JP2018524884A - Signal receiving method and apparatus, communication device, program, and recording medium - Google Patents

Abstract

The present invention discloses a signal receiving method and apparatus, and a communication device. In the method, a receiving antenna receives a signal and outputs the signal to a frequency selection filter, the frequency selection filter outputs a signal in a different band to a corresponding transmission branch, and the transmission branch is sequentially connected. The signal is processed by the variable gain amplifier and the noise suppression filter and then output to the multiplexer, and the multiplexer processes the input signal of each transmission branch and then outputs the signal to the RF sampler. And the RF sampler processes the multiplexer and then outputs it to a signal processing device within the device.

Description

  Although the present invention relates to the field of signal reception, it is not limited to this.

  With increasing demand for multiband and integration of wireless communication systems, base station systems are evolving towards the trend of small size, high bandwidth and multiband. The requirement for a multiband receiver is realized in the prior art as follows. That is, as shown in FIG. 1, the bandwidth of the intermediate frequency gain variable amplifier and the bandwidth of the receiving ADC (Analog-to-Digital Converter) are limited, and the gain of the transmission branch for each band. Because there is a request to control the transmission independently, it has been realized by single-replicating a single-band transmission branch. According to this method, the number of elements to be used, the occupied area, and the power consumption increase, and there is a problem that the request for downsizing the base station is not satisfied. For this reason, the prior art multiband receiving method has poor applicability.

  The following is a summary of the subject matter described in detail herein. This summary is not intended to limit the scope of the claims.

  The present invention provides a signal receiving method and apparatus, and a communication device for solving a problem of poor applicability of the prior art.

The present invention provides a signal receiving method, the method comprising:
The receiving antenna receives the multiband signal and outputs it to the frequency selective filter;
The frequency selective filters each outputting different band signals to corresponding transmission branches;
The transmission branch performs a gain process and a noise suppression process on a signal by a gain variable amplifier and a noise suppression filter that are sequentially connected, and then outputs the signal to a multiplexer; and
The multiplexer combines the output signals of a plurality of transmission branches, and then outputs the multiplexed signal to an RF sampler;
The RF sampler includes a step of converting a multiband RF signal output from the multiplexer into a baseband signal.

  Optionally, the transmission branch further includes a low noise amplifier, and an output signal of the frequency selective filter is amplified by low noise power by the low noise amplifier and then output to the variable gain amplifier.

  Alternatively, the number of bands is two, the frequency selection filter includes a reception demultiplexer frequency selection filter, and the number of transmission branches is two.

Optionally, performing a noise suppression process on the signal comprises:
The method includes the step of suppressing noise in bands other than the corresponding band in the transmission branch by calculating and controlling the degree of suppression of the noise suppression filter in each transmission branch.

Optionally, there are two bands, the first band and the second band, the number of transmission branches is 2, and the first transmission branch and the second transmission branch are two. Yes, the first band corresponds to the first transmission branch, the second band corresponds to the second transmission branch,
The degree of suppression A1 in the frequency range of the second band of the noise suppression filter in the first transmission branch is A1 = NF1-NF2 + X2 + Y1,
The degree of suppression A2 in the frequency range of the first band of the noise suppression filter in the second transmission branch is A2 = NF2-NF1 + X1 + Y2,
Where NF1 is the noise factor of the first band link, and when the first band is blocked, NF1 is the noise factor of the link after the gain of the first band is attenuated; NF2 Is the noise factor of the second band link, and if the second band is blocked, NF2 is the noise factor of the link after the gain of the second band is attenuated; X1 is the first Is the gain attenuation of the first transmission branch when the second band is blocked; X2 is the gain attenuation of the second transmission branch when the second band is blocked; Y1 and Y2 Is a preset value greater than zero.

Optionally, performing gain processing on the signal comprises:
Based on the output power of the RF sampler and the output power of each transmission branch, the attenuation amount of the variable gain amplifier in each transmission branch is calculated and controlled, and the output power of the RF sampler is set to a gain callback threshold and an attenuation threshold. And the difference between the output powers of the transmission branches is made smaller than a preset value.

Furthermore, the present invention provides a signal receiving device,
In a signal reception apparatus including a reception antenna, a frequency selection filter, at least two transmission branches, a multiplexer and an RF sampler, wherein the transmission branch includes a gain variable amplifier and a noise suppression filter connected in sequence.
The receiving antenna is configured to receive a multiband signal and output it to a frequency selective filter;
An input terminal of the frequency selection filter is connected to the reception antenna, the frequency selection filter includes a plurality of output terminals having different output bands, and each output terminal is connected to an input terminal of a corresponding transmission branch, and the frequency selection filter Are configured to output different band signals to the corresponding transmission branches, respectively.
The variable gain amplifier is configured to perform gain processing on a signal;
The noise suppression filter is configured to perform noise suppression processing on a signal,
An output end of the transmission branch is connected to an input end of the multiplexer, an output end of the multiplexer is connected to an input end of the RF sampler, and the multiplexer receives output signals of a plurality of transmission branches. After combining, it is configured to output to the RF sampler,
The RF sampler is configured to convert a multiband RF signal output from the multiplexer into a baseband signal.

  Optionally, the transmission branch further includes a low noise amplifier, and an input terminal of the low noise amplifier is connected to an output terminal of the frequency selective filter, and an output terminal of the low noise amplifier is an input terminal of the variable gain amplifier. The low noise amplifier is configured to amplify low noise power with respect to the output signal of the frequency selective filter.

  Alternatively, the number of bands is two, the frequency selection filter includes a reception demultiplexer frequency selection filter, and the number of transmission branches is two.

  Optionally, a calculation module is further included, and the calculation module suppresses other bands than the corresponding band in the transmission branch by calculating and controlling the degree of suppression of the noise suppression filter in each transmission branch. Configured to do.

Optionally, there are two bands, the first band and the second band, the number of transmission branches is 2, and the first transmission branch and the second transmission branch are two. Yes, the first band corresponds to the first transmission branch, the second band corresponds to the second transmission branch,
The calculation module
The suppression degree A1 of the noise suppression filter in the first transmission branch in the frequency range of the second band is controlled to A1 = NF1-NF2 + X2 + Y1,
The noise suppression filter in the second transmission branch is configured to control the suppression degree A2 in the frequency range of the first band to A2 = NF2-NF1 + X1 + Y2,
Where NF1 is the noise factor of the first band link, and when the first band is blocked, NF1 is the noise factor of the link after the gain of the first band is attenuated; NF2 Is the noise factor of the second band link, and if the second band is blocked, NF2 is the noise factor of the link after the gain of the second band is attenuated; X1 is the first X2 is the gain attenuation of the first transmission branch when the band is blocked; X2 is the gain attenuation of the second transmission branch when the second band is blocked; Y1 and Y2 , A preset value greater than zero.

  Optionally, the signal receiving apparatus further includes a control module, and the control module determines the attenuation amount of the gain variable amplifier in each transmission branch based on the output power of the RF sampler and the output power of each transmission branch. Configured to calculate and control to cause the output power of the RF sampler to be between a gain callback threshold and an attenuation threshold and to make the difference in output power of each transmit branch less than a preset value .

  Furthermore, the present invention provides a communication device, and the communication device includes the signal receiving apparatus.

  According to an embodiment of the present invention, there is provided a signal receiving method capable of simultaneously receiving signals in multiple bands, and since transmission branches are independent from each other, even when a blocking signal exists in one band, The reception sensitivity performance can be achieved, the architecture is simple, the power consumption and the occupied area of the PCB are low, contribute to the miniaturization of the base station, and improve the applicability of the multiband reception technology.

  Upon reading and understanding the drawings and detailed description, other aspects of the invention can be understood.

It is a schematic diagram which shows the structure of the signal receiving apparatus of a prior art. It is a schematic diagram which shows the structure of the signal receiver which concerns on 1st Example of this invention. It is a flowchart which shows the signal reception method which concerns on 2nd Example of this invention. It is a schematic diagram which shows the structure of the signal receiver which concerns on the 3rd Example of this invention. It is a flowchart which shows the signal reception method which concerns on 3rd Example of this invention.

In the following, embodiments of the present invention are interpreted and described with reference to the drawings.
First embodiment:

  FIG. 2 is a schematic diagram showing the configuration of the signal receiving apparatus according to the first embodiment of the present invention. As shown in FIG. 2, in this embodiment, the signal receiving apparatus 1 according to the embodiment of the present invention includes a receiving antenna 11, a frequency selective filter 12, at least two transmission branches 13, a multiplexer 14 and an RF. (Radio Frequency) includes a sampler 15; each of the transmission branches 13 includes a sequentially variable gain amplifier 131 and a noise suppression filter 132; the frequency selection filter 12 has an input end connected to the receiving antenna 11, and The output terminals include a plurality of output terminals having different output bands, and each output terminal is connected to the input terminal of the corresponding transmission branch 13; the output terminal of the transmission branch 13 is connected to the input terminal of the multiplexer 14; The output end is connected to the input end of the RF sampler 15, and the output end of the RF sampler 15 is connected to a signal processing device in the device.

Here, the receiving antenna 11 is configured to receive a multiband signal and output it to the frequency selective filter 12;
The frequency selective filter 12 is configured to output signals of different bands to the corresponding transmission branches 13, respectively.
The variable gain amplifier 131 is configured to perform gain processing on a signal,
The noise suppression filter 132 is configured to perform noise suppression processing on a signal,
The multiplexer 14 is configured to combine the output signals of a plurality of transmission branches and output the resultant to the RF sampler 15;
The RF sampler 15 is configured to convert the multiband RF signal output from the multiplexer 14 into a baseband signal.

  In one embodiment, the transmission branch 13 in the above embodiment further includes a low noise amplifier, the input terminal of the low noise amplifier is connected to the output terminal of the frequency selective filter 12, and the output terminal of the low noise amplifier is the variable gain amplifier 131. The low noise amplifier is configured to amplify the output signal of the frequency selective filter 12 with low noise power.

  In one embodiment, there are two bands in the above embodiment, the frequency selection filter 12 includes a reception demultiplexer frequency selection filter, and the number of transmission branches 13 is two.

  In one embodiment, the signal receiving device 1 in the above embodiment further includes a calculation module, and the calculation module calculates and controls the degree of suppression of the noise suppression filter in each transmission branch 13, thereby controlling the inside of the transmission branch. Are configured to suppress noise in other bands than the corresponding band.

In one embodiment, there are two bands, a first band and a second band, the number of transmission branches is two, and two bands, a first transmission branch and a second transmission branch. The first band corresponds to the first transmission branch, the second band corresponds to the second transmission branch,
The calculation module
The suppression degree A1 of the noise suppression filter in the first transmission branch in the frequency range of the second band is controlled to A1 = NF1-NF2 + X2 + Y1,
The noise suppression filter in the second transmission branch is configured to control the suppression degree A2 in the frequency range of the first band to A2 = NF2-NF1 + X1 + Y2,
Where NF1 is the noise factor of the first band link, and when the first band is blocked, NF1 is the noise factor of the link after the gain of the first band is attenuated; NF2 is the noise factor of the second band link, and if the second band is blocked, NF2 is the noise factor of the link after the gain of the second band is attenuated; X1 is The gain attenuation of the first transmission branch when the first band is blocked; X2 is the gain attenuation of the second transmission branch when the second band is blocked; Y1 And Y2 are preset values greater than zero.

  In one embodiment, the signal receiving apparatus 1 in the above embodiment further includes a control module, and the control module can change the gain in each transmission branch 13 based on the output power of the RF sampler 15 and the output power of each transmission branch 13. The attenuation amount of the amplifier 131 is calculated and controlled so that the output power of the RF sampler 15 exists between the gain callback threshold value and the attenuation threshold value, and the difference between the output power values of the transmission branches 13 is set to a preset value. Configured to be smaller.

Correspondingly, according to an embodiment of the present invention, a communication device is further provided, the communication device including a signal receiving apparatus according to an embodiment of the present invention. Generally, the communication device is a device such as a base station.
Second embodiment:

  FIG. 3 is a flowchart showing a signal receiving method according to the second embodiment of the present invention. As shown in FIG. 3, in the present embodiment, the signal receiving method according to the embodiment of the present invention includes the following steps.

  S301: The receiving antenna receives a multiband signal and outputs it to a frequency selection filter.

  S302: The frequency selection filter outputs signals of different bands to the corresponding transmission branches.

  S303: The transmission branch performs gain processing and noise suppression processing on the signal by the sequentially connected variable gain amplifier and noise suppression filter, and then outputs the signal to the multiplexer.

  S304: The multiplexer multiplexes the output signals of a plurality of transmission branches, and then outputs them to the RF sampler.

  S305: The RF sampler converts the multiband RF signal output from the multiplexer into a baseband signal.

  In one embodiment, the transmission branch in the above embodiment further includes a low noise amplifier, and the output signal of the frequency selective filter is amplified by low noise power by the low noise amplifier and then output to the variable gain amplifier.

  In one embodiment, the number of bands in the above embodiment is two, the frequency selection filter includes a reception demultiplexer frequency selection filter, and the number of transmission branches is two.

  In one embodiment, the step of performing noise suppression processing on a signal includes calculating and controlling a degree of suppression of the noise suppression filter in each transmission branch, so that a band other than the corresponding band in the transmission branch is obtained. The step of suppressing the noise.

In one embodiment, there are two bands, a first band and a second band, the number of transmission branches is two, and two bands, a first transmission branch and a second transmission branch. The first band corresponds to the first transmission branch, the second band corresponds to the second transmission branch,
The degree of suppression A1 in the frequency range of the second band of the noise suppression filter in the first transmission branch is A1 = NF1-NF2 + X2 + Y1,
The degree of suppression A2 in the frequency range of the first band of the noise suppression filter in the second transmission branch is A2 = NF2-NF1 + X1 + Y2,
Where NF1 is the noise factor of the first band link, and when the first band is blocked, NF1 is the noise factor of the link after the gain of the first band is attenuated; NF2 Is the noise factor of the second band link, and when the second band is blocked, NF2 is the noise factor of the link after the gain of the second band is attenuated; X2 is the gain attenuation of the first transmission branch when the first band is blocked; X2 is the gain attenuation of the second transmission branch when the second band is blocked; Y2 is a preset value greater than zero.

In one embodiment, performing gain processing on the signal comprises:
Based on the output power of the RF sampler and the output power of each transmission branch, the attenuation amount of the variable gain amplifier in each transmission branch is calculated and controlled, and the output power of the RF sampler is calculated as a gain callback threshold and an attenuation threshold. And the difference between the output powers of the transmission branches is made smaller than a preset value.

Hereinafter, embodiments of the present invention will be described in more detail with reference to application scenarios.
Third embodiment:

  This example describes the invention in more detail in connection with application scenarios.

FIG. 4 is a schematic diagram showing the configuration of the signal receiving apparatus according to the third embodiment of the present invention. As shown in FIG. 4, in this embodiment, the signal receiving apparatus according to the embodiment of the present invention is
It includes a receiving antenna 11, a frequency selective filter 12, at least two transmission branches 13, a multiplexer 14, an RF sampler 15, a calculation module 16 and a control module 17, and each of the transmission branches 13 is connected in sequence. The low-noise amplifier 133, the variable gain amplifier 131, and the noise suppression filter 132; the frequency selection filter 12 includes a plurality of output terminals whose input terminals are connected to the receiving antenna 11 and whose output bands are different from each other. Is connected to the input end of the corresponding transmission branch 13; the output end of the transmission branch 13 is connected to the input end of the multiplexer 14; the output end of the multiplexer 14 is connected to the input end of the RF sampler 15, and RF The output end of the sampler 15 is connected to a signal processing device in the device.

  FIG. 5 is a schematic diagram showing the configuration of the signal receiving method according to the third embodiment of the present invention. As shown in FIG. 5, in the present embodiment, the signal receiving method according to the embodiment of the present invention includes the following steps.

  S501: The frequency selective filter separates the double-band signal received by the receiving antenna into the corresponding transmission branches.

  S502: The low noise amplifier performs low noise power amplification on the received small signals of the two bands.

  S503: The variable gain amplifier performs gain processing on the signal under the control of the control module.

  Here, the variable gain amplifier adjusts the gains of the two band receivers, performs gain attenuation when a large blocking signal is input, and performs gain amplification when a low sensitivity signal is input.

  This step can include the following sub-steps.

  51-1: The control module calculates the saturated power output power level of the RF sampler RFADC, where the power level refers to the sum of the power of the two bands and is variable in gain based on the peak-to-average ratio of the system signal Set attenuation threshold and attenuation stepping of amplifier AGC.

  51-2: The control module reads whether or not the power level output from the PD1 detection point has reached the attenuation threshold value. If the power level has been reached, the control module executes 51-3. 2 is executed again.

  51-3: Read the power levels of the detection point of PD2 and the detection point of PD3, and determine whether the power of the detection point of PD2 is larger than the power of the detection point of PD3 by + Z, where Z is the system design If the value is larger, 51-4 is executed; otherwise, 51-5 is executed.

  51-4: After attenuation of the variable gain amplifier in the link of band 1 according to attenuation stepping, 51-2 is executed to detect whether or not the attenuation threshold has been reached.

  51-5: It is determined whether or not the power at the detection point of PD3 is larger than the power at the detection point of PD2 by + Z. If so, 51-6 is executed, otherwise 51-7 is set. Run.

  51-6: After attenuation of the variable gain amplifier in the band 2 link according to attenuation stepping, 51-2 is executed to detect whether the attenuation threshold is reached.

  51-7: After attenuation of the variable gain amplifiers in the two-band links according to attenuation stepping, 51-2 is executed to detect whether the attenuation threshold is reached or not.

Correspondingly, this step further includes a gain callback flow. That is,
52-1: setting an appropriate gain callback threshold according to system requirements;
52-2: Read the power at the detection point of PD1 to determine whether or not the power has reached the gain callback threshold, and if so, execute 52-3, otherwise Re-executing 52-2;
52-3: It is determined whether or not the power at the detection point of PD2 is larger than the power at the detection point of PD3 by + Z. If so, 52-4 is executed, otherwise 52-7 is executed. Steps to perform;
52-4: It is determined whether or not the attenuation of the link where the band 2 is located is 0 dB. If it is 0 dB, 52-5 is executed, and if not, 52-6 is executed. Steps,
52-5: Call back gain on band 1 link with attenuated stepping as callback stepping, then re-execute 52-3;
52-6: Call back gain on band 2 link with attenuated stepping as callback stepping, then re-execute 52-3;
52-7: It is determined whether or not the power at the detection point of PD3 is larger than the power at the detection point of PD2 by + Z. If it is larger, 52-8 is executed, otherwise 52-11 is set. Steps to perform;
52-8: It is determined whether or not the attenuation of the link where the band 1 is located is 0 dB. If it is 0 dB, execute 52-9, otherwise execute 52-10. Steps,
52-9: Call back gain on band 2 link with attenuated stepping as callback stepping, then re-run 52-3;
52-10: Call back gain on band 1 link with attenuated stepping as callback stepping, then re-run 52-3;
52-11: Calling back the gains on the links of the two bands, respectively, with attenuation stepping as callback stepping, and then re-executing 52-3.

  S504: The noise suppression filter performs noise suppression filter processing under the control of the calculation module.

  The calculation module calculates the minimum gain at the sensitivity required for the transmission branches of the two bands, respectively, due to the low noise performance of the RFADC; the saturation power level of the RFADC and the blocking level in the air interface band required for the two bands Accordingly, the maximum gain in blocking necessary for the transmission branches of the two bands is calculated respectively; and the maximum value required for the gain attenuation in the case of blocking in the two bands is extracted.

Under the band 2 blocking level, the transmission branch gain attenuation is X2, the non-blocking input level in band 1 is the sensitivity signal power, and the band 1 link no attenuation noise factor is NF1. Yes, the gain is G1, the noise factor of the link after the band 2 gain is attenuated by X is NF2, the gain is G2, and the degree of suppression in the frequency range of band 2 by the band 1 filter is It is defined as A1 (plus), and the degree of suppression in the frequency range of band 1 by the filter of band 2 is defined as A2 (plus); the band before the multiplexer by the analog link where band 1 is located Calculate the thermal noise level -174 dBm / Hz + NF1 + G1-A1 in the frequency range of 2, depending on the analog link where band 2 is located, The thermal noise level −174 dBm / Hz + NF2 + G2−X2 in the frequency range of band 2 before the multiplexer is calculated. When the former thermal noise is smaller than the latter thermal noise by a predetermined amount Y1 (plus value), overlay After that, the total noise is equivalent to the thermal noise in the range of band 2 by the analog link where band 2 is located, ie
-174 dBm / Hz + NF1 + G1-A1 = -174 dBm / Hz + NF2 + G2-X2-Y1.
In this case, the obtained suppression degree request is A1 = NF1-NF2 + X2 + Y1.

Further, under the blocking level of band 1, the gain attenuation amount of the transmission branch is X1, the non-blocking input level in the band of band 2 is the sensitivity signal power, and the noise coefficient with no attenuation amount of the link of band 2 is NF2, gain is G2, and after the band 1 gain is attenuated by X1, the noise factor of the link is NF1 and the gain is G1; The degree of suppression is defined as A1 (plus), and the degree of suppression in the frequency range of band 1 by the band 2 filter is defined as A2 (plus); the multiplexing is performed by the analog link where band 2 is located. The thermal noise level −174 dBm / Hz + NF2 + G2−A2 in the frequency range of band 1 in front of the unit is calculated, and the analog signal where band 1 is located is calculated. -174 dBm / Hz + NF1 + G1-X1 which is a thermal noise level in the frequency range of band 1 before the multiplexer is calculated, and the former thermal noise is smaller than the latter thermal noise by a predetermined amount Y2 (plus value) In addition, the total noise after overlay is equivalent to the thermal noise within the range of band 2 of the analog link where band 2 is located, ie
-174 dBm / Hz + NF2 + G2-A2 = -174 dBm / Hz + NF1 + G1-X1-Y2.
In this case, the obtained degree of suppression is A2 = NF2-NF1 + X1 + Y2.

  Y1 and Y2 may be the same or different.

  By calculating the suppression degrees A1 and A2, a noise suppression filter that satisfies the suppression degree requirement is selected.

  S505: The multiplexer multiplexes the signals of the two bands, and then outputs them to the RF sampler.

  S506: The RF sampler realizes RF sampling in a large multiband and directly converts the RF signal into a baseband signal.

  In the present embodiment, the noise suppression filter suppresses the noise in the frequency range of band 2 to a certain level in the reception / transmission branch of band 1 and also maintains the noise in the frequency range of band 1 in the reception / transmission branch of band 2. To the level of. If there is a blocking signal in band 1, the gain of the receiver in band 1 performs gain attenuation to avoid power overflow of the RFADC device, and the gain of the receiver without blocking in band 2 is still The maximum gain is maintained, so that the low noise level output through the variable gain amplifier is different, and the difference between the low noise levels of the two bands is related to the gain difference of the link and NF, and through the multiplexer. After that, the noise level is a total value. When the noise powers of the two branches are greatly different, the SNR (signal-to-noise ratio) of the transmission branch having a low noise level is always affected. Therefore, the noise suppression filter is arranged in front of the multiplexer.

  It should be understood by those skilled in the art that all or some of the steps of the above embodiments can be realized by a computer program flow. The computer program can be stored on a computer readable storage medium, and the computer program is executed on a corresponding hardware platform (eg, system, device, apparatus, facility, etc.) and a method when executed. One or more combinations of the steps of the embodiments may be included.

  Alternatively, all or some of the steps of the above embodiments can also be implemented using integrated circuits, each of which can be made as one integrated circuit module, or within them. A plurality of modules or steps can be created and realized in a single integrated circuit module.

  The devices / functional modules / functional units in the above embodiments can be realized by adopting general-purpose computing devices, which may be concentrated on a single computing device or distributed over a network composed of a plurality of computing devices. Also good.

  When the device / functional module / functional unit in the above embodiment is realized in the form of a software functional module and sold or used as an independent product, it may be stored in one computer-readable recording medium. The computer-readable recording medium may be a read-only memory, a magnetic disk, an optical disk, or the like.

  By implementing the embodiment of the present invention, reception in multiple bands can be realized at the same time, and since the transmission branches are independent from each other, even if a blocking signal exists in one band, reception by the other band Sensitivity performance can be achieved. In addition, the architecture is simple, the power consumption and the area occupied by the PCB are low, which contributes to the miniaturization of the base station and improves the applicability of the multiband reception technology.

The present invention provides a signal receiving method and apparatus, a communication device , a program, and a recording medium for solving a problem that lacks applicability of the prior art.

Furthermore, the present invention provides a communication device, and the communication device includes the signal receiving apparatus.
According to another embodiment of the present invention, a program is provided, and the program is executed by a processor to realize a signal receiving method.
According to another embodiment of the present invention, a recording medium is provided, and the program is recorded on the recording medium.

Figure 5 is a flowchart illustrating a signal reception how according to a third embodiment of the present invention. As shown in FIG. 5, in the present embodiment, the signal receiving method according to the embodiment of the present invention includes the following steps.

Under the band 2 blocking level, the transmission branch gain attenuation is X2, the non-blocking input level in band 1 is the sensitivity signal power, and the band 1 link no attenuation noise factor is NF1. Yes, the gain is G1, the noise factor of the link after the band 2 gain is attenuated by X is NF2, the gain is G2, and the degree of suppression in the frequency range of band 2 by the band 1 filter is It is defined as A1 (plus), and the degree of suppression in the frequency range of band 1 by the filter of band 2 is defined as A2 (plus); the band before the multiplexer by the analog link where band 1 is located Calculate the thermal noise level -174 dBm / Hz + NF1 + G1-A1 in the frequency range of 2, depending on the analog link where band 2 is located, The thermal noise level −174 dBm / Hz + NF2 + G2−X2 in the frequency range of band 2 before the multiplexer is calculated. When the former thermal noise is smaller than the latter thermal noise by a predetermined amount Y1 (plus value), overlay After that, the total noise is equivalent to the thermal noise in the range of band 2 by the analog link where band 2 is located, ie
-174 dBm / Hz + NF1 + G1-A1 = -174 dBm / Hz + NF2 + G2-X2-Y1.
In this case, the obtained degree of suppression is A1 = NF1-NF2 + X2 + Y1.

Claims (13)

The receiving antenna receives the multiband signal and outputs it to the frequency selective filter;
The frequency selective filters each outputting different band signals to corresponding transmission branches;
The transmission branch performs gain processing and noise suppression processing on the signal by a sequentially connected variable gain amplifier and noise suppression filter, and then outputs to the multiplexer; and
The multiplexer combines the output signals of a plurality of transmission branches, and then outputs the multiplexed signal to an RF sampler;
The RF sampler includes a step of converting a multiband RF signal output from the multiplexer into a baseband signal. The transmit branch further includes a low noise amplifier;
The signal reception method according to claim 1, wherein an output signal of the frequency selective filter is output to the variable gain amplifier after being amplified with low noise power by the low noise amplifier. The band is two,
The frequency selection filter includes a reception duplexer frequency selection filter,
The signal reception method according to claim 1, wherein the number of transmission branches is two. The step of performing noise suppression processing on the signal includes:
The signal reception method according to claim 1, further comprising a step of suppressing noise in a band other than the corresponding band in the transmission branch by calculating and controlling a degree of suppression of the noise suppression filter in each transmission branch. . There are two bands, the first band and the second band, the number of transmission branches is two, the first transmission branch and the second transmission branch, and the first band. Band corresponds to the first transmission branch, the second band corresponds to the second transmission branch,
The degree of suppression A1 in the frequency range of the second band of the noise suppression filter in the first transmission branch is A1 = NF1-NF2 + X2 + Y1,
The degree of suppression A2 in the frequency range of the first band of the noise suppression filter in the second transmission branch is A2 = NF2-NF1 + X1 + Y2,
Where NF1 is the noise factor of the first band link, and when the first band is blocked, NF1 is the noise factor of the link after the gain of the first band is attenuated; NF2 Is the noise factor of the second band link, and if the second band is blocked, NF2 is the noise factor of the link after the gain of the second band is attenuated; X1 is the first Is the gain attenuation of the first transmission branch when the second band is blocked; X2 is the gain attenuation of the second transmission branch when the second band is blocked; Y1 and Y2 The signal reception method according to claim 4, wherein is a preset value greater than zero. Performing gain processing on the signal comprises:
Based on the output power of the RF sampler and the output power of each transmission branch, the attenuation amount of the variable gain amplifier in each transmission branch is calculated and controlled, and the output power of the RF sampler is set to a gain callback threshold and an attenuation threshold. The signal receiving method according to claim 1, further comprising: a step of making the difference between the output powers of the transmission branches smaller than a preset value. In a signal reception apparatus including a reception antenna, a frequency selection filter, at least two transmission branches, a multiplexer and an RF sampler, wherein the transmission branch includes a gain variable amplifier and a noise suppression filter connected in sequence.
The receiving antenna is configured to receive a multiband signal and output it to a frequency selective filter;
An input terminal of the frequency selection filter is connected to the reception antenna, the frequency selection filter includes a plurality of output terminals having different output bands, and each output terminal is connected to an input terminal of a corresponding transmission branch, and the frequency selection filter Are configured to output different band signals to the corresponding transmission branches, respectively.
The variable gain amplifier is configured to perform gain processing on a signal;
The noise suppression filter is configured to perform noise suppression processing on a signal,
An output end of the transmission branch is connected to an input end of the multiplexer, an output end of the multiplexer is connected to an input end of the RF sampler, and the multiplexer receives output signals of a plurality of transmission branches. After combining, it is configured to output to the RF sampler,
The RF sampler is configured to convert a multiband RF signal output from the multiplexer into a baseband signal. The transmit branch further includes a low noise amplifier;
An input terminal of the low noise amplifier is connected to an output terminal of the frequency selective filter, an output terminal of the low noise amplifier is connected to an input terminal of the variable gain amplifier,
The signal receiving apparatus according to claim 7, wherein the low noise amplifier is configured to amplify low noise power with respect to an output signal of a frequency selective filter. The signal receiving apparatus according to claim 7, wherein the number of bands is two, the frequency selection filter includes a reception demultiplexer frequency selection filter, and the number of transmission branches is two. Further including a calculation module;
The calculation module is configured to suppress bands other than the corresponding band in the transmission branch by calculating and controlling a degree of suppression of the noise suppression filter in each transmission branch. The signal receiving device described. There are two bands, the first band and the second band, the number of transmission branches is two, the first transmission branch and the second transmission branch, and the first band. Band corresponds to the first transmission branch, the second band corresponds to the second transmission branch,
The calculation module
The suppression degree A1 of the noise suppression filter in the first transmission branch in the frequency range of the second band is controlled to A1 = NF1-NF2 + X2 + Y1,
The noise suppression filter in the second transmission branch is configured to control the suppression degree A2 in the frequency range of the first band to A2 = NF2-NF1 + X1 + Y2,
Where NF1 is the noise factor of the first band link, and when the first band is blocked, NF1 is the noise factor of the link after the gain of the first band is attenuated; NF2 Is the noise factor of the second band link, and if the second band is blocked, NF2 is the noise factor of the link after the gain of the second band is attenuated; X1 is the first X2 is the gain attenuation of the first transmission branch when the band is blocked; X2 is the gain attenuation of the second transmission branch when the second band is blocked; Y1 and Y2 The signal receiving device according to claim 10, wherein the value is a preset value greater than zero. Further including a control module;
The control module calculates and controls the amount of attenuation of the variable gain amplifier in each transmission branch based on the output power of the RF sampler and the output power of each transmission branch, and outputs the output power of the RF sampler as a gain callback. The signal receiving device according to any one of claims 7 to 11, wherein the signal receiving device is provided between a threshold value and an attenuation threshold value, and is configured to make a difference in output power between the transmission branches smaller than a preset value. . A communication device comprising the signal receiving apparatus according to claim 7.

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