JP2007295334A - Ch-setting automatic change method for agile ofdm-sp and agile ofdm-sp with ch-setting automatic change function - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve the problem that a conventional CH-setting change requires time and effort, and when an OFDM is located at the top of a mountain or in a remote place, the operation in situ, consequently, is troublesome and very expensive. <P>SOLUTION: Channel (CH) data before repacking are stored in an OFDM-SP unit of an agile OFDM-SP. After that, the presence of an input signal is detected for each CH while receiving input signals of stored multiple CHs by the OFDM-SP unit. When the input signal of any one of the CHs is not detected, the received CH data are compared with the previously-stored CH data. Subsequently, when new CH data are detected without detecting any one of the CH data in the CH data before repacking, it is determined that the CHs are repacked, and then, the setting of input CHs of the OFDM-SP unit is automatically changed to the CH data after repacking. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an agile OFDM-SP automatic repacking method and an agile orthogonal frequency division multiplexing signal converter (OFDM-SP) with an automatic repacking function used in the method. When the frequency arrangement change (channel arrangement change: repacking) that is performed when the television broadcast is switched from the current terrestrial analog broadcast to the terrestrial digital broadcast, the channel (CH) setting of the agile OFDM-SP is automatically set It is intended to be changed.

  Currently, terrestrial digital broadcasting has started in some parts of Japan, and terrestrial analog broadcasting will end in 2011 and will be switched to terrestrial digital broadcasting. In this case, the frequency arrangement of the current digital terrestrial broadcasting is changed again. This change in frequency arrangement is called repacking. OFDM (Orthogonal Frequency Division Multiplexing) is adopted as a modulation method for terrestrial digital broadcasting. Agile CATV equipment, especially OFDM-SP, has to change the input / output frequency setting according to the frequency change by the repacking, and in the case of fixed type, the equipment needs to be replaced.

  As one of the methods to change the input / output setting frequency setting of Agile type OFDM-SP, various information in the network information table (NIT: Network Information Table) is read and changed to the frequency after repacking based on the information. There is a way to do it. This method is time consuming and laborious to change. In addition, when OFDM-SP is installed on a mountain or in a remote area, it is necessary to go to the installation site one by one to change the frequency or replace the equipment, which is laborious and expensive. Become. Incidentally, the NIT transmits information for associating transmission channel information such as frequency and organization channels, and describes all organization channel ID numbers included in one distribution system.

  An object of the present invention is to provide an agile OFDM-SP having a function capable of automatically changing a set CH to a CH after repacking when the frequency is changed by repacking.

The agile OFDM-SP CH setting automatic changing method of the present invention comprises the following configurations 1 to 4 as described in claim 1.
1. Store the CH data before repacking in Agile OFDM-SP equipped with two or more OFDM-SP units,
2. After the storage, the input signal is received by the OFDM-SP unit and the presence of the input signal is detected for each CH,
3. If no input signal of any CH is detected by the detection, the detected CH data and the previously stored CH data are stored without storing the detected CH data in the OFDM-SP unit. In the OFDM-SP unit,
4). As a result of the comparison, if any CH data in the previously stored CH data is not present and new CH data is detected, it is determined that the CH has been repacked, and the input / output CH is determined in the OFDM-SP unit. Was automatically changed to CH data after repacking.

The agile OFDM-SP CH setting automatic change method of the present invention comprises the following configurations 1 to 7 as described in claim 2.
1. The multi-channel input signal before repacking is stored in the control unit of the agile OFDM-SP including two or more OFDM-SP units and a control unit,
2. After storing, the input signal is received by the OFDM-SP unit and the presence or absence of the input signal is detected for each CH,
3. When the input signal of any CH is not detected by the detection, an abnormality notification signal is transmitted from the detected OFDM-SP unit to the control unit,
4). The control unit that has received the error notification signal detects the CH data of the input signal received at that time for each CH,
5). Compare the detected CH data in the control unit with or without storing the detected CH data in the control unit,
6). As a result of the comparison, when any CH data in the previously stored CH data is not detected and new CH data is detected, the control unit determines that the CH of the input signal has been repacked and performs OFDM from the control unit. -Send a control signal to the SP unit to change the CH data setting to the CH data after repacking,
7). The OFDM-SP unit automatically changes the CH data setting to the repacked CH data based on the control signal.

  The method for automatically changing the CH setting of the agile type OFDM-SP according to the present invention is the method for automatically changing the CH setting of the agile type OFDM-SP according to claim 1 or 2, wherein: Alternatively, storage of CH data before repacking in the control unit is performed automatically by detecting the input signal by the OFDM-SP unit, or stored without detection.

The agile OFDM-SP of the present invention has the following configurations 1 and 2 as described in claim 4.
1. It has an OFDM-SP unit with the number of input channels,
2. Each OFDM-SP unit uses a frequency conversion function that converts the input signal to the IF frequency, an input signal detection function that splits a part of the input signal and detects the presence or absence of each channel, and an input signal detection function. A comparison function for storing the CH data stored in the OFDM-SP unit with or without storing it in the OFDM-SP unit, and any CH data in the CH data before repacking is detected by the comparison. When new CH data is detected, the comparison / determination function that determines that the CH has been repacked, and the setting of the OFDM-SP unit's CH data is automatically converted to the repacked CH data based on this determination. Equipped with a setting change function to change.

The agile OFDM-SP of the present invention has the following configurations 1 to 7 as described in claim 5.
1. An OFDM-SP unit with the number of input channels and a control unit that receives the multi-channel input signal and controls the OFDM-SP unit,
2. Each OFDM-SP unit has a frequency conversion function that converts the input signal to the IF frequency, an input signal detection function that detects a part of the input signal and detects the presence or absence of each channel, and communication that can communicate with the control unit. And a setting change function to change the CH data setting of the OFDM-SP unit to CH data after repacking,
4). The communication unit transmits an abnormal signal to the communication unit of the control unit when an input signal of some CH is not detected by the input signal detection function,
5). The control unit stores the CH data before repacking, the CH data storage function, the input signal detection function that detects the input signal for each CH when the abnormal signal is received, the detected CH data and the previously stored CH data Comparison and judgment function for judging that CH is repacked when there is no CH data in the CH data before repacking and there is new CH data, and communication that can communicate with each OFDM-SP unit Part
6). When the communication unit of the control unit determines that the CH has been repacked by the comparison determination function, the communication unit transmits a control signal that instructs the OFDM-SP unit to change the setting to the CH data after repacking. Has function,
7). The setting change function of the OFDM-SP unit automatically changes the CH data setting of the OFDM-SP unit to the CH data after repacking when a control signal is received from the control unit.

  As described in claim 6, the agile OFDM-SP of the present invention is an input that stores CH data before repacking in the agile OFDM-SP with the CH setting automatic change function according to claim 4 or claim 5. The signal storage unit automatically stores CH data before repacking detected by detecting multi-CH input signals input to the OFDM-SP unit, or before repacking without detecting input signals. CH data is input and stored.

The automatic CH setting change method of the agile OFDM-SP of the present application and the agile OFDM-SP with the automatic CH setting change function have the following effects.
1. CH settings after repacking can be automatically detected and the input CH setting of Agile OFDM-SP can be automatically changed from the CH setting before repacking to the CH setting after repacking. There is no.
2. The CH setting after repacking is changed in real time, so there is no time delay in changing the CH setting. For this reason, even when an on-air wave is transmitted in the CATV system, the signal can be transmitted without stopping after repacking.
3. It can be put to practical use simply by attaching a detection circuit, surface acoustic wave (SAW) filter, general CPU, etc. to the existing OFDM-SP unit.

(Embodiment 1)
An example of an embodiment of an agile OFDM-SP CH setting automatic change method of the present application and an agile OFDM-SP used in the method will be described below with reference to FIGS. As shown in FIG. 1, this embodiment uses an agile OFDM-SP in which four OFDM-SP units are connected in parallel between a four-branch (4DIV) and a four-mixer (4MIX). This is a case of receiving 4CH (CH13, CH14, CH15, CH16). The four OFDM-SP units are for CH13, CH14, CH15, and CH16.

  Each OFDM-SP unit in Fig. 1 has an input-side mixer (MIX), an input-side local oscillator (OSC: 517MHz to 811MHz), a SAW filter (SAW) for securing out-of-band attenuation, and a branch after the input terminal IN. , Detector (DET), CPU, communication unit communicating between each OFDM-SP unit, output side local oscillator (OSC: 517-811MHz), output side mixer (MIX).

  On-air waves for terrestrial digital broadcasting have CH13 to CH62 arranged in a frequency band of 470 MHz to 770 MHz. In the automatic CH setting changing method of this embodiment, each OFDM-SP unit in FIG. 1 receives an input signal, and the CH data before repacking (CH arrangement in FIG. 2) is automatically sent to each OFDM-SP unit. Remember. The storage is performed as follows.

  The input signal input from the input terminal IN is mixed with the local signal from the input-side local oscillator (OSC) by the input-side mixer (MIX), frequency-converted to IF frequency, taken out by the SAW filter (SAW), A part of the received signal is branched by the branching unit of the OFDM-SP unit in FIG. 1, and the presence or absence of the branching signal is detected by the detector (DET). In the case of CH13, the current flows as long as CH13 is input before repacking, so that the output of the detector (DET) is signaled (H). This state is maintained until repacking or an abnormality occurs in the device. The presence / absence (H, L) of the input channel to each OFDM-SP unit at this time is communicated between the communication units of the OFDM-SP unit and stored in each OFDM-SP unit.

  In the above state, each OFDM-SP unit always receives an input signal and detects the presence or absence of the input signal for each CH. If any CH in the input signal is not detected, the detected CH data is transmitted to the OFDM-SP. The detected CH data and the CH data previously stored in the OFDM-SP are compared by the CPU of each OFDM-SP unit with or without storing in the unit. As a result of this comparison, when any CH data in the previously stored CH data before repacking disappears and new CH data (CH arrangement in FIG. 3) is detected, the CH arrangement is repacked. The CPU of the OFDM-SP unit determines that the CH data setting of the OFDM-SP unit is automatically changed to the CH data after repacking by the CPU of the OFDM-SP unit. More specifically, the CH data is automatically changed as follows.

  Since the input signal to each OFDM-SP unit in FIG. 1 is not band-limited by a filter or the like, all on-air waves (CH13 to CH62) are input to each OFDM-SP unit. In this state, each OFDM-SP unit constantly receives an input signal and detects the presence (H or L) of the input signal for each CH. In this detection, if any CH is not detected, the CPU of the OFDM-SP unit determines that an error has occurred in the input channel, and the OFDM-SP unit stops operating due to an abnormal cause, for example, due to radio wave suspension. It is confirmed whether there is no input signal (L) or no input signal (L) for repacking. By the way, when the CH arrangement of the input signal is repacked and CH13 is changed to CH62, for example, the CH13 radio wave disappears, so the CH13 detector output becomes no signal (L).

  In order to confirm the cause of the abnormality, it is necessary to fix the IF frequency to, for example, 44 MHz, which is the IF frequency of CATV (hereinafter the same), so the OSC local frequency in 6 MHz steps with the synthesizer (PLL) of the OFDM-SP unit. 517MHz ・ 523MHz ・ ・ ・ 811MHz is automatically changed in sequence and the presence of input signals (CH13 to CH62) being received is checked for each CH. When the input channel is CH13 (473 MHz), the IF frequency is obtained at the oscillation frequency 517 MHz of the input side local oscillator OSC, and the IF frequency is extracted by the SAW filter (SAW). A part of the signal extracted by the SAW filter (SAW) is branched by the branching device in FIG. 1, and the presence or absence of the branching signal is detected by the detector (DET). The output of the detector (DET) is H for a CH with an input signal, and the output is L for a CH without an input signal. The CH data detected at this time is stored in the CPU of each OFDM-SP unit.

  When the cause of the abnormality is repacking (changed from CH13 to CH62), CH13, CH14, CH15, and CH16 (CH arrangement in FIG. 2) before repacking are CH14, CH15, CH16, Since it becomes CH62 (CH arrangement in FIG. 3), it is confirmed that repacking has been performed by comparing the CH data before repacking with the CH data after detection by the CPU of the OFDM-SP unit. The The output L OFDM-SP unit automatically changes its setting CH from CH13 to CH62.

  If the occurrence of an abnormality (CH13 output L) is not due to repacking but simply due to the CH13 radio wave being stopped, etc., the new CH data confirmed after the occurrence of the abnormality is CH14, CH15, CH16 In this case, the setting of the OFDM-SP unit is not changed, and the standby state is kept as it is before the repacking, and the current operation is performed when the radio wave of CH13 is restored.

  The signal extracted by the SAW filter (SAW) is mixed with the local oscillation signal (local signal) oscillated from the output-side local oscillator (OSC) and converted to the input frequency (470 MHz to 770 MHz), and the output terminal (OUT ) Is output.

  The CH data before repacking to the OFDM-SP unit is stored in the OFDM-SP unit without the input signal being detected by the OFDM-SP unit. It can also be stored in the SP unit.

  The CH change can be performed in the same manner as described above by increasing or decreasing the number of OFDM-SP units even if the number of reception channels increases or decreases.

(Embodiment 2)
Another embodiment of an agile OFDM-SP CH setting automatic change method and an agile OFDM-SP with a CH setting automatic change function according to this embodiment will be described with reference to FIGS. In this embodiment, the agile OFDM-SP of FIG. 4 is used to receive on-air waves of four channels CH13, CH14, CH15, and CH16. The agile OFDM-SP in Fig. 3 has four OFDM-SP units connected in parallel between the five-branch (DIV) and four-mixer (MIX), and one controller connected to the five-branch (DIV). Has been. The four OFDM-SP units are for CH13, CH14, CH15, and CH16.

  Each OFDM-SP unit has an input side IN (input) mixer (MIX), input side local oscillator (OSC: 517MHz to 811MHz), SAW filter (SAW), branching device, detector (DET), CPU, control unit Communication unit, output side local oscillator (OSC: 517-811MHz), output side mixer (MIX). The SAW filter (SAW) is inserted in order to secure out-of-band attenuation.

  The control unit is equipped with a communication unit that communicates with the mixer (MIX), local oscillator (OSC: local oscillation frequency :), SAW filter (SAW), detector (DET), CPU, and OFDM-SP unit after the input terminal IN. ing.

  In the CH setting automatic change method of this embodiment, each OFDM-SP unit in FIG. 1 receives an input signal and automatically stores the CH data before repacking (CH arrangement in FIG. 2) in the control unit. . The storage is performed as follows.

Input signal from input terminal IN is input side local oscillator (OSC) by input side mixer (MIX)
The signal is mixed with the local signal from, and converted to the IF frequency of CATV, extracted by a SAW filter (SAW), and a part of the signal is branched by the branching unit of the OFDM-SP unit shown in FIG. The presence or absence of a wave is detected with a detector (DET). In the case of CH13, the current flows as long as CH13 is input before repacking, so that the output of the detector (DET) is signaled (H). This state is maintained until repacking or an abnormality occurs in the device. The presence / absence (H, L) of the input channel to each OFDM-SP unit at this time is transmitted from the communication unit of the OFDM-SP unit to the communication unit of the control unit and stored in the CPU of the control unit.

  In the above state, each OFDM-SP unit always receives an input signal and detects the presence or absence of the input signal for each CH. Since the input signal to each OFDM-SP unit in FIG. 4 is not band-limited by a filter or the like, all ON-AIRs (CH13 to CH62) are input to each OFDM-SP unit. The input signal is always received by each OFDM-SP unit, and the presence (H or L) of the input signal is detected for each CH.

  The input signal input from the input terminal IN is mixed with the local signal from the input local oscillator (OSC) by the input mixer (MIX) and frequency-converted to the IF frequency of CATV, which is extracted by the SAW filter (SAW). A part of the signal is branched by the branching unit of the OFDM-SP unit in FIG. 1, and the presence or absence of the branching signal is detected by the detector (DET). If any CH is not detected in this detection, the OFDM-SP unit determines that an abnormality has occurred in the input channel in the CPU. Incidentally, when the CH arrangement of the input signal is repacked and CH13 is changed to CH62, for example, the CH13 radio wave disappears, so the CH13 detector output becomes no signal (L). At this time, the OFDM-SP unit determines that there is an abnormality in the input channel and transmits an abnormality signal to the control unit. The transmitted OFDM-SP unit then turns off the output and waits.

  The control unit that has received the abnormal signal stores which OFDM-SP unit output first becomes L (whether the abnormal signal has been output). When an alarm output is output from the OFDM-SP unit I, the control unit stores the output from the OFDM-SP unit I in the CPU. In this case, the control unit determines that there is an abnormality in the input channel, and the cause of the abnormality is that the OFDM-SP unit has stopped due to the CH13 radio wave suspension etc. and has become L, or because of repacking it has become L Check if it was.

  In order to confirm the cause of the abnormality, it is necessary to fix the IF frequency to 44 MHz, etc., so the OSC local frequency is automatically changed sequentially from 517 MHz to 523 MHz ... 811 MHz in 6 MHz steps with the synthesizer (PLL) of the OFDM-SP unit. While checking the presence or absence of input signals (CH13 to CH62) being received for each channel. When the input channel is CH13 (473 MHz), the IF frequency is 44 MHz at the oscillation frequency 517 MHz of the input-side local oscillator OSC, and the IF frequency is extracted by the SAW filter (SAW). A part of the signal extracted by the SAW filter (SAW) is branched by the branching device in FIG. 1, and the presence or absence of the branching signal is detected by the detector (DET). The output of the detector DET is H for a CH with an input signal, and the output is L for a CH without an input signal. The detected CH data is stored in the CPU of the control unit.

  When the cause of the abnormality is repacking (changed from CH13 to CH62), CH13, CH14, CH15, and CH16 (CH arrangement in FIG. 2) before repacking are CH14, CH15, CH16, Since it becomes CH62 (CH arrangement in FIG. 3), it is confirmed that repacking has been performed by comparing the CH data before repacking with the CH data at the time of detection by the CPU of the OFDM-SP unit. The Based on this confirmation, a change instruction signal is transmitted from the communication unit of the control unit to the communication unit of the OFDM-SP unit that has transmitted the release signal so as to change the setting of the input CH of the OFDM-SP unit from CH13 to CH62.

  The OFDM-SP unit that has received the change instruction signal automatically changes the set CH from CH13 to CH62 to match the repacking by the special CPU. At this time, the control unit re-stores channel information in CH14, CH15, CH16, and CH62.

  If only CH14, CH15, and CH16 channel information is newly obtained and CH62 cannot be obtained even when the abnormality occurs (CH13 output L), repacking is not performed and the CH13 radio wave is simply stopped due to a pause or the like. It can be judged that it is waving. In this case, the control unit sends standby information instructing the OFDM-SP unit to wait in that state, and the SP unit waits according to the standby information, and automatically when the radio wave of CH13 is restored. Keep it working.

  The signal taken out by the SAW filter (SAW) is mixed with a local oscillation signal (local signal) oscillated from the output-side local oscillator (OSC), converted to the frequency at the time of input (470 MHz to 770 MHz), and output terminal ( OUT).

  The storage of CH data before repacking to the control unit described above is not performed by detecting the input signal by the OFDM-SP unit and storing it, but artificially controlling the CH data (CH arrangement) known in advance. It can also be stored in the unit.

  The CH change can be performed in the same manner as described above by increasing or decreasing the number of OFDM-SP units even if the number of reception channels increases or decreases.

Explanatory drawing which shows an example of CH setting automatic change method of Agile type OFDM-SP of this invention, and Agile type OFDM-SP with a CH setting automatic change function. Explanatory drawing which shows an example of CH arrangement | sequence before repacking. Explanatory drawing which shows an example of CH arrangement | sequence after repacking. Explanatory drawing which shows the other example of CH setting automatic change method of Agile type OFDM-SP of this invention, and Agile type OFDM-SP with a CH setting automatic change function.

Explanation of symbols

5DIV 5branch 4MIX 4mixer
IN input terminal
MIX input mixer, output mixer
OSC Input local oscillator, Output local oscillator
SAW SAW filter
DET detector

Claims (6)

An agile OFDM-SP channel (CH) setting automatic changing method characterized by comprising the following configurations 1 to 4.
1. Store the CH data before repacking in Agile OFDM-SP equipped with two or more OFDM-SP units,
2. After storing, the input signal is received by the OFDM-SP unit and the presence or absence of the input signal is detected for each CH,
3. If no input signal of any CH is detected by the detection, the detected CH data and the previously stored CH data are stored without storing the detected CH data in the OFDM-SP unit. In the OFDM-SP unit,
4). As a result of the comparison, if any CH data in the previously stored CH data is not present and new CH data is detected, it is determined that the CH has been repacked, and the input / output CH is determined in the OFDM-SP unit. Was automatically changed to CH data after repacking. A method for automatically changing the CH setting of an agile OFDM-SP comprising the following configurations 1 to 7:
1. The multi-channel input signal before repacking is stored in the control unit of the agile OFDM-SP including two or more OFDM-SP units and a control unit,
2. After storing, the input signal is received by the OFDM-SP unit and the presence or absence of the input signal is detected for each CH,
3. When the input signal of any CH is not detected by the detection, an abnormality notification signal is transmitted from the detected OFDM-SP unit to the control unit,
4). The control unit that has received the error notification signal detects the CH data of the input signal received at that time for each CH,
5). Compare the detected CH data in the control unit with or without storing the detected CH data in the control unit,
6). As a result of the comparison, when any CH data in the previously stored CH data is not detected and new CH data is detected, the control unit determines that the CH of the input signal has been repacked and performs OFDM from the control unit. -Send a control signal to the SP unit to change the CH data setting to the CH data after repacking,
7). The OFDM-SP unit automatically changes the CH data setting to the repacked CH data based on the control signal.   3. The agile OFDM-SP CH setting automatic change method according to claim 1 or 2, wherein CH data is stored in the OFDM-SP unit or control unit before repacking is detected by the OFDM-SP unit. The method of automatically changing the CH setting of the agile OFDM-SP, which is automatically performed or stored without detection. Agile OFDM-SP with CH setting automatic change function, characterized by having the following configurations 1 and 2.
1. It has an OFDM-SP unit with the number of input channels,
2. Each OFDM-SP unit uses a frequency conversion function that converts the input signal to the IF frequency, an input signal detection function that splits a part of the input signal and detects the presence or absence of each channel, and an input signal detection function. A comparison function for storing the CH data stored in the OFDM-SP unit with or without storing it in the OFDM-SP unit, and any CH data in the CH data before repacking is detected by the comparison. When new CH data is detected, the comparison / determination function that determines that the CH has been repacked, and the setting of the OFDM-SP unit's CH data is automatically converted to the repacked CH data based on this determination. Equipped with a setting change function to change. Agile OFDM-SP with CH setting automatic change function characterized by comprising the following configurations 1-7.
1. An OFDM-SP unit with the number of input channels and a control unit that receives the multi-channel input signal and controls the OFDM-SP unit,
2. Each OFDM-SP unit has a frequency conversion function that converts the input signal to the IF frequency, an input signal detection function that detects a part of the input signal and detects the presence or absence of each channel, and communication that can communicate with the control unit. And a setting change function to change the CH data setting of the OFDM-SP unit to CH data after repacking,
4). The communication unit transmits an abnormal signal to the communication unit of the control unit when an input signal of some CH is not detected by the input signal detection function,
5). The control unit stores the CH data before repacking, the CH data storage function, the input signal detection function that detects the input signal for each CH when the abnormal signal is received, the detected CH data and the previously stored CH data Comparison and judgment function for judging that CH is repacked when there is no CH data in the CH data before repacking and there is new CH data, and communication that can communicate with each OFDM-SP unit Part
6). When the communication unit of the control unit determines that the CH has been repacked by the comparison determination function, the communication unit transmits a control signal that instructs the OFDM-SP unit to change the setting to the CH data after repacking. Has function,
7). The setting change function of the OFDM-SP unit automatically changes the CH data setting of the OFDM-SP unit to the CH data after repacking when a control signal is received from the control unit. 6. The agile OFDM-SP with CH setting automatic change function according to claim 4 or 5, wherein the input signal storage unit for storing CH data before repacking is an input signal of multiple CHs input to the OFDM-SP unit. CH setting, which is to automatically store the CH data before repacking detected by detecting or detecting and inputting the CH data before repacking without detecting the input signal Agile OFDM-SP with automatic change function.

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