KR102055192B1 - Apparatus and method for calibrating i/q imbalance of direct-conversion transmitter - Google Patents

Abstract

The present invention measures a reference RSB which is an RSB of a signal output from the direct conversion transmitter with respect to an in-phase signal (I _D ) and a quadrature phase signal (Q _D ) of a digital baseband input to the direct conversion transmitter. Gain of the direct conversion transmitter through a method of measuring an additional RSB which is an RSB of a signal output from the direct conversion transmitter according to a gain mismatch parameter g _a or a phase mismatch parameter θ _a input to a baseband. error parameter (g _err) and the phase error, and determines the parameters (θ _err), configured to take advantage of the gain error parameter (g _err) and the phase error parameter (θ _err) in the I / Q imbalance compensation in the direct conversion transmitter being The advantage is that simple, accurate compensation is possible.

Description

I / Q imbalance compensation device and method for direct conversion transmitters {APPARATUS AND METHOD FOR CALIBRATING I / Q IMBALANCE OF DIRECT-CONVERSION TRANSMITTER}

The present invention relates to an apparatus and method for compensating I / Q imbalance of a direct-conversion transmitter in a simple and accurate manner through residual side-band measurement.

In general, in a communication system, in order to transmit a large amount of information within a given bandwidth, an in-phase signal (I _D ) and a quadrature signal (Q _D ) having a phase difference of 90 ° from the in-phase signal An orthogonal modulated signal is used. Among the apparatuses for generating such quadrature modulated signals are direct conversion transmitters, which are widely used in communication systems because they are compact and operate at low cost.

1 is a diagram schematically illustrating an I / Q imbalance compensation device of a direct conversion transmitter according to an embodiment of the present invention.

As shown in FIG. 1, the direct conversion transmitter 1 includes two digital to analog converters (DACs) 11 and 12, two low pass filters 21 and 22, two mixers 31 and 32, and a local part. It may include an oscillator 40 and the adder 50.

The in-phase signal I _D of the digital baseband is input to the first DAC 11, and the quadrature phase signal Q _D of the digital baseband is input to the second DAC 12. The in-phase signal I _D and the quadrature signal Q _D are digital signals, the first DAC 11 converts the in-phase signal I _D into an analog signal, and the second DAC 12 The quadrature phase signal Q _D is converted into an analog signal.

The first low pass filter 21 removes high frequency components from the in-phase signal converted into an analog signal to generate an in-phase analog signal I _A , and the second low pass filter 22 converts the quadrature into an analog signal. The high frequency component is removed from the phase signal to generate a quadrature analog signal Q _A.

The first mixer 31 mixes the in-phase analog signal I _{A with} the in-phase local oscillation signal LO _I generated by the local oscillator 40, and the second mixer 32 performs the quadrature analog signal Q. _A ) is mixed with the quadrature local oscillation signal LO _Q generated by the local oscillator 40.

The adder 50 adds or subtracts signals output from the first mixer 31 and the second mixer 32 to generate an orthogonal modulated signal of a lower side band or an upper side band. Since the generated quadrature modulated signal has an in-phase signal (I _D ) and a quadrature phase signal (Q _D ), the receiving end demodulates the quadrature modulated signal to perform in-phase signal (I _D ) and quadrature phase (Q _D ). You can get it.

As such, the direct conversion transmitter 1 has an in-phase signal and a quadrature signal, which must be orthogonal with a phase difference of exactly 90 °. However, due to the analog characteristics of the direct conversion transmitter 1, there is a gain imbalance in which the gain between the in-phase signal I _D and the quadrature signal Q _D is different, and the in-phase signal I _D and the quadrature signal Q _D. Phase imbalance may occur when the phase is out of phase at 90 °, and in this case, there is a problem in that the demodulation signal is severely degraded when the demodulated signal is demodulated at the receiver. Accordingly, it is necessary to provide a technique for compensating for the I / Q imbalance of the direct conversion transmitter 1 as in Patent Document 1 below.

Korean Registered Patent Publication No. 1455894 (Published: 2014.10.22.)

The present invention has been made to solve the above problems, and an object thereof is to provide an I / Q imbalance compensation device and method capable of compensating I / Q imbalance of a direct conversion transmitter in a simple and accurate manner.

In order to achieve the above object, the I / Q imbalance compensation device of the direct conversion transmitter according to the present invention, the in-phase signal (I _D ) and quadrature phase signal (Q _D ) of the digital baseband input to the direct conversion transmitter RSB measurement unit for measuring the RSB (Residual Side-Band) of the signal output from the direct conversion transmitter as a reference RSB; And a control unit for inputting a gain mismatch parameter g _a or a phase mismatch parameter θ _a to the digital baseband, wherein the RSB measurement unit includes the gain mismatch parameter g input to the digital baseband. _a ) or according to the phase mismatch parameter θ _a , the RSB of the signal output from the direct conversion transmitter is measured as an additional RSB, and the controller uses the reference RSB and the additional RSB measured by the RSB measurement unit. The gain error parameter g _err and the phase error parameter θ _err of the direct conversion transmitter are determined, and an inverse compensation value of the gain error parameter g _err and the phase error parameter θ _err is obtained. And to compensate for the I / Q imbalance of the direct conversion transmitter.

Here, the control unit inputs _a gain mismatch parameter g _a to the digital baseband, and the RSB measurement unit outputs an RSB of a signal output from the direct conversion transmitter according to the input of the gain mismatch parameter g _a . Measure as a first additional RSB, wherein the control unit further inputs _a phase mismatch parameter θ _a to the digital baseband, and the RSB measurement unit according to the input of the phase mismatch parameter θ _a The RSB of the signal output from is measured as a second additional RSB, and the controller measures a gain error parameter g _err and a phase error parameter θ _err using the reference RSB, the first additional RSB, and the second additional RSB. It is characterized by determining.

Alternatively, the control unit inputs _a phase mismatch parameter θ _a to the digital baseband, and the RSB measurement unit outputs an RSB of a signal output from the direct conversion transmitter according to the input of the phase mismatch parameter θ _a . Measure as a first additional RSB, wherein the control unit further inputs _a gain mismatch parameter g _a to the digital baseband, and the RSB measurement unit according to the input of the gain mismatch parameter g _a The RSB of the signal output from is measured as a second additional RSB, and the controller measures a gain error parameter g _err and a phase error parameter θ _err using the reference RSB, the first additional RSB, and the second additional RSB. It is characterized by determining.

Alternatively, the control unit inputs _a gain mismatch parameter g _a to the digital baseband, and the RSB measurement unit outputs an RSB of a signal output from the direct conversion transmitter according to the input of the gain mismatch parameter g _a . Measured as a first additional RSB, wherein the controller inputs the phase mismatch parameter θ _a to the digital baseband instead of the gain mismatch parameter g _a , and the RSB measurement unit measures the phase mismatch parameter θ _A RSB of the signal output from the direct conversion transmitter is measured as a second additional RSB according to the input of _a ), and the controller uses a gain error parameter g _err using the reference RSB, the first additional RSB, and the second additional RSB. ) And the phase error parameter θ _err .

Alternatively, the control unit inputs _a phase mismatch parameter θ _a to the digital baseband, and the RSB measurement unit outputs an RSB of a signal output from the direct conversion transmitter according to the input of the phase mismatch parameter θ _a . Measured as a first additional RSB, wherein the control unit inputs the gain mismatch parameter g _a to the digital baseband instead of the phase mismatch parameter θ _a , and the RSB measurement unit measures the gain mismatch parameter g _A RSB of the signal output from the direct conversion transmitter is measured as a second additional RSB according to the input of _a ), and the controller uses a gain error parameter g _err using the reference RSB, the first additional RSB, and the second additional RSB. ) And the phase error parameter θ _err .

Alternatively, the control unit inputs _a gain mismatch parameter g _a and a phase mismatch parameter θ _a to the digital baseband, and the RSB measurement unit measures the gain mismatch parameter g _a and a phase mismatch parameter ( The RSB of the signal output from the direct conversion transmitter is measured as a first additional RSB according to the input of θ _a ), and the controller removes the phase mismatch parameter θ _a from the digital baseband to remove the digital baseband. Only the gain mismatch parameter g _a is input to the RSB measurement unit, and the RSB measurement unit measures the RSB of the signal output from the direct conversion transmitter as a second additional RSB according to the input of the gain mismatch parameter g _a . The controller determines a gain error parameter g _err and a phase error parameter θ _err using the reference RSB, the first additional RSB, and the second additional RSB. It is characterized by.

Alternatively, the control unit inputs _a gain mismatch parameter g _a and a phase mismatch parameter θ _a to the digital baseband, and the RSB measurement unit measures the gain mismatch parameter g _a and a phase mismatch parameter ( measuring the RSB of the signal output from the direct conversion transmitter as a first additional RSB according to the input of θ _a ), and the controller removes the gain mismatch parameter g _a from the digital baseband to remove the digital baseband. Only the phase mismatch parameter θ _a is input to the RSB measuring unit, and the RSB measuring unit measures the RSB of the signal output from the direct conversion transmitter as a second additional RSB according to the input of the phase mismatch parameter θ _a . the controller determines a gain error parameter (g _err) and the phase error parameter (θ _err) by using the reference RSB, RSB first additional and second additional RSB And that is characterized.

On the other hand, in order to achieve the above object, the I / Q imbalance compensation method of the direct conversion transmitter according to the present invention, the digital baseband in-phase signal (I _D ) and the digital baseband quadrature phase input to the direct conversion transmitter A reference RSB measurement step of measuring a residual side-band (RSB) of a signal output from the direct conversion transmitter as a reference RSB with respect to a signal Q _D ; Gain mismatch parameters to the digital baseband (g _a) or the phase mismatch parameter (θ _a) to enter the said direct conversion transmitter according to the gain mismatch parameter (g _a) or the phase mismatch parameter (θ _a) An additional RSB measurement step of measuring the RSB of the signal output from the additional RSB; An error parameter determining step of determining a gain error parameter g _err and a phase error parameter θ _err of the direct conversion transmitter using the reference RSB and the additional RSB; And an I / Q imbalance compensation step of compensating I / Q imbalance of the direct conversion transmitter by inputting an inverse compensation value of the gain error parameter g _err and a phase error parameter θ _err to the digital baseband. It can be made, including.

Here, in the additional RSB measurement step, a gain mismatch parameter g _a is input to the digital baseband to measure an RSB of a signal output from the direct conversion transmitter as a first additional RSB, and phase in the digital baseband. Input _a mismatch parameter θ _a to further measure the RSB of the signal output from the direct conversion transmitter as a second additional RSB. In the error parameter determining step, the reference RSB, the first additional RSB, and the second additional RSB are determined. The gain error parameter g _err and the phase error parameter θ _err are determined by using.

Alternatively, in the additional RSB measurement step, a phase mismatch parameter θ _a is input to the digital baseband to measure an RSB of a signal output from the direct conversion transmitter as a first additional RSB, and gain to the digital baseband. Further inputting _a mismatch parameter g _a to measure the RSB of the signal output from the direct conversion transmitter as a second additional RSB. In the error parameter determining step, the reference RSB, the first additional RSB and the second additional RSB are determined. The gain error parameter g _err and the phase error parameter θ _err are determined by using.

Alternatively, in the additional RSB measurement step, a gain mismatch parameter g _a is input to the digital baseband to measure the RSB of the signal output from the direct conversion transmitter as a first additional RSB, and the digital baseband Input the phase mismatch parameter θ _a instead of _a gain mismatch parameter g _a to measure the RSB of the signal output from the direct conversion transmitter as a second additional RSB. In the error parameter determination step, the reference RSB The gain error parameter g _err and the phase error parameter θ _err are determined using the first additional RSB and the second additional RSB.

Alternatively, in the additional RSB measurement step, a phase mismatch parameter θ _a is input to the digital baseband to measure an RSB of a signal output from the direct conversion transmitter as a first additional RSB, and the digital baseband The gain mismatch parameter g _a is input instead of _a phase mismatch parameter θ _a to measure the RSB of the signal output from the direct conversion transmitter as a second additional RSB, and in the error parameter determination step, the reference RSB The gain error parameter g _err and the phase error parameter θ _err are determined using the first additional RSB and the second additional RSB.

Alternatively, in the additional RSB measurement step, a gain mismatch parameter g _a and a phase mismatch parameter θ _a are input to the digital baseband, and RSB of the signal output from the direct conversion transmitter is used as a first additional RSB. The RSB of the signal output from the direct conversion transmitter is measured and the phase mismatch parameter θ _a is removed from the digital baseband so that only the gain mismatch parameter g _a is input to the digital baseband. It is measured as a second additional RSB, and in the error parameter determination step, the gain error parameter g _err and the phase error parameter θ _err are determined using the reference RSB, the first additional RSB, and the second additional RSB. It is characterized by.

Alternatively, in the additional RSB measurement step, a gain mismatch parameter g _a and a phase mismatch parameter θ _a are input to the digital baseband, and RSB of the signal output from the direct conversion transmitter is used as a first additional RSB. The RSB of the signal output from the direct conversion transmitter is measured, and the gain mismatch parameter g _a is removed from the digital base band so that only the phase mismatch parameter θ _a is input to the digital base band. It is measured as a second additional RSB, and in the error parameter determination step, the gain error parameter g _err and the phase error parameter θ _err are determined using the reference RSB, the first additional RSB, and the second additional RSB. It is characterized by.

The present invention measures a reference RSB which is an RSB of a signal output from the direct conversion transmitter with respect to an in-phase signal (I _D ) and a quadrature phase signal (Q _D ) of a digital baseband input to the direct conversion transmitter. Gain of the direct conversion transmitter through a method of measuring an additional RSB which is an RSB of a signal output from the direct conversion transmitter according to a gain mismatch parameter g _a or a phase mismatch parameter θ _a input to a baseband. error parameter (g _err) and the phase error, and determines the parameters (θ _err), configured to take advantage of the gain error parameter (g _err) and the phase error parameter (θ _err) in the I / Q imbalance compensation in the direct conversion transmitter being The advantage is that simple, accurate compensation is possible.

In addition, since the present invention measures the RSB of the signal output from the direct conversion transmitter and determines the error parameters g _err , θ _err through the measured RSB (ie, the reference RSB and the additional RSB), The advantage is that no additional hardware configuration is required that degrades accuracy.

In addition, the present invention has the advantage that the computational efficiency is higher than that of the conventional I / Q imbalance compensation device or method due to the non-repetitive characteristics, it is possible to quickly compensate.

1 is a diagram schematically illustrating an I / Q imbalance compensation device of a direct conversion transmitter according to an embodiment of the present invention.
2 exemplarily shows a reference RSB.
FIG. 3A is _a diagram illustrating a first additional RSB measured when _a gain mismatch parameter g _a is input to a digital baseband, and FIG. 3B illustrates a phase mismatch parameter θ _a to the digital baseband. 2 is a diagram illustrating a second additional RSB measured when further inputted.
4A is _a diagram exemplarily illustrating a first additional RSB measured when _a phase mismatch parameter θ _a is input to a digital baseband, and FIG. 4B is a diagram of a gain mismatch parameter g _a for _a digital baseband. 2 is a diagram illustrating a second additional RSB measured when further inputted.
FIG. 5A illustrates a first additional RSB measured when _a gain mismatch parameter g _a is input to a digital baseband, and FIG. 5B illustrates the gain mismatch parameter g _{a in a} digital baseband. Instead, the second additional RSB measured when the phase mismatch parameter θ _a is inputted is illustrated.
FIG. 6A is _a diagram illustrating a first additional RSB measured when _a phase mismatch parameter θ _a is input to _a digital baseband, and FIG. 6B is _a digital base band instead of the phase mismatch parameter θ _a . 2 is a diagram illustrating a second additional RSB measured when _a gain mismatch parameter g _a is inputted to.
FIG. 7A is _a diagram exemplarily illustrating a first additional RSB measured when _a gain mismatch parameter g _a and a phase mismatch parameter θ _a are input to a digital baseband, and FIG. 7B is a diagram illustrating a digital baseband. A second additional RSB measured by removing the phase mismatch parameter θ _a so that only the gain mismatch parameter g _a is input to the digital baseband is illustrated.
FIG. 8A is _a diagram exemplarily illustrating a first additional RSB measured when _a gain mismatch parameter g _a and a phase mismatch parameter θ _a are input to a digital base band, and FIG. A second additional RSB is measured when the gain mismatch parameter g _a is removed so that only the phase mismatch parameter θ _a is input to the digital baseband.
9 is a flowchart of an I / Q imbalance compensation method of a direct conversion transmitter according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail preferred embodiments of the present invention. Like reference numerals in the accompanying drawings denote like elements. The accompanying drawings are provided to enable a person skilled in the art to fully convey the technical idea of the present invention, and the present invention is not limited to the accompanying drawings, but is not limited within the scope of changing the technical idea of the present invention. It can be embodied in any number. Detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

The DACs 11 and 12, the low pass filters 21 and 22, the mixers 31 and 32 and the adder 50 of the direct conversion transmitter 1 shown in FIG. The gain imbalance and phase imbalance in (1), that is, the factor that brings about I / Q imbalance.

Hereinafter, all the factors affecting the gain imbalance of the direct conversion transmitter 1 are defined as one parameter, the gain error parameter g _err , and all the factors affecting the phase imbalance of the direct conversion transmitter 1 are one It is defined by the phase error parameter θ _{err which} is a parameter.

In the present invention, after determining the gain error parameter g _err and the phase error parameter θ _err present in the direct conversion transmitter 1, the reverse compensation of the gain error parameter g _err and the phase error parameter θ _err is performed. The present invention proposes a method for compensating I / Q imbalance of the direct conversion transmitter 1 by inputting a value into a digital baseband located at the front end of the direct conversion transmitter 1. In addition, the present invention proposes a method of determining the gain error parameter g _err and the phase error parameter θ _err through a plurality of residual side-band (RSB) measurements, which will be described in detail below. .

는 직접 변환 송신기(1)에 존재하는 게인 에러 파라미터(g_err)와 위상 에러 파라미터(θ_err)로 인해 다음의 수학식 1과 같이 나타낼 수 있다.Up-converting signal generated by the local oscillator 40 shown in FIG.

May be represented by Equation 1 below due to a gain error parameter g _err and a phase error parameter θ _err present in the direct conversion transmitter 1.

[Equation 1]

이고,

이다.here,

ego,

to be.

를

라 할 때, 직접 변환 송신기(1)의 출력 신호

는 다음의 수학식 2와 같이 나타낼 수 있다.On the other hand, positive digital baseband signals

To

In this case, the output signal of the direct conversion transmitter 1

Can be expressed as Equation 2 below.

[Equation 2]

는 상측파대(Upper Side-band) 주파수를 의미하며

이고,

는 하측파대(Lower Side-band) 주파수를 의미하며

이다. here,

Means Upper Side-band frequency,

ego,

Means lower side-band frequency,

to be.

If there is no gain imbalance in the direct conversion transmitter 1 (g _err = 0) and no phase imbalance also exists (θ _err = 0), then K ₁ = 1 and K ₂ = 0, which means that the transmitted signal This means having only the upper band signal as desired.

However, when there is a gain imbalance (g _err ≠ 0) or a phase imbalance (θ _err ≠ 0) in the direct conversion transmitter 1, the transmission signal has not only an upper band signal but also an unwanted lower band signal. In a communication system, a relationship between an upper sideband signal and a lower sideband signal may be represented by a residual side band (RSB) called a residual sideband, which is defined by Equation 3 below.

[Equation 3]

Here, assuming that the gain error parameter and the phase error parameter are minute (for example, g _err <0.1, θ _err <3π / 180 rad / s), Equation 3 may be simplified as shown in Equation 4 below, which will be referred to below as reference RSB (i.e., gain mismatch parameter g _a described later in the digital baseband). Or RSB when no phase mismatch parameter θ _a is input. Equation 4 assumes that the I / Q imbalance of the direct conversion transmitter 1 does not occur in the digital baseband, which allows the digital component to generate a quadrature signal that is relatively accurate compared to the analog component. Because.

[Equation 4]

As shown in FIG. 2, the reference RSB equation may be represented by a circle having a center of (0, 0) in a plane consisting of a gain g and a phase θ, and directly converted among the points forming the circle. There is a gain error parameter g _err and a phase error parameter θ _err of the transmitter 1. In order to determine the gain error parameter g _err and the phase error parameter θ _{err of the} direct conversion transmitter 1, a gain mismatch parameter g _a or a phase mismatch parameter θ _a is applied to the digital baseband. It is required to enter.

는 다음의 수학식 5와 같이 나타낼 수 있다. 여기서, 게인 미스매치 파라미터(g_a)와 위상 미스매치 파라미터(θ_a)는 직접 변환 송신기(1)의 게인 에러 파라미터(g_err)와 위상 에러 파라미터(θ_err)를 결정하기 위하여, 후술하는 제어부(120)가 디지털 베이스밴드에 입력하는 파라미터이다. 그리고 게인 미스매치 파라미터에 음의 부호(-g_a)를 붙인 이유는 계산상의 편의를 위한 것이다.A positive digital baseband signal when _a gain mismatch parameter g _a and a phase mismatch parameter θ _a are input to the digital base band.

May be expressed as Equation 5 below. Here, the gain mismatch parameter g _a and the phase mismatch parameter θ _a are the control units described later to determine the gain error parameter g _err and the phase error parameter θ _err of the direct conversion transmitter 1. Reference numeral 120 is a parameter input to the digital baseband. The reason for adding _a negative sign (-g _a ) to the gain mismatch parameter is for calculation convenience.

[Equation 5]

이고,

이다.here,

ego,

to be.

는 다음의 수학식 6과 같이 나타낼 수 있다.And the output signal of the direct conversion transmitter 1

May be expressed as in Equation 6 below.

[Equation 6]

When RSB is represented in the same manner as in Equation 3, Equation 7 below.

[Equation 7]

As with the previous reference RSB equation, assuming that the gain and phase error parameters are small (for example, g _err <0.1, θ _err <3π / 180 rad / s), Equation 7 can be simplified as in Equation 8 below, which is further referred to as an additional RSB (i.e. gain mismatch parameter g _a or phase to the digital baseband). RSB) when _a mismatch parameter θ _a is input.

[Equation 8]

The additional RSB equation is represented by a circle centered on (g _a , θ _a ) in _a plane consisting of gain g and phase θ.

In order to compensate for the I / Q imbalance of the direct conversion transmitter 1, a gain error parameter g _err and a phase error parameter θ _err existing in the direct conversion transmitter 1 should be determined. In the plane consisting of (g) and phase (θ), it is represented by a circle centered on (0, 0), and Equation (8) is represented by (g _a , θ _a ) in the plane consisting of gain (g) and phase (θ). Since it is represented by a circle having the center, it can be seen that RSB should be measured two or more times in order to determine the gain error parameter g _err and the phase error parameter θ _{err of the} direct conversion transmitter 1.

Referring back to FIG. 1, the I / Q imbalance compensation device 100 of the direct conversion transmitter according to the present invention may include an RSB measurement unit 110 and a control unit 120.

The RSB measuring unit 110 is configured to convert the signal output from the direct conversion transmitter 1 to the in-phase signal I _D and the quadrature phase signal Q _D of the digital baseband inputted to the direct conversion transmitter 1. RSB is measured as reference RSB.

The control unit 120 determines a gain mismatch parameter g _a or a phase mismatch to the digital baseband in order to determine a gain error parameter g _err and a phase error parameter θ _err present in the direct conversion transmitter 1. Enter the parameter θ _a .

Here, the gain mismatch parameter g _a and the phase mismatch parameter θ _a inputted to the digital baseband by the controller 120 are values set by the user to the controller 120, or are pre-set to the controller 120. It may be a value that is set. That is, the gain mismatch parameter g _a or the phase mismatch parameter θ _a input to the digital baseband corresponds to values previously known to the controller 120.

In addition, the fact that the control unit 120 inputs the gain mismatch parameter g _a or the phase mismatch parameter θ _a to the digital baseband means that the control unit 120 inputs the gain mismatch parameter g _a to the digital baseband. Inputting only, inputting a phase mismatch parameter θ _a , or inputting a gain mismatch parameter g _a and a phase mismatch parameter θ _a simultaneously.

The RSB measurement unit 110 measures an RSB according to a gain mismatch parameter g _a or a phase mismatch parameter θ _a input to the digital baseband as an additional RSB. That is, the reference RSB refers to an RSB when a gain mismatch parameter g _a or a phase mismatch parameter θ _a is not input to the digital base band as described above, and the additional RSB is a gain miss to the digital base band. RSB when _a match parameter g _a or a phase mismatch parameter θ _a is input.

The control unit 120 uses the reference RSB and one or two additional RSBs measured by the RSB measuring unit 110 and the gain error parameter g _err and the phase error parameter θ _{err of} the direct conversion transmitter 1. Is determined.

를 입력(즉, 게인 미스매치 파라미터로서

을 입력하고, 위상 미스매치 파라미터로서

을 입력)함으로써 직접 변환 송신기의 I/Q 불균형을 보상할 수 있다.In addition, the controller 120 compensates the I / Q imbalance of the direct conversion transmitter by inputting the inverse compensation values of the determined gain error parameter g _err and the phase error parameter θ _err into the digital baseband. Specifically, the controller 120 is a digital baseband

Is entered as the gain mismatch parameter.

, Enter the phase mismatch parameter

Can compensate for the I / Q imbalance of the direct conversion transmitter.

Hereinafter, referring to FIG. 2 to FIG. 8B in addition to FIG. 1, the gain error parameter g _err and the phase error parameter of the direct conversion transmitter 1 may be obtained through the I / Q imbalance compensation device of the direct conversion transmitter according to the present invention. An embodiment of determining θ _err ) will be described in more detail.

2 exemplarily shows a reference RSB.

As described above, the RSB measuring unit 110 is the direct conversion transmitter 1 with respect to the in-phase signal I _D and the quadrature phase signal Q _D of the digital baseband input to the direct conversion transmitter 1. Measure the RSB of the signal output from the RSB as a reference RSB.

)으로 나타나게 된다.In this case, the reference RSB may be represented as in Equation 4 above, and the schematic diagram of the reference RSB is a circle having (0, 0) centered on a plane composed of a gain (g) and a phase (θ) as shown in FIG. (The radius is

Will be displayed as).

Among the points forming a circle in FIG. 2, a gain error parameter g _err and a phase error parameter θ _err of the direct conversion transmitter 1 exist. Accordingly, in order to determine the gain error parameter g _err and the phase error parameter θ _{err of the} direct conversion transmitter 1, the control unit 120 uses the gain mismatch parameter g _a or the phase mismatch parameter ( Enter θ _a ) into the digital baseband.

3A to 8B illustrate _a gain error parameter g _err of the direct conversion transmitter 1 as the control unit 120 inputs _a gain mismatch parameter g _a or a phase mismatch parameter θ _a to the digital baseband. And a phase error parameter θ _err are shown.

<First Embodiment>

First, FIG. 3A is _a diagram exemplarily illustrating a first additional RSB measured when _a gain mismatch parameter g _a is input to _a digital baseband.

In order to determine the gain error parameter g _err and the phase error parameter θ _{err of the} direct conversion transmitter 1, the controller 120 may input _a gain mismatch parameter g _a to the digital baseband. In this case, the RSB measuring unit 110 may measure the RSB of the signal output from the direct conversion transmitter 1 as a first additional RSB according to the input of the gain mismatch parameter g _a .

)으로 나타나게 된다.The first additional RSB may be represented by Equation 9 below, and the first additional RSB may be represented by a gain g and a phase θ as shown in FIG. 3A. The circle (radius centered around (g _a , 0) in the plane)

Will be displayed as).

[Equation 9]

Referring to FIG. 3A, it can be seen that _two intersection points (ie, sol ₁ , sol ₂ ) on the plane (g _, θ) where the reference RSB and the first additional RSB meet. The intersection point between the reference RSB and the first additional RSB can be known by combining and solving Equations 4 and 9, and can be expressed as Equations 10 and 11 below.

[Equation 10]

[Equation 11]

According to Equation 10 and FIG. 3A, the gain error parameter g _err is a value g _a / 2 corresponding to 1/2 of _a gain mismatch parameter g _a when the reference RSB and the first additional RSB are the same. It can be seen that when the reference RSB is greater than the first additional RSB, the value is located to the right of g _a / 2, and when the reference RSB is smaller than the first additional RSB, the value is located to the left of the g _a / 2 ( In FIG. 3A, it is assumed that the reference RSB is larger than the first additional RSB.

According to Equation 11, when the gain error parameter g _err is determined, it can be seen that two solutions exist in the phase error parameter θ _err .

However, there may be a case where only one solution has a phase error parameter θ _err . In this case, since only one intersection point between the measured reference RSB and the first additional RSB exists, the second additional RSB to be described later is measured. The parameter corresponding to the intersection may be determined as the gain error parameter g _err and the phase error parameter θ _err of the direct conversion transmitter 1.

However, as shown in FIG. 3A, when there are two intersection points (ie, sol ₁ , sol ₂ ) between the reference RSB and the first additional RSB, any one of the two intersections gains the gain of the direct conversion transmitter 1. The error parameter g _err and the phase error parameter θ _err must be determined.

3B is _a diagram illustrating a second additional RSB measured when the phase mismatch parameter θ _a is further input to the digital baseband, and is a direct conversion transmitter among two intersection points between the reference RSB and the first additional RSB. In order to determine an intersection corresponding to the gain error parameter g _err of (1) and the phase error parameter θ _err , the controller 120 may further input _a phase mismatch parameter θ _a to the digital baseband. Accordingly, the RSB measurement unit 110 may measure the RSB of the signal output from the direct conversion transmitter 1 as a second additional RSB according to the input of the phase mismatch parameter θ _a .

)으로 나타나게 된다.The second additional RSB may be represented by Equation 12 below, and the second additional RSB may be represented by gain g and phase θ as shown in FIG. 3B. The circle (radius is centered on (g _a , θ _a ) in the plane

Will be displayed as).

[Equation 12]

Referring to FIG. 3B, it can be seen that only one intersection point (ie, sol ₁ ) exists on the (g _, θ) plane where the reference RSB, the first additional RSB, and the second additional RSB meet.

The intersection point where the reference RSB, the first additional RSB, and the second additional RSB meet can be known by the controller 120 in combination with Equation 4, Equation 9 and Equation 12 above.

이고, 제2 추가 RSB의 크기가 제1 추가 RSB의 크기보다 큰 경우에는

이 됨을 알 수 있으므로, 제어부(120)는 기준 RSB와 제1 추가 RSB를 통해 게인 에러 파라미터(g_err)를 결정한 뒤, 제1 추가 RSB의 크기와 제2 추가 RSB의 크기 비교를 통해 위상 에러 파라미터(θ_err)를 결정할 수도 있다.Alternatively, the intersection point of the reference RSB, the first additional RSB, and the second additional RSB may be obtained by controlling the gain error parameter (the system of Equations 4 and 9) through the reference RSB and the first additional RSB. g _err ) may be determined by comparing the size of the first additional RSB with the size of the second additional RSB. More specifically, referring to FIG. 3B, when the size of the second additional RSB is smaller than the size of the first additional RSB.

If the size of the second additional RSB is greater than the size of the first additional RSB

The controller 120 determines the gain error parameter g _err through the reference RSB and the first additional RSB, and then compares the phase error parameter by comparing the magnitude of the first additional RSB with the size of the second additional RSB. (θ _err ) may be determined.

That is, the controller 120 determines the gain error parameter g _err and the phase error parameter θ _{err of} the direct conversion transmitter 1 using the reference RSB and the first additional RSB (the reference RSB and the first additional RSB). If there is only one intersection point between RSBs), the gain error parameter g _err and the phase error parameter θ _{err of} the direct conversion transmitter 1 are obtained using the reference RSB, the first additional RSB, and the second additional RSB. Can be determined (if there are two intersections between the reference RSB and the first additional RSB).

Second Embodiment

4A is _a diagram illustrating a first additional RSB measured when _a phase mismatch parameter θ _a is input to _a digital baseband.

In order to determine the gain error parameter g _err and the phase error parameter θ _{err of the} direct conversion transmitter 1, the controller 120 may input _a phase mismatch parameter θ _a to the digital baseband. In this case, the RSB measuring unit 110 may measure the RSB of the signal output from the direct conversion transmitter 1 as the first additional RSB according to the input of the phase mismatch parameter θ _a .

)으로 나타나게 된다.The first additional RSB may be represented by Equation 13 below, and the first additional RSB may be represented by a gain g and a phase θ as shown in FIG. 4A. The circle (radius is centered on (θ _a , 0) in the plane

Will be displayed as).

[Equation 13]

Referring to FIG. 4A, it can be seen that _two intersection points (ie, sol ₁ and sol ₂ ) intersect the reference RSB and the first additional RSB on the plane (g _, θ). The intersection point between the reference RSB and the first additional RSB can be known by combining and solving Equations 4 and 13, and can be expressed as Equations 14 and 15 below.

[Equation 14]

[Equation 15]

According to Equation 14 and FIG. 4A, the phase error parameter θ _err is a value θ _a / 2 corresponding to 1/2 of the phase mismatch parameter θ _a when the reference RSB and the first additional RSB are the same. When the reference RSB is larger than the first additional RSB, the value is higher than θ _a / 2, and when the reference RSB is smaller than the first additional RSB, it is lower than θ _a / 2. In FIG. 4A, it is assumed that the reference RSB is larger than the first additional RSB.

According to Equation 15, when the phase error parameter θ _err is determined, it can be seen that two solutions exist in the gain error parameter g _err .

However, there may be a case where only one solution has a gain error parameter g _err . In this case, since only one intersection point between the measured reference RSB and the first additional RSB exists, the second additional RSB to be described later is measured. The parameter corresponding to the intersection may be determined as the gain error parameter g _err and the phase error parameter θ _err of the direct conversion transmitter 1.

However, as shown in FIG. 4A, when there are two intersection points between the reference RSB and the first additional RSB (that is, sol ₁ and sol ₂ ), any one of the two intersections gains the gain of the direct conversion transmitter 1. The error parameter g _err and the phase error parameter θ _err must be determined.

4B is _a diagram illustrating a second additional RSB measured when the gain mismatch parameter g _a is further input to the digital baseband, and is a direct conversion transmitter among two intersection points between the reference RSB and the first additional RSB. In order to determine an intersection corresponding to the gain error parameter g _err of (1) and the phase error parameter θ _err , the controller 120 may further input _a gain mismatch parameter g _a to the digital baseband. Accordingly, the RSB measuring unit 110 may measure the RSB of the signal output from the direct conversion transmitter 1 as a second additional RSB according to the input of the gain mismatch parameter g _a .

)으로 나타나게 된다.The second additional RSB may be represented by Equation 16 below, and the second additional RSB may be represented by gain g and phase θ as shown in FIG. 4B. The circle (radius is centered on (g _a , θ _a ) in the plane

Will be displayed as).

[Equation 16]

Referring to FIG. 4B, it can be seen that there is only one intersection point (ie, sol ₂ ) on the (g _, θ) plane where the reference RSB, the first additional RSB, and the second additional RSB meet.

The intersection point where the reference RSB, the first additional RSB, and the second additional RSB meet can be known by the controller 120 in combination with Equation 4, Equation 13, and Equation 16 above.

이고, 제2 추가 RSB의 크기가 제1 추가 RSB의 크기보다 큰 경우에는

이 됨을 알 수 있으므로, 제어부(120)는 기준 RSB와 제1 추가 RSB를 통해 위상 에러 파라미터(θ_err)를 결정한 뒤, 제1 추가 RSB의 크기와 제2 추가 RSB의 크기 비교를 통해 게인 에러 파라미터(g_err)를 결정할 수도 있다.Alternatively, the intersection point of the reference RSB, the first additional RSB, and the second additional RSB may be controlled by the controller 120 first through the reference RSB and the first additional RSB (the system of Equations 4 and 13). θ _err ) can be determined by comparing the size of the first additional RSB with the size of the second additional RSB. More specifically, referring to FIG. 4B, when the size of the second additional RSB is smaller than the size of the first additional RSB.

If the size of the second additional RSB is greater than the size of the first additional RSB

The controller 120 determines the phase error parameter θ _err through the reference RSB and the first additional RSB, and then increases the gain error parameter by comparing the magnitude of the first additional RSB with the size of the second additional RSB. You can also determine (g _err ).

That is, the controller 120 determines the gain error parameter g _err and the phase error parameter θ _{err of} the direct conversion transmitter 1 using the reference RSB and the first additional RSB (the reference RSB and the first additional RSB). If there is only one intersection point between RSBs), the gain error parameter g _err and the phase error parameter θ _{err of} the direct conversion transmitter 1 are obtained using the reference RSB, the first additional RSB, and the second additional RSB. Can be determined (if there are two intersections between the reference RSB and the first additional RSB).

Third Embodiment

5A is _a diagram exemplarily illustrating a first additional RSB measured when _a gain mismatch parameter g _a is input to _a digital baseband.

In order to determine the gain error parameter g _err and the phase error parameter θ _{err of the} direct conversion transmitter 1, the controller 120 may input _a gain mismatch parameter g _a to the digital baseband. In this case, the RSB measuring unit 110 may measure the RSB of the signal output from the direct conversion transmitter 1 as the first additional RSB according to the input of the gain mismatch parameter g _a .

)으로 나타나게 된다.The first additional RSB may be represented by Equation 17 below, and the first additional RSB may be represented by a gain g and a phase θ as shown in FIG. 5A. The circle (radius centered around (g _a , 0) in the plane)

Will be displayed as).

[Equation 17]

Referring to FIG. 5A, it can be seen that there are two intersection points (ie, sol ₁ and sol ₂ ) on the plane (g _, θ) where the reference RSB and the first additional RSB meet each other. Can be found by solving the equations (4) and (17).

However, there may be a case where only one intersection point between the reference RSB and the first additional RSB exists on the plane (g _, θ). In this case, the second additional RSB to be described later does not need to be measured. The parameter may be determined as a gain error parameter g _err and a phase error parameter θ _err of the direct conversion transmitter 1.

However, as shown in FIG. 5A, when there are two intersection points (ie, sol ₁ , sol ₂ ) between the reference RSB and the first additional RSB, any one of the two intersections gains the gain of the direct conversion transmitter 1. The error parameter g _err and the phase error parameter θ _err must be determined.

FIG. 5B is _a diagram exemplarily illustrating a second additional RSB measured when _a phase mismatch parameter θ _a is input to the digital baseband instead of the gain mismatch parameter ga, wherein the reference RSB and the first additional RSB are shown. FIG. In order to determine an intersection corresponding to the gain error parameter g _err and the phase error parameter θ _err of the direct conversion transmitter 1 among the two intersections, the control unit 120 controls the gain mismatch parameter (D) in the digital baseband. g _a ), instead, may input _a phase mismatch parameter θ _a , whereby the RSB measurement unit 110 is output from the direct conversion transmitter 1 according to the input of the phase mismatch parameter θ _a . The RSB of the signal can be measured as the second additional RSB.

)으로 나타나게 된다.The second additional RSB may be represented by Equation 18, and the second additional RSB may be represented by a gain g and a phase θ as shown in FIG. 5B. The circle (radius is centered on (0, θ _a ) in the plane

Will be displayed as).

Equation 18

Referring to FIG. 5B, it can be seen that only one intersection point (ie, sol ₁ ) exists on the (g _, θ) plane where the reference RSB, the first additional RSB, and the second additional RSB meet.

The intersection point where the reference RSB, the first additional RSB, and the second additional RSB meet can be known by the controller 120 in combination with Equation 4, Equation 17 and Equation 18.

That is, the controller 120 determines the gain error parameter g _err and the phase error parameter θ _{err of} the direct conversion transmitter 1 using the reference RSB and the first additional RSB (the reference RSB and the first additional RSB). If there is only one intersection point between RSBs), the gain error parameter g _err and the phase error parameter θ _{err of} the direct conversion transmitter 1 are obtained using the reference RSB, the first additional RSB, and the second additional RSB. Can be determined (if there are two intersections between the reference RSB and the first additional RSB).

Fourth Example

FIG. 6A is _a diagram exemplarily illustrating a first additional RSB measured when _a phase mismatch parameter θ _a is input to _a digital baseband.

In order to determine the gain error parameter g _err and the phase error parameter θ _{err of the} direct conversion transmitter 1, the controller 120 may input _a phase mismatch parameter θ _a to the digital baseband. In this case, the RSB measuring unit 110 may measure the RSB of the signal output from the direct conversion transmitter 1 as the first additional RSB according to the input of the phase mismatch parameter θ _a .

)으로 나타나게 된다.The first additional RSB may be represented by Equation 19 below, and the first additional RSB may be represented by a gain g and a phase θ as shown in FIG. 6A. The circle (radius is centered on (0, θ _a ) in the plane

Will be displayed as).

[Equation 19]

Referring to FIG. 6A, it can be seen that there are two intersection points (ie, sol ₁ and sol ₂ ) on the plane (g _, θ) where the reference RSB and the first additional RSB meet, and thus, the reference RSB and the first additional RSB. Can be found by solving the equations (4) and (19).

However, there may be a case where only one intersection point between the reference RSB and the first additional RSB exists on the plane (g _, θ). In this case, the second additional RSB to be described later does not need to be measured. The parameter may be determined as a gain error parameter g _err and a phase error parameter θ _err of the direct conversion transmitter 1.

However, as shown in FIG. 6A, when there are two intersection points (ie, sol ₁ and sol ₂ ) between the reference RSB and the first additional RSB, any one of the two intersections gains the gain of the direct conversion transmitter 1. The error parameter g _err and the phase error parameter θ _err must be determined.

FIG. 6B is _a diagram exemplarily illustrating a second additional RSB measured when _a gain mismatch parameter g _a is input to the digital baseband instead of the phase mismatch parameter θ _a . In order to determine an intersection corresponding to a gain error parameter g _err and a phase error parameter θ _err of the direct conversion transmitter 1 among two intersection points between RSBs, the controller 120 controls a phase mismatch parameter to the digital baseband. Instead of (θ _a ), a gain mismatch parameter g _a may be input, and accordingly, the RSB measurement unit 110 outputs from the direct conversion transmitter 1 according to the input of the gain mismatch parameter g _a . The RSB of the signal to be measured can be measured as the second additional RSB.

)으로 나타나게 된다.The second additional RSB may be represented by Equation 20 below, and the second additional RSB may be represented by a gain g and a phase θ as shown in FIG. 6B. The circle (radius centered around (g _a , 0) in the plane)

Will be displayed as).

[Equation 20]

Referring to FIG. 6B, it can be seen that only one intersection point (ie, sol ₂ ) exists on the (g _, θ) plane where the reference RSB, the first additional RSB, and the second additional RSB meet.

The intersection point where the reference RSB, the first additional RSB, and the second additional RSB meet can be known by the controller 120 in combination with Equation 4, Equation 19, and Equation 20 above.

That is, the controller 120 determines the gain error parameter g _err and the phase error parameter θ _{err of} the direct conversion transmitter 1 using the reference RSB and the first additional RSB (the reference RSB and the first additional RSB). If there is only one intersection point between RSBs), the gain error parameter g _err and the phase error parameter θ _{err of} the direct conversion transmitter 1 are obtained using the reference RSB, the first additional RSB, and the second additional RSB. Can be determined (if there are two intersections between the reference RSB and the first additional RSB).

Fifth Embodiment

FIG. 7A is _a diagram exemplarily illustrating a first additional RSB measured when _a gain mismatch parameter g _a and a phase mismatch parameter θ _a are input to _a digital baseband.

In order to determine the gain error parameter g _err and the phase error parameter θ _{err of the} direct conversion transmitter 1, the control unit 120 controls the gain mismatch parameter g _a and the phase mismatch parameter (D) in the digital baseband. θ _a ) can be input at the same time, in which the RSB measurement unit 110 is output from the direct conversion transmitter 1 according to the gain mismatch parameter g _a and the phase mismatch parameter θ _a . The RSB of the signal can be measured as the first additional RSB.

)으로 나타나게 된다.The first additional RSB may be represented by Equation 21 below, and the first additional RSB may be represented by a gain g and a phase θ as shown in FIG. 7A. The circle (radius is centered on (g _a , θ _a ) in the plane

Will be displayed as).

[Equation 21]

Referring to FIG. 7A, it can be seen that _two intersection points (ie, sol ₁ and sol ₂ ) intersect the reference RSB and the first additional RSB on the plane (g _, θ), that is, the reference RSB and the first additional RSB. Can be found by solving equations 4 and 21 in a row.

However, there may be a case where only one intersection point between the reference RSB and the first additional RSB exists on the plane (g _, θ). In this case, the second additional RSB to be described later does not need to be measured. The parameter may be determined as a gain error parameter g _err and a phase error parameter θ _err of the direct conversion transmitter 1.

However, as shown in FIG. 7A, when there are two intersection points (i.e., sol ₁ , sol ₂ ) between the reference RSB and the first additional RSB, any one of the two points is the gain of the direct conversion transmitter 1. The error parameter g _err and the phase error parameter θ _err must be determined.

FIG. 7B is _a diagram exemplarily illustrating a second additional RSB measured when the phase mismatch parameter θ _a is removed from the digital baseband so that only the gain mismatch parameter g _a is input to the digital baseband. In order to determine an intersection corresponding to the gain error parameter g _err and the phase error parameter θ _err of the direct conversion transmitter 1 among the two intersection points between the reference RSB and the first additional RSB, the control unit 120 uses a digital base. By removing the phase mismatch parameter θ _a from the band, only the gain mismatch parameter g _a is input to the digital baseband. Accordingly, the RSB measuring unit 110 performs the gain mismatch parameter g _a . The RSB of the signal output from the direct conversion transmitter 1 can be measured as a second additional RSB according to the input of.

)으로 나타나게 된다.The second additional RSB may be represented by Equation 22, and the second additional RSB may be represented by a gain g and a phase θ as shown in FIG. 7B. The circle (radius around the g _a , 0) in the plane

Will be displayed as).

[Equation 22]

Referring to FIG. 7B, it can be seen that only one intersection point (ie, sol ₁ ) exists on the (g _, θ) plane where the reference RSB, the first additional RSB, and the second additional RSB meet.

The intersection point where the reference RSB, the first additional RSB, and the second additional RSB meet can be known by the controller 120 in combination with Equation 4, Equation 21 and Equation 22.

That is, the controller 120 determines the gain error parameter g _err and the phase error parameter θ _{err of} the direct conversion transmitter 1 using the reference RSB and the first additional RSB (the reference RSB and the first additional RSB). If there is only one intersection point between RSBs), the gain error parameter g _err and the phase error parameter θ _{err of} the direct conversion transmitter 1 are obtained using the reference RSB, the first additional RSB, and the second additional RSB. Can be determined (if there are two intersections between the reference RSB and the first additional RSB).

Sixth Example

8A is _a diagram exemplarily illustrating a first additional RSB measured when _a gain mismatch parameter g _a and a phase mismatch parameter θ _a are input to _a digital baseband.

In order to determine the gain error parameter g _err and the phase error parameter θ _{err of the} direct conversion transmitter 1, the control unit 120 controls the gain mismatch parameter g _a and the phase mismatch parameter (D) in the digital baseband. θ _a ) can be input at the same time, in which the RSB measurement unit 110 is output from the direct conversion transmitter 1 according to the gain mismatch parameter g _a and the phase mismatch parameter θ _a . The RSB of the signal can be measured as the first additional RSB.

)으로 나타나게 된다.The first additional RSB may be represented by Equation 23, and the first additional RSB may be represented by a gain g and a phase θ as shown in FIG. 8A. The circle (radius is centered on (g _a , θ _a ) in the plane

Will be displayed as).

[Equation 23]

Referring to FIG. 8A, it can be seen that there are two intersection points (ie, sol ₁ and sol ₂ ) on the plane (g _, θ) where the reference RSB and the first additional RSB meet each other. Can be found by solving equation 4 and equation 23 together.

However, there may be a case where only one intersection point between the reference RSB and the first additional RSB exists on the plane (g _, θ). In this case, the second additional RSB to be described later does not need to be measured. The parameter may be determined as a gain error parameter g _err and a phase error parameter θ _err of the direct conversion transmitter 1.

However, as shown in FIG. 8A, when there are two intersection points between the reference RSB and the first additional RSB (that is, sol ₁ and sol ₂ ), any one of the two intersections gains the gain of the direct conversion transmitter 1. The error parameter g _err and the phase error parameter θ _err must be determined.

8B is _a diagram illustrating a second additional RSB measured when the gain mismatch parameter g _a is removed from the digital baseband so that only the phase mismatch parameter θ _a is input to the digital baseband. In order to determine an intersection corresponding to the gain error parameter g _err and the phase error parameter θ _err of the direct conversion transmitter 1 among the two intersection points between the reference RSB and the first additional RSB, the control unit 120 uses a digital base. The gain mismatch parameter g _a may be removed from the band so that only the phase mismatch parameter θ _a is input to the digital baseband. Accordingly, the RSB measuring unit 110 performs the phase mismatch parameter θ _a . The RSB of the signal output from the direct conversion transmitter 1 can be measured as a second additional RSB according to the input of.

)으로 나타나게 된다.The second additional RSB may be represented by Equation 24 below, and the second additional RSB may be represented by a gain g and a phase θ as shown in FIG. 8B. The circle (radius is centered on (0, θ _a ) in the plane

Will be displayed as).

[Equation 24]

Referring to FIG. 8B, it can be seen that only one intersection point (ie, sol ₁ ) exists on the (g _, θ) plane where the reference RSB, the first additional RSB, and the second additional RSB meet.

The intersection point where the reference RSB, the first additional RSB, and the second additional RSB meet can be known by the controller 120 in combination with Equation 4, Equation 23, and Equation 24.

That is, the controller 120 determines the gain error parameter g _err and the phase error parameter θ _{err of} the direct conversion transmitter 1 using the reference RSB and the first additional RSB (the reference RSB and the first additional RSB). If there is only one intersection point between RSBs), the gain error parameter g _err and the phase error parameter θ _{err of} the direct conversion transmitter 1 are obtained using the reference RSB, the first additional RSB, and the second additional RSB. Can be determined (if there are two intersections between the reference RSB and the first additional RSB).

9 is a flowchart of a method for compensating I / Q imbalance of a direct conversion transmitter according to an embodiment of the present invention. Hereinafter, the I / Q of the direct conversion transmitter 1 according to an embodiment of the present invention will be described with reference to FIG. 9. How to compensate for Q imbalance will be explained.

In the I / Q imbalance compensation method of the direct conversion transmitter 1 according to an embodiment of the present invention, first, the digital baseband in-phase signal I _D is input by the RSB measurement unit 110 to the direct conversion transmitter 1. And a reference RSB measurement step of measuring the RSB of the signal output from the direct conversion transmitter 1 as a reference RSB with respect to the digital baseband quadrature signal Q _D (S100).

Next, a gain mismatch parameter g _a or a phase mismatch parameter θ _a is input to the digital baseband, and RSB according to the gain mismatch parameter g _a or phase mismatch parameter θ _a is obtained. An additional RSB measurement step of measuring as an additional RSB is made (S200).

The input of the gain mismatch parameter g _a or the phase mismatch parameter θ _a for the digital baseband may be performed by the controller 120. Here, the fact that the control unit 120 inputs the gain mismatch parameter g _a or the phase mismatch parameter θ _a to the digital baseband means that the control unit 120 inputs the gain mismatch parameter g _a to the digital baseband. Inputting only, inputting a phase mismatch parameter θ _a , or inputting a gain mismatch parameter g _a and a phase mismatch parameter θ _a simultaneously. In addition, measurement of the RSB (ie, additional RSB) according to the gain mismatch parameter g _a or the phase mismatch parameter θ _a may be performed by the RSB measurement unit 110.

Next, the controller 120 performs an error parameter determination step of determining a gain error parameter g _err and a phase error parameter θ _err using the reference RSB and the additional RSB (S300).

를 입력(즉, 게인 미스매치 파라미터로서

을 입력하고, 위상 미스매치 파라미터로서

을 입력)함으로써 직접 변환 송신기의 I/Q 불균형을 보상할 수 있다.Finally, the controller 120 inputs an inverse compensation value of the gain error parameter g _err and the phase error parameter θ _err to the digital baseband to compensate for the I / Q imbalance of the direct conversion transmitter. / Q performs an imbalance compensation step (S400). Specifically, the controller 120 is a digital baseband

Is entered as the gain mismatch parameter.

, Enter the phase mismatch parameter

Can compensate for the I / Q imbalance of the direct conversion transmitter.

In the I / Q imbalance compensation method of the direct conversion transmitter according to the present invention, the additional RSB measurement step may be performed by the first to sixth embodiments described above.

In brief, in the additional RSB measurement step according to the first embodiment, the RSB of the signal output from the direct conversion transmitter 1 is first added by inputting _a gain mismatch parameter g _a to the digital baseband. The RSB of the signal output from the direct conversion transmitter 1 may be measured as a second additional RSB by measuring as an RSB and further inputting _a phase mismatch parameter θ _a to the digital baseband.

In the additional RSB measurement step according to the second embodiment, the phase mismatch parameter θ _a is input to the digital baseband to measure the RSB of the signal output from the direct conversion transmitter 1 as the first additional RSB. By further inputting _a gain mismatch parameter g _a to the digital baseband, the RSB of the signal output from the direct conversion transmitter 1 may be measured as a second additional RSB.

In the additional RSB measurement step according to the third embodiment, the gain mismatch parameter g _a is input to the digital baseband to measure the RSB of the signal output from the direct conversion transmitter 1 as the first additional RSB. The RSB of the signal output from the direct conversion transmitter 1 may be measured as a second additional RSB by inputting the phase mismatch parameter θ _a to the digital baseband instead of the gain mismatch parameter g _a .

In the additional RSB measurement step according to the fourth embodiment, the phase mismatch parameter θ _a is input to the digital baseband to measure the RSB of the signal output from the direct conversion transmitter 1 as the first additional RSB. The RSB of the signal output from the direct conversion transmitter 1 may be measured as a second additional RSB by inputting the gain mismatch parameter g _a to the digital baseband instead of the phase mismatch parameter θ _a .

In a further RSB measurement step according to the fifth embodiment, a gain mismatch parameter g _a and a phase mismatch parameter θ _a are input to _a digital baseband to obtain an RSB of a signal output from the direct conversion transmitter 1. The direct conversion transmitter 1 is measured as a first additional RSB and the phase mismatch parameter θ _a is removed from the digital baseband so that only _a gain mismatch parameter g _a is input to the digital baseband. The RSB of the signal output from) can be measured as the second additional RSB.

Finally, in the additional RSB measurement step according to the sixth embodiment, a gain mismatch parameter g _a and a phase mismatch parameter θ _a are input to _a digital baseband to obtain an RSB of a signal output from the direct conversion transmitter. Measured as a first additional RSB and output from the direct conversion transmitter with the gain mismatch parameter g _a removed from the digital baseband such that only _a phase mismatch parameter θ _a is input to the digital baseband. The RSB of the signal to be measured can be measured as the second additional RSB.

After the additional RSB measurement step according to the embodiments, the control unit 120 uses the reference RSB, the first additional RSB and the second additional RSB to obtain the gain error parameter g _err and phase of the direct conversion transmitter 1. The error parameter θ _err may be determined, and the I / Q imbalance of the direct conversion transmitter 1 is input by inputting the inverse compensation values of the gain error parameter g _err and the phase error parameter θ _err into the digital baseband. You can compensate.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited to the above-described embodiments, which can be variously modified and modified by those skilled in the art to which the present invention pertains. Of course, variations are possible. Therefore, the technical idea of the present invention should be grasped only by the claims, and all equivalent or equivalent modifications thereof will belong to the scope of the technical idea of the present invention.

1: direct conversion transmitter
11: first DAC 12: second DAC
21: first low pass filter 22: second low pass filter
31: first mixer 32: second mixer
40: local oscillator 50: adder
100: I / Q imbalance compensation device
110: RSB measuring unit 120: control unit

Claims (14)

A device for compensating for I / Q imbalance in a direct conversion transmitter,
Representing a relationship between an upper band signal and a lower band signal of a signal output from the direct conversion transmitter with respect to an in-phase signal I _D and a quadrature phase signal Q _D of a digital baseband input to the direct conversion transmitter. An RSB measurement unit measuring a residual side-band (RSB) as a reference RSB; And
And a controller for inputting a gain mismatch parameter g _a or a phase mismatch parameter θ _a to the digital baseband.
The RSB measurement unit measures an RSB of a signal output from the direct conversion transmitter as an additional RSB according to the gain mismatch parameter g _a or phase mismatch parameter θ _a input to the digital baseband.
The controller determines an intersection where the reference RSB and the additional RSB measured by the RSB measuring unit meet in a plane consisting of gain and phase as a gain error parameter g _err and a phase error parameter θ _err of the direct conversion transmitter. And inputting an inverse compensation value of the gain error parameter g _err and the phase error parameter θ _err into the digital baseband to compensate for the I / Q imbalance of the direct conversion transmitter. I / Q imbalance compensation device.
The method of claim 1,
The control unit inputs _a gain mismatch parameter g _a to the digital baseband, and the RSB measurement unit first outputs an RSB of a signal output from the direct conversion transmitter according to an input of the gain mismatch parameter g _a . Measured as an additional RSB,
The control unit further inputs _a phase mismatch parameter θ _a to the digital baseband, and the RSB measuring unit removes an RSB of a signal output from the direct conversion transmitter according to the input of the phase mismatch parameter θ _a . 2 measured as an additional RSB,
The controller determines the gain error parameter g _err and the phase error parameter θ _err by using the reference RSB, the first additional RSB, and the second additional RSB. Device.
The method of claim 1,
The control unit inputs _a phase mismatch parameter θ _a to the digital baseband, and the RSB measurement unit first outputs an RSB of a signal output from the direct conversion transmitter according to the input of the phase mismatch parameter θ _a . Measured as an additional RSB,
The control unit further inputs _a gain mismatch parameter g _a to the digital baseband, and the RSB measuring unit removes an RSB of a signal output from the direct conversion transmitter according to the input of the gain mismatch parameter g _a . 2 measured as an additional RSB,
The controller determines the gain error parameter g _err and the phase error parameter θ _err by using the reference RSB, the first additional RSB, and the second additional RSB. Device.
The method of claim 1,
The control unit inputs _a gain mismatch parameter g _a to the digital baseband, and the RSB measurement unit first outputs an RSB of a signal output from the direct conversion transmitter according to an input of the gain mismatch parameter g _a . Measured as an additional RSB,
The control unit inputs the phase mismatch parameter θ _a to the digital baseband instead of the gain mismatch parameter g _a , and the RSB measurement unit directly inputs the input according to the phase mismatch parameter θ _a . Measuring the RSB of the signal output from the conversion transmitter as a second additional RSB,
The controller determines the gain error parameter g _err and the phase error parameter θ _err by using the reference RSB, the first additional RSB, and the second additional RSB. Device.
The method of claim 1,
The control unit inputs _a phase mismatch parameter θ _a to the digital baseband, and the RSB measurement unit first outputs an RSB of a signal output from the direct conversion transmitter according to the input of the phase mismatch parameter θ _a . Measured as an additional RSB,
The control unit inputs the gain mismatch parameter g _a to the digital baseband instead of the phase mismatch parameter θ _a , and the RSB measurement unit directly inputs the input according to the gain mismatch parameter g _a . Measuring the RSB of the signal output from the conversion transmitter as a second additional RSB,
The controller determines the gain error parameter g _err and the phase error parameter θ _err by using the reference RSB, the first additional RSB, and the second additional RSB. Device.
The method of claim 1,
The control unit inputs _a gain mismatch parameter g _a and a phase mismatch parameter θ _a to the digital baseband, and the RSB measurement unit measures the gain mismatch parameter g _a and a phase mismatch parameter θ _a. Measuring the RSB of the signal output from the direct conversion transmitter as a first additional RSB according to
The controller removes the phase mismatch parameter θ _a from the digital baseband so that only the gain mismatch parameter g _a is input to the digital baseband, and the RSB measurement unit measures the gain mismatch parameter g. measuring the RSB of the signal output from the direct conversion transmitter as a second additional RSB according to the input of _a ),
The controller determines the gain error parameter g _err and the phase error parameter θ _err by using the reference RSB, the first additional RSB, and the second additional RSB. Device.
The method of claim 1,
The control unit inputs _a gain mismatch parameter g _a and a phase mismatch parameter θ _a to the digital baseband, and the RSB measurement unit measures the gain mismatch parameter g _a and a phase mismatch parameter θ _a. Measuring the RSB of the signal output from the direct conversion transmitter as a first additional RSB according to
The controller removes the gain mismatch parameter g _a from the digital baseband so that only the phase mismatch parameter θ _a is input to the digital baseband, and the RSB measurement unit measures the phase mismatch parameter θ. measuring the RSB of the signal output from the direct conversion transmitter as a second additional RSB according to the input of _a ),
The controller determines the gain error parameter g _err and the phase error parameter θ _err by using the reference RSB, the first additional RSB, and the second additional RSB. Device.
A method for compensating for I / Q imbalance in a direct conversion transmitter,
The relationship between the upper sideband signal and the lower sideband signal of the signal output from the direct conversion transmitter with respect to the digital baseband in-phase signal I _D and the digital baseband quadrature signal Q _D input to the direct conversion transmitter. A reference RSB measurement step of measuring a residual side-band (RSB) indicating as a reference RSB;
Gain mismatch parameters to the digital baseband (g _a) or the phase mismatch parameter (θ _a) to enter the said direct conversion transmitter according to the gain mismatch parameter (g _a) or the phase mismatch parameter (θ _a) An additional RSB measurement step of measuring the RSB of the signal output from the additional RSB;
An error parameter determining step of determining an intersection where the reference RSB and the additional RSB meet in a plane consisting of gain and phase as a gain error parameter g _err and a phase error parameter θ _err of the direct conversion transmitter; And
And an I / Q imbalance compensation step of compensating I / Q imbalance of the direct conversion transmitter by inputting an inverse compensation value of the gain error parameter g _err and a phase error parameter θ _err to the digital baseband. I / Q imbalance compensation method of direct conversion transmitter.
The method of claim 8,
In the additional RSB measurement step,
Input _a gain mismatch parameter g _a to the digital baseband to measure the RSB of the signal output from the direct conversion transmitter as a first additional RSB, and add a phase mismatch parameter θ _a to the digital baseband. Measuring the RSB of a signal input and output from the direct conversion transmitter as a second additional RSB,
In the error parameter determination step,
And determining the gain error parameter (g _err ) and the phase error parameter (θ _err ) using the reference RSB, the first additional RSB, and the second additional RSB.
The method of claim 8,
In the additional RSB measurement step,
Input _a phase mismatch parameter θ _a to the digital baseband to measure the RSB of the signal output from the direct conversion transmitter as a first additional RSB, and add a gain mismatch parameter g _a to the digital baseband. Measuring the RSB of a signal input and output from the direct conversion transmitter as a second additional RSB,
In the error parameter determination step,
And determining the gain error parameter (g _err ) and the phase error parameter (θ _err ) using the reference RSB, the first additional RSB, and the second additional RSB.
The method of claim 8,
In the additional RSB measurement step,
Inputting _a gain mismatch parameter g _a to the digital baseband to measure the RSB of the signal output from the direct conversion transmitter as a first additional RSB, and instead of the gain mismatch parameter g _a to the digital baseband. Inputting the phase mismatch parameter θ _a to measure the RSB of the signal output from the direct conversion transmitter as a second additional RSB,
In the error parameter determination step,
And determining the gain error parameter (g _err ) and the phase error parameter (θ _err ) using the reference RSB, the first additional RSB, and the second additional RSB.
The method of claim 8,
In the additional RSB measurement step,
Inputting _a phase mismatch parameter θ _a to the digital baseband to measure the RSB of the signal output from the direct conversion transmitter as a first additional RSB, and instead of the phase mismatch parameter θ _a to the digital baseband. Inputting the gain mismatch parameter g _a to measure the RSB of the signal output from the direct conversion transmitter as a second additional RSB,
In the error parameter determination step,
And determining the gain error parameter (g _err ) and the phase error parameter (θ _err ) using the reference RSB, the first additional RSB, and the second additional RSB.
The method of claim 8,
In the additional RSB measurement step,
A gain mismatch parameter g _a and a phase mismatch parameter θ _a are input to the digital baseband to measure an RSB of a signal output from the direct conversion transmitter as a first additional RSB, and in the digital baseband, The RSB of the signal output from the direct conversion transmitter is measured as a second additional RSB while removing _a phase mismatch parameter θ _a so that only _a gain mismatch parameter g _a is input to the digital baseband.
In the error parameter determination step,
And determining the gain error parameter (g _err ) and the phase error parameter (θ _err ) using the reference RSB, the first additional RSB, and the second additional RSB.
The method of claim 8,
In the additional RSB measurement step,
A gain mismatch parameter g _a and a phase mismatch parameter θ _a are input to the digital baseband to measure an RSB of a signal output from the direct conversion transmitter as a first additional RSB, and in the digital baseband, The RSB of the signal output from the direct conversion transmitter is measured as a second additional RSB while removing _a gain mismatch parameter g _a so that only _a phase mismatch parameter θ _a is input to the digital baseband.
In the error parameter determination step,
And determining the gain error parameter (g _err ) and the phase error parameter (θ _err ) using the reference RSB, the first additional RSB, and the second additional RSB.

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