KR100683393B1 - Simplified interference exclusion apparatus with double antennas testing a telecommunication board and its method - Google Patents

Abstract

A simple communication board test apparatus providing an interference cancellation function using two antennas of the present invention includes a first received RF signal incident through a first antenna A1 and a second incident signal through a second antenna A2. RF signal synthesizing means for synthesizing two received RF signals; Down-converting means for converting a radio frequency (RF) signal incident through the first and second antennas (A1, A2) into an intermediate frequency (IF) signal; A / D converting means for converting the analog signal of the intermediate frequency output from the down converting means into a digital signal; Receives the signal output from the A / D converting means and filters the signal to be processed in the baseband and applies a phase change to the second received RF signal incident on the second antenna A2 or the second received RF signal processing means. Baseband processing means for generating a control signal for mode change of the signal; And the second received RF signal processing means for processing the second received RF signal incident on the second antenna A2 according to the control signal of the baseband processing means.

Antenna, Test, Interference, Elimination, Communication

Description

Simplified interference exclusion apparatus with double antennas testing a telecommunication board and its method}             

1 is a configuration example of a simple communication board test apparatus providing an interference cancellation function by employing two antennas according to the present invention;

Figure 2 is an example of setting the distance between the two antennas employed in the simple communication board test apparatus according to the present invention,

3 is a conceptual diagram for explaining a reception signal constellation diagram of a simple communication board test apparatus according to the present invention;

4 and 5 is a conceptual diagram for explaining the change in the signal constellation according to the change in the phase delay value when the simple communication board test apparatus of FIG. 3 operates in the bypass mode;

FIG. 6 is a conceptual diagram illustrating a change in viewing constellation when the simplified communication board test apparatus of FIG. 3 operates in an inverting mode. FIG.

* Explanation of symbols for the main parts of the drawings

110: RF signal synthesizer 120: down converter                 

130: A / D converter 140: baseband processor

150: second receiving RF signal processor

In the present invention, in order to enable experiments in various wireless communication environments (eg, channel conditions, etc.) when field testing a communication board, two antennas are employed to remove the interference from the signal-to-interference ratio. It relates to a simple communication board test apparatus and method for providing.

In general, there is a limit in that it is not desirable to change the directivity or cancel the interference at the RF stage in a wireless receiving system environment employing one antenna.

Therefore, by arranging several antennas uniformly, the power radiated from each antenna causes constructive interference in a specific direction, and offset interference occurs in a different direction, which eventually increases the directivity of the radiation pattern in a desired direction. An array antenna was used to remove the interference.

As a representative example, a smart antenna can be provided. In order to provide such an environment, an RF stage must be composed in parallel in proportion to its performance, and the baseband also has a disadvantage of greatly increasing its complexity.

Of course, the fact that the baseband processor needs to be replaced with a smart antenna does not only present a difficulty in manufacturing a test board, but also in using a smart antenna having a complicated structure as described above in developing a test communication device. It has the disadvantage of being very uneconomical.

In order to solve the above problems, the present invention employs only two antennas to provide an interference cancellation function so that an experiment in various wireless communication environments can be performed on a communication board to be tested. It is an object of the present invention to provide a simple communication board test apparatus and method for greatly changing).

In order to achieve the above object, the present invention provides a simple communication board test apparatus for providing an interference cancellation function by employing two antennas, the first received RF signal and the second received through the first antenna (A1) RF signal synthesizing means for synthesizing a second received RF signal incident through the antenna A2; Down-converting means for converting a radio frequency (RF) signal incident through the first and second antennas (A1, A2) into an intermediate frequency (IF) signal; A / D converting means for converting the analog signal of the intermediate frequency output from the down converting means into a digital signal; Receives the signal output from the A / D converting means and filters the signal to be processed in the baseband and applies a phase change to the second received RF signal incident on the second antenna A2 or the second received RF signal processing means. Baseband processing means for generating a control signal for mode change of the signal; And the second received RF signal processing means for processing the second received RF signal incident on the second antenna A2 according to the control signal of the baseband processing means.

Preferably, the second receiving RF signal processing means bypasses or inverts the second received RF signal incident through the second antenna A2 according to the control signal of the baseband processing means of the present invention. It is characterized by.

In addition, the interference cancellation method for a simple communication board test using two antennas of the present invention, the first received RF signal incident through the first antenna A1 and the second received RF incident through the second antenna A2. Synthesizing the signals; Converting a radio frequency (RF) signal incident through the first and second antennas A1 and A2 into an intermediate frequency (IF) signal; Converting the intermediate frequency analog signal into a digital signal; Generating a control signal to receive the digital signal, to filter the baseband for processing, and to apply a phase change of the second received RF signal incident to the second antenna A2; And bypassing or inverting the second received RF signal incident through the second antenna A2 according to the control signal.

Hereinafter, a simple communication board test apparatus and method for providing an interference cancellation function by employing two antennas will be described in detail with reference to the accompanying drawings.                     

1 is a configuration example of a simple communication board test apparatus providing an interference cancellation function by employing two antennas according to the present invention.

A first RF signal of a radio frequency (RF) incident through the first antenna A1 and a second RF signal of a radio frequency (RF) incident through the second antenna A2 may be RF signal synthesizers. The high frequency signal synthesized by the 110 and output from the RF signal synthesizer 110 is converted into an intermediate frequency (IF) by the down converter 120, and the A / D converter 130 converts the down converter ( The converted intermediate frequency analog signal output from 120 is converted into a digital signal, and the baseband processor 140 can receive the digital signal output from the A / D converter 130 and process it at the baseband. While filtering so as to apply a phase change of the second received RF signal incident on the second antenna A2 or to generate a control signal for mode change of the second received RF signal processing means. In this case, the second received RF signal processor 150 may invert the second received RF signal incident on the second antenna A2 according to the control signal generated by the baseband processor 140, or bypass the bypass signal. You may.

2 is an exemplary view illustrating the distance setting between two antennas employed in the simple communication board test apparatus according to the present invention.

라 할 때, 상기 제1 및 제2 안테나 사이의 거리를

로 위치시키고, 기지국이나 중계국이 안테나 사이의 거리에 비해서 매우 멀기 때문에 들어오는 입사파를 평면파로 가정하며, 이 때 입사각을

라 정하고, 제1 안테나 A1와 제2 안테나 A2에 입사되어 상기 RF 합성기(110)를 통과하는 신호를 계산하면 다음과 같다.The wavelength of the signal incident on the first and second antennas

When the distance between the first and the second antenna

Since the base station or relay station is far from the distance between the antennas, the incoming incident wave is assumed to be a plane wave, and the incident angle

When the signal incident on the first antenna A1 and the second antenna A2 and passed through the RF synthesizer 110 is calculated as follows.

When the first received RF signal incident on the first antenna A1 is y ₀ (t) and the second received RF signal incident on the second antenna A2 is y ₁ (t), the _first received RF signal incident on the second antenna A2 is incident. Since the second received RF signal y ₁ (t) has a phase delay and a time delay than the first received RF signal of the first antenna A1, Equation 1 is obtained.

는 아래 수학식 2의 시간지연

를 수학식3에 대입함으로써 유도된다.Phase delay of equation (1)

Is the time delay of Equation 2 below

Is derived by substituting the equation (3).

Therefore, when the second received RF signal incident on the second antenna A2 is bypassed according to the control signal of the baseband receiver 14, the signal p ^B (outputted at the output terminal of the RF signal synthesizer 110 ( t) and a signal p ^I (outputted from the output terminal of the RF signal synthesizer 110 when the second received RF signal incident on the second antenna A2 is inverted according to the control signal from the baseband receiver 14). t) is the same as Equation 4 and Equation 5, respectively.

는 바이패스의 경우

이 되고, 인버팅의 경우

가 된다.Phase Delay from Equations 4 and 5

Is for bypass

In the case of inverting

Becomes

The operation of the above cases will be described as follows.

First, the case of bypassing will be described. 4 and 5 are conceptual views for explaining the change in the signal constellation according to the change of the phase delay value when the simple communication board test apparatus of FIG. 3 operates in the bypass mode. In this case, the value is set to 0 because it is based on the phase offset of the signal received at the first antenna A1.

가 49^o보다 작거나 -49^o 보다 큰 경우에는 랜덤 가정의 간섭보다 평균수신전력이 상대적으로 크게 되고, 그 이외의 경우에는 랜덤 가정의 간섭보다 평균수신전력이 상대적으로 작게 된다. 여기서, 도 3의 굵은 실선 부분은 신호와 간섭이 다 같이 입사될 수 있는 범위이고, 도 4와 도5의 굵은 실선 부분은 신호가 입사될 수 있는 범위이다. 결국, 평균 수신 전력을 비교하여 볼 때, 도 3에서의 평균전력보다는 도 4에서의 평균전력이 더 높고, 도 5에서의 평균전력이 가장 낮다.Assuming phase of incident signal is random, phase delay

If less than a 49 ^o -49 ^o or greater than has been largely by the average received power of a relatively more random home interference, the control of the average reception power is relatively small than that of the random home interference. Here, the thick solid line part of FIG. 3 is a range in which signal and interference can be incident together, and the thick solid line part of FIGS. 4 and 5 is a range in which a signal can be incident. As a result, when comparing the average received power, the average power in FIG. 4 is higher than the average power in FIG. 3, and the average power in FIG. 5 is the lowest.

However, in the case of FIG. 5, if the second receiving RF signal processor 150 inverts the second received RF signal incident to the second antenna A2 without bypassing, the constellation of the signal as shown in FIG. When calculating the average power in the above manner, it can be seen that the signal-to-interference ratio is improved more than using one antenna. Specifically, according to the formula calculation, the signal-to-interference ratio is improved by 1.9 dB compared to the case of using one antenna.

49

는 고정된 값이 아니며, 통신 보드의 테스트를 위하여 조절 가능한 값이다.Where the presented phase angle

49

Is not a fixed value, but an adjustable value for testing the communication board.

The present invention described above is capable of various substitutions, modifications, and changes without departing from the technical spirit of the present invention for those skilled in the art to which the present invention pertains, and the foregoing embodiments and the accompanying drawings. It is not limited to.

According to the configuration and operation as described above, the present invention has a better signal-to-noise ratio performance than when using one antenna, and the calculation in the baseband or the RF band is simple, thereby eliminating the need for complicated circuits.

In addition, it is possible to test a communication chip or a board by facilitating sufficient field testing even with a simplified test device structure without employing a complicated array antenna, and by easily eliminating interference without significantly changing the baseband processing structure. There is an excellent effect that significantly reduces the time or cost of work.

Claims (7)

delete RF signal synthesizing means for synthesizing a first received RF signal incident through the first antenna A1 and a second received RF signal incident through the second antenna A2; Down-converting means for converting a radio frequency (RF) signal incident through the first and second antennas (A1, A2) into an intermediate frequency (IF) signal; A / D converting means for converting the analog signal of the intermediate frequency output from the down converting means into a digital signal; Receives the signal output from the A / D converting means and filters the signal to be processed in the baseband and applies a phase change to the second received RF signal incident on the second antenna A2 or the second received RF signal processing means. Baseband processing means for generating a control signal for mode change of the signal; And And second receiving RF signal processing means for processing a second received RF signal incident on the second antenna A2 according to the control signal of the baseband processing means. According to a control signal of the baseband processing means, the second receiving RF signal processing means bypasses or inverts the second received RF signal incident through the second antenna A2. A simple communication board test device that provides an interference cancellation function. The method of claim 2, The baseband processing means receives the RF signal incident on the second antenna A2 when the phase delay of the second received RF signal incident through the second antenna A2 is smaller than 49 degrees or larger than −49 degrees. A simple communication board test apparatus for providing an interference canceling function by employing two antennas, characterized by sending a bypass control signal to the second receiving RF signal processing means. The method of claim 2, The baseband processing means, when the phase delay of the second received RF signal incident through the second antenna A2 is greater than 49 degrees or less than -49 degrees, the second reception incident to the second antenna A2 Simple communication board test apparatus for providing an interference cancellation function by employing two antennas, characterized in that for transmitting a control signal for inverting the RF signal to the second receiving RF signal processing means. delete A first step of synthesizing a first received RF signal incident through the first antenna A1 and a second received RF signal incident through the second antenna A2; A second step of converting a radio frequency (RF) signal incident through the first and second antennas A1 and A2 into an intermediate frequency (IF); Converting the intermediate frequency analog signal into a digital signal; The control signal for receiving the digital signal and filtering the baseband for processing and applying a phase change of the second received RF signal incident to the second antenna A2 or for changing the mode of the second receiving RF signal processing means. Generating a fourth step; And A fifth step of bypassing or inverting a second received RF signal incident through the second antenna A2 according to the control signal, The fourth step, Bypassing the second received RF signal incident on the second antenna A2 when the phase delay of the second received RF signal incident through the second antenna A2 is smaller than 49 degrees or larger than −49 degrees. Sixth step of generating a control signal Simple communication board test method providing an interference cancellation function by employing two antennas configured to include. A first step of synthesizing a first received RF signal incident through the first antenna A1 and a second received RF signal incident through the second antenna A2; A second step of converting a radio frequency (RF) signal incident through the first and second antennas A1 and A2 into an intermediate frequency (IF); Converting the intermediate frequency analog signal into a digital signal; The control signal for receiving the digital signal and filtering the baseband for processing and applying a phase change of the second received RF signal incident to the second antenna A2 or for changing the mode of the second receiving RF signal processing means. Generating a fourth step; And A fifth step of bypassing or inverting a second received RF signal incident through the second antenna A2 according to the control signal, The fourth step, Inverting the second received RF signal incident on the second antenna A2 when the phase delay of the second received RF signal incident through the second antenna A2 is greater than 49 degrees or less than −49 degrees. Sixth step of generating a control signal Simple communication board test method providing an interference cancellation function by employing two antennas configured to include.

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