JPH0749378A - Intermittent frequency modulation radar system - Google Patents

Abstract

PURPOSE:To accurately measure a relative distance and relative speed against respective target objects by preventing the peak combination error when a plurality of target objects exist. CONSTITUTION:A grouping means M2 performs correlative computation for the respective peaks of power spectrums of beat signals in an increase modulation section and decrease modulation section and of power spectrum in a non- modulation section, and groups the respective peaks in three sections that are highly correlative with each other. A judgement means M3 judges whether or not the difference between the peak frequencies in the increase and decrease modulation sections coupled each other is about two times the peak frequency in the non-modulation section.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an intermittent frequency modulation radar device, and more particularly to an intermittent frequency modulation radar device mounted on a vehicle for detecting a target object.

[0002]

2. Description of the Related Art Conventionally, various devices have been developed and mounted on a vehicle for the purpose of improving a driver's low operation range and improving safety. Development of a radar device for detecting the is also active. As a radar device, a device using radio waves such as millimeter waves or a device using laser light has been proposed.
In Japanese Unexamined Patent Publication No. 4-105086, a carrier wave is frequency-modulated by a triangular wave, and the modulation is intermittently stopped and transmitted / received.
The relative distance and relative speed to the target object are calculated from the peak frequency of the beat signal power spectrum of and the peak frequency of the beat signal power spectrum of the frequency falling part (down beat), and it is not possible to accurately identify when the relative speed is high. There is described an intermittent frequency modulation radar device that accurately identifies a plurality of target objects by using the Doppler frequency in the non-modulation mode and improves the relative velocity detection accuracy by the Doppler frequency.

[0003]

In the conventional device, when there are a plurality of target objects to be detected, there are a plurality of upbeat spectrum peak frequencies, downbeat spectrum peak frequencies and Doppler frequencies. There is a problem in that it is not possible to discriminate which of the down-beat spectrum peaks corresponds to which Doppler frequency, and the relative distance and relative speed to each target object cannot be accurately detected.

The present invention has been made in view of the above points,
By performing the grouping based on the correlation of the peaks of the increasing modulation section (up section), the decreasing modulation section (down section), and the non-modulation section, performing the combination determination of each group and calculating the relative distance and the relative speed, It is an object of the present invention to provide an intermittent frequency modulation radar device capable of preventing a combination error of peaks when a plurality of target objects are present and accurately measuring a relative distance and a relative speed to each target object.

[0005]

FIG. 1 shows the principle of the present invention. In the figure, the radar device body M1 includes a transmitter for transmitting a carrier wave, a receiver for receiving a reflected wave of the carrier wave,
The frequency modulation means for increasing / decreasing / non-modulating the frequency of the carrier wave, and the beat signal calculating means for calculating the frequency difference between the transmission signal and the reception signal are provided. The relative distance and relative velocity from the peak frequency of the power spectrum of each beat signal to the target object are calculated.

The grouping means M2 performs a correlation operation between the peak of the power spectrum of the beat signal in the increasing modulation section, the peak of the power spectrum of the beat signal in the decreasing modulation section, and the peak of the power spectrum of the non-modulation section to obtain the correlation. The peaks in each of the three high sections are grouped.

The determining means M3 determines whether the difference between the peak frequency of the beat signal in the increasing modulation section and the peak frequency of the beat signal in the decreasing modulation section, which are grouped with each other, is approximately twice the peak frequency of the non-modulation section. To do.

As a result, the radar apparatus body M1 obtains the relative distance and the relative velocity of the target object from the peak frequencies of the three sections of the group which satisfy the conditions of the above-mentioned determination means.

[0009]

In the present invention, the peaks of the increasing modulation section, the decreasing modulation section, and the non-modulating section are grouped by using the correlation, and the three grouped peaks are the peak frequency of the increasing modulation section and the decreasing modulation section. If the difference between the peak frequency and the peak frequency is approximately twice the peak frequency in the non-modulation section, the relative distance and the relative velocity are calculated assuming that the grouping is correct, so that an error in grouping, that is, a combination of peaks can be prevented and obtained. The relative distance and relative speed to each target object are accurate.

[0010]

FIG. 2 shows a block diagram of the device of the present invention. In the figure, the transmission side circuit includes a carrier wave generator 10 and a frequency modulator 1.
2, a modulation voltage generator 14, a circulator 16, and a transmission antenna 18. A carrier wave is output from the carrier wave generator 10 and supplied to the frequency modulator 12.
On the other hand, a triangular wave whose amplitude changes in a triangular shape is generated from the modulation voltage generator 14 and is supplied to the frequency modulator 12 as a modulation wave which intermittently stops the output. by this,
The carrier wave from the carrier wave generator 10 is frequency-modulated, the frequency changes into a triangular shape with the lapse of time, and a transmission signal as shown in FIG. 3 that intermittently maintains a constant frequency is output. This transmission signal is supplied to the transmission antenna 18 via the circulator 16 and radiated toward the object to be detected. On the other hand, a part of the transmission signal is supplied to the mixer of the receiving circuit described later via the circulator 16.

The receiving side circuit includes a receiving antenna 20, a mixer 22, an amplifier 24, a filter 26, a fast Fourier transform processor (FFT signal processor) 28, and a target recognizer 3.
0, a risk determiner 32, and an alarm 34.
The reflected wave from the detected object is received by the receiving antenna 20 and supplied to the mixer 22. In the mixer 22, the reception signal and a part of the transmission signal from the circulator 16 are combined by a difference calculation to generate a beat signal. Mixer 22
The beat signal from is amplified by the amplifier 24 and supplied to the FFT signal processor 28 via the anti-aliasing filter 26. The FFT signal processor 28 obtains the power spectrum of each of the frequency rising portion and the frequency falling portion and supplies them to the target recognizer 30.

FIG. 4 shows a flow chart of an embodiment of the target recognition processing executed by the target recognizer 30.
This process is executed, for example, every tens of msec. In the figure, in step S10, peaks are detected from the respective power spectrums in the up and down sections of the modulation mode and in the non-modulation mode section. Here, for example, when there are two target objects a and b in the radar beam as shown in FIG. 5, there are two peaks corresponding to the opposite signals from these two objects. 6A is a power spectrum in the up section, FIG. 6B is a power spectrum in the down section, and FIG. 6C is a power spectrum in the non-modulation section. The peak frequencies of the objects a and b are represented by f ₁ and f ₂ (subscripts up, dn, and d indicate upbeat, downbeat, and Doppler, respectively).

Next, in step S12, a predetermined frequency range (window) centered on each peak is cut out on the power spectrum of each of the three sections. In step S14, the power spectrum of the window of each peak in the up section is used as a reference to correlate with the power spectrum of the window of each peak of the down section, and the peak with the highest correlation is selected for pairing. Here, the up section,
The windows of the down sections are divided for each predetermined frequency Δf, and the sum of differences between the spectrum of the up section and the power spectrum of the down section is used as the correlation amount. The higher the correlation, the smaller the correlation amount. Further, in step S16, similarly, with reference to the power spectrum of the window power spectrum of each peak in the up section, no modulation (C
W) The correlation between each peak and the power spectrum of the window is taken, and the peak with the highest correlation is selected for pairing.

In step S18, the steps S14,
From the pairing result of S16, the peak of the down section and the peak of the non-modulation section paired with the arbitrary peak of the up section are grouped with the peak of the up section as a reference.

Next, in step S20, the number γ is reset to zero, and in step S22 it is determined whether or not the three grouped peaks satisfy the following equation.

Fdni-fupi≈2fdi (1) where the subscript i is the group number, where fx is between the peak frequency fup in the up section and the relative frequency fx obtained from the peak frequency fdn in the down section. There is a relationship of = (fdn-fup) / 2, and the relative velocity frequency fx should be the same as the Doppler frequency, that is, the peak frequency of the non-modulation section. Therefore, it can be confirmed that the grouping of the three peaks is correct if the expression (1) is satisfied. If the expression (1) is satisfied, a group (set) of three peaks is determined in step S24. If not satisfied, the number of times γ is incremented by 1 in step S26, it is determined in step S28 whether the number of times γ is 3 or less, and if it is less than 3, it is further determined in step S30 whether the number of times γ is 1, 2 or 3. .

When the number of times γ is 1, the peaks in the up section and the non-modulation section in the group are not changed in step S32, and the peak having the second highest correlation among the peaks in the down section is paired with the peak of the upbeat. Step S22
Proceed to. If the number of times γ is 2, the peaks in the up section and the down section in the group are not changed in step S34, the peak having the highest correlation in the down section is returned so as to be paired with the peak of the upbeat, and the peak of the unmodulated section The peak having the second highest correlation with the peak is paired with the peak of the upbeat, and the process proceeds to step S22. When the number of times γ is 1, the peak of the up section in the group is not changed in step S36, and the peaks of the down section and the non-modulation section are 2 respectively.
The second-highest correlation peak is paired with the upbeat peak, and the process proceeds to step S22.

After changing the combination of the peaks of the down section and the non-modulation section with respect to the peak of the upbeat by executing the steps S32, S34 and S36, it is determined whether the equation (1) is satisfied again in step S22. To be determined. When the group of three peaks is confirmed by satisfying the expression (1), the process proceeds to step S38. If the group is not confirmed even after the group is changed in steps S32, S34 and S36, the process proceeds from step S28 to step S38.

In step S38, it is determined whether or not there is a peak that has not been grouped yet in the up section, and if there is a peak, in step S40 the down section paired with another peak in the up section is processed as in step S18. The peaks and the peaks in the non-modulation section are grouped and the process proceeds to step S20. If no peak remains, the process proceeds to step S42.

In the next step S42, the distance frequency fr =
(Fdown + fup) / 2 and Doppler frequency fd, and fd = 2v / c · f0 fr = 4fm Δf / c · R, where v: relative speed, c: speed of light, f0: center frequency, fm:
Modulation frequency, Δf: relative distance and relative velocity are calculated from the frequency deviation width, and the process is terminated.

The calculated distance data and relative velocity data are supplied to the danger determiner 32. The risk determiner 32 compares the safety distance that is predetermined or calculated according to the running state of the vehicle and the calculated distance data, and if the safety distance is less than or equal to the safety distance, it is determined as dangerous. The alarm 34 notifies the driver.

As described above, the peaks of the up section, the down section, and the non-modulation section are grouped by using the correlation, and the three grouped peaks are the peak frequency of the up section and the peak frequency of the down section. If the difference is approximately twice the peak frequency of the non-modulated section, the relative distance and relative velocity are calculated assuming that the grouping is correct, and therefore grouping, that is, an error in the combination of peaks is prevented, and the obtained target objects and The relative distance and relative velocity are accurate.

[0023]

As described above, according to the intermittent frequency modulation radar device of the present invention, the grouping is performed based on the correlation of the peaks of the up section, the down section, and the non-modulation section to determine the combination of each group. By calculating the relative distance and relative velocity, it is possible to prevent peak combination errors when there are multiple target objects and to accurately measure the relative distance and relative velocity with each eyelid object, which is extremely useful in practice. .

[Brief description of drawings]

FIG. 1 is a principle diagram of the present invention.

FIG. 2 is a block diagram of the device of the present invention.

FIG. 3 is a waveform diagram of a transmission signal.

FIG. 4 is a flowchart of target recognition processing.

FIG. 5 is an explanatory diagram of a radar beam and a detected object.

FIG. 6 is an explanatory diagram of a power spectrum.

[Explanation of symbols]

 M1 radar device body M2 grouping means M3 judging means M4 second pairing means M5 peak confronting means 10 carrier wave generator 12 frequency modulator 14 modulation voltage generator 16 circulator 18 transmission antenna 20 reception antenna 22 mixer 24 amplifier 26 filter 28 FFT Signal processor 30 Target recognizer 32 Danger judgment device 34 Alarm device

Claims (1)

[Claims] 1. A transmitter for transmitting a carrier wave, a receiver for receiving a reflected wave of the carrier wave, a frequency modulation means for increasing / decreasing / non-modulating the frequency of the carrier wave, and a transmitting signal and a receiving signal. Beat signal calculation means for calculating the frequency difference, and intermittent frequency modulation radar for calculating the relative distance and relative speed from the peak frequency of the power spectrum to the target object in each beat signal in the increasing modulation section / decreasing modulation section / non-modulation section In the apparatus, the correlation calculation of the peak of the power spectrum of the beat signal in the increasing modulation section, the peak of the power spectrum of the beat signal in the decreasing modulation section, and the peak of the power spectrum of the non-modulation section is performed, and each of the three sections having high correlation Grouping means for grouping the peaks of, and increasing modulation grouped together Between the peak frequency of the beat signal and the peak frequency of the beat signal in the decreasing modulation section is about twice the peak frequency of the non-modulation section. An intermittent frequency modulation radar device, characterized in that the relative distance and relative velocity of a target object are obtained from the peak frequencies of each of the three sections of a satisfied group.