KR20030026122A - Radar detector using saturation drive amplifier - Google Patents

Abstract

PURPOSE: A broadband radar detector by employing a saturated regional operation amplifier is provided to drastically improve the broadband receiving performance of the radar detector by designing the radar detector circuit in accordance with the present invention employing the amplifier to operate the local oscillation frequency to the saturated region. CONSTITUTION: A broadband radar detector by employing a saturated regional operation amplifier includes an antenna(10) for receiving a frequency, a first local oscillator(20) for generating a frequency variable signal, a first amplifying block(200) for amplifying the signal outputted from the first local oscillator(20), a first filter block(30) for removing a noise signal generated from the first local oscillator(20), a second amplifying block(300) for amplifying the signal noise filtered through the first filter block(30) a first mixing block(40) for mixing the signal transmitted through the first amplifying block(200) and the frequency variable signal generated at the first local oscillator(20), an amplifying block(50) for amplifying the frequency signal mixed by the first mixing block(40), a second local oscillator(60) for generating a frequency to modulate the frequency signal passed through the amplifying block(50), a second mixing block(70) for mixing the frequency generated at the second local oscillator(60) and the frequency signal passing through the amplifying block(50), a second filter block(80) for obtaining only a signal having a specific band width passing through the second mixing block(70), a demodulator(90) for analog to digital converting the frequency signal filtered with a specific frequency through the filter block, a main control block(100) for implementing an appropriate control of the elements, a function operational block(110) for implementing a function operation of the radar detector and a display panel(120) for recognizing to a user during the detection of the specific signal.

Description

Radar detector using saturation domain amplifier

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radar detector, and more particularly, to a radar detector that provides improved performance by presenting a circuit having a stable oscillator output.

Radar detector is a system that detects a laser or ultra-high frequency shot from a speed gun to measure the speed and informs the driver by voice, text, and beeping.In some developed countries, a microwave or laser (Raser detector) Various radar detectors have been developed and used for safe driving of vehicles.

Conventionally, there are three methods for detecting a radar for speed measurement using a radar detector. First, there is a gun diode method using gun diode as a frequency generator and mixer. Second, there is a voltage controlled oscillator method using voltage controlled oscillator as a frequency generator. Third, dielectric oscillator. There is a dielectric oscillator method using (Dielectric Resonate Oscillator) as a frequency generator.

However, most of the speed measuring radar detectors currently in use are a gun diode method and a voltage controlled oscillator method. The first method, the gun diode method, consumes a lot of current in the operation of the gun diode. Sensitivity is inferior in detecting speed radar.

In the case of using the voltage controlled oscillation method, which is the second method, it is difficult to manufacture, but it is characterized by less current consumption and better sensitivity than the dry diode method.

Lastly, when the third method, the dielectric oscillator, is the best method among the three methods, the efficiency of the work is inferior, and the current technology does not receive a good response in the market due to the increase in the selling price of the product. have.

Hereinafter, the configuration and operation of a general radar detector will be described with reference to the accompanying drawings.

1 is an explanatory diagram for explaining the use principle of the radar detector, a device for detecting a variety of ultra-high frequency emitted from the speed gun, X-band frequency (10.525 GHz), K-band frequency (24.150 GHz), It responds to frequencies in certain bands, such as the Ka-band frequency (34.7 GHz ± 1.3 GHz), infrared rays, and the VG-2 to detect radar detectors, informing the driver of the presence of a speed gun.

The radar detector as described above has recently informed the driver of various driving information in advance by encoding various information signals such as railroad crossings, fog areas, and speed reduction as well as the presence or absence of a speed gun.

As described above, the radar detector for alerting the driver in response to various frequencies includes an antenna 10 for receiving ultra-high frequency, as shown in the circuit block diagram of FIG. 2A; A first local oscillator 20 for generating a frequency; A first filter part (30) for removing noise of the signal from the first local oscillator; A first mixing part (40) for mixing with the frequency generated in said first local oscillating part for frequency converting the ultra-high frequency received from said antenna; An amplifying unit (50) for amplifying the frequencies mixed by the first mixing unit; A second local oscillator (60) for generating a frequency to be mixed with the frequency signal passed through the amplifier; A second mixing unit 70 for mixing the frequency generated by the second local oscillating unit and the frequency signal passing through the amplifying unit; A second filter unit (80) for obtaining only a specific band signal of the frequency signal passing through the second mixing unit; A demodulator (90) for A / D converting a frequency signal filtered to a specific band through the second filter unit; A main control unit (100) for receiving and processing the demodulated signal and for performing appropriate control of each component; A function manipulation unit 110 for a function manipulation of the radar detector; It is basically composed of a display unit 120 for recognizing a user when detecting a specific signal.

In addition, a laser detecting means for detecting a laser may be further added to the above configuration.

The antenna 10 is a horn antenna X-band frequency (10.525 GHz), K-band frequency (24.150 GHz), Ka-band frequency (34.7 GHz ± 1.3 GHz), infrared radiation emitted from the speed gun The VG-2 may receive a specific signal such as a VG-2 for detecting a radar detector.

The frequency signal received by the antenna 10 is input to the first mixer 40, and the first mixer 40 is mixed with the frequency variable signal generated by the first local oscillator 20. .

The signal mixed in the first mixing unit 40 is amplified through the amplifier 50 and input to the second mixing unit 70.

The second mixing unit 70 modulates the frequency of various bands generated by the second local oscillator 60 and removes noise components through the second filter unit 80.

The signal from which the noise component is removed through the second filter unit 80 is transmitted to the demodulator 90, and the demodulator 90 performs A / D conversion for signal input to the main controller 100. .

The main control unit 100 enables the function switching and operation by the function control unit 110, and performs a user notification function through the sound / lamp of the display unit 120, and also the first, second local oscillation unit ( 20) and 60 are included.

However, the conventional radar detector having the basic configuration as described above should combine the signal received from the first mixing unit 40 and the signal received through the antenna 10, wherein the first local oscillator 20 There is a disadvantage that the general characteristics of the output signal are not good.

That is, as shown in the simulation program output value diagram of ADS (Advanced Design System) of HP (Hewlett Packard) of FIG. Because it does not show, it is the cause of performance degradation in implementing the broadband in the operation of the radar detector.

The present invention, in order to solve the above problems, by adjusting the signal output from the first local oscillator 20 for the signal input to the first mixing unit 40 to maintain a stable and uniform have.

In addition, the purpose is to improve the performance of the radar detector through the stabilization of the signal output from the first local oscillator to the first mixing unit 40.

In addition, the present invention proposes a method of achieving the same or improved performance by using a general-purpose, low-cost part rather than an expensive part.

1 is an exemplary view for explaining the use of the radar detector

2A and 2B are block diagrams illustrating the configuration of a conventional radar detector, respectively.

3 is a test result diagram showing first local oscillation signal characteristics input to a first mixing unit in a radar detector without a conventional saturation amplifier stage;

4 is a diagram illustrating a radar detector circuit using a saturation region operational amplifier according to the present invention.

5 is a block diagram showing a radar detector circuit using a saturation region operational amplifier according to the present invention.

<Description of the symbols for the main parts of the drawings>

10 antenna 20 first local oscillator

30: first filter unit 40: first mixing unit

50: amplification unit 60: second local oscillation unit

70: second mixing unit 80: second filter unit

90: demodulation unit 100: main fisherman

110: function control unit 120: display unit

200: first amplifier 300: second amplifier

In order to achieve the above object, the present invention saturates the signal oscillated from the first local oscillator and introduced into the first mixer to maintain a constant input level by improving the imbalance of the oscillation signal flowing into the first mixer. It is characterized by the additional use of an amplifier operating in the domain.

Hereinafter, a preferred embodiment of the radar detector according to the present invention will be described with reference to the accompanying drawings.

4 is a block diagram showing the configuration of a radar detector according to the present invention;

An antenna 10 for receiving ultra-high frequency; A first local oscillator 20 for generating a frequency; A first amplifier (200) for amplifying the signal output from the first local oscillator; and a first filter (30) for removing noise from the signal amplified by the first amplifier; A second amplifier (300) for amplifying the noise filtered signal by the first filter unit again; A first mixing part (40) for mixing with the frequency oscillated by the first local oscillating part (20) for frequency converting the ultra-high frequency received from the antenna; An amplifying unit (50) for amplifying the frequencies mixed by the first mixing unit; A second local oscillator (60) for generating a frequency to be mixed with the frequency signal passed through the amplifier; A second mixing unit 70 for mixing the frequency generated by the second local oscillating unit and the frequency signal passing through the amplifying unit; A second filter unit (80) for obtaining only a specific band signal of the frequency signal passing through the second mixing unit; A demodulator (90) for A / D converting a frequency signal filtered to a specific band through the second filter unit; A main control unit (100) for receiving and processing the demodulated signal and for performing appropriate control of each component; A function manipulation unit 110 for a function manipulation of the radar detector; A radar detector including a display unit 120 for recognizing a user when a specific signal is detected is presented.

The present invention further comprises a first amplifier 200 and a second amplifier 300 operating in a saturation region between the first mixing unit 40 and the first local oscillating unit 20.

The antenna 10 is a horn antenna, which is an X-band frequency (10.525 GHz), a K-band frequency (24.150 GHz), a Ka-band frequency (34.7 GHz ± 1.3 GHz), and an infrared ray emitted from a speed gun. The VG-2 may receive a specific signal such as a VG-2 for detecting a radar detector.

The frequency signal received by the antenna 10 is input to the first mixer 40, and the first mixer 40 is mixed with the frequency variable signal generated by the first local oscillator 20. .

The signal mixed in the first mixing unit 40 is amplified through the amplifier 50 and input to the second mixing unit 70.

The second mixing unit 70 modulates the frequency of various bands generated by the second local oscillator 60 and removes noise components through the second filter unit 80.

The signal from which the noise component is removed through the second filter unit 80 is transmitted to the demodulator 90, and the demodulator 90 performs A / D conversion for signal input to the main controller 100. .

The main control unit 100 enables the function switching and operation by the function control unit 110, and performs a user notification function through the sound / lamp of the display unit 120, and also the first, second local oscillation unit ( 20) and 60 are included.

In addition, although the laser detecting means for detecting the laser may be further added to the above configuration, the configuration and description thereof will be omitted.

The first amplifier 200 and the second amplifier 300 is preferably a device having an amplified gain output of at least 15dBm or more with respect to the input signal level.

The gain is typically calculated as dB = 10log (output / input). For example, an amplifier with an input of 1W and an output of 100W is 100 times the amplifier. Expressed in dB, this would be 10log 100/1 = 20dB (log100 = log102 is 2). This time, if there is an attenuator that inputs 100W and outputs 15W, log15 / 100 = -8.2dB (log0.15 = -0.823). When amplified, it becomes + dB, and when attenuated, it becomes -dB.

First, the first amplifier 200 amplifies and outputs a frequency of about 10.963 GHz to 11.863 GHz band, which is output twice the frequency of 5.8 GHz from the first local oscillator 20 by a gain ratio of about 15 dBm or more. After that, the 5.8 GHz band, which is an unnecessary frequency band, is removed by the first filter unit 30.

The noise filtered signal by the first filter unit 30 is input to the second amplifier 300.

The signal input to the second amplifier 300 is amplified again to the saturation region, and preferably saturated with an amplification gain output of 18 dBm or more so that the signal amplified by the first amplifier 200 can be more stably operated. Amplify the oscillation signal to the region.

FIG. 5 is a diagram illustrating a simulation test output result amplified to the saturation region by the first amplifier 200 and the second amplifier 300 to prove the reliability of the present invention, in the frequency range of 10.825 GHz band. Shows stable output of.

The first local oscillator 20 amplifies the frequency of about 10.963 GHz to 11.83 GHz output at twice the frequency of 5.8 GHz by about 15 dB or more gain ratio, which is then unnecessary by the first filter unit 30. After removing the 5.8 GHz band, which is a frequency band, the second amplifier 300 saturates amplification to have a uniform gain characteristic of about 18 dB, and then, between the first mixing section 40 and the amplifying section 50, The output waveform of the first local oscillator 20 measured by a spectrum analyzer (8593E).

As a result of the output measurement, the oscillation frequency output from the first local oscillator 20 by the first amplifier 200 and the second amplifier 300 according to the present invention is input to the first mixing unit 40. It can be seen that the stable broadband oscillation characteristic effect can be obtained.

By designing the radar detector circuit according to the present invention using an amplifier that operates to amplify the local oscillation frequency to the saturation region as described above, the frequency signal output from the first local oscillator 20 is directly connected to the reception performance of the radar detector A stable oscillation signal can be input to the first mixing unit 40 in a wideband frequency band, thereby greatly improving the wideband reception performance of the radar detector.

Claims (3)

Radar detector for detecting a specific signal, An antenna for receiving ultra-high frequency; A first local oscillator for generating a frequency; A first amplifier for amplifying the signal output from the first local oscillator; A first filter unit for removing noise from the signal amplified by the first amplifier; A second amplifier for amplifying the noise filtered signal by the first filter unit again; A first mixing unit for mixing with the frequency oscillated by the first local oscillator to frequency convert the ultra-high frequency received from the antenna; An amplifier for amplifying the frequencies mixed by the first mixing unit; A second local oscillator for generating a frequency to be mixed with the frequency signal passed through the amplifier; A second mixing unit for mixing the frequency generated by the second local oscillating unit and the frequency signal passing through the amplifying unit; A second filter unit for obtaining only a specific band signal of the frequency signal passing through the second mixing unit; A demodulator for A / D converting a frequency signal filtered to a specific band through the second filter; A main controller for receiving and processing the demodulated signal and for performing appropriate control of each component; A function control unit for functioning the radar detector; Display unit for recognizing a user when detecting a specific signal Radar detector including The method according to claim 1, The first amplifier has a radar detector, characterized in that the output of more than 15dBm The method according to claim 1, The second amplifier has a radar detector characterized in that the output of more than 18dBm