KR102270670B1 - Multi-band receiver - Google Patents

Abstract

A multiband receiver according to an embodiment of the present invention includes an analog-to-digital converter for converting multiband analog radio signals into a digital baseband signal, and a first path signal by varying a sample rate and sample delay of the digital baseband signal. and a first signal extractor configured to generate a second path signal by bypassing the digital baseband signal, wherein the first signal extractor includes a sample delay difference between the first path signal and the second path signals. A first baseband signal is extracted using a difference in group delay between the first path signal and the second path signal resulting from .

Description

Multiband Receiver {MULTI-BAND RECEIVER}

The present invention relates to a wireless signal receiver that can be used in wireless communication, and more particularly, to a multi-band receiver capable of directly downconverting and receiving a plurality of signals transmitted in different bands at the same time.

Recently, a terminal of a wireless communication system accommodates new requirements for meeting various wireless standards along with a miniaturization trend. In particular, there is a need for a reception technology capable of simultaneously implementing multiple bands and multiple modes with flexibility, adaptability, and awareness. Furthermore, next-generation wireless standards will provide dynamic spectrum allocation and spectrum sharing to increase spectrum efficiency and provide better quality of service (QoS). In addition, non-contiguous frequency bands may be allocated to increase spectrum use efficiency. These requirements require a technology that can simultaneously receive signals transmitted in two or more different frequency bands through a single receiver.

Meanwhile, in recent years, at least two or more different communication standards are simultaneously accommodated in one wireless receiver, or in a communication method such as a cognitive radio communication system, while receiving a signal in an arbitrary frequency band, another arbitrary frequency A function that can scan whether a signal exists in a band is required. However, in the conventional receiver, a receiver circuit or chip must be independently provided for each mode and each frequency band or channel. Accordingly, there is a problem in that the circuit structure of the receiver is complicated and the unit price is high. Therefore, there is a need for a new type of receiver capable of supporting multiple bands and multiple modes using a single receiver circuit.

Bandpass sampling technology is considered as the best alternative to satisfy these requirements. The bandpass sampling technology is a technology that directly converts the frequency of the RF band signal to the baseband by sampling at a sampling rate that is at least twice the signal bandwidth. In the conventional bandpass sampling receiver, two sampling clocks having a relative time delay are applied to two analog-to-digital converters (hereinafter referred to as ADC), respectively, for sampling, and then aliasing using signal processing. ) was removed. However, these bandpass sampling receivers require the use of two ADCs. Accordingly, there is a problem in that hardware complexity is increased, and since a delay time between two paths is generated by using an analog device, there is a problem in that a delay time error between the paths and performance deterioration due to an imbalance in signal size occur.

It is an object of the present invention to provide a multi-band receiver capable of simultaneously down-converting and receiving multi-band signals located in an arbitrary frequency band while using only a single RF chain and a single ACDC. there is

Another object of the present invention is to provide a multi-band receiver capable of removing mutual interference and separating a desired signal even when two signals cause mutual interference in a baseband using only a single ADC.

Another object of the present invention is to provide a multi-band receiver capable of reducing complexity and cost compared to the prior art in which two ADCs are used because only a single ADC is used, and can be miniaturized.

Another object of the present invention is to solve the problem of performance degradation due to a delay time error and signal amplitude imbalance between two paths that occur in a conventional secondary bandpass sampling technique using two ADCs.

Another object of the present invention is to provide a multi-band receiver capable of receiving a signal in an arbitrary frequency band with a single receiver circuit and scanning whether a signal exists in another arbitrary frequency band.

A multiband receiver according to an embodiment of the present invention for achieving the above object includes an analog-to-digital converter for converting multiband analog radio signals into a digital baseband signal, and varying a sample rate of the digital baseband signal and sample and a first signal extractor configured to generate a first path signal by delay, and bypass the digital baseband signal to generate a second path signal, wherein the first signal extractor includes the first path signal and the second path signal. A first baseband signal is extracted by using a difference in group delay between the first path signal and the second path signal resulting from a sample delay difference between the signals.

A multiband receiver according to another embodiment of the present invention for achieving the above object includes an analog-to-digital converter for converting multiband analog radio signals into a digital baseband signal, and sample-delaying and sampling the digital baseband signal. and a first signal extractor configured to generate a first path signal by varying a rate, and to generate a second path signal by varying a sample rate of the digital baseband signal, wherein the first signal extractor includes the first path signal and the A first baseband signal is extracted by using a difference in group delay between the first path signal and the second path signals resulting from a difference in sample delay between the second path signals.

According to the present invention as described above, it is possible to simultaneously down-convert and receive multi-band signals located in an arbitrary frequency band while using only a single RF chain and a single ACDC.

According to the present invention, even when two signals cause mutual interference in baseband using only a single ADC, mutual interference can be removed and desired signals can be separated.

In addition, since only a single ADC is used, complexity and cost are reduced, and miniaturization is possible compared to the conventional technique in which two ADCs are used.

In addition, it is possible to solve problems of performance degradation due to a delay time error between two paths and a signal amplitude imbalance occurring in the conventional secondary bandpass sampling technique using two ADCs.

1 is a diagram exemplarily showing analog spectra of two signals located in an arbitrary frequency band.
2 is a block diagram schematically showing the configuration of a dual-band receiver according to the first embodiment of the present invention.
FIG. 3 is a diagram illustrating a spectrum R _A ^δ _{(f) of a first path signal D A} output from the sample rate downconverter illustrated in FIG. 2 .
4 is a view showing the spectrum ^δ R _B (f) of the second path signal (DR _B) shown in Fig.
5 is a diagram illustrating a spectrum of _{the first baseband signal DR 1} output from the adder 146 of FIG. 2 .
6 is a diagram illustrating a spectrum of _{the second baseband signal DR 2} output from the adder 156 of FIG. 2 .
7 is a block diagram schematically showing the configuration of a dual-band receiver according to a second embodiment of the present invention.
8 is a block diagram schematically showing the configuration of a dual-band receiver according to a third embodiment of the present invention.
FIG. 9 is a view showing a spectrum R _A ^δ (f) of a _{first path signal D A} output from the first sample rate converter of FIG. 8 .
10 is a view showing a second sample rate spectrum ^δ R _B (f) of the second signal path _(B DR) output from the converter shown in Fig.
11 is a block diagram schematically showing a dual-band receiver according to a fourth embodiment of the present invention.

Both the foregoing general description and the following detailed description are illustrative for the purpose of providing an additional description of the claimed invention. Therefore, the present invention is not limited to the embodiments described herein and may be embodied in other forms. The embodiments introduced herein are provided so that the disclosed content may be thorough and complete, and the spirit of the present invention may be sufficiently conveyed to those skilled in the art.

The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present application, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

In this specification, when it is stated that a part includes a certain element, it means that other elements may be further included. In addition, each embodiment described and illustrated herein also includes a complementary embodiment thereof. Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a diagram exemplarily showing analog spectra of two signals located in an arbitrary frequency band. Referring to FIG. 1 , _{radio signals transmitted through two frequency bands f c1} and f _c2 may act as mutual interference in a baseband after sampling.

It may be assumed that the first analog RF signal AR ₁ has a first carrier frequency f _c1 and a first signal bandwidth B _{1 .} In addition, it may be assumed that the second analog RF signal AR ₂ has a second carrier frequency f _c2 and a second signal bandwidth B _{2 .} The spectrum R _AR1+ (f) represents the positive frequency spectrum component of the first analog RF signal AR ₁ , and the spectrum R _{AR1 -} (f) represents the negative frequency spectrum component of the first analog RF signal AR _{1 .} . And, the spectrum R _{AR2 +} (f) represents the positive frequency spectrum component of the second analog RF signal (AR ₂ ), and the spectrum R _{AR2 -} (f) is the negative frequency spectrum of the second analog RF signal (AR _{2 )} indicates the ingredients.

2 is a block diagram schematically showing a multi-band receiver according to a first embodiment of the present invention. The multiband receiver 100 of the present invention to be described below may be configured as a bandpass sampling receiver. In addition, although dual-band is illustrated as an example of multi-band here, it will be well understood that the technique of the present invention can be easily applied to a multi-band signal in which three or more signals are received. 2, the multi-band receiver 100 of the present invention includes an antenna 110, first and second analog band filters 120 and 125, an adder 127, an analog-to-digital converter 130, and a first It may include a signal extractor 140 and a second signal extractor 150 .

The antenna 110 receives an analog radio signal (Analog RF Signal) transmitted wirelessly. The received analog radio signal may include a signal transmitted in at least two or more frequency bands. Here, it has been described that the analog radio signal is transmitted through two different frequency bands, but it will be well understood by those skilled in the art that the analog radio signal may be transmitted in three or more multi-bands.

The first and second analog bandpass filters 120 and 125 may be configured as wideband bandpass filters for filtering a wideband signal. The first analog band filter 120 may be designed such _{that the passband is limited to the first bandwidth B 1 .} The first analog band filter 120 may generate a first analog RF signal AR _{1 having a first bandwidth B 1} and a first carrier frequency f _c1 as a filtering result. The second analog band filter 125 may be designed such _{that the passband is limited to the second bandwidth B 2 .} The second analog band filter 125 may generate a second analog RF signal AR _{2 having a second bandwidth B 2} and a second carrier frequency f _c2 as a filtering result. _{In an exemplary embodiment, the passbands and passbands B 1} and B ₂ set in the first and second analog band filters 120 and 125 may have fixed values or may be adjusted to different values. To this end, the first and second analog bandpass filters 120 and 125 may be configured as tunable bandpass filters (Tunable BPF).

The adder 127 adds the filtering result of the first analog bandpass filter 120 and the filtering result of the second analog bandpass filter 125 . That is, the adder 127 _{generates a multi-band analog RF signal (AR) by adding the analog RF signal (AR 1} ) and the analog RF signal (AR ₂ ), and converts the multi-band analog RF signal (AR) to an analog-digital will be passed to the transducer 130 .

The analog-to-digital converter 130 converts the multiband analog RF signal AR into a digital baseband signal DR. The analog-to-digital converter 130 will sample the multiband analog RF signal AR based on the _{sample rate f s .} Then, the sampled data is quantized by the analog-to-digital converter 130 to be output as a multi-band digital baseband signal DR.

The first signal extractor 140 and the second signal extractor 150 extract the first signal Signal_1 and the second signal Signal_2 from the digital baseband signal DR output from the analog-to-digital converter 130 . separate each

The first signal extraction unit 140 includes a sample rate up-converter 141 , a sample delay 142 , a sample rate down-converter 143 , a first digital filter 144 , a second digital filter 145 , and an adder. (146). In addition, the baseband signal DR sampled by the analog-to-digital converter 130 may be separated and processed into two signal paths. That is, the first path through the sample rate up-converter 141 , the sample delay 142 , the sample rate down-converter 143 , and the first digital filter 144 , and the second digital filter 145 through only the It is added in the adder 146 via the second path. Signals processed through the first and second paths are added by the adder 146 and output as a first signal Singal_1. The first signal Signal_1 is a baseband signal obtained by removing any one of signals transmitted in multiband.

In the first signal extraction unit 140 , the digital baseband signal DR output from the analog-to-digital converter 130 is a first path signal processed along the first path and a second path processed along the second path. separated by a signal. As a digital baseband signal (DR) travels through a first path, the sampling rate is increased N times, a certain number of samples (eg, 1 sample) is delayed, and then the sample rate is decreased by N times. is converted And the first path signal is provided to the adder 146 after being processed by the first digital filter 144 .

In addition, the digital baseband signal DR is transmitted as the second path signal along the second path. The digital baseband signal DR will only pass through the second digital filter 145 without changing the sample delay or sample rate when passing through the second path.

Here, the product of the up-sample rate (N) of the sample rate up-converter 141 included in the first path and the down-sample rate (1/N) of the sample rate down-converter 143 should be 1. That is, the sample rate of the first path signal passing through the sample rate up-converter 141 and the sample rate down-converter 143 will be the same as the sample rate at the output of the analog-to-digital converter 130 . The first path signal is delayed by the sample delay 142 positioned between the sample rate up-converter 141 and the sample rate down-converter 143 . Sample delay 142 delays the first path signal by D samples. Here, the delay magnitude D of the sample delayer 142 may be an integer greater than 0 and smaller than the denominator (N) of the downward sample rate.

The D-sample delayed signal through the sample delay 142 is down-sampled such that the sample rate is multiplied by 1/N through the sample rate down-converter 143 . The output signal of the sample rate downconverter 143 is provided to a first digital filter 144 . The digital baseband signal DR output from the analog-to-digital converter 130 is processed by the second digital filter 145 constituting the second path and provided to the adder 146 . Here, the first digital filter 144 and the second digital filter 145 are designed based on a relative sample delay difference or fractional delay between the first and second paths. The second baseband signal DR2 may be removed through the first and second digital filters 144 and 145 and the adder 146 and the first baseband signal DR1 may be extracted.

A relative sample delay difference and a fractional delay between the first and second paths appear as different group delays in multi-band signals located in different frequency bands. By using the effect of these different group delays, it is possible to separate the multiband signal even if the two signals mutually interfere in the baseband. The design of the first digital filter 144 and the second digital filter 145 is made by reflecting these characteristics.

The second signal extractor 150 may include a third digital filter 154 , a fourth digital filter 155 , and an adder 156 . The output signal of the sample rate down converter 143 may pass through a third path including a third digital filter 154 . And the baseband signal DR sampled by the analog-to-digital converter 130 is added by the adder 156 via a fourth path passing through the fourth digital filter 155 . Signals processed through the third and fourth paths are added by the adder 156 and output as a second signal Singal_2.

The baseband signal (DR _A) delivered to the third path affected by the sample delay in the second signal extraction section 150 is processed by the third digital filter 154. The fourth digital filter 155 will process _{the baseband signal DR B} transferred to the fourth path where the sample delay does not occur. Third and fourth digital filter (154, 155) may be designed to enable the removal of any of the signal using a different part of the delay effect of the baseband signal (DR _A) and the baseband signal (DR _B) .

When the output signals of each of the third to fourth digital filters 154 and 155 are added by the adder 156 , the second signal Signal_2 will be extracted.

According to the configuration of the first signal extraction unit 140 and the second signal extraction unit 150 of the present invention as described above, the first baseband signal DR ₁ and the second baseband signal DR ₂ do not interfere with each other. Even if it occurs, it is possible to completely extract each of _{the first baseband signal DR 1} and the second baseband signal DR _{2 at the same time by removing the interference.} Accordingly, it is possible to support multi-band and multi-mode by using a single receiver circuit without independently providing a separate receiver circuit for each signal band. In particular, since a single analog-to-digital converter is used in the receiver circuit of the present invention, the hardware complexity of the receiver is lowered, the directivity of the circuit is increased, and the unit price is lowered and the power consumption is reduced because the size of the receiver is reduced. .

According to this configuration, the multi-band receiver of the present invention may simultaneously receive at least two or more signals having an arbitrary frequency band and signal bandwidth with a single receiver circuit, and communication such as a Cognitive Radio communication system In this method, it is possible to provide a function of receiving a signal in an arbitrary frequency band and scanning whether a signal exists in another arbitrary frequency band.

Hereinafter, a method for designing the first to second digital filters 144 and 145 using different effects of fractional delay will be described.

FIG. 3 is a diagram exemplarily illustrating a spectrum R _A ^δ _{(f) of a first path signal D A} output from the sample rate down converter 143 illustrated in FIG. 2 . 4 is a view showing the spectrum ^δ R _B (f) of the second path signal (DR _B) corresponding to the spectrum of the baseband digital signal (DR) shown in Fig. 2 by way of example. Here, the spectrum R _A ^δ (f) of the first path signal D _A is the digital baseband signal DR by a sample rate up-converter 141 , a sample delay 142 , and a sample rate down-converter 143 . represents the spectrum of the signal processed by _A first spectral R ^δ (f) of the signal path (DR _A) is a signal adding the delayed portion of the D / N size (Fractional Delay) as compared to the second signal path. As a result, the (DR _A) 1-path signals have a treatment effect as the inclusion of the group delay (Group Delay) to the second path signal (DR _B).

The first and second baseband signals (DR _1, DR ₂₎ constituting the reference back to the spectrum, the first path signal (DR _A) shown in Figs. 3 to 4 and a second path signal (DR _B) It can be seen that interference may occur in the first and second baseband signals DR ₁ and DR _{2 constituting the baseband.} That is, the first baseband signal DR ₁ and the second baseband signal DR ₂ may cause interference with each other in the baseband. Nevertheless, the multiband receiver 100 (see FIG. 2 ) of the present invention _{removes the interference between the first and second baseband signals DR 1} , DR ₂ , and removes the interference between the first baseband signal DR ₁ and the second baseband signal DR 1 . Each of the band signals DR ₂ may be accurately extracted.

In the present invention, the first and second baseband signals (DR _1, DR ₂₎ when an interference occurs between the first and second baseband signals illustratively describes the configuration of extracting (DR _1, DR ₂₎ will be In the present invention, the first path signal (DR _A) and a second signal path _(B DR) has signal characteristics which are as follows.

The effect of the group delay due to the time delay of the first baseband signal DR ₁ included in the first path signal D _{A may be expressed by Equations 1 and 2 below.} Equation 1 represents an image component shifted from the negative band of the first baseband signal DR ₁ , and Equation 2 represents an image component shifted from the positive band of the first baseband signal DR ₁ , respectively. .

Here, n ₁ is a frequency band position index, 0, 1, 2, 3, ... It can have an integer value of . And D is the magnitude of the sample delay, and N is the conversion rate of the sample rate down-converter 143 . In addition, the effect of the group delay of the second baseband signal DR ₂ included in the first path signal D _A may be expressed by Equations 3 and 4 below. Equation 3 represents an image component shifted from the negative band of the second baseband signal DR ₂ , and Equation 4 represents an image component shifted from the positive band of the second baseband signal DR ₂ , respectively. .

Here, n ₂ is the frequency band position index of the second analog RF signal (AR ₂ ), 0, 1, 2, 3, ... It can have an integer value of . n ₁ and n ₂ are the first analog RF signal (AR ₁ ) and the second analog RF signal (AR ₂ ), respectively, the carrier frequency (f _c1 , f _c2 ) and the sample rate (f) of the ADC (130, see FIG. 2 ) _s ) can be expressed in Equation 5 below.

Here, the round function round(x) means a rounding operation of x.

_A delay difference between the above-described first path signal DRA and the second path signal DR _B and a group delay between the first baseband signal DR ₁ and the second baseband signal DR ₂ . Influence can be used to separate the signals of the two bands. For this processing, the response characteristics of the first and second digital filters 144 and 145 and the third and fourth digital filters 154 and 155 described above will be designed.

_{The spectrum R A} ^δ (f) in the first Nyquist zone band of _{the first path signal D A} output from the sample rate down converter 143 may be expressed by Equation 6 below.

And spectrum ^δ R _B (f) of in the first Nyquist zone bandwidth of the second signal path _(B DR) output from the analog-to-digital converter 130 can be expressed by Equation 7 below.

And the spectrum of the signals processed by the first and second digital filters 144 and 145 may be expressed by Equations 8 and 9 below.

And the spectrum of the output signal of the adder 146 will be expressed by Equation 10 below.

Here, in order to remove the second baseband signal DR ₂ and extract the first baseband signal DR ₁ , Equation 11 below must be satisfied.

By solving Equation 11, the frequency responses of the first and second digital filters 144 and 145 can be obtained as shown in Equations 12 and 13 below.

In the same manner, the frequency responses of the third and fourth digital filters 154 and 155 can be obtained as shown in Equations 14 and 15 below.

The relationship between the first path signal D _A and the second path signal DR _{B as} described above, and the first and second baseband signals DR ₁ and DR _{2 included in the first path signal D A} . Digital filters can be designed using the effect of the relative group delay between the two. That is, by designing the first to fourth digital filters 144 , 145 , 154 , and 155 in consideration of the group delay, it is possible to separate _{the first and second baseband signals DR 1} and DR _{2 , respectively.} In an exemplary embodiment, the first to fourth digital filters 144 , 145 , 154 , and 155 may be implemented as finite impulse response (FIR) filters.

Also, as can be seen from Equations 13 and 15, it can be seen that H _B (f) and H _D (f) are constants, not functions of frequency. Accordingly, it will be well understood that the second and fourth digital filters 145 and 155 can be easily implemented as a multiplier. In this case, the synchronous delay delaying the sample rate up-converter 141, the sample rate down-converter 143, and the delay time according to the signal processing generated during the filter processing of the first or third digital filters 144 and 154 You may be able to equip them together.

5 is a diagram illustrating a spectrum of _{the first baseband signal DR 1} output from the above-described adder 146 . Referring to FIG. 5 , it can be confirmed that _{the second baseband signal DR 2} is removed and only the first baseband signal DR _{1 is extracted. According to the present invention, the first baseband signal DR 1} may be extracted using the first and second digital filters 144 and 145 and the adder 146 .

6 is a diagram illustrating a spectrum of _{the second baseband signal DR 2} output from the above-described adder 156 . Referring to FIG. 6 , it can be seen that _{the first baseband signal DR 1} is removed and only the second baseband signal DR _{2 is extracted. The second baseband signal DR 2} may be extracted using the third and fourth digital filters 154 and 155 and the adder 156 .

7 is a block diagram schematically showing a multi-band receiver 200 according to a second embodiment of the present invention. Referring to FIG. 7, the multi-band receiver 200 of the present invention includes an antenna 210, first and second analog band filters 220 and 225, an adder 227, an analog-to-digital converter 230, and a first It may include a signal extractor 240 and a second signal extractor 250 . Here, the antenna 210, the first and second analog bandpass filters 220 and 225, the adder 227, the analog-to-digital converter 230, and the first signal extraction unit 240 are substantially identical to those of FIG. same. Accordingly, descriptions thereof will be omitted.

The first signal Signal_1 may be generated by the adder 246 by adding the outputs of the first digital filter 244 and the second digital filter 245 . The second signal Signal_2 may be extracted by subtracting the first signal Signal_1 that is the output of the adder 246 from the output of the analog-to-digital converter 230 . However, it is assumed that the first digital filter 244 and the second digital filter 245 are provided as FIR filters having a sample rate tap length K. In this case, the first signal Signal_1 , which is the output signal of the adder 246 , has a sample delay by the size of round (K/2) compared to the output of the analog-to-digital converter 230 that does not pass through the digital filter. Accordingly, if the output of the analog-to-digital converter 230 is sample-delayed by round(K/2) using the second delayer 252, it can be synchronized in the subtractor 254. When the first signal Signal_1 is subtracted from the output of the analog-to-digital converter 230 delayed by round (K/2) by the subtractor 254, the second signal Signal_2 is extracted. The spectrum of the second signal Signal_2 is shown in FIG. 6 .

8 is a block diagram schematically showing the configuration of a multi-band receiver 300 according to a third embodiment of the present invention. In addition, although two bands are exemplified here, it will be well understood that the technology of the present invention can be easily applied to a multi-band signal in which three or more signals are received. 8, the multi-band receiver 300 of the present invention includes an antenna 310, first and second analog band filters 320 and 325, an adder 327, an analog-to-digital converter 330, and a first It may include a signal extractor 340 and a second signal extractor 350 .

The antenna 310 performs a function of receiving an analog RF signal transmitted wirelessly. The received analog RF signal may include at least two or more frequency bands.

The first and second analog bandpass filters 320 and 325 may be configured as wideband bandpass filters for filtering a wideband signal. The first analog band filter 320 may be designed such _{that the passband is limited to the first bandwidth B 1 .} The first analog band filter 320 may generate a first analog RF signal AR _{1 having a first bandwidth B 1} and a first carrier frequency f _c1 as a filtering result. The second analog band filter 325 may be designed such _{that the passband is limited to the second bandwidth B 2 .} The second analog band filter 325 may generate a second analog RF signal AR _{2 having a second bandwidth B 2} and a second carrier frequency f _c2 as a filtering result. _{In an exemplary embodiment, the passbands and passbands B 1} and B ₂ set in the first and second analog band filters 320 and 325 may have fixed values or may be adjusted to different values. To this end, the first and second analog bandpass filters 320 and 325 may be configured as a tunable BPF.

The adder 327 adds the filtering result of the first analog bandpass filter 320 and the filtering result of the second analog bandpass filter 325 . The analog signals filtered by the adder 327 may be transferred to the analog-to-digital converter 330 as a multi-band analog RF signal AR.

The analog-to-digital converter 330 samples the multiband analog RF signal AR and outputs it as a digital baseband signal DR. The analog-to-digital converter 330 will sample the multiband analog RF signal AR based on the _{sample rate f s .} Then, the sampled signal is quantized by the analog-to-digital converter 330 to be output as a multi-band digital baseband signal DR.

The first signal extractor 340 and the second signal extractor 350 extract the first signal Signal_1 and the second signal Signal_2 from the digital baseband signal DR output from the analog-to-digital converter 330 . separate each

The first signal extraction unit 340 includes a sample delay 342 , a first sample rate converter 343 , a first digital filter 344 , a second sample rate converter 345 , a second digital filter 346 , An adder 347 is included. The output of the analog-to-digital converter 330 is divided into two signal paths by the first signal extraction unit 340 . That is, the output of the analog-to-digital converter 330 is separated and transferred into a first path passing through the sample delay 342 and a second path in which a delay does not occur.

Sample rate converters 343 and 345 are included in each of the first and second paths. Each of the first sample rate converter 343 and the second sample rate converter 345 may adjust the sample rate of the input signal by L/M times. That is, the sample rate f' _{s of each of the baseband signals D A} and DR _B by the analog-to-digital converter 330 and the sample rate converters 343 and 345 can be expressed by Equation 16 below. .

Here, L and M are natural numbers, and L<M. Therefore, the baseband signal (DR _A) delivered to the first digital filter 344 will have a fractional delay (Fractional Delay) of the LD / M by the sample delay 342 and a first sample rate converter (343) . This fractional delay will play a very important role in eliminating interference. In addition, the sample rate selection of the analog-to-digital converter 330 may be more flexible according to the sample rate settings of the first sample rate converter 343 and the second sample rate converter 345 .

_{The baseband signals DR A} , DR _B processed by the sample rate converters 343 , 345 are filtered by the digital filters 344 , 346 and added in an adder 347 to the baseband acting as interference. signal is removed. That is, the signal output from the adder 347 will be output as the first signal Signal_1 from which any one of the baseband signals is extracted. The response characteristics of each of the digital filters 344 and 346 will be described in detail with reference to FIGS. 9 to 10 to be described later.

The second signal extractor 350 may include a third digital filter 354 , a fourth digital filter 356 , and an adder 357 . The output signal of the first sample rate converter 343 may pass through a third path including a third digital filter 354 . And the output signal of the second sample rate converter 345 is added in the adder 357 via a fourth path including a fourth digital filter 356 . The signals processed through the third and fourth paths are added by the adder 357 and output as a second signal Singal_2.

Sample rate converters (353, 355) the baseband signal (DR _A, DR _B) processed by the base band that acts as an interference haejimyeon more in the digital filters, and filtering by the (354, 356), an adder (357) signal is removed. That is, the signal output from the adder 357 will be output as the second signal Signal_2 from which any one of the baseband signals is extracted.

FIG. 9 is a diagram exemplarily illustrating a spectrum R _A ^δ (f) of _{a first path signal D A} output from the first sample rate converter 343 of FIG. 8 . 10 is a view showing a second sample rate converter 345, the spectrum ^δ R _B (f) of the second signal path _(B DR) output from the shown in Figure 8 by way of example.

The spectrum R _A ^δ _{(f) of the first path signal D A} shown in FIG. 9 is a digital baseband signal DR that is an output of the analog-to-digital converter 330 is a sample delay 342 , and a first The spectrum of the signal processed by the sample rate converter 343 is shown. That is, the spectrum R _A ^δ (f) of the first path signal D _A is a signal to which a fractional delay of LD/M is applied. As a result, the (DR _A) 1-path signals have a treatment effect as the inclusion of the group delay (Group Delay) to the second path signal (DR _B).

Referring back to the spectrum shown in FIGS. 9 to 10 , interference may occur between the first and second baseband signals DR ₁ and DR _{2 constituting the first path signal D RA .} Also, it can be seen that baseband interference may occur between the first and second baseband signals DR ₁ and DR ₂ constituting the second path signal DR _{B .} That is, the first baseband signal DR ₁ and the second baseband signal DR ₂ may cause interference with each other in the baseband. Nevertheless, the multiband receiver 300 (refer to FIG. 8) of the present invention _{removes the interference between the first and second baseband signals DR 1} and DR ₂ and removes the interference between the first baseband signal DR ₁ and the second baseband signal DR 1 . Each of the two baseband signals DR ₂ may be accurately extracted.

In the present invention, the first and second baseband signals (DR _1, DR ₂₎ when an interference occurs between the first and second baseband signals illustratively describes the configuration of extracting (DR _1, DR ₂₎ will be In the present invention, the first path signal (DR _A) and a second signal path _(B DR) has signal characteristics which are as follows.

The effect of the group delay due to the time delay of the first baseband signal DR ₁ included in the first path signal D _{A may be expressed by Equations 17 and 18 below.} Equation 17 represents an image component shifted from the negative band of the first baseband signal DR ₁ , and Equation 18 represents an image component shifted from the positive band of the first baseband signal DR ₁ , respectively. .

In addition, the effect of the group delay of the second baseband signal DR ₂ included in the first path signal D _A may be expressed by Equations 19 and 20 below. Equation 19 represents an image component shifted from the negative band of the second baseband signal DR ₂ , and Equation 20 represents an image component shifted from the positive band of the second baseband signal DR ₂ , respectively. .

Here, n ₁ and n ₂ are the frequency band position index of each of the first analog RF signal (AR ₁ ) and the second analog RF signal (AR ₂ ), 0, 1, 2, 3, ... It can have an integer value of . n ₁ and n ₂ are the carrier frequencies f _c1 , f _c2 of the first analog RF signal AR ₁ and the second analog RF signal AR ₂ , respectively, and at the outputs of the sample rate converters 343 and 345 . sample rate (f _'s) = Lf _s /M) can be expressed by Equation 21 below.

Here, the round function round(x) means a rounding operation of x.

The above-described first path signal (DR _A) and the second path signal (DR _B) the group delay (Group delay) between the delay difference between the first baseband signal (DR ₁₎ and the second baseband signal (DR ₂₎ Effect can be used to separate the signals of the two bands. That is, the interference between the two signals may be removed through the design of the first and second digital filters 344 and 346 and the third and fourth digital filters 354 and 356 described above.

In the following, the first path signal to remove the interference from (DR _A) and a second signal path _(B DR) and will be described in the method of designing a digital filter (344, 346) for extracting the desired signal. _{First, the spectrum R A} ^δ (f) in the first Nyquist zone band of _{the first path signal D A} output from the first sample rate converter 343 may be expressed by Equation 22 below.

And the second spectrum ^δ R _B (f) in the first Nyquist zone bandwidth of the sample rate of the second signal path _(B DR) output from the converter 345 can be expressed by Equation 23 below.

And the spectrum of the signals processed by the first and second digital filters 344 and 345 may be expressed by Equations 24 and 25 below.

And the spectrum of the output signal of the adder 347 will be expressed by Equation 26 below.

Here, in order to remove the second baseband signal DR ₂ and extract the first baseband signal DR ₁ , Equation 27 below must be satisfied.

By solving Equation 27, the frequency responses of the first and second digital filters 344 and 346 can be obtained as shown in Equations 28 and 29 below.

In the same manner, the design of the third and fourth digital filters 354 and 356 may be possible.

The relationship between the first path signal D _A and the second path signal DR _{B as} described above, and the first and second baseband signals DR ₁ and DR _{2 included in the first path signal D A} . The effect of the relative group delay between the two is used in the design of the digital filter. By designing the first to fourth digital filters 344 , 346 , 354 , and 356 using the group delay, each of the first and second baseband signals DR ₁ and DR ₂ may be separated. In an exemplary embodiment, the first to fourth digital filters 344 , 346 , 354 , and 356 may be configured as finite impulse response (FIR) filters.

Also, as can be seen from Equation 29 above, H _B (f) is a constant, not a function of frequency. Accordingly, it can be seen that the second and fourth digital filters 346 and 356 can be easily implemented as a multiplier. In addition, it may be provided with a synchronous delay delay by the delay time generated in the filter processing process by the first digital filter 344.

The first and fourth digital filters 344 , 346 , 354 , 356 designed in the above manner have an operating frequency f' _s = Lf _s /M). And the coefficients of the digital filters according to the two radio frequency bands (B ₁ , B _{2 ) may be recalculated.} In addition, by resetting the first and fourth digital filters 344 , 346 , 354 , and 356 using the recalculated filter coefficients, multi-band signals located in an arbitrary band may be received.

11 is a block diagram schematically showing the configuration of a multi-band receiver 400 according to a fourth embodiment of the present invention. 11, the multi-band receiver 400 of the present invention includes an antenna 410, first and second analog band filters 420 and 425, an adder 427, an analog-to-digital converter 430, and a first It may include a signal extractor 440 and a second signal extractor 450 . Here, the antenna 410, the first and second analog bandpass filters 420 and 425, the adder 427, the analog-to-digital converter 430, and the first signal extraction unit 440 are substantially the same as those of FIG. same. Accordingly, descriptions thereof will be omitted.

The first signal Signal_1 may be generated by the adder 447 by adding the outputs of the first digital filter 444 and the second digital filter 446 . In addition, the second signal Signal_2 may be extracted by subtracting the first signal Signal_1 that is the output of the adder 447 from the output of the analog-to-digital converter 430 . However, it is assumed that the first digital filter 444 and the second digital filter 446 are provided as an FIR filter having a tap length K. Then, the first signal Signal_1, which is the output signal of the adder 447, has a sample delay by the size of round (K/2) compared to the output of the second sample rate converter 445 that does not pass through the digital filter. Therefore, if the output of the second sample rate converter 445 is delayed by a sample by round (K/2) using the second delayer 452, it can be synchronized in the subtractor 454 . When the first signal Signal_1 is subtracted from the output of the second sample rate converter 445 delayed by round (K/2) by the subtractor 454, the second signal Signal_2 is extracted.

So far, the present invention has been looked at with respect to preferred embodiments thereof. Those of ordinary skill in the art to which the present invention pertains will understand that the present invention can be implemented in a modified form without departing from the essential characteristics of the present invention. Therefore, the disclosed embodiments should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is indicated in the claims rather than the foregoing description, and all differences within the scope equivalent thereto should be construed as being included in the present invention.

On the other hand, it is apparent to those skilled in the art that the structure of the present invention can be variously modified or changed without departing from the scope or technical spirit of the present invention. In view of the foregoing, it is contemplated that the present invention includes such modifications and variations of the present invention provided that they fall within the scope of the following claims and their equivalents.

Claims (20)

an analog-to-digital converter for converting multiband analog radio signals into digital baseband signals; And
a first signal extracting unit generating a first path signal by varying a sample rate of the digital baseband signal and delaying the sample, and bypassing the digital baseband signal to generate a second path signal;
The first signal extraction unit:
a first sample rate converter for changing a sample rate of the digital baseband signal by N times;
a sample delay delaying the output of the first sample rate converter by at least one sample unit; and
a second sample rate converter for outputting the first path signal by varying the sample rate of the output from the sample delayer by 1/N,
The first signal extractor extracts a first baseband signal by using a difference in group delay between the first path signal and the second path signal resulting from a sample delay difference between the first path signal and the second path signal. multiband receiver. The method of claim 1,
The first signal extraction unit:
a first digital filter for filtering the first path signal;
a second digital filter for filtering the second path signal; And
and an adder for adding the filtering result of the first digital filter and the filtering result of the second digital filter to output the first baseband signal. 3. The method of claim 2,
and the second digital filter includes a multiplier for amplifying the digital baseband signal with a specific gain. 4. The method of claim 3,
and a synchronous delayer for delaying the digital baseband signal by a specific delay time and providing it to the multiplier. 3. The method of claim 2,
and the adder is configured as a subtractor for outputting the first baseband signal by subtracting the filtering result of the second digital filter from the filtering result of the first digital filter. an analog-to-digital converter for converting multiband analog radio signals into digital baseband signals;
a first signal extracting unit generating a first path signal by varying a sample rate of the digital baseband signal and delaying the sample, and bypassing the digital baseband signal to generate a second path signal; And
a second signal extraction unit providing the first path signal as a third path signal and bypassing the digital baseband signal as a fourth path signal;
The first signal extractor extracts a first baseband signal by using a difference in group delay between the first path signal and the second path signal resulting from a sample delay difference between the first path signal and the second path signal. and
The second signal extractor extracts a second baseband signal by using a difference in group delay between the third path signal and the fourth path signal resulting from a sample delay difference between the third path signal and the fourth path signal. multiband receiver. 7. The method of claim 6,
The second signal extraction unit:
a third digital filter for filtering the third path signal;
a fourth digital filter for filtering the fourth path signal; And
and an adder for adding the filtering result of the third digital filter and the filtering result of the fourth digital filter and outputting the added result as the second baseband signal. 8. The method of claim 7,
and the fourth digital filter includes a multiplier for amplifying the digital baseband signal with a specific gain. 9. The method of claim 8,
and a synchronous delay delay delaying the digital baseband signal by a specific delay time and providing it to the multiplier. 8. The method of claim 7,
and the adder is configured as a subtractor for outputting the second baseband signal by subtracting the filtering result of the fourth digital filter from the filtering result of the third digital filter. an analog-to-digital converter for converting multiband analog radio signals into digital baseband signals;
A first path signal is generated by varying a sample rate of the digital baseband signal and a sample delay, and a second path signal is generated by bypassing the digital baseband signal, the first path signal and the second path signal a first signal extraction unit for extracting a first baseband signal using a difference in group delay between the first path signal and the second path signal resulting from a difference in sample delay between the two; And
and a second signal extraction unit for outputting a second baseband signal by subtracting a signal delaying the second path signal by a specific length from the first baseband signal. 12. The method of claim 11,
The second signal extraction unit:
a second sample delay delaying the second path signal by the specific length; And
and a subtractor for subtracting an output of a second sample delay from the first baseband signal. an analog-to-digital converter for converting multiband analog radio signals into digital baseband signals; And
a first signal extracting unit for generating a first path signal by sample-delaying the digital baseband signal and varying a sample rate, and generating a second path signal by changing the sample rate of the digital baseband signal;
The first signal extraction unit:
a sample delay delaying the digital baseband signal by at least one sample unit (D and D are natural numbers);
a first sample rate converter for applying a partial delay to a first path signal by varying a sample rate of an output signal of the sample delayer by a factor of L/M (L<M, L, M are natural numbers); and
a second sample rate converter for applying a partial delay to a second path signal by varying the sample rate of the digital baseband signal by L/M times;
The first signal extractor extracts a first baseband signal by using a difference in group delay between the first path signal and the second path signal resulting from a sample delay difference between the first path signal and the second path signal. multiband receiver. 14. The method of claim 13,
The first signal extraction unit:
a first digital filter for filtering the first path signal;
a second digital filter for filtering the second path signal; And
and an adder for adding the filtering result of the first digital filter and the filtering result of the second digital filter to output the first baseband signal. 15. The method of claim 14,
and the second digital filter includes a multiplier for amplifying the digital baseband signal with a specific gain. an analog-to-digital converter for converting multiband analog radio signals into digital baseband signals;
a first signal extractor for generating a first path signal by sample-delaying the digital baseband signal and varying a sample rate, and generating a second path signal by changing the sample rate of the digital baseband signal; And
and a second signal extraction unit providing the first path signal as a third path signal and providing the second path signal as a fourth path signal,
The first signal extractor extracts a first baseband signal by using a difference in group delay between the first path signal and the second path signal resulting from a sample delay difference between the first path signal and the second path signal. and,
The second signal extractor extracts a second baseband signal by using a difference in group delay between the third path signal and the fourth path signal resulting from a sample delay difference between the third path signal and the fourth path signal. multiband receiver. 17. The method of claim 16,
The second signal extraction unit:
a third digital filter for filtering the third path signal;
a fourth digital filter for filtering the fourth path signal; And
and an adder for adding the filtering result of the third digital filter and the filtering result of the fourth digital filter and outputting the added result as the second baseband signal. 18. The method of claim 17,
and the fourth digital filter includes a multiplier for amplifying the digital baseband signal with a specific gain. an analog-to-digital converter for converting multiband analog radio signals into digital baseband signals;
The digital baseband signal is sample-delayed and the sample rate is varied to generate a first path signal, and the digital baseband signal is generated as a second path signal by varying the sample rate, the first path signal and the second path a first signal extraction unit for extracting a first baseband signal using a difference in group delay between the first path signal and the second path signal resulting from a difference in sample delay between signals; And
and a second signal extracting unit for outputting a second baseband signal by subtracting a signal delaying the second path signal by a specific length from the first baseband signal. 20. The method of claim 19,
The second signal extraction unit:
a second sample delay delaying the second path signal by the specific length; And
and a subtractor for subtracting the output of the second sample delay from the first baseband signal.

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