JP5874591B2 - Transmitting apparatus and transmitting method - Google Patents

Description

  The present invention relates to a transmission technique, and more particularly to a transmission apparatus and a transmission method for transmitting a predetermined signal.

  A printer as a computer peripheral device is an example of a device that executes a series of operations based on operation specifications set by a user. When a printer error occurs due to a user setting input error, the printer is stopped and warning information is displayed on the user's computer display. As a control method for such devices, the detected error history is stored, the error occurrence risk for the setting input is calculated based on the error history and setting information, and a warning corresponding to the error occurrence risk is displayed. (For example, Patent Document 1).

JP 2001-56889 A

  Technical standard conformity certification (hereinafter also referred to as “technical suit”) is to prove that a specific radio equipment (a radio equipment for use in a small radio station) complies with the technical standards of radio wave laws and regulations. It is. This is implemented in accordance with the regulations concerning the technical standard conformity certification of the specified radio equipment of the Ministry of Internal Affairs and Communications. For this reason, the specific radio equipment can be used without technical procedures such as notification in a limited state. When the specific wireless facility is an area broadcast transmission device, the skill level is acquired by setting the output level, channel, and the like to a specific state. When the skill is acquired, a sticker with the skill number is affixed to the transmitter. Then, the transmitter can be used only with the channel, output level, and antenna that have acquired the skill. On the other hand, it is also possible to use the transmission device with an output level other than the output level permitted in the technical suit or with another antenna. In that case, it is necessary to remove the skillful seal, obtain a preliminary license at that output level, perform a registration check, and obtain a license.

  In order to protect the channel, output, or radio wave quality associated with it, the transmission of radio waves should be stopped when an abnormal state of the device is detected. In the case of an area broadcast transmitter, the following operation is performed when an abnormal state is detected. In the first operation, transmission of radio waves is stopped when a temperature abnormality is detected, particularly when it is detected that the temperature of the RF system is outside the temperature to be guaranteed. In the second operation, the transmission of radio waves is stopped when the accuracy of time ± 500 ms, which is defined by the standards of the Radio Industries Association (ARIB), is exceeded. In the third operation, when there are a master transmission device and a slave transmission device each corresponding to an SFN (Single Frequency Network) function, and a signal or clock from the master transmission device is interrupted in the transmission device on the slave side, synchronization is performed. The transmission of the radio wave is stopped because it is determined that is no longer possible.

  When radio waves are stopped in such a state, how to resume transmission of radio waves becomes an issue. Generally, once the radio wave is stopped, it is necessary for an administrator or an operator to manually restart the transmission device. Therefore, it takes time to resume transmission of radio waves. In addition, when the technical suit is acquired in the area broadcast, the radio operator is not required to transmit the radio wave. On the other hand, if the technical skill is not acquired, it is necessary for a wireless worker to make settings on the spot in order to transmit radio waves, which is troublesome.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a technique for starting resumption of transmission when transmission is stopped.

  In order to solve the above problems, a transmission device according to an aspect of the present invention includes a transmission unit that transmits a signal, a control unit that controls the operation of the transmission unit, and a setting unit that sets the content of control performed in the control unit With. The control unit stops the operation of the transmission unit when the transmission unit is different from the normal state, and the setting unit (1) when the transmission device has acquired the technical standard conformity certification, the transmission unit is in the normal state. It can be set to automatically resume the operation of the transmission unit when it returns to (2) When the transmission unit has not acquired the technical standard conformity certification and the transmission unit has returned to the normal state In addition, it is not possible to set by the first user to automatically resume the operation of the transmission unit, and when the transmission unit returns to the normal state, the operation of the transmission unit is automatically resumed. It can be set by a second user having a higher degree of freedom of setting than one user.

  Another aspect of the present invention is a transmission method. This method includes the steps of setting the content of control, the step of controlling the operation according to the setting, and the step of transmitting a signal according to the control in the step of controlling. The controlling step stops the operation of the transmitting step when the transmitting step is different from the normal state, and the setting step is (1) when the technical standard conformity certificate is acquired, the transmitting step is normal When returning to the state, it can be set to automatically resume the operation of the transmitting step. (2) When the technical standard conformity certification has not been acquired, when the transmitting step returns to the normal state The operation of the transmitting step cannot be automatically resumed by the first user, and when the transmitting step returns to the normal state, the transmitting step is automatically resumed. It can be set by a second user having a higher degree of freedom of setting than the first user.

  It should be noted that any combination of the above-described constituent elements and a conversion of the expression of the present invention between a method, an apparatus, a system, a recording medium, a computer program, etc. are also effective as an aspect of the present invention.

  According to the present invention, when transmission is stopped, transmission can be resumed.

It is a figure which shows the structure of the transmitter which concerns on Example 1 of this invention. It is a figure which shows the data structure of the menu at the time of logging in with the administrator authority to the transmission apparatus of FIG. It is a figure which shows the data structure of the menu at the time of logging in with the setter authority to the transmission apparatus of FIG. It is a figure which shows the skill suitable setting menu displayed by the display part of FIG. It is a figure which shows the electromagnetic wave reset setting menu displayed by the display part of FIG. It is a flowchart which shows the setting procedure by the transmitter of FIG. It is a flowchart which shows the restart procedure by the transmitter of FIG. It is a figure which shows the structure of the transmitter which concerns on Example 2 of this invention. It is a figure which shows the data structure of the table memorize | stored in the setting part of FIG.

Example 1
Before describing the present invention specifically, an outline will be given first. The first embodiment of the present invention relates to a transmission device that can transmit a signal by acquiring a skill, such as a transmission device for area broadcasting. In such a transmission apparatus, technical suitability is generally obtained when shipped from a factory, and a seal (hereinafter referred to as “technical suit seal”) for proving it is attached. The operator can use the transmission device as it is. However, depending on the setting environment of the transmission apparatus, it is necessary to change the appropriate and permitted antenna, output level, and frequency. In this case, the manager (hereinafter referred to as “setting person”) removes the skillful seal and then changes the combination that is technically permitted and allows the transmission apparatus to be used. When an abnormality occurs in such a transmission apparatus, transmission from the transmission apparatus is stopped as described above. In such a situation, the present embodiment executes the following processing in order to restart transmission easily and quickly. It should be noted that here, a user who is a user of the transmitting apparatus and is a user other than the setter and whose settable parameters are limited by the radio operator, that is, a user who has a lower setting degree of freedom is referred to as “operator”. That's it.

  The setter and the operator log in to the transmission device. At that time, the password is different between the setter and the operator. When logging in as a setter, a screen for selecting whether the transmission device is suitable for the skill or not is displayed. The setter sets whether or not the skill is suitable while viewing this screen. It is also possible to set automatic resumption of transmission regardless of whether the skill suits or not. On the other hand, when logging in as an operator, it is not possible to set whether or not the skill suits. In addition, when the skill suits, the automatic resumption of transmission can be set as in the case of the setter. If it does not fit technically, automatic resumption of transmission cannot be set. That is, a user interface is provided for designating whether or not to automatically return after an abnormality has occurred and a state in which transmission of radio waves has to be stopped has occurred.

  FIG. 1 shows a configuration of a transmission apparatus 100 according to Embodiment 1 of the present invention. The transmission device 100 includes a transmission unit 10, a setting unit 12, an input unit 14, a display unit 16, an external clock input unit 18, an external clock monitoring unit 20, a temperature monitoring unit 22, and a control unit 24.

  The transmission unit 10 transmits a signal from the antenna. Here, the transmission apparatus 100 corresponds to area broadcasting. Area broadcasting is a service that transmits content data limitedly to a narrow area with transmission power smaller than the transmission power of terrestrial digital broadcasting. In area broadcasting, since the broadcasting area is much narrower than general terrestrial digital broadcasting, it is expected to be operated in various fields and various places. The terrestrial digital broadcast is installed by a broadcaster, and the area broadcast is installed by the above-mentioned operator or setter. The transmission unit 10 generates an OFDM (Orthogonal Frequency Division Multiplexing) modulated wave by executing an IFFT (Inverse Fast Fourier Transform) process, similarly to the terrestrial digital broadcasting. Control of the transmission unit 10 is performed by the control unit 24.

  The temperature monitoring unit 22 monitors the temperature of the transmission unit 10. The temperature monitoring unit 22 outputs the measured temperature information to the control unit 24. The external clock input unit 18 receives an external clock when the transmission unit 10 is set to the external clock synchronization mode by the control unit 24. The external clock input unit 18 converts the frequency using, for example, a PLL (Phase Locked Loop). The external clock input unit 18 outputs the converted frequency clock to the transmission unit 10. The transmission unit 10 receives a clock from the external clock input unit 18 and transmits a signal synchronized with the clock from the antenna.

  The external clock monitoring unit 20 monitors whether an external clock is normally input to the external clock input unit 18. When an external clock is not input to the external clock input unit 18, the external clock monitoring unit 20 detects an abnormality and outputs an abnormality signal to the control unit 24. This is a case where the external clock is stopped, and corresponds to a case where the transmission unit 10 cannot synchronize with the clock from the external clock input unit 18.

  The control unit 24 controls the operation of the transmission unit 10. The control unit 24 receives temperature information from the temperature monitoring unit 22. When the temperature becomes higher than a threshold value, for example, 80 ° C., the control unit 24 detects that the transmission unit 10 is abnormal. This corresponds to a case where the transmission unit 10 is different from the normal state. At that time, the control unit 24 causes the transmission unit 10 to stop signal transmission. Further, when the control unit 24 receives an abnormal signal from the external clock monitoring unit 20, the control unit 24 recognizes that the transmission unit 10 is abnormal. This corresponds to the fact that the transmission unit 10 is different from the normal state. Even in this case, the control unit 24 causes the transmission unit 10 to stop signal transmission. That is, the control unit 24 stops the operation of the transmission unit 10 when the temperature of the transmission unit 10 is different from the normal state due to the temperature rise or the supply of the external clock is stopped.

  The setting unit 12 sets the content of control performed in the control unit 24. Although various settings may be used, it is assumed here that the operation of the stopped transmission unit 10 is automatically restarted. Other settings are, for example, transmission schedule settings. The setting unit 12 receives input of settings from the operator and the setter via the input unit 14, and displays a setting screen on the display unit 16 in order to facilitate such input. Such a setting screen corresponds to a user interface. The setting screen will be described later. The input unit 14 includes buttons, a mouse, and the like, and receives input from users such as an operator and a setter. The input includes, for example, setting of an ID, a password, and a transmission parameter. The input is not limited to these. The input unit 14 outputs the accepted input to the setting unit 12.

  The setting unit 12 receives an ID and a password from the input unit 14 in an initial stage. The setting unit 12 previously determines a combination of an ID and a password for an operator (hereinafter referred to as “first combination”) and a combination of an ID and a password for the setter (hereinafter referred to as “second combination”). Remember. Here, as described above, the ID and password for the setter are known only to the radio operator. If the received ID and password correspond to the first combination, the setting unit 12 permits login with the operator authority, and if the received ID and password correspond to the second combination, the setting unit 12 permits the login with the setter authority.

  Note that when logging on to the user interface for the first time, the setting unit 12 selects the right to log on from the options, and changes the authentication method using a password or the like according to the right. This authentication method may be another method such as adopting another authentication method to enter the setter authority after the first logon with administrator authority, but which authority is currently used on the user interface? It only has to be decided. As described above, at least two stages are defined for the authority for operating the user interface. The lowest authority is the authority with the lower operator authority, and the authority higher than the operator authority is the setter authority.

  The setting unit 12 has different contents of the screen to be displayed on the display unit 16 and a directory structure of the screen depending on whether the authority is the operator or the setter. FIG. 2 shows the data structure of the menu when logging in to the transmitting apparatus 100 with the administrator authority. A transmission schedule setting menu, a radio wave return setting menu, and the like are arranged under the top menu. FIG. 3 shows the data structure of the menu when logging in to the transmission apparatus 100 with the authority of the setter. Below the top menu, a transmission schedule menu, a radio wave return setting menu, a skill suitability setting menu, and the like are arranged. That is, in the structure of the setter authority, compared with the structure of the operator authority, a skill appropriate setting menu is added. The menu to be added may be other than these.

  Here, a skill appropriate setting menu for setting authority is described. The setting unit 12 causes the display unit 16 to display a skill suitability setting menu. As described above, whether or not the skill appropriate setting menu can be displayed is determined by the login authority. In other words, with the operator authority, the skill appropriate setting menu cannot be displayed, and with the operator authority, the skill appropriate setting menu can be displayed. FIG. 4 shows the skill appropriateness setting menu displayed by the display unit 16. As shown in the figure, a check box is included in this menu. If the check box is checked, the setting unit 12 has performed the skill-adaptive setting. If the check box has not been checked, the setting unit 12 has not performed the skill-matching setting. The setting of the check box is changed by clicking the check box with the mouse of the input unit 14 or the like.

  Next, the radio wave recovery setting menu will be described. The radio wave recovery setting menu is a screen for setting whether to automatically resume the operation of the stopped transmission unit 10. The display of the menu varies depending on whether or not the skill is acquired and the authority of login. When the transmitting apparatus 100 has acquired the skill, the display unit 16 displays the radio wave return setting menu regardless of the setting authority or the operator authority. Therefore, when the transmission apparatus 100 has acquired the skill, the setting unit 12 transmits the transmission unit 10 when the transmission unit 10 returns to the normal state regardless of the setting authority or the operator authority. It is possible to set to automatically resume the operation. Here, when the transmission unit 10 returns to the normal state, the state returns from the state in which the external clock is not input to the external clock input unit 18 to the state in which the external clock is input to the external clock input unit 18. It corresponds to the case. Further, when the transmission unit 10 returns to the normal state, it corresponds to a case where the control unit 24 returns from a state where the temperature is higher than the threshold value to a state where the temperature is equal to or lower than the threshold value. At that time, when the resumption is set in the setting unit 12, the control unit 24 causes the transmission unit 10 to resume transmission.

  When the transmission apparatus 100 has not acquired the technical suit, the setting unit 12 automatically resumes the operation of the transmission unit 10 when the transmission unit 10 returns to the normal state if the authority is the operator. Cannot be set. Therefore, in this case, the display unit 16 does not display the radio wave return setting menu. When the transmission apparatus 100 has not acquired technical suitability, the setting unit 12 can automatically resume the operation of the transmission unit 10 when the transmission unit 10 returns to the normal state if the authority is an administrator. Can be set. In other words, if it is an administrator authority, the same processing as in the case of acquiring technical aptitude is performed.

  FIG. 5 shows a radio wave return setting menu displayed by the display unit 16. As shown, two check boxes are shown. The upper check box indicates “return from temperature abnormality detection”. This is because when the temperature measured by the temperature monitoring unit 22 drops to a certain level from the state where the temperature measured by the temperature monitoring unit 22 is abnormal, the transmitter 10 returns to the abnormal state. Sets whether to resume transmission. For example, this corresponds to a case where the abnormal temperature is 80 ° C. and is lowered to 70 ° C. If checked, recovery will be done automatically. If the check is not entered, transmission is not resumed even if the temperature is sufficiently lowered by the temperature monitoring unit 22 after once detecting an abnormal state. A person or the like resumes transmission manually by another means.

  The lower check box indicates "Return from clock input error detection". This is to set whether to recover from the clock input abnormality detection. As described above, when the external clock input unit 18 does not normally receive an external clock, and the external clock input unit 18 becomes unable to synchronize with an external clock, the external clock monitoring unit 20 notifies the control unit 24. An abnormal signal is sent. In response to this, the control unit 24 controls the transmission unit 10 to stop wireless transmission through the antenna. Thereafter, when the external clock is restored, the external clock input unit 18 can stably receive and synchronize with the external clock when the external clock monitoring unit 20 controls the control unit. The output of the abnormal signal to 24 is stopped. If this check box is checked when this abnormal signal is not output, the control unit 24 automatically controls the transmission unit 10 to resume wireless transmission through the antenna. On the other hand, if the check is not entered, the control unit 24 does nothing, and a person or the like restarts the output manually by another means.

  This configuration can be realized in terms of hardware by a CPU, memory, or other LSI of any computer, and in terms of software, it can be realized by a program loaded in the memory, but here it is realized by their cooperation. Draw functional blocks. Accordingly, those skilled in the art will understand that these functional blocks can be realized in various forms by hardware only, software only, or a combination thereof.

  The operation of the transmission apparatus 100 configured as above will be described. FIG. 6 is a flowchart illustrating a setting procedure performed by the transmission device 100. If the technical suit is acquired (Y in S10), the qualification of the radio operator is not particularly necessary for the automatic return, and therefore the setting unit 12 can set the automatic return (S12). If technical skill is not acquired (N in S10), and if it is an administrator authority (Y in S14), it is assumed that the radio operator has the administrator authority. Since the user has the authority to start, the setting unit 12 can set automatic return (S16). If it is not the administrator authority (N of S14), step 16 is skipped.

  FIG. 7 is a flowchart showing a resumption procedure by the transmission apparatus 100. If it is different from the normal state (S40), the control unit 24 stops the operation of the transmission unit 10 (S42). If the normal state is not restored (N in S44), the process returns to step 42. If it returns to a normal state (Y of S44), the control part 24 will restart operation | movement of the transmission part 10 (S46).

  According to the embodiment of the present invention, when the skill is acquired, the transmission is automatically resumed when returning to the normal state, so that the non-transmission period can be shortened. In addition, when the skill is acquired, the transmission is automatically resumed when the normal state is restored, so that the labor of the administrator or the operator can be saved. Further, when the technical suit has not been acquired, it is impossible for the operator to set the transmission to be automatically resumed when returning to the normal state, so that unauthorized transmission can be avoided. Also, if the technical aptitude has not been acquired, it can be set by the administrator, i.e. the radio operator, to automatically resume transmission when returning to the normal state. The non-transmission period can be shortened with the meaning of resuming transmission.

(Example 2)
Next, a second embodiment of the present invention will be described. As in the first embodiment, the second embodiment relates to a transmission apparatus that can perform transmission stop and transmission restart. In the transmission apparatus according to the first embodiment, transmission stop and transmission restart are automatically executed according to the temperature and the external clock. The second embodiment relates to a transmission apparatus that performs transmission stop and transmission restart according to time.

  FIG. 8 shows a configuration of the transmission apparatus 100 according to the second embodiment of the present invention. The transmission device 100 includes a transmission unit 10, a setting unit 12, an input unit 14, a display unit 16, a GPS input unit 30, a terrestrial digital broadcast input unit 32, an Internet input unit 34, and a radio clock input unit 36. The control unit 24 includes a clock unit 38.

  The clock unit 38 measures time. In the area broadcast, since the time included in the broadcast allows only an error of ± 500 ms with respect to the accurate time, the clock unit 38 obtains an accurate reference time and adjusts the internal time. Therefore, the clock unit 38 has a function of adjusting the time acquired from any of the radio wave clock input unit 36 from the GPS input unit 30. The clock unit 38 receives a manual time setting from an administrator or an operator via the input unit 14 and the setting unit 12. Therefore, the clock unit 38 also has a function of adjusting to the time input manually.

  The GPS input unit 30 acquires time from a GPS (Global Positioning System). The GPS input unit 30 receives a GPS signal and extracts time from the GPS signal. The GPS input unit 30 outputs the time to the control unit 24. The terrestrial digital broadcast input unit 32 acquires time from the terrestrial digital broadcast. Digital terrestrial broadcasting is also operated with an error of ± 500 ms, similar to area broadcasting. The terrestrial digital broadcast input unit 32 receives the terrestrial digital broadcast and extracts a TOT signal from the terrestrial digital broadcast. The terrestrial digital broadcast input unit 32 outputs the TOT signal to the control unit 24 as time.

  The Internet input unit 34 connects to the Internet and acquires time from an NTP (Network Time Protocol) server on the Internet. The internet input unit 34 outputs the time to the control unit 24. The radio clock input unit 36 acquires radio waves from the radio clock. The radio clock input unit 36 extracts time from radio waves. The radio clock input unit 36 outputs the time to the control unit 24.

  The clock unit 38 sets the time to the reference time information input from any of the GPS input unit 30, the digital terrestrial broadcast input unit 32, the Internet input unit 34, and the radio clock input unit 36. Since a known technique may be used for adjusting the time, description thereof is omitted here. The clock unit 38 outputs the adjusted time (hereinafter referred to as “first time”) to the transmission unit 10. As described above, the clock unit 38 may receive a manually input time. The clock unit 38 outputs a time (hereinafter referred to as “second time”) that matches the received time to the transmission unit 10. The transmission unit 10 receives the first time or the second time.

  However, when the time information is not input from the GPS input unit 30, the terrestrial digital broadcast input unit 32, the Internet input unit 34, the radio clock input unit 36 to the clock unit 38, or when the clock unit 38 is not manually set. The clock unit 38 is self-propelled. Therefore, the time is shifted depending on the accuracy of the crystal oscillator that drives the clock unit 38. For example, when a crystal or crystal oscillator with 0.1 ppm accuracy is used, it is 1 / 10,000,000, and there is a possibility that 0.00864 seconds may be deviated from 1 day = 86400 seconds. If the time is shifted by 0.00864 seconds per day, it takes 57.8 days if the first time is completely matched until it exceeds ± 500 ms defined in the area broadcasting. Considering this, for example, the time may be corrected once in 57 days.

  In order to correct once every 57 days, the algorithm for performing the correction is operated every day, and when approaching the 57th day, for example, GPS, TOT, and radio clock signals for correction for 27 days could not be acquired. The control unit 24 causes the display unit 16 to display “If the correction signal is not obtained within 30 days, the radio wave will stop.” This corresponds to a warning display. Even if it is displayed immediately before the radio wave is stopped, it is not possible to cope with it and it is troublesome to display it frequently, so a warning is output if it is within a specific time (in days) depending on the acquisition interval, method, and crystal accuracy .

  The control unit 24 detects whether or not it is in a normal state with respect to the first time or the second time. Detection for the first time is performed as follows. When there is input of time information from the GPS input unit 30, the terrestrial digital broadcast input unit 32, the Internet input unit 34, and the radio clock input unit 36 to the clock unit 38, the control unit 24 detects that it is in a normal state. On the other hand, when there is no time information input from the GPS input unit 30, the terrestrial digital broadcast input unit 32, the Internet input unit 34, and the radio clock input unit 36 to the clock unit 38, the control unit 24 detects that it is not in a normal state. It should be noted that the control unit 24 may detect that it is not in a normal state within a period from the correction of the time until it exceeds ± 500 ms defined by area broadcasting, for example, within the above-mentioned 57 days. When the period is longer than the period, the control unit 24 may detect that it is not in the normal state. However, in the case of manual setting, since the accuracy of setting is affected by human reaction time, for example, if the setting is shifted by ± 325 ms, the remaining setting is 175 ms, so it is necessary to set within 20 days.

  Detection for the second time is performed as follows. If it is within the period from the correction of the time manually until it exceeds ± 500 ms defined by area broadcasting, for example, within the above-mentioned 57 days, the control unit 24 detects that it is not in the normal state. On the other hand, when it becomes longer than a period, the control part 24 will detect that it is not a normal state. When not in the normal state, as in the first embodiment, the control unit 24 causes the transmission unit 10 to stop transmission.

  When the transmission is stopped, the control unit 24 causes the transmission unit 10 to resume transmission according to the setting, as in the first embodiment. Here, when the time is corrected based on inputs from GPS, TOT, NTP server, and radio clock, even if these inputs are temporarily interrupted, if they can be acquired again, they will automatically resume from that point Is possible. On the other hand, when the time is set manually (manual), since the time lag increases unilaterally thereafter, automatic recovery cannot be performed. In other words, there are functions that can and cannot be automatically restored.

  In order to cope with this, when the transmission unit 10 receives the first time, the setting unit 12 automatically restarts the operation of the transmission unit 10 when the transmission unit 10 returns to the normal state. It can be set. On the other hand, the setting unit 12 cannot be set to automatically resume the operation of the transmission unit 10 when the transmission unit 10 accepts the second time.

  FIG. 9 shows the data structure of the table stored in the setting unit 12. In the top row, time correction means are listed. The second line indicates whether automatic return is possible. As described above, manual setting is not possible, and others are allowed. The correction in the third line is set for the control unit 24 by the input unit 14 and indicates which correction means is effective. Only correction means that are actually used are set. The fourth line shows the date when the correction means set to “Yes” in the third line is corrected by using that means.

  The fifth line shows the maximum correction interval of each correction means. The value in this line is a fixed value. Since GPS and the like are very accurate, the error in the time is within the specified range of ± 500 ms without correction for 57 days, for example, as described above after correction. On the other hand, since terrestrial digital broadcasting is expected to shift the original time information in units of 1 second, it is less accurate than GPS. As a result, even if it is corrected, the time may be deviated, so the period until ± 500 ms shift becomes shorter than 57 days. Similar to terrestrial digital broadcasting, the NTP server also has a shorter period because errors can increase when the line is congested. Further, in the case of manual setting, there is an error in the response time of human setting, so the accuracy is low compared to GPS. When the accuracy of the clock unit 38 is 0.1 ppm, it is 57 days if it is completely matched. On the other hand, when there is a possibility of deviation by 100 ms, 57.8 [days] × (1-100 / 500) = 46.24 [day], and when there is a possibility of deviation by Nms, 57.8 [days] ] × (1-N / 500) [day].

  The sixth line shows the number of days remaining until the correction deadline when today's date is January 31st. For example, in the case of GPS, since the final correction is made on January 12, January 31 to January 12 = 19 days ago. Since the maximum interval is 57 days, the remaining number of days is 57-19 days = 38 days. This line is also calculated in the third line only for the correction means used. The largest of the remaining days is the remaining days until correction when the transmission apparatus 100 is viewed as a whole. Even if the remaining number of days becomes a negative number as in the manual correction means of FIG. 9, that is, even if the correction means alone may already exceed the standard ± 500 ms, the other means If is a large number of remaining days, it becomes effective. The control unit 24 calculates these every day.

  When the time is corrected, the control unit 24 updates the date of the last correction on the fourth line for the used correction means. When the maximum number of days in the remaining days column falls below a certain numerical value (for example, 10 days), the control unit 24 informs the display unit 16 that the radio wave will be stopped unless GPS time correction is performed within 38 days. A warning is issued by displaying "." Here, the maximum number of remaining days in the sixth line of FIG. 9 is displayed at the 38th day, and the corresponding correction means is displayed at the GPS position.

  According to the embodiment of the present invention, when the time according to the reference time information is accepted, it is possible to set the transmission to be automatically restarted when returning to the normal state. If it is available, transmission can be resumed immediately. In addition, when accepting the time according to the manual setting, it is impossible to automatically restart the transmission, and thus it is possible to avoid using the time that has been shifted.

  In the above, this invention was demonstrated based on the Example. This embodiment is an exemplification, and it will be understood by those skilled in the art that various modifications can be made to the combination of each component and each processing process, and such modifications are also within the scope of the present invention. . For example, it is conceivable that only one of a plurality of corrections is validated or a plurality of corrections are given priority.

  In the embodiment of the present invention, the transmission device 100 includes an input unit 14 and a display unit 16. However, the present invention is not limited thereto. For example, the input unit 14 and the display unit 16 may be provided in a PC without being provided in the transmission device 100, and the transmission device 100 and the PC may be connected via a network. According to this modification, the degree of freedom of configuration can be improved.

  In the first embodiment of the present invention, the control unit 24 stops or restarts the transmission of the transmission unit 10 based on the temperature and the clock. However, the present invention is not limited to this. For example, the control unit 24 may stop or restart the transmission of the transmission unit 10 based on only the temperature or only the clock. According to this modification, the configuration of the transmission device 100 can be simplified.

  In the second embodiment of the present invention, GPS or the like is used as a reference time. However, the present invention is not limited to this. For example, the time may be used as a reference time from another device. According to this modification, the degree of freedom of the device configuration can be improved.

  The first embodiment and the second embodiment may be combined. According to this modification, it is possible to obtain an effect obtained by combining the first embodiment and the second embodiment.

  DESCRIPTION OF SYMBOLS 10 Transmission part, 12 Setting part, 14 Input part, 16 Display part, 18 External clock input part, 20 External clock monitoring part, 22 Temperature monitoring part, 24 Control part, 100 Transmission apparatus.

Claims (3)

A transmitter for transmitting a signal;
A control unit for controlling the operation of the transmission unit;
A setting unit for setting the content of control performed in the control unit,
The control unit stops the operation of the transmission unit when the transmission unit is different from a normal state,
The setting unit can be configured to (1) automatically resume the operation of the transmission unit when the transmission unit returns to a normal state when the transmission device has acquired a technical standard conformity certificate. (2) If the transmitter has not acquired the technical standard conformity certification, the first user can automatically resume the operation of the transmitter when the transmitter returns to the normal state. By the second user who has a higher degree of freedom in setting than the first user, that the operation of the transmitting unit is automatically restarted when the transmitting unit returns to the normal state. A transmission device characterized by being configurable. The transmission unit accepts a first time according to reference time information acquired from the outside or a second time according to manual setting,
The control unit detects whether the transmission unit is in a normal state with respect to the first time or the second time,
The setting unit can be set to automatically resume the operation of the transmission unit when the transmission unit is receiving the first time and the transmission unit returns to a normal state. The transmission device according to claim 1, wherein when the unit accepts the second time, it is impossible to set to automatically resume the operation of the transmission unit. Setting the content of the control;
Controlling the operation according to the settings;
Transmitting a signal according to the control in the controlling step,
The controlling step stops the operation of the transmitting step when the transmitting step is different from a normal state;
The setting step can be set to (1) automatically resuming the operation of the transmitting step when the transmitting step returns to a normal state when the technical standard conformity certification is acquired. Yes, (2) If the technical standard conformity certificate has not been acquired, it is not set by the first user to automatically resume the operation of the transmitting step when the transmitting step returns to the normal state. It is possible, and when the transmitting step returns to the normal state, the second user having a higher degree of freedom in setting than the first user is set to automatically resume the operation of the transmitting step. A transmission method characterized in that it is possible.

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