JP2004007074A - Signal level measuring apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a signal level measuring apparatus capable of identifying a kind of a signal that is being measured and an artificial satellite of a transmission source. <P>SOLUTION: A tuner unit 14 selects signals of a satellite and a channel (transponder) designated by an operation section 15 among RF signals separated by a power separation filter 12 on the basis of PLL data Dp, demodulates the selected signals, measures the signal level, and decodes the demodulated signal by using a symbol rate Db or the like to obtain digital data. A synchronous byte of a TS packet is detected from the digital data and a prescribed discrimination signal is activated while the synchronous byte is being detected. A display section 16 lights up an identification mark denoting whether or not a signal for digital broadcasting is received from a designated satellite on the basis of the discrimination signal. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a signal level measuring device for measuring a signal level of an input signal.
[0002]
[Prior art]
Conventionally, level checkers have been used to adjust the direction (azimuth and elevation) of the receiving antenna that receives the transmitted radio waves from artificial satellites, and to adjust the plane of polarization etc. when linearly polarized waves are used as the transmitted radio waves. Have been.
[0003]
This level checker is normally used by connecting to a transmission line for transmitting a signal received from a receiving antenna. When one of the channels (transponders) provided by the target artificial satellite is designated, the level checker is received. The signal level of the signal is measured, and the measurement result is displayed using a numerical value, a bar graph, or the like.
[0004]
[Problems to be solved by the invention]
By the way, when the receiving antenna is receiving the transmitted radio wave from the artificial satellite, the signal level of the received signal is about 70 to 80 dBμ, and even when the receiving antenna is not receiving the transmitted radio wave from the artificial satellite. , The signal level of the received signal may be about 60 dBμ. In particular, if a booster is installed downstream of the antenna, the signal level of the received signal supplied via the booster may exceed 70 dBμ even if no transmission radio wave is received.
[0005]
That is, even if the signal level measured using the above-described level checker is 70 to 80 dBμ, the transmission radio wave from the artificial satellite is not necessarily received. In addition, the above-described level checker receives all transmission waves from artificial satellites that use the same frequency as the designated channel, so even if the receiving antenna receives transmission waves from artificial satellites, The radio waves are not always from the desired artificial satellite.
[0006]
Therefore, in order to surely adjust the direction of the receiving antenna, it is necessary to actually connect a tuner for viewing the program and reproduce and check the received signal, which is troublesome.
Also, the level checker can be used, for example, when confirming whether or not a signal of a desired frequency band (for example, digital broadcast) is distributed to an indoor TV terminal of an existing TV facility. However, with the above-described level checker, it is possible to check whether there is a signal in the designated frequency band, but whether the signal is a signal for analog broadcasting or a signal for digital broadcasting There was also a problem that cannot be identified.
[0007]
SUMMARY OF THE INVENTION It is an object of the present invention to provide a signal level measuring device capable of identifying the type of a signal under measurement and the artificial satellite of the transmission source in order to solve the above problems.
[0008]
[Means for Solving the Problems]
In the signal level measuring device according to the first aspect of the present invention, the satellite designating means designates one of artificial satellites for performing digital broadcasting, and the channel designating means designates the designated artificial satellite. , The digital data extraction unit converts the input signal from the satellite channel designated by the satellite designation unit and the channel designation unit. The digital signal is demodulated and decoded as a received signal, and digital data is extracted.
[0009]
Since parameters required for demodulation and decoding (number of channels, frequency assigned to each channel, symbol rate, etc.) differ from one satellite to another, the digital data extracting means uses the channel of the designated artificial satellite. , These parameters are set as appropriate.
[0010]
When the digital data extracting means succeeds in extracting the digital data, the notifying means notifies that the input signal is a received signal from the artificial satellite specified by the satellite specifying means.
As described above, according to the signal level measuring apparatus of the present invention, not only the signal level is measured, but also the demodulation and decoding of the signal and the confirmation of the content of the signal are performed. Can be reliably identified as a signal for a desired broadcast signal.
[0011]
Therefore, for example, when adjusting the direction of the receiving antenna so as to receive a transmission radio wave from an artificial satellite that performs digital broadcasting, the direction in which the peak of the noise level can be obtained without using a tuner for viewing the program. It is possible to reliably prevent erroneous adjustment in the direction of the artificial satellite other than desired.
[0012]
Further, the signal level measuring device of the present invention can also be suitably used when confirming whether or not a signal for digital broadcasting is distributed to an indoor antenna terminal or the like in an existing TV facility or the like.
In addition, the notification means may visually notify via a display device such as a display, or may notify audibly via an audio device such as a speaker. Further, the notification means may be configured to generate only a notification signal, supply the signal to an external device provided separately from the device, and perform notification via the external device.
[0013]
By the way, a signal for satellite digital broadcasting uses the MPEG2 system, and in this case, a TS packet is obtained by demodulating and decoding a received signal. In order to cope with this, as described in claim 2, the digital data extracting means extracts a TS packet as digital data, and determines whether or not pre-specified specific information included in the TS packet has been recognized. It is desirable to configure so as to determine the success or failure of digital data extraction.
[0014]
As the specific information included in the TS packet, a synchronization byte (47H) can be used.
However, the specific information is not limited to the synchronization byte. For example, similar to the synchronization byte, information common to all TS packets and information enabling identification of the source artificial satellite are included in the TS packet. If so, such information may be used as the specific information.
[0015]
Next, the channel specifying means can be configured to specify a channel according to an external operation, that is, an operation performed by a user of the apparatus, as described in claim 4. In this case, the user of the device can arbitrarily set the channel for measuring the signal level.
[0016]
By the way, when adjusting the direction of the receiving antenna, if the artificial satellite knows the channel on which the transmission radio wave is reliably transmitted, the adjustment may be performed by designating the channel. However, some channels, such as communication satellites, transmit radio waves only for a time required by the user, and it may not be clear whether the designated channel is transmitting the radio waves. In this case, when the transmission radio wave from the artificial satellite cannot be received, it cannot be immediately confirmed whether the reception cannot be performed because the direction of the receiving antenna is bad or the designated channel is stopped. In order to confirm this, there is a problem in that the direction of the receiving antenna must be fixed and the signal level must be measured by designating all the channels one by one.
[0017]
Therefore, as set forth in claim 5, a channel search means for sequentially switching channels designated by the channel designation means is provided at least until the digital data extraction means succeeds in extracting the digital data, and the transmission radio wave is transmitted. The channel may be automatically searched.
[0018]
In this case, the direction of the receiving antenna can be adjusted reliably and in a short time without previously knowing which channel is transmitting the transmission radio wave.
Next, the satellite designating means may be configured to designate an artificial satellite in accordance with an external operation as described in claim 6, or as described in claim 7, the artificial satellite designated by the satellite designating means. A satellite search means for sequentially switching may be provided so that all artificial satellites are automatically searched.
[0019]
In particular, in the signal level measuring apparatus according to claim 7, which is provided with a satellite search means, for example, when confirming whether or not a signal for a desired digital broadcast is distributed to an indoor TV terminal or the like of an existing TV facility, It can be easily checked without the need for troublesome channel selection (designation of satellites and channels), and it is also possible to immediately identify which satellite is transmitting the signal from the content of the notification by the notification means. Can be.
[0020]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram showing an overall configuration of a signal level measuring device (level checker) 10 of the present embodiment.
[0021]
The level checker 10 of the present embodiment has two modes: an adjustment mode set when adjusting the direction of the receiving antenna, and a check mode set when checking the supply state of the satellite digital broadcast signal to the indoor antenna terminal or the like. It operates in one of two operation modes, and displays the signal level and the like of the received signal in digital broadcast channel (transponder) units.
[0022]
The MPEG2 system is applied to a signal transmitted through a channel for satellite digital broadcasting, and a 204-byte packet called a TS (Transport Stream) packet is used. This TS packet includes a synchronization byte (47H) at the beginning, and the entire TS packet including the synchronization byte is coded by a convolutional code and a Reed-Solomon code, and further subjected to PSK modulation. And transmitted from each satellite.
[0023]
Further, as shown in FIG. 1, in this embodiment, an offset type parabolic antenna is used as the receiving antenna 2, and this receiving antenna 2 is connected to a reflecting mirror 2a and a supporting arm, as is well known. And a converter 2b arranged at the focal position of the reflecting mirror 2a.
[0024]
However, the converter 2b is configured to operate using a DC component of a voltage signal supplied via a transmission line L for transmitting a reception signal as a power supply. Then, the converter 2b receives the radio wave collected by the reflecting mirror 2a and converts the received signal to an intermediate frequency signal (RF signal: RF signal: 10.678 [GHz] in the present embodiment) using a local signal. The frequency is converted to 1032 to 1336 [MHz] for the BS antenna and 1590 to 2071 [MHz] for the CS antenna) and transmitted to the transmission line L.
[0025]
In particular, when the receiving antenna 2 is a CS antenna, the converter 2b must superimpose the polarization signal and the tone signal from JCSAT4 if the tone signal (32 to 53 [kHz]) is superimposed on the DC component. For example, the polarization signal from JCSAT3 is selected, and if the DC component voltage (supply voltage) of the polarization signal from the selected satellite is a predetermined low voltage (11 V in this embodiment), the vertical If the polarization signal is a predetermined high voltage (15 V in this embodiment), a horizontal polarization signal is selected, and an RF signal obtained by frequency-converting the selected vertical or horizontal polarization signal is output. I have.
[0026]
Since such a converter 2b is well known for both the BS antenna and the CS antenna, a detailed description of its configuration will be omitted.
Next, the level checker 10 according to the present embodiment supplies a DC component serving as a power source of the converter 2b to the transmission line L via the terminal 11, and also receives a reception signal (from the converter 2b input via the transmission line L). A power supply separation filter 12 for separating an RF signal from a DC component, a DC component to be supplied to the converter 2b, and when a CS antenna is designated as a measurement target, the DC component voltage (feeding) is determined according to the satellite selection signal Ss. And a power supply unit 13 for superposing a tone signal in accordance with the polarization selection signal Sm.
[0027]
Further, the level checker 10 demodulates a signal of a specified channel from the RF signals separated by the power supply separation filter 12 based on PLL data Dp to be described later, demodulates the signal, and measures the signal level. At the same time, a tuner unit 14 for executing processing such as decoding a demodulated signal using a symbol rate Db or the like to obtain a TS packet, and specifying a satellite or a channel (transponder) for which a reception level is to be measured. Operation unit 15, a display unit 16 such as a liquid crystal display panel, and a well-known microcomputer mainly composed of a CPU, a ROM, and a RAM. Satellite selection signal Ss, polarization selection signal Sm, PLL data Dp for tuner unit 14, symbol In addition, the display unit 16 sets various types of display based on the signal level and the discrimination signal read from the tuner unit 14, the adjustment mode processing when adjusting the reception antenna 2, the indoor antenna terminal, and the like. And a control unit 17 for executing a confirmation mode process or the like when confirming a signal supplied to the device.
[0028]
Then, the tuner unit 14 directly demodulates the signal of the channel whose center frequency is the frequency indicated by the PLL data Dp, and detects the synchronization byte of the TS packet from the digital data obtained by further decoding the demodulated signal. While the synchronization byte continues to be detected, a predetermined determination signal is turned on. Note that such a tuner unit 14 can be easily configured using, for example, a digital DBS front end (manufactured by Sharp, model name: BS2F7VZ0430) or a channel decoder (manufactured by NEC, model name: μPD61521).
[0029]
In the adjustment mode, the display unit 16 receives a digital broadcast signal from a satellite or a channel designated by an operation on the operation unit 15, a signal level of the designated channel, or a designated satellite. It is configured to display an identification mark or the like indicating whether or not the signal level has been set, and especially when JCSAT No. 3 or 4 is designated as a measurement target, the signal levels of both of them can be displayed simultaneously. The display unit 16 is configured to display, in the confirmation mode, all the satellite names that can be specified by the device and the presence or absence of a signal from the satellite.
[0030]
Here, each process executed by the CPU of the control unit 17 will be described in detail.
The ROM of the control unit 17 stores an information table indicating information about each satellite and channel, in addition to a program for executing each process, and each process refers to this information table. Various settings and controls.
[0031]
In the information table, as shown in FIG. 2, for each satellite, the channel number of the channel for digital broadcasting, the PLL data Dp indicating the frequency of the local signal to be used when extracting the channel, and the demodulated data. The stored signal symbol rate Db, the channel number of a promo channel on which digital broadcasting is constantly performed, and the like are stored. Here, each satellite is assigned a satellite number. Is assigned to the BSAT in the present embodiment. No. 1, JCSAT No. 3 2, JCSAT No. 4 NO. 3 has been assigned.
[0032]
First, the processing executed when the operation mode is set to the adjustment mode and the BSAT is selected as the measurement target (hereinafter, referred to as “BS adjustment mode”) will be described with reference to the flowchart shown in FIG.
When this processing is started, first, the internal settings of the device are cleared (S110). Then, the measurement conditions set via the operation unit 15, that is, the satellite to be measured (BSAT in this case) and the channel are read (S120), and the read measurement conditions and the contents of the information table stored in the ROM are read. The set PLL data Dp and symbol rate Db are output to the tuner unit 14 (S130).
[0033]
Then, the tuner unit 14 selects a signal of the designated channel in accordance with the PLL data Dp from the IF signal input via the terminal 11 and then demodulates the signal, and indicates the demodulated signal at the symbol rate Db. At the set speed, and extracts TS packets.
[0034]
Then, the signal level of the signal demodulated from the tuner unit 14 is read, and the signal level is displayed on the display unit 16 together with the measurement conditions (satellite name and channel) read in S120 (S140). It is determined whether or not the discrimination signal output from the tuner unit 14 is turned on, that is, whether or not the synchronization byte of the TS packet is detected (S150).
[0035]
At this time, if the discrimination signal is on, the identification mark on the display panel of the display unit 16 is turned on (S160), while if the discrimination signal is not on, the identification mark on the display panel of the display unit 16 is turned on. Is turned off (S170).
Thereafter, the operation unit 15 is operated to determine whether or not the measurement condition has been changed (S180). If there is no change, the process returns to S140 and repeats the measurement of the reception level under the same condition. Return and execute this process again from the beginning.
[0036]
Next, a process executed when the adjustment mode is set by the operation unit 15 and JCSAT Nos. 3 and 4 are selected as measurement targets (hereinafter, referred to as “CS adjustment mode”) will be described with reference to the flowchart shown in FIG. I do.
When this process is started, first, the internal settings of the device are cleared (S210). Then, the measurement conditions set via the operation unit 15, that is, the satellites to be measured (here, JCSAT3 and 4) and the channel are read (S220), and any satellite (here, JCSAT3) is selected. The satellite to be measured is set by outputting the satellite selection signal Ss to the power supply unit 13 (S230). At the same time, the polarization selection signal Sm, the PLL data Dp, and the symbol rate Db are changed according to the measurement conditions read in S220, the satellite to be measured set in S230, and the contents of the information table stored in the ROM. This is set and output to the power supply unit 13 and the tuner unit 14 (S240).
[0037]
Then, the power supply unit 13 switches the setting of the DC component to be supplied to the converter 2b (the magnitude of the power supply voltage / whether or not the tone signal is superimposed) according to the satellite selection signal Ss and the polarization selection signal Sm, and The unit 14 selects a signal of a designated channel in accordance with the PLL data Dp from the IF signals input via the terminal 11, demodulates the signal, and demodulates the demodulated signal at the speed indicated by the symbol rate Db. Decode and extract TS packets.
[0038]
Then, the signal level of the demodulated signal is read from the tuner unit 14 and the signal level is displayed on the display unit 16 together with the selected satellite name and channel (S250), and the tuner unit 14 outputs the signal level. It is determined whether or not the determination signal is turned on, that is, whether or not the synchronization byte of the TS packet is detected (S260).
[0039]
At this time, if the discrimination signal is on, after setting the reception enable flag of the satellite to be measured (S270), it is determined whether the reception enable flag is set for both satellites (S280), and both satellites receive. If the flag is set, the identification mark is turned on (S290).
[0040]
On the other hand, if it is determined in S260 that the determination signal is turned off, or if it is determined in S280 that the reception enable flag of any of the satellites is not set, the reception of the satellite to be measured is performed. The permission flag is reset, and if the identification mark is lit, it is turned off (S300).
[0041]
After S290 or S300, the satellite to be measured is switched by outputting a satellite selection signal Ss for selecting a satellite which is not currently selected to the power supply unit 13. At this time, if the channel (transponder) arrangement of the two desired satellites is not the same, the channel (transponder) is also selected (S310).
[0042]
Thereafter, the operation unit 15 is operated to determine whether the measurement condition has been changed (S320). If there is no change, the process returns to S250 to repeat the measurement of the reception level under the same condition. Return and execute this process again from the beginning.
[0043]
That is, regardless of the BS adjustment mode and the CS adjustment mode, when adjusting the direction of the receiving antenna 2, the transmission line from the receiving antenna 2 is connected to the terminal 11 of the level checker 10, and The operation mode of the level checker 10 is set to the adjustment mode, and the satellite to be measured and the channel used for the measurement are input.
[0044]
Then, since the signal level is displayed on the display panel of the display unit 16, the direction of the receiving antenna 2 may be adjusted so that the signal level becomes a peak. At this time, if the receiving antenna 2 is adjusted in the correct direction, the received signal from the satellite is demodulated and decoded, and the TS packet is extracted, so that the identification mark is turned on. On the other hand, if the receiving antenna 2 is not adjusted to the correct satellite, even if the signal level has peaked, the identification mark remains off because no TS packet is extracted from the received signal.
[0045]
Here, the case of receiving from two satellites has been described as an example, but it is also possible to similarly receive from three or more satellites and display the identification mark only when all satellites can be received.
Next, processing executed when the confirmation mode is set by the operation unit 15 will be described with reference to the flowchart shown in FIG.
[0046]
When this process is started, first, a parameter i for specifying a satellite to be measured is initialized to 1 (S410).
Then, it is determined whether or not i = 1 (in this case, whether or not the satellite to be measured is BSAT) (S420). If the satellite to be measured is not BSAT but is JCSAT No. 3 or 4, information stored in the ROM is obtained. The promo channel of the satellite to be measured (satellite of NO.i) is specified based on the table, the satellite selection signal Ss and the polarization selection signal Sm corresponding to the promo channel are set, and output to the power supply unit 13 (S430). ).
[0047]
Further, based on the information table stored in the ROM, the PLL data Dp and the symbol rate Db are set so that the measurement is performed for the promo channel of the satellite to be measured, and output to the tuner unit 14 (S440).
Then, the tuner unit 14 demodulates the signal of the designated channel in accordance with the PLL data Dp among the IF signals input via the terminal 11, and converts the demodulated signal at the speed indicated by the symbol rate Db. Decode and extract the TS packet (sync byte).
[0048]
Then, the signal level of the signal demodulated from the tuner unit 14 is read, and the signal level is displayed on the display unit 16 (S450). At the same time, whether or not the discrimination signal output from the tuner unit 14 is on is determined. That is, it is determined whether the synchronization byte of the TS packet is detected (S460).
[0049]
At this time, if the discrimination signal is turned on, the reception enable flag of the satellite to be measured (satellite of NO.i) is set (S470), while if the discrimination signal is not turned on, reception of the satellite to be measured is enabled. The flag is reset (S480).
Thereafter, the parameter i is incremented (S490), and it is determined whether or not the parameter i is greater than 3 (S500). If the parameter i is larger, it is determined that the measurement has been completed for all the satellites that can be specified by the device and received. After displaying all the satellites for which the flag is set on the display panel of the display unit 16 (S510), the process returns to S410. However, if there is no satellite with the reception enabled flag set, a message to that effect (for example, “reception disabled”) is displayed.
[0050]
On the other hand, if the parameter i is 3 or less, it is determined whether any key operation has been performed on the operation unit 15 (S520). If no key operation has been performed, the process returns to S420 to return to the next satellite. Is measured in the same manner, and if a key operation has been performed, the process returns to S410 in order to start the process again from the beginning.
[0051]
In other words, when confirming whether or not a signal of the satellite digital broadcast is distributed to the in-home antenna terminal and the like, and what kind of signal is being distributed, the connection between the in-home antenna terminal and the terminal 11 of the level checker 10 is determined. The connection is established by a transmission line, and the operation mode of the level checker 10 is set to the confirmation mode via the operation unit 15.
[0052]
Then, the level checker 10 tries to measure the signal level of the signal of the promo channel on which the digital broadcasting is constantly performed and extracts the TS packets for all the satellites, and displays the respective signal levels and extracts the TS packets. Display successful satellite names. That is, not only whether or not a signal for digital broadcasting is distributed to the in-home antenna terminal, but also from which satellite the signal is distributed is displayed.
[0053]
As described above, according to the level checker 10 of the present embodiment, in the adjustment mode, not only the signal level is displayed but also whether or not the TS packet has been extracted from the received signal is displayed by the identification mark. Has been.
Therefore, when the direction of the receiving antenna 2 is adjusted, it is possible to reliably prevent the direction of the receiving antenna 2 from being erroneously adjusted to a direction other than the designated satellite, and it is guaranteed that the TS packet can be extracted. The direction of the receiving antenna 2 can be adjusted so that digital broadcasting can be surely viewed without checking with a program viewing tuner.
[0054]
That is, even if another satellite is performing the same digital broadcasting in the MPEG2 system, the frequency (PLL data Dp) and the symbol rate Db must match in order to extract a TS packet. As long as the identification mark does not light up by mistake.
[0055]
Further, according to the level checker 10 of the present embodiment, in the confirmation mode, the promo channel of each satellite is automatically searched, and all the satellites for which the TS packet has been successfully extracted are displayed.
Therefore, the operation for confirming whether or not the satellite digital broadcast signal is distributed and the operation for confirming from which satellite the signal is distributed can be performed extremely easily and reliably.
[0056]
Although one embodiment of the present invention has been described above, the present invention is not limited to the above embodiment, and can be implemented in various modes.
For example, in the above-described embodiment, the measurement is performed by specifying the satellite and the channel in the adjustment mode. However, when only the satellite is specified, the channel may be automatically searched.
[0057]
In this case, in the BS adjustment mode, for example, as shown in FIG. 6, after S130, a step (S132) of determining whether the determination signal is on is inserted. If the determination signal is on, S140 is performed. If the determination signal is not on, the channel is changed (S134), and the process returns to S130 to automatically search for the channel on which the determination signal is on. The order of switching channels may be, for example, the order registered in the information table, or may be the order of search registered separately.
[0058]
Also, in the case of the CS adjustment mode or the confirmation mode, a channel can be automatically searched by inserting steps similar to S132 and S134 after S240 and S440, respectively.
In the above embodiment, the information table is stored in the ROM. However, the information table is stored in a rewritable memory such as a non-volatile RAM or an EEPROM, and when the promo channel or the digital broadcast channel is changed. , So that it can be easily handled.
[0059]
Further, in the above embodiment, the case where the level checker 10 is used for adjusting the direction of the receiving antenna 2 and for confirming the digital broadcast signal distributed to the home antenna terminal has been described as an example. The level checker 10 is a system that uses a signal to which the MPEG system is applied, such as a transmodulation system that receives a signal of a terrestrial digital broadcast or a BS digital broadcast and remodulates the signal into a signal suitable for a CATV system. , Any system can be used.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration of a level checker according to an embodiment.
FIG. 2 is an explanatory diagram showing the contents of an information table.
FIG. 3 is a flowchart showing the contents of processing executed in a BS adjustment mode.
FIG. 4 is a flowchart showing the contents of processing executed in a CS adjustment mode.
FIG. 5 is a flowchart showing the contents of processing executed in a confirmation mode.
FIG. 6 is a modified example of the process executed in the BS adjustment mode.
[Explanation of symbols]
Reference numeral 2: receiving antenna, 2a: reflecting mirror, 2b: converter, 10: level checker, 11: terminal, 12: power separation filter, 13: power supply unit, 14: tuner unit, 15: operation unit, 16: display unit, 17: control unit, L: transmission line, Db: symbol rate, Dp: PLL data, Sm: polarization selection signal, Ss: satellite selection signal.

Claims (7)

In a signal level measuring device for measuring a signal level of an input signal,
Satellite designation means for designating one of the artificial satellites for digital broadcasting,
Channel designating means for designating any of the channels provided by the satellite designated by the satellite designating means;
Digital data extracting means for demodulating and decoding the input signal as a signal received from the channel of the satellite designated by the satellite designating means and the channel designating means, and extracting digital data;
Notifying means for notifying that the input signal is a received signal from an artificial satellite specified by the satellite specifying means when the digital data extracting means succeeds in extracting digital data;
A signal level measuring device comprising: The digital data extracted by the digital data extracting means is a TS packet, and the success or failure of the digital data extraction is determined based on whether or not the specified specific information included in the TS packet is recognized. The signal level measuring device according to claim 1. The signal level measuring device according to claim 2, wherein the specific information is a synchronization byte. 4. The signal level measuring device according to claim 1, wherein the channel designation unit designates the channel according to an external operation. 5. The apparatus according to claim 1, further comprising channel search means for sequentially switching channels designated by said channel designation means at least until the digital data extraction means succeeds in extracting digital data. Signal level measuring device. 6. The signal level measuring device according to claim 1, wherein the satellite designating unit designates an artificial satellite according to an external operation. 7. The signal level measuring device according to claim 1, further comprising a satellite search unit for sequentially switching an artificial satellite designated by the satellite designation unit.

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