JP2002372577A - Obstruction detector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an obstruction detector capable of accurately detecting the positions of a plurality of objects even when receiving reflected waves from a plurality of objects using a plurality of receivers. SOLUTION: This obstruction detector is provided with a transmitting part for transmitting radio wave to a detection area; receiving parts 23 for respectively receiving reflected wave from the objects; delay time computing parts 4, 5 for respectively detecting delay time of the reflected wave received by the respective receiving parts 2, 3, to the transmission wave; a distance-angle computing part 6 for detecting a distance from the respective receiving parts 2, 3 to the transmitting part 1 via the objects from the detected results of the delay time computing parts 4, 5 and obtaining the distance and angle to the objects from the transmitting part 1 on the basis of the distance and the position relation between the respective receiving parts 2, 3 and the transmitting part 1; and a combination determining part 7 for detecting a set of reflected waves reflected by the same object, out of a plurality of reflected waves when the respective receiving parts 2, 3 receive a plurality of reflected waves reflected by a plurality of objects, and outputting the detected result to the distance-angle computing part 6.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

TECHNICAL FIELD The present invention relates to an electromagnetic wave, an ultrasonic wave,
The present invention relates to an obstacle detection device that measures a distance and an angle to an object using a wave such as a laser beam.

[0002]

2. Description of the Related Art FIG.
As shown in FIG. 8, two transmitters 1a that transmit radio waves to a predetermined detection area and two transmitters that are arranged at equal intervals on both sides of the transmitter 1a and receive reflected waves by the radio waves transmitted from the transmitter 1a, respectively. 2. Description of the Related Art A radar apparatus that includes receivers 2a and 3a and detects a distance and an angle to an object X has been conventionally provided.

FIG. 17 is a schematic diagram showing the configuration of this radar apparatus. The transmitter 1 transmits a transmission wave W1 from a transmitter 1a, and the reception waves W2 and W3 received by the receivers 2a and 3a.
And a delay time calculation unit 4 for comparing the transmission wave W1 of the transmission unit 1 and the reception wave W2 of the reception unit 2 to obtain a delay time t1 of the reception wave W2 with respect to the transmission wave W1. And the transmission wave W1 of the transmission unit 1 and the reception unit 3
And a delay time calculating section 5 for calculating a delay time t2 of the received wave W3 with respect to the transmission wave W1 by comparing the received wave W3 with the received wave W3.
The distance / angle calculator 6 that calculates the distance and angle to the object X using t2 constitutes a radar device.

[0004] A method for obtaining the distance and angle from the transmitter 1a to the object X will be briefly described below. The object X is an ellipse D1 whose focus is on the positions of the transmitter 1a and the receiver 2a.
And an ellipse D2 whose focal point is the position of the transmitter 1a and the receiver 3a. The coordinates of the point on the ellipse D1 are (X ₁ , Y ₁ ), the coordinates of the point on the ellipse D2 are (X ₂ , Y ₂ ), and the distance from the transmitter 1a to the receiver 2a via the object X is L1, the receiver 3 from the transmitter 1a via the object X
a is L2, the transmitter 1a and each of the receivers 2a, 3a
If the distance between is set to d, the following relationship is established. However, the _{a = L 1/2, b} = L 2/2.

[0005] _{^{X 1 2 / a 2 + Y}} 1 2 / (a 2 -d 2) = 1 ... X 2 2 / b 2 + Y 2 2 / (b 2 -d 2) = 1 ... Here, from the transmitter 1a Assuming that the emitted radio waves are reflected by the object X and the reflected waves are received by the receivers 2a and 3a, the distances L1 and L2 are obtained, respectively, and the intersection of the ellipses D1 and D2 is obtained by using the above equation. That is, the coordinates of the object X can be obtained, and the distance and angle from the transmitter 1a to the object X can be obtained.

FIG. 19A is a waveform diagram of a transmission wave W1 emitted from the transmitter 1a, and FIGS. 19B and 19C are reception waves W2 and W received by the receivers 2a and 3a, respectively.
3 are respectively shown, and when the distance measuring method of this radar apparatus is a pulse method, each of the receivers 2a, 3a
Have the delay times t1 and t2 corresponding to the distances L1 and L2, respectively. Here, the delay times t1 and t2 are represented by the following equation, where C is the propagation speed of the radio wave.

T1 = L1 / C (that is, L1 = t1 × C) t2 = L2 / C (that is, L2 = t2 × C) Thus, in this radar device, the delay time calculation unit 4 uses the transmission unit 1 The delay time t1 of the reception wave W2 is obtained by comparing the wave W1 with the reception wave W2 of the reception unit 2, and the delay time calculation unit 5 compares the transmission wave W1 of the transmission unit 1 and the reception wave W3 of the reception unit 3 with each other. The delay time t2 of the received wave W3 is obtained by the comparison, and the distance / angle calculator 6 calculates the distance L using the formula from the measured values of the delay times t1 and t2.
The distance and the angle from the transmitter 1a to the object X are obtained by obtaining 1, L2, and further obtaining the position of the object X using the formula.

[0008]

By the way, in the above-mentioned radar apparatus, when a plurality of (for example, two) objects Xa and Xb exist in the detection area as shown in FIG.
As shown in FIG. 1, the received waveforms received by the receivers 2a and 3a include the received waves from the two objects Xa and Xb, respectively. That is, the reception waveform of the receiver 2a includes the reception waves W2a and W2b from the two objects Xa and Xb, and the reception waveform of the receiver 3a includes the reception waves W3b and W3a from the two objects Xa and Xb. I do. In the example shown in FIG. 21, the distance from the receiver 2a to the transmitter 1a via the object Xa is equal to the distance from the receiver 3a to the transmitter 1a via the object Xb, and Since the distance from the transmitter 3a to the transmitter 1a via the object Xa is equal to the distance from the receiver 2a to the transmitter 1a via the object Xb, the reception wave W by the objects Xa and Xb is equal.
The delay times of 2a and W3a are substantially the same time t1, and the delay times of the received waves W3b and W2b by the objects Xa and Xb are substantially the same time t2.

For this reason, the distance / angle calculating unit 6 determines whether the received wave W
2a and W3b are determined as reflected waves by the object Xa and the object X
a and the angle of the received wave W2b, W
If the distance and the angle of the object Xb are determined by judging 3a as the reflected wave of the object Xb, the positions of the objects Xa and Xb can be correctly determined, but the received waves W2a and W3a can be determined by the object Xa.
When the distance and the angle of the object Xa are detected by determining the reflected wave of the object Xa and the distance and the angle of the object Xb are determined by determining the received waves W2b and W3b as the reflected waves by the object Xb,
There is a problem that the positions of the objects Xa and Xb are erroneously detected as erroneous positions (positions indicated by dotted lines in FIG. 20).

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and has as its object the object of the present invention when receiving reflected waves from a plurality of objects using a plurality of receivers. An object of the present invention is to provide an obstacle detection device capable of accurately detecting a position.

[0011]

In order to achieve the above object, according to the first aspect of the present invention, there is provided a transmitting unit for transmitting a wave such as an electromagnetic wave, an ultrasonic wave, or a laser beam to a detection area; A plurality of receiving units each receiving the reflected wave, and a distance from each receiving unit to the transmitting unit via the object is detected based on a delay time of the reflected wave received by each receiving unit with respect to the transmitting wave, and the distance and each receiving unit are detected. Based on the positional relationship between the unit and the transmitting unit, a distance / angle detecting unit that detects a distance and an angle from the transmitting unit to the object, and whether each receiving unit has received a plurality of reflected waves reflected by a plurality of objects. If a plurality of reflected waves are detected, a set of reflected waves reflected by the same object is detected from among the plurality of reflected waves based on the characteristics of the waveform of each reflected wave. To output the distance to the angle / angle detector And a distance / angle detection unit, wherein the distance / angle detection unit detects a distance and an angle to each object from a set of reflected waves of the same object detected by the combination detection unit. Since the transmitted wave from the transmitting unit is reflected by a plurality of objects, respectively, the plurality of receiving units receive the plurality of reflected waves respectively, and the distance / angle calculating unit calculates the reflected wave reflected by the different objects. When the distance and the angle from the combination to the object are obtained, the distance and the angle to the object may be erroneously detected.However, the combination detecting unit detects the reflected wave reflected by the same object based on the characteristics of the waveform of the reflected wave. Since the combination is determined, and the distance / angle calculation unit obtains the distance and the angle to the plurality of objects based on the determination result, the position of each object can be accurately detected even when a plurality of objects exist. .

According to a second aspect of the present invention, in the first aspect of the present invention, the combination detecting section compares the amplitudes of a plurality of reflected waves received by each of the receiving sections, thereby detecting the reflected waves reflected by the same object. It is characterized by detecting pairs, and when the reflectances of a plurality of objects are different from each other, the amplitude of the reflected waves reflected by each object is different, so the combination detection unit compares the amplitudes of the plurality of reflected waves. By doing so, a set of reflected waves reflected by the same object can be reliably detected.

According to a third aspect of the present invention, in the first aspect of the present invention, the combination detecting section obtains a correlation value between a plurality of reflected waves received by each of the receiving sections, thereby obtaining a reflected light reflected by the same object. It is characterized by detecting a set of waves, and when the relative velocities of a plurality of objects and the transmitting unit are different from each other, the frequency of the reflected waves reflected by each of the objects changes due to the Doppler shift. By determining the correlation value of a plurality of reflected waves, a set of reflected waves reflected by the same object can be reliably detected.

According to a fourth aspect of the present invention, in the first aspect of the present invention, the combination detecting section detects a Doppler shift occurring at a frequency of each reflected wave according to a relative velocity between the plurality of objects. In addition to obtaining the current movement vector of the corresponding object, estimating the current movement vector of each object from the history of the positions and angles of the plurality of objects obtained by the distance / angle detection unit, and estimating the measured value of the movement vector The method is characterized by detecting a set of reflected waves reflected by the same object by comparing the values, and when the relative speeds of a plurality of objects and the transmission unit are different from each other, the reflected waves reflected by each object are different. Is changed by the Doppler shift, the movement vector of each object can be obtained by detecting the frequency change of each reflected wave. By comparing the motion vector with the result of estimating the motion vector of each object from the history of the position and angle of the object obtained by the distance / angle calculation unit, the set of reflected waves reflected by the same object is reliably detected. it can.

According to a fifth aspect of the present invention, in the first aspect of the present invention, the combination detecting section detects a Doppler shift occurring at a frequency of each reflected wave according to a relative velocity between the plurality of objects. While determining the current movement vector of the corresponding object, and estimating the movement speed and acceleration of each object from the history of the positions and angles of the plurality of objects determined by the distance / angle detection unit, the measured values of the movement vector and It is characterized by detecting a set of reflected waves reflected by the same object by comparing the estimated values of the moving speed and the acceleration, and when the relative velocities of the plurality of objects and the transmission unit are different, respectively, Since the frequency of the reflected wave reflected by the object changes due to the Doppler shift, it is possible to obtain the movement vector of each object by detecting the frequency change of each reflected wave. By comparing the movement vector obtained in this way with the result of estimating the movement speed and acceleration of each object from the history of the position and angle of the object obtained by the distance / angle calculation unit, reflection by the same object The set of reflected waves thus detected can be reliably detected.

According to a sixth aspect of the present invention, in the first aspect of the present invention, a measurement interval for changing a time interval for measuring the position of the object based on the data of the distance and the angle of the object obtained by the distance / angle detection unit. It is characterized in that a variable section is provided, and the measurement interval can be changed according to the distance and the angle between the object and the object.

According to a seventh aspect of the present invention, in the first aspect of the invention, the data of the distance and angle of the object obtained by the distance / angle detection unit, and the moving speed of the obstacle detection device itself input from the outside. A measurement interval variable unit that changes a time interval for measuring the position of the object based on the distance between the object and the object, and changes the measurement interval according to the own moving speed. be able to.

According to an eighth aspect of the present invention, in the first aspect of the present invention, the presence or absence of an interfering wave other than the reflected wave is detected from the reception waveform of the receiving unit. It is characterized by having provided a modulation variable section that changes at least one of the modulation speed, if there is an interfering wave, by changing at least one of the frequency of the transmission wave or its modulation speed, Interference with interference waves can be prevented.

[0019]

(Embodiment 1) Embodiment 1 of the present invention will be described with reference to FIG. In the radar device according to the present embodiment, in the radar device described in the conventional example, it is determined whether or not a plurality of reception waves (reflected waves) reflected by a plurality of objects exist in the reception waveforms of the reception units 2 and 3. However, if there are a plurality of received waves, the characteristics of the received waves received by the receiving units 2 and 3 and the distance / angle calculation unit 6 (distance / angle detection unit)
A combination determination unit 7 (combination detection unit) that detects a set of reception waves reflected by the same object from among a plurality of reception waves based on the history of calculation results of the above and outputs the detection result to the distance / angle calculation unit 6 ), And the distance / angle calculation unit 6 obtains the positions of one or more objects based on the detection result of the combination determination unit 7. Since the configuration other than the combination determination unit 7 is the same as that of the radar device described in the conventional example, the same components are denoted by the same reference numerals and description thereof will be omitted.

As described in the background art, the delay time calculation unit 4 includes a transmission wave W1 of the transmission unit 1 and a reception wave W2 of the reception unit 2.
Is compared with the delay time t1 of the received wave W2.
Seeking. Similarly, the delay time calculation unit 5 obtains the delay time t2 of the reception wave W3 by comparing the transmission wave W1 of the transmission unit 1 with the reception wave W3 of the reception unit 3.

Here, the calculation results of the delay time calculation units 4 and 5 are input to the combination determination unit 7, and when a plurality of calculation results are input from the delay time calculation units 4 and 5, A plurality of reception waves W2, W
3 is determined to exist (that is, it is determined that a plurality of objects exist in the detection area). When a plurality of reception waves W2 and W3 are present in the reception waveforms of the reception units 2 and 3, the combination determination unit 7 detects a set of reception waves W2 and W3 reflected by the same object based on characteristics of the reception waveform. , And outputs the detection result to the distance / angle calculator 6.

At this time, the distance / angle calculation unit 6 detects the distance from each of the receivers 2a and 3a to the transmitter 1a via the object from the set of reception waves reflected by the same object. The distance and angle from the transmitter 1a to this object are detected using the distance and the relative positional relationship between the transmitter 1a and the receivers 2a and 3a. , The positions of a plurality of objects (that is, the distances and angles from the transmitter 1a to each object) can be accurately detected.

As described above, when a plurality of reception waves W2 and W3 exist in the reception waveforms of the reception units 2 and 3 (when a plurality of objects exist), the combination determination unit 7 determines the characteristics of the reception waves W2 and W3. Of the received waves reflected by the same object from among the plurality of received waves based on the above, etc., and the distance / angle calculation unit 6 is reflected by the same object based on the detection result of the combination determination unit 7. Since the distance and angle from the received wave to this object are obtained, the distance and angle to each object can be accurately detected even when a plurality of objects exist.

(Embodiment 2) Embodiment 2 of the present invention is shown in FIG.
This will be described with reference to FIGS. FIG. 2 is a schematic configuration diagram of the radar device according to the present embodiment. In the present embodiment, a plurality of reception units 2 and 3 receive a plurality of reception signals instead of the combination determination unit 7 described in the first embodiment. An amplitude determining unit 7a is provided for detecting a set of reception waves reflected by the same object from among the plurality of reception waves W2 and W3 by comparing the amplitudes of the reception waves W2 and W3. Since the configuration other than the amplitude determination unit 7a is the same as that of the first embodiment, the same components are denoted by the same reference numerals and description thereof will be omitted.

A case where two objects Xa and Xb having different sizes and materials are detected by using the radar apparatus will be described with reference to FIG. The reflectances of the two objects Xa and Xb are different depending on the size and the material, and in this embodiment, the reflectance of the object Xb is higher than the reflectance of the object Xa. The two objects Xa and Xb are present at target positions around the X axis, the object Xa is located on the receiver 2a side with the X axis interposed therebetween, and the object Xb is located on the receiver 3a side with the X axis interposed therebetween. .

Therefore, as shown in FIGS. 4A to 4C, the receiver 2a receives the reception wave W2a reflected by the object Xa when the time t1 has elapsed after transmitting the transmission wave W1. Then, when the time t2 has elapsed, the reception wave W2b reflected by the object Xb is received. On the other hand, the receiver 3a receives the reception wave W3a reflected by the object Xb when the time t1 elapses after transmitting the transmission wave W1, and receives the reception wave W3a reflected by the object Xa when the time t2 elapses. W3b is received. Here, since the reflectance of the object Xb is sufficiently higher than the reflectance of the object Xa,
The received wave W2a, W3b by the object Xa is more than the object Xb
, The amplitudes of the received waves W2b and W3a are larger. Note that the distance from each of the receivers 2a and 3a to the transmitter 1a via the object Xa or Xb is such that the attenuation of the received wave due to the distance does not matter.
The amplitude of the received wave is determined by the reflectance of the two objects Xa and Xb.

In the case where the reflectances of the two objects Xa and Xb are different from each other, the amplitudes of the reception waves reflected by the respective objects Xa and Xb are different. , W3a,..., W3a,.
And the set of received waves W2b and W3a are determined to be received waves by the same object, and the result is output to the distance / angle calculation unit 6.

At this time, in the distance / angle calculating section 6, based on the detection result of the amplitude judging section 7a, a set of received waves reflected by the same object is transmitted from each of the receivers 2a and 3a via the object. 1a, and the distance and angle from the transmitter 1a to this object are detected using the distance and the relative positional relationship between the transmitter 1a and the receivers 2a, 3a. Is performed on all the objects, the positions of the plurality of objects (that is, the distances and angles from the transmitter 1a to each object) can be accurately detected.

As described above, when a plurality of reception waves W2a..., W3a... Exist in the reception waveforms of the reception units 2 and 3 (when a plurality of objects exist), the amplitude determination unit 7a sets each reception wave W2.
By comparing the amplitudes of a..., W3a..., a set of received waves reflected by the same object is detected from among the plurality of received waves. , The distance and angle from the received wave reflected by the same object to this object are obtained, so that even if there are a plurality of objects, the distance and angle to each object can be accurately detected.

(Embodiment 3) FIG. 5 shows Embodiment 3 of the present invention.
This will be described with reference to FIGS. FIG. 5 is a schematic configuration diagram of a radar device according to the present embodiment. In the present embodiment, a plurality of reception units 2 and 3 receive a plurality of reception signals instead of the combination determination unit 7 described in the first embodiment. Received waves W2a ..., W3a
.. To obtain a plurality of received waves W2a.
, W3a, etc., is provided with a correlation value determination unit 7b for detecting a set of reception waves reflected by the same object. Note that the configuration other than the correlation value determination unit 7b is the same as that of the first embodiment.
The same components are denoted by the same reference numerals, and description thereof will be omitted.

A case where two objects Xa and Xb having different moving directions and moving speeds are detected by using the radar apparatus will be described with reference to FIGS. Two objects Xa,
Since Xb has substantially the same reflectance, each object Xa,
, W3a... Reflected by Xb have substantially the same amplitude. The two objects Xa and Xb are X
The object Xa exists at a target position around the axis, the object Xa is on the receiver 2a side with the X axis interposed therebetween, and the object Xb is the receiver 3 with the X axis interposed therebetween.
It is located on the a side.

Therefore, as shown in FIGS. 7A to 7C, the receiver 2a receives the reception wave W2a reflected by the object Xa when the time t1 has elapsed after transmitting the transmission wave W1. Then, when the time t2 has elapsed, the reception wave W2b reflected by the object Xb is received. On the other hand, the receiver 3a receives the reception wave W3a reflected by the object Xb when the time t1 has elapsed after transmitting the transmission wave W1, and receives the reception wave W3a reflected by the object Xa when the time t2 has elapsed. W3b is received. Here, one object Xa moves in a direction approaching the radar device (transmitter 1a and receivers 2a, 3a), and the other object Xb moves in a direction away from the radar device, and is reflected by the object Xa. Received waves W2a and W3b and received wave W reflected by object Xb
A Doppler shift corresponding to the moving speed of each of the objects Xa and Xb occurs in 2b and W3a, and the frequency changes. That is, the frequencies of the reception waves W2a and W3b reflected by the object Xa become higher than the frequency of the transmission wave W1,
The frequencies of the received waves W2b and W3a reflected by b become lower than the frequency of the transmitted wave W1.

The correlation value judging section 7b obtains a correlation value between the waveforms of the reception waves W2a and W2b input from the reception section 2 and the waveforms of the reception waves W3a and W3b input from the reception section 3. The combination of the received waves having a high value (in this embodiment, the set of the received waves W2a and W3b and the set of the received waves W2b and W3a) is determined to be the received wave by the same object, and the result is output to the distance / angle calculation unit 6. .

At this time, the distance / angle calculator 6 detects the distance from each of the receivers 2a and 3a to the transmitter 1a via the object from the set of the received waves reflected by the same object. The distance and angle from the transmitter 1a to this object are detected using the distance and the relative positional relationship between the transmitter 1a and the receivers 2a and 3a. , The positions of a plurality of objects (that is, the distances and angles from the transmitter 1a to each object) can be accurately detected.

As described above, when a plurality of reception waves W2a..., W3a... Exist in the reception waveforms of the reception units 2 and 3 (when a plurality of objects exist), the correlation value determination unit 7b determines each reception wave W2.
By calculating the correlation values of 2a..., W3a..., A set of received waves reflected by the same object is detected from among a plurality of received waves. Since the distance and angle from the received wave reflected by the same object to this object are obtained based on the result, the distance and angle to each object can be accurately detected even when a plurality of objects exist.

(Embodiment 4) FIG. 8 shows Embodiment 4 of the present invention.
This will be described with reference to FIGS. FIG. 8 is a schematic configuration diagram of a radar device according to the present embodiment.
When a plurality of reception waves are received by each of the reception units 2 and 3 instead of the combination determination unit 7 described in the first embodiment, the objects obtained from the reception waves W2a. Is compared with the movement vector estimated from the history of the distance and angle detected by the distance / angle calculation unit 6, the speed history determination unit 7c that extracts the combination of the reception waves reflected by the same object is used. Provided. The configuration other than the speed history determination unit 7c is the same as that of the first embodiment.
The same components are denoted by the same reference numerals, and description thereof will be omitted.

A case in which a moving object Xa and a stationary object Xb are detected using this radar device will be described with reference to FIGS. One object Xa is obliquely moving in a direction approaching the radar device. In this radar device, measurement is performed at predetermined time intervals, and the position of the object Xa at the time of the previous measurement is indicated by a broken line in FIG. 10, and the current position is indicated by a solid line in FIG. FIG.
9 (a) shows the waveform of the transmission wave W1 transmitted from the transmitter 1a, and FIGS. 9 (b) and 9 (c) show the waveforms of the reception waves W2a ..., W3a ... received by the receivers 2a, 3a, respectively. .

When a plurality of objects are moving, a Doppler shift occurs according to the moving speed of each object, and the frequency of the reflected wave (received wave) changes. The moving speed of the object in the directions of the machines 2a and 3a can be detected. In the example shown in FIG. 9, one of the objects Xa is obliquely moving in a direction approaching the radar apparatus, and therefore, as shown in FIGS. 9B and 9C, the received waves W2a and W3b reflected by the object Xa Indicates that a Doppler shift occurs according to the moving speed of the object Xa, and the received waves W2a,
The frequency of W3b changes. Here, since the moving speed of the object Xa in the direction of the receiver 3a is faster than the moving speed of the object Xa in the direction of the receiver 2a, the moving speed of the object Xa is smaller than the frequency change occurring in the received wave W2a received by the receiver 2a. The frequency change occurring in the received wave W3b received by the receiver 3a is larger. Since the reflectances of the two objects Xa and Xb are substantially equal, the amplitudes of the received waves W2a... W3a reflected by the respective objects Xa and Xb are substantially equal.

.., W3a received by the receivers 2a, 3a from the receivers 2, 3, respectively.
Are input, and the history of the positions of the objects Xa and Xb (that is, the distances and angles to the objects Xa and Xb) and the estimated positions of the objects Xa and Xb at the time of the current measurement are input from the distance / angle calculator 6. Is done. Note that the objects Xa, X
As the estimated position of b, the position indicated by the solid line in FIG.
Position where objects Xa and Xb are aligned on the axis (see FIG. 20)
However, the following processing is performed assuming that the current positions of the objects Xa and Xb are the positions shown in FIG.

The speed history determination unit 7c obtains the moving speed of the object in the direction of each of the receivers 2a and 3a from the frequency change between the transmitted wave W1 and the received waves W2a..., W3a. Xa, the estimated position of Xa, and a plurality of received waves W2a,.
A plurality of movement vectors of the object Xa are estimated based on the combination of the movement speeds in the directions of the receivers 2a and 3a obtained from 3a. For example, V1 in FIG.
A moving vector estimated by combining the moving speed obtained from the received wave W3b with the moving speed obtained from the received wave W3b is represented by V in FIG.
2 is the moving speed obtained from the received wave W2a and the received wave W3a
A moving vector estimated by combining the moving speed (velocity 0) obtained from the above, V3 in the figure is a combination of the moving speed (velocity 0) obtained from the received wave W2b and the moving speed obtained from the received wave W3b. Each of the estimated motion vectors is shown.

Next, the speed history determination unit 7c estimates the movement vector of the object Xa from the position of the object Xa at the time of the previous measurement and the estimated position of the object Xa at the time of the current measurement. That is,
The speed history determination unit 7c determines that the object X
The distance traveled by a is determined, the distance is divided by the data update time (measurement interval) to determine the moving speed, and the movement vector is estimated.

The speed history determination unit 7c determines the distance
The moving vector of the object estimated from the history of the detection result of the angle calculating unit 6 is compared with a plurality of moving vectors estimated from the received waves W2a, W3a, and the directions and lengths (ie, moving speeds) of the vectors are close. By selecting one, a set of received waves reflected by the same object (a set of received waves W2a and W3b and a set of received waves W2b and W3a in this embodiment) is obtained. The speed history determination unit 7c determines that the object X
Assuming that the estimated positions of a and Xb are such that the objects Xa and Xb are arranged on the X axis, the same processing as described above is performed.
In this case, the movement vector of the object estimated from the history of the detection result of the distance / angle calculation unit 6 and the received waves W2a,.
Since a plurality of motion vectors estimated from a... do not coincide at all, it is determined that the estimated values of the objects Xa and Xb are incorrect.

At this time, in the distance / angle calculating section 6, based on the determination result of the speed history determining section 7 c, the receivers 2 a and 3 a pass through the objects from the set of the received waves reflected by the same object. The distance to the transmitter 1a is detected, and the distance and angle from the transmitter 1a to this object are detected using the distance and the relative positional relationship between the transmitter 1a and the receivers 2a and 3a. By performing the above-described processing for all objects, the positions of a plurality of objects (that is,
distance and angle from a to each object) can be accurately detected.

(Embodiment 5) FIG. 1 shows Embodiment 5 of the present invention.
This will be described with reference to FIGS. FIG. 11 is a schematic configuration diagram of a radar device according to the present embodiment. In the present embodiment, instead of the combination determining unit 7 described in the first embodiment, each of the receiving units 2 and 3 transmits a plurality of received waves. If received,
The movement vector of the object obtained from the reception waves W2a..., W3a... Of the reception units 2 and 3 is compared with the acceleration of the object obtained from the distance and angle history of the object detected by the distance / angle calculation unit 6. Accordingly, an acceleration history determination unit 7d for extracting a combination of the reception waves reflected by the same object is provided.
Since the configuration other than the acceleration history determination unit 7d is the same as that of the first embodiment, the same components are denoted by the same reference numerals and description thereof will be omitted.

A case in which a moving object Xa and a stationary object Xb are detected using this radar device will be described with reference to FIGS. One object Xa
Is moving obliquely in a direction approaching the radar device, and the position of the object Xa measured two times before is indicated by a dashed line, the position measured last time is indicated by a broken line, and the current position is indicated by a solid line. FIG. 12A shows a transmission wave W transmitted from the transmitter 1a.
12 (b) and (c) show the receivers 2a and 3
., W3a..., W3a.

When a plurality of objects are moving, a Doppler shift occurs according to the moving speed of each object, and the frequency of the reflected wave (received wave) changes. The moving speed of the object in the directions of the machines 2a and 3a can be detected. In the example shown in FIG. 13, one object Xa moves obliquely in a direction approaching the radar apparatus, and therefore, as shown in FIGS.
A Doppler shift corresponding to the moving speed of the object Xa occurs in the reception waves W2a and W3b reflected by the reception wave W2a and W3b.
The frequencies of a and W3b change. Here, since the moving speed of the object Xa in the direction of the receiver 3a is faster than the moving speed of the object Xa in the direction of the receiver 2a, the moving speed of the object Xa is smaller than the frequency change occurring in the received wave W2a received by the receiver 2a. Receiver 3
The frequency change occurring in the received wave W3b received by
It is getting bigger. Since the reflectances of the two objects Xa and Xb are substantially equal, the amplitudes of the received waves W2a... W3a reflected by the respective objects Xa and Xb are substantially equal.

Here, the acceleration history determination unit 7d includes the reception wave W2a received by the receivers 2a and 3a from the reception units 2 and 3.
, W3a ... are input, and the positions of the objects Xa, Xb (that is, the objects Xa, Xb
Distance and angle) and the object X at the time of this measurement.
The estimated positions of a and Xb are input. As the estimated positions of the objects Xa and Xb at the time of this measurement, there are a position indicated by a solid line in FIG. 13 and a position where the objects Xa and Xb are arranged on the X axis (see FIG. 20). Objects Xa, Xb
The following processing is performed assuming that the current position is the position shown in FIG.

The acceleration history determination unit 7d determines the moving speed of each object Xa, Xb in the direction of the receivers 2a, 3a from the frequency change between the transmitted wave W1 and the received waves W2a, W3a,. And a plurality of movement vectors of the object Xa are estimated based on a current estimated position of the object Xa and a combination of moving speeds in the directions of the receivers 2a and 3a obtained from the plurality of received waves W2a. . For example, V1 in FIG.
Is a moving vector estimated by combining the moving speed obtained from the received wave W2a and the moving speed obtained from the received wave W3b, and V2 in the figure is obtained from the moving speed obtained from the received wave W2a and the received wave W3a. V3 in the figure indicates the motion vector estimated by combining the moving speed obtained from the received wave W2b and the moving vector obtained by combining the moving speed obtained from the received wave W3b. .

The acceleration history determination unit 7d includes a distance
The history of the position of the object Xa detected by the angle calculation unit 6 and the current estimated position are input, and the object Xa at the time of the measurement two times before is input.
, The position of the object Xa at the previous measurement, and the estimated position of the object Xa at the current measurement, the distance that the object Xa has moved from the last measurement to the previous measurement, and the The distance traveled by the object Xa before the measurement can be obtained. By dividing these distances by the data update time (measurement interval), the velocity component of the object Xa at the previous measurement and the current measurement and the distance Is obtained. Then, in the acceleration history determination unit 7d, two-dimensional information of the velocity component and the acceleration component (the moving direction of the object Xa)
, An estimated value of the movement vector of the object Xa is obtained,
By comparing this estimated value with a plurality of motion vectors estimated from the received waves W2a, W3a,..., And selecting a vector having a similar direction and length (i.e., moving speed), the reception reflected by the same object is selected. A set of waves (in this embodiment, a set of received waves W2a and W3b and a set of received waves W2b and W3a) is extracted. In addition, the acceleration history determination unit 7d performs the same processing as described above, assuming that the estimated positions of the objects Xa and Xb are such that the objects Xa and Xb are arranged on the X axis. The movement vector of the object estimated from the history of the detection result of the angle calculation unit 6 and the reception waves W2a,.
Since the plurality of movement vectors estimated from W3a... Do not match at all, it is determined that the estimated values of the objects Xa and Xb are incorrect.

At this time, the distance / angle calculation unit 6 converts the set of reception waves reflected by the same object based on the detection result of the acceleration history determination unit 7d from the receivers 2a and 3a via the object. The distance to the transmitter 1a is detected, and the distance and angle from the transmitter 1a to this object are detected using the distance and the relative positional relationship between the transmitter 1a and the receivers 2a and 3a. By performing the above-described processing for all objects, the positions of a plurality of objects (that is, the distances and angles from the transmitter 1a to each object) can be accurately detected.

(Embodiment 6) Embodiment 6 of the present invention is shown in FIG.
This will be described with reference to FIG. In the present embodiment, in the radar device described in the first embodiment, the proximity determining unit 8 that obtains the degree of approach between the radar device and the object from the data of the distance and the angle to the object detected by the distance / angle calculating unit 6 And a pulse variable unit 9 for changing a transmission interval (that is, a data update interval) at which the transmission unit 1 transmits a transmission pulse (transmission wave W1) in accordance with the proximity detected by the proximity determination unit 8. Since the configuration other than the proximity determining unit 8 and the pulse varying unit 9 is the same as that of the first embodiment, the same components are denoted by the same reference numerals and description thereof will be omitted.

The proximity / degree calculation unit 8 includes a distance / angle calculation unit 6
Is input, and when the distance between the object closest to the radar device and the radar device becomes equal to or smaller than a predetermined threshold, the pulse variable unit 9 transmits the data of the transmission unit 1. The interval is shortened to increase the data update speed of the radar device. Therefore, when the object is at a short distance, by shortening the data update interval, abnormal approach of the object can be detected at an early stage, and occurrence of a collision accident or the like can be prevented before it occurs. Here, the proximity determination unit 8 and the pulse variable unit 9 constitute a measurement interval variable unit.

When the radar device is mounted on a moving object such as a car, as shown in FIG.
The moving speed V0 of the moving object may be input to the proximity determining unit 8, and the threshold may be changed according to the moving speed V0. If the moving speed V0 of the radar device itself is fast, the time from the detection of a stationary object to the collision with the stationary object becomes shorter. Therefore, if the moving speed V0 is faster than a predetermined threshold speed, the threshold is increased. By increasing the distance (threshold) for shortening the transmission interval of the transmission wave W1, the data update interval can be shortened in a state where the object is farther, and the abnormal approach of the object can be detected early. As a result, it is possible to prevent a collision accident from occurring.

In the present embodiment, the proximity determining section 8 and the pulse varying section 9 are provided in the radar apparatus described in the first embodiment. The degree determination unit 8 and the pulse variable unit 9 may be provided to shorten the data update interval according to the degree of approach of the object, and the same effect as described above can be obtained.
Further, in the present embodiment, when the distance between the object and the radar device becomes equal to or smaller than a predetermined threshold, the pulse variable unit 9 transmits the transmission wave W1.
Although the transmission interval is shortened, the transmission interval may be changed in any manner as long as the transmission interval is changed according to the distance between the object and the radar device.

(Embodiment 7) Embodiment 7 of the present invention is shown in FIG.
This will be described with reference to FIG. In the present embodiment, in the radar device described in the first embodiment, an interference wave determination unit 10 that determines whether an interference wave exists in the reception waveforms of the reception units 2 and 3.
When the interference wave determination unit 10 detects the presence of the interference wave, the modulation signal variable unit 11 that changes the frequency of the transmission wave W1 transmitted from the transmission unit 1 and the modulation speed thereof (the rate of changing the frequency of the transmission wave W1). Are provided. Here, the interference wave determination unit 10 and the modulation signal variable unit 11 constitute a modulation variable unit. Since the configuration other than the interference wave determination unit 10 and the modulation signal variable unit 11 is the same as that of the first embodiment, the same components are denoted by the same reference numerals and description thereof will be omitted.

The interference wave determination unit 10 includes the reception waves of the reception units 2 and 3, the delay times t 1 and t 2 obtained by the delay time calculation units 4 and 5, and the distance obtained by the distance / angle calculation unit 6. And data such as the history of the angle and the history of the combination determined by the combination determination unit 7. From these data, it is determined whether or not abnormal data is periodically generated. Is periodically generated, it is determined that an interfering wave is present, and a detection signal is output to the modulation signal varying unit 11.

The modulation signal variable section 11 includes an interference wave determination section 10
When the detection signal is input from the transmission unit 1, the transmission frequency and the modulation speed of the transmission wave W1 transmitted from the transmission unit 1 are changed, and interference with the interfering wave is avoided, and the reception wave W2
, W3a ... can be reliably detected. When a plurality of objects are detected, there are a plurality of received waves W2a ..., W3a ... reflected by the plurality of objects, respectively.
Although the probability of collision with another interfering wave increases, in the present embodiment, when the presence of the interfering wave is detected, the transmission frequency of the transmitting wave W1 or at least one of its modulation speeds is changed to change the interfering wave. Interference is avoided so that multiple objects can be detected accurately.

In this embodiment, the interfering wave determination section 10 and the modulation signal variable section 11 are provided in the radar apparatus described in the first embodiment. However, in the radar apparatus described in the second to fifth embodiments, An interfering wave determination unit 10 and a modulation signal variable unit 11 are provided.
1 and the modulation speed thereof may be changed, and the same effect as described above can be obtained.

In each of the above embodiments, the radar device has been described as an example. However, the present invention is not intended to limit the obstacle detection device to the above-described radar device. It goes without saying that the present invention may be applied to those using electromagnetic waves or those using a method other than the pulse method as the distance measuring method.

[0060]

As described above, according to the first aspect of the present invention, there is provided a transmitter for transmitting a wave such as an electromagnetic wave, an ultrasonic wave, or a laser beam at a predetermined time interval, and reflection of the wave by one or more objects. A plurality of receiving units that respectively receive the waves, and each receiving unit detects whether or not each of the receiving units has received a plurality of reflected waves reflected by a plurality of objects. A combination detector that determines a combination of reflected waves reflected by the same object from among a plurality of reflected waves based on the characteristics of the reflected waves, and a plurality of reflected by the same object based on the determination result of the combination detector. From the reflected waves, determine the distance from each receiving unit to the transmitting unit via the object,
A distance / angle calculation unit for calculating a distance and an angle from the transmission unit to each object by using the distance and the relative positional relationship between each reception unit and the transmission unit; If there is, the transmission wave from the transmission unit is reflected by a plurality of objects, respectively, so that the plurality of reception units receive the plurality of reflected waves, respectively, and the distance / angle calculation unit is reflected by different objects. When the distance and the angle to the object are obtained from the combination of the reflected waves, there is a possibility that the distance and the angle to the object may be erroneously detected. The combination of waves is determined, and the distance / angle calculation unit calculates the distance and angle to multiple objects based on the determination result, so that even if there are multiple objects, the position of each object can be accurately detected. it can.

According to a second aspect of the present invention, in the first aspect of the present invention, the combination detecting section compares the amplitudes of a plurality of reflected waves received by each of the receiving sections to determine the amplitude of the reflected waves reflected by the same object. It is characterized by detecting pairs, and when the reflectances of a plurality of objects are different from each other, the amplitude of the reflected waves reflected by each object is different, so the combination detection unit compares the amplitudes of the plurality of reflected waves. By doing so, a set of reflected waves reflected by the same object can be reliably detected.

According to a third aspect of the present invention, in the first aspect of the present invention, the combination detecting section obtains a correlation value between a plurality of reflected waves received by each receiving section, thereby obtaining a reflected light reflected by the same object. It is characterized by detecting a set of waves, and when the relative speeds of the plurality of objects and the transmission unit are different,
Since the frequency of the reflected waves reflected by each object changes due to the Doppler shift, the combination detector reliably detects the set of reflected waves reflected by the same object by calculating the correlation value of multiple reflected waves. it can.

According to a fourth aspect of the present invention, in the first aspect of the present invention, the combination detecting section detects a Doppler shift occurring at a frequency of each reflected wave according to a relative speed between the plurality of objects. In addition to obtaining the current movement vector of the corresponding object, estimating the current movement vector of each object from the history of the positions and angles of the plurality of objects obtained by the distance / angle calculation unit, and estimating the measured value of the movement vector The method is characterized by detecting a set of reflected waves reflected by the same object by comparing the values, and when the relative speeds of a plurality of objects and the transmission unit are different from each other, the reflected waves reflected by each object are different. Is changed by the Doppler shift, the movement vector of each object can be obtained by detecting the change in the frequency of each reflected wave. By comparing the vector and the result of estimating the movement vector of each object from the history of the position and angle of the object obtained by the distance / angle calculation unit, the set of reflected waves reflected by the same object can be reliably detected. .

According to a fifth aspect of the present invention, in the first aspect of the present invention, the combination detecting section detects a Doppler shift generated at a frequency of each reflected wave according to a relative speed between a plurality of objects. While determining the current movement vector of the corresponding object, estimating the movement speed and acceleration of each object from the history of the positions and angles of the plurality of objects determined by the distance / angle calculation unit, It is characterized by detecting a set of reflected waves reflected by the same object by comparing the estimated values of the moving speed and the acceleration, and when the relative velocities of the plurality of objects and the transmission unit are different, respectively, Since the frequency of the reflected wave reflected by the object changes due to the Doppler shift, the movement vector of each object can be obtained by detecting the frequency change of each reflected wave. By comparing the movement vector obtained in this manner with the estimated values of the moving speed and acceleration of each object from the history of the position and angle of the object obtained by the distance / angle calculation unit, the reflected light was reflected by the same object. The set of reflected waves can be reliably detected.

According to a sixth aspect of the present invention, in the first aspect of the present invention, the measurement interval for changing the time interval for measuring the position of the object based on the data of the distance and the angle of the object obtained by the distance / angle calculation unit. It is characterized in that a variable section is provided, and the measurement interval can be changed according to the distance and the angle between the object and the object.

According to a seventh aspect of the present invention, in the first aspect of the present invention, the data of the distance and the angle of the object obtained by the distance / angle calculation unit and the moving speed of the obstacle detection device itself input from the outside. A measurement interval variable unit that changes a time interval for measuring the position of the object based on the distance between the object and the angle, and can change the measurement interval according to the moving speed. it can.

According to an eighth aspect of the present invention, in the first aspect of the present invention, the presence or absence of an interfering wave other than the reflected wave is detected from the reception waveform of the receiving section. It is characterized by having provided a modulation variable section that changes at least one of the modulation speed, if there is an interfering wave, by changing at least one of the frequency of the transmission wave or its modulation speed, Interference with interference waves can be prevented.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram of a radar device according to a first embodiment.

FIG. 2 is a schematic configuration diagram of a radar device according to a second embodiment.

FIG. 3 is an explanatory diagram illustrating a state in which the distance and the angle between two objects are detected by using the above radar device.

FIG. 4 is a waveform diagram of each part of the radar device according to the first embodiment;
(A) is a waveform diagram showing a transmission wave of the transmitter 1a, (b)
(C) is a waveform diagram showing the reception waves of the receivers 2a and 3a.

FIG. 5 is a schematic configuration diagram of a radar device according to a third embodiment.

FIG. 6 is an explanatory diagram illustrating a state in which the distance and the angle between two objects are detected using the radar device of the above.

FIG. 7 shows a waveform diagram of each part of the radar device,
(A) is a waveform diagram showing a transmission wave of the transmitter 1a, (b)
(C) is a waveform diagram showing the reception waves of the receivers 2a and 3a.

FIG. 8 is a schematic configuration diagram of a radar device according to a fourth embodiment.

FIG. 9 shows a waveform diagram of each part of the radar device of the above,
(A) is a waveform diagram showing a transmission wave of the transmitter 1a, (b)
(C) is a waveform diagram showing the reception waves of the receivers 2a and 3a.

FIG. 10 is an explanatory diagram illustrating a state in which a distance and an angle between two objects are detected by using the above radar device.

FIG. 11 is a schematic configuration diagram of a radar device according to a fifth embodiment.

FIG. 12 shows a waveform diagram of each part of the radar device,
(A) is a waveform diagram showing a transmission wave of the transmitter 1a, (b)
(C) is a waveform diagram showing the reception waves of the receivers 2a and 3a.

FIG. 13 is an explanatory diagram illustrating a state in which the distance and the angle between two objects are detected by using the above radar device.

FIG. 14 is a schematic configuration diagram of a radar device according to a sixth embodiment.

FIG. 15 is a schematic configuration diagram of another radar device of the above.

FIG. 16 is a schematic configuration diagram of a radar device according to a seventh embodiment.

FIG. 17 is a schematic configuration diagram of a conventional radar device.

FIG. 18 is an explanatory diagram illustrating a state in which a distance and an angle of one object are detected by using the above radar device.

FIG. 19 shows a waveform diagram of each part of the radar device of the above,
(A) is a waveform diagram showing a transmission wave of the transmitter 1a, (b)
(C) is a waveform diagram showing the reception waves of the receivers 2a and 3a.

FIG. 20 is an explanatory diagram illustrating a state in which the distance and the angle between two objects are detected by using the above radar device.

FIG. 21 is a waveform diagram of each part of the radar device,
(A) is a waveform diagram showing a transmission wave of the transmitter 1a, (b)
(C) is a waveform diagram showing the reception waves of the receivers 2a and 3a.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Transmitting unit 2, 3 Receiving unit 4, 5 Delay time calculating unit 6 Distance / angle calculating unit 7 Combination judging unit

Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat II (Reference) G01S 13/93 G01S 13/93 Z 15/93 15/93 (72) Inventor Satoshi Hirata 1048 Odakadoma, Oazadomo, Kadoma City, Osaka Prefecture Matsushita Electric Works Co., Ltd. AA02 AB13 AC11 AC28 AD04 AD15 AD19 BA01 BE08 CA02 5J084 AA02 AA05 AA07 AA09 AD01 BA02 BA32 BA38 CA03 CA68 EA04 EA22 EA24

Claims (8)

[Claims] 1. A transmitting section for transmitting a wave such as an electromagnetic wave, an ultrasonic wave, or a laser beam to a detection area, a plurality of receiving sections for respectively receiving reflected waves of the wave by an object, and reflections received by each receiving section. The distance from each receiving unit to the transmitting unit via the object is detected from the delay time of the wave with respect to the transmitted wave, and the distance from the transmitting unit to the object is determined based on this distance and the positional relationship between each receiving unit and the transmitting unit. And a distance / angle detecting unit for detecting an angle and an angle, and detecting whether each receiving unit has received a plurality of reflected waves reflected by a plurality of objects, and detecting each reflected wave when detecting a plurality of reflected waves. A combination detector that detects a set of reflected waves reflected by the same object from among a plurality of reflected waves based on the characteristics of the waveform of the reflected wave and outputs the detection result to a distance / angle detector. The detection unit detects the combination detected by the combination detection unit. From the set of the reflected wave by the object, the obstacle detection device and detects the distance and angle to each object. 2. The combination detecting section according to claim 1, wherein a pair of reflected waves reflected by the same object is detected by comparing the amplitudes of a plurality of reflected waves received by each receiving section. An obstacle detection device as described in the above. 3. The combination detecting section detects a set of reflected waves reflected by the same object by calculating a correlation value between a plurality of reflected waves received by each receiving section. Item 2. The obstacle detection device according to Item 1. 4. The combination detecting section detects a Doppler shift occurring at a frequency of each reflected wave according to a relative velocity between the plurality of objects, thereby obtaining a current movement vector of a corresponding object. Estimating the current movement vector of each object from the history of the position and angle of the plurality of objects determined by the distance / angle detection unit, reflected by the same object by comparing the measured value and estimated value of the movement vector The obstacle detecting device according to claim 1, wherein a set of reflected waves is detected. 5. The combination detecting section detects a Doppler shift occurring at a frequency of each reflected wave according to a relative speed between a plurality of objects, thereby obtaining a current movement vector of a corresponding object. Estimating the moving speed and acceleration of each object from the history of the positions and angles of the plurality of objects obtained by the distance / angle detecting unit, and comparing the measured value of the moving vector with the estimated value of the moving speed and acceleration. 2. The obstacle detecting device according to claim 1, wherein a set of reflected waves reflected by the same object is detected by the following. 6. A measurement interval variable unit for changing a time interval for measuring a position of an object based on data of the distance and angle of the object obtained by the distance / angle detection unit. 2. The obstacle detection device according to claim 1. 7. A time interval for measuring the position of the object based on the data of the distance and angle of the object obtained by the distance / angle detection unit and the moving speed of the obstacle detection device itself input from the outside. 2. The obstacle detection device according to claim 1, further comprising a measurement interval variable unit for changing the distance. 8. A modulation unit for detecting presence or absence of an interference wave other than the reflected wave from a reception waveform of a reception unit and, if an interference wave is present, changing at least one of a frequency of a transmission wave and a modulation speed thereof. The obstacle detection device according to claim 1, further comprising a variable unit.