. The satellite time related information is received, and the received satellite time related information is stored as satellite time data. Then, the time adjustment device is configured to select one of at least two satellite time data in which a difference between at least two satellite time data substantially coincides with a difference between subframe information units including at least two satellite time data. One is selected and the generation time information is modified based on the selected satellite time data.
Thereby, since the time correction apparatus can avoid using uncertain correction time information for correction of generation time information, it can suppress the deviation | shift amount of the corrected generation time information.

  Preferably, the subframe 1 to the subframe 5 respectively have subframe ID data, and when the reception start timing of the reception unit is immediate, the reception unit starts reception, and the reception start setting The reception unit sets the reception start timing of the subsequent subframe 1 based on the first subframe ID data received by the reception unit this time, and the reception start timing of the subsequent subframe 1 arrives Until the receiving unit suspends reception until the reception start timing of the subsequent subframe 1 arrives, the receiving unit resumes reception of the subsequent subframe 1. A time correction apparatus that receives the satellite time-related information and the satellite health information of frame 1.

According to the above configuration, in the time adjustment device, when each of subframe 1 to subframe 5 has subframe ID data, and the reception start timing of the reception unit is immediate, the reception unit starts reception. Then, the reception start setting unit sets the reception start timing of the subsequent subframe 1 based on the first subframe ID data received by the reception unit this time, and the reception start timing of the subsequent subframe 1 arrives. Until the reception timing of the subsequent subframe 1 arrives, the reception of the reception unit is resumed. Then, the receiving unit receives the satellite time related information and the satellite health information of the subsequent subframe 1.
Accordingly, the time adjustment device can reduce power consumption because efficient reception is performed by temporarily stopping reception of the reception unit.

  Preferably, there are a plurality of the position information satellites, and the reception unit includes a state determination unit that determines an operation state of the position information satellite based on the satellite health information, and based on a determination result of the state determination unit. The receiving unit receives the satellite signal from the position information satellite different from the position information satellite.

According to the above configuration, there are a plurality of position information satellites, and the time adjustment device has a state determination unit in which the reception unit determines the operation state of the position information satellite based on the satellite health information, and the determination result of the state determination unit The receiving unit receives a satellite signal from another position information satellite.
Thus, when the operation state of the position information satellite is not normal, the time adjustment device can perform time adjustment with high accuracy by receiving a satellite signal from another position information satellite.

  Preferably, when the elapsed time from the previous reception of the satellite health information to the current time is a predetermined time or more, the reception unit is the subframe information unit including the satellite time related information and the satellite health information. The time correction apparatus is characterized by receiving subframe 1.

According to the above configuration, in the time adjustment device, when the elapsed time from the reception of the previous satellite health information to the current time is equal to or longer than the predetermined time, the reception unit transmits the subframe 1 including the satellite time related information and the satellite health information. Receive.
From this, the time adjustment device receives the subframe 1 when the elapsed time from the previous reception of the satellite health information to the current time is a predetermined time or more, so that the operation state of the position information satellite is determined by the satellite health information. Can be confirmed. As a result, the time adjustment device can determine the reliability of the satellite time related information, and thus can correct the time accurately.

  According to the present invention, the above-described problem shows a time information generation unit that generates time information and generates time information, satellite time related information that is time related information of a position information satellite, and an operation state of the position information satellite. Each of the position information satellites for each subframe information unit, each unit including a plurality of subframe information units each including the satellite time information and at least one of the satellite health information. Based on the instruction information of the external input unit, a receiving unit that receives satellite signals transmitted in order from the outside, an external input unit that generates instruction information to instruct the receiving unit to receive by external input A reception start setting unit for setting a reception start timing of the reception unit so that the satellite signal is received immediately or at a fixed timing; A correction time information storage unit that stores the satellite time related information of the satellite signal as correction time information, and the generation time information is corrected based on the correction time information. This is achieved by a time measuring device with a time adjusting device, wherein reception of the receiving unit is started from the time when the start timing arrives.

  According to the present invention, the above-described problem shows a time information generation unit that generates time information and generates time information, satellite time related information that is time related information of a position information satellite, and an operation state of the position information satellite. Each of the position information satellites for each subframe information unit, each unit including a plurality of subframe information units each including the satellite time information and at least one of the satellite health information. A receiving unit that receives satellite signals transmitted in order from an external input step of generating instruction information for instructing reception to the receiving unit by input from the outside, based on the instruction information, A reception start setting step for setting a reception start timing of the reception unit so as to receive the satellite signal immediately or at a fixed timing; A step of starting reception of the reception unit from the point of time, a correction time information storage step of storing the satellite time related information of the satellite signal received by the reception unit as correction time information, and the generation time information And a step of correcting based on the correction time information.

  Hereinafter, preferred embodiments of a time adjustment device, a time measuring device with a time adjustment device, and a time adjustment method will be described in detail with reference to the accompanying drawings and the like.

(First embodiment)
FIG. 1 is a schematic diagram showing a wristwatch with a GPS time correction device (hereinafter referred to as a GPS wristwatch) as a timekeeping device with a time correction device of the first embodiment, and FIG. 2 is a schematic cross-sectional view of FIG. It is. FIG. 3 is a schematic diagram showing the main hardware configuration of the GPS wristwatch shown in FIGS.
As shown in FIGS. 1 and 2, the GPS wristwatch 10 has a time display unit on which a dial 13, a second hand, a minute hand, an hour hand, and other hands 13 are arranged, and positions such as latitude, longitude, and city name. A display 14 including an LCD display panel on which information and various messages are displayed is formed. The pointer 13 is driven via a gear by a step motor including a motor coil 19 and the like.
As shown in FIG. 1, the GPS wristwatch 10 includes an external operation unit 5 for inputting a reception instruction and the like from the outside. The external operation unit 5 can input an instruction when the user or the like receives the GPS satellite 15a (15b to 15d) and wants to correct the time.

As shown in FIG. 2, the GPS wristwatch 10 has a GPS antenna 11. The GPS antenna 11 is provided in the receiving device 40 (see FIG. 3). The GPS antenna 11 is a patch antenna that receives satellite signals from a plurality of GPS satellites 15a (15b to 15d) orbiting the earth over a predetermined orbit.
The GPS antenna 11 is disposed on the surface of the dial 12 opposite to the time display surface. The dial 12 is formed of plastic or the like that is a material that transmits radio waves that are signals from the GPS satellites 15a (15b to 15d).
The GPS satellites 15a (15b to 15d) are examples of position information satellites, and a plurality of the GPS satellites 15a (15b to 15d) exist above the earth. In the present embodiment, satellite signals are received from the GPS satellites 15a (15b to 15d) present at the position where they are most easily received. In FIG. 1, four GPS satellites 15a to 15d are shown for convenience, but the number of GPS satellites is not limited to this.

Further, the outer case 17 is made of a metal such as stainless steel or titanium. The bezel 16 is preferably made of ceramics in order to improve the reception performance of the satellite signals from the GPS satellites 15a (15b to 15d) of the GPS antenna 11. The bezel 16 is provided with a surface glass portion 18.
The battery 24 is a secondary battery such as a lithium ion battery. And the magnetic sheet 21 is arrange | positioned under the battery 24, and the coil 22 for charging is arrange | positioned through the magnetic sheet 21. As shown in FIG. Therefore, the battery 24 can be charged with electric power from an external charger by electromagnetic induction by the charging coil 22.
Further, the magnetic sheet 21 can bypass the magnetic field. Thereby, the magnetic sheet 21 can reduce the influence of the battery 24 and can perform energy transmission efficiently. And the back glass part 23 is arrange | positioned in the center part of the back cover 26 for electric power transfer.
The GPS wristwatch 10 is configured as described above.

As shown in FIG. 3, the GPS wristwatch 10 includes a time display device 45, a reception device 40, and a time adjustment device 44, and has a configuration that also functions as a computer. Hereinafter, each configuration shown in FIG. 3 will be described.
As shown in FIG. 3, the GPS wristwatch 10 includes a receiving device 40, and receives a satellite signal received from the GPS satellite 15 a (15 b to 15 d) in FIG. 1 from the GPS antenna 11 and a filter (SAW) 31 and RF (Radio). The frequency band is taken out by the baseband unit 30 via the frequency (radio frequency) unit 27.
Here, the filter (SAW) 31 is a band pass filter, and extracts a 1.5 GHz satellite signal. The satellite signal extracted in this way is amplified by the LNA 47, mixed with the signal of the VCO 41 by the mixer 46, and down-converted to IF (intermediate frequency). The clock signal for the PLL circuit 34 is generated from a crystal oscillation circuit (TCXO) 32 with a temperature compensation circuit.
The satellite signal passes through an IF filter 35 and an IF amplifier, and is converted into a digital signal by an ADC (A / D converter) 42. The baseband unit 30 calculates satellite signals based on the control signal. The time data obtained by the baseband unit 30 is stored in the storage unit of the control unit 20, and the corrected time information is displayed through the drive circuit 43.

As described above, the receiving device 40 includes the RF unit 27 and the baseband unit 30, and the RF unit 27 includes a PLL circuit 34, an IF filter 35, a VCO 41, an ADC (A / D converter) 42, an LNA 47, and the like. I have.
The receiving device 40 including the GPS antenna 11 and the filter (SAW) 31 is an example of a receiving unit and is also called a GPS device. Hereinafter, the receiving device 40 including the GPS antenna 11 and the filter (SAW) 31 is referred to as a receiving device 40 or the like.
The baseband unit 30 includes a DSP (Digital Signal Processor) 39, a CPU (Central Processing Unit) 36, and an SRAM (Static Random Access Memory) 37, a crystal oscillation circuit (TCXO) 32 with a temperature compensation circuit, and a flash memory. 33 etc. are also connected.

  The control unit 20 is provided with an RTC (real time clock) 38. The RTC 38 is incremented by a reference clock determined by a crystal resonator connected to the control unit 20. The control unit 20 includes a CPU 20a.

In addition, the charging coil 22 charges the battery 24 as a secondary battery through the charge control circuit 28, and supplies driving power from the battery 24 to the time adjustment device 44 and the like through the regulator 29. Yes. And the control part 20 sends a control signal to the receiver 40 grade | etc.,.
The GPS wristwatch 10 can control the receiving operation of the receiving device 40 and the like via the control unit 20.
As described above, the GPS wristwatch 10 of this embodiment is an electronic timepiece.
The RTC 38 is an example of a time information generation unit that generates time information, and the internal time data 73b (see FIG. 7) that is the time information generated by the RTC 38 is an example of the generation time information. The receiving device 40 is an example of a receiving unit.

4 to 7 are schematic diagrams showing the main software configuration of the GPS wristwatch 10, and FIG. 4 is an overall view.
As shown in FIG. 4, the control unit 20 of the GPS wristwatch 10 includes various programs in the various program storage unit 50, various data in the first various data storage unit 60, and in the second various data storage unit 70. It is configured to process various data.
FIG. 5 is a schematic diagram showing data in the various program storage units 50 of FIG. 4, and FIG. 6 is a schematic diagram showing data in the first various data storage units 60 of FIG. FIG. 7 is a schematic diagram showing data in the second various data storage unit 70 of FIG.
Note that the first various data storage unit 60 in FIG. 6 mainly shows data stored in advance. Further, the second various data storage unit 70 in FIG. 7 mainly shows data after the data in the first various data storage unit 60 is processed by the programs in the various program storage units 50. .
8 and 9 are schematic flowcharts showing main operations and the like of the GPS wristwatch 10.

  The operation of the GPS wristwatch 10 will be described below with reference to various programs and various data in FIGS. 5 to 7 according to the flowcharts in FIGS.

First, as shown in FIG. 8, in ST10, it is determined whether or not the external operation unit 5 (an example of an external input unit) is operated and a reception instruction is given. That is, for example, when the user receives a satellite signal from the GPS satellite 15a (15b to 15d) and wants to correct the time display of the hand 13 or the like, the user operates the external operation unit 5 to operate the GPS satellite 15a (15b). -15d) are input.
Then, the reception instruction information from the external operation unit 5 is stored as the reception instruction data 75a in the reception instruction information storage unit 75 of FIG. Then, the operation signal confirmation program 54 in FIG. 5 confirms the reception instruction information storage unit 75 in FIG. 7 and determines whether the reception instruction data 75a is stored.

If it is confirmed in ST10 that the reception instruction data 75a is stored in the reception instruction information storage unit 75 of FIG. 7, the process proceeds to ST11.
In ST11, the timing for starting reception of the GPS satellite 15a (15b to 15d) is set based on the reception instruction data 75a, and stored as reception start timing data.
Specifically, the reception start information setting program 58 (an example of a reception start setting unit) in FIG. 5 confirms the time at which the reception instruction data 75a in FIG. 7 is stored based on the internal time data 73b in FIG. Then, the reception start information setting program 58 generates reception start data 76a based on the reception timing data 61a stored in the reception timing information storage unit 61 of FIG.
The reception start information setting program 58 in FIG. 5 generates the reception start data 76a so that the internal time data 73b in FIG. 7 can be corrected at a timing of 0 second or 30 seconds per minute close to the time of the reception instruction data 75a. And stored in the reception start storage unit 76.

That is, for example, the time of the reception instruction data 75a when the user operates the external operation unit 5 to input the reception instruction of the GPS satellite 15a (15b to 15d) is from 7:00 am 21 seconds to 49 seconds. If it is between, the time from 7:00 am 50 seconds to 58 seconds is set as the reception start data 76a in consideration of the search time of the GPS satellite 15a (15b to 15d). And reception of the internal time data 73b is started at a timing of 7:01 am.
For example, if the time of the reception instruction data 75a is between 7:00:51 am and 7:01:19 am, the time of 7:01:20 to 28 seconds is the reception start data 76a. It is said. And reception of the internal time data 73b is started at the timing of 7:01:30 am.
That is, the reception instruction data 75a is set so that the internal time data 73b is corrected at a fixed time of 0 seconds or 30 seconds.
As described above, the reception start data 76a is set with the timing before the start of transmission of a subframe 1 (an example of a subframe information unit) to be described later of the satellite signal of the GPS satellite 15a (15b to 15d).
The reception start data 76a is set in consideration of the activation time of the RF unit 27 such as the reception device 40 in addition to the search time of the GPS satellite 15a (15b to 15d).
Accordingly, the reception start data 76a is set so that the search for the GPS satellites 15a (15b to 15d) is started about 2 to 10 seconds before the transmission start of the subframe 1.

Then, the process proceeds to ST12. In ST12, the internal time data 73b in FIG. 7 is referred to and it is determined whether or not the reception start data 76a has been reached. Specifically, the reception start determination program 51 in FIG. 5 refers to the internal time data 73b in FIG. 7 and determines whether or not the reception start data 76a in FIG. 7 has been reached. That is, since the reception start data 76a is, for example, the time from 7:01:20 to 28 seconds as described above, the time information based on the internal time data 73b is 7:01:20 am Confirm that the time is 28 seconds.
When the time information based on the internal time data 73b has not reached the reception start data 76a, the start of reception is waited until the time information based on the internal time data 73b reaches the reception start data 76a. .

On the other hand, when the time information based on the internal time data 73b reaches the reception start data 76a, the process proceeds to ST13. In ST13, reception of the GPS satellite 15a (15b to 15d) is started. That is, the receiving device 40 and the like are activated to prepare for a state in which the GPS satellite 15a (15b to 15d) can be searched.
Specifically, the receiving device 40 or the like starts operation, and generates a C / A code pattern of a GPS satellite 15a (15b to 15d) described later in order to receive a satellite signal from the GPS antenna 11.

Then, the process proceeds to ST14 and a GPS satellite search is started. That is, the satellite search program 52 of FIG. 5 adjusts the GPS satellite 15a (15b to 15d) that can be synchronized by the receiving device 40 and the like by adjusting the generation timing of the C / A code pattern of the GPS satellite 15a (15b to 15d). Search.
The search time of the GPS satellite 15a (15b to 15d) varies depending on whether or not the orbit information of the GPS satellite 15a (15b to 15d) is retained. In the case of a cold start state that does not hold orbit information, the search time takes several seconds.
The GPS wristwatch 10 determines the search start timing so that the data of the subframe 1 can be reliably received according to the holding state of the orbit information.

Next, proceeding to ST15, whether or not it takes more than a certain time until the receiver 40 or the like can synchronize by adjusting the generation timing of the C / A code pattern of the GPS satellite 15a (15b to 15d). Judging.
Specifically, the reception stop determination program 57 in FIG. 5 counts the time from the start of reception, and determines whether or not it takes a certain time or more to search for the GPS satellites 15a (15b to 15d). If it takes more than a certain amount of time, it is determined that a time-out has occurred, the process proceeds to ST16, and the reception ends.
According to this, when the GPS wristwatch 10 is in an environment where the GPS satellite 15a (15b to 15d) cannot be received, for example, indoors, the receiving device 40 is operated for a long time. A lot of power is consumed. In such a case, the GPS wristwatch 10 can avoid wasteful power consumption by terminating reception after a certain period of time has elapsed.

On the other hand, if it is not timed out in ST15, the process proceeds to ST17.
In ST17, it is determined whether or not the GPS satellite 15a (15b to 15d) has been captured. That is, the receiving device 40 and the like search for the GPS satellites 15a (15b to 15d) and synchronize with the satellite search program 52 of FIG. And it is judged whether the navigation message which is an example of the satellite signal of GPS satellite 15a (15b-15d) mentioned later can be demodulated.
If the GPS satellite 15a (15b to 15d) cannot be captured, the process returns to ST14, the search for the GPS satellite 15a (15b to 15d) is performed again, and the other GPS satellites 15a (15b to 15d) are captured. It has become.

On the other hand, if the GPS satellite 15a (15b to 15d) can be captured, the process proceeds to ST18 in FIG. 9 to acquire a navigation message.
Here, before explaining the process of ST18, the navigation message transmitted from the GPS satellite 15a (15b-15d) is demonstrated.

FIG. 10 is a schematic explanatory view showing a navigation message.
As shown in FIG. 10A, signals are transmitted from each of the GPS satellites 15a to 15d in units of one frame data (30 seconds). This one frame data has five subframe data from subframe 1 to subframe 5 (one subframe data is 6 seconds). Each subframe data has 10 words (one word is 0.6 seconds).
The head word of each subframe data is a TLM word storing TLM (Telemetry word) data, and preamble data is stored in the head of the TLM word as shown in FIG. 10B. Has been.
The word following the TLM word is a HOW word in which HOW (hand over word) data is stored. In this HOW word, GPS time information of a GPS satellite called TOW (Time of Week) is placed at the head. Stored.
In the GPS time information, the elapsed time from 0 o'clock every Sunday is displayed in seconds, and returns to 0 at 0 o'clock on the next Sunday. The GPS time information is information in seconds indicated every week from the beginning of the week, and is a numerical value representing elapsed time in 1.5 seconds.
The GPS time information is also referred to as Z count data, and is an example of satellite time related information, which is a clue that the receiving device 40 and the like know the current time.

The week number of GPS time information (hereinafter referred to as “Z count data”) is assigned to the week, and the week number data is included in the navigation message.
The starting point of the Z count data is 10:00, January 6, 1980 in UTC (at the time of world agreement), and the week starting on this day is week number 0. The receiving device 40 and the like obtain the current GPS time by acquiring the week number data and the elapsed time (second) data (Z count data).
The week number data is data that is updated on a weekly basis.
Therefore, if the receiving device 40 or the like has already acquired the week number data and the elapsed time from the time when the week number data is acquired is counted, the week number data may not be acquired again. From the acquired week number data and the Z count data, the current week number data of the GPS satellite 15a (15b to 15d) is known. Thus, normally, by receiving only the Z count data, the GPS wristwatch 10 can perform the receiving operation in a short time, and the power consumption can be reduced.
Further, as shown in FIG. 10B, the data following the Z count data of the HOW word includes subframe ID data which is subframe number information. As a result, the GPS wristwatch 10 can determine whether the received subframe data corresponds to subframe 1 to subframe 5 based on the subframe ID data.

As shown in FIG. 10, the navigation message is data in which the frame data (main frame configuration) is 50 bps and the total number of bits is 1500 bits.
The main frame data is divided into five subframe data each having 300 bits (bits).
As described above, subframe 1 to subframe 5 have Z count data of TLM word and HOW word, respectively.

  In addition to the TLM word and HOW word, the navigation message includes ephemeris (detailed orbit information for each GPS satellite 15a (15b to 15d)), almanac (rough orbit information for all GPS satellites 15a (15b to 15d)), It has data such as UTC data (world agreement time information etc.) not shown.

FIG. 11 is a schematic conceptual diagram for explaining a part of each word data (WORD 1 to WORD 5) of the subframe 1.
As shown in FIG. 11, in the word 3 of the subframe 1, the above-described week number (WN) data and satellite health state information as an example of satellite health information indicating the operation state of the GPS satellite 15a (15b to 15d) itself are shown. Data (also referred to as SVhealth or satellite health information).

Since the navigation messages from the GPS satellites 15a (15b to 15d) are transmitted as described above, the reception of the GPS satellites 15a (15b to 15d) of the present embodiment refers to the GPS satellites 15a to 15d. The best condition is to synchronize the phase with the C / A code from the GPS satellite 15a (15b to 15d).
In this case, a C / A code (1023 chip (1 ms)) is used particularly for synchronization in units of 1 ms. The C / A code (1023 chip (1 ms)) is different for each GPS satellite 15a (15b to 15d) orbiting the earth and is unique.
Therefore, when a navigation message of a specific GPS satellite 15a (15b to 15d) is received, a C / A code specific to the specific GPS satellite 15a (15b to 15d) is generated from the receiving device 40, which is a receiving unit. In this way, it is possible to receive the signal by synchronizing the phase.
When synchronized with the C / A code (1023 chip (1 ms)), the navigation message can be received. For example, the preamble data of the TLM word and the Z count data of the HOW word of subframe 1 as shown in FIG. It can be acquired. Then, after receiving the TLM word and the HOW word, the receiving device 40 and the like can continuously acquire week number (WN) data and satellite health status information data.

The satellite health state information data (SVhealth) can determine the operating states of the received GPS satellites 15a (15b to 15d) and the other GPS satellites 15a (15b to 15d) themselves. That is, it is possible to determine from the satellite health state information data whether the GPS satellite 15a (15b to 15d) itself has some trouble or is a test satellite.
Then, whether or not the acquired Z count data is reliable can be determined by checking the correctness (parity check) with the parity data after the Z count data of the HOW word shown in FIG. If an error is confirmed by the parity check, the Z count data can be regarded as having some abnormality and not used for time correction.

Returning to FIG. 9, if the satellite can be captured in ST17, the process proceeds to ST18. In ST18, it is determined whether or not Z count data has been acquired.
Specifically, the time data acquisition program 53 of FIG. 5 receives a navigation message from the GPS satellite 15a (15b to 15d) and acquires Z count data. And it is memorize | stored in the receiving satellite time information storage part 71 of FIG. 7 as receiving satellite time data 71a.
Then, the time information consistency determination program 501 (an example of a determination unit) in FIG. 5 determines whether or not the received satellite time data 71a (an example of satellite time related information) in FIG. Judgment is made.
That is, the time information consistency determination program 501 in FIG. 5 confirms whether the parity information is the parity data after the Z count data of the HOW word. If an error is confirmed in the parity data, the acquired Z count data is regarded as having some abnormality and is not used for time correction.
As a result, if an abnormality is found, the time data acquisition program 53 in FIG. 5 considers that the Z count data could not be acquired, and returns to ST14 in FIG.

  On the other hand, when the time information consistency determination program 501 in FIG. 5 determines that there is no abnormality in ST18, the time data acquisition program 53 in FIG. 5 determines that the acquired Z count data can be used for time correction. The reception satellite time data 71a in the reception satellite time information storage unit 71 is converted into the first reception time data 73a1 of the reception time data 73a (an example of the correction time information) in the time data storage unit 73 (an example of the correction time information storage unit). Store as (an example of correction time information). Here, it is determined that the Z count data has been acquired, and the process proceeds to ST19.

In ST19, the satellite health condition information data described above is acquired.
Specifically, the other satellite information acquisition program 55 in FIG. 5 acquires the satellite health state information data included in the word 3 of the subframe 1. The other satellite information acquisition program 55 in FIG. 5 stores the acquired satellite health state information data as satellite health state data 72a (an example of satellite health information) in the satellite health state information storage unit 72 in FIG. ing.

Next, the process proceeds to ST20, and it is determined whether or not the satellite health state data 72a of FIG. 7 indicates that the GPS satellite 15a (15b to 15d) is normal. Specifically, the satellite health information confirmation program 56 (an example of a state determination unit) determines the operation state of the GPS satellites 15a (15b to 15d) based on the satellite health state data 72a.
Here, the satellite health state data 72a indicates that there is some abnormality when the code data is other than 0, and it is understood that the GPS satellite 15a (15b to 15d) cannot be used. . The satellite health state data 72a indicates that the code data is normal when the code data is 0, and the GPS satellite 15a (15b to 15d) is in a normal state.
Accordingly, the GPS wristwatch 10 can determine whether or not the navigation message from the GPS satellite 15a (15b to 15d) is reliable.

If the satellite health status data 72a in FIG. 7 indicates an abnormality in the GPS satellite 15a (15b to 15d) in ST20, the process proceeds to ST21.
In ST21, the reception stop determination program 57 in FIG. 5 temporarily stops reception by the receiving device 40 and the like. Then, the received satellite change program 59 of FIG. 5 stores the changed received satellite synchronization data 74a in the changed received satellite synchronization information storage unit 74 of FIG. 7 so as to change the GPS satellites 15a (15b to 15d) to be received.
Then, returning to ST13, reception of the other GPS satellites 15a (15b to 15d) is started based on the changed reception satellite synchronization data 74a.
From this, when the GPS wristwatch 10 has any abnormality in the GPS satellite 15a (15b to 15d), the GPS wristwatch 10 receives the navigation message from the other GPS satellite 15a (15b to 15d) having no abnormality, High time correction can be performed.

On the other hand, if the satellite health status data 72a indicates that the GPS satellite 15a (15b to 15d) is normal in ST20, the process proceeds to ST22.
In ST22, it is determined whether or not consistency with the internal time data is obtained. Specifically, the threshold deviation determination program 503 determines that the deviation amount between the internal time data 73b of FIG. 7 as the current time information and the first reception time data 73a1 of the reception time data 73a is the consistency verification threshold value of FIG. It is determined whether the consistency verification threshold value data 62a (an example of the threshold deviation amount) stored in the storage unit 62 is obtained. The consistency verification threshold data 62a is, for example, about 0.5 seconds per day.

If the consistency is not obtained in ST22, the process proceeds to ST23.
Here, the internal time data 73b in FIG. 7 is a value that depends on the performance of the RTC 38 that generates the internal time data 73b. The deviation of the internal time data 73b is caused by a frequency deviation of the crystal resonator connected to the control unit 20 serving as a reference clock for the RTC 38 (hereinafter also referred to as a frequency deviation of the RTC 38).
Therefore, when the frequency deviation of the RTC 38 becomes large due to some influence, and the deviation amount between the internal time data 73b of FIG. 7 and the first reception time data 73a1 becomes larger than the consistency verification threshold data 62a of FIG. Determines that consistency has not been achieved, and proceeds to ST23.
In ST23, the time data acquisition program 53 of FIG. 5 acquires the next subframe data, subframe 2 and subframe 3, from the same GPS satellite 15a (15b to 15d) when the Z count data of subframe 1 is acquired. Z count data is acquired. Then, the Z count data of the subframe 2 is stored in the second reception time data 73a2 (an example of the correction time information) of the reception time data 73a of the time data storage unit 73 in FIG. 7, and the third reception time data 73a3 (correction) As an example of time information, the Z count data of subframe 3 is stored. In this case, the GPS wristwatch 10 is also configured such that the above-described time information consistency determination program 501 in FIG. 5 performs a parity check that is a correct / incorrect determination of each Z count data.

Next, the process proceeds to ST24, and Z count data in which consistency is obtained at least twice is adopted for each of the Z count data of subframe 1, subframe 2, and subframe 3. Specifically, the reception time data consistency determination program 505 in FIG. 5 receives the first reception time data 73a1, the second reception time data 73a2, and the third reception, which are the reception time data 73a in the time data storage unit 73 in FIG. Each data of the time data 73a3 is compared.
If the amount of deviation between each data (Z count data) is substantially the same as the amount of deviation between the original sub-frame data, it is determined that consistency is achieved, and the reception time when the consistency is achieved. Data 73a is adopted. Specifically, the subframe data is transmitted in units of 6 seconds, and the Z count data of each subframe data is also shifted by 6 seconds.
Therefore, the reception time data consistency determination program 505 determines whether or not the first reception time data 73a1 and the second reception time data 73a2 are shifted by 6 seconds, and whether the second reception time data 73a2 and the third reception are received. It is determined whether or not the time data 73a3 has a deviation of 6 seconds, and whether or not the first reception time data 73a1 and the third reception time data 73a3 have a deviation of 12 seconds.
Then, the process proceeds to ST25. Therefore, in ST23, the consistency between the reception time data 73a and the internal time data 73b is not determined.

On the other hand, if consistency is obtained in ST22, the process proceeds to ST25. In ST25, the reception stop determination program 57 of FIG. 5 stops the reception of the receiving device 40 and the like, and ends the reception of the navigation message from the GPS satellite 15a (15b to 15d).
Then, the process proceeds to ST26, and the time information correction program 502 in FIG. 5 corrects the time based on the reception time data 73a in the internal time data 73b in FIG.
If the received time data 73a is consistent with the internal time data 73b in ST22, the first received time data 73a1 of the received time data 73a is used. In ST22, the received time data 73a is compared with the internal time data 73b. If consistency is not achieved, the reception time data 73a adopted in ST24 is used.
The time information correction program 502 in FIG. 5 stores the corrected time as clock display time data 73c in FIG.
Then, the clock display time data correction program 504 in FIG. 5 corrects the display time on the dial 13 and the display 14 of the dial 12 of the GPS wristwatch 10 based on the clock display time data 73c in FIG. ing.
The GPS wristwatch 10 is adapted to correct the time by the above operation and the like.

FIG. 12 is a schematic diagram showing the reception period in time series when the receiver 40 of the GPS wristwatch 10 receives a navigation message from the GPS satellite 15a (15b to 15d).
As shown in FIG. 12, at the time of (A) reception instruction, the user operates the external operation unit 5 to input an instruction to receive GPS satellites 15a (15b to 15d). The GPS wristwatch 10 informs the user of the start of receiving the navigation message of the GPS satellite 15a (15b to 15d) by displaying on the display 14 or the like.
However, at this time point (at the time point of word 10 of subframe 2), the set reception start timing (about 2 to 10 seconds before the time of 0 seconds or 30 seconds per minute) has not been reached, so the receiving device 40 etc. do not enter into the navigation message reception operation of the GPS satellite 15a (15b-15d).
The receiving device 40 and the like are in a standby state until reaching the set reception start timing. Then, the receiving device 40 and the like start receiving the navigation message of the GPS satellite 15a (15b to 15d) when the set reception start timing is reached.
Therefore, the receiving device 40 or the like does not perform a receiving operation during this standby state. Thereby, the GPS wristwatch 10 can suppress an increase in power consumption when the time is corrected.

FIG. 12A shows an example of a reception pattern when consistency with the internal time data 73b is obtained in ST22, and FIG. 12B shows consistency with the internal time data 73b in ST22. It is an example of the reception pattern when it cannot be taken.
FIG. 12A shows that the receiving apparatus 40 and the like start receiving operation about 2 seconds (for 3 words) before subframe 1 and receive from TLM word to word 3 of subframe 1. Show.
Here, the receiving device 40 and the like are synchronized with the C / A code of the GPS satellite 15a (15b to 15d) by satellite search. Thereby, the receiving device 40 and the like can synchronize with the start position of the TLM word of the subframe 1 at the start of reception, and the Z count data (TOW) of the HOW word following the TLM word, the satellite health state of the word 3 Information data can be acquired.
As a result, the GPS wristwatch 10 has a shorter reception period (reception time) than when all the words of the subframe 1 are received. Further, the GPS wristwatch 10 can grasp the operation state of the satellite from the satellite health state information data acquired from the word 3 of the subframe 1. Thus, the GPS wristwatch 10 can correct the time accurately with a short reception time.

Also, FIG. 12B shows that the receiving device 40, etc., has received from the TLM word of subframe 1 to word 3, and then received the TLM word and HOW word of subframe 2 and subframe 3. Show. In order to synchronize the reception of the subframe 2 and the subframe 3, the receiving device 40 and the like receive both TLM words including the preamble data.
As shown in FIG. 12 (b), the GPS wristwatch 10 sets the reception period to be temporarily suspended after about 1.8 seconds (3 words) from the start of reception of the TLM word in subframe 1. The amount of power supplied to the device 40 or the like is reduced, and reception is stopped for about 4.2 seconds, which is the remaining 7 words of the subframe 1.

Then, the GPS wristwatch 10 increases the amount of power supplied to the receiving device 40 and the like again as the reception period after the lapse of the temporary suspension period, and acquires the Z count data of the TLM word and HOW word of the subframe 2.
Then, the GPS wristwatch 10 sets the suspension period again after about 1.2 seconds (2 words) from the start of reception of the TLM word in the subframe 2, and reduces the amount of power supplied to the receiving device 40 and the like. Thus, reception is stopped for about 4.8 seconds, which is the remaining 8 words of subframe 2.
Then, the GPS wristwatch 10 increases the amount of power supplied to the receiving device 40 and the like again as the reception period after the suspension period has elapsed, and acquires the Z count data of the TLM word and HOW word of the subframe 3. Then, the GPS wristwatch 10 ends the reception after about 1.2 seconds (2 words) from the start of the reception of the TLM word in the subframe 3.

As described above, the GPS wristwatch 10 effectively receives the subframe data by shortening the substantial reception time, for example, by providing a temporary stop period during which the reception is suspended. From this, the GPS wristwatch 10 can suppress an increase in power consumption when adjusting the time. The temporary stop period can be set as appropriate by the reception stop determination program 57 and the reception start information setting program 58 shown in FIG.
In consideration of errors such as RTC38, the reception start timing of each subframe data is set earlier than the assumed timing, and the reception end timing of each subframe data is set later than the assumed timing. Is preferred.

As described above, the GPS wristwatch 10 generates the reception instruction data 75a for the external operation unit 5 to instruct the reception of the reception device 40 or the like based on the input of the reception instruction from the user or the like, and the reception instruction data 75a. The reception start information setting program 58 instructs the reception device 40 or the like to start reception, and the reception device 40 or the like acquires the Z count data of the subframe 1.
Thereby, the GPS wristwatch 10 can perform time correction (correction of the internal time data 73b) at a timing close to the timing at which the user wants to correct the time.

  In addition, the GPS wristwatch 10 is time-corrected based on the reception time data 73a, which is the reception satellite time data 71a determined to be correct by the time information consistency determination program 501, so that accurate time correction can be performed. it can.

  Furthermore, the GPS wristwatch 10 instructs the reception device 40 and the like to receive so that the reception start information setting program 58 corrects the internal time data 73b at a fixed timing of the internal time data 73b. In the GPS wristwatch 10, the reception start determination program 51 determines the reception start timing based on the reception start data 76a. Therefore, the GPS wristwatch 10 is easy to use because the time is adjusted at a fixed timing, for example, at a timing of 0 seconds or 30 seconds.

The GPS wristwatch 10 is different from the GPS satellite 15a (15b to 15d) currently received by the receiving device 40 or the like by the receiving satellite change program 59 based on the determination result of the satellite health information confirmation program 56. The navigation message from the GPS satellite 15a (15b to 15d) is received.
Thus, the GPS wristwatch 10 can correct the internal time data 73b with the Z count data of the navigation message from the GPS satellite 15a (15b to 15d) having no abnormality. From this, the GPS wristwatch 10 can reliably perform time correction with high accuracy.

  The GPS wristwatch 10 corrects the time based on the second reception time data 73a2 or the third reception time data 73a3 when the first reception time data 73a1 when the internal time data 73b is corrected is not certain. Thus, it is possible to avoid further increasing the amount of time shift of the internal time data 73b.

(Second Embodiment)
Since the GPS wristwatch 10a of the second embodiment has many configurations in common with the first embodiment, the same configurations are denoted by the same reference numerals, description thereof is omitted, and different points are mainly described. To do.
1 to 4 and 6 which are schematic explanatory views of the GPS wristwatch 10a have the same configuration as that of the first embodiment.
15 and 16 are schematic flowcharts showing main operations and the like of the GPS wristwatch 10a. 13 shows various programs in the various program storage unit 150 of the GPS wristwatch 10a, and FIG. 14 shows various data in the second various data storage unit 170.

FIG. 17 is a schematic diagram showing a reception period in time series when the receiving device 40 of the GPS wristwatch 10a of the second embodiment receives a navigation message from the GPS satellite 15a (15b to 15d). is there.
As shown in FIG. 17, in the second embodiment, when there is an instruction for reception immediately from the external operation unit 5, a search for the GPS satellite 15a (15b to 15d) is started and reception is performed. Yes.
Then, Z count data and subframe ID data are acquired from the first received subframe data (see FIG. 10B). As described above, the subframe ID data is information indicating what number of subframe data the subframe data is.

Therefore, the GPS wristwatch 10a knows that the first received subframe data is subframe 3 from the subframe ID data, for example, as shown in FIG. In the GPS wristwatch 10a, the subframe data consists of 10 words, and one word is 0.6 seconds. Therefore, if this subframe ID data is known, the Z count data of the next subframe 1 is obtained. The timing when is transmitted.
Therefore, the GPS wristwatch 10a sets a temporary stop period after about 1.2 seconds (2 words) from the start of reception of the TLM word in subframe 3, and reduces the amount of power supplied to the receiving device 40 and the like. Reception is stopped for about 16.8 seconds, which is the remaining 8 words of subframe 3, subframe 4, and subframe 5 minutes.
Then, the GPS wristwatch 10a increases the power supply amount to the receiving device 40 and the like again as the reception period after the lapse of the temporary suspension period, and the TLM word of the subsequent subframe 1, the Z count data of the HOW word, the word 3 satellite health status information data is acquired.
Then, the GPS wristwatch 10a ends the reception after about 1.8 seconds (3 words) from the start of the reception of the TLM word of the subframe 1 described above.
As a result, the GPS wristwatch 10a can acquire the Z count data twice, so that the time can be corrected more accurately.

Here, along with the schematic flowcharts of FIGS. 15 and 16, the operation of the GPS wristwatch 10a will be described with reference to FIGS.
In the GPS wristwatch 10a of the second embodiment, unlike the first embodiment, after receiving the GPS satellite 15a (15b to 15d) after the step ST10, the GPS satellite is captured. (ST200, ST201).
That is, as shown in FIG. 15, when the external operation unit 5 is operated in ST10, a reception instruction is given, and the reception instruction data 75a as instruction information is stored, the satellite reception start program 508 in FIG. However, reception of the GPS satellites 15a (15b to 15d) is started at the timing when the reception instruction data 75a is stored (an example of an immediate timing).
Then, in ST201, the satellite search program 52 in FIG. 13 outputs synchronization data with the GPS satellite 15a (15b to 15d), starts a search for the GPS satellite 15a (15b to 15d), and the GPS satellite 15a ( 15b-15d). Since steps ST15 to ST18 are the same as those in the first embodiment, description thereof is omitted.

If the Z count data can be acquired in ST18, the process proceeds to ST202.
In ST202, the subframe ID confirmation program 506 in FIG. 13 acquires subframe ID data following the Z count data, and stores it in the subframe ID information storage unit 77 as subframe ID data 77a in FIG. Then, as described above, for example, it can be seen that the subframe data is subframe 3.
In ST18, when the Z count data cannot be acquired, the process returns to ST201. However, the process may proceed to ST202 to acquire subframe ID data.

Then, the process proceeds to ST203. In ST203, the timing setting program 507 (an example of the reception start setting unit) in FIG. 13 sets the reception start timing of the next subframe 1 from the subframe ID data 77a, and the subframe 1 reception start storage unit 716 The subframe 1 reception start data 716a is stored.
That is, if the subframe data is subframe 3, the TLM word reception start timing of the next subframe 1 is 18.0 seconds (30 words worth) from the TLM word reception start timing of subframe 3. ) Is set as the time after.
And reception is suspended until the start timing.

Then, the process proceeds to ST204. In ST204, reception start determination program 511 determines whether internal time data 73b in FIG. 14 has reached subframe 1 reception start data 716a.
If it is determined that the subframe 1 reception start data 716a has been reached, the process proceeds to ST205, where the time data acquisition program 53 and the other satellite information acquisition program 55 in FIG. Information data is acquired.
Then, the process proceeds to ST20. Since the steps from ST20 to ST26 are the same as those in the first embodiment, description thereof will be omitted.
On the other hand, if the internal time data 73b in FIG. 14 has not reached the subframe 1 reception start data 716a, the process waits until the internal time data 73b in FIG. 14 reaches the subframe 1 reception start data 716a.

As described above, the GPS wristwatch 10a of the second embodiment can acquire the Z count data twice, so that it is possible to correct the time more accurately.
The GPS wristwatch 10a can perform time adjustment more effectively in the following cases.
For example, if the elapsed time from the time of the previous successful reception is long and the amount of deviation of the time information of the internal time data 73b is large, the GPS wristwatch 10a misses the reception timing of the subframe 1. There is a possibility.
In such a case, the GPS wristwatch 10a immediately starts the receiving operation in accordance with the immediate receiving instruction from the external operation unit 5, and synchronizes with the navigation message of the GPS satellite 15a (15b to 15d). Data is acquired, Z count data such as subframe 1 is acquired, and time correction is performed.
Such time correction is preferably performed when the RTC 38 that generates the internal time data 73b of the GPS wristwatch 10a has an accuracy of about ± 15 seconds per month, and has not been received for more than one month.

(Third embodiment)
Since the GPS wristwatch 10b according to the third embodiment has many configurations in common with those in the first embodiment, the common configurations are denoted by the same reference numerals, description thereof is omitted, and different points are mainly described. To do.
FIGS. 1 to 4 which are schematic explanatory diagrams of the GPS wristwatch 10b have the same configuration as that of the first embodiment.
FIG. 18 is a schematic flowchart showing main operations and the like of the GPS wristwatch 10b.
The GPS wristwatch 10b receives the subframe 1 when the elapsed time from the time when the previous navigation message was received and the satellite health state information data was acquired to the present time is a predetermined time or more, and the Z count data and the satellite health Get status information data.
When the elapsed time is less than the predetermined time, the GPS wristwatch 10b receives the subframe data and acquires the Z count data regardless of the subframe data number.

Thereby, the GPS wristwatch 10b receives the subframe 1 when the elapsed time from the time when the satellite health state information data was acquired to the current time is equal to or longer than a predetermined time, so that the GPS satellites can be obtained from the satellite health state information data. The operation state of 15a (15b-15d) can be confirmed. As a result, the GPS wristwatch 10b can determine the reliability of the acquired Z count data, and thus can correct the time accurately.
In addition, when the elapsed time is less than the predetermined time, the GPS wristwatch 10b receives the latest subframe data and obtains the Z count data regardless of the subframe data number, so that the reception time is short. Thus, the time can be corrected in a short time. Thereby, the GPS wristwatch 10b can suppress an increase in power consumption when the time is corrected.

Here, along the schematic flowchart of FIG. 18, the operation of the GPS wristwatch 10b and the like will be described focusing on differences from the first embodiment.
First, when the external operation unit 5 is operated in ST10 and a reception instruction is given, the process proceeds to ST300.
Next, in ST300, it is determined whether the stored satellite health status information data is valid. Specifically, the satellite health information confirmation program 56 in FIG. 5 acquires the previous satellite health status information data and stores it in the satellite health status information storage unit 72 as the satellite health status data 72a in FIG. It is determined whether or not the elapsed time has exceeded a predetermined time.
The predetermined time is preferably about 24 hours considering that the time accuracy when the GPS wristwatch 10b is not receiving is about ± 15 seconds per month.
If the stored satellite health status information data is valid in ST300, the process proceeds to ST13 and starts receiving the GPS satellites 15a (15b to 15d). Henceforth, since ST14-ST18 and ST22 are common with 1st Embodiment, description is abbreviate | omitted.
On the other hand, if the stored satellite health status information data is not valid in ST300, the process proceeds to ST11, and thereafter, the same operation as in the first embodiment is performed.

Next, if the acquired Z count data is consistent with the internal time data 73b of FIG. 7 in ST22, the process proceeds to ST25, and thereafter, the same operation as in the first embodiment is performed.
On the other hand, if the acquired Z count data is not consistent with the internal time data 73b of FIG. 7 in ST22, the process proceeds to ST301.
In ST301, two subsequent subframe data of the subframe data including the Z count data acquired in ST18 are received, and each Z count data is acquired.

Then, the process proceeds to ST302. In ST302, it is determined whether or not the consistency of each Z count data acquired in ST18 and ST301 has been obtained twice or more. Since the determination method is the same as ST24 of the first embodiment, the description thereof is omitted.
In ST302, when the consistency of each Z count data is obtained twice or more, the process proceeds to ST25, and thereafter, the same operation as that of the first embodiment is performed.
On the other hand, in ST302, when the consistency of each Z count data cannot be obtained twice or more, the process returns to ST13 and the above-described operation is repeated.

  As described above, the GPS wristwatch 10b according to the third embodiment appropriately receives the received subframe data depending on whether or not the elapsed time from the time when the satellite health state information data was acquired to the current time is equal to or longer than a predetermined time. By selecting, the time can be adjusted accurately and in a short time. In addition, since the GPS wristwatch 10b can correct the time in a short time, the increase in power consumption during the time adjustment can be suppressed.

In each of the above-described embodiments, the GPS satellite is described as an example of the position information satellite. However, the position information satellite is not only a GPS satellite, but also other global navigation satellite systems (GNSS) such as Galileo and GLONASS, A satellite that transmits a satellite signal including time information, such as a stationary satellite such as SBAS or a quasi-zenith satellite, may be used.
Further, in each of the embodiments described above, in ST10, the presence or absence of a reception instruction is determined by the external operation unit 5, but the present invention is not limited to this. In ST10, instead of the external operation unit 5, for example, each GPS wristwatch has a built-in tilt switch, a gyro sensor, etc., and by detecting the tilt level, tilt speed, etc. of each GPS wristwatch, a reception instruction is received. The presence or absence may be determined.

Schematic which shows the wristwatch with GPS of 1st Embodiment. 1 is a schematic sectional view of a GPS wristwatch according to a first embodiment. Schematic which shows the main hardware constitutions inside the wristwatch with GPS of a 1st embodiment. 1 is an overall schematic diagram illustrating a main software configuration and the like of a GPS wristwatch according to a first embodiment. Schematic which shows the data in the various program storage part of FIG. Schematic which shows the data in the 1st various data storage part of FIG. Schematic which shows the data in the 2nd various data storage part of FIG. The schematic flowchart which shows the main operation | movement etc. of the wristwatch with GPS of 1st Embodiment. The schematic flowchart which shows the main operation | movement etc. of the wristwatch with GPS of 1st Embodiment. Schematic explanatory drawing which shows the navigation message of 1st Embodiment. The schematic conceptual diagram for demonstrating the word data of the sub-frame 1 of 1st Embodiment. Schematic which shows the reception period of the navigation message of the GPS wristwatch of 1st Embodiment in time series. Schematic which shows the data in the various program storage part of the wristwatch with GPS of 2nd Embodiment. Schematic which shows the data in the 2nd various data storage part of the wristwatch with GPS of 2nd Embodiment. The schematic flowchart which shows the main operation | movement etc. of the GPS wristwatch of 2nd Embodiment. The schematic flowchart which shows the main operation | movement etc. of the GPS wristwatch of 2nd Embodiment. Schematic which shows the reception period of the navigation message of the GPS wristwatch of 2nd Embodiment in time series. The schematic flowchart which shows the main operation | movement etc. of the GPS wristwatch of 3rd Embodiment.

Explanation of symbols

  5 ... External operation unit 10, 10a, 10b ... GPS wristwatch, 15a to 15d ... GPS satellite, 38 ... RTC, 40 ... receiving device, 45 ... time display device, 50, 150 ... various program storage units, 51, 511 ... reception start determination program, 52 ... satellite search program, 53 ... time data acquisition program, 54 ... operation signal confirmation program, 55 ... other satellite information acquisition program, 56 ... satellite health information confirmation program, 57 ... reception stop determination program, 58 ... reception start information setting program, 59 ... reception satellite change program, 501 ... time information consistency determination program, 502 ... time information correction program, 503 ... threshold deviation determination program, 504 ... clock display time data correction program, 505 ... reception time Data consistency judgment program, 506... Subframe D confirmation program, 507 ... timing setting program, 508 ... satellite reception start program, 60 ... first various data storage unit, 61a ... reception timing data, 62a ... consistency verification threshold data, 70, 170 ... second various data Storage unit, 71a ... Reception satellite time data, 72a ... Satellite health status data, 73 ... Time data storage unit, 73a ... Reception time data, 73a1 ... First reception time data, 73a2 ... Second reception time data, 73a3 ... Third time Reception time data, 73b ... Internal time data, 73c ... Time data for clock display, 74a ... Changed reception satellite synchronization data, 75a ... Reception instruction data, 76a ... Reception start data, 77a ... Subframe ID data, 716a ... Subframe 1 Reception start data.

Claims (9)

A time information generating unit that generates time information and generates time information;
Including satellite time related information, which is time related information of the position information satellite, and satellite health information indicating an operation state of the position information satellite, each including the satellite time related information and at least one of the satellite health information. A plurality of subframe information units included in a receiving unit that receives satellite signals sequentially transmitted from the position information satellite for each subframe information unit;
An external input unit that generates instruction information for instructing reception to the reception unit by an external input;
Based on the instruction information of the external input unit, a reception start setting unit that sets a reception start timing of the reception unit so as to receive the satellite signal immediately or at a fixed timing;
A correction time information storage unit that stores the satellite time related information of the satellite signal received by the reception unit as correction time information,
The time adjustment device in which the generation time information is corrected based on the correction time information, and the reception unit starts reception from the time when the start timing has arrived. The time correction device according to claim 1, wherein the position information satellite is a GPS satellite, and the satellite signal is based on five subframe information units from subframe 1 to subframe 5,
The satellite health information is included in the subframe 1, and the receiving unit receives the satellite time related information and the satellite health information of the subframe 1. The time correction apparatus according to claim 1 or 2, wherein the reception unit includes a determination unit that performs correct / incorrect determination on the received satellite time related information,
The time correction device, wherein the correction time information is the satellite time related information determined to be correct by the determination unit. The time correction device according to claim 3, wherein a current time correction amount that is a time correction amount of the generation time information corrected based on the correction time information is the time when the generation time information was corrected last time. When the threshold deviation amount, which is the time deviation amount corresponding to the elapsed time from the generation time information, is exceeded,
The receiving unit receives the satellite time-related information of a plurality of subsequent subframe information units, and the received satellite time-related information of the subsequent plurality of subframe information units is respectively used as satellite time data. Remembered,
Any one of the at least two satellite time data, wherein the difference between the at least two satellite time data substantially matches the difference between the subframe information units including the at least two satellite time data. Is selected,
The time adjustment device, wherein the generation time information is corrected based on the selected satellite time data. The time correction apparatus according to claim 2, wherein each of the subframe 1 to the subframe 5 includes subframe ID data.
When the reception start timing of the reception unit is immediately, the reception unit starts reception,
The reception start setting unit sets reception start timing of the subsequent subframe 1 based on the first subframe ID data received by the reception unit this time, and receives the subsequent subframe 1 reception. By temporarily stopping the reception of the reception unit until the start timing arrives, and restarting the reception of the reception unit from the time when the reception start timing of the subsequent subframe 1 arrives,
The time correction device, wherein the receiving unit receives the satellite time related information and the satellite health information of the subsequent subframe 1. 6. The time correction device according to claim 1, wherein there are a plurality of the position information satellites, and the receiving unit determines an operation state of the position information satellite based on the satellite health information. Has a judgment part,
The time correction apparatus according to claim 1, wherein the receiving unit receives the satellite signal from the position information satellite different from the position information satellite based on the determination result of the state determination unit. In the time adjustment device according to any one of claims 1 to 6, when the elapsed time from the reception of the satellite health information last time to the current time is a predetermined time or more,
The time correction device, wherein the receiving unit receives the subframe 1 as the subframe information unit including the satellite time related information and the satellite health information. A time information generating unit that generates time information and generates time information;
Including satellite time related information, which is time related information of the position information satellite, and satellite health information indicating an operation state of the position information satellite, each including the satellite time related information and at least one of the satellite health information. A plurality of subframe information units included in a receiving unit that receives satellite signals sequentially transmitted from the position information satellite for each subframe information unit;
An external input unit that generates instruction information for instructing reception to the reception unit by an external input;
Based on the instruction information of the external input unit, a reception start setting unit that sets a reception start timing of the reception unit so as to receive the satellite signal immediately or at a fixed timing;
A correction time information storage unit that stores the satellite time related information of the satellite signal received by the reception unit as correction time information,
The time adjustment device in which the generation time information is corrected based on the correction time information, and reception of the reception unit is started from the time when the start timing has arrived. apparatus. A time information generating unit that generates time information and generates time information;
Including satellite time related information, which is time related information of the position information satellite, and satellite health information indicating an operation state of the position information satellite, each including the satellite time related information and at least one of the satellite health information. A plurality of subframe information units included in a unit, and a receiving unit that receives satellite signals sequentially transmitted from the position information satellite for each subframe information unit, and
An external input step for generating instruction information for instructing reception to the receiving unit by input from the outside,
Based on the instruction information, a reception start setting step for setting a reception start timing of the reception unit so as to receive the satellite signal immediately or at a fixed timing;
Starting reception of the receiving unit from the time when the start timing has arrived;
A correction time information storage step of storing the satellite time related information of the satellite signal received by the reception unit as correction time information;
Correcting the generation time information based on the correction time information;
A time correction method comprising:

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