JP4041584B2 - Satellite reception system and reception signal mixer - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a satellite reception system including a CS antenna that receives two types of radio waves transmitted from a communication satellite and having different polarization planes, and a BS antenna that receives a transmission radio wave from a broadcasting satellite, and the system The present invention relates to a reception signal mixer suitable for mixing reception signals from antennas.
[0002]
[Prior art]
Conventionally, as a CS antenna that receives transmission radio waves from a communication satellite (hereinafter also simply referred to as CS), two types of radio waves with orthogonal polarization planes transmitted from CS, or two types with different directions of rotation of polarization planes, are used. It is known that can receive radio waves.
[0003]
For example, when this type of CS antenna receives a first voltage signal (generally DC 11V) that serves both as polarization switching and power supply at the output terminal of the received signal, the vertical polarization of two orthogonally polarized waves is received. When a radio wave of a wave is converted into a CS received signal of a predetermined frequency band and output, and a second voltage signal (generally DC 15V) that serves both as polarization switching and power supply is received at the output terminal of the received signal, A CS converter is provided that converts horizontally polarized radio waves into a CS received signal in a predetermined frequency band and outputs the CS received signal.
[0004]
The polarization switching operation of this CS converter is for a general CS antenna that receives radio waves of two orthogonal polarizations. For example, in a CS antenna that receives circularly polarized radio waves with different turning directions, When receiving a right-handed circularly polarized wave, DC 13V is supplied to the CS converter as a first voltage signal, and when receiving a left-handed circularly polarized wave, a direct current is supplied as a second voltage signal. 18V is supplied to the CS converter.
[0005]
On the other hand, BS antennas that receive transmission radio waves from broadcast satellites (hereinafter also simply referred to as BS) have been known. The BS antenna normally operates by receiving a direct current of 15 V as a power supply voltage signal at a reception signal output terminal, and converts a transmission signal from a broadcasting satellite into a BS reception signal of a predetermined frequency band and outputs it. A BS converter is provided.
[0006]
[Problems to be solved by the invention]
By the way, generally, when a plurality of receiving antennas such as a VHF antenna and a UHF antenna are installed outdoors, and a reception signal from each receiving antenna is transmitted to a terminal device such as a television receiver installed indoors, Is received by a mixer (so-called mixer) provided in the vicinity of the antenna, and the mixer and the indoor terminal device are connected by a single transmission line (usually a coaxial cable is used). I am doing so.
[0007]
However, when the CS antenna and the BS antenna are installed outdoors, it is necessary to supply different voltage signals from the terminal side to the converter of each antenna in order to obtain reception signals from these antennas simultaneously. Yes, the received signal from each antenna could not be drawn indoors using a single transmission line.
[0008]
In other words, a CS tuner that receives a signal received from the CS antenna has a function of outputting two kinds of voltage signals for switching the polarization plane to the CS antenna, and a BS tuner that receives the signal received from the BS antenna or a BS tuner built-in. A TV has a function of outputting a voltage signal for driving a BS converter to the BS antenna side. However, when each terminal device is connected to the CS antenna and the BS antenna by a single transmission line, The voltage signal for driving each converter is mixed on this transmission line, so that the polarization plane switching of the CS antenna cannot be normally performed. For this reason, conventionally, when a CS antenna and a BS antenna are installed outdoors and a reception signal from each antenna is transmitted to an indoor terminal device, the indoor terminal device and the converter of each antenna are Each was connected using a dedicated transmission line.
[0009]
Therefore, in the facility where the CS antenna and the BS antenna are installed outdoors, there is a problem that the wiring work of the transmission line is troublesome.
The present invention has been made in view of these problems, and in a facility where both a CS antenna and a BS antenna are installed, a reception signal from each of these antennas can be transmitted to the terminal side using a single transmission line. It is an object of the present invention to provide a satellite reception system and a reception signal mixer suitable for use in the system.
[0010]
[Means for Solving the Problems and Effects of the Invention]
In the satellite reception system according to claim 1, which is made to achieve the above object, two types of radio waves transmitted from a communication satellite and having different polarization planes are respectively converted into a first polarization signal and a second polarization signal. When the first voltage signal for both polarization switching and power supply is received at the output terminal of the received signal to the terminal side, the first polarized signal is received as a CS received signal in a predetermined frequency band. When the second voltage signal for both polarization switching and power supply, which is set to a voltage higher than the first voltage signal at the output terminal, is output from the output terminal to the terminal side after frequency conversion to A CS antenna having a CS converter that converts the second polarization signal into a CS reception signal in a predetermined frequency band and outputs the CS reception signal from the output terminal to the terminal side; receives a transmission radio wave from a broadcasting satellite; Supply power to the received signal output terminal When receiving a voltage signal, and a BS antenna with a BS converter output from the output terminal performs frequency conversion of a transmission signal to the BS reception signal in a predetermined frequency band from a satellite broadcasting the received terminal side. And the input terminal of a mixer is connected to the output terminal of a CS converter and the output terminal of a BS converter, respectively, and the received signal from each converter is mixed in a mixer.
[0011]
The reception signal mixed by the mixer is transmitted from the output terminal of the mixer to the duplexer via one transmission line. The demultiplexer demultiplexes the received signal transmitted via the transmission line into a CS received signal and a BS received signal, and outputs the demultiplexed signal to each received signal demodulation terminal device. As a result, the received signals from the CS antenna and the BS antenna are transmitted to each terminal device for demodulating the received signals.
[0012]
On the other hand, on the transmission path for transmitting the CS reception signal output from the mixer to the terminal device for demodulating the CS reception signal, at least a CS converter and a BS converter according to the polarization switching signal output from the terminal device There is provided a power supply device that generates a first voltage signal or a second voltage signal having an amount of electric power sufficient to operate and outputs the first voltage signal to the mixer side. The duplexer outputs the signal received from the terminal device side for demodulating the CS received signal to the mixer side, and the mixer outputs the voltage signal received at the output terminal from each input terminal to the output terminal of each converter. Output.
[0013]
Therefore, the CS converter operates by receiving the first voltage signal or the second voltage signal supplied from the mixer side, and the signal of the polarization plane corresponding to the voltage signal (the first polarization signal or the second voltage signal). Frequency) to a CS reception signal in a predetermined frequency band and output from the output terminal to the terminal side, and the BS converter operates by receiving the voltage signal supplied from the mixer side, and broadcasts. The transmission radio wave from the satellite is frequency-converted into a BS signal in a predetermined frequency band and output from the output terminal to the terminal side.
[0014]
Further, in the present invention, the CS converter and the BS converter have local oscillation used for frequency conversion of each received signal. As a signal About the same frequency Signal It is intended to be used.
This is the conventional frequency conversion for the CS converter. Local oscillation signal frequency (local oscillation frequency) When the local oscillation frequency for frequency conversion in the 11.2 GHz and BS converter is 10.678 GHz, the frequency band of the CS reception signal obtained by converting the transmission radio wave from the communication satellite launched in Japan by the CS converter, This is because the frequency band of the BS reception signal obtained by frequency conversion of the transmission radio wave from the broadcasting satellite by the BS converter overlaps, and it becomes impossible to transmit each reception signal through one transmission line.
That is, in the present invention, each of these converters Of local oscillation signal used for frequency conversion in By setting the frequencies to substantially the same frequency, the frequency bands of the reception signals output from the converters are shifted so that the reception signals can be mixed and transmitted through a single transmission line.
[0015]
Therefore, according to the present invention, in a satellite reception system equipped with a CS antenna and a BS antenna, a received signal from each converter is transmitted to the terminal side using one transmission line while operating the converter of each antenna normally. Thus, the wiring work for connecting each antenna and the terminal device can be easily performed.
[0016]
Here, in the satellite reception system according to claim 1, when the BS converter is configured to operate by receiving the second voltage signal as a voltage signal for power supply, the CS converter includes a first one. If the first voltage signal having a voltage lower than that of the second voltage signal is output from the power supply device in order to frequency-convert the polarized signal, the BS converter does not operate normally.
[0017]
Therefore, when the BS converter is configured in this way, as described in claim 2, the voltage signal received at the output terminal of the mixer is the first voltage signal, the second voltage signal. In any case, a second voltage signal for driving the BS converter is generated from this voltage signal, and the generated second voltage signal is transferred from the input terminal connected to the BS converter to the output terminal of the BS converter. A constant voltage circuit for outputting may be provided. In other words, in this way, even if the BS converter is configured to operate with the second voltage signal, the BS converter can always operate normally.
[0018]
On the other hand, in the satellite reception system according to claim 1, the BS converter operates as a frequency conversion unit that converts a transmission signal from satellite broadcasting into a BS reception signal in a predetermined frequency band, receiving the second voltage signal. When the frequency converter is provided and the mixer is configured to output the voltage signal received at the output terminal as it is from each input terminal connected to the output terminal of the CS converter and the BS converter, 3, the BS converter can drive the frequency converter from the voltage signal regardless of whether the voltage signal from the mixer received at the output terminal is the first voltage signal or the second voltage signal. A constant voltage circuit that generates the second voltage signal and supplies the second voltage signal to the frequency converter may be provided.
[0019]
Next, the present invention can be applied not only to two antennas, a CS antenna and a BS antenna, but also to a satellite reception system including other reception antennas such as a VHF antenna and a UHF antenna. In such a system, the mixer may be configured as described in claim 4.
[0020]
That is, in the satellite reception system according to claim 4, the mixer receives one or a plurality of signals for receiving reception signals from other reception antennas separately from the reception signals from the converters of the CS antenna and the BS antenna. An input terminal is provided, and all reception signals from other reception antennas input to the input terminal and reception signals from the converters are mixed and output from the output terminal. Therefore, according to the satellite reception system of the fourth aspect, not only the CS reception signal and the BS reception signal but also the reception signals from other reception antennas such as a VHF antenna and a UHF antenna can be transmitted through one transmission line. Can be transmitted to the terminal side via the cable, and the wiring work of the transmission line can be performed more easily.
[0021]
Further, in the satellite reception system according to any one of claims 1 to 4, the mixer receives at least one of the reception signals input from the respective input terminals, as described in claim 5, to the other reception. An amplifier circuit that amplifies the signal before mixing with the signal may be incorporated. If the mixer is configured in this way, it is possible to amplify a part or all of the received signal rather than simply mixing the received signal input from each input terminal. In a system in which signal attenuation is large or a system in which each received signal is distributed to a plurality of terminal devices on the terminal side, each received signal can be supplied to the terminal device while maintaining a predetermined level or higher. Become.
[0022]
In the satellite reception system according to any one of claims 1 to 5 described above, the reception signal transmitted via the transmission line is used instead of the duplexer as described in claim 6. A distributor that distributes a plurality of signals and outputs them to the terminal device for demodulating each received signal may be provided.
[0023]
Next, in the satellite reception system having the above-described CS antenna and BS antenna, the invention described in claims 7 to 9 is for mixing the reception signals output from each converter and outputting them to the terminal side. It is an invention relating to a suitable received signal mixer.
And in the reception signal mixer according to claim 7, the mixing circuit mixes the reception signal from each converter input to the input terminal, and outputs the mixed reception signal from the output terminal to the terminal side, The voltage signal output circuit sends the first voltage signal or the second voltage signal for both polarization switching and power supply transmitted from the terminal side to the output terminal to the input terminal side that receives the CS reception signal from the CS converter. This voltage is output as it is, regardless of whether the voltage signal for both polarization switching and power supply transmitted from the terminal side to the output terminal is the first voltage signal or the second voltage signal. A second voltage signal for driving the BS converter is generated from the signal, and the generated second voltage signal is output to an input terminal that receives a BS reception signal from the BS converter.
[0024]
That is, the reception signal mixer according to claim 7 is an optimum mixer for constructing the satellite reception system according to claim 2, and as described above, the BS converter uses the second voltage signal. Even if it is configured to operate, it is possible to transmit the reception signals from the CS converter and the BS converter to the terminal side using one transmission line while always operating the BS converter normally.
[0025]
Next, a reception signal mixer according to claim 8 is configured to further add a reception signal from another reception antenna to the reception signal mixer according to claim 7, in addition to the reception signal output from each converter. Provide one or a plurality of input terminals for input, mix all received signals from other receiving antennas input to this input terminal and received signals from each converter, and output from the output terminal to the terminal side It is comprised as follows.
[0026]
That is, this reception signal mixer is an optimum mixer for constructing the satellite reception system according to claim 4, and includes not only the CS reception signal and the BS reception signal, but also other VHF antennas, UHF antennas, and the like. A reception signal from the reception antenna can also be transmitted to the terminal side through one transmission line.
[0027]
Next, the reception signal mixer according to claim 9 is the reception signal mixer according to claim 7 or claim 8, wherein at least one of the reception signals input from each input terminal is replaced with another reception signal. An amplifying circuit for amplifying before mixing is built in.
Therefore, this reception signal mixer is an optimum mixer for constructing the satellite reception system according to claim 5, and is a system in which the transmission line from the mixer to the terminal is long and attenuation of the reception signal is large. In a system in which each received signal is distributed to a plurality of terminal devices on the terminal side, each received signal can be supplied to the terminal device while being held at a predetermined level or higher.
[0028]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a schematic configuration diagram showing the overall configuration of a satellite receiving system according to an embodiment to which the present invention is applied.
[0029]
As shown in FIG. 1, in the satellite reception system of this embodiment, each reception signal (CS reception signal, BS reception signal) from the CS antenna 2 and the BS antenna 4 installed outdoors is installed indoors in a general household. This is a receiving system for transmitting up to a CS tuner 14 and a BS tuner built-in television (TV: hereinafter simply referred to as a television) 16.
[0030]
The CS antenna 2 is an offset parabolic antenna that receives orthogonal two-polarized transmission radio waves transmitted from a communication satellite (CS), and the focal position of the reflecting mirror 2a via a reflecting mirror 2a and a support arm (not shown). And CS converter 2b arranged in The CS converter 2b is operated by a voltage signal for both polarization switching and power supply input from the terminal side to the output terminal of the received signal, and the orthogonally polarized two waves from the CS collected by the reflecting mirror 2a. The transmission radio wave is received as the first polarization signal and the second polarization signal, respectively, and either the first polarization signal or the second polarization signal is received according to the voltage signal input to the output terminal. One of these is selected, and the selected polarization signal is received by a CS in a predetermined frequency band (specifically, 1572 to 2072 MHz) using a local oscillation signal Lo having a frequency of 10.678 GHz generated by a local oscillator (not shown). It is converted into a signal (CS / IF shown in the figure) and output.
[0031]
In the present embodiment, when the CS converter 2b receives 11 VDC from the output terminal as the first voltage signal, the CS received signal obtained by frequency-converting the vertical polarization signal as the first polarization signal is output from the output terminal. When a DC voltage of 15 V is received as the second voltage signal at the output terminal, a CS reception signal obtained by frequency-converting the horizontal polarization signal as the second polarization signal is output from the output terminal.
[0032]
The BS antenna 4 is an offset parabolic antenna that receives transmission radio waves from a broadcasting satellite (BS). The BS antenna 4 is disposed at the focal position of the reflecting mirror 4a via a reflecting mirror 4a and a support arm (not shown). And a converter 4b. The BS converter 4b is operated by a power supply voltage signal (DC 15V in this embodiment) input to the reception signal output terminal from the terminal side, and transmitted from the BS collected by the reflecting mirror 4a. Using a local oscillation signal Lo having a frequency of 10.678 GHz generated by a local oscillator (which is the same as that incorporated in the CS converter 2b) that receives a radio wave and is not shown, a predetermined frequency band (specifically, 1035 to 1335 MHz) BS received signal (BS · IF shown in the figure) and output.
[0033]
Next, the output terminals of the converters 2b and 4b are connected to input terminals TCS and TBS (see FIG. 3) of a mixer (hereinafter referred to as a mixer) 10 via coaxial cables, respectively. , 4b, the CS reception signal and the BS reception signal are mixed by the mixer 10 and output from the output terminal TMO (see FIG. 3) of the mixer 10 to the terminal side. The configuration of the mixer 10 will be described later.
[0034]
The output terminal TMO of the mixer 10 is connected to the input terminal of the duplexer 12 installed indoors via one coaxial cable as a transmission line. The demultiplexer 12 is for demultiplexing the received signal transmitted from the mixer 10 via the coaxial cable into a CS received signal and a BS received signal. The demultiplexed CS received signal is coaxial cable. The BS reception signal is output to the TV tuner 16 via a coaxial cable.
[0035]
Furthermore, a power supply device 20 is provided on the transmission path (coaxial cable) of the CS reception signal from the duplexer 12 to the CS tuner 14. As shown in FIG. 2, the power supply device 20 is provided with an input terminal TIN and an output terminal Tout for a CS reception signal, and the CS reception of the duplexer 12 is connected to the input terminal TIN via a coaxial cable. A signal output terminal is connected, and the output terminal TOUT is connected to a CS reception signal input terminal of the CS tuner 14 via a coaxial cable.
[0036]
The CS tuner 14 receives two kinds of voltage signals for polarization switching / power supply to the CS antenna 2 from the input terminal of the CS reception signal according to instructions from the user (11 V DC, horizontal deviation when receiving vertical polarization). This is a general CS tuner configured to selectively output one of DC 15V when receiving a wave).
[0037]
The duplexer 12 is a so-called current passing type, and inputs a voltage signal (specifically, a DC 11V or 15V signal output from the power supply device 20) to the CS reception signal output terminal from the terminal side. It has a function of bypassing to the side (by extension, the side of the mixer 10 connected via a coaxial cable).
[0038]
Next, the configuration of the power supply device 20 will be described in detail.
As shown in FIG. 2, the power supply device 20 includes a power transformer 22 that transforms an AC voltage (for example, AC 100 V) from a commercial power input through an AC plug into a predetermined AC voltage (for example, AC 24 V), A full-wave rectifier circuit 24 that generates a DC power supply voltage by full-wave rectifying the AC voltage after transformation by the power transformer 22, and an output voltage from the full-wave rectifier circuit 24, receive a predetermined DC constant voltage (this embodiment) In this embodiment, a constant voltage circuit 26 for generating 15 VDC) and a DC constant voltage 15 V generated by the constant voltage circuit 26 are generated, and a constant voltage for generating a lower DC constant voltage (11 VDC in this embodiment) is received. Circuit 28.
[0039]
The constant voltage circuits 26 and 28 are voltage signals (DC 15V or DC) with sufficient electric energy (current capacity: about 400 to 500 mA) to operate the CS converter 2b of the CS antenna 2 and the BS converter 4b of the BS antenna 4 simultaneously. 11V), and is configured around 15V output and 11V output three-terminal regulators 26a and 28a, respectively. The constant voltage circuit 26 is provided with capacitors C2 and C3 and a choke coil L3 for stabilizing the output (DC 15V) from the three-terminal regulator 26a. The constant-voltage circuit 28 includes a three-terminal regulator 28a. Is provided with a capacitor C4 for stabilizing the output (DC 11V).
[0040]
Further, the power supply device 20 receives a CS reception signal inputted from the duplexer 12 to the input terminal TIN, and a capacitor for cutting off DC and low frequency signals and passing high frequency signals connected between the input terminal TIN and the output terminal TOUT. Outputs to the terminal (that is, CS tuner 14) from the output terminal TOUT via C1, and connects one end of the DC constant voltage (DC 11V or DC 15V) generated by the constant voltage circuit 26 or 28 to the input terminal TIN. The voltage is output from the input terminal TIN to the branching filter 12 side through the choke coil L2 for passing DC and low-frequency signals and blocking high-frequency signals, and further output from the CS tuner 14 and input to the output terminal TOUT. A signal (DC 11V or DC 15V) is taken inside through a choke coil L1 for DC / low-frequency signal passing and high-frequency signal blocking, one end of which is connected to the output terminal TOUT. Writing, power separation circuit 32 is provided.
[0041]
The voltage signal from the CS tuner 14 input via the choke coil L1 of the power source separation circuit 32 is input to the voltage determination circuit 34 as a polarization switching signal, and the voltage determination circuit 34 determines the polarization switching signal. From the voltage level, it is determined on the terminal side whether a received signal of vertical polarization or horizontal polarization is necessary.
[0042]
That is, the voltage determination circuit 34 includes a Zener diode D1 whose cathode is connected to the other end of the choke coil L1 via the resistor R2, and a collector which is connected to the choke coil L1 via the resistor R1 and the relay coil 30b of the relay 30. The NPN transistor TR1 is connected to the other end, the base is connected to the anode of the Zener diode D1, the ground is connected through the resistor R3, and the emitter is grounded as it is, and the polarization is transmitted through the choke coil L1. When the voltage level of the voltage signal input as the switching signal is equal to or higher than the determination voltage (for example, DC 13V) determined by the breakdown voltage of the Zener diode D1 and the resistance values of the resistors R2 and R3 (that is, horizontal polarization) When the received signal is required), the transistor TR1 is turned on and current is passed through the relay coil 30b. Conversely, when the voltage level of the voltage signal input through the choke coil L1 is lower than the determination voltage (that is, when a vertically polarized reception signal is required), the transistor TR1 is turned off, It operates so as to cut off the energization of the relay coil 30b.
[0043]
In addition, when the relay coil 30b is energized, the other end of the choke coil L2 of the power supply separation circuit 32 is connected to the output of the constant voltage circuit 26, and when the relay coil 30b is not energized, Is connected to the output of the constant voltage circuit 28.
[0044]
As a result, when the voltage signal for selecting the vertical polarization (DC 11 V) is output from the input terminal of the CS tuner 14, the transistor TR1 in the voltage determination circuit 34 is turned off, and the relay coil 30b is turned off. The energized state and the DC 11V voltage signal generated by the constant voltage circuit 28 are output to the branching filter 12 side. Conversely, the voltage signal for selecting the horizontal polarization (DC) is input from the input terminal of the CS tuner 14. 15V) is output, the transistor TR1 in the voltage determination circuit 34 is turned on, the relay coil 30b is energized, and the DC 15V voltage signal generated by the constant voltage circuit 26 is demultiplexed. Will be output to the device 12 side. The voltage signal is transmitted to the output terminal TMO of the mixer 10 via the duplexer 12 and the coaxial cable.
[0045]
On the other hand, the mixer 10 is configured as shown in FIG. 3, and the voltage signal (DC 11V or DC 15V) transmitted from the power supply device 20 to the output terminal TMO via the duplexer 12 and the coaxial cable is used as it is. The CS received signal is output from the input terminal TCS to the CS converter 2b, and the BS received signal input terminal TBS to the BS converter 4b receives a voltage signal transmitted from the power supply device 20 of DC 11V or DC 15V. Even so, a DC 15V for driving the BS converter 4b is generated and output from this voltage signal.
[0046]
That is, in the mixer 10, the CS reception signal input to the input terminal TCS from the CS converter 2b side passes through the high-pass filter (HPF) 42 that passes the CS reception signal and blocks the BS reception signal to the output terminal TMO. The BS received signal transmitted and inputted to the input terminal TBS from the BS converter 4b side passes the DC and low frequency signal blocking / high frequency signal passing capacitor C12, the BS received signal and the low pass filter for blocking the CS received signal ( LPF) 44 and the DC and low frequency signal cutoff / high frequency signal passing capacitor C11 are led to the output terminal TMO.
[0047]
As a result, the CS reception signal input to the input terminal TCS and the BS reception signal input to the input terminal TBS are mixed with each other and output from the output terminal TMO. The high-pass filter 42, the capacitor C12, the low-pass filter 44, and the capacitor C11 function as a mixing circuit according to claim 7.
[0048]
Further, a choke coil L10 for DC and low-frequency signal passing / high-frequency signal cut-off is connected in parallel to the high-pass filter 42 for CS reception signal transmission. The choke coil L10 causes the power terminal 20 to output terminal TMO. The voltage signal (DC 11V or DC 15V) transmitted to is directly output from the input terminal TCS to the CS converter 2b.
[0049]
As a result, the CS converter 2b outputs a CS reception signal obtained by frequency-converting the polarization signal (vertical polarization signal or horizontal polarization signal) corresponding to this voltage signal, and the CS tuner 14 is requested by the user. A received signal on the plane of polarization is transmitted. The choke coil L10 functions as a voltage signal output circuit according to claim 7.
[0050]
Next, a BS reception signal transmission path including capacitors C11 and C12 and a low-pass filter 44 is connected to a DC-DC converter 46 via DC and low-frequency signal passing / high-frequency signal blocking choke coils L11 and L12. Are connected in parallel. The DC-DC converter 46 takes in the voltage signal (DC 11V or DC 15V) transmitted from the power supply device 20 to the output terminal TMO via the choke coil L11, and uses the voltage signal to drive the BS converter 4b. And a voltage signal of DC 15 V is supplied from the input terminal TBS to the BS converter 4b by outputting the generated voltage signal to the input terminal TBS via the choke coil L12. It functions as the described constant voltage circuit. As the DC-DC converter 46, in order to efficiently generate a direct current of 15 V, for example, a DC power converter configured with a chopper circuit used as a so-called power conversion circuit may be used.
[0051]
As a result, DC 15V is always supplied to the BS converter 4b regardless of the voltage signal generated by the power supply device 20, and the BS converter 4b operates normally. Therefore, the user can enjoy BS broadcasting on the television 16 while recording the television signal received and demodulated by the CS tuner 14 with a video deck (not shown). Note that the amount of power of the voltage signal generated by the DC-DC converter 46 is the amount of power necessary to operate the BS converter 4b (current capacity: about 100 to 200 mA). The remainder is used for the operation of the CS converter 2b.
[0052]
As described above, according to the satellite reception system of the present embodiment, the power supply device 20 corresponds to the voltage for switching the polarization plane in the CS converter 2b and simultaneously operates the CS converter 2b and the BS converter 4b. A voltage signal having an amount of electric power necessary for the generation is supplied to the CS converter 2b via the mixer 10 as it is, and the BS converter 4b is supplied with the DC-DC converter 46 in the mixer 10 from the voltage signal. The voltage signal for driving the BS converter 4b generated in the above is supplied. For this reason, while the CS converter 2b and the BS converter 4b are always operating normally, the received signals from the converters 2b and 4b can be transmitted to the terminal side with one coaxial cable, and the coaxial cable wiring work can be simplified. At the same time, an easy-to-use satellite reception system can be constructed.
[0053]
As mentioned above, although one Example of this invention was described, this invention is not limited to the said Example, A various aspect can be taken.
For example, in the above-described embodiment, the power supply device 20 has been described as generating the direct current 11V and the direct current 15V as the first voltage signal and the second voltage signal using the two constant voltage circuits 28 and 26. For example, as shown in FIG. 4, instead of the two constant voltage circuits 26 and 28, an output variable constant voltage circuit 29 capable of switching the output voltage between DC 11V and DC 15V is provided, and the voltage determination circuit 34 is provided. The output voltage from the constant voltage circuit 29 may be switched directly according to the determination result by
[0054]
That is, the output variable constant voltage circuit 29 shown in FIG. 4 is basically the same as the constant voltage circuit 26 shown in FIG. 2, and includes a three-terminal regulator 29a and voltage stabilizing capacitors C2 and C3. Is configured. 2 is different from that of FIG. 2 in that the reference potential setting terminal of the three-terminal regulator 29a is connected to the constant voltage output terminal via the resistor R4 and is connected to the contact 30a of the relay 30 for reference potential setting. That is, the terminal is switched between the direct grounding via the contact 30a of the relay 30 or the grounding via the resistor R5.
[0055]
In the output variable constant voltage circuit 29 configured as described above, when the contact 30a of the relay 30 directly grounds the reference potential setting terminal of the three-terminal regulator 29a, the output voltage becomes a preset setting voltage. When the contact 30a of the relay 30 has the reference potential setting terminal of the three-terminal regulator 29a grounded via the resistor R5, the output voltage is higher than the set voltage by the voltage across the resistor R5. .
[0056]
Therefore, in the output variable constant voltage circuit 29 shown in FIG. 4, a three-terminal regulator 29a having an 11V output is used, and when the resistance values of the resistors R4 and R5 are 15V DC, By setting the voltage across the resistor R5 to be 4V, the output voltage can be switched to 11V or 15V by energization / non-energization of the relay coil 30b in the relay 30.
[0057]
Therefore, even if the output variable constant voltage circuit 29 shown in FIG. 4 is used in place of the constant voltage circuits 26 and 28 in the power supply device 20 shown in FIG. 2, the operation of the voltage determination circuit 34 causes the CS converter 2b to operate. The voltage signal to be supplied can be switched to either DC 11V or DC 15V, and the configuration of the power supply device 20 can be simplified.
When the voltage signal supplied to the CS converter 2b is switched to either DC 11V or DC 15V by switching the output voltage from the output variable constant voltage circuit 29 by the operation of the voltage determination circuit 34 as described above, FIG. In the output variable constant voltage circuit 29, the reference potential setting terminal of the three-terminal regulator 29a is grounded via the resistor R6, and the energization / non-energization of the relay coil 30b on the voltage determination circuit 34 side is performed. It may be configured to switch whether or not the resistor R7 is connected in parallel to the resistor R6 by the contact 30a of the relay 30 whose ON / OFF state is switched by.
[0058]
That is, when the relay coil 30b is energized, the contact 30a is turned off, the reference potential setting terminal of the three-terminal regulator 29a is grounded by the resistor R6, the output from the three-terminal regulator 29a becomes 15V, and the relay coil When 30b is not energized, the contact 30a is turned on, the reference potential setting terminal of the three-terminal regulator 29a is grounded by the combined resistance of the resistor R6 and the resistor R7, and the output from the three-terminal regulator 29a is output. It is set to 11V.
[0059]
In this way, when the ON / OFF state of the contact 30a is switched, the reference potential setting terminal of the three-terminal regulator 29a is prevented from being temporarily opened, and the three-terminal regulator 29a is always open. A voltage of 11V or 15V can be output.
[0060]
In the above embodiment, the BS converter 4b is described as operating at 15V DC. However, like the BS converter 4b 'shown in FIG. 6, the frequency converter 54 constituting the BS converter 4b operates at 15V DC. Even if it is, the voltage signal (DC 11V or 15V) input from the mixer 10 side to the output terminal TBO is separated by the power supply separation circuit 56, and the frequency is separated from the separated voltage signal (DC 11V or 15V). The BS converter may be configured so that the voltage signal for driving the converter 54 (DC 15V) is generated by the constant voltage circuit 58. That is, the BS converter 4b is not simply constituted by the receiving unit 52 and the frequency converting unit 54 as in the conventional case, but a constant voltage circuit 58 having the same function as the above-described DC-DC converter 46 is provided therein. Thus, the BS converter 4b ′ is configured to operate only by inputting the same voltage signal as that of the CS converter 2b to the BS converter 4b ′.
[0061]
If the BS converter 4b 'configured as described above is used, the mixer 10' for mixing the received signals of CS and BS has a choke coil L11 from the mixer 10 of the above embodiment as shown in FIG. , L12, and the DC-DC converter 46 can be removed, and instead, a simple mixer having a choke coil L21 that bypasses the voltage signal from the output terminal TMO to the input terminal TBS can be used.
[0062]
In the above embodiment, the CS converter 2b provided in the CS antenna 2 receives a transmission radio wave from one communication satellite, and frequency-converts either a horizontal polarization signal or a vertical polarization signal therein. However, when the CS antenna 2 is configured to be able to receive radio waves transmitted from two communication satellites, the power supply device 20 is connected to the power supply device 20 shown in FIG. ).
[0063]
In other words, the CS antenna has two receiving units for receiving radio waves transmitted from two communication satellites, respectively, and the CS converter receives a voltage signal for both polarization switching and power supply supplied from the terminal side. Depending on whether or not a pulse signal for switching satellites (frequency: about 30 kHz to 60 kHz) is superimposed, one of the two receiving units is selectively operated, and from among the signals from the operating receiving unit, There is known a configuration in which a vertical or horizontal polarization signal corresponding to a voltage signal for both polarization switching and power supply is selected and frequency-converted.
[0064]
In such a system equipped with a CS antenna for receiving two satellites, a voltage obtained by superimposing a pulse signal on a voltage signal for both polarization switching and power supply from a terminal device such as a CS tuner for switching the receiving satellite. A signal will be output. Therefore, the power supply device 20 used in such a system has the same pulse as the pulse signal superimposed on the voltage signal input from the terminal device side such as the CS tuner on the 11V or 15V voltage signal generated as described above. It is necessary to configure so that signals can be superimposed and output to the CS antenna side.
[0065]
When the power supply device 20 is configured as described above, for example, as shown in FIG. 8A, the CS tuner is provided in the power supply device 20 shown in FIG. 4 via the output terminal TOUT and the power supply separation circuit 32. 14 is provided with a pulse extraction / amplification circuit 80 for extracting and amplifying a pulse signal superimposed on the voltage signal from the voltage signal input from the 14 side, and an output from the pulse extraction / amplification circuit 80 (in other words, The pulse signal) is superimposed on the voltage signal (11V or 15V) generated by the internal circuit such as the output variable constant voltage circuit 29 by the pulse superimposing circuit 82, and the voltage signal after the superposition of the pulse signal is converted into the power source separation circuit 32. Further, it may be configured to output to the branching filter 12 (and hence the mixer 10) side through the input terminal TIN.
[0066]
Further, for example, as shown in FIG. 8B, the high frequency component in the voltage signal input from the CS tuner 14 side via the output terminal TOUT and the power supply separation circuit 32 in the power supply device 20 shown in FIG. In other words, a high-pass filter (HPF) 90 that bypasses (that is, a pulse signal) is provided, and the pulse signal that has passed through the high-pass filter 90 is directly passed through the power supply separation circuit 32 and the input terminal TIN to be connected to the duplexer 12 (and hence the mixer 10). ) Side may be configured to output.
[0067]
When the power supply device 20 is configured as shown in FIG. 8B, a pulse signal superimposed on the voltage signal input from the CS tuner 14 side is input to the voltage determination circuit 34 or a high-pass filter. The voltage from the power supply separation circuit 32 to the voltage determination circuit 34 is such that the pulse signal output to the branching filter 12 side is not attenuated by the pulse signal that has passed through 90 wrapping around to the output variable constant voltage circuit 29 side. The signal path and the voltage signal path from the output variable constant voltage circuit 29 to the power source separation circuit 32 are respectively a low-pass filter (LPF) 92 that blocks the pulse signal and passes only the DC component of the voltage signal. 94 may be provided.
[0068]
Next, in the above embodiment, the satellite reception system including two antennas, the CS antenna 2 and the BS antenna 4, has been described, but the present invention includes other reception antennas such as a VHF antenna and a UHF antenna. Needless to say, the present invention can also be applied to a satellite reception system. In this case, the mixer 10 may be configured to mix all the received signals from these antennas and output them to the terminal side. Further, the mixer 10 may include an amplifier circuit that amplifies a part or all of the received signal input from the antenna side via the input terminal. Further, instead of the duplexer 12, a distributor that simply distributes the received signal transmitted from the mixer may be used.
[0069]
The power supply device may be arranged on a transmission path from the mixer to the CS tuner, and is provided on a transmission line (coaxial cable) between the splitter used in place of the duplexer or the duplexer and the mixer. Also good. The duplexer and distributor may be built in the power supply device.
[Brief description of the drawings]
FIG. 1 is a configuration diagram illustrating a configuration of a satellite reception system according to an embodiment.
FIG. 2 is an electric circuit diagram illustrating a configuration of a power supply device according to an embodiment.
FIG. 3 is an electric circuit diagram illustrating a configuration of a mixer according to an embodiment.
4 is a configuration diagram showing a modification of the power supply device shown in FIG. 2. FIG.
5 is an explanatory diagram showing a modification of a voltage switching portion by a relay contact in the power supply device shown in FIG. 4; FIG.
FIG. 6 is a block diagram illustrating another configuration example of a BS converter.
7 is an electric circuit diagram illustrating a configuration example of a mixer used together with the BS converter illustrated in FIG. 6;
FIG. 8 is an explanatory diagram for explaining a modification of the power supply device when used in a system including a CS antenna for receiving two satellites as a CS antenna.
[Explanation of symbols]
2 ... CS antenna, 2b ... CS converter, 4 ... BS antenna, 4b ... BS converter, 10 ... mixer, 12 ... duplexer, 14 ... CS tuner, 16 ... TV, 20 ... power supply, 46 ... DC-DC converter 58 ... Constant voltage circuit.

Claims (9)

Two types of radio waves transmitted from communication satellites with different polarization planes are received as the first polarization signal and the second polarization signal, respectively, and the polarization is switched to the output terminal of the reception signal to the terminal side. When receiving the first voltage signal also serving as a power supply, the first polarization signal is frequency-converted into a CS reception signal of a predetermined frequency band and output from the output terminal to the terminal side, and the output terminal receives the first voltage signal. When receiving a second voltage signal for both polarization switching and power supply set to a voltage higher than the voltage signal of 1, the second polarization signal is converted into a CS reception signal of a predetermined frequency band and the output A CS antenna with a CS converter that outputs from the terminal to the terminal side;
When receiving a transmission radio wave from a broadcasting satellite and receiving a voltage signal for power supply at an output terminal of a reception signal to the terminal side, the received transmission signal from the satellite broadcast is converted into a BS reception signal in a predetermined frequency band And a BS antenna provided with a BS converter that outputs from the output terminal to the terminal side,
A pair of input terminals connected to the output terminal of the CS converter and the output terminal of the BS converter, respectively, and the received signals from the converters input to the input terminals are mixed and output from the output terminals And
Connected to the output terminal of the mixer via a single transmission line, demultiplexes the received signal transmitted via the transmission line into the CS received signal and the BS received signal, and demodulates each received signal. A duplexer that outputs to a terminal device for
Provided on a transmission path from the mixer to a terminal device for demodulating a CS received signal, and sufficient power to operate at least the CS converter and BS converter according to the polarization switching signal output from the terminal device Generating a first voltage signal or a second voltage signal in an amount and outputting the generated voltage signal to the mixer side;
The duplexer outputs a signal received from the CS reception signal demodulation terminal device side to the mixer side, and the mixer outputs the voltage signal received at the output terminal to each of the input terminals. To output to the output terminal of each converter,
In addition, each of the CS converter and the BS converter uses a local oscillation signal having substantially the same frequency for frequency conversion of each received signal, so that reception is possible with a single transmission line having a frequency band shifted from each other. A satellite reception system configured to output a signal . The satellite reception system according to claim 1, wherein
The BS converter is configured to operate by receiving the second voltage signal as the power supply voltage signal.
The mixer generates a second voltage signal for driving the BS converter from the voltage signal regardless of whether the voltage signal received at the output terminal is the first voltage signal or the second voltage signal. A satellite receiving system comprising a constant voltage circuit for outputting the generated second voltage signal from an input terminal connected to the BS converter to an output terminal of the BS converter. The satellite reception system according to claim 1, wherein
The mixer is configured to output the voltage signal received at the output terminal as it is from each input terminal connected to the output terminal of the CS converter and the BS converter,
The BS converter
A frequency converter that converts the transmission signal from the satellite broadcast into a BS reception signal in a predetermined frequency band by receiving the second voltage signal;
Regardless of whether the voltage signal from the mixer received at the output terminal is the first voltage signal or the second voltage signal, the second voltage signal for driving the frequency converter is generated from the voltage signal. And a constant voltage circuit to be supplied to the frequency converter,
A satellite receiving system comprising: In the satellite reception system according to any one of claims 1 to 3,
The mixer includes one or a plurality of input terminals for inputting reception signals from other reception antennas separately from the reception signals output from the converters, and receives other reception signals input to the input terminals. A satellite reception system configured to mix all reception signals from an antenna and reception signals from the converters and output the mixture from the output terminal. In the satellite reception system according to any one of claims 1 to 4,
The satellite receiving system according to claim 1, wherein the mixer includes an amplifying circuit for amplifying at least one of the received signals input from the input terminals before mixing with the other received signals. In the satellite reception system according to any one of claims 1 to 5,
Instead of the branching filter, a satellite receiving system comprising a distributor that distributes a plurality of received signals transmitted via the transmission line and outputs the divided signals to a terminal device for demodulating each received signal . Two types of radio waves transmitted from communication satellites with different polarization planes are received as the first polarization signal and the second polarization signal, respectively, and the polarization is switched to the output terminal of the reception signal to the terminal side. When receiving the first voltage signal also serving as a power supply, the first polarization signal is frequency-converted into a CS reception signal in a predetermined frequency band and output from the output terminal to the terminal side, and the output terminal receives the first voltage signal. When receiving a second voltage signal for both polarization switching and power supply set to a voltage higher than the voltage signal of 1, the second polarization signal is converted into a CS reception signal of a predetermined frequency band and the output A CS antenna with a CS converter that outputs from the terminal to the terminal side;
When receiving a transmission radio wave from a broadcasting satellite and receiving the second voltage signal as a power supply voltage signal at an output terminal of a reception signal to the terminal side, the received transmission signal from the satellite broadcasting is transmitted to a predetermined frequency band. A BS antenna provided with a BS converter that converts the frequency into a BS received signal and outputs the signal from the output terminal to the terminal side;
A reception signal mixer used for mixing the reception signals output from the converters and outputting them to the terminal side,
A pair of input terminals connected to the output terminals of the converters to input the received signals output from the converters;
A mixing circuit that mixes reception signals from the converters input to the input terminals;
An output terminal for outputting the reception signal mixed in the mixing circuit to the terminal side;
The first voltage signal or the second voltage signal for both polarization switching and power supply transmitted from the terminal side to the output terminal is output as it is to the input terminal side that receives the CS reception signal from the CS converter. A voltage signal output circuit;
Regardless of whether the polarization switching / power supply voltage signal transmitted from the terminal side to the output terminal is the first voltage signal or the second voltage signal, the BS converter is driven from the voltage signal. A constant voltage circuit that generates a second voltage signal of the second voltage signal and outputs the generated second voltage signal to an input terminal that receives a BS reception signal from the BS converter;
A received signal mixer. The received signal mixer according to claim 7.
Separately from the reception signals output from the converters, one or a plurality of input terminals for inputting reception signals from other reception antennas are provided.
Received signal mixing characterized in that all received signals from other receiving antennas inputted to the input terminal and received signals from the respective converters are mixed and output from the output terminal to the terminal side. vessel. The received signal mixer according to claim 7 or 8,
A reception signal mixer comprising an amplification circuit for amplifying at least one of the reception signals input from each input terminal before mixing with other reception signals.

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