KR20110025092A - Receiving apparatus and receiving method - Google Patents

Abstract

PURPOSE: A receiving device and a receiving method for efficiently performing the down conversion of a radio frequency signal are provided to normally receive the radio frequency signal of at least one band. CONSTITUTION: A phase converting unit(120) generates phase difference between output signals of a filter unit. The phase converting unit outputs a plurality of sample signals by down-converting output signals of the filter unit. A quantizing unit(130) converts sample signals into a digital signal. A signal separating unit(140) separates a plurality of output signals by using phase difference.

Description

Receiving device and receiving method {RECEIVING APPARATUS AND RECEIVING METHOD}

The present invention relates to a receiving apparatus and a receiving method.

A receiving device of a wireless communication system receives a radio frequency (RF) signal transmitted from a transmitting device through an antenna and performs processes such as filtering, amplification, frequency conversion, and analog to digital conversion.

When performing this process by receiving an RF signal, which is an analog signal, at least twice the sampling frequency of the carrier frequency is required to apply a sampling theory. However, in general, since the bandwidth of the signal is only 0.03 to 2% of the carrier frequency, the reception process is very inefficient and the amount of data to be processed becomes excessive.

In order to solve this problem, a band pass sampling (BPS) scheme is used. In the BPS reception method, the sampling frequency is determined by the bandwidth of the signal without depending on the frequency carrier frequency, thereby enabling efficient system design. As a technique of processing an input signal as a digital signal as described above, a BPS reception method using a small bandwidth is referred to as a digital direct conversion method or an RF direct conversion method. In addition, the BPS reception method is referred to algorithmically as band pass sampling, harmonic sampling, or sub-sampling.

The BPS reception method intentionally generates aliasing using a sampling frequency lower than the Nyquist rate and has a sampling rate depending on the bandwidth of the information. In addition, the BPS reception method is based on the theory that the analog downconversion function can be replaced by sampling, and since the received signal is sampled immediately after passing a low noise amplifier (LNA), a low-cost and small-size reception device can be realized. Can be.

A receiving device of the BPS reception method can down-convert a signal having an integer position relationship between a carrier frequency and a signal bandwidth to a minimum sample rate twice the bandwidth, but a non-integer position signal may be converted into You can downconvert to a minimum sample rate greater than 2 times. However, since the sampling frequency depends on the position of the signal band, the receiving device of the BPS reception method should change the sample rate according to the bandwidth of the signal and the position of the band for universal access. There is also a difficulty in varying the bandwidth.

Recently, a receiving apparatus has been proposed in which an aliasing is removed through signal processing after sampling a signal using two paths so as to have a relatively delay time. In this way, the sample rate can be selected without considering aliasing according to the position of the signal, and the minimum sampling frequency can be selected to be equal to the bandwidth of the signal. However, when the sample rate of the input signal is a bandwidth, aliasing occurs when the receiving device samples the bandwidth.

In addition, these receiving apparatuses mainly aim to downconvert one RF signal. When one RF signal of a band to be received and an RF signal of another band are simultaneously received and processed, aliasing occurs to the RF signal of another band. That is, aliasing generally occurs when receiving and processing a plurality of RF signals.

The technical problem to be achieved by the present invention is to receive and process the RF signal of at least one band at the same time normally and at the same time, and to efficiently perform down-conversion of the RF signal of other bands.

According to an embodiment of the present invention, a receiving apparatus includes an RF filter unit for selecting and outputting down-converted signals from a plurality of received signals having different bands, and generating output phases between the output signals of the filter unit. Output signal of the quantization unit by using a phase shifter for down-converting the signals and outputting a plurality of sample signals, a quantization unit converting the plurality of sample signals from a discrete signal to a digital signal, and a phase shift value generated by the phase difference And a signal separator for separating and outputting a plurality of output signals corresponding to the plurality of received signals.

The plurality of received signals include a first received signal, a second received signal, and a third received signal, and the plurality of output signals correspond to a first output signal corresponding to the first received signal and the second received signal. And a third output signal corresponding to the second output signal and the third received signal.

The signal separation unit may include a first interpolant receiving a first signal, which is one of the output signals of the quantization unit, and outputting a fourth output signal, and a second signal which is one of the output signals of the quantization unit. Receives an addition result of a second interpolant for outputting a fifth output signal, a first adder for adding the fourth output signal and the fifth output signal, and a first adder to select and output the first output signal; And a high pass filter configured to receive the addition result of the first adder and to select and output the second output signal.

The filter coefficient value of the first interpolant may be an inverse of the bandwidth when the absolute value of the frequency is smaller than the bandwidth, and may be 0 otherwise.

The filter coefficient value of the second interpolant is a value obtained by dividing a negative value of a phase shift of a negative frequency component of the third received signal by the bandwidth when the frequency is between a negative value of a bandwidth and zero. If the frequency is between 0 and the bandwidth, the negative value of the phase shift of the positive frequency component of the third received signal is divided by the bandwidth, otherwise it may be 0.

The first output signal may be 1 when the frequency is between 0 and the center frequency of the first output signal and the second output signal, and 0 otherwise.

The second output signal may be 1 when the frequency is between half of the center frequency and the sampling frequency, and may be 0 otherwise.

The signal separator may include a third interpolant receiving the second signal and outputting a sixth output signal, and a second adder configured to add the fourth output signal and the sixth output signal and output the third output signal. It may further include.

The filter coefficient value of the third interpolant is negative of the second received signal when the frequency is between a negative value of half the sampling frequency and a negative value of the center frequency of the first output signal and the second output signal. The negative value of the phase shift of the frequency component of is divided by the bandwidth, and when the frequency is between the negative value of the center frequency and zero, the negative of the phase shift of the negative frequency component of the first received signal A value divided by the bandwidth, and when the frequency is between 0 and the center frequency, a negative value of a phase shift of a positive frequency component of the first received signal is divided by the bandwidth, and the frequency If the center frequency is between half of the sampling frequency, the negative value of the phase shift of the positive frequency component of the second received signal is divided by the bandwidth, otherwise It may be zero.

The phase shifter may include at least one track and holder for receiving the clock signal having a time difference and generating the phase difference.

The RF The filter unit may include at least one band pass filter.

The receiving apparatus according to another embodiment of the present invention down-converts the first received signal, the second received signal, and the third received signal of different bands with different phase shift values, respectively, and thus, the first received signal. A receiving device for outputting a first output signal corresponding to the second output signal corresponding to the second output signal and a third output signal corresponding to the third received signal, wherein the absolute value of the frequency is smaller than the bandwidth. A first interpolant which has an inverse of the bandwidth, 0 otherwise as a filter coefficient value, and outputs a fourth output signal, and when the frequency is between a negative value of the bandwidth and 0, the third reception The negative value of the phase shift of the negative frequency component of the signal divided by the bandwidth, and when the frequency is between 0 and the bandwidth, the phase shift of the positive frequency component of the third received signal Is a value obtained by dividing a value by the bandwidth, and in other cases, a value of 0 is a filter coefficient value, and a sixth output obtained by adding the second interpolant, the fourth output signal, and the fifth output signal to output a fifth output signal. A first adder for outputting a signal, the sixth output signal is received so that the first is 0 and the center frequency of the first output signal and the second output signal is 1, otherwise 0 is 0. A low pass filter outputting as one output signal, the sixth output signal, and outputting 1 when the frequency is between half of the center frequency and the sampling frequency and 0 otherwise, as the second output signal. A high pass filter, the negative value of the phase shift of the negative frequency component of the second received signal if the frequency is between a negative value of half the sampling frequency and the negative value of the center frequency Is divided by the bandwidth, and when the frequency is between the negative value of the center frequency and zero, the negative value of the phase shift of the negative frequency component of the first received signal is divided by the bandwidth. Is between 0 and the center frequency, the negative value of the phase shift of the positive frequency component of the first received signal divided by the bandwidth, and when the frequency is between the center frequency and half of the sampling frequency, A third interpolant having a value obtained by dividing a negative value of a phase shift of a positive frequency component of the second received signal by a bandwidth, otherwise, 0 as a filter coefficient value and outputting a seventh output signal; And a second adder for adding the fourth output signal and the seventh output signal and outputting the third output signal as the third output signal.

A reception method according to another embodiment of the present invention is a method in which a reception device receives a plurality of reception signals having different bands, and down-converts the plurality of reception signals while generating a phase difference between the plurality of reception signals. Outputting a sample signal of, converting the plurality of sample signals from a discrete signal to a digital signal, and using the phase shift value generated by the phase difference, in the plurality of sample signals converted into the digital signal. And separating and outputting a plurality of output signals corresponding to the plurality of received signals, respectively.

The plurality of received signals include a first received signal, a second received signal, and a third received signal, and the plurality of output signals correspond to a first output signal corresponding to the first received signal and the second received signal. And a third output signal corresponding to the third output signal and the third output signal, wherein the separating and outputting the first output signal comprises receiving a first signal including the plurality of sample signals converted into the digital signal. Outputting a fourth output signal, receiving a second signal in which the plurality of sample signals converted into the digital signal coexist with different phase shift values, and outputting a fifth output signal, the fourth output signal And summing the fifth output signal, selecting and outputting the first output signal from the sum result, and selecting the second output signal from the sum result. It may comprise the step of outputting.

The receiving of the first signal and outputting the fourth output signal may be performed based on a filter coefficient value of 0 when the absolute value of the frequency is smaller than the bandwidth, and in other cases, the bandwidth.

Receiving the second signal and outputting a fifth output signal, when the frequency is between the negative value of the bandwidth and 0, the negative value of the phase shift of the negative frequency component of the third received signal; A value obtained by dividing the bandwidth, and when the frequency is between 0 and the bandwidth, the negative value of the phase shift of the positive frequency component of the third received signal is divided by the bandwidth, otherwise the filter coefficient is 0 Can be performed based on a value.

The first output signal may be 1 when the frequency is between 0 and the center frequency of the first output signal and the second output signal, and 0 otherwise.

The second output signal may be 1 when the frequency is between half of the center frequency and the sampling frequency, and may be 0 otherwise.

The separating and outputting may further include receiving the second signal and outputting a sixth output signal, and outputting the third output signal by adding the fourth output signal and the sixth output signal. can do.

Receiving the second signal and outputting a sixth output signal may include: when the frequency is between a negative value of half the sampling frequency and a negative value of the center frequency of the first output signal and the second output signal, The negative value of the phase shift of the negative frequency component of the second received signal divided by the bandwidth, and when the frequency is between the negative value of the center frequency and zero, the negative frequency of the first received signal The negative value of the phase shift of the component divided by the bandwidth, and when the frequency is between 0 and the center frequency, the negative value of the phase shift of the positive frequency component of the first received signal divided by the bandwidth Value, and when the frequency is between the center frequency and half of the sampling frequency, the negative value of the phase shift of the positive frequency component of the second received signal divided by the bandwidth Value, otherwise it may be performed based on a filter coefficient value of zero.

According to the present invention, a wireless communication receiver can normally receive and process RF signals of at least one other band at the same time, and can efficiently perform downconversion of the RF signal. Therefore, while receiving one RF signal of a reception band normally, two RF signals of different bands may be found in a wideband frequency domain, and thus, three RF signals may be normally received as a whole. In addition, a plurality of RF signals transmitted by dividing into different frequency bands can be normally received simultaneously.

1 is a block diagram of a receiving apparatus according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating a baseband signal down-converted by an RF signal and a receiving apparatus according to FIG. 1.
FIG. 3 is a diagram illustrating a phase shift generated while being down-converted to baseband by the RF signal shown in FIG. 2 and the reception device of FIG. 1.
4 is a diagram illustrating three signals output by a receiving apparatus according to an embodiment of the present invention.
5 is a flowchart illustrating a receiving method of a receiving apparatus according to an embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise. In addition, the terms “… unit”, “… unit”, “module”, etc. described in the specification mean a unit that processes at least one function or operation, which may be implemented by hardware or software or a combination of hardware and software. have.

Hereinafter, a receiving apparatus and a receiving method according to an embodiment of the present invention will be described in detail with reference to the drawings.

1 is a block diagram of a receiver according to an embodiment of the present invention, FIG. 2 is a diagram illustrating an RF signal and a baseband signal down-converted by the receiver according to FIG. 1, and FIG. 3 is shown in FIG. 2. FIG. 4 is a diagram illustrating a phase shift generated while downconverting to a baseband by an RF signal and the reception device of FIG. 1, and FIG. 4 is a diagram illustrating three signals output by a reception device according to an embodiment of the present invention. to be.

Referring to FIG. 1, the reception apparatus 100 receives and processes a radio frequency (RF) signal (R ₀ (f), R ₁ (f), and R ₂ (f)) received through an antenna. The device outputs down-converted signals S ₀ , S ₁ , and S ₂ .

Referring to FIG. 2 and FIG. 3, RF signals (R ₀ (f), R ₁ (f), and R ₂ (f)) having three different bands are divided by the interval of the sample rate fs. it is assumed that each of n _o, n _1, n positioned in the _second area in the region. receiver 100 according to one embodiment of the invention RF signal _{((R 0 (f),} R 1 (f), R _If the frequency domain where ₂ (f) is located is different, the phase shifts resulting from downconverting the RF signals (R ₀ (f), R ₁ (f), and R ₂ (f)) are different. Three signals of different bands are separated and output, that is, three RF signals (R ₀ (f), R ₁ (f), and R ₂ (f)) are sub-sampled to the base band. when nested the aliasing is generated in the phase-shift value ^{(β -n0, β -n1, β} -n2) it can separate the signals by using the difference.

Signals S ₀ , S ₁ , and S ₂ output by the receiving apparatus according to an embodiment of the present invention are RF signals (R ₀ (f), R ₁ (f), and R ₂ (f) as shown in FIG. 4). ) Is a down-converted signal separated from each other.

Referring to FIG. 4, the frequency f ₁ is defined as the center frequency of the signals S ₀ and S ₁ as shown in Equation 1 below.

[Equation 1]

Here, the frequency f _oH is the high bound frequency of the signal S ₀ , and the frequency f _1L is the low bound frequency of the signal S ₁ .

Referring back to FIG. 1, the reception apparatus 100 includes an RF filter 111, 112, 113, a phase converter 120, a clock generator 125, a quantization unit 130, and a signal separation unit 140. It includes.

Each of the RF filter units 111, 112, and 113 simultaneously receives three RF signals (R ₀ (f), R ₁ (f), and R ₂ (f)) having different bands received by the antenna. The RF signal to be converted is selected, and noise and aliasing of the selected RF signal are removed, so that the filter units 111, 112, and 113 may be tunable band pass filters.

The phase converter 120 down-converts the RF signal selected by the RF filter units 111, 112, and 113 into a sample signal using a preset sampling frequency fs. In this case, the sampling frequency fs may be set at least twice (2B) the bandwidth B of the RF signal. The phase shifter 120 may include two track and holders 121 and 122. Two track-and-holders 121 and 122 may generate a phase difference between the two signals by receiving the clock signal having the time difference T _Δ from the clock generation section 125 generates a two sample signals having the time difference T _Δ .

The clock generator 125 generates clock signals having different time differences. The clock generator 125 distributes the generated clock signal to the phase shifter 120 and the quantizer 130.

The quantizer 130 converts two sample signals having a phase difference into a digital signal, generates a sample stream having different phases, and transfers the sample streams to the signal separator 140.

The signal separation unit 140 receives two sample streams having different phases, separates and outputs three signals S _o , S ₁ , and S ₂ using different phase shift values of the two sample streams. Interpolants 142, 143, 144, adders 145, 146, low pass filter 147, and high pass filter 148.

The interpolants 142, 143, and 144 are a type of filter that recovers only a desired signal.

The output signals of the interpolants 142 and 143 are added using the adder 145, and the two signals _SO and S ₁ are separated using the low pass filter 147 and the high pass filter 148.

The output signals of the interpolants 142 and 144 are added using the adder 146 and the signals S ₂ are separated.

The filter coefficient value of the interpolant 142 may be represented by S _A (f), and may be designed as Equation 2 below.

[Equation 2]

That is, when the absolute value of the frequency f of the signal is smaller than the bandwidth B, the filter coefficient value of the interpolant 142 is the inverse of the bandwidth, and in other cases, it is zero.

The filter coefficient value of the interpolant 143 may be represented by S _B1 (f), and may be designed as Equation 3 below.

&Quot; (3) "

That is, the filter coefficient value of the interpolant 143 is the negative value of the phase shift of the negative frequency component of the RF signal R ₂ (f) when the frequency is between the negative value of the bandwidth and zero. The value is divided by the bandwidth, and when the frequency is between 0 and the bandwidth, the negative value of the phase shift of the positive frequency component of the RF signal R ₂ (f) is divided by the bandwidth, otherwise it is 0. .

Inteopolran agent (142, 143) the two signals (S _o, S ₁₎ from the signal (S _o), a low pass filter (147) for separating the separated through may be represented by S _LP (f), the following mathematical It can be designed as Equation 4.

&Quot; (4) "

That is, if the low-pass filter between the output value, i.e. the signal of (147) (S _o) is the center frequency in the frequency 0 (f ₁₎ has a 1, and is 0 otherwise.

Inteopolran agent (142, 143) the two signals (S _o, S _1), the high-pass filter 148 for separating a signal (S ₁₎ from the separated through may be represented by S _HP (f), the following mathematical It can be designed as shown in Equation 5.

[Equation 5]

That is, the output value of the high pass filter 148, that is, the signal S ₁ is _{1 when} the frequency is between half of the center frequency f ₁ and the sampling frequency f _s , and 0 otherwise.

The filter coefficient value of the interpolant 144 may be represented by S _B2 (f), and may be designed as in Equation 6 below.

&Quot; (6) "

That is, the filter coefficient value of the interpolant 144 is the RF signal R ₁ (f) when the frequency is between a half negative value of the sampling frequency f _s and a negative value of the center frequency f ₁ . The negative value of the phase shift of the negative frequency component of divided by the bandwidth, and when the frequency is between the negative value of the center frequency f ₁ and zero, the negative of the RF signal R ₀ (f) The negative value of the phase shift of the frequency component divided by the bandwidth, and when the frequency is between 0 and the center frequency f ₁ , the phase shift of the positive frequency component of the RF signal R ₀ (f) A negative value divided by the bandwidth, and when the frequency is between the center frequency f ₁ and half of the sampling frequency f _s , the phase shift of the positive frequency component of the RF signal R ₁ (f) Negative value divided by bandwidth, otherwise 0.

As such, when the interpolants 142, 143, and 144, the low pass filter 147, and the high pass filter 148 are designed as shown in Equations 2 to 6, three RF signals located in different frequency bands The baseband can be simultaneously received without interference.

In addition, the signals R ₀ (f) and R ₁ (f) are signals to be received, and even when the signals R ₂ (f) exist as interference signals, the signals R ₂ (f) in the received signal Only the signals R ₀ (f) and R ₁ (f) can be received normally.

Now, a reception method according to an embodiment of the present invention will be described in detail with reference to FIG. 5.

5 is a flowchart illustrating a receiving method of the receiving apparatus 100 according to an embodiment of the present invention.

Referring to FIG. 5, the reception apparatus 100 receives three RF signals of different bands from an antenna and selects and filters an RF signal to be down-converted (S510).

Subsequently, the reception apparatus 100 down-converts the filtered RF signal into sample signals using a preset sampling frequency (S520). In this case, clock signals having different time differences may be inserted such that the sample signals have different phase differences, and the preset sampling frequency may be twice the bandwidth.

Thereafter, the reception device 100 converts the sample signal into a digital signal in step S530.

The receiving device 100 separates and outputs three down-converted signals existing in different bands from the converted digital signal (S540). In this case, three signals may be separated and output without interference using the interpolant, the low pass filter, and the high pass filter designed according to Equations 2 to 6 described above.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

Claims (20)

An RF filter unit selecting and outputting a signal to be down-converted from each of a plurality of received signals having different bands;
A phase converter configured to down-convert output signals of the filter unit and output a plurality of sample signals while generating a phase difference between the output signals of the filter unit;
A quantization unit converting the plurality of sample signals into discrete signals and digital signals, and
A signal separator for separating and outputting a plurality of output signals corresponding to the plurality of received signals from the output signals of the quantization unit by using the phase shift value generated by the phase difference.
Receiving device comprising a. In claim 1,
The plurality of received signals include a first received signal, a second received signal, and a third received signal, and the plurality of output signals correspond to a first output signal corresponding to the first received signal and the second received signal. And a third output signal corresponding to the second output signal and the third received signal. In claim 2,
The signal separation unit,
A first interpolant for receiving a first signal, which is one of the output signals of the quantization unit, and outputting a fourth output signal;
A second interpolant which receives a second signal, which is one of the output signals of the quantization unit, and outputs a fifth output signal;
A first adder summing the fourth output signal and the fifth output signal,
A low pass filter for receiving the addition result of the first adder and selecting and outputting the first output signal; and
A high pass filter that receives the addition result of the first adder and selects and outputs the second output signal.
Receiving device comprising a. 4. The method of claim 3,
The filter coefficient value of the first interpolant is
If the absolute value of the frequency is less than the bandwidth, it is the inverse of the bandwidth,
0 otherwise
Receiving device. 4. The method of claim 3,
The filter coefficient value of the second interpolant is
If the frequency is between the negative value of the bandwidth and zero, the negative value of the phase shift of the negative frequency component of the third received signal is divided by the bandwidth,
If the frequency is between 0 and the bandwidth, the negative value of the phase shift of the positive frequency component of the third received signal is divided by the bandwidth,
0 otherwise
Receiving device. 4. The method of claim 3,
The first output signal is,
1 if the frequency is between 0 and the center frequency of the first output signal and the second output signal,
0 otherwise
Receiving device. In claim 6,
The second output signal is,
1, when the frequency is between half of the center frequency and the sampling frequency,
0 otherwise
Receiving device. 4. The method of claim 3,
The signal separation unit,
A third interpolant for receiving the second signal and outputting a sixth output signal; and
A second adder for adding the fourth output signal and the sixth output signal to output the third output signal;
Receiving device further comprising. 9. The method of claim 8,
The filter coefficient value of the third interpolant is
The negative value of the phase shift of the negative frequency component of the second received signal when the frequency is between a negative value of half the sampling frequency and a negative value of the center frequency of the first output signal and the second output signal Divided by the bandwidth,
When the frequency is between a negative value of the center frequency and zero, a negative value of a phase shift of a negative frequency component of the first received signal is divided by the bandwidth,
When the frequency is between 0 and the center frequency, the negative value of the phase shift of the positive frequency component of the first received signal is divided by the bandwidth,
When the frequency is between the center frequency and half of the sampling frequency, the negative value of the phase shift of the positive frequency component of the second received signal is divided by the bandwidth,
0 otherwise
Receiving device. In claim 1,
The phase conversion unit includes at least one track and holder for receiving a clock signal having a time difference to generate the phase difference. In claim 1,
The RF A receiving device comprising at least one band pass filter. A first output signal corresponding to the first received signal and the second output signal by down-converting the first received signal, the second received signal, and the third received signal of different bands with different phase shift values, respectively; A receiver for outputting a second output signal corresponding to a received signal and a third output signal corresponding to the third received signal,
A first interpolant for outputting a fourth output signal having an inverse of the bandwidth when the absolute value of the frequency is smaller than the bandwidth and 0 as the filter coefficient value otherwise;
When the frequency is between the negative value of the bandwidth and 0, the negative value of the phase shift of the negative frequency component of the third received signal divided by the bandwidth, and the frequency is between 0 and the bandwidth. A second interpolant having a negative value of the phase shift of the positive frequency component of the third received signal divided by the bandwidth, otherwise 0 as a filter coefficient value, and outputting a fifth output signal; ,
A first adder for adding the fourth output signal and the fifth output signal to output a sixth output signal,
A low pass that receives the sixth output signal and outputs 1 if the frequency is between 0 and the center frequency of the first output signal and the second output signal, and otherwise outputs 0 as the first output signal filter,
A high pass filter which receives the sixth output signal and outputs 1 when the frequency is between half of the center frequency and the sampling frequency and 0 as the second output signal;
If the frequency is between the negative value of half of the sampling frequency and the negative value of the center frequency, the negative value of the phase shift of the negative frequency component of the second received signal divided by the bandwidth is equal to the frequency. The negative value of the phase shift of the negative frequency component of the first received signal is divided by the bandwidth when the center frequency is between a negative value and 0, and when the frequency is between 0 and the center frequency, A value obtained by dividing a negative value of a phase shift of a positive frequency component of a received signal by the bandwidth, and when the frequency is between half of the sampling frequency and the center frequency, A third interpolant having a negative value of the phase shift divided by the bandwidth, otherwise 0 as a filter coefficient value, and outputting a seventh output signal,
A second adder for adding the fourth output signal and the seventh output signal together and outputting the third output signal;
Receiving device comprising a. A method for receiving a plurality of received signals having different bands by a receiving device,
Outputting a plurality of sample signals by down-converting the plurality of received signals while generating a phase difference between the plurality of received signals;
Converting the plurality of sample signals from discrete signals to digital signals, and
Separating and outputting a plurality of output signals corresponding to the plurality of received signals from the plurality of sample signals converted into the digital signal by using the phase shift value generated due to the phase difference
Receiving method comprising a. In claim 13,
The plurality of received signals include a first received signal, a second received signal, and a third received signal, and the plurality of output signals correspond to a first output signal corresponding to the first received signal and the second received signal. And a third output signal corresponding to the second output signal and the third received signal,
Separating and outputting,
Receiving a first signal including the plurality of sample signals converted into the digital signal and outputting a fourth output signal;
Receiving a second signal in which the plurality of sample signals converted into the digital signal coexist with different phase shift values and outputting a fifth output signal;
Summing the fourth output signal and the fifth output signal;
Selecting and outputting the first output signal from the sum result; and
Selecting and outputting the second output signal from the sum result
Receiving method comprising a. The method of claim 14,
Receiving the first signal and outputting a fourth output signal,
If the absolute value of the frequency is less than the bandwidth, it is the inverse of the bandwidth,
Otherwise based on a filter coefficient value of zero
Receiving method. The method of claim 14,
Receiving the second signal and outputting a fifth output signal,
If the frequency is between the negative value of the bandwidth and zero, the negative value of the phase shift of the negative frequency component of the third received signal is divided by the bandwidth,
If the frequency is between 0 and the bandwidth, the negative value of the phase shift of the positive frequency component of the third received signal is divided by the bandwidth,
0 otherwise
Performed based on filter coefficient values
Receiving method. The method of claim 14,
The first output signal is,
1 if the frequency is between 0 and the center frequency of the first output signal and the second output signal,
0 otherwise
Receiving method. The method of claim 17,
The second output signal is,
1, when the frequency is between half of the center frequency and the sampling frequency,
0 otherwise
Receiving method. The method of claim 14,
Separating and outputting,
Receiving the second signal and outputting a sixth output signal; and
Adding the fourth output signal and the sixth output signal to output the third output signal;
Receiving method further comprising. The method of claim 19,
Receiving the second signal and outputting a sixth output signal,
The negative value of the phase shift of the negative frequency component of the second received signal when the frequency is between a negative value of half the sampling frequency and a negative value of the center frequency of the first output signal and the second output signal Divided by the bandwidth,
When the frequency is between a negative value of the center frequency and zero, a negative value of a phase shift of a negative frequency component of the first received signal is divided by the bandwidth,
When the frequency is between 0 and the center frequency, the negative value of the phase shift of the positive frequency component of the first received signal is divided by the bandwidth,
When the frequency is between the center frequency and half of the sampling frequency, the negative value of the phase shift of the positive frequency component of the second received signal is divided by the bandwidth,
0 otherwise
Performed based on filter coefficient values
Receiving method.

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