JP2017184020A - Inspection system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an inspection system enabling an easy change of the signal level of a test signal.SOLUTION: The inspection system includes: a transmitter 11 which is connected to an input terminal 2 at the inspection of a reception facility 1, to transmit a test signal TS having a set signal level and a set frequency and also information indicative of the set signal level superposed thereto; and a receiver 12 which is connected to the terminal 8 of a terminal device at the inspection, to detect the signal level of the test signal TS transmitted from the transmitter 11, and extract the information, indicative of the signal level which is set by the transmitter 11, from the received test signal TS. This enables an easy change of the signal level of the test signal TS.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an inspection system, and more particularly to an inspection system for inspecting a receiving facility that receives satellite broadcasts.

  Patent Document 1 discloses an inspection system including a transmitter and a receiver that are respectively connected to an input terminal and a terminal terminal of a reception facility when the reception facility is inspected. The transmitter outputs a test signal having a set frequency and a known signal level to the input terminal. The receiver receives a test signal from the terminal terminal and compares the signal level of the received test signal with a plurality of reference levels to determine the transmission loss of the receiving equipment.

JP 2011-199768 A

  However, in Patent Document 1, when changing the signal level of the test signal, it is necessary not only to change the signal level of the test signal on the transmitter side, but also to change the reference level in multiple stages on the receiver side. There is a problem that the labor involved in changing the signal level of the test signal is large.

  Therefore, a main object of the present invention is to provide an inspection system capable of easily changing the signal level of a test signal.

  The inspection system according to the present invention is an inspection system for inspecting a reception facility having an input terminal and a terminal terminal, and includes a transmitter and a receiver connected to the input terminal and the terminal terminal, respectively, when the reception facility is inspected. It is a thing. The transmitter has a set first signal level and a set frequency, and outputs a test signal on which information indicating the first signal level is superimposed to the input terminal. The first signal level of the test signal is lowered to the second signal level due to transmission loss of the receiving facility. The receiver receives a test signal from the terminal terminal, detects a second signal level of the received test signal, and extracts information indicating the first signal level from the received test signal.

  In the inspection system according to the present invention, on the transmitter side, information indicating the set first signal level is superimposed on the test signal and output to the input terminal of the reception facility, and on the receiver side, the information is received from the terminal terminal. The second signal level of the test signal is detected, and information indicating the first signal level is extracted from the test signal. Therefore, when the first signal level of the test signal is changed, it is only necessary to change the first signal level on the transmitter side, so that the signal level of the test signal can be easily changed.

It is a circuit block diagram which illustrates the composition of the receiving equipment used as the inspection object of the inspection system of this application. 1 is a circuit block diagram showing a configuration of an inspection system according to an embodiment of the present invention. FIG. 3 is a front view illustrating a configuration of a transmitter illustrated in FIG. 2. FIG. 4 is a circuit block diagram illustrating a configuration of a transmitter illustrated in FIG. 3. FIG. 3 is a front view illustrating a configuration of the receiver illustrated in FIG. 2. FIG. 6 is a circuit block diagram illustrating a configuration of the receiver illustrated in FIG. 5. FIG. 7 is a circuit block diagram illustrating a configuration of a tuner IC illustrated in FIG. 6.

  In recent years, it is planned to implement 4K television broadcasting and 8K television broadcasting (hereinafter referred to as 4K / 8K television broadcasting) having higher image resolution than the current television broadcasting. In 4K / 8K television broadcasting, radio waves in the current television broadcast frequency band (1032 MHz to 2071 MHz) may be used, but the frequency band is expanded and is higher than the current frequency band (2224 to 3224 MHz). ) May be used.

  When the frequency band is expanded, if a 4K / 8K television broadcast is received by the current receiving equipment, a large transmission loss occurs at the receiving equipment, and a high-frequency signal having a desired signal level cannot be received at the terminal terminal. Therefore, in order to receive 4K / 8K television broadcasting, it is necessary to install a new receiving facility with a small transmission loss in a high frequency band (2224 to 3224 MHz).

  When the start time of 4K / 8K television broadcast is determined, in order to receive 4K / 8K television broadcast simultaneously with the start, it is necessary to install a new receiving facility before the start. However, at the time when a new receiving facility is installed, the radio wave of 4K / 8K television broadcasting has not been transmitted yet, so it is impossible to inspect whether a high-frequency signal having a desired signal level reaches the terminal terminal. There is. In this embodiment, this problem can be solved.

  FIG. 1 is a circuit block diagram illustrating the configuration of a receiving facility 1 for receiving 4K / 8K television broadcasting. In FIG. 1, a receiving facility 1 is installed in, for example, a housing complex, and includes an input terminal 2, a booster 3, a distributor 4, coaxial cables 5 and 7, a branching device 6, and a terminal terminal 8.

  The input terminal 2 is connected to an antenna 9 for 4K / 8K television broadcasting. The antenna 9 receives radio waves for 4K / 8K television broadcasting from a broadcasting satellite (not shown). The booster 3 amplifies the high frequency signal from the antenna 9 with a predetermined gain (for example, 30 dB) and outputs it to the input terminal of the distributor 4.

  The distributor 4 distributes the high-frequency signal given from the booster 3 to the input terminal to a plurality of output terminals. The plurality of output terminals of the distributor 4 respectively correspond to a plurality of houses included in an apartment house, for example. The high frequency signal output from each output terminal of the distributor 4 is given to the input terminal of the branching device 6 in the corresponding house via the coaxial cable 5.

  The branching device 6 distributes the high-frequency signal given to the input terminal from the distributor 4 to a plurality of output terminals. The plurality of output terminals of the branching device 6 respectively correspond to, for example, a plurality of rooms in a house. The high frequency signal output from each output terminal of the branching device 6 is supplied to the terminal terminal 8 of the corresponding room via the coaxial cable 7. The terminal 8 is connected to a television receiver 10 for 4K television broadcasting or 8K television broadcasting. The television receiver 10 displays 4K television broadcast or 8K television broadcast video.

  As described above, in order to receive 4K / 8K TV broadcasts simultaneously with the start of 4K / 8K TV broadcasts, a new receiving facility 1 is installed before the start, and the radio waves of 4K / 8K TV broadcasts are still being transmitted. It is necessary to inspect the receiving facility 1 in a situation where reception is not possible.

  FIG. 2 is a block diagram showing the configuration of the inspection system according to the embodiment of the present invention. In FIG. 2, this inspection system is a system for inspecting a reception facility 1 and includes a transmitter 11 and a receiver 12.

  When inspecting the receiving facility 1, the input terminal 2 of the receiving facility 1 is connected to the output terminal 11a of the transmitter 11 instead of the antenna 9, and the terminal terminal 8 is input to the input terminal 12a of the receiver 12 instead of the television receiver 10. Connected to.

  The transmitter 11 has a set frequency (for example, 3224 MHz), a set signal level (for example, 70 dBμV), and a test signal TS on which information indicating the set signal level (in this case, 70 dBμV) is superimposed. Output to the input terminal 2. The test signal TS is obtained by, for example, FSK (Frequency Shift Keying) modulation of the high-frequency signal having the set frequency described above using the information indicating the set signal level and amplifying the signal to the set signal level. is there. The modulation method may be any method other than the FSK method.

  The test signal TS input from the transmitter 11 to the reception facility 1 is amplified by the booster 3 with a predetermined gain (for example, 30 dB). The test signal TS of 70 dBμV output from the transmitter 11 is amplified to 100 dBμV by the booster 3 and given to the input terminal of the distributor 4. The test signal TS output from the output terminal to be inspected among the plurality of output terminals of the distributor 4 is supplied to the receiver 12 via the coaxial cable 5, the branching device 6, the coaxial cable 7, and the terminal terminal 8. The

  Assuming that transmission losses of −15 dB, −2 dB, −8 dB, −2 dB, and −8 dB have occurred in the distributor 4, the coaxial cable 5, the branching device 6, the coaxial cable 7, and the terminal terminal 8, respectively, the receiver 12 Is supplied with a test signal TS of 100−35 = 65 dBμV.

  The receiver 12 detects the signal level of the received test signal TS (in this case, 65 dBμV) and demodulates the test signal TS to indicate the signal level set by the transmitter 11 (in this case, 70 dBμV). Information is extracted from the test signal TS. The receiver 12 subtracts the signal level (70 dBμV in this case) of the test signal TS transmitted from the transmitter 11 from the signal level (65 dBμV in this case) of the received test signal TS, and the transmission loss of the receiving equipment 1 (In this case, -5 dB) is obtained. The receiver 12 displays the signal level of the received test signal TS (in this case, 65 dBμV) and the transmission loss of the receiving facility 1 (in this case, −5 dB) on the image display unit.

  When a high-frequency signal of 70 dBμV is supplied from the antenna 9 to the input terminal 2, if the signal level of the high-frequency signal at the terminal terminal 8 is within an allowable range (for example, 57 to 81 dBμV), the inspection result of the receiving facility 1 is “good. " In the above-described example, since the signal level (65 dBμV) of the test signal TS at the terminal 8 is within an allowable range (for example, 57 to 81 dBμV), the inspection result of the reception facility 1 is “good”. In this case, the 4K / 8K television broadcast can be viewed on the television receiver 10 at the same time as the 4K / 8K television broadcast is started.

  If the signal level of the test signal TS at the terminal 8 is smaller than an allowable range (for example, 57 to 81 dBμV), the inspection result of the reception facility 1 is “defective”. In this case, the reception facility 1 is checked. For example, if the old distributor 4 is used by mistake, the distributor 4 is replaced with a 4K / 8K television broadcast product. Alternatively, the booster 3 is replaced with a booster having a large gain.

  If the signal level of the test signal TS at the terminal 8 is higher than an allowable range (for example, 57 to 81 dBμV), the inspection result of the receiving facility 1 is “defective”. In this case, for example, the booster 3 is replaced with a booster having a small gain or the booster 3 is removed. Thereafter, the inspection is performed again as described above, and if the signal level of the test signal TS at the terminal 8 is within an allowable range (for example, 57 to 81 dBμV), the inspection result of the receiving facility 1 becomes “good” and the 4K / 8K TV It is ready to receive broadcasts.

  FIG. 3 is a front view showing the configuration of the transmitter 11 shown in FIG. In FIG. 3, the transmitter 11 includes a main body unit 20, an output terminal 11 a provided at the upper end of the main body unit 20, an image display unit 21 provided at an upper part in front of the main body unit 20, and a front surface of the main body unit 20. The operation part 22 provided in the center part of the.

  The output terminal 11a is connected to the input terminal 2 of the receiving equipment 1 to be inspected via a coaxial cable. The image display unit 21 includes an LCD (Liquid Crystal Display) on which a set frequency (MHz), a set signal level (dBμV), and the like are displayed. The operation unit 22 includes five buttons B1 to B5 and a cross key K1. Four buttons B1 to B4 are arranged at the four corners of the cross key K1, and one button B5 is arranged in the center hole of the cross key K1. A control unit and the like described later are accommodated in the main body unit 20. A battery serving as a power source for the transmitter 11 is accommodated in the lower end of the main body 20.

  The user of the transmitter 11 holds the lower part of the main body 20 with one hand, operates the operation unit 22 with the other hand while looking at the image display unit 21, and sets the frequency and signal level of the test signal TS. The test signal TS is transmitted.

  That is, when the power button B2 is pressed and held, the power is turned on and the built-in control unit and the like are initialized. When the power button B2 is pressed and held while the power is on, the power is turned off. When the mode button B1 is pressed while the power is on, the frequency mode and the channel mode are switched each time the mode button B1 is pressed, and characters indicating the mode blink on the screen of the image display unit 21. For example, when the determination button B5 is pressed while the frequency character is blinking, the frequency character is lit on the screen of the image display unit 21, and the frequency mode is determined. When the determination button B5 is pressed while the channel character is flashing, the channel character is lit on the screen of the image display unit 21, and the channel mode is determined.

  In the frequency mode, pressing the upper end (or right end) of the cross key K1 increases the frequency, and pressing the lower end (or left end) of the cross key K1 decreases the frequency. For example, when the decision button B5 is pressed while the character of 3224 MHz is blinking on the screen of the image display unit 21, the character of 3224 MHz is lit and the selection of 3224 MHz is decided.

  In the channel mode, pressing the upper end (or right end) of the cross key K1 increases the channel number, and pressing the lower end (or left end) of the cross key K1 decreases the channel number. For example, when the character Xch (where X is a positive integer) is blinking on the screen of the image display unit 21 and the determination button B5 is pressed, the character Xch lights up and the selection of Xch is determined. The Xch is a channel broadcast using the highest frequency band in 4K / 8K television broadcasting.

  When the signal level setting button B3 is pressed, characters indicating the signal level blink on the screen of the image display unit 21. When the determination button B5 is pressed while the signal level character is blinking, the signal level character is lit on the screen of the image display unit 21, and the signal level can be set. Pressing the upper end (or right end) of the cross key K1 increases the signal level, and pressing the lower end (or left end) of the cross key K1 decreases the signal level.

  After the frequency is set, pressing the enter button B5 while the character of the desired signal level (for example, 70 dBμV) is flashing has the set frequency (for example, 3224 MHz) and the set signal level (70 dBμV). The test signal TS on which the information indicating the set signal level (70 dBμV) is superimposed is output from the output terminal 11a.

  After the channel is set, when the character of a desired signal level (for example, 70 dBμV) is flashing and the decision button B5 is pressed, for example, the frequency of the set channel (for example, Xch) and the set signal level (70 dBμV) ), And a test signal TS on which information indicating a set signal level (70 dBμV) is superimposed is output from the output terminal 11a.

  FIG. 4 is a circuit block diagram showing a configuration of the transmitter 11. 4, the transmitter 11 includes an image display unit 21, an operation unit 22, a control unit 23, a memory 24, a PLL (Phase Locked Loop) / FSK modulation unit 25, a crystal oscillator 26, a voltage controlled oscillator (VCO). ) 27, amplifiers 28 and 34, switches 29 and 33, band pass filters (BPF) 30 to 32, branching unit 35, capacitor 36, reactor 37, level monitor 38, level control unit 39, and output terminal 11a including.

  The operation unit 22 outputs a signal indicating the operation result of the five buttons B1 to B5 and the cross key K1. The control unit 23 controls the entire transmitter 11 according to a signal from the operation unit 22. The control unit 23 stores the frequency set using the operation unit 22 and the set signal level in the memory 24, displays them on the image display unit 21, and gives them to the PLL / FSK modulation unit 25. The frequency set using the operation unit 22 includes a frequency set in the frequency mode and a channel frequency set in the channel mode.

  The crystal oscillator 26 is, for example, a temperature compensation type oscillator, and generates a clock signal having a reference frequency. The PLL / FSK modulation unit 25 operates in synchronization with the clock signal from the crystal oscillator 26, generates a control voltage, and supplies it to the voltage controlled oscillator 27. The PLL / FSK modulation unit 25 sets the level of the control voltage according to the set frequency. Further, the PLL / FSK modulator 25 modulates the control voltage according to the set signal level, thereby superimposing information indicating the set signal level on the control voltage. Therefore, the control voltage includes information indicating the set frequency and information indicating the set signal level.

  The voltage controlled oscillator 27 outputs a high frequency signal having a frequency corresponding to the control voltage. The amplifier 28 amplifies the high frequency signal from the voltage controlled oscillator 27. The high frequency signal amplified by the amplifier 28 is fed to the switch 29 and fed back to the PLL / FSK modulation unit 25. The PLL / FSK modulation unit 25 adjusts the control voltage so that the phase of the fed back high-frequency signal matches the phase of the clock signal of the reference frequency.

  The switches 29 and 33 are controlled by the control unit 23 and connect between the amplifiers 28 and 34 a band pass filter selected according to the frequency of the test signal TS among the three band pass filters 30 to 32. The selected band pass filter removes unnecessary frequency components from the high frequency signal from the amplifier 28. The high frequency signal that has passed through the switch 29, the selected bandpass filter, and the switch 33 is provided to the amplifier 34.

  The gain of the amplifier 34 can be controlled and is controlled by the level control unit 39. The amplifier 34 amplifies the high frequency signal from the switch 33 with a gain controlled by the level control unit 39. The branching unit 35 divides the high-frequency signal from the amplifier 34 into a test signal TS and a monitor signal. The test signal TS is given to the output terminal 11a via the capacitor 36. The monitor signal is given to the level monitor 38.

  The capacitor 36 is provided to cut off the DC voltage. The reactor 37 is connected between the output terminal 11a and the control unit 23, cuts off the high-frequency signal, and passes the DC voltage. The reactor 37 is provided, for example, for inspecting whether or not a DC voltage can be supplied from the terminal terminal 8 to the input terminal 2. When the DC voltage applied to the terminal terminal 8 of the receiving facility 1 is transmitted to the control unit 23 via the input terminal 2, the output terminal 11 a, and the reactor 37, the control unit 23 transmits DC from the terminal terminal 8 to the input terminal 2. It is determined that a voltage can be supplied.

  The level monitor 38 detects the signal level of the monitor signal from the branching device 35 and gives a signal indicating the detected value to the control unit 23. The control unit 23 generates a control signal so that the signal level detected by the level monitor 38 becomes a level corresponding to the set signal level. The level control unit 39 controls the gain of the amplifier 34 according to the control signal from the control unit 23. In this way, the test signal TS having the set signal level and the set frequency and on which the information indicating the set signal level is superimposed is generated.

  FIG. 5 is a front view showing the configuration of the receiver 12 shown in FIG. In FIG. 5, the receiver 12 includes a main body unit 50, an input terminal 12 a provided at the upper end of the main body unit 50, an image display unit 51 provided at an upper part in front of the main body unit 50, and a front surface of the main body unit 50. The operation part 52 provided in the center part of the.

  The input terminal 12a is connected to the terminal terminal 8 of the receiving equipment 1 to be inspected via a coaxial cable. The image display unit 51 includes an LCD, and a set frequency (MHz), a signal level of the received test signal TS (dBμV), a transmission loss (dB), and the like are displayed on the screen. The operation unit 52 includes five buttons B11 to B15 and a cross key K11. Four buttons B11 to B14 are arranged at the four corners of the cross key K11, and one button B15 is arranged in the central hole of the cross key K11. The main body unit 50 accommodates a control unit and the like which will be described later. A battery serving as a power source for the receiver 12 is accommodated in the lower end of the main body 50.

  The user of the receiver 12 holds the lower part of the main body 50 with one hand, operates the operation unit 52 with the other hand while looking at the image display unit 51, sets the frequency of the test signal TS, etc. A signal TS is received.

  That is, when the power button B12 is pressed and held, the power is turned on and the built-in control unit and the like are initialized. When the power button B12 is pressed and held while the power is on, the power is turned off. When the mode button B11 is pressed while the power is on, the frequency mode, the channel mode, and the transmission test mode are switched in turn each time the mode button B11 is pressed, and characters indicating the mode blink on the screen of the image display unit 51.

  For example, when the determination button B15 is pressed while the frequency character is blinking, the frequency character is lit on the screen of the image display unit 51, and the frequency mode is determined. In the frequency mode, pressing the upper end (or right end) of the cross key K11 increases the frequency, and pressing the lower end (or left end) of the cross key K11 decreases the frequency. For example, when the decision button B15 is pressed while the character of 3224 MHz is blinking on the screen of the image display unit 51, the character of 3224 MHz is lit and the selection of 3224 MHz is decided.

  When the determination button B15 is pressed while the channel character is flashing, the channel character is lit on the screen of the image display unit 21, and the channel mode is determined. In channel mode, pressing the upper end (or right end) of the cross key K11 increases the ch number, and pressing the lower end (or left end) of the cross key K11 decreases the ch number. For example, if the determination button B15 is pressed while the character Xch is blinking on the screen of the image display unit 51, the character 13ch is lit and the selection of Xch is determined.

  When the decision button B15 is pressed while the character of the transmission test is blinking, the character of the transmission test is lit on the screen of the image display unit 21, the transmission test mode is decided, and the signal level of the received test signal TS, The detected transmission loss is displayed on the screen of the image display unit 51.

  Note that the signal quality can be switched by pressing the left end of the cross key K11, and the volume can be switched by pressing the right end of the cross key K11. The detection result can be stored by pressing the button B13, and the voltage can be measured by pressing the button B14.

  FIG. 6 is a circuit block diagram showing the configuration of the receiver 12. In FIG. 6, a capacitor 53, a tuner IC 54, a demodulator 55, an oscillator 56, and a control unit 57 are accommodated in the main body 50 of the receiver 12.

  The test signal TS given from the transmitter 11 to the input terminal 12 a via the receiving facility 1 is given to the tuner IC 54 via the capacitor 53. The capacitor 53 is provided to cut off the DC voltage. As shown in FIG. 7, the tuner IC 54 includes an amplifier 60, a local oscillator 61, a mixer circuit 62, a band pass filter 63, and a control signal generation unit 64.

  The amplifier 60 amplifies the test signal TS with a gain corresponding to the automatic gain control signal AGC from the demodulator 55. The local oscillator 61 generates a local oscillation signal having a frequency corresponding to the control signal CNT1 from the control signal generation unit 64. The mixer circuit 62 mixes the test signal TS from the amplifier 60 and the local oscillation signal from the local oscillator 61 to generate an intermediate frequency signal IF. As a result, the test signal TS having the frequency selected by the operation unit 52 is converted into an intermediate frequency signal IF having a predetermined frequency band. The frequency selected by the operation unit 52 includes the frequency of the channel selected by the operation unit 52.

  The bandwidth of the band-pass filter 63 can be changed to a desired frequency width, and is set by the control signal CNT2 from the control signal generator 64. The band pass filter 63 passes only the signal component having the set frequency width in the intermediate frequency signal IF in the predetermined frequency band.

  The control signal generator 64 generates the control signals CNT1 and CNT2 based on the clock signal SCL and the data signal SCA supplied from the demodulator 55. The control signals CNT1 and CNT2 are supplied to the local oscillator 61 and the band pass filter 63, respectively. For example, when 3224 MHz is set using the operation unit 52, the test signal TS of 3224 MHz is converted into an intermediate frequency signal IF of a predetermined frequency band, and the band of the set frequency width of the intermediate frequency signal IF is set. Only the signal component passes through the band-pass filter 63.

  Returning to FIG. 6, the demodulator 55 operates in synchronization with the clock signal generated by the oscillator 56. The demodulator 55 transmits the clock signal SCL and the data signal SCA to the tuner IC 54 and controls the tuner IC 54. Further, the demodulator 55 generates an automatic gain control signal AGC so that the signal level of the intermediate frequency signal IF from the tuner IC 54 becomes a predetermined signal level, feeds back to the tuner IC 54, and controls the automatic gain control signal AGC. Part 57 is given.

  Further, the demodulator 55 extracts information indicating the set signal level by demodulating the intermediate frequency signal IF from the tuner IC 54. The demodulator 55 supplies the information indicating the extracted signal level or the like as the data signal SCA to the control unit 57 in synchronization with the clock signal SCL. The control unit 57 is constituted by, for example, a microcomputer including a CPU (Central Processing Unit) and a memory.

  The control unit 57 controls the entire receiver 12 according to a signal from the operation unit 52. In particular, the control unit 57 transmits a clock signal SCL and a data signal SCA to the image display unit 51 according to a signal from the operation unit 52 to display an image. The control unit 57 detects the signal level of the actually received test signal TS based on the automatic gain control signal AGC from the demodulator 55 and causes the image display unit 51 to display the signal level.

  The control unit 57 detects the signal level of the test signal TS set by the transmitter 11 based on the data signal SCA from the demodulator 55 and causes the image display unit 51 to display the signal level. Based on the signal level of the test signal TS actually received and the signal level of the test signal TS set by the transmitter 11, the control unit 57 obtains the transmission loss of the receiving facility 1 and images the obtained transmission loss. It is displayed on the display unit 51.

  As described above, in this embodiment, the transmitter 11 is connected to the input terminal 2 of the receiving facility 1, and the receiver 12 is connected to the terminal terminal 8, so that the transmitter 11 can be used for 4K / 8K television broadcasting. A frequency test signal TS is transmitted, and the receiver 12 detects the signal level of the test signal TS. Therefore, even when the 4K / 8K television broadcast is not yet implemented, it is possible to determine whether the reception facility 1 can receive the 4K / 8K television broadcast.

  If the signal level of the test signal TS received by the receiver 12 is lower than the desired signal level as a result of inspecting the receiving facility 1 using the inspection system of the present embodiment, the distributor 4, the branching unit 6, etc. Since there is a possibility that a product for 2K television broadcasting is used by mistake, it is preferable to confirm whether or not the distributor 4, the branching device 6 and the like are for 4K / 8K television broadcasting.

  When renewing an existing receiving equipment for 4K / 8K television broadcasting, check whether the existing coaxial cable can be used by inspecting the receiving equipment 1 using the inspection system of this embodiment. can do. Further, by inspecting the receiving facility 1 using the inspection system of the present embodiment, whether or not the booster 3 is necessary and whether or not it is better to replace the booster 3 with a high gain booster or a low gain booster. Can be determined.

  In addition, information indicating the set signal level is transmitted by being superimposed on the test signal TS, and information indicating the signal level is extracted from the test signal on the receiving side, so when changing the signal level of the test signal TS, It is sufficient to change the signal level on the transmitter 11 side, and there is no need to change the signal level on the receiver 12 side. Therefore, the signal level of the test signal TS can be easily changed.

  In this embodiment, the signal level of the received test signal TS and the transmission loss of the inspected receiving equipment 1 are displayed on the image display unit 51 of the receiver 12. However, the present invention is not limited to this. Instead of this, a signal level indicated by information extracted from the test signal TS may be displayed on the image display unit 51. Further, the signal level of the received test signal TS, the transmission loss of the inspected receiving equipment 1, and the signal level indicated by the information extracted from the test signal TS may be displayed on the image display unit 51.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  1 receiving equipment, 2 input terminals, 3 boosters, 4 distributors, 5,7 coaxial cable, 6,35 branching device, 8 terminal terminals, 9 antenna, 10 TV receiver, 11 transmitter, 11a output terminal, 12 receiver , 12a input terminal, 20, 50 main unit, 21, 51 image display unit, 22, 52 operation unit, B1-B5, B11-B15 buttons, K1, K11 cross keys, 23, 57 control unit, 24 memory, 25 PLL / FSK modulator, 26 crystal oscillator, 27 voltage controlled oscillator, 28, 34, 60 amplifier, 29, 33 switch, 30-32, 63 band pass filter, 36, 53 capacitor, 37 reactor, 38 level monitor, 39 level control 54 tuner IC 55 demodulator 56 oscillator 61 local oscillator 62 mixer circuit 64 Control signal generator.

Claims (9)

An inspection system for inspecting a receiving facility having an input terminal and a terminal terminal,
A transmitter and a receiver respectively connected to the input terminal and the terminal terminal when inspecting the receiving facility;
The transmitter has a set first signal level and a set frequency, and outputs a test signal superimposed with information indicating the first signal level to the input terminal,
The first signal level of the test signal is reduced to a second signal level due to transmission loss of the receiving facility;
The receiver receives the test signal from the terminal terminal, detects the second signal level of the received test signal, and extracts information indicating the first signal level from the received test signal. , Inspection system.   The inspection system according to claim 1, wherein the receiver calculates the transmission loss based on the detected second signal level and the extracted information indicating the first signal level.   The inspection system according to claim 2, wherein the receiver includes an image display unit that displays the transmission loss.   The inspection system according to claim 2, wherein the receiver includes an image display unit that displays the detected second signal level and the transmission loss. The transmitter is
An operation unit for setting each of the first signal level and the frequency;
A signal generation unit that superimposes information indicating the first signal level set using the operation unit on a signal of the frequency set using the operation unit;
An amplifier for amplifying the signal generated by the signal generator and generating the test signal having the first signal level set using the operation unit;
The receiver
A demodulator for extracting information indicating the first signal level from the test signal received from the terminal terminal;
Detecting the second signal level of the test signal received from the terminal terminal, based on the detected second signal level and information indicating the first signal level extracted by the demodulator, A control unit for obtaining the transmission loss;
The inspection system according to claim 2, further comprising an image display unit that displays the transmission loss obtained by the control unit.   The inspection system according to claim 5, wherein the image display unit further displays the second signal level detected by the control unit. The receiving facility is a facility for receiving satellite broadcasting,
The inspection system according to any one of claims 1 to 6, wherein after the reception facility is inspected, the input terminal is connected to an antenna, and the terminal terminals are connected to a television receiver.   The inspection system according to any one of claims 1 to 7, wherein the reception facility includes a booster connected between the input terminal and the terminal terminal and amplifying a signal from the input terminal. The receiving facility is a facility for receiving at least one of 4K television broadcasting and 8K television broadcasting,
The inspection system according to any one of claims 1 to 8, wherein the frequency of the test signal can be set to 3224 MHz.

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