KR101572538B1 - All directions-oriented radio noise tracking system - Google Patents

Abstract

The present invention relates to an omnidirection-oriented radio noise tracking system and, more specifically, relates to a system which tracks an RF noise that affects communication quality in a radio communication system. The omnidirection-oriented radio noise tracking system of the present invention comprises: an antenna unit (110), arranged with an angle of 360/n, to obtain omnidirection-oriented antenna patterns by consisting of transceiving antennas (110a, 110b...110n); and a frequency conversion combining device (100) which receives each signal from each of the transceiving antennas (110a, 110b...110n) through lines (112, 113) connected to the antenna unit (110), filters the received signal, converts the signal into a frequency band of (n-1) with respect to one frequency after filtering and amplifying the signal, combines the signals into one, and outputs the signal. The omnidirection-oriented radio noise tracking system of the present invention has an effect that is capable of reducing the measuring time by receiving omnidirectional noise at the same time since the multiple antennas (110a,110b...110n) are installed inside cylindrical antenna in different directions.

Description

TECHNICAL FIELD [0001] The present invention relates to an omnidirectional radio noise tracking system,

The present invention relates to an omni-directional wireless noise tracking system, and more particularly to a system for simultaneously tracking RF noise affecting communication quality in a wireless communication system in all directions.

The introduction of RF noise in mobile communication and other wireless communication, which is a core industry in the world, is the most important and direct factor for lowering communication quality and communication quality. Of the total.

On the other hand, the method of tracking actual noise is not improved compared to the initial development of wireless communication.

The current RF noise tracking method is usually operated by connecting a spectrum analyzer to one directional antenna and searching for a direction in which the strongest noise signal flows.

If you use a single input antenna to measure the RF RF noise signal, it will not take a long time to find a strong direction for each measurement point. If the measurement is made with a spectrum analyzer, In case of noise, it takes a long time to find the direction of noise in each point, and it is necessary to turn the antenna several times or dozens of times to find the direction by comparing the output.

Therefore, it is necessary to operate several antennas at the same time in order to find the direction of the incoming signal in real time. However, when the input signals from the various antennas are signals of the same frequency band, An analyzer is needed.

A technique related to such a noise measurement system is disclosed in Korean Patent Registration No. 10-0268678 (Interference Signal Source Measurement Apparatus and Method).

The base station of the cellular system includes a directional antenna for sensing an external signal and a stepping motor for rotating the direction of the antenna by a predetermined angular interval at predetermined intervals, a low noise amplifier for amplifying a signal detected by the antenna, A spectrum analyzer for measuring the level of the signal amplified by the amplifier, and a control processor for controlling the motor and the spectrum analyzer and displaying the level of the measured signal by azimuth angle.

However, due to the characteristics of the RF noise, the above technique often changes the amplitude and frequency at every moment, and it takes a long time to find the direction in which the strongest signal flows.

In addition, since the time required to find the direction is increased each time the moving point is moved, the overall tracking time also takes a long time.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above problems and to provide an omnidirectional antenna including n antennas to reduce noise tracking time by comparing and analyzing all signals input from all directions at the same time.

It is a further object of the present invention to provide an offset adjusting unit for adjusting the phase offset of each antenna signal generated by the characteristic of each antenna line, thereby improving the reception quality of the antenna.

In order to achieve the above object, an omni-directional wireless noise tracking system of the present invention is an omnidirectional wireless noise tracking system comprising n transmission / reception antennas and arranged at an angle of 360 / An antenna unit 110 for acquiring a signal; And receiving signals from n transmit / receive antennas through antenna lines 112 and 113 connected to the antenna unit 110, filtering and amplifying the received signals, converting the signals into n frequency bands, combining the signals into one spectrum, And a conversion coupling device (100).

Here, the n transmit / receive antennas are directional antennas and are planar type array antennas.

The frequency conversion and combination device 100 includes a band pass filter 120 for receiving signals from n transmit and receive antennas and passing a signal of a desired frequency band, An offset adjusting unit 140 for varying and attenuating the respective signal levels amplified and output from the low noise amplifying unit 130, an offset adjusting unit 140 for adjusting the respective signals outputted from the offset adjusting unit 140, (N-1) mixer circuits connected to (n-1) oscillation circuits to generate signals of different frequency bands, and a frequency converter A signal combining unit 170 for collecting and combining signals of frequency bands, and an offset adjusting unit 140 for receiving a command from an external terminal 190 or controlling the offset adjusting unit 140 according to a calibration procedure by a predetermined program And a control unit 140.

The offset adjustment unit 140 may include an attenuator 141 that adjusts the signal level output from the low noise amplification unit 130 to be suitable for transmitting the signal level to the next stage, A switch 142 for switching on / off by an on / off control signal of the operational amplifier 150 to select an antenna for phase offset adjustment, and a switch 142 for connecting the resistor and a plurality of on / off selectable capacitors A phase adjustment circuit 143 that adjusts the phase of the capacitor to match the phase of the output signal of the different antennas so that the capacitor is selected by the on / off control signal of the controller 140, , ≪ / RTI >

The frequency conversion and combination device 100 adjusts the phase offset according to the characteristic difference between the n transmission / reception antennas and the signal input port 101 of the frequency conversion / combination device 100, So that the phases of the respective antenna signals coincide with each other.

The frequency conversion and combination apparatus 100 further includes a spectrum analyzer 180 to measure a combined signal for n antennas output from the signal combining unit 170 as a signal level with respect to frequency.

The omni-directional wireless noise tracking system of the present invention has the effect that the measurement time can be shortened by installing n antennas in different directions inside the cylindrical antenna unit and simultaneously receiving noise in all directions.

Since the omni-directional wireless noise tracking system of the present invention is converted into n frequencies by using a frequency conversion and coupling unit, the frequency spectrum of the omni-directional wireless noise tracking system is combined into one spectrum, Can be compared and analyzed at the same time.

Further, the omnidirectional-oriented wireless noise tracking system of the present invention has another effect that the communication quality and characteristics can be improved by correcting the characteristic change of one or more antenna lines for the aging change with the offset adjusting unit.

1 is a block diagram of an omni-directional wireless noise tracking system according to the present invention;
2 is a configuration diagram of an offset compensation unit according to FIG. 1;
3 is a plan view of the antenna unit according to FIG. 1;
4 is a conceptual layout view of an antenna line according to Fig. 1;

Hereinafter, the present invention will be described in detail with reference to the drawings.

1 is a configuration diagram of an omni-directional wireless noise tracking system according to the present invention, Fig. 2 is a configuration diagram of an offset compensator according to Fig. 1, Fig. 3 is a plan view of an antenna unit according to Fig. Fig. 2 is a conceptual layout diagram of an antenna line according to the first embodiment.

1 to 4, an omni-directional wireless noise tracking system according to the present invention includes an antenna unit 110, a frequency conversion and combination apparatus 100, a spectrum analyzer 180, and a terminal 190 .

The present invention receives and amplifies an RF signal through n antennas 110a, 110b,... 110n, converts each signal into n different frequencies f0, f1, ..., 180), it is possible to find the strongest noise signal and direction of inflow from all directions even with a single measurement (where n = 2, 3, 4, ...., n)

The cylindrical antenna 114 is provided with n antennas 110a, 110b,... 110n arranged in different directions in an equi-angular direction and receives noise in all directions at the same time. It can be installed in the inside, or it can be used for portable use in small size.

The frequency conversion and combination device 100 converts various signals of the same frequency band into different frequency bands, and outputs the same frequency band to the frequency conversion / combination device 100, And then input to a spectrum analyzer 180 that combines and outputs the signals in a single spectrum through the frequency conversion / combination device 100.

Since the frequency converting and combining apparatus converts the signals into different frequencies (f0, f1, ..., fn) and combines them, the spectrum analyzer 180 generates a spectrum in which the frequency bands are different from each other. At the same time, comparison analysis is possible at the same time, so that the direction of the strongest signal flowing in real time can be found.

In addition, as a further function, a band-pass filter 120a is provided to receive only a noise of a desired band in the frequency conversion / combination device 100, and includes a low noise amplifier 130a for amplifying an input noise signal, The offset adjustment unit 140 is provided for correcting the output of each of the noise signals received by the antennas 110a, 110b, ..., 110n.

In other words, in order to compare and analyze the output with one spectrum analyzer while operating several antennas at the same time, all of the signals coming from each antenna are converted into different frequency bands, and when the spectrum is measured by combining them, The spectrum analyzer can measure the level difference of the incoming signals in each direction in real time.

In the present invention, a large multidirectional antenna having multiple antennas oriented in different directions receives multiple inputs of the same frequency band, band-pass filters, amplifies, and phase-adjusts them, and converts them into different frequency bands, And outputs the frequency-converted signal.

The multidirectional antenna and the frequency conversion and coupling device are portable and can be installed in a vehicle and used for RF noise tracking to maximize communication quality through rapid RF noise tracking and minimize damage to subscribers or users .

The system of the present invention is a wireless noise tracking system having an omnidirectional offset adjustment function, wherein the antenna unit 110 is composed of n transmitting / receiving antennas 110a, 110b ... 110n, and 360 / n So as to obtain an omni-directional antenna pattern.

The frequency conversion and combination apparatus 100 receives the signals from the respective transmit / receive antennas 110a, 110b, ..., 110n through the internal antenna line 112 and the external antenna line 113 connected to the antenna unit 110, Filters and amplifies the signals, converts them into n different frequency bands, combines them into one spectrum, and outputs them.

The transmit / receive antennas 110a, 110b,... 110n may be planar array antennas as directional antennas.

Each of the antennas 110a, 110b ... 110n is connected to the antenna port 111 through the internal antenna line 112 and each of the antennas 110a, 110b ... 110n has a beam width of 360 / n .

Each antenna 110a, 110b ... 110n of the antenna unit 110 should be driven by the same amplitude and frequency to obtain a desirable omni-directional (omni-directional) antenna pattern.

The antenna unit 110 is fixed inside the antenna case 114 and is connected to the signal input port 101 of the frequency conversion and coupling unit 100 by the antenna lines 112 and 113 and the frequency conversion and coupling unit 100 is moved It can be attached to the outside of the vehicle to easily receive radio waves by using a vehicle fixing member 115 made of a magnet or the like at the lower end of the antenna case 114 so as to be installed inside the vehicle.

The frequency conversion and combination device 100 includes a band pass filter 120 for receiving a signal from each of the transmit / receive antennas 110a, 110b,... 110n and passing a signal of a desired frequency band, A low noise amplifier 130 for amplifying each signal output from the low pass filter 120, an offset adjuster 140 for adjusting and attenuating the signal levels amplified and output from the low noise amplifier 130, A frequency converter 160 for combining the signals output from the frequency divider 140 with the mixer circuits 160a, 160b and 160c connected to the oscillation circuits B, C and D to generate signals of different frequency bands, A signal combining unit 170 for collecting and combining signals of different frequency bands output from the frequency converting unit 160 and an offset adjusting unit 170 for receiving an instruction from an external terminal 190 or performing an offset adjusting procedure by a predetermined program, It is configured to include a control unit 140 for controlling the unit 140.

The offset adjustment unit 140 includes an attenuator 141 that adjusts each signal level output from the low noise amplifying unit 130 so as to be adapted to transmit the signal level to the next stage, a control unit 150 that adjusts the signal output from the attenuator, A switch 142 for on / off switching on / off by the on / off control signal of the switch 142 to select an antenna for phase offset adjustment, And a phase adjustment circuit 143 for adjusting the phase of the signal to coincide with the phase of the signal.

The attenuator 141 can attenuate the input signal using a switch so that it is suitable for input to the next stage from the maximum range that is transmitted without being attenuated.

Here, the control unit 140 turns on / off one or more switches S142 according to a control command received from an external terminal 190 via a GPIB or the like.

The switch S142 is always turned on when the power is turned on by the calibration switch and on / off controlled by the control signal of the control unit 140 at the time of calibration (phase offset adjustment).

The terminal 190 can measure an input signal and an output signal with a portable PC or the like in cooperation with the spectrum analyzer 180. The terminal 190 analyzes a measured signal and adjusts the offset according to the measured signal. And outputs a control command to the control unit 150. [

Also, the terminal 190 has a frequency adjustable oscillator (not shown) and can apply an oscillation frequency output from the oscillator (not shown) to the transmit / receive antennas 110a, 110b, ..., have.

The frequency conversion and combination device 100 is configured to have a characteristic difference between the respective transmission lines 112 and 113 between the transmission / reception antennas 110a, 110b, ..., 110n and the signal input port 101 of the frequency conversion / So that the phases of the respective antenna signals can be adjusted to coincide with each other.

The frequency conversion and combination device 100 further includes a spectrum analyzer 180 connected to the signal output port 102 so that each of the antennas 110a, 110b ... 110n output from the signal combining unit 170, (Signals in four different frequency bands) to the frequency can be measured at the signal level with respect to frequency.

100: Frequency conversion / combination device 110:
120: bandpass filter unit 130: low noise amplifier
140: offset adjustment unit 150:
160: Frequency converter 170: Signal combiner
180: spectrum analyzer 190: terminal

Claims (6)

In an omni-directional wireless noise tracking system,
an antenna unit 110 composed of n transmitting / receiving antennas 110a, 110b, ..., 110n and arranged at an angle of 360 / n degrees to obtain an omni-directional antenna pattern; And
Receiving signals from the n transmitting / receiving antennas 110a, 110b, ..., 110n through the lines 112 and 113 connected to the antenna unit 110, filtering and amplifying the signals, converting the signals into n frequency bands, And a frequency conversion / combination device (100)
The frequency conversion and combination device 100 includes a band pass filter 120 for receiving a signal from each of the transmit / receive antennas 110a, 110b ... 110n and passing a signal of a desired frequency band, An offset adjusting unit 140 for varying and attenuating the respective signal levels amplified and output from the low noise amplifying unit 130, an offset adjusting unit 130 for adjusting the output level of the low noise amplifying unit 130, (N-1) mixer circuits connected to (n-1) oscillation circuits to generate signals of different frequency bands, a frequency converter A signal combiner 170 for collecting and combining signals of different frequency bands output from the receiver 160 and an external terminal 190 or receiving a command from the external terminal 190 or performing a calibration procedure by a predetermined program, And a control unit (150) for controlling the radio frequency noise.
The method according to claim 1,
Wherein the n transmit / receive antennas (110a, 110b ... 110n) are directional antennas and are planar type array antennas.
delete The method according to claim 1,
The offset adjustment unit 140
An attenuator 141 for variably adjusting each signal level output from the low noise amplifying unit 130 so as to be adapted to transmit the signal level to the next stage, an on / off control signal generator 140 for adjusting a signal output from the attenuator, And a switch 142 for adjusting the phase of the output signal of the different antenna to match the phase of the output signal of the other antenna so as to make the phase of the signal output from the switch 142 faster or slower And a phase adjustment circuit (143) for adjusting the phase of the radio signal.
The method according to claim 1,
The frequency conversion and combination device 100 has characteristics of the respective antenna lines 112 and 113 between the respective transmit / receive antennas 110a to 110n and the signal input port 101 of the frequency conversion / And adjusts the phase offset according to the difference to adjust the phases of the respective antenna signals to coincide with each other.
The method according to claim 1,
The frequency conversion and combination device 100 further includes a spectrum analyzer 180 and outputs a combined signal for each of the antennas 110a, 110b ... 110n output from the signal combining unit 170, Level wireless noise tracking system.

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