CN213484860U - Multichannel low-power consumption broadband receiver - Google Patents

Abstract

The utility model discloses a multichannel low-power consumption broadband receiver, which comprises an N-path frequency conversion module, a local oscillator module, a correction module and a power division module; the N paths of frequency conversion modules have the same function and structure, wherein N is a positive integer greater than or equal to 2; the local oscillator module and the correction module are used for generating local oscillator signals, and the local oscillator signals are respectively supplied to each path of frequency conversion module through the power division module; and the N paths of receiving modules, the local oscillator modules and the correction modules are connected with one another in a whole machine mode through the power division modules. The utility model discloses common local oscillator and crystal oscillator are used to the multichannel, greatly reduced product consumption.

Description

Multichannel low-power consumption broadband receiver

Technical Field

The utility model belongs to the technical field of the microwave, concretely relates to multichannel low-power consumption broadband receiver.

Background

With the rapid development of modern communication, the use requirement on microwave frequency is further improved, and an ultra-wideband receiver can accurately monitor a fact signal, so that the ultra-wideband receiver is widely applied to multiple fields of radar, communication, electronic countermeasure and the like. The broadband receiver is mainly used for processing signals of each frequency band received by the antenna, and filtering, frequency-converting and amplifying the received signals so as to carry out digital processing on the signals. The multi-channel receiver can receive the same signal in different directions so as to locate, point-to-point and the like the signal.

The defects and shortcomings of the prior art are as follows:

1. the existing multi-channel broadband receiver is large in size.

2. The existing multi-channel receiver has large power consumption, the high-performance receiver is usually larger than 20W, and a fixed large power supply is needed to support the operation of the high-performance receiver.

3. The existing multi-channel broadband receiver has poor performance index, weak anti-interference capability and narrow coverage frequency.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem that there is the consumption big, the performance index is poor in current broadband receiver, the utility model provides a multichannel low-power consumption broadband receiver.

The utility model discloses a following technical scheme realizes:

a multi-channel low-power consumption broadband receiver comprises an N-channel frequency conversion module, a local oscillator module, a correction module and a power division module;

the N paths of frequency conversion modules have the same function and structure, wherein N is a positive integer greater than or equal to 2;

the local oscillator module and the correction module are used for generating local oscillator signals, and the local oscillator signals are respectively supplied to each path of frequency conversion module through the power division module;

and the N paths of receiving modules, the local oscillator modules and the correction modules are connected with one another in a whole machine mode through the power division modules.

Preferably, the utility model discloses in each way frequency conversion module include gain control unit, radio frequency preselector unit, low noise amplifier B, wave filter B, mixer A, an intermediate frequency filter and gain control unit, mixer B, two intermediate frequency filter and gain control units, intermediate frequency filter unit and output unit;

wherein, 20M-8G radio frequency signals from the antenna are subjected to initial filtering and gain control processing through the gain control unit;

the signals processed by the gain control unit are subjected to segmented filtering processing by the radio frequency preselector unit;

the signal processed by the radio frequency preselector unit is processed by a low noise amplifier B and a filter B in sequence and then is input into the mixer A;

the frequency mixer A mixes the input radio frequency signal with a local oscillation signal generated by the local oscillation module and outputs an intermediate frequency signal;

the intermediate frequency signal is filtered and gain-controlled by the intermediate frequency filtering and gain control unit and then is input into the mixer B;

the mixer B mixes the signal output by the intermediate frequency filtering and gain control unit with a second local oscillation signal generated by the local oscillation module and outputs a second intermediate frequency signal;

the two intermediate-frequency signals are filtered and gain-controlled by the two intermediate-frequency filtering and gain control units and then input to the intermediate-frequency filtering unit for intermediate-frequency filtering;

the signal processed by the intermediate frequency filtering unit is processed by the output unit and outputs a required intermediate frequency signal.

Preferably, the gain control unit of the present invention comprises a filter a, a single-pole multi-throw switch a, a low noise amplifier a, a radio frequency attenuator a, and a single-pole multi-throw switch B;

the low noise amplifier A and the radio frequency attenuator A are arranged between the single-pole multi-throw switch A and the single-pole multi-throw switch B;

after being filtered by the filter A, 20M-8G radio frequency signals from an antenna are selected by the single-pole multi-throw switch A to be input to the low noise amplifier A for processing or input to the radio frequency attenuator A for processing or not for processing, and then are selected by the single-pole multi-throw switch B for output.

Preferably, the radio frequency preselector unit of the utility model comprises a single-pole multi-throw switch C, a preselection filter group and a single-pole multi-throw switch D;

the pre-selection filter bank is arranged between the single-pole multi-throw switch C and the single-pole multi-throw switch D;

the signal output after being processed by the gain control unit is selected by the single-pole multi-throw switch C to enter the pre-selection filter bank for segmented filtering processing, and then is selected by the single-pole multi-throw switch D to be output.

Preferably, the utility model discloses a preselection filter group is including parallelly connected setting in preselection filter A, preselection filter B, preselection filter C, preselection filter D, preselection filter E and preselection filter F between single-pole multi-throw switch C and the single-pole multi-throw switch D.

Preferably, the intermediate frequency filtering and gain control unit of the present invention comprises a filter C, an intermediate frequency filter a, an intermediate frequency amplifier a, an intermediate frequency filter B and an intermediate frequency attenuator a;

an intermediate frequency signal output by the mixer A is filtered by the filter C to remove mixing interference signals, and then is processed by the intermediate frequency filter A, the intermediate frequency amplifier A, the intermediate frequency filter B and the intermediate frequency attenuator in sequence and then is input to the mixer B.

Preferably, the filter C of the present invention is a microstrip interdigital filter.

Preferably, the second intermediate frequency filtering and gain control unit of the present invention comprises an intermediate frequency filter C, an intermediate frequency amplifier B, an intermediate frequency attenuator B, a temperature control attenuator a, and a low pass filter E;

and the two intermediate frequency signals output by the mixer B are processed by the intermediate frequency amplifier B, the intermediate frequency attenuator B, the temperature control attenuator A and the low pass filter E in sequence after redundant intermodulation signals generated by the mixer B are filtered by the intermediate frequency filter C.

Preferably, the intermediate frequency filtering unit of the present invention includes a single-pole multi-throw switch E, an intermediate frequency filter D, an intermediate frequency filter E, an intermediate frequency filter F, and a single-pole multi-throw switch F;

the intermediate frequency filter D, the intermediate frequency filter E and the intermediate frequency filter F are arranged between the single-pole multi-throw switch E and the single-pole multi-throw switch F in parallel;

the signals processed and output by the two intermediate frequency filtering and gain control units enter the intermediate frequency filter D, the intermediate frequency filter E or the intermediate frequency filter F for filtering processing through the single-pole multi-throw switch E, and then are selectively output through the single-pole multi-throw switch F.

Preferably, the output unit of the present invention comprises an intermediate frequency amplifier C, an intermediate frequency attenuator C, a temperature control attenuator B, an intermediate frequency amplifier D, and a low pass filter F;

and the signals processed and output by the intermediate frequency filtering unit are processed by the intermediate frequency amplifier C, the intermediate frequency attenuator C, the temperature control attenuator B, the intermediate frequency amplifier D and the low-pass filter F in sequence to obtain required intermediate frequency signals and output the intermediate frequency signals.

The utility model discloses have following advantage and beneficial effect:

1. the utility model discloses a module carries on the support is divided to the merit, realizes the interconnection of all the other modules, and same local oscillator and control are used to a plurality of products, and make full use of product space does not need unnecessary product support or quick-witted case, the volume of reduction product that can be great.

2. The utility model discloses common local oscillator and crystal oscillator are used to the multichannel, greatly reduced product consumption.

3. The utility model can change the volume and power consumption of the product according to different use environments and requirements of customers; the utility model has the advantages of ultra-high dynamic range, monitoring sensitivity and anti-interference ability; the utility model discloses can realize the switching of the multiple intermediate frequency of multiple bandwidth.

Drawings

The accompanying drawings, which are included to provide a further understanding of the embodiments of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the principles of the invention. In the drawings:

fig. 1 is a schematic block diagram of a receiver according to the present invention.

Fig. 2 is a schematic diagram of the power distribution module structure of the present invention.

Fig. 3 is a schematic structural diagram of the frequency conversion module of the present invention.

Reference numbers and corresponding part names in the drawings:

1-filter A, 2-single-pole multi-throw switch A, 3-low noise amplifier A, 4-radio frequency attenuator A, 5-single-pole multi-throw switch B, 6-single-pole multi-throw switch C, 7-radio frequency preselector group A, 8-single-pole multi-throw switch D, 9-low noise amplifier B, 10-filter B, 11-mixer A, 12-filter C, 13-intermediate frequency filter A, 14-intermediate frequency amplifier A, 15-intermediate frequency filter B, 16-intermediate frequency attenuator A, 17-mixer B, 18-intermediate frequency filter C, 19-intermediate frequency amplifier B, 20-intermediate frequency attenuator B, 21-temperature controlled attenuator A, 22-low pass filter E, 23-single-pole multi-throw switch E, 24-intermediate frequency filter D, 25-intermediate frequency filter E, 26-intermediate frequency filter F, 27-single pole multiple throw switch F, 28-intermediate frequency amplifier C, 29-intermediate frequency attenuator C, 30-temperature controlled attenuator B, 31-intermediate frequency amplifier D, 32-low pass filter F.

Detailed Description

Hereinafter, the terms "include" or "may include" used in various embodiments of the present invention indicate the existence of the functions, operations or elements of the present invention, and do not limit the addition of one or more functions, operations or elements. Furthermore, as used in various embodiments of the present invention, the terms "comprises," "comprising," "includes," "including," "has," "having" and their derivatives are intended to refer only to the particular feature, number, step, operation, element, component, or combination of the foregoing, and should not be construed as first excluding the existence of, or adding to, one or more other features, numbers, steps, operations, elements, components, or combination of the foregoing.

In various embodiments of the present invention, the expression "or" at least one of a or/and B "includes any or all combinations of the words listed simultaneously. For example, the expression "a or B" or "at least one of a or/and B" may include a, may include B, or may include both a and B.

Expressions (such as "first", "second", and the like) used in various embodiments of the present invention may modify various constituent elements in various embodiments, but may not limit the respective constituent elements. For example, the above description does not limit the order and/or importance of the elements described. The foregoing description is for the purpose of distinguishing one element from another. For example, the first user device and the second user device indicate different user devices, although both are user devices. For example, a first element could be termed a second element, and, similarly, a second element could be termed a first element, without departing from the scope of various embodiments of the present invention.

It should be noted that: if it is described that one constituent element is "connected" to another constituent element, the first constituent element may be directly connected to the second constituent element, and a third constituent element may be "connected" between the first constituent element and the second constituent element. In contrast, when one constituent element is "directly connected" to another constituent element, it is understood that there is no third constituent element between the first constituent element and the second constituent element.

The terminology used in the various embodiments of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the various embodiments of the invention. As used herein, the singular forms are intended to include the plural forms as well, unless the context clearly indicates otherwise. Unless otherwise defined, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the various embodiments of the present invention belong. The terms (such as those defined in commonly used dictionaries) should be interpreted as having a meaning that is consistent with their contextual meaning in the relevant art and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein in various embodiments of the present invention.

To make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail below with reference to the following examples and drawings, and the exemplary embodiments and descriptions thereof of the present invention are only used for explaining the present invention, and are not intended as limitations of the present invention.

Examples

Compared with the existing multi-channel receiver, which has the problems of large power consumption, poor performance, weak anti-interference capability, narrow coverage frequency band range and the like, the embodiment provides the multi-channel low-power-consumption broadband receiver. The receiver of the embodiment comprises an N-path frequency conversion module, a local oscillator module, a correction module and a power division module; the N paths of frequency conversion modules have the same function and structure, wherein N is a positive integer greater than or equal to 2; the local oscillator module and the correction module are used for generating local oscillator signals, and the local oscillator signals are respectively supplied to each path of frequency conversion module through the power division module; and the N-path frequency conversion module, the local oscillation module and the correction module are connected with each other in a whole machine mode through the power division module.

Specifically, as shown in fig. 1-3, the receiver of this embodiment mainly includes a 9-way 20M-8G frequency conversion module (that is, N of this embodiment takes the value of 9), a local oscillation module, a correction module, and a power division module.

Local oscillator signals are respectively supplied to each module through power division, the power divider is used as a rack for complete machine assembly, specifically as shown in fig. 2, a multichannel receiver is interconnected through the power divider, two channels to 9 (even more) channels can be simultaneously operated, and only a small area in each receiving module (frequency conversion module) has a local oscillator large signal, so that a local oscillator loop and a crystal oscillator are removed, the signal shielding difficulty in the receiving system is greatly reduced, the anti-interference capability and the electromagnetic compatibility of products are obviously improved, real-time signals and small signals can be more accurately monitored, and the signals are accurately positioned.

The receiver of the embodiment only uses one crystal oscillator and one local oscillator loop, and is divided into a plurality of channels through the passive power divider, so that the product power consumption is greatly reduced, and each receiving channel is provided with a turn-off system, so that the product power consumption is fully controlled. The system can also realize different power consumption and weight without different volumes and different scenes by changing to different versions according to the requirements of customers on signal quality.

The 9 frequency conversion modules of this embodiment have the same structure and function, wherein each frequency conversion module includes a gain control unit, a radio frequency preselector unit, a low noise amplifier B, a filter B, a mixer a, an intermediate frequency filtering and gain control unit, a mixer B, two intermediate frequency filtering and gain control units, an intermediate frequency filtering unit, and an output unit.

In the embodiment, 20M-8G radio frequency signals from the antenna are subjected to initial filtering and gain control processing through the gain control unit;

the signals processed by the gain control unit are subjected to segmented filtering processing through a radio frequency preselector unit;

the signal processed by the radio frequency preselector unit is processed by a low noise amplifier B and a filter B in sequence and then input to a mixer A;

the mixer A mixes the input radio frequency signal with a local oscillation signal generated by a local oscillation module and outputs an intermediate frequency signal;

an intermediate frequency signal is input into the mixer B after being filtered and gain-controlled by an intermediate frequency filtering and gain control unit;

the mixer B mixes the signal output by the intermediate frequency filtering and gain control unit with a second local oscillation signal generated by the local oscillation module and outputs a second intermediate frequency signal;

the second intermediate-frequency signal is filtered and gain-controlled by a second intermediate-frequency filtering and gain-controlling unit and then input to an intermediate-frequency filtering unit for intermediate-frequency filtering;

the signal processed by the intermediate frequency filtering unit is processed by an output unit and outputs a required intermediate frequency signal.

The low-noise amplifier B of the embodiment has low noise coefficient and low power consumption, and reduces the power consumption of the whole machine and the deterioration of low signal noise.

The filter B of the present embodiment is a low-pass filter, and is mainly used for filtering harmonic signals generated after the signal is too low in the noise amplifier B.

The mixer a of this embodiment is a primary mixer, which mainly converts a broadband rf signal into two single-point-intermediate frequency signals for further filtering.

The mixer B of the present embodiment is a two-point mixer, which is mainly used to convert two single points and one intermediate frequency into the desired intermediate frequency output signal, and usually a high-intercept-point mixer is used.

The frequency conversion module of the embodiment is realized by two times of frequency conversion, 20-3600M is converted to about 5G by up-conversion, and 3600-8000M is down-converted to about 2500M intermediate frequency, so that better image frequency intermediate frequency suppression is realized, the anti-interference capability of a product is enhanced, and then two intermediate frequency signals are converted into intermediate frequency signals required by people and provided for later-stage digital processing. The frequency conversion module of the embodiment can realize ultrahigh dynamic range gain control, the low noise mode can reach ultralow noise coefficient, and the low distortion mode can greatly reduce the distortion of signals so as to ensure the receiver to carry out linear processing on signal powers with different sizes.

Specifically, as shown in fig. 3, the gain control unit of the present embodiment includes a filter a, a single-pole multi-throw switch a, a low noise amplifier a, a radio frequency attenuator a, and a single-pole multi-throw switch B;

the low noise amplifier A, the radio frequency attenuator A and the through channel are arranged between the single-pole multi-throw switch A and the single-pole multi-throw switch B in parallel;

after being filtered by a filter A, 20M-8G radio frequency signals from an antenna are selected by a single-pole multi-throw switch A to be input into a low noise amplifier A for processing or input into a radio frequency attenuator A for processing or not processing (direct connection), and then are selected by a single-pole multi-throw switch B for output.

The filter a of the present embodiment is a low-pass filter.

The gain control unit of the embodiment is used for realizing primary filtering and preceding-stage gain control of radio frequency signals, can achieve the highest gain control range of 45dB in a shunting mode, and can greatly improve the dynamic range of a receiver.

The radio frequency preselector unit of the embodiment comprises a single-pole multi-throw switch C, a preselection filter bank and a single-pole multi-throw switch D;

the preselection filter group is arranged between the single-pole multi-throw switch C and the single-pole multi-throw switch D;

the signals output after being processed by the gain control unit enter a preselection filter bank for segmented filtering processing by a single-pole multi-throw switch C, and then are selectively output by a single-pole multi-throw switch D. The preselection filter bank of the embodiment comprises preselection filters A-F arranged between a single-pole multi-throw switch C and a single-pole multi-throw switch D in parallel, namely, the preselection filter bank of the embodiment can better filter mirror intermediate frequency interference and second-order intermodulation signal interference by dividing 6 paths of radio frequency filtering.

An intermediate frequency filtering and gain control unit of the present embodiment includes a filter C, an intermediate frequency filter a, an intermediate frequency amplifier a, an intermediate frequency filter B, and an intermediate frequency attenuator a;

an intermediate frequency signal output by the mixer A is filtered by a filter C to remove mixing interference signals, and then is processed by the intermediate frequency filter A, the intermediate frequency amplifier A, the intermediate frequency filter B and the intermediate frequency attenuator in sequence and then is input to the mixer B.

The filter C of the present embodiment is a microstrip interdigital filter, and is used for primarily filtering an interference signal.

The intermediate frequency filter a and the intermediate frequency filter B of this embodiment can select filters with different performances according to requirements, and enhance the anti-interference capability of the receiver and the filtering capability of the image frequency signal.

The if amplifier a of this embodiment is an if amplifier, and is mainly a high-linearity low-noise amplifier, which ensures the noise and linearity range of the receiver.

The intermediate frequency attenuator A of the embodiment is used for overall gain control.

The second intermediate frequency filtering and gain control unit of the embodiment comprises an intermediate frequency filter C, an intermediate frequency amplifier B, an intermediate frequency attenuator B, a temperature control attenuator A and a low pass filter E;

the two intermediate frequency signals output by the mixer B are processed by an intermediate frequency amplifier B, an intermediate frequency attenuator B, a temperature control attenuator A and a low pass filter E in sequence after redundant intermodulation signals generated by the mixer B are filtered by the intermediate frequency filter C.

The if filter C of the present embodiment is a band pass filter, and is mainly used for filtering out the unwanted intermodulation signals generated by the mixer.

The intermediate frequency filtering unit of the embodiment comprises a single-pole multi-throw switch E, an intermediate frequency filter D, an intermediate frequency filter E, an intermediate frequency filter F and a single-pole multi-throw switch F;

the intermediate frequency filter D, the intermediate frequency filter E and the intermediate frequency filter F are arranged between the single-pole multi-throw switch E and the single-pole multi-throw switch F in parallel;

the signals processed and output by the two intermediate frequency filtering and gain control units enter an intermediate frequency filter D, an intermediate frequency filter E or an intermediate frequency filter F for filtering processing through a single-pole multi-throw switch E, and then are selectively output through the single-pole multi-throw switch F.

The output unit of the embodiment comprises an intermediate frequency amplifier C, an intermediate frequency attenuator C, a temperature control attenuator B, an intermediate frequency amplifier D and a low-pass filter F;

the signals processed and output by the intermediate frequency filtering unit are processed by the intermediate frequency amplifier C, the intermediate frequency attenuator C, the temperature control attenuator B, the intermediate frequency amplifier D and the low pass filter F in sequence to obtain required intermediate frequency signals and output the intermediate frequency signals.

The intermediate frequency amplifier B, the intermediate frequency amplifier C and the intermediate frequency amplifier D of the present embodiment are two intermediate frequency amplifiers, and a high linearity amplifier is mainly selected to ensure the linearity degree of the whole machine.

The intermediate frequency attenuator B and the intermediate frequency attenuator C of the embodiment are gain control attenuators for adjusting gain control of the whole machine.

The temperature-controlled attenuator A and the temperature-controlled attenuator B of the embodiment mainly have the function of keeping the gain consistency of the whole machine in high and low temperature states.

The low pass filter E and the low pass filter F of the present embodiment are mainly used to ensure the linearity and the matching link of the whole device.

The above-mentioned embodiments, further detailed description of the objects, technical solutions and advantages of the present invention, it should be understood that the above description is only the embodiments of the present invention, and is not intended to limit the scope of the present invention, and any modifications, equivalent substitutions, improvements, etc. made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims (10)

1. A multi-channel low-power consumption broadband receiver is characterized in that the receiver comprises an N-channel frequency conversion module, a local oscillator module, a correction module and a power division module;

the N paths of frequency conversion modules have the same function and structure, wherein N is a positive integer greater than or equal to 2;

the local oscillator module and the correction module are used for generating local oscillator signals, and the local oscillator signals are respectively supplied to each path of frequency conversion module through the power division module;

and the N paths of receiving modules, the local oscillator modules and the correction modules are connected with one another in a whole machine mode through the power division modules.

2. The multi-channel low-power-consumption broadband receiver of claim 1, wherein each frequency conversion module comprises a gain control unit, a radio frequency pre-selector unit, a low noise amplifier (B), a filter (B), a mixer (A), an intermediate frequency filtering and gain control unit, a mixer (B), a two intermediate frequency filtering and gain control unit, an intermediate frequency filtering unit and an output unit;

wherein, 20M-8G radio frequency signals from the antenna are subjected to initial filtering and gain control processing through the gain control unit;

the signals processed by the gain control unit are subjected to segmented filtering processing by the radio frequency preselector unit;

the signal processed by the radio frequency preselector unit is processed by a low noise amplifier B and a filter B in sequence and then is input into the mixer A;

the frequency mixer A mixes the input radio frequency signal with a local oscillation signal generated by the local oscillation module and outputs an intermediate frequency signal;

the intermediate frequency signal is filtered and gain-controlled by the intermediate frequency filtering and gain control unit and then is input into the mixer B;

the mixer B mixes the signal output by the intermediate frequency filtering and gain control unit with a second local oscillation signal generated by the local oscillation module and outputs a second intermediate frequency signal;

the two intermediate-frequency signals are filtered and gain-controlled by the two intermediate-frequency filtering and gain control units and then input to the intermediate-frequency filtering unit for intermediate-frequency filtering;

the signal processed by the intermediate frequency filtering unit is processed by the output unit and outputs a required intermediate frequency signal.

3. The multi-channel low-power consumption broadband receiver of claim 2, wherein the gain control unit comprises a filter A, a single-pole multi-throw switch A, a low noise amplifier A, a radio frequency attenuator A and a single-pole multi-throw switch B;

after being filtered by the filter A, 20M-8G radio frequency signals from an antenna are selected by the single-pole multi-throw switch A to be input to the low noise amplifier A for processing or input to the radio frequency attenuator A for processing or not for processing, and then are selected by the single-pole multi-throw switch B for output.

4. The multi-channel low-power-consumption broadband receiver of claim 2, wherein the radio frequency pre-selector unit comprises a single-pole multi-throw switch C, a pre-selection filter bank and a single-pole multi-throw switch D;

the pre-selection filter bank is arranged between the single-pole multi-throw switch C and the single-pole multi-throw switch D;

the signal output after being processed by the gain control unit is selected by the single-pole multi-throw switch C to enter the pre-selection filter bank for segmented filtering processing, and then is selected by the single-pole multi-throw switch D to be output.

5. The multi-channel low-power-consumption broadband receiver according to claim 4, wherein the preselection filter bank comprises a preselection filter A, a preselection filter B, a preselection filter C, a preselection filter D, a preselection filter E and a preselection filter F, which are arranged in parallel between the single-pole multi-throw switch C and the single-pole multi-throw switch D.

6. The multi-channel low-power consumption broadband receiver of claim 2, wherein the intermediate frequency filtering and gain control unit comprises a filter C, an intermediate frequency filter a, an intermediate frequency amplifier a, an intermediate frequency filter B and an intermediate frequency attenuator a;

an intermediate frequency signal output by the mixer A is filtered by the filter C to remove mixing interference signals, and then is processed by the intermediate frequency filter A, the intermediate frequency amplifier A, the intermediate frequency filter B and the intermediate frequency attenuator in sequence and then is input to the mixer B.

7. The multi-channel low-power broadband receiver of claim 6, wherein the filter B is a microstrip interdigital filter.

8. The multi-channel low-power consumption broadband receiver of claim 2, wherein the two intermediate frequency filtering and gain control units comprise an intermediate frequency filter C, an intermediate frequency amplifier B, an intermediate frequency attenuator B, a temperature control attenuator A and a low pass filter E;

and the two intermediate frequency signals output by the mixer B are processed by the intermediate frequency amplifier B, the intermediate frequency attenuator B, the temperature control attenuator A and the low pass filter E in sequence after redundant intermodulation signals generated by the mixer B are filtered by the intermediate frequency filter C.

9. The multi-channel low-power consumption broadband receiver of claim 2, wherein the intermediate frequency filtering unit comprises a single-pole multi-throw switch E, an intermediate frequency filter D, an intermediate frequency filter E, an intermediate frequency filter F and a single-pole multi-throw switch F;

the intermediate frequency filter D, the intermediate frequency filter E and the intermediate frequency filter F are arranged between the single-pole multi-throw switch E and the single-pole multi-throw switch F in parallel;

the signals processed and output by the two intermediate frequency filtering and gain control units enter the intermediate frequency filter D, the intermediate frequency filter E or the intermediate frequency filter F for filtering processing through the single-pole multi-throw switch E, and then are selectively output through the single-pole multi-throw switch F.

10. The multi-channel low-power consumption broadband receiver of claim 2, wherein the output unit comprises an intermediate frequency amplifier C, an intermediate frequency attenuator C, a temperature controlled attenuator B, an intermediate frequency amplifier D and a low pass filter F;

and the signals processed and output by the intermediate frequency filtering unit are processed by the intermediate frequency amplifier C, the intermediate frequency attenuator C, the temperature control attenuator B, the intermediate frequency amplifier D and the low-pass filter F in sequence to obtain required intermediate frequency signals and output the intermediate frequency signals.

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