KR950000337B1 - Radar receiver system with test function - Google Patents

Abstract

The system for testing the function of the part for receiving and processing the radar signal includes a wave guide/converter guiding the radar signal received from the antenna and converting the signal to an appropriate form to transmit through the coaxial line, a noise generator generating the regular noise to measure the characteristic of the receiving system, a processor processing the received radar signal, and a switch connecting the processor to the noise generator when testing but otherwise to the wave guide/converter.

Description

Radar Receiving System with Test Function

1 is a block diagram of a radar receiving system having a conventional test function.

2 is a block diagram of noise generating means.

3 is a block diagram of a radar receiving system having a test function according to the present invention.

4 is a diagram for explaining a noise figure in the radar receiving signal processor.

* Explanation of symbols for main parts of the drawings

102: radar receiver 103: radar receiving signal processing unit

301: switching means

The present invention relates to a radar system, and more particularly, to a radar system capable of testing the function of the part receiving and processing the radar signal.

Most of the radar systems that perform high performance are configured to include test equipment inside the receiver. Such test equipment is commonly called a built-in test equipment (BITE), and a noise index (NF) of the radar receiving signal processor is included. This function measures the noise figure or sensitivity.

The built-in test equipment (BITE) of the conventional radar system is composed of a noise generating means, a directional coupler, a measuring means, etc., and the transient noise output from the noise generating means is the directional coupler ( After the directional coupler is applied to the radar receiving signal processor, a test function is performed by examining how the transient noise appears in a predetermined portion of the radar receiving signal processor. However, the directional coupler has a very large power loss due to its coupling characteristic, so that it is not easy to observe the effect of excessive noise output from the noise generating means on the radar receiving signal processor. In other words, the noise generating means must generate a signal having a very high power level in order to take the power loss caused by the directional coupler and cause the influence to be sufficient to observe the radar receiving signal processor. There is a problem.

Accordingly, an object of the present invention is to provide a radar receiving system having a test function capable of performing a test function of the radar receiving signal processor by reducing the power loss of the transient noise output from the noise generating means.

In order to achieve the above object, a radar receiving system having a test function according to the present invention is a radar system, in which a waveguide / coaxial converting means for converting a radar signal received from an antenna through a waveguide or the like into a form suitable for transmitting to a coaxial transmission path. And; Noise generating means for generating a regular signal of a predetermined voltage to measure characteristics of a receiver portion for receiving and processing a radar signal of the radar system; A radar reception signal processor for performing amplification, frequency conversion, analog digital conversion, and digital data analysis on the received signal; And switching means for connecting the noise generating means to the radar receiving signal processing unit for measuring the characteristics of the radar receiving signal processing unit and otherwise connecting the waveguide / coaxial conversion unit to the radar receiving signal processing unit. The radar reception signal processor may be configured to test the function of the radar reception signal processor by extracting and inspecting a signal output from a predetermined portion of the radar reception signal processor.

Next, the present invention will be described in more detail with reference to the accompanying drawings.

1 is a block diagram of a radar receiving system having a conventional test function, which includes a waveguide / coaxial conversion unit 101, a noise generating unit 104, a directional coupler 105, a radar receiving signal processing unit 103, It comprises a measuring means 106. The radar reception signal processor 103 analyzes a low noise amplifier (LNA) 107, a frequency converter 108, and an analog digital converter and a digital signal for converting an analog signal into a digital signal although not shown in the drawing. And digital signal processing means for extracting the information contained therein.

In Fig. 1, the received signal from the antenna is usually transmitted through the waveguide because the receiving path uses the same line as the transmission signal, which mostly uses high power. The signal transmitted through the waveguide is applied to the waveguide / coaxial conversion means 101 via a circulator. The waveguide / coaxial conversion means 101 performs a function of converting a high power signal transmitted through a waveguide, a circulator, or the like into a signal having a low power so as to be suitable for a coaxial transmission path. The noise generating unit 104 performs a function of generating a transient noise having a predetermined output level in order to test the function of the radar reception signal processing unit 103. Transient noise should be higher than the noise normally seen in the radar reception signal processor 103 so that its effect can be easily observed. Here, the ratio of the power of the transient noise output by the noise generating means 104 to the power of the signal applied to the radar receiving signal processor in decibels is referred to as an Excessive Noise Ratio (ENR).

Directional coupler (105) is a kind of three-dimensional circuit element to properly separate two waveguides by combining two waveguides according to the direction, and after connecting the waveguide / coaxial conversion means 10 at a certain distance, The noise generating means 104 is connected to an ohmic termination having a predetermined resistance value (about 50?).

The low noise amplifier 107 of the radar reception signal processing unit 103 performs a function of amplifying a signal output to the directional coupler 105 and is configured to have a low noise. The frequency converting means 108 performs a function of converting a high frequency signal output from the low noise amplifier 107 into an intermediate frequency (IF) signal. That is, the frequency converting means 108 performs a function of transitioning the high frequency signal to an intermediate frequency signal by performing a low pass filtering after mixing a high frequency signal output from the low noise amplifier 107 and a predetermined signal having a low frequency. do.

The measuring means 106 tests the function by measuring the characteristics of the transient noise signal appearing in a predetermined portion of the portion constituting the radar reception signal processor 103, and measures the noise index (NF) or the sensitivity ( In the case of testing the sensitivity, a signal appearing at the output terminal of the frequency converting means 108 is measured as shown in the drawing. Here, the signal flow in the case of measuring the noise figure is as follows.

First, transient noise having a transient noise ratio of about 15 dB to 28 dB is generated from the noise generating means 104. The generated transient noise signal is coupled through the directional coupler 105 and applied to the radar receiving signal processor 103. The signal applied to the radar reception signal processor 103 is amplified by the low noise amplifier 107 and frequency shifted to the intermediate frequency band through the frequency conversion means 108. The signal converted into the intermediate frequency band is measured by measuring means such as an oscilloscope or a spectrum analyzer.

However, in the case of measuring the noise figure by the above process, the power of the transient noise is absolutely reduced by the directional coupler 105, so that the measuring means such as an oscilloscope or spectrum analyzer are used. In observing, the power of the transient noise signal flowing into the measuring means becomes less than the noise floor and the sensitivity in the measuring vehicle body, so that it is practically impossible to observe the transient noise signal.

Therefore, in this case, as described above, the ratio of the transient noise output from the noise generating means 104 should be very large, and the coupling factor of the directional coupler 105 should be relatively low.

2 is a block diagram according to an embodiment of the noise generating means, which includes a noise source 201 and a power supply control circuit 202. As shown in FIG. The noise source 201 is a circuit for outputting a transient noise signal, which normally encloses gas in a tube and applies a constant power to generate noise, or applies a breakdown voltage to a zener diode to generate noise. There is this. Such a noise source generates a transient noise signal by supplying power from a power source.

The power supply control circuit 202 performs a function of controlling the supply of power required for the operation of the noise source 201. That is, the power control circuit 202 performs a function of supplying power to the noise source 201 when a function of the laser reception signal processing unit 103 is to be tested, and performs a switching operation. The external control circuit of FIG. 2 is a signal indicating whether or not the test function is performed.

3 is a block diagram of a radar receiving system having a test function according to the present invention, in which the waveguide / coaxial conversion means 101 includes a noise generating means 104, a switching means 301, a measuring means 106 and a laser reception signal. It is comprised including the processing part 103. That is, among the conventional components, the directional coupler 105 is replaced by the switching means 301, and the external control signal applied to the noise generating means 104 is simultaneously applied to the switching means 301. It is becoming.

The switching unit 301 connects the noise generating unit 104 to the radar receiving signal processing unit 103 in order to measure the characteristics of the radar receiving signal processing unit 103, and otherwise, the waveguide / coaxial conversion unit ( 101 is connected to the radar receiving signal processor 103. In particular, the switching means used in radar systems, etc., is suitable for high frequency signals such as a single path single in- put switch (SPDT) composed of pin diodes and the like. The switching means 301 has a very low power loss (about 2 dB or less) compared to the conventional directional coupler 105, so that the user can calculate the noise figure of the radar reception signal processor 103. A transient noise signal with a power level sufficient for s appears at the output of the frequency converting means 108.

Next, the noise figure will be described.

The noise figure of a circuit expresses the ratio of the signal-to-noise ratio (SN ratio) of the output side to the signal-to-noise ratio (SN ratio) of the input side of a circuit in decibels, and represents the degree of the noise which generate | occur | produces in a circuit. If the magnitudes of the signal and noise at the input and output sides are S _i , S _o and N _o , respectively, the noise figure NF is

It is represented by If the circuit is ideal and no noise is added at all, Equation (1) has a value of "0".

Measuring the noise index and sensitivity of the circuit using the noise generating means 104 will be described with reference to FIG.

In FIG. 4, N1 denotes a signal power appearing at the output terminal of the frequency converting means 108 when there is no output from the noise generating means 104, and N2 denotes a predetermined power of the noise generating means 104. When outputting a transient noise signal having a transient noise ratio refers to the signal power appearing at the output terminal of the frequency conversion means (108).

Various noise signals may be applied to the radar reception signal processor 103 in addition to the transient noise signal generated and applied by the noise generating means 104. For example, the input termination noise generated at the interconnection point of the circuit elements and the noise signal flowing into the radar reception signal processing unit from the outside are mentioned. Here, another equation representing the noise figure is shown below.

Where NF = noise index

N = noise power measured by the measuring means

k = Boltzmann constant (1.374 × 10 ^-23 joule / K °)

T _o = Absolute temperature (290 ° K)

B = bandwidth of the radar receiving signal processor

G = gain of the radar receive signal processor

That is, Equation (2) shows the noise figure in terms of temperature and frequency band.

In addition, the transient noise ratio (ENR)

T ₁ denotes thermal noise caused by temperature when the noise generating means 104 is in a “COLD” state, that is, when the transient noise signal is not output, and T ₂ denotes the noise generating means. When the 104 is in the "HOT" state, i.e. when outputting a transient noise signal, it indicates thermal noise due to temperature.

Therefore, the radar reception when the noise power measured from the output terminal of the frequency conversion means 108 is N ₂ and N ₁ , respectively, when the noise generating means 104 is in the "hot" state and in the "cold" state, respectively. The noise index (NF) of the signal processing unit is obtained by the following equation (4).

As described above, the present invention has the advantage that the signal attenuation of the transient noise signal is reduced by making the built-in test function in the radar system easier to observe in the measuring means, and the switching means is controlled externally. Since the switching operation is performed directly according to the signal, the radar reception signal processor of the radar system can be easily tested.

Claims (3)

A radar system comprising: waveguide / coaxial conversion means for converting a radar signal received from an antenna through a waveguide or the like into a form suitable for transmission to a coaxial transmission path; Noise generating means for generating a regular signal of a predetermined voltage to measure characteristics of a receiver portion for receiving and processing a radar signal of the radar system; A radar reception signal processor for performing amplification, frequency conversion, analog digital conversion, and digital data analysis on the received signal; And switching means for connecting the noise generating means to the radar receiving signal processing unit for measuring the characteristics of the radar receiving signal processing unit and otherwise connecting the waveguide / coaxial conversion unit to the radar receiving signal processing unit. And testing the function of the radar reception signal processing unit by extracting and inspecting a signal output from a predetermined portion of the radar reception signal processing unit and a signal output from the noise generating means. The apparatus of claim 1, wherein the radar receiving signal processor comprises: a low noise amplifier for low noise amplifying a received signal; And a frequency converting means for converting the frequency band by mixing the output signal of the low noise amplifier with a predetermined signal having a low frequency and measuring the noise figure by checking the ratio of the output of the frequency converting means and the output of the noise generating means. Radar receiving system having a test function, characterized in that. 2. The radar receiving system according to claim 1, wherein the fraud switching means is composed of a pin diode and is composed of a single path single input switch (SPDT) which reduces a high frequency signal attenuation.