KR20130034097A - System for distortion compensation of ultra fast impulse signal on coaxial cable - Google Patents

Abstract

PURPOSE: A system for solving distortion of a high-speed impulse signal on a coaxial cable is provided to draw the peak value and rise time of an original signal which is not distorted using the characteristic of a distorted signal drawn through a measuring instrument, thereby solving the distortion problem generated on the coaxial cable due to the distortion of the high-speed impulse signal. CONSTITUTION: An input module(100) inputs an impulse signal to measure, conducts Laplace transform and draws a frequency spectrum waveform equation of a pulse signal which is not distorted. A network analysis module(200) converts the value of a coaxial cable into a complex number equation. A cable feature extraction module(300) draws a transfer function(S) of the cable through curve fitting. A distorted pulse signal calculation module(400) draws a distorted pulse signal using the transfer function. A distorted signal compensation module(500) draws the peak value and rise time of a signal which is not distorted through curve fitting. [Reference numerals] (S100) Input module; (S200) Network analysis module; (S300) Cable feature extraction module; (S400) Distorted pulse signal calculation module; (S500) Distorted signal compensation module;

Description

SYSTEM FOR DISTORTION COMPENSATION OF ULTRA FAST IMPULSE SIGNAL ON COAXIAL CABLE}

The present invention relates to a system for solving the distortion problem of an impulse signal, and more particularly, the rise time and peak value of a distorted signal derived from a measuring instrument, and the rise time and peak of an original signal that is not distorted using the characteristics of a cable. The present invention relates to a system for solving distortion problems of ultra-high speed impulse signals occurring on coaxial cables.

Currently, high frequency circuits of various wireless communication devices commonly found around us are mainly implemented by mounting elements on circuit boards, and coaxial cables are widely used for signal transmission and reception between such circuit boards and external signal sources. .

The coaxial cable is a medium capable of transmitting both an analog signal and a digital signal, and an inner conductor is surrounded by an inner insulator made of a dielectric, an outer conductor surrounds the inner insulator, and finally an outer insulator wraps the outer conductor. Has a concentric structure.

The coaxial cable is widely used in high frequency systems because it receives less external electrical interference and less power loss.

In the case of a single frequency, copper loss and dielectric loss occur, but since dispersion problems do not occur, it is easy to recover the original signal simply by experimentally comparing the original signal and confirming how much the voltage is reduced. Since the loss factor is determined according to the frequency of the cable, if only the frequency of the signal is known, the loss factor can be multiplied to restore the original signal level.

However, in the case of the impulse signal, ?? has a frequency bandwidth that spans the area, so a dispersion problem occurs and multiplying only the loss coefficient at a specific frequency does not give rise to the rise time and peak value of the original signal.

In recent years, research and development have been made in connection with the present invention, and many other publications have been disclosed, including Korean Patent Application Publication No. 10-2007-0052396 (cable connection device for suppressing intermodulation distortion).

The prior document has a body portion is formed so that the coaxial cable for transmitting a signal is inserted into the circuit board; A first support part supporting a bottom surface of the circuit board; And a second support part supporting the upper surface of the circuit board at a predetermined distance from the first support part.

As described above, the prior art document may insulate the circuit board and the conductor board to transmit a signal by reducing the magnitude of the intermodulation distortion.

However, the above-mentioned prior document cannot completely solve the distortion, and the rise time and peak value of the original signal cannot be known.

In order to solve the above problems, the present invention derives the rise time and peak value of the original signal, which is not distorted, in a short time by using the rise time and peak value of the distorted signal derived from the measuring instrument and the characteristics of the cable. It is an object of the present invention to provide a system for solving a distortion problem of an ultra-high speed impulse signal occurring on a coaxial cable.

)을 도출하는 입력모듈; 동축 케이블을 네트워크 분석기를 통해 크기와 위상값을 포함하는

또는

값을 도출하고 복소수식으로 변환시키는 네트워크분석모듈; 네트워크분석모듈를 통해 도출한

또는

을 데이터 분석 프로그램을 이용하여 곡선접합(curve fitting)하여 케이블의 전달함수

(S)를 도출하는 케이블특성추출모듈; 입력모듈를 통해 도출한 (

), 보상상수(k) 및 케이블특성추출모듈를 통해 도출한 전달함수

(S)를 이용하여 왜곡된 펄스 신호를 도출하는 왜곡펄스신호계산모듈; 및 왜곡펄스신호계산모듈를 통해 도출한 데이터값을 곡선접합(curve fitting)을 수행하여 왜곡되지 않은 신호의 상승시간과 첨두값을 도출하는 왜곡신호보상모듈; 를 포함한다.In order to achieve the above technical problem, a system for solving a distortion problem of an ultra-high speed impulse signal occurring on a coaxial cable according to the present invention includes inputting an impulse signal to be measured, and performing a Laplace transform on an equation of a frequency spectrum waveform of a pulse signal before distortion.

An input module for deriving); Coaxial cable containing the magnitude and phase value through the network analyzer

or

A network analysis module for deriving a value and converting the value into a complex equation; Derived through the network analysis module

or

Cable transfer function by curve fitting using a data analysis program

Cable characteristic extraction module for deriving (S); Derived through the input module (

), The transfer constant derived from the compensation constant (k) and the cable characteristic extraction module

A distortion pulse signal calculation module for deriving a distorted pulse signal using (S); And a distortion signal compensation module configured to perform curve fitting on the data values derived through the distortion pulse signal calculation module to derive the rise time and the peak value of the non-distorted signal. .

), 보상상수(k) 및 케이블특성추출모듈를 통해 도출한 전달함수

(S)를 이용하여 왜곡된 펄스 신호를 도출하되, 다음의 [수식6]를 통해 도출하는 것을 포함한다.In addition, the distortion pulse signal calculation module is derived through the input module (

), The transfer constant derived from the compensation constant (k) and the cable characteristic extraction module

Deriving a distorted pulse signal using (S), including the following through [Equation 6].

[수식6]

[Equation 6]

In addition, the distortion pulse signal calculation module includes deriving an integral term including two singular points of [Equation 6] through Cauchy integration between the two singular points, as shown in the following [Equation 7].

[수식7]

[Equation 7]

는 원래 펄스 신호의 peak값,

와

는 특이점,

(s)는

(s)의 실수 부분.here,

Is the peak value of the original pulse signal,

Wow

Is singularity,

(s) is

the real part of (s).

In addition, the distortion signal compensation module includes performing curve fitting on the data values derived through the distortion pulse signal calculation module to derive a delay value of the rise time due to the distortion as shown in Equation 8 below.

[수식8]

[Equation 8]

는 왜곡으로 인한 상승시간의 뒤쳐짐(지연) 정도,

는 원래 신호의 상승시간.here,

Is the lag of the rise time due to distortion,

Is the rise time of the original signal.

,

)과 왜곡된 신호의 상승시간을 다음의 [수식11]에 대입하여 원래 신호의 상승시간을 도출하는 것을 포함한다.For the distortion signal compensation ratio, refer to the data sheet of the coaxial cable.

,

) And substituting the rise time of the distorted signal into Equation 11 below to derive the rise time of the original signal.

[수식11]

[Equation 11]

및

는 동축 케이블의 특성,

는 왜곡된 신호의 상승시간.here,

And

Characteristics of coaxial cable,

Is the rise time of the distorted signal.

In addition, curve fitting is performed on the data values derived through the distortion pulse signal calculation module to derive a ratio of the peak value of the distorted signal and the peak value of the undistorted original signal as shown in Equation 12 below. It includes.

[수식12]

[Equation 12]

는 왜곡된 신호의 첨두값,

는 왜곡된 신호의 상승시간,

는 원래 왜곡되지 않은 신호의 첨두값.here,

Is the peak value of the distorted signal,

Is the rise time of the distorted signal,

Is the peak of the original undistorted signal.

,

), 왜곡된 신호의 상승시간 및 왜곡된 신호의 첨두값를 다음의 [수식14]에 대입하여 왜곡되지 않은 원래 신호의 첨두값을 도출하는 것을 포함한다.For the distortion signal compensation module, refer to the data sheet of the coaxial cable.

,

), Substituting the rise time of the distorted signal and the peak value of the distorted signal into the following Equation 14 to derive the peak value of the original signal that is not distorted.

[수식14]

[Equation 14]

및

는 동축 케이블의 특성값,

는 왜곡된 신호의 첨두값,

는 왜곡된 신호의 상승시간.here,

And

Is the characteristic value of the coaxial cable,

Is the peak value of the distorted signal,

Is the rise time of the distorted signal.

According to the present invention as described above, by providing a generalized system for deriving the rise time and peak value of the original signal, by using the cable characteristic value of the data sheet and the rise time and peak value of the distorted signal, There is an effect of deriving the rise time and the peak value in a short time.

1 is an overall configuration diagram of a system for solving distortion problem of an ultra-high speed impulse signal occurring on a coaxial cable according to the present invention.
Figure 2 is an embodiment of a network analysis module of the system for solving the distortion problem of the ultra-high speed impulse signal occurring on the coaxial cable according to the present invention.
3 is a cable characteristic value of the cable characteristic extraction module of the system for solving the distortion problem of the ultra-high speed impulse signal occurring on the coaxial cable according to the present invention.
Figure 4 is a cable characteristic value of the cable characteristic extraction module of the system for solving the distortion problem of the ultra-high speed impulse signal occurring on the coaxial cable according to the present invention.
Diagram showing the.
5 is a data value of a distortion pulse signal calculation module of a system for solving a distortion problem of a high speed impulse signal occurring on a coaxial cable according to the present invention;
6 is a data value of a distortion pulse signal calculation module of a system for solving a distortion problem of an ultra-high speed impulse signal occurring on a coaxial cable according to the present invention.

Specific features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. Prior to this, terms and words used in the present specification and claims are to be interpreted in accordance with the technical idea of the present invention based on the principle that the inventor can properly define the concept of the term in order to explain his invention in the best way. It should be interpreted in terms of meaning and concept. It is to be noted that the detailed description of known functions and constructions related to the present invention is omitted when it is determined that the gist of the present invention may be unnecessarily blurred.

Hereinafter, a system and a method for solving the distortion problem of an ultra-high speed impulse signal occurring on a coaxial cable will be described in detail with reference to the accompanying drawings. 1 is an overall configuration diagram of a system for solving a distortion problem of an ultra-high speed impulse signal occurring on a coaxial cable according to the present invention.

As shown in FIG. 1, a system for solving a distortion problem of an ultra-high speed impulse signal occurring on a coaxial cable according to the present invention includes an input module 100, a network analysis module 200, a cable characteristic extraction module 300, and a distortion. It comprises a pulse signal calculation module 400 and the distortion signal compensation module 500.

First, the input module 100 is expressed in the following Equation 1 to obtain the rising time (nsec) of the non-distorted state, that is, the impulse signal to be measured.

[수식1]

[Equation 1]

와

는 상승시간 및 펄스폭을 결정하는 시간상수,

는 첨두치, k는 보상상수를 나타낸다.
here,

Wow

Is a time constant that determines rise time and pulse width,

Is the peak and k is the compensation constant.

The compensation constant k is calculated by the following [Equation 2].

[수식2]

[Equation 2]

In order to obtain the equation of the frequency spectrum waveform of the impulse signal to be measured, Equation 1 is expressed by Laplace transform as shown in Equation 3 below.

[수식3]

[Equation 3]

The rise time of the pulse is defined as the time from the 0.1 point to the 0.9 point of the peak and the pulse width is defined as the Full Width Half Maximum.

또는

데이터를 도출한다.In addition, as shown in Figure 2, the network analysis module 200 is the amplitude (Amplitude) and phase (Phase) value of the coaxial cable through a network analyzer (Network Analyzer)

or

Derive the data.

와

는 같은 데이터 값이므로 어떠한 것을 사용해도 무방하다.here,

Wow

Since is the same data value, you can use any one.

(s)의 함수라고 가정하고, 상기

데이터를 복소수 형태로 변환시키면 다음의 [수식4]와 같이 나타낸다.The amplitude is A (s) and the phase is

Assume that it is a function of (s),

When data is converted into the complex form, it is expressed as the following [Equation 4].

[수식4]

[Equation 4]

+j

(s는 복소주파수,

는 각주파수),

=2

f (f는 주파수)를 나타낸다.
Where s =

+ j

(s is complex frequency,

Is the angular frequency),

= 2

f (f is frequency).

In addition, the cable characteristic extraction module 300 may derive the transfer function of the cable when performing curve fitting on the S (s) data derived through the network conversion module 200 using a data analysis program. This is derived using the following [Equation 5].

[수식5]

[Equation 5]

Here, the unknowns including n and m are shown in FIGS. 3 to 4, and each unknown is different for each cable and is an index indicating the characteristics of the cable.

)과 보상상수(k) 및 상기 케이블특성추출모듈(300)을 통해 도출한 전달함수

(s)를 다음의 [수식6]에 대입하여 왜곡된 펄스 신호를 구한다.In addition, the distortion pulse signal calculation module 400 is a formula of the frequency spectrum waveform of the pre-distorted pulse signal derived through the input module 100 (

) And the compensation function (k) and the transfer function derived through the cable characteristic extraction module 300

Substituting (s) into Equation 6 below, the distorted pulse signal is obtained.

[수식6]

[Equation 6]

The integral term of [Equation 6] includes two singularities. If Cauchy integration is performed between two singularities, the following distortion pulse function is obtained.

[수식7]

[Equation 7]

는 원래 펄스 신호의 peak값,

와

는 특이점,

(s)는

(s)의 실수 부분을 나타낸다.
here,

Is the peak value of the original pulse signal,

Wow

Is singularity,

(s) is

The real part of (s) is shown.

In addition, as shown in Figures 5 to 6, by changing the original input signal in [Equation 7] to derive a distorted signal, and to derive data including the difference between the rise time and the peak value of the two signals Show in graph.

In addition, the distortion signal compensation module 500 curve-fits the data values derived through the distortion pulse signal calculation module 400 to represent a linear function to increase the distortion due to distortion as shown in Equation 8 below. The delay value of time is derived.

[수식8]

[Equation 8]

는 왜곡으로 인한 상승시간의 뒤쳐짐(지연) 정도,

는 원래 신호의 상승시간을 나타낸다.
here,

Is the lag of the rise time due to distortion,

Represents the rise time of the original signal.

On the other hand, the relationship between the original rise time and the distorted rise time is expressed by the following equation (9).

[수식9]

[Equation 9]

는 왜곡된 신호의 상승시간을 나타낸다.
here,

Represents the rise time of the distorted signal.

에 대입하여 다음의 [수식10]을 도출한다.Equation 8 to Equation 9

Substituting in, yields the following [Equation 10].

[수식10]

[Equation 10]

1.6635 and 0.4674 are values representing the characteristics of any one of the existing coaxial cables, and when Equation 10 is generalized, Equation 11 is shown.

[수식11]

[Equation 11]

및

는 동축 케이블의 특성을 나타내는 것으로서, 사용자가 사용하려는 동축 케이블의 데이터시트를 참고하여

및

값 및 왜곡된 신호의 상승시간을 [수식11]에 대입하면 원래 신호의 상승시간을 도출한다.
here,

And

Indicates the characteristics of the coaxial cable, refer to the data sheet of the coaxial cable

And

Substituting the value and the rise time of the distorted signal into [Equation 11] derives the rise time of the original signal.

In addition, the distortion signal compensation module 500 curve-fits the data values derived through the distortion pulse signal calculation module 400 to represent a linear function to express an undistorted signal as shown in Equation 12 below. The ratio between the peak value and the peak value of the distorted signal is derived.

[수식12]

[Equation 12]

는 왜곡된 신호의 첨두값,

는 왜곡된 신호의 상승시간,

는 원래 왜곡되지 않은 신호의 첨두값을 나타낸다.
here,

Is the peak value of the distorted signal,

Is the rise time of the distorted signal,

Denotes the peak of the original undistorted signal.

When summed up to the peak value (peak value of the original signal) of the undistorted signal to be obtained through Equation 12, Equation 13 below.

[수식13]

[Equation 13]

The above values 0.0011 and 0.923 represent characteristics of any one of the existing coaxial cables, and when generalized in Equation 13, Equation 14 is used.

[수식14]

[Equation 14]

및

는 동축 케이블의 특성을 나타내는 것으로서, 사용자가 사용하려는 동축 케이블의 데이터시트를 참고하여

및

값을 [수식14]에 대입하면 왜곡된 신호의 첨두값을 통해 원래 신호의 첨두값을 도출한다.here,

And

Indicates the characteristics of the coaxial cable, refer to the data sheet of the coaxial cable

And

Substituting the value into [Equation 14] derives the peak value of the original signal through the peak value of the distorted signal.

While the present invention has been particularly shown and described with reference to preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It will be appreciated by those skilled in the art that numerous changes and modifications may be made without departing from the invention. And all such modifications and changes as fall within the scope of the present invention are therefore to be regarded as being within the scope of the present invention.

S: Distortion problem solving system of high speed impulse signal
100: input module 200: network analysis module
300: cable characteristic extraction module 400: distortion pulse signal calculation module
500: distortion signal compensation module

Claims (7)

In a system for solving the distortion problem of an ultra-high speed impulse signal occurring on a coaxial cable,
Input the impulse signal to be measured and Laplace transform the frequency spectrum of the pulse signal before distortion.

An input module 100 for deriving;
Coaxial cable containing the magnitude and phase value through the network analyzer

or

A network analysis module 200 for deriving a value and converting the value into a complex equation;
Derived through the network analysis module 200

or

Cable transfer function by curve fitting using a data analysis program

Cable characteristic extraction module 300 for deriving (S); Derived through the input module 100 (

), The compensation constant (k) and the transfer function derived through the cable characteristic extraction module 300

A distortion pulse signal calculation module 400 for deriving a distorted pulse signal using (S); And
A distortion signal compensation module 500 for deriving a rise time and a peak value of the non-distorted signal by performing curve fitting on the data values derived through the distortion pulse signal calculation module 500; Distortion problem solving system of ultra-high speed impulse signal generated on a coaxial cable comprising a.
The method of claim 1,
The distortion pulse signal calculation module 400,
Derived through the input module 100 (

), The compensation constant (k) and the transfer function derived through the cable characteristic extraction module 300

A system for solving distortion problems of ultra-high speed impulse signals generated on a coaxial cable, wherein the distorted pulse signal is derived using (S), but is derived through Equation 6 below.

[Equation 6]
The method of claim 2,
The distortion pulse signal calculation module 400,
An ultrafast impulse generated on a coaxial cable characterized by deriving a distortion pulse function as shown in [Equation 7] through Cauchy integration between the integral term containing two singular points of [Equation 6] between two singular points. Signal distortion problem solving system.

[Equation 7]
here,

Is the peak value of the original pulse signal,

Wow

Is singularity,

(s) is

the real part of (s).
The method of claim 1,
The distortion signal compensation module 500,
A coaxial cable comprising a curve fitting of a data value derived through the distortion pulse signal calculation module 400 to derive a delay value of a rise time due to distortion as shown in Equation 8 below. Distortion Problem Solving System for High-Speed Impulse Signals

[Equation 8]
here,

Is the lag of the rise time due to distortion,

Is the rise time of the original signal.
5. The method of claim 4,
The distortion signal compensation ratio 500 is,
Refer to the data sheet for the coaxial cable and

,

) And the rise time of the distorted signal is substituted into the following Equation 11 to derive the rise time of the original signal.

[Equation 11]
here,

And

Characteristics of coaxial cable,

Is the rise time of the distorted signal.
The method of claim 1,
The ratio of the peak value of the distorted signal and the peak value of the undistorted original signal is performed by performing curve fitting on the data value derived through the distortion pulse signal calculation module 400. Distortion problem solving system of the ultra-high speed impulse signal generated on the coaxial cable, characterized in that to derive.

[Equation 12]
here,

Is the peak value of the distorted signal,

Is the rise time of the distorted signal,

Is the peak of the original undistorted signal.
The method according to claim 6,
The distortion signal compensation module 500,
Refer to the data sheet for the coaxial cable and

,

), The distortion problem of the high-speed impulse signal generated on the coaxial cable characterized in that the peak value of the original signal is not distorted by substituting the rise time of the distorted signal and the peak value of the distorted signal into Equation 14 below. Resolution system.

[Equation 14]
here,

And

Is the characteristic value of the coaxial cable,

Is the peak value of the distorted signal,

Is the rise time of the distorted signal.

Images