JP3930376B2 - FMCW radar equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an FMCW radar apparatus, and particularly to an FMCW radar apparatus that performs short-range high-resolution ranging.
[0002]
[Prior art]
The FMCW radar device applies frequency modulation to the transmission signal by a triangular wave or sawtooth wave, mixes the reflected signal reflected by the object of the transmission signal and the transmission signal, and the frequency of the beat signal generated by the time difference between the two signals Determine the distance from
Referring to FIG. 6 showing a block diagram of a sensor unit of a general FMCW radar apparatus, the sensor unit 1 receives a transmission antenna 11 that transmits a transmission signal TX, a reflection signal RX from a target, and outputs a reception signal R. Receiving antenna 12, a modulator 14 that generates a sawtooth wave modulation signal M for FMCW radar, and a high-frequency oscillator that outputs an FM-modulated high-frequency signal RF whose oscillation frequency is controlled (frequency-modulated) by the modulation signal M 13, a mixer 15 that mixes the received signal R supplied from the receiving antenna 12 and the high-frequency signal RF supplied from the oscillator 13 to output the beat signal B, and amplifies the beat signal B to generate the beat signal BO. And an amplifier 16 for outputting.
[0003]
Next, the operation of the sensor unit 1 will be described with reference to FIG. 6. The modulator 14 generates a sawtooth wave modulation signal M and supplies it to the oscillator 13. The oscillator 13 is composed of a voltage controlled oscillator (VCO) having the same frequency as the carrier frequency, and generates a high frequency signal RF of a continuous wave (CW) whose oscillation frequency is controlled by the modulation signal M, that is, frequency modulated (FM). To the transmission antenna 11 and the mixer 15. Here, for convenience of explanation, the frequency modulation characteristic of the oscillator 13, that is, the modulation signal voltage (level) versus the oscillation frequency characteristic, is directly proportional to the level of the modulation signal M, that is, linearly oscillates as the level of the modulation signal M increases. Assume that the frequency rises. Therefore, when the level of the modulation signal M is the lowest value, the frequency of the high-frequency signal RF is the lowest, and when the level of the modulation signal M is the highest value, the frequency of the high-frequency signal RF is the highest. It is assumed that the high-frequency signal RF has a carrier (carrier wave) frequency f ₀ when the central voltage, which is an intermediate voltage of the highest voltage, is used. The difference between the lowest and highest frequencies of the high-frequency signal RF is called a frequency modulation bandwidth ΔF.
[0004]
The transmission antenna 11 irradiates the transmission target TX to the target to be measured. The target irradiated with the transmission signal TX emits a corresponding scattered wave. The component returning to the transmission direction in the scattered wave is a backscattered signal (hereinafter referred to as a reflected signal RX). The receiving antenna 12 receives this reflected signal RX as a received signal R and supplies it to the mixer 15. The mixer 15 mixes the reception signal R and the above-described high-frequency signal RF, generates a beat signal B that is a result of mixing both the signals R and RF, and supplies the beat signal B to the amplifier 16. The amplifier 16 amplifies the beat signal B and outputs the amplified beat signal BO.
[0005]
Next, the principle of distance measurement of the FMCW radar will be described with reference to FIG. 7 showing the change in frequency with respect to time of the transmission signal and the reception signal of the FMCW radar apparatus together with the time chart. This is a signal having a frequency F _b generated by mixing a reception signal and a transmission signal delayed by a propagation time t, which is a time required for round-trip spatial propagation until reception.
From this frequency shift width F _b , a propagation time t from transmission to reception of the transmission signal is calculated and converted into a distance R.
The propagation time t of the FMCW radar can be obtained from Equation 1.
Further, the distance R to the target can be obtained by Equation 2.
[0006]
[Expression 1]
t = T × F _b / ΔF
Where T: modulation period, ΔF: frequency modulation band number width
[Expression 2]
R = C × t / 2
Where R: distance, C: speed of light
As described above, the beat signal B of the transmission wave and the reception wave is obtained, and the frequency of the obtained beat signal B is measured to obtain the delay time, that is, the propagation time t. From this propagation time t, the distance R can be converted.
[0009]
Next, referring to FIG. 8, which shows a block diagram of a conventional FMCW radar device using the above-described ranging principle, this conventional FMCW radar device radiates a frequency-modulated transmission signal by a sawtooth wave and is reflected by a target. a sensor section 1 above for outputting a beat signal BO corresponding receiving a reflected signal, the beat frequency to process the beat signal BO, i.e., the signal and outputs the detected target information determined frequency F _b target detection signal L A processing unit 2 and a display unit 3 that receives the target detection signal L and displays it on a display or the like are provided. The signal processor 2 converts the beat signal BO into a digital signal and outputs a digital beat signal DB, and a weighting unit that performs a weighting operation on the digital beat signal DB using a window function and outputs a weighted beat signal WB. A circuit 22, a Fourier transform circuit 23 that Fourier-transforms the weighted beat signal WB and outputs a complex signal IQ, an amplitude calculation circuit 24 that calculates an amplitude that is an absolute value of the complex signal IQ and outputs an amplitude signal AB, and an amplitude signal And a detection circuit 25 that performs target information detection processing from AB and outputs a target detection signal L.
[0010]
Next, with reference to FIG. 8, the operation of the conventional FMCW radar apparatus will be described with particular emphasis on the operation of the signal processing unit 2. The sensor unit 1 radiates a frequency-modulated transmission signal as described above. The reflected signal from the target is received and the corresponding beat signal BO is output and supplied to the signal processing unit 2.
In the signal processing unit 2, the A / D converter 21 converts the beat signal BO supplied from the sensor unit 1 from analog to digital, generates a corresponding digital beat signal DB, and supplies it to the weighting circuit 22. The weighting circuit 22 performs a weighting operation using a window function such as a Hanning window in order to reduce side lobes of the frequency spectrum, outputs a weighted beat signal WB, and supplies it to the Fourier transform circuit 23. The Fourier transform circuit 23 performs a Fourier transform process on the weighted beat signal WB, generates a complex signal IQ, and supplies the complex signal IQ to the amplitude calculation circuit 24. The amplitude calculation circuit 24 performs amplitude calculation processing of the complex signal IQ, generates an amplitude signal AB that is an absolute value of the complex signal IQ, and supplies the amplitude signal AB to the detection circuit 25. The detection circuit 25 detects target information by amplitude detection that is target detection based on amplitude information such as peak detection, edge detection, or threshold processing for the amplitude signal AB, and outputs a target detection signal L. Here, amplitude detection is described as peak detection.
[0011]
The display unit 3 displays the target detection signal L output from the signal processing unit 2 on the display. In the distance measurement in such an FMCW radar apparatus, the distance resolution ΔR is expressed as Equation 3 as is well known.
[0012]
[Equation 3]
ΔR = C / 2ΔF
[0013]
Therefore, in order to realize a very high distance resolution, for example, on the order of several centimeters, it is necessary to expand the frequency modulation bandwidth to an ultra-wide band (1 GHz order).
However, these improvement measures are not always feasible due to hardware restrictions and restrictions imposed by the Radio Law.
[0014]
[Problems to be solved by the invention]
The above-mentioned conventional FMCW radar apparatus needs to use an ultra-wideband frequency modulation bandwidth when a very high distance resolution is required. These measures are based on hardware restrictions, radio wave laws, etc. There was a drawback that it was not always feasible due to restrictions.
[0015]
An object of the present invention is to provide an FMCW radar device with high distance resolution without increasing the frequency modulation bandwidth.
[0016]
[Means for Solving the Problems]
In the first configuration of the FMCW radar apparatus of the present invention, the transmission signal is subjected to frequency modulation by a triangular wave or a sawtooth wave, the reflected signal reflected by the object of the transmission signal is mixed with the transmission signal, and both signals are mixed. An FMCW radar apparatus that determines a distance from the frequency of a beat signal generated by a time difference, and includes the following components (A) and (B).
(A) A sensor unit that emits a frequency-modulated transmission signal by the triangular wave or sawtooth wave, receives the reflected signal reflected by the target, and outputs a beat signal of the corresponding frequency;
(B) Detecting a null point on the frequency spectrum by linking the half-time signal of either one of the latter half or the first half of the beat signal and then linking with the signal of the other half of the beat signal. A signal processing unit that outputs a target detection signal.
[0017]
In the second configuration of the FMCW radar apparatus of the present invention, the transmission signal is frequency-modulated by a triangular wave or a sawtooth wave, the reflected signal reflected by the object of the transmission signal is mixed with the transmission signal, and both signals are mixed. An FMCW radar apparatus that determines a distance from the frequency of a beat signal generated by a time difference, and includes the following components (A) and (B).
(A) A sensor unit that emits a frequency-modulated transmission signal by the triangular wave or sawtooth wave, receives the reflected signal reflected by the target, and outputs a beat signal of the corresponding frequency;
(B) A coarse measurement mode for processing the beat signal and detecting a beat frequency by amplitude detection, which is target detection based on amplitude information of a frequency spectrum, and either one of the second half and the first half of the beat signal in time A signal processing unit having a fine measurement mode in which a null point on the frequency spectrum is detected and output as a target detection signal by connecting with a half-phase signal that is not reversed phase as a reversed phase .
[0018]
According to a third configuration of the present invention, in the FMCW radar apparatus having the second configuration, the amplitude detection is a peak detection of a frequency spectrum.
[0019]
According to a fourth configuration of the present invention, in the FMCW radar apparatus of the second configuration, the signal processing unit includes the following components (A) to (H).
(A) an A / D converter for converting the beat signal into a digital signal and outputting the digital beat signal;
(B) a weighting circuit for performing a weighting operation by a window function on the digital beat signal and outputting a weighted beat signal;
(C) a first Fourier transform circuit that Fourier-transforms the weighted beat signal and outputs a complex signal;
(D) a first amplitude calculation circuit that calculates an amplitude that is an absolute value of the complex signal and outputs an amplitude signal;
(E) The half beat signal which is divided into the temporal first half and the second half of the weighted beat signal and inverts the phase of one of the latter half and the first half beat signals and then does not invert the phase. An anti-phase processing circuit that outputs an anti-phase weighted beat signal in which one of the halves is in anti-phase,
(F) a second Fourier transform circuit that Fourier transforms the antiphase weighted beat signal and outputs an antiphase complex signal;
(G) a second amplitude calculation circuit for calculating the amplitude of the negative-phase complex signal and outputting a negative-phase amplitude signal;
(H) When the coarse / coarse switching signal for switching between the coarse measurement mode and the fine measurement mode indicates the coarse measurement mode, detection processing by the amplitude detection of the amplitude signal is performed, and the fine / coarse switching signal is A null detection circuit that performs null point detection processing of the negative phase amplitude signal when detecting the measurement mode, detects the null point, and generates the target detection signal.
[0020]
According to a fifth configuration of the present invention, in the FMCW radar apparatus of the second configuration, the signal processing unit includes the following components (A) to (I).
(A) an A / D converter for converting the beat signal into a digital signal and outputting the digital beat signal;
(B) a weighting circuit for performing a weighting operation by a window function on the digital beat signal and outputting a weighted beat signal;
(C) a first Fourier transform circuit that Fourier-transforms the weighted beat signal and outputs a complex signal;
(D) a first amplitude calculation circuit that calculates an amplitude that is an absolute value of the complex signal and outputs an amplitude signal;
(E) the weighting beat signal coupled to half of those who do not phase inversion after inverting any one of the phase of the first half and these latter half portion is divided into a temporal first half and the second half portion halves A negative phase processing circuit that outputs a negative phase weighted beat signal in which one of
(F) a second Fourier transform circuit that Fourier transforms the antiphase weighted beat signal and outputs an antiphase complex signal;
(G) a second amplitude calculation circuit for calculating the amplitude of the negative-phase complex signal and outputting a negative-phase amplitude signal;
(H) When the fine / coarse switching signal for switching between the coarse measurement mode and the fine measurement mode indicates the coarse measurement mode, the amplitude signal is output as it is, and when the fine / coarse switching signal indicates the fine measurement mode. Is a division circuit that divides the amplitude signal by the negative-phase amplitude signal and outputs a divided amplitude signal;
(Li) A detection circuit that detects the amplitude of the amplitude signal or the divided amplitude signal and outputs the target detection signal.
[0021]
According to a sixth configuration of the present invention, in the FMCW radar apparatus having the first or second configuration, the sensor unit includes the following components (a) to (f).
(A) a transmission antenna for transmitting the transmission signal;
(B) a receiving antenna that receives the reflected signal from the target and outputs a received signal;
(C) a modulator for generating a modulation signal of the triangular wave or sawtooth wave;
(D) a high-frequency oscillator that outputs an RF-modulated high-frequency signal whose oscillation frequency is controlled (frequency-modulated) by the modulation signal;
(E) a mixer that mixes the received signal and the high-frequency signal and outputs the beat signal;
(F) An amplifier for amplifying the beat signal.
[0022]
DETAILED DESCRIPTION OF THE INVENTION
The embodiment of the present invention uses a sensor in common with the prior art that outputs a beat signal, which is a mixing result of a received signal and a high-frequency signal, and uses only the first half or second half data of the beat signal as a reverse phase to perform Fourier transform. By detecting the null point of the frequency spectrum obtained by conversion, the amplitude change rate increases as it approaches the null point, and the distance accuracy is improved by utilizing the difference detection feature that becomes infinite at the null point. It is characterized by.
[0023]
【Example】
Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a block diagram showing the configuration of the first embodiment of the present invention. In addition, the same code | symbol is attached | subjected to the block of the same function as the structure of FIG. The FMCW radar apparatus shown in this figure radiates a frequency-modulated transmission signal using a sawtooth wave common to the prior art, receives the reflected signal reflected by the target, and outputs the corresponding beat signal BO. In addition to the display unit 3 that receives the target detection signal L and displays it on a display or the like, the beat signal BO is processed in place of the signal processing unit 2 to detect amplitudes such as frequency spectrum peak detection (hereinafter, for convenience of explanation). In addition to the coarse measurement mode in which the beat frequency F _b is obtained by the amplitude detection as a peak detection), the second half of the beat signal BO is connected to the first half of the beat signal BO as the opposite phase. A signal processing unit 2A having a fine measurement mode in which a null point is detected and output as a target detection signal L is provided.
The signal processing unit 2A converts the beat signal BO common to the conventional one into a digital signal and outputs a digital beat signal DB, and performs a weighting operation on the digital beat signal DB by a window function to perform a weighted beat signal WB. , A Fourier transform circuit 23 that Fourier transforms the weighted beat signal WB and outputs a complex signal IQ, and an amplitude calculation circuit 24 that calculates an amplitude that is an absolute value of the complex signal IQ and outputs an amplitude signal AB. In addition, the weighted beat signal WB is divided into the data of the first half and the data of the second half, the phase of the data of the second half is inverted, and then connected to the data of the first half so that the second half is reversed. The anti-phase processing circuit 26 for outputting the phase-weighted beat signal WRB and the anti-phase complex signal IQR by Fourier-transforming the anti-phase weighted beat signal WRB The Fourier transform circuit 27 that performs the calculation, the amplitude calculation circuit 28 that calculates the amplitude of the anti-phase complex signal IQR and outputs the anti-phase amplitude signal ABR, and the fine coarse switching signal CF that switches between the coarse measurement mode and the fine measurement mode is at a low level. When (logic value 0), the peak detection process of the amplitude signal AB is performed, and when the fine switching signal CF is at a high level (logic value 1), the null point detection process of the negative phase amplitude signal ABR is performed to detect the null point. And a null detection circuit 29 for generating the target detection signal L.
[0024]
Next, with reference to FIG. 1 and FIG. 2 and FIG. 3 showing the waveforms of the respective parts in waveform diagrams, the operation of the present embodiment will be described with emphasis on the difference from the prior art. , The reflected signal from the target is received, the corresponding beat signal BO is output, and supplied to the signal processing unit 2A.
The A / D converter 21 of the signal processing unit 2A converts the beat signal BO supplied from the sensor unit 1 from analog to digital, generates a corresponding digital beat signal DB, and supplies it to the weighting circuit 22. For convenience of explanation, referring to FIG. 2 (a) showing an example of the waveform of the digital beat signal DB represented in the form of an analog signal, the digital beat signal DB is the time during the life of the target. Regardless of the signal, the amplitude is constant. For convenience of explanation, in each waveform shown in FIGS. 2 and 3, the unit of time is arbitrary, and the amplitude is expressed as a relative value with ± 1.0 as the maximum value of each positive and negative.
[0025]
The weighting circuit 22 performs a weighting operation with a window function such as a Hanning window on the supplied digital beat signal DB to reduce a side lobe of the frequency spectrum, and outputs a weighted beat signal WB. To the processing circuit 26. For convenience of explanation, referring to FIG. 2B showing an example of a weighted beat signal WB with a window function as a Hanning window, the weighted beat signal WB is moderate from the target start point (time = 0 vicinity). At the center of the target (near time = 70), the amplitude A becomes maximum, and the amplitude gradually decreases toward the end point (near time = 130).
[0026]
The Fourier transform circuit 23 performs a Fourier transform process on the weighted beat signal WB to generate a complex signal IQ, and the amplitude calculation circuit 24 performs an amplitude calculation process on the complex signal IQ, and an amplitude signal AB that is an absolute value of the complex signal IQ. Is generated and supplied to the null detection circuit 29. The amplitude signal AB corresponds to the frequency spectrum of the weighted beat signal WB, and referring to FIG. 2 (c) showing an example of the frequency spectrum waveform after Fourier transform, the horizontal axis shown in FIG. The vertical axis represents amplitude. The unit of distance is arbitrary.
[0027]
The null detection circuit 29 performs rough measurement when the coarse / coarse switching signal CF for switching between the coarse measurement mode for detecting distance by the same detection process as in the prior art and the fine measurement mode for performing distance detection by null detection of this embodiment is at a low level. It becomes a mode. In this case, the null detector circuit 29, the same processing as the conventional detection circuit 25 to the amplitude signal AB which supplied, wherein the target information by the peak detecting process, namely, the amplitude signal corresponding to the frequency deviation width F _b And a target detection signal L is output. In this case, the vicinity of the peak of the wide mountain curve is detected as the amplitude signal and output as the target detection signal L.
[0028]
In parallel, the antiphase processing circuit 26 temporally divides the weighted beat signal WB into data in the first half frequency domain and data in the second half frequency domain and inverts the phase of the data in the second half. Processing is performed to output a reverse-phase weighted beat signal WRB in which the latter half of the data is in reverse phase, and this is supplied to the Fourier transform circuit 27. With reference to (a) of FIG. 3 showing an example of the negative phase weighted beat signal WRB in the waveform diagram, when compared with the above beat signal WB shown in (b) of FIG. It can be seen that the phase is inverted from the center of the target (around time = 70) in the latter half.
[0029]
The Fourier transform circuit 27 performs a Fourier transform on the antiphase weighted beat signal WRB, outputs an antiphase complex signal IQR, and supplies it to the amplitude calculation circuit 28. The amplitude calculation circuit 28 performs amplitude calculation processing of the anti-phase complex signal IQR, generates an anti-phase amplitude signal ABR that is an absolute value of the anti-phase complex signal IQR, and supplies it to the null detection circuit 29. The negative phase amplitude signal ABR corresponds to amplitude information in the time (distance) region in the frequency spectrum of the negative phase weighted beat signal WRB.
The null detection circuit 29 is in a fine measurement mode when the fine / fine switching signal CF is at a high level. At this time, the null detection circuit 29 performs null detection on the supplied negative phase amplitude signal ABR.
[0030]
Referring to FIG. 3B showing an example of the negative phase amplitude signal ABR in the waveform diagram of the frequency spectrum after Fourier transform, the horizontal axis shown in this figure represents the distance, and the vertical axis represents the amplitude. The unit of distance is the same as that of the amplitude signal AB described above. As shown in the figure, the antiphase amplitude signal ABR equivalently represents an amplitude difference with respect to the distance between the first half and the second half of the frequency spectrum in time, and the point where the amplitude of the first half and the second half becomes equal is zero. It has a so-called null point. The amplitude change in the vicinity of the null point becomes larger as the rate of change, that is, the differential coefficient approaches the null point, due to the nature of the difference detection, and becomes infinite at the null point. Therefore, it can be seen that the amplitude change rate in the vicinity of the peak position of the amplitude signal AB decreases as it approaches the peak point, and is much steeper than the peak point that is zero at the peak point. That is, the amplitude signal AB common to that according to the prior art has a poor resolution due to the above-described characteristics of the peak point, and it is difficult to measure with sufficient accuracy.
[0031]
On the other hand, in the antiphase amplitude signal ABR of the present embodiment, a steep null point is formed at the target position (distance), and it can be seen that a highly accurate measurement value can be obtained by detecting this.
[0032]
However, since the negative phase amplitude signal ABR may have a point of amplitude 0 that cannot be distinguished from the null point even at a position where no target exists, the null detection process 29 initially sets the fine switching signal CF to a low level. The level is set to the rough measurement mode, the target signal is roughly measured by the amplitude signal AB, the target information is detected, and the rough target detection signal is output. Subsequently, the fine switching signal CF is set to a high level to switch to the fine measurement mode, null detection only in the vicinity of the rough target detection signal (target), that is, fine measurement is performed to detect target information, and the target detection signal L is Output. In other words, fine target detection is performed using the rough target detection signal as an open gate. Those results are displayed on the display unit 3.
Thereby, ranging resolution can be improved without expanding the frequency modulation bandwidth.
[0033]
Next, a second embodiment of the present invention will be described.
FIG. 4 is a block diagram showing the configuration of the second embodiment. The same components as those in FIG. 1 are denoted by the same reference numerals.
The difference from the first embodiment of FIG. 1 is that instead of the null detection circuit 29, the amplitude signal AB is output as it is when the fine switching signal CF is low, and the fine switching signal CF is high. In some cases, the division circuit 30 that divides the amplitude signal AB by the anti-phase amplitude signal ABR and outputs the divided amplitude signal AD, and the peak detection of the amplitude signal AB or the divided amplitude signal AD and outputs the target detection signal L are common. And a detection circuit 25.
[0034]
Next, referring to FIG. 4 and FIG. 5 which shows a waveform of the divided amplitude signal AD with the horizontal axis representing the distance and the vertical axis representing the amplitude, the operation of the present embodiment is different from the first embodiment. To explain, when the fine switching signal CF is in the high level fine measurement mode, the null point is further emphasized by dividing the amplitude signal AB by the antiphase amplitude signal ABR, and the resulting divided amplitude signal AD is: A steeper characteristic than the negative phase amplitude signal ABR is obtained. The division amplitude signal AD is peak detected by the detection circuit 25 and the target detection signal L is output.
[0035]
In the above-described embodiment, the negative-phase weighted beat signal is generated with the latter half of the data as the reverse phase, but the same effect can be obtained even when the negative-phase weighted beat signal is generated with the first half of the data as the reverse phase. can get.
Further, although the target detection method in the amplitude signal (frequency spectrum) in the coarse measurement mode is the peak detection, it is obvious that a detection method such as edge detection or threshold processing may be used.
[0036]
【The invention's effect】
As described above, the FMCW radar apparatus according to the present invention connects the data of either the second half or the first half of the beat signal with the data of either the first half or the second half of the beat signal in the reverse phase. In addition to the peak detection output of the frequency spectrum of the target beat signal, one of the first half / second half frequency domain data of the beat signal is provided. By using the null detection output of the frequency spectrum with a steeper characteristic obtained as a reverse phase, it is possible to perform more accurate distance measurement, so the ranging resolution is not increased without increasing the frequency modulation bandwidth There is an effect that can be improved.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a first embodiment of an FMCW radar apparatus of the present invention.
FIG. 2 is a waveform diagram showing a beat signal, a weighted beat signal, and a frequency spectrum waveform after Fourier transform, illustrating an example of operation in the conventional FMCW radar apparatus having the configuration of FIG. 1;
FIG. 3 shows an example of operation in the FMCW radar apparatus according to the embodiment of the present invention, a waveform in which the latter half of the beat signal is reversed in phase and connected to the first half, and a frequency spectrum waveform after Fourier transformation of the signal after the reverse phase processing. It is a wave form diagram shown respectively.
FIG. 4 is a block diagram showing a configuration of a second embodiment of the FMCW radar apparatus of the present invention.
FIG. 5 shows a frequency spectrum obtained by dividing the weighted beat signal and the frequency spectrum waveform after Fourier transformation by the frequency spectrum waveform after Fourier transformation of the signal after the reverse phase processing, showing an example of the operation in the second embodiment of the present invention. It is a wave form diagram which shows a waveform.
FIG. 6 is a block diagram illustrating an example of a configuration of a sensor unit of a general FMCW radar apparatus.
FIG. 7 is a time chart showing a change in frequency with respect to time of a transmission signal and a reception signal of the FMCW radar apparatus.
FIG. 8 is a block diagram showing an example of a conventional FMCW radar apparatus.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Sensor part 2, 2A, 2B Signal processing part 3 Display part 11 Transmission antenna 12 Reception antenna 13 Oscillator 14 Modulator 15 Mixer 16 Amplifier 21 A / D converter 22 Weighting circuit 23, 27 Fourier transform circuit 24, 28 Amplitude calculation Circuit 25 Detection circuit 26 Reverse phase processing circuit 29 Null detection circuit 30 Division circuit

Claims (6)

FMCW that applies frequency modulation to the transmission signal with a triangular wave or sawtooth wave, mixes the reflected signal reflected by the object of the transmission signal and the transmission signal, and determines the distance from the frequency of the beat signal generated by the time difference between the two signals A radar apparatus comprising the following components (a) and (b):
(A) A sensor unit that emits a frequency-modulated transmission signal by the triangular wave or sawtooth wave, receives the reflected signal reflected by the target, and outputs a beat signal of the corresponding frequency;
(B) Detecting a null point on the frequency spectrum by linking the half-time signal of either one of the latter half or the first half of the beat signal and then linking with the signal of the other half of the beat signal. A signal processing unit that outputs a target detection signal. FMCW that applies frequency modulation to the transmission signal with a triangular wave or sawtooth wave, mixes the reflected signal reflected by the object of the transmission signal and the transmission signal, and determines the distance from the frequency of the beat signal generated by the time difference between the two signals A radar apparatus comprising the following components (a) and (b):
(A) A sensor unit that emits a frequency-modulated transmission signal by the triangular wave or sawtooth wave, receives the reflected signal reflected by the target, and outputs a beat signal of the corresponding frequency;
(B) A coarse measurement mode for processing the beat signal and detecting a beat frequency by amplitude detection, which is target detection based on amplitude information of a frequency spectrum, and either one of the second half and the first half of the beat signal in time A signal processing unit having a fine measurement mode in which a null point on the frequency spectrum is detected and output as a target detection signal by connecting with a half-phase signal that is not reversed phase as a reversed phase .   3. The FMCW radar apparatus according to claim 2, wherein the amplitude detection is peak detection of a frequency spectrum. The FMCW radar apparatus according to claim 2, wherein the signal processing unit includes the following components (a) to (h).
(A) an A / D converter for converting the beat signal into a digital signal and outputting the digital beat signal;
(B) a weighting circuit for performing a weighting operation by a window function on the digital beat signal and outputting a weighted beat signal;
(C) a first Fourier transform circuit that Fourier-transforms the weighted beat signal and outputs a complex signal;
(D) a first amplitude calculation circuit that calculates an amplitude that is an absolute value of the complex signal and outputs an amplitude signal;
(E) The weighted beat signal is divided into the first half and the second half, and after inverting the phase of either one of the latter half or the first half, it is connected to the beat signal of the other half that does not invert the phase. An anti-phase processing circuit that outputs an anti-phase weighted beat signal in which one half is in anti-phase,
(F) a second Fourier transform circuit that Fourier transforms the antiphase weighted beat signal and outputs an antiphase complex signal;
(G) a second amplitude calculation circuit for calculating the amplitude of the negative-phase complex signal and outputting a negative-phase amplitude signal;
(H) When the coarse / coarse switching signal for switching between the coarse measurement mode and the fine measurement mode indicates the coarse measurement mode, detection processing by the amplitude detection of the amplitude signal is performed, and the fine / coarse switching signal is A null detection circuit that performs null point detection processing of the negative phase amplitude signal when detecting the measurement mode, detects the null point, and generates the target detection signal. The FMCW radar apparatus according to claim 2, wherein the signal processing unit includes the following components (a) to (ii).
(A) an A / D converter for converting the beat signal into a digital signal and outputting the digital beat signal;
(B) a weighting circuit for performing a weighting operation by a window function on the digital beat signal and outputting a weighted beat signal;
(C) a first Fourier transform circuit that Fourier-transforms the weighted beat signal and outputs a complex signal;
(D) a first amplitude calculation circuit that calculates an amplitude that is an absolute value of the complex signal and outputs an amplitude signal;
(E) the weighting beat signal coupled to half of those who do not phase inversion after inverting any one of the phase of the first half and these latter half portion is divided into a temporal first half and the second half portion halves A negative phase processing circuit that outputs a negative phase weighted beat signal in which one of
(F) a second Fourier transform circuit that Fourier transforms the antiphase weighted beat signal and outputs an antiphase complex signal;
(G) a second amplitude calculation circuit for calculating the amplitude of the negative-phase complex signal and outputting a negative-phase amplitude signal;
(H) When the fine / coarse switching signal for switching between the coarse measurement mode and the fine measurement mode indicates the coarse measurement mode, the amplitude signal is output as it is, and when the fine / coarse switching signal indicates the fine measurement mode. Is a division circuit that divides the amplitude signal by the negative-phase amplitude signal and outputs a divided amplitude signal;
(Li) A detection circuit that detects the amplitude of the amplitude signal or the divided amplitude signal and outputs the target detection signal. The FMCW radar apparatus according to claim 1, wherein the sensor unit includes the following components (a) to (f).
(A) a transmission antenna for transmitting the transmission signal;
(B) a receiving antenna that receives the reflected signal from the target and outputs a received signal;
(C) a modulator for generating a modulation signal of the triangular wave or sawtooth wave;
(D) a high-frequency oscillator that outputs an RF-modulated high-frequency signal whose oscillation frequency is controlled (frequency-modulated) by the modulation signal;
(E) a mixer that mixes the received signal and the high-frequency signal and outputs the beat signal;
(F) An amplifier for amplifying the beat signal.

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