JP2018197697A - Radio wave sensor - Google Patents

Abstract

To efficiently detect existence and distance of a changing object or the like excellently in a short calculation time without requiring a high-speed CPU or a large memory.SOLUTION: A beat signal (mixer output waveform) obtained in first frequency sweep is stored to a memory, and a differential beat signal is obtained by subtracting the beat signal in the first sweep from a beat signal obtained in, for example, a second sweep. The differential beat signal emphasizes only frequency and amplitude components that have been changed between the first sweep and the second sweep. By performing FFT calculation of the waveforms of the differential beat signal and converting it into frequency spectrum, the existence of a mobile object and its distance are measured without performing FFT calculation in the respective beat signals.SELECTED DRAWING: Figure 1

Description

  The present invention is a radio wave sensor, in particular, a radio wave sensor that transmits a modulated wave in a microwave band and a millimeter wave band and detects the presence, distance, etc. of the object by comparing the transmitted wave and the received wave reflected from the object. It relates to signal processing.

  As a radio wave type sensor using a microwave or the like, for example, a Doppler sensor that detects a Doppler frequency, a two-frequency Doppler sensor that uses two Doppler sensors with different transmission frequencies, and a linear change in the transmission frequency over a certain period of time An FMCW sensor or the like that measures a distance from a frequency of a difference between a transmission wave and a reception wave to a stationary body is known. In this radio wave sensor, the use of a frequency band such as 10.5 GHz and 24 GHz as a sensor requiring no license is permitted.

  The Doppler sensor transmits, for example, a continuous wave having a constant frequency, detects a Doppler frequency indicating a difference between the transmitted wave and a reflected wave from an object, and detects a target moving body using the Doppler frequency signal. Or measure its speed. Since this Doppler sensor can detect only a moving object, it has an advantage that only a moving object can be detected even in a place where there are many stationary objects such as indoors, but the distance cannot be measured.

  The two-frequency Doppler sensor uses two Doppler sensors with different transmission frequencies and measures the distance of the moving body from the phase difference between the two Doppler frequency outputs, and has the advantage that the distance of the moving body can be measured. However, in order to obtain a Doppler frequency output, at least the object needs to move a distance longer than the wavelength of the transmission wave, and it is difficult to measure minute movements. In addition, when the movement is slow, the Doppler frequency is low, so a long measurement time is required, and there is a high possibility that an inaccurate measurement result will be obtained. Furthermore, it is often difficult to reduce current consumption due to intermittent operation or the like.

  Further, the FMCW sensor (FMCW sensor) continuously raises or lowers the transmission frequency by a predetermined modulation width by sweeping, and receives the reflected wave reflected by the obstacle ahead of the transmission wave. The distance from the difference between the transmission frequency and the reception frequency obtained by mixing the received wave and the transmitted wave to the stationary object can be measured, but in environments with many stationary objects, such as indoors, stationary objects within the antenna directivity range Since all are observed, the distance of the object to be detected cannot be identified. In addition, since the separation resolution of the distance is limited to the sweep frequency width, in the case of the 10.5 GHz band or the 24 GHz band permitted to be used by the radio wave sensor, the transmission bandwidth can be used only 50 MHz or a maximum of 200 MHz. The person standing in front of has a disadvantage that it is masked by the reflected wave from the wall and cannot be detected.

In object detection, there is a demand to detect moving objects such as people and cars in an environment with many obstacles such as walls and telephone poles for the purpose of monitoring, etc., and to grasp the distance. It was difficult for sensors to meet this requirement.
On the other hand, as one of the solutions to the above problem, as shown in Patent Documents 1 and 2, the FMCW sensor is used to perform the FFT operation on the mixer output signal obtained by one sweep. Proposals have been made to obtain a frequency spectrum (frequency-amplitude information), compare the frequency spectrum obtained by the first sweep with the frequency spectrum obtained by the second sweep, and distinguish between the moving body and the stationary body.

Japanese Patent No. 3575334 Japanese Patent No. 4613711 JP 2009-145282 A

  However, in the FMCW sensor that has been conventionally proposed, the FFT operation for obtaining the frequency spectrum (frequency-amplitude information) is performed once for each of the output waveforms of the first and second sweeps. In order to obtain the above result, the FFT operation is performed twice, so that the calculation process takes time, a lot of memory is required, and a high-speed CPU and a device with a large memory capacity must be prepared. is there.

  In addition, since the frequency resolution obtained by the FFT operation is limited in frequency resolution by the order of the FFT operation, it is necessary to increase the order of the FFT in order to capture minute movements. There is a problem that the sensor is required to be increased in size and expensive.

  The present invention has been made in view of the above problems, and its purpose is to efficiently detect the presence and distance of an object having a change in a short calculation time without requiring a high-speed CPU and a large memory. An object of the present invention is to provide a radio wave sensor that can detect well.

In order to achieve the above object, the invention of claim 1 transmits a modulated wave that is swept in a predetermined modulation width and period, and whose oscillation frequency continuously rises or falls, and this transmitted wave exists in the front. Radio wave sensor equipped with a transmission / reception circuit that receives a reflected wave generated by reflection from a moving object and outputs a beat signal (mixer output waveform) having a frequency difference between the two waves by mixing the transmitted wave and the received wave The beat signal of the transmission wave and the reception wave obtained by the first sweep is stored, and the beat signal and the beat signal of the transmission wave and the reception wave obtained by the second sweep are subtracted. A difference beat signal is obtained, and a change in an object is detected using frequency spectrum information obtained by performing an FFT operation on the difference beat signal.
The invention of claim 2 is characterized in that a distance to an object having changed is obtained from the frequency spectrum information.
The invention according to claim 3 obtains a differential beat signal by subtracting beat signals obtained by the first sweep and the second sweep having the same frequency gradient, and performs an FFT operation on the differential beat signal to obtain frequency spectrum information. It is characterized by obtaining.

The invention according to claim 4 outputs a first beat signal obtained by sweeping with a gradient whose frequency rises or falls and a second beat signal obtained by sweeping with a frequency gradient opposite to the first beat signal. Then, after inverting one of the first beat signal and the second beat signal in time, a difference beat signal is obtained by subtraction of both beat signals, and frequency spectrum information is obtained by performing an FFT operation on the difference beat signal. It is characterized by that.
The invention of claim 5 sets a distance range to be reported or a distance range not to be reported for the distance information obtained by the frequency spectrum information, and an object in a range other than the distance range to be reported or in a distance range not to be reported Is not detected.
The invention of claim 6 is the distance information of the moving body of the frequency spectrum obtained from the differential beat signal based on the first sweep and the second sweep, and the frequency spectrum of the beat signal obtained only by the first sweep. The distance information of objects is compared, and the distance of only a stationary object is detected.

  According to the above configuration, a modulation wave that continuously increases or decreases in frequency with a predetermined modulation width and period is sequentially transmitted from the transmission circuit by the frequency sweep, and the beat signal (mixer output analog) obtained by the first sweep is transmitted. Waveform) is stored in the memory, and when a beat signal is obtained based on the second sweep, the beat signal from the second sweep and the beat signal from the first sweep (the amplitudes at the same time from the start of the sweep) Subtraction (subtraction) is performed to obtain a differential beat signal. Then, by converting the waveform of the differential beat signal into a frequency spectrum by FFT (Fast Fourier Transform) calculation, the presence of an object, particularly a moving object, and its distance are measured.

That is, in the subtraction process, if the beat signal obtained by the second sweep contains the same frequency and amplitude component as those contained in the beat signal obtained by the first sweep, it is attenuated. Only the frequency and amplitude components that have changed between the first sweep and the second sweep are emphasized. When the differential beat signal is subjected to an FFT operation, the frequency at which the amplitude shows a peak in the frequency spectrum (frequency-amplitude information) becomes information proportional to the distance to the object (moving body) that has changed. Existence and distance are extracted.
Even when a plurality of objects move, if the distances are different, a plurality of frequency spectrum peaks can be obtained. Therefore, it is possible to obtain the distances of the plurality of moving bodies by separating them.

  According to the present invention, since the number of FFT computations may be small, a distance can be measured efficiently in a short computation time without requiring a high-speed CPU or a large memory, and there are many reflectors such as indoors. Even in a space, there is an advantage that the distance to a changing object can be measured well.

  Furthermore, the moving body obtained with the frequency spectrum of the differential beat signal by the second sweep (first and second) from the waveform of the object (stationary body, etc.) obtained with the frequency spectrum of the beat signal by one sweep. By removing the waveform, there is an advantage that information on only a stationary object can be obtained accurately.

It is a block diagram which shows the circuit structure of the radio wave type sensor of the Example which concerns on this invention. It is a wave form diagram which shows the signal formed by the frequency sweep and transmission / reception in an Example. It is a figure which shows the frequency sweep [figure (a)] of an Example, and the beat signal waveform [figure (b)] obtained by sweep. It is a flowchart figure which shows one example (sweep of the same frequency gradient) of the process by the radio wave type sensor of an Example. It is a flowchart figure which shows the other example (sweep of a reverse direction frequency gradient) in the process by the electromagnetic wave type sensor of an Example. It is a wave form diagram which shows the up sweep used in an Example, and a down sweep. It is a wave form diagram for demonstrating the beat signal and frequency spectrum when there is no moving body obtained by the sweep of the same frequency gradient of an Example. It is a wave form diagram for demonstrating the beat signal and frequency spectrum when there is no moving body obtained by the sweep of the reverse frequency gradient of an Example. It is a wave form diagram which shows a frequency spectrum when there exists a moving body in an Example. It is a wave form diagram which shows a frequency spectrum of a beat signal obtained by one sweep of an example [figure (a)], and a wave form diagram which shows a frequency spectrum of a difference beat signal obtained by two sweeps.

FIG. 1 shows a circuit configuration of a radio wave sensor according to the embodiment. This radio wave sensor is an FMCW sensor using a microwave.
As shown in FIG. 1, in the FMCW sensor of the embodiment, a transmission unit (circuit) 1 that transmits a modulated wave in which the oscillation frequency continuously increases or decreases by frequency sweep, and a reflected wave from an object (target object). Receiving unit 2 for mixing the transmission wave and the receiving wave, mixer 3 for outputting the beat signal (mixer output waveform), memory 4 for storing the output of mixer 3, and subtracting unit for calculating the difference between the beat signals 5. FFT processing unit 6 that calculates a frequency spectrum (frequency-amplitude information) from the waveform of the differential beat signal that is the output of the subtracting unit 5, and a measuring unit 7 that measures the presence and distance of stationary and moving objects from the frequency spectrum. Is included.

First, when the microwave modulated based on the frequency sweep is transmitted from the transmission unit 1, the reception unit 2 receives the reflected wave from the object, and the mixer 3 mixes both the waves to obtain the difference frequency. A beat signal is obtained.
FIG. 2 shows the waveform of each signal such as frequency sweep and transmission wave, and FIG. 3 shows the beat signal obtained by each sweep. As shown in FIG. In the frequency sweep, a sweep of a predetermined period (time) t ₁ is performed in the frequency band of the frequencies f _{1 to} f ₂ (down sweeping in the figure is a downward sweep). Then, as shown in FIG. 2B, the transmission wave of the modulated wave formed by the sweep is transmitted from the transmission unit 1, and the reception unit 2 obtains the transmission wave by reflecting from the object. The received wave (echo wave) shown in FIG. 2C is received. This received wave arrives with a slight delay according to the distance to the object, and there is a time delay of t = 2R / c (R: distance to the object, c: speed of light) with respect to the transmitted wave. .

  Further, the mixer 3 mixes the reception wave of FIG. 2C and the transmission wave of FIG. 2B, thereby outputting a beat signal shown in FIG. That is, as described above, since the reception wave is delayed compared to the transmission wave, a beat signal (mixer output waveform) having a frequency difference between the two waves is obtained.

  As shown in FIG. 3A, the transmission wave is continuously transmitted by sweeping at a predetermined interval (for example, up sweep), so that the beat signal is transmitted from the mixer 3 as shown in FIG. Output sequentially. Since the frequency of the beat signal varies depending on the sweep time, the sweep frequency band (occupied bandwidth), and the distance to the object, the distance can be obtained by analyzing this frequency.

FIG. 4 shows the processing when the same frequency gradient is swept in the embodiment. As shown in FIG. 4, in the embodiment, the beat signal (waveform) is first obtained by the first (previous) sweep. The beat signal waveform is stored in the memory 4 (step 102). Next, a beat signal (waveform) is acquired by the second (this time) sweep (step 103), and thereafter, for example, a beat signal based on the first sweep is subtracted from the beat signal based on the second sweep by the subtracting unit 5. The difference beat signal is obtained by subtracting (or subtracting the beat signal from the second sweep from the beat signal from the first sweep) (step 104). This differential beat signal (waveform) is a signal (waveform) of a difference between beat signals obtained by the first (or previous) and second (or current) sweeps, and two sweeps are 1 It is sequentially performed as a unit for obtaining one measurement result.
Next, the differential beat signal output from the subtraction unit 5 is converted into a frequency spectrum by performing an FFT operation (FFT operation unit 6) (step 105), and the distance from the peak frequency to the object is measured (step). 106).

FIG. 5 shows the processing when the frequency gradient is swept in the reverse direction in the embodiment, and FIG. 6 shows the up sweep and the down sweep used in this case.
As shown in FIG. 6, not only when the same frequency gradient is used as the sweep performed continuously, but only the down sweep in which the frequency decreases as described above or only the up sweep in which the frequency increases, as shown in FIG. Both up sweep and down sweep can be formed and used. When using sweeps of the same frequency gradient, it is only necessary to obtain the difference, but when using both up sweep and down sweep, the slope is reversed, so one of the voltage waveforms is timed. It is necessary to obtain the difference after inversion.

  In the example of FIG. 5, for example, when the up sweep is performed at the first time in step 201, the second sweep of step 203 uses a down sweep that is a reverse frequency gradient (up sweep when the first time is a down sweep). The waveform of the beat signal obtained by the above is acquired. In step 204, the beat signal waveform based on the first sweep stored in the memory 4 is time-reversed. In step 205, for example, the beat signal (waveform) by the first sweep that is time-reversed by the subtracting unit 5 is used. Is subtracted from the beat signal (waveform) obtained by the second sweep, and the frequency spectrum is calculated from the differential beat signal output from the subtracting unit 5.

  FIG. 7 shows a processing waveform when there is no moving body obtained by sweeping with the same frequency gradient. In the embodiment, as shown in FIG. 7A, each beat by up sweep 1 and up sweep 2 is shown. A signal waveform is obtained. Here, the frequency spectrum by the beat signals of sweep 1 and sweep 2 is as shown in FIG. 7B, but in the embodiment, the waveform of the differential beat signal as shown in FIG. 7C is output (subtracted). 7) and performing the FFT operation, the frequency spectrum of FIG. 7D is obtained. As shown in FIG. 7 (d), when there is no moving body, the signal intensity at each frequency is almost zero.

  FIG. 8 shows a processing waveform when there is no moving body obtained by sweeping the frequency gradient in the reverse direction. In this case, the waveform of the beat signal by the up sweep 1 is shown in FIG. On the other hand, the waveform of the beat signal by the down sweep 1 is obtained in a time-reversed relationship. Then, the waveform of the differential beat signal as shown in FIG. 8B is output (output of the subtracting unit 5), and the frequency spectrum shown in FIG. 8C is obtained by performing the FFT operation. Also in this case, as shown in FIG. 8C, when there is no moving body, the signal intensity at each frequency is almost zero.

  FIG. 9 shows the frequency spectrum when there is a moving body. FIG. 9A shows the frequency spectrum obtained by the up sweep 1 beat signal and the up sweep 2 beat signal by a solid line and a chain line. As shown in FIG. 9B, the frequency spectrum of the differential beat signal obtained based on the up sweep 1 and the up sweep 2 is as shown in FIG. Appears (frequency corresponds to distance).

  FIG. 10 shows an example of a frequency spectrum (frequency-amplitude) for showing the effect of the embodiment. FIG. 10A shows the frequency spectrum of a beat signal obtained by one sweep (stationary object observation). FIG. 10B shows the frequency spectrum of the differential beat signal (for moving object observation). As shown in FIG. 10A, when there are a plurality of reflectors, a plurality of peaks indicating the object, for example, 1 to 4 are observed accordingly, and each distance is measured from the frequency indicating the peak value. . In such a situation, when two objects are close to each other like the peaks 1 and 2, the peak 2 having a low reflection level is masked by the large peak 1 and stands, for example, in front of a wall in a room or the like. In some cases, people cannot be separated and cannot be detected. Further, a peak (object) 4 or the like smaller than the set threshold cannot be observed, and only a stationary object is detected in this case.

On the other hand, in the present invention, the beat signal obtained by the first sweep is stored as a voltage waveform, a differential beat signal waveform which is a difference from the voltage waveform of the beat signal of the second sweep is obtained, and this difference is obtained. The distance of the moving body is detected by converting the beat signal waveform into a frequency spectrum by FFT calculation.
For example, as shown in FIG. 10B, according to the frequency spectrum (frequency-amplitude information) obtained in the embodiment, the moving object is detected as a peak 4 with a clear value. The distance of the moving body is measured from the frequency.

  In the conventional FMCW sensor, as described above, at least two FFT operations are performed until one result is obtained, and a high-speed CPU capability and sufficient memory are required. Since the differential beat signal from two sweeps is used, only one FFT operation is required, the processing is light, the result can be obtained at high speed, and the CPU computing capacity and memory capacity can be reduced. .

In the embodiment, as shown in FIG. 10B, the distance information of the moving body of the frequency spectrum obtained from the differential beat signal based on the first sweep and the second sweep, as shown in FIG. The distance information of the object of the frequency spectrum of the beat signal obtained by only one sweep is compared, and the distance of only the stationary object is also detected, thereby clearly distinguishing the moving object from the stationary object. It becomes possible to detect.
For example, if the object of peak 2 detected in FIG. 10 (a) is detected as indicated by the chain line in FIG. 10 (b) and is known to be a moving body, it is certain that the stationary body has peaks 1 and 3. Can be determined.

  Furthermore, in the embodiment, it is also possible to issue a warning (warning, etc.) in response to detection of a moving object. (Distance range not to be reported), and it is possible to improve the efficiency and simplification of the measurement by not detecting an object outside this distance range (or the distance range not to be reported). .

1 ... transmission unit, 2 ... reception unit,
3 ... mixer, 4 ... memory,
5 ... subtraction unit, 6 ... FFT operation unit,
7: Measuring unit.

Claims (6)

A modulated wave that is swept by a predetermined modulation width and period and transmits a modulated wave in which the oscillation frequency continuously rises or falls continuously is received, and a reflected wave that is generated when the transmitted wave is reflected by an object existing ahead is received, In a radio wave sensor equipped with a transmission / reception circuit that outputs a beat signal having a frequency difference between both waves by mixing a transmission wave and a reception wave,
The beat signal of the transmission wave and reception wave obtained by the first sweep is stored, and the difference beat is obtained by subtraction between the beat signal and the beat signal of the transmission wave and reception wave obtained by the second sweep. A radio wave sensor characterized by detecting a change in an object using frequency spectrum information obtained by obtaining a signal and performing an FFT operation on the differential beat signal.   2. The radio wave sensor according to claim 1, wherein a distance to an object having changed is obtained from the frequency spectrum information.   A difference beat signal is obtained by subtraction of beat signals obtained by the first sweep and the second sweep having the same frequency gradient, and frequency spectrum information is obtained by performing an FFT operation on the difference beat signal. The radio wave sensor according to claim 1 or 2.   A first beat signal obtained by a sweep having a gradient in which the frequency increases or decreases and a second beat signal obtained by a sweep having a frequency gradient opposite to the first beat signal are output, and the first beat signal is output. The frequency spectrum information is obtained by obtaining a differential beat signal by subtracting both beat signals after temporally inverting one of the second beat signals and performing an FFT operation on the differential beat signal. The radio wave sensor according to 1 or 2.   A distance range to be reported or a distance range not to be reported is set for the distance information obtained from the frequency spectrum information, and an object in a range other than the distance range to be reported or not to be detected is not detected. The radio wave sensor according to any one of claims 1 to 4. The distance information of the moving body of the frequency spectrum obtained from the differential beat signal based on the first sweep and the second sweep is compared with the distance information of the object of the frequency spectrum of the beat signal obtained only by the first sweep. The radio wave sensor according to claim 1, wherein the distance of only a stationary body is detected.

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