KR20030009841A - Curved line generator of adaptive stc - Google Patents

Abstract

PURPOSE: An adaptive STC curve generator is provided to prevent a trouble of target search operation owing to variation of a clutter according to geographical features by storing various STC curves corresponding to specific geographical features and selecting appropriate curves according to conditions. CONSTITUTION: A sensitivity time control(STC) trigger generator(110) makes an STC trigger code signal comprising an STC trigger signal and a signal based on a distance range of a radar. An operating circuit(130) changes specific bits of the STC trigger code signal according to selection of an operator so as to be suitable to current geographical features. A memory(140) outputs STC curve information stored at a specific address corresponding to the STC trigger code signal. A DAC(150) generates an STC curve using STC curve information from the memory. A voltage control attenuator(160) attenuates the STC curve from the DAC.

Description

Adaptive STC Curve Generator {CURVED LINE GENERATOR OF ADAPTIVE STC}

The present invention relates to a STC (sensitivity time control) curve generator, and more particularly, to store various types of STC curve corresponding to a specific terrain, and according to the situation by the operator appropriately select the STC curve according to the terrain The present invention relates to an adaptive STC curve generator that blocks the detection of a target due to changes in clutter.

In general, the change in the received power according to the distance in the radar is expressed by Equation 1 below.

Since the signal reflected back to the radar by the above equation is inversely proportional to the square of the distance, the sensitive radar cannot receive the signal reflected back from the near fixed target as it is. If a radar is designed to receive a signal reflected from a near fixed target, the cost rises exponentially because parts of the radar's receiving front end must have a very large dynamic range.

Thus, an STC curve generating circuit is used to protect the receiver by attenuating the reflected signal at an appropriately proportional distance range at the receiving front end, and to prevent saturation of myths.

The STC curve generating circuit is a circuit which is installed at the front end of the radar and is used to protect the receiver of the radar and to remove the near clutter from a large signal reflected at a short distance.

Hereinafter, the configuration and operation of a conventional STC curve generating circuit will be described with reference to FIGS. 1 to 3.

1 is a block diagram schematically showing a configuration of a conventional STC curve generating circuit, FIG. 2 is a graph showing an output waveform of each point in FIG. 1, and FIG. 3 is a measured waveform of an STC curve of a conventional STC curve generating circuit. This is a waveform diagram showing.

1 to 3, a trigger signal as shown in a of FIG. 2 is generated from a STC trigger generator 11 programmed in an erasable programmable logic device (EPLD) according to a transmission time point.

The pulse generator 12 receiving this signal generates pulses at predetermined intervals according to values of an internal variable resistor (not shown) and a capacitor (not shown), and outputs a pulse signal as shown in b of FIG. 2. By this pulse signal, the switch (transistor) 13 is switched as shown in FIG. 2C, and the signal output from the switch 13 is set to discharge time of the internal capacitor (not shown) of the RC circuit 14 by the internal variable resistor. (Not shown) is adjusted to generate an STC curve as shown in FIG.

When the STC curve output from the RC circuit 14 is input to the voltage control attenuator 16 by adjusting the level and amplitude as shown in FIG. 2E through the amplification driver 15, the STC curve is finally obtained by the voltage control attenuator 16. Attenuation curves are generated and output to the radar receiver.

However, the STC curve generation circuit 10 is used to generate all the STC curves (solid lines) that can be generated as shown in FIG. 3, but the STC curves satisfying the elimination of normal clutter in the gray portion and the near detection performance are obtained. Couldn't make The test results show that the best STC curve for the terrain above is a dashed line.

In other words, when the amount of attenuation is small in the conventional STC curve generating circuit, the near-field clutter increases, making it difficult to identify the real target on the radar, and when the amount of the attenuation is large, the actual target information may be lost. There is a problem that is difficult to detect the target due to a lot of changes in the clutter according to the change of the terrain.

In addition, a large number of variable resistors are used in the STC curve generation circuit, and the mass resistance is relatively low because each variable resistor must be adjusted during mass production, and there is a problem that the variable resistor cannot be adjusted during the operation of the radar.

Accordingly, an object of the present invention is to solve the above problems, and stores various types of STC curves corresponding to a specific terrain, and according to the situation, the operator selects the STC curves appropriately, thereby changing the clutter according to the terrain. It is to prevent the detection of the target becomes difficult.

In addition, another object of the present invention is to provide a convenience to the operator by selecting and varying the STC curve by digital processing, the mass productivity is relatively high, and the need for in-process adjustment procedures is unnecessary.

1 is a block diagram schematically showing the configuration of a conventional STC curve generation circuit.

2 is a graph showing an output waveform of each point in FIG.

3 is a waveform diagram showing actual waveforms of an STC curve of a conventional STC curve generation circuit.

Figure 4 is a block diagram schematically showing the configuration of the adaptive STC curve generator according to the present invention

5 is a diagram illustrating codes for each STC curve stored in a memory of the adaptive STC curve generator according to the present invention.

6 is a graph showing each STC curve stored in the memory of the adaptive STC curve generator.

7 is a graph showing the STC curve output through the adaptive STC curve generator according to the present invention

<Explanation of symbols for main parts of the drawings>

110: STC trigger generator 120: signal buffer

130: operation circuit 140: memory

150: D / A converter 160: voltage controlled attenuator

Features of the present invention for achieving the above object,

In the receiving front end of the radar,

An STC trigger generator for generating an STC trigger code signal including a STC trigger signal and a signal according to a radar distance range according to a transmission time point according to a system clock;

An operation circuit for changing a specific bit of the STC trigger code signal according to the operator's selection to suit the current terrain;

A memory for outputting STC curve information stored at a specific address corresponding to the STC trigger code signal;

A D / A converter for generating an STC curve using the STC curve information output from the memory;

And a voltage controlled attenuator configured to attenuate and output the STC curve output from the D / A converter.

Here, between the STC trigger generator and the memory,

A signal buffer for amplifying and outputting the STC trigger code signal output from the STC trigger generator by a predetermined level is further provided.

Here also the operation circuit,

It is composed of a plurality of dip switches.

Here again the operation circuit,

A controller that outputs a control signal in response to an operator's input through a radar operator panel,

And an interface for communicating with the memory.

Here again in the memory,

As the radar range is long and short, a plurality of pieces of STC curve information are separated and stored.

Hereinafter, the configuration of the adaptive STC curve generator according to the present invention will be described in detail with reference to FIG.

4 is a block diagram schematically showing the configuration of an adaptive STC curve generator according to the present invention.

Referring to FIG. 4, the adaptive STC curve generator 100 according to the present invention includes an STC trigger generator 110, a signal buffer 120, an operation circuit 130, a memory 140, and a D / A. And a converter 150 and a voltage controlled attenuator 160.

First, the STC trigger generator 110 generates an STC trigger code signal including an STC trigger signal (STC-A0 to STC-A6) and a signal (LONG / SHORT_STC) according to the distance range of the radar in accordance with the transmission time according to the system clock. do. Here, the STC trigger code signal can control the minute change of the time axis by dividing 20usec into 2 ⁷ combination codes. Here, the STC trigger generator 110 is also programmed and formed in an erasable programmable logic device (EPLD).

The signal buffer 120 amplifies and outputs the STC trigger code signal output from the STC trigger generator 110 at a predetermined level.

The operation circuit 130 also changes the upper bits of the STC trigger code signal according to the operator's selection to suit the current terrain. Here, the operation circuit 130 is composed of a plurality of dip switches (not shown) may be selected according to the operator's operation, the controller for outputting a control signal in accordance with the operator's input through the operation panel (not shown) of the radar (Not shown) and an interface for communication (not shown) may be selected according to the operator's charging.

Meanwhile, the memory 140 is input through the signal buffer 120 and outputs STC curve information stored at a specific address corresponding to the STC trigger code signal whose upper bit is changed according to the operator's selection. Here, the memory 140 stores a plurality of STC curve information according to the long and short of the radar range.

In addition, the D / A converter 150 generates an STC curve using the STC curve information output from the memory 140.

The voltage controlled attenuator 160 attenuates and outputs the STC curve output from the D / A converter 150.

Hereinafter, the operation of the adaptive STC curve generator according to the present invention will be described in detail with reference to FIGS. 4 to 7.

5 is a diagram showing codes for each STC curve stored in the memory of the adaptive STC curve generator according to the present invention, Figure 6 is a graph showing each STC curve stored in the memory of the adaptive STC curve generator, Figure 7 is This is a graph showing the STC curve output through the adaptive STC curve generator.

First, the STC trigger generator 110 generates and outputs an STC trigger code signal including a signal based on the STC trigger signal and the radar distance range according to the transmission time point according to the system clock, and then the signal is transmitted through the signal buffer 120. A predetermined level is amplified and input to the memory 140.

At this time, when the operator operates the manipulation circuit 130 to select the STC curve suitable for the surrounding terrain, that is, change the upper bit of the STC trigger code signal, the upper bit of the STC trigger code signal input to the memory 140 is changed.

Then, the memory 140 outputs STC curve information corresponding to the STC trigger code signal to the D / A converter 150 using the STC trigger code signal as address data.

When the input / output converter 150 receives the STC curve information output from the memory 140, that is, the digital data, converts the digital data into an analog signal, that is, the STC curve, generates the STC curve and outputs the STC curve to the voltage control attenuator 160. The voltage control attenuator 160 attenuates the STC curve and outputs the attenuated curve to a receiver (not shown) of the radar.

On the other hand, if it is determined that the operator does not select the correct STC curve, the operator may change the STC curve by manipulating the manipulation circuit 130 again.

In this way, when the operator selects the STC curve according to the surrounding environment, as shown in FIG. 6, the most ideal STC curve is actually generated in FIG. 3. In addition, the operator may select a plurality of STC curves stored in the memory 140 according to the selection. You can select / change specific STC curves among the STC curves.

As described above, according to the adaptive STC curve generator according to the present invention, various types of STC curves corresponding to a specific terrain are stored, and the operator selects the STC curve appropriately according to the situation. The detection of the target can be prevented from becoming difficult.

In addition, it is possible to select and vary the STC curve by digital processing to provide convenience for the operator by having a relatively high productivity and eliminating the need for in-operation adjustment procedures.

Claims (5)

In the receiving front end of the radar, An STC trigger generator for generating an STC trigger code signal including a STC trigger signal and a signal according to a radar distance range according to a transmission time point according to a system clock; An operation circuit for changing a specific bit of the STC trigger code signal according to the operator's selection to suit the current terrain; A memory for outputting STC curve information stored at a specific address corresponding to the STC trigger code signal; A D / A converter for generating an STC curve using the STC curve information output from the memory; And a voltage controlled attenuator for attenuating and outputting the STC curve output from the D / A converter. The method of claim 1, Between the STC trigger generator and the memory, And a signal buffer configured to amplify and output the STC trigger code signal output from the STC trigger generator by a predetermined level. The method of claim 1, The operation circuit, Adaptive STC curve generator, characterized in that composed of a plurality of dip switches. The method of claim 1, The operation circuit, A controller that outputs a control signal in response to an operator's input through a radar operator panel, Adaptive STC curve generator, characterized in that configured as an interface for communicating with the memory. The method of claim 1, In the memory, Adaptive STC curve generator, characterized in that the plurality of STC curve information is stored separately according to the long and short of the radar range.