JP2007235433A - Low-noise block converter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To perform frequency conversion from the RF signal of a satellite broadcast reception signal into a first IF signal and a second IF signal, by removing an image frequency (IF Image) for a second frequency conversion block whose frequency conversion is performed on the second IF signal. <P>SOLUTION: This one cable wide band LNB is provided with RF mixers 103 and 133 for converting a satellite broadcast reception signal into the channel signal group of an intermediate frequency band and IF mixers 110, 113, 140 and 143 for converting the channel signal group into a predetermined fixed frequency, wherein band-elimination filters 12 and 14 are installed between the RF mixers 103 and 133 and the IF mixers 110, 113, 140 and 143 so that image frequency for the IF mixers 110, 113, 140 and 143 can be attenuated. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a low noise block converter (hereinafter referred to as “LNB”) which is a frequency converter for satellite broadcast reception.

  Conventionally, there has been a desire to connect four BS receivers (for example, two BS receivers with two tuners) to one LNB, and there has been a four-output LNB having four output terminals. However, the 4-output LNB requires four cables between the BS receiver and the economic burden is large. Thus, an LNB that outputs four signals on one cable has been proposed (see, for example, Patent Document 1).

  FIG. 7 is a diagram showing a configuration example of an LNB that directly converts an RF signal into one IF signal. A horizontal polarization signal H is input to one low noise amplifier 101 of the LNB, and a vertical polarization signal V is input to the other low noise amplifier 131. An image signal (RF Image) is removed from the horizontal polarization signal H output from one low noise amplifier 101 by a band pass filter 102, and a vertical polarization signal V output from the other low noise amplifier 131 is a band pass filter. At 132, the image signal (RF Image) is removed. In the subsequent RF mixers 103 and 133, when the IF signal (0.5 GHz to 2.55 GHz) is converted by multiplication with the local oscillation frequency Lo = 10.2 GHz, the image band (RF Image) is 7.65 GHz to 9. .7 GHz. Conventionally, this image band (RF Image: 7.65 GHz to 9.7 GHz) has been removed by the bandpass filters 102 and 132.

  For an RF signal (10.7 GHz to 12.75 GHz) extracted by one band pass filter 102, a local oscillation signal Lo (supplied from a local oscillator 104 in an RF mixer 103 serving as a first frequency conversion block). 10.2 GHz) and is converted into an IF signal (for example, 0.5 GHz to 2.55 GHz) as a channel signal group. Similarly, with respect to the RF signal (10.7 GHz to 12.75 GHz) extracted by the other bandpass filter 132, the local oscillation supplied from the local oscillator 104 in the RF mixer 133 serving as the first frequency conversion block is also performed. The signal Lo is multiplied and converted to an IF signal (0.5 GHz to 2.55 GHz) as a channel signal group.

  The IF signals output from the RF mixers 103 and 133 are input to the distributors 107 and 137 via the amplifiers 106 and 136, branched there, and input to the first and second switch circuits 108 and 138. The switch circuit 108 is a 2-input × 2-output switch circuit that receives two IF signals of the horizontal polarization signal H and the vertical polarization signal V and outputs the IF signals from the output terminals 108a and 108b. Similarly, the switch circuit 138 is a two-input × two-output switch circuit that inputs two IF signals, a horizontal polarization signal H and a vertical polarization signal V, and outputs them from output terminals 138a and 138b.

  IF mixers 110 and 113 serving as a second frequency conversion block are connected to two output terminals 108a and 108b of the first switch circuit 108 via amplifiers 109 and 112, respectively. The IF mixers 110 and 113 multiply the input IF signal by the local oscillation signals supplied from the corresponding voltage controlled oscillators 111 and 114, respectively, and generate the horizontal polarization signal H and the vertical polarization signal V from 0.5 GHz to Frequency conversion is performed from a frequency band of 2.55 GHz to a specific fixed frequency (for example, IF mixer 110 is 1.4 GHz and IF mixer 113 is 1.516 GHz). IF mixers 140 and 143 serving as a second frequency conversion block are connected to the two output terminals 138a and 138b of the second switch circuit 138 via amplifiers 139 and 142, respectively. The IF mixers 140 and 143 multiply the input IF signal by the local oscillation signals supplied from the corresponding voltage controlled oscillators 141 and 144, respectively, and convert the horizontal polarization signal H and the vertical polarization signal V to 0.5 GHz-2. Each frequency is converted from a frequency band of .55 GHz to a specific fixed frequency (for example, IF mixer 140 is 1.632 GHz and IF mixer 143 is 1.748 GHz).

  Amplifiers 115, 116, 145, and 146 are connected to the output stages of the IF mixers 110, 113, 140, and 144, and the bandpass filters 123, 122 are connected via impedance baluns 121, 122, 151, and 152. 124, 153, and 154 are connected. The IF signals converted into fixed frequencies by the IF mixers 110, 113, 140, and 144 respectively cut unnecessary frequency components for the respective fixed frequencies by the bandpass filters 123, 124, 143, and 144, and are mixed in two stages. Mix in units 125, 145 and 126. Then, after being amplified with the set gain by the IF amplifier 127, it is output from the output port to the cable.

In this way, the RF mixers 103 and 133 serving as the first frequency conversion blocks convert the signals to the first IF signals, and the IF mixers 110, 113, 140, and 143 serving as the second frequency conversion blocks each have a fixed frequency. To the second IF signal. There is an advantage that the number of oscillators and mixers can be reduced by making the frequency conversion block into a two-stage configuration and converting it into the first and second IF signals. An LNB that directly converts a wideband (10.7 GHz to 12.75 GHz) television signal into a narrowband (0.5 GHz to 2.55 GHz) IF signal, such as the LNB shown in FIG. 7, is called a wideband LNB for convenience. And
US Patent Application Publication No. 2003/0141949

However, when the RF signal is converted into the first and second IF signals in the above-described wideband LNB, the first image signal (RF Image) which becomes the image frequency for the first frequency conversion block (103, 132). : 7.65 GHz to 9.7 GHz) as well as a second image signal (IF Image) that is an image frequency for the second frequency conversion block. If the second IF signal has each of the fixed frequencies, 3.3 GHz to 6.046 GHz is the second image signal (IF Image).
Also, the low frequency side (3.3 GHz) of the second image signal (IF Image) is close to the high frequency side (2.55 GHz) of the signal band of the first IF signal that is the satellite broadcast reception signal. If the bandpass filters 102 and 132 try to remove the first image signal (RF Image) at the same time, there is a problem that the bandpass filters 102 and 132 are enlarged.

  The present invention has been made in view of such a point, and when the frequency conversion is performed from the RF signal of the satellite broadcast reception signal to the first IF signal and the second IF signal, the frequency conversion to the first IF signal is performed. The image frequency (IF) for the second frequency conversion block that converts the frequency to the second IF signal without increasing the size of the filter for removing the image frequency (RF Image) for the first frequency conversion block. An object of the present invention is to provide a low noise block converter capable of removing (Image).

  The low noise block converter of the present invention includes a first frequency conversion block that converts a satellite broadcast reception signal into a channel signal group in an intermediate frequency band, and a second frequency conversion block that converts the channel signal group into a predetermined fixed frequency. And an attenuation circuit provided between the first frequency conversion block and the second frequency conversion block for attenuating a frequency band that is an image frequency for the second frequency conversion block. To do.

  According to this configuration, since the attenuation circuit that attenuates the frequency band that is the image frequency for the second frequency conversion block is provided between the first frequency conversion block and the second frequency conversion block, The image frequency (IF Image) for the second frequency conversion block without increasing the size of the bandpass filter for removing the image frequency (RF Image) for the first frequency conversion block before the frequency conversion block. Can be attenuated.

  According to the present invention, in the low noise block converter, the attenuation circuit is configured by a band elimination filter.

  With this configuration, the image frequency (IF Image) for the second frequency conversion block can be removed by the band elimination filter, and the satellite in the region where the frequency band of the satellite broadcast reception signal and the image frequency (IF Image) are close to each other. The image frequency (IF Image) can be sufficiently attenuated without attenuating the broadcast reception signal.

  According to the present invention, in the low noise block converter, the attenuation circuit can be configured by a low pass filter.

  In the low noise block converter, the present invention is provided between the attenuation circuit and the second frequency conversion block, and a plurality of input terminals for inputting a plurality of channel signal groups and channels input from the input terminals. A switch circuit having a plurality of output terminals for outputting a signal group is provided.

  With this configuration, a plurality of frequency conversion blocks can be connected to a plurality of output ends of the switch circuit, and a channel signal group can be converted into a plurality of fixed frequencies and output.

  Further, the present invention provides the low noise block converter including a plurality of the first frequency conversion blocks, and the switch circuit selects a channel signal group input to the input terminal from the plurality of first frequency conversion blocks. Output.

  With this configuration, a plurality of first frequency conversion blocks can be arranged at the input stage of the switch circuit, while a plurality of second frequency conversion blocks can be arranged at the output stage of the switch circuit. The channel signal group from the frequency conversion block can be received by the switch circuit, and the input channel signal group can be selected and output to a plurality of subsequent frequency conversion blocks.

  According to the present invention, it is possible to remove the second image signal (IF Image) without increasing the size of the band-pass filter for removing the first image signal (RF Image).

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
FIG. 1 is an overall configuration diagram of a wideband LNB according to an embodiment of the present invention. In the figure, the same components as those of the wideband LNB shown in FIG.

  In the wideband LNB according to the present embodiment, the horizontal polarization signal H from which the first image signal (RF Image) has been removed by the bandpass filter 102 in the input line of the horizontal polarization signal H is subjected to first frequency conversion. The vertical polarization signal V is converted into the first IF signal by the RF mixer 103 serving as a block, and the first image signal (RF Image) is removed by the band pass filter 132 in the input line of the vertical polarization signal V. Is converted into a first IF signal by an RF mixer 133 serving as a first frequency conversion block. Further, the first IF signal relating to the horizontal polarization signal H and the vertical polarization signal V output from the first switch circuit 108 is converted into a second fixed frequency signal by the IF mixers 110 and 113 serving as the second frequency conversion block. IF mixers 140 and 143 that convert the first IF signal related to the horizontal polarization signal H and the vertical polarization signal V output from the second switch circuit 138 into a second frequency conversion block. To convert to a fixed IF second IF signal. Four second IF signals each converted to a specific fixed frequency are combined and output from the output port to one cable. As described above, in the present embodiment, the RF signal is converted into the first IF signal by the RF mixers 103 and 133 serving as the first frequency conversion block, similarly to the wideband LNB shown in FIG. The IF mixer 110, 113, 140, 143, which is a second frequency conversion block, converts each IF signal into a second IF signal with a fixed frequency, and synthesizes these second IF signals into one cable. The output is provided.

  In the present embodiment, in the input line of the horizontally polarized signal H, the high-pass filter 11 is provided before the low noise amplifier 101, and the second image signal (after the RF mixer 103 and before the distributor 107 is provided. A band elimination filter 12 for removing (IF Image) is provided. Similarly, in the input line of the vertically polarized signal V, the high-pass filter 13 is provided before the low noise amplifier 131, and the second image signal (IF Image) is provided after the RF mixer 133 and before the distributor 137. A band elimination filter 14 for elimination is provided.

  Here, the first and second image signals generated in the wideband LNB according to the present embodiment will be specifically described. As shown in FIG. 1, it is assumed that RF signals input as satellite broadcast reception signals are a horizontal polarization signal H and a vertical polarization signal V of 10.7 GHz to 12.75 GHz. The local oscillation signal Lo that is multiplied by the RF signal by the RF mixers 103 and 133 that are the first frequency conversion blocks is 10.2 GHz, and the first IF signal that is the first and second channel signal groups is 0. It is assumed that the frequency is 5 GHz to 2.55 GHz. When the first IF signal is 0.5 GHz to 2.55 GHz and the local oscillation signal Lo is 10.2 GHz, the signal of the first IF signal is from a signal band other than 10.7 GHz to 12.75 GHz of the satellite broadcast reception signal. The band that can be converted to the band 0.5 GHz to 2.55 GHz, that is, the image band that becomes the image frequency (RF Image) for the first frequency conversion block (103, 133) is 7.65 GHz to 9.7 GHz. This image band is called “RF Image1”.

  The fixed frequencies obtained by multiplying each local oscillation signal by the first IF signal in the IF mixers 110, 113, 140, and 143 serving as the second frequency conversion block are 1.400 GHz, 1.516 GHz, 1 It is assumed that the frequency is .632 GHz and 1.748 GHz. If the local oscillation signal to be multiplied by the first IF signal is 1.9 GHz to 4.3 GHz, the signal is converted from the signal band other than 0.5 GHz to 2.55 GHz of the first IF signal to each of the fixed frequencies. The obtained band, that is, the image band that becomes the image frequency (IF Image) for the second frequency conversion block (110, 113, 140, 143) is 3.3 GHz to 5.35 GHz for a fixed frequency of 1.400 GHz. The fixed frequency of 1.516 GHz is 3.532 GHz to 5.582 GHz, the fixed frequency of 1.632 GHz is 3.764 GHz to 5.814 GHz, and the fixed frequency of 1.748 GHz is 3.75 GHz. 996 GHz to 6.046 GHz. These image bands are referred to as “IF Image1_1”, “IF Image1_2”, “IF Image1_3”, and “IF Image1_4” in order from the top. The minimum frequency of 3.3 GHz to the maximum frequency of 6.046 GHz in the entire image band for generating the second image signal is an image band for the second IF signal, and this image band is referred to as “IF Image1”.

  In the RF mixers 103 and 133, which are the first frequency conversion blocks, the bands that can be frequency converted to the second image signal (IF Image1: 3.3 GHz to 6.046 GHz) are 13.5 GHz to 16.246 GHz and 4. Two of 154 GHz to 6.9 GHz. The former frequency band is “RF Image2_1”, and the latter frequency band is “RF Image2_2”.

  In the present embodiment, an RF signal including a satellite broadcast reception signal of 10.7 GHz to 12.75 GHz is input to the high-pass filters 11 and 13 provided in the input stage of the wideband LNB, and a high frequency of 9.7 GHz or higher Pass through. FIG. 2A is a diagram illustrating the frequency characteristics of the RF signal in the section from the output stage of the high-pass filters 11 and 13 to the input stage of the band-pass filters 102 and 132. As shown in the figure, the signals of the image band “RF Image1” of 7.65 GHz to 9.7 GHz and the frequency band “RF Image2_2” of 4.154 GHz to 6.9 GHz included in the attenuation regions of the high pass filters 11 and 13 are obtained. It is attenuated. On the other hand, “RF Image2_1”, which is the RF signal component of the image band “IF Image1” for the second IF signal, is 9.7 GHz or higher and remains without being removed.

  RF signals that pass through the high-pass filters 11 and 13 and are amplified with a predetermined gain by the low-noise amplifiers 101 and 131 are input to the band-pass filters 102 and 132. The band-pass filters 102 and 132 use a band having a predetermined margin in the frequency band 10.7 GHz to 12.75 GHz of the satellite broadcast reception signal as a pass band. In the present embodiment, the maximum frequency of 9.7 GHz of the image band “RF Image1” is −40 dB or more without attenuating 10.7 GHz, which is the minimum frequency of the satellite broadcast reception signal, due to the frequency characteristics of the bandpass filters 102 and 132. It is attenuated. FIG. 2B is a frequency characteristic diagram of the RF signal in the section from the output stage of the bandpass filters 102 and 132 to the input stage of the RF mixers 103 and 133. As shown in the figure, since the minimum frequency 10.7 GHz of the satellite broadcast reception signal and the maximum frequency 9.7 GHz of the image band “RF Image1” are about 1 GHz apart, the above attenuation characteristics increase the filter size. Is feasible. A specific configuration of the high-pass filters 11 and 13 will be described later.

  On the other hand, the minimum frequency 13.5 GHz of “RF Image2_1” that is the RF signal component of the image band “IF Image1” for the second IF signal is only about 750 MHz away from the maximum frequency 12.75 GHz of the satellite broadcast reception signal. In order to attenuate the high frequency side from around 13.5 GHz to about −40 dB as described above without attenuating the maximum frequency 12.75 GHz of the satellite broadcast reception signal, the band-pass filters 102 and 132 must be significantly enlarged. . In the present embodiment, in order to keep the sizes of the bandpass filters 102 and 132 as in the conventional case, the attenuation is limited to about −20 dB in the vicinity of 13.5 GHz. As a result, the first IF signal is output while including the signal component of “RF Image2_1” that will later become the image band “IF Image1”.

  In the RF mixers 103 and 133 serving as the first frequency conversion block, the first IF signal frequency-converted by multiplying the RF signal output from the bandpass filters 102 and 132 by the local oscillation signal Lo is output. The The first IF signal is amplified with a predetermined gain by the amplifiers 106 and 136 and then input to the band elimination filters 12 and 14. FIG. 3A is a frequency characteristic diagram of the first IF signal in the section from the output stage of the RF mixers 103 and 133 to the previous stage of the band elimination filters 12 and 14. The frequency band of 10.7 GHz to 12.75 GHz of the satellite broadcast reception signal is frequency-converted to 0.5 GHz to 2.55 GHz. In addition, the frequency band “RF Image2_1” 13.5 GHz to 16.246 GHz, which is not partially attenuated by the bandpass filters 102 and 132, is frequency-converted to 3.3 GHz to 6.046 GHz. As described above, 3.3 GHz to 6.046 GHz is the image band “IF Image1” for the second IF signal.

  The band elimination filters 12 and 14 have a band elimination characteristic with a bandwidth of about 3.3 GHz to 4.2 GHz. As described above, in the RF signal, the bandpass filters 102 and 132 could not sufficiently attenuate the vicinity of 13.5 GHz to 14.0 GHz in the frequency band “RF Image2_1”. Therefore, the band elimination filter removes the portion corresponding to the area where the attenuation is insufficient before the frequency conversion by the second frequency conversion block from the first IF signal after the frequency conversion by the first frequency conversion block. 12 and 14 are removed. FIG. 3B is a frequency characteristic diagram of the first IF signal in a section from the output stage of the band elimination filters 12 and 14 to the input stage of the IF mixers 110, 113, 140, and 143 serving as the second frequency conversion block. It is. As shown in the figure, by passing the band elimination filters 12 and 14, the high frequency side of 3.3 GHz or higher in the first IF signal can be attenuated to around −40 dB. As a result, the image band “IF Image1” for the second IF signal can be sufficiently removed.

  The first IF signal on the horizontal polarization signal H side that has passed through the band elimination filters 12 and 14 is distributed to the first switch circuit 108 and the second switch circuit 138 by the distributor 107, and on the vertical polarization signal V side. The first IF signal is distributed by the distributor 137 to the first switch circuit 108 and the second switch circuit 138.

  The first IF signals selected and output from the first and second switch circuits 108 and 138 are frequency-converted to specific frequencies by IF mixers 110, 113, 140, and 143, respectively, which are second frequency conversion blocks. .

  Thus, the frequency band “RF Image2_2” of the frequency bands “RF Image2_1” and “RF Image2_2” corresponding to the image band “IF Image1” for the second IF signal is removed by the bandpass filters 102 and 132. The frequency band “RF Image2_1” that could not be sufficiently attenuated (removed) remains after being converted to the first IF signal, but is removed by the band elimination filters 12 and 14 before the conversion to the second IF signal. . Accordingly, the first IF signal from which the image band “IF Image1” has been removed is input to the IF mixers 110, 113, 140, and 143 and converted into the second IF signal.

  The second IF signals converted into fixed frequencies by the IF mixers 110, 113, 140, and 144 respectively cut unnecessary frequency components for the respective fixed frequencies by the bandpass filters 123, 124, 143, and 144, and 2 Mix in stage mixers 125, 145 and 126. Then, after being amplified with the set gain by the IF amplifier 127, it is output from the output port to the cable.

  Next, specific configuration examples of the bandpass filters 102 and 132 and the band elimination filters 12 and 14 will be described.

  FIG. 4 is a diagram illustrating a configuration example of the bandpass filter 102 (132). The coupling filter elements 21-1 to 21-6 and the coupling filter elements 22-1 to 22-5 are alternately arranged on the substrate 20 alternately and adjacent to the coupling filter element 21-1 at one end. The input / output filter element 23 is disposed, and the other input / output filter element 24 is disposed adjacent to the coupling filter element 21-6 at the other end.

  Each coupling filter element has an open stub 32 formed on the center side of the substrate from an intermediate point 31 connected to the ground, and a short stub 33 formed on the side surface of the substrate. The coupling filter elements 21-1 to 21-6 arranged on one side and the coupling filter elements 22-1 to 22-5 arranged on the other side alternately arrange the open stubs 32 in the arrangement direction. ing.

  A band having a frequency characteristic having a central passband of 10.7 GHz to 12.75 GHz by adjusting the interval between adjacent coupling filter elements, the width of each coupling filter element, and the lengths of the open stub 32 and the short stub 33. The pass filter 102 (132) can be configured.

  As a result of simulating the frequency characteristics of the bandpass filter configured as described above, it was confirmed that the low frequency side of 9.7 GHz can be attenuated by −40 dB or more. Therefore, the image band “RF Image1” (7.65 GHz to 9.7 GHz) and the RF signal component “RF Image2_2” (4.154 GHz to 6.9 GHz) of the image band “IF Image1” for the second IF signal are set. Performance that can be eliminated can be realized.

  FIG. 5 is a diagram showing a configuration example in which the band elimination filter 12 (14) is configured by a lumped constant LC filter. In this lumped LC filter, an LC parallel circuit composed of a capacitor 33 and an inductor 34 and an LC parallel circuit composed of a capacitor 35 and an inductor 36 are provided in series between one input / output port 31 and the other input / output port 32. The LC series circuit including the capacitor 37 and the inductor 38 is provided between the intermediate connection point and the ground.

  As a result of simulating the frequency characteristics of the lumped constant LC filter configured as described above, it was confirmed that a band rejection characteristic of about 3.3 GHz to 4.2 GHz can be realized. Note that the band rejection characteristic varies somewhat depending on variations in the capacitor capacitance value. In the above-described lumped constant LC filter, the change of the frequency characteristic with respect to the variation of the capacitor capacitance value was simulated. When the L value was fixed and the C value was changed by ± 0.1 pF, the variation at 3.3 GHz was 30 dB or more. When the capacitance value of the capacitor is +0.1 pF larger than the design value, the attenuation near 3.3 GHz may be insufficient.

  FIG. 6 is a diagram showing a configuration example in which the band elimination filter 12 (14) is configured by a distributed constant LC filter. This distributed constant LC filter has one end of the stripline 40 as one input / output port 41 and the other end as the other input / output port 42, and passes through a T-shaped branch at the first intermediate point of the stripline 40. An open stub 43 of approximately λ / 4 (13.5 mm) is formed, and approximately λ / 4 (through a T-shaped branch path at a second intermediate point that is a predetermined distance (10.0 mm) away from the first intermediate point. 14.5 mm) open stub 44 is formed. The center frequency is set to 3.6 GHz.

  As a result of simulating the frequency characteristics of the distributed constant LC filter configured as described above, it was confirmed that a band rejection characteristic of about 3.3 GHz to 4.2 GHz can be realized. In addition, when the length of the open stubs 43 and 44 was changed by ± 0.1 mm and the change in attenuation at 3.3 GHz was confirmed, it was within 10 dB. Therefore, by configuring the band elimination filter 12 (14) with a distributed constant LC filter, stable performance in which variation in attenuation at 3.3 GHz is suppressed with respect to variation in the length of the open stubs 43 and 44 is achieved. realizable.

  As described above, according to the present embodiment, the IF mixers 110, 113, 140, and 143 that are the second frequency conversion blocks that are the subsequent stages of the RF mixers 103 and 133 that are the first frequency conversion blocks. Since the band removal filters 12 and 14 for removing the image band “IF Image1” that cannot be removed by the bandpass filters 102 and 132 are provided in the previous stage, the signal band of the satellite broadcast reception signal is not attenuated. Good image characteristics can be realized.

  The present invention is not limited to the above-described embodiment, and various modifications can be made. For example, a low-pass filter or a band-pass filter can be used instead of the band elimination filters 12 and 14. A circuit other than the band elimination filters 12 and 14 may be used as long as it is an attenuation circuit capable of attenuating an image band close to the signal band of the satellite broadcast reception signal to a required attenuation level.

  The present invention is applicable to a wideband LNB with one cable output for satellite broadcast reception.

Configuration diagram of wideband LNB according to an embodiment of the present invention (A) Frequency characteristic diagram of RF signal after passing through high-pass filter in the above embodiment, (b) Frequency characteristic diagram of RF signal after passing through band-pass filter (A) Frequency characteristic diagram of IF signal after passing through RF mixer in the above embodiment, (b) Frequency characteristic diagram of IF signal after passing through band elimination filter Configuration diagram of a bandpass filter composed of interdigital filters Configuration diagram of band elimination filter composed of lumped constant LC filter Configuration diagram of band elimination filter composed of distributed constant LC filter Configuration diagram of conventional wideband LNB

Explanation of symbols

11, 13 High-pass filter 12, 14 Band elimination filter 101, 131 Low-noise amplifier 102, 132 Band-pass filter 103, 133 Mixer 104 Local oscillator 106, 136 IF amplifier 108 First switch circuit 110, 113, 140, 1439 IF Mixer 111, 114, 141, 144 Voltage controlled oscillator 121, 122, 151, 152 Balun 123, 124, 153, 154 Band pass filter

Claims (5)

A first frequency conversion block for converting a satellite broadcast reception signal into a channel signal group of an intermediate frequency band;
A second frequency conversion block for converting the channel signal group to a predetermined fixed frequency;
An attenuation circuit that is provided between the first frequency conversion block and the second frequency conversion block and attenuates a frequency band that is an image frequency for the second frequency conversion block; Low noise block converter.   2. The low noise block converter according to claim 1, wherein the attenuation circuit is constituted by a band elimination filter.   2. The low noise block converter according to claim 1, wherein the attenuation circuit is constituted by a low pass filter.   Provided between the attenuation circuit and the second frequency conversion block, and a plurality of input terminals for inputting a plurality of channel signal groups and a plurality of output terminals for outputting channel signal groups input from the input terminals. The low noise block converter according to any one of claims 1 to 3, further comprising a switch circuit having the same. A plurality of the first frequency conversion blocks;
5. The low noise block converter according to claim 4, wherein the switch circuit selects and outputs a group of channel signals input to the input terminal from the plurality of first frequency conversion blocks.

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