JP6339446B2 - Detection device, detection method, and program - Google Patents

Description

  The present invention relates to a detection device, a detection method, and a program for transmitting a detection signal and receiving a reflected wave from an object.

  Conventionally, as a detection device, an ultrasonic detection device that transmits a detection signal of a sound wave in water and receives a reflected wave from an object such as a school of fish is known. In such an ultrasonic detector, an ultrasonic wave (interference signal) transmitted from another ship may be included in the received signal (see Patent Document 1).

  Therefore, the conventional ultrasonic detection device takes the amplitude ratio between the reception signal obtained by the latest transmission / reception operation and the reception signal obtained by the previous transmission / reception operation, and the amplitude ratio is equal to or larger than a predetermined value. It is determined that it is interference.

Japanese Patent No. 4017943

  However, in the conventional method, when the frequency of interference increases, interference removal cannot be performed sufficiently. For example, when an interference signal is received at the same timing in multiple transmission / reception operations, the amplitude ratio between the reception signal obtained in the latest transmission / reception operation and the reception signal obtained in the previous transmission / reception operation Therefore, it becomes difficult to determine that there is interference.

  Therefore, an object of the present invention is to provide a detection device, a detection method, and a program capable of appropriately removing the interference even when the frequency of interference increases.

  The detection device of the present invention includes a transducer that transmits a detection signal and receives a reflected wave from an object as a reception signal, and each target data in a data string for each detection direction of the reception signal. Sequentially, a threshold value calculation unit that calculates a threshold value based on amplitudes of a plurality of data adjacent to the target data, a threshold value calculated by the threshold value calculation unit in order for each target data, and an amplitude of the target data In comparison, an amplitude limiting unit that limits the amplitude of the target data when the amplitude of the target data exceeds the threshold value is provided.

  Thus, since the detection device of the present invention calculates a threshold value in a data string for each detection direction, even in the case where an interference signal is received at the same timing in a plurality of transmission / reception operations, Interference can be removed appropriately. Further, for example, in the case of performing amplification processing according to the detection distance (ie, performing TVG processing), when the interference signal is input at the same level in a short cycle, the distance from the object is compared with the level of the reflected wave from the object. Although the level of interference may increase, the detection device of the present invention calculates the threshold value using a plurality of adjacent data in order for each target data, and therefore, even when TVG processing is performed, interference is detected. Can be removed appropriately.

  Note that the threshold value may be calculated using a plurality of data before the target data (that is, the side closer to the own device) or a plurality of data after the time (the side far from the own device). It may be used. In addition, the threshold value may be calculated using a plurality of data that are temporally changed with respect to the target data.

  The threshold value may be calculated by any method, for example, based on the average value, median value, or mode value of the amplitude.

  Further, the threshold value calculation unit divides a plurality of data adjacent to the target data into a plurality of groups, with a predetermined number of continuous data as one group, and based on the amplitude value of the predetermined number of data in each group It is preferable to calculate a threshold value. For example, the threshold value calculation unit calculates an average value for each group, and sets the minimum value among these average values as the threshold value. As a result, even when the interference signal is input as a pulse having a very large amplitude in one detection direction, the threshold value does not become too large due to the influence of the interference signal, and the interference can be appropriately removed. .

  In addition, it is preferable that the time length of the plurality of data used for calculating the threshold is longer than the time width of the interference signal and shorter than the time width of the detection signal. Thereby, it is possible to appropriately remove only the interference signal without removing the echo reflected and received by the object.

  Moreover, it is preferable that the interference removing unit is disposed at a stage after the beam forming unit and at a stage before the filter unit. In general, the number of reception signals after beam formation (number of detection directions) is smaller than the number of reception signals before beam formation (number of ultrasonic transducers). Therefore, the amount of calculation can be reduced by arranging the interference removing unit at the subsequent stage of the beam forming unit. In addition, when pulse compression is performed in the filter unit when the time width of the interference signal is short, the interference signal is expanded in the time direction, so that the effect of interference removal may be reduced. Therefore, by disposing the interference removing unit in front of the filter unit, the interference signal is not expanded in the time direction, and the interference signal can be appropriately removed.

  In addition, the detection device preferably includes a quadrature detection unit that converts a received signal into a complex signal. In this case, the threshold value calculation unit calculates a threshold value based on the amplitude of the complex signal, and the amplitude limiter unit calculates the threshold value calculated based on the amplitude of the complex signal and the amplitude of target data in the complex signal. , And when the amplitude of the target data exceeds the threshold, the amplitude is limited while maintaining the phase of the complex signal. Thereby, it is possible to limit only the amplitude while maintaining the phase.

  Further, the detection method of the present invention includes a transmission / reception step of transmitting a detection signal and receiving a reflected wave from an object as a reception signal, and a data string for each detection direction of the reception signal. A threshold calculation step for calculating a threshold based on the amplitudes of a plurality of data adjacent to the target data in order for the target data, a threshold calculated in the threshold calculation step for each target data, and an amplitude of the target data, And an amplitude limiting step of limiting the amplitude of the target data when the amplitude of the target data exceeds the threshold value.

  Further, the program of the present invention includes a transmission / reception step for transmitting a detection signal and receiving a reflected wave from an object as a reception signal, and a data string for each detection direction in the reception signal. A threshold calculation step for calculating a threshold based on the amplitudes of a plurality of data close to the target data in order for the data, a threshold calculated in the threshold calculation step for each target data, and the amplitude of the target data In comparison, when the amplitude of the target data exceeds the threshold value, an amplitude limiting step of limiting the amplitude of the target data is executed by the detection device.

  According to the present invention, even when the frequency of interference increases, the interference can be appropriately removed.

FIG. 1A is a perspective view for explaining an underwater detection operation by a scanning sonar that is an example of the detection device of the present invention, and FIG. 1B is an external view of an ultrasonic transducer. It is a block diagram which shows the structure of a scanning sonar. It is a figure which shows an example of the image (detection image) displayed on a display. It is a figure for demonstrating the calculation method of a threshold value. It is a figure for demonstrating the application example of the calculation method of a threshold value. It is a figure which shows the effect of an interference removal process.

  FIG. 1A is a perspective view for explaining an underwater detection operation by a scanning sonar that is an example of the detection device of the present invention.

  The scanning sonar 1 is mounted on the ship. The transducer 10 of the scanning sonar 1 is installed on the bottom of the ship. The scanning sonar 1 is a device that detects underwater using ultrasonic waves. Ultrasonic waves are transmitted radially by a plurality of ultrasonic transducers 100 as shown in FIG. The ultrasonic waves transmitted into the water are reflected by an object such as a school of fish and received as reception signals by the plurality of ultrasonic transducers 100. As shown in FIG. 1A, the scanning sonar 1 combines the reception signals of the plurality of ultrasonic transducers 100 to form a beam 60 having directivity at a predetermined angle θ with respect to the horizontal plane. The scanning sonar 1 generates a plurality of beams 60 by switching a plurality of ultrasonic transducers 100 used for synthesis. Then, the scanning sonar 1 generates a video signal based on the amplitude of each beam 60 and displays an echo image on the display 30.

  A fish finder 2 is mounted on the ship. The transmitter / receiver of the fish finder 2 is installed on the bottom of the ship. The fish finder 2 is also an example of a detection device. The fish finder 2 transmits and receives ultrasonic waves directly under its own ship. The scanning sonar 1 and the fish finder 2 are arranged close to each other. Therefore, the ultrasonic wave radiated from the fish finder 2 is received by the scanning sonar 1 as an interference signal. Therefore, the scanning sonar 1 performs a process of removing an interference signal included in the received signal.

  FIG. 2A is a block diagram illustrating a configuration of the scanning sonar 1. The scanning sonar 1 includes a transducer 10, a transmission / reception switch 11, a transmission device 12, a reception device 20, and a display 30. FIG. 2B is a block diagram illustrating a configuration of the receiving device 20. The receiving device 20 includes an A / D conversion unit 13, a quadrature detection unit 14, a beam forming unit 15, an interference removal unit 16, a filter unit 17, and a video signal generation unit 18.

  For example, the transducer 10 includes a cylindrical casing 150 as shown in FIG. In the transducer 10, a plurality of ultrasonic transducers 100 are arranged in a predetermined pattern on the circumferential side surface of the cylindrical casing 150.

  The transmission device 12 outputs a pulsed transmission signal. The transmission signal is output to the transceiver 10 via the transmission / reception switch 11. The transducer 10 converts the input transmission signal into an ultrasonic pulse that is a detection signal, and radiates the ultrasonic pulse from a plurality of ultrasonic transducers 100 into the water. Each of the plurality of ultrasonic transducers 100 receives a reflected wave from an object as a reception signal.

  The transmission / reception switch 11 outputs the reception signals received by the plurality of ultrasonic transducers 100 in the transducer 10 to the A / D conversion unit 13 of the receiving device 20, respectively.

  The A / D conversion unit 13 converts the input analog reception signal into a digital reception signal at a predetermined sampling period, and outputs the digital reception signal to the quadrature detection unit 14.

  The quadrature detection unit 14 performs quadrature detection processing on the received signals received by the plurality of ultrasonic transducers 100, and extracts I signal components and Q signal components. These I signal component and Q signal component are obtained from N data strings I [0] + jQ [0], I [1] + jQ [1],..., I [N−1] + jQ [N−1]. Expressed as a complex signal. The absolute value of the complex signal corresponds to the amplitude of the received signal received by the plurality of ultrasonic transducers 100, and the deflection angle of the complex signal corresponds to the phase. The received signal converted into the complex signal is output to the beam forming unit 15.

  The beam forming unit 15 forms a beam having directivity in the predetermined detection direction by combining the reception signals received by the plurality of ultrasonic transducers 100 with respect to the predetermined detection direction. Further, the beam forming unit 15 can form beams in a plurality of detection directions by switching a plurality of ultrasonic transducers 100 used for synthesis.

  The received signal synthesized as a beam signal in each detection direction is input to the interference cancellation unit 16. The interference removal unit 16 performs a removal process of an interference signal included in the input reception signal in each detection direction. The received signal after the interference signal is removed is input to the filter unit 17.

  The filter unit 17 performs various filter processes on the input received signal. For example, the filter unit 17 performs a correlation operation between a reference signal (for example, a transmission signal) and a reception signal, and performs pulse compression of the reception signal. For example, the filter unit 17 performs band limitation on the received signal.

  The video signal generation unit 18 generates a video signal based on the received signal after the filtering process and outputs it to the display 30. For example, the video signal generation unit 18 generates a video signal having a gradation corresponding to the amplitude of the reception signal in each detection direction, and causes the display 30 to display an echo image. In addition, the video signal generation unit 18 performs a process of matching the number of received signal data with the number of display pixels of the display 30.

  In addition, the video signal generation unit 18 has a built-in memory (not shown) that temporarily stores a video signal obtained by one or more previous transmissions. Thereby, the video signal generation unit 18 can perform correlation processing between the past video signal and the current video signal. For example, the video signal generation unit 18 compares the video signals obtained at the time of two consecutive transmissions (current and previous), and selects and outputs the video signal having the lower level for each pixel. Thereby, an interference signal having a relatively high level can be removed without lowering the level of the echo image. However, the image correlation processing by the video signal generation unit 18 is not an essential configuration in the present invention.

  As described above, an image as shown in FIGS. 3A and 3B is displayed on the display 30. FIG. 3A and FIG. 3B are diagrams illustrating an example of an image (detected image) displayed on the display 30. The display 30 displays an echo image corresponding to the azimuth and distance around the position of the ship. In this example, a noise image corresponding to sea surface reflection is displayed around the ship. In addition, an image corresponding to screw noise is displayed behind the ship. In addition, an echo image of the school of fish is displayed on the upper right side of the screen.

  3A shows a detection image when the interference removing unit 16 does not perform interference removal (conventional configuration), and FIG. 3B shows a case where the interference removing unit 16 performs interference removal (this embodiment). It is a detection image of the configuration of the form.

  When the transducer of the fish finder 2 is installed close to the transducer 10 of the scanning sonar 1, the interference signal is periodically received corresponding to the transmission cycle of the fish finder 2. The In this example, since the transmission period of the scanning sonar 1 is longer than the transmission period of the fish finder 2, as shown in FIG. 3A, the interference signal is detected at every fixed distance in the detection image of the scanning sonar 1. A high-level interference image resulting from is displayed. The interference removal unit 16 removes the interference signal that appears at every certain distance.

  FIG. 2C is a block diagram illustrating a configuration of the interference removal unit 16. The interference removing unit 16 includes a threshold value calculating unit 161 and an amplitude limiting unit 162.

  A reception signal in each detection direction output from the beam forming unit 15 is input to the threshold calculation unit 161. The threshold calculation unit 161 calculates a threshold for determining whether or not there is interference based on the amplitude of the reception signal in each detection direction.

  FIG. 4A is a diagram for explaining a threshold value calculation method. The horizontal axis of the graph shown in FIG. 4A represents distance, and the vertical axis represents amplitude. The threshold calculation unit 161 receives a complex number I [0] + jQ [0], I [1] + jQ [1],..., I [N−1] + jQ of N data strings when a received signal in a certain detection direction is received. In the case of [N−1], the amplitude of each complex data, that is, the absolute value (r [0], r [1],..., R [N−1]) of each complex data is calculated. Then, the threshold value calculation unit 161 sequentially sets the threshold value Th for each complex data (hereinafter referred to as “target data”) based on the amplitudes of a plurality (M: M <N) of complex data immediately before the target data. Is calculated. That is, for the n + Mth target data, an average value of M pieces of amplitude data constituting the amplitude data string (r [n], r [n + 1],..., R [n + M−1]) is obtained. As the threshold Th, the average value may be used as it is, or may be a value obtained by multiplying the average value by a predetermined coefficient C (for example, C = 3). Or it is good also as an aspect which adds a predetermined constant to an average value, and it is good also as an aspect which adds a predetermined constant to the value which multiplied the average value and the predetermined coefficient. Moreover, the calculation method of threshold value Th is not restricted to an average value, For example, it is good also as an aspect calculated based on a median value or a mode value.

  The threshold value calculation unit 161 outputs the calculated threshold value Th of each target data to the amplitude limiting unit 162. The threshold value calculation unit 161 repeats such threshold value Th calculation processing while changing the value of n from 0 to NM. That is, the threshold value Th is calculated for the Mth to N−1th target data. A predetermined constant is output as the threshold Th for the 0th to M−1th target data.

  The amplitude limiter 162 receives the received signal in each detection direction output from the beam forming unit 15. Then, the amplitude limiter 162 compares the threshold value Th with the amplitude of the target data in order for each target data. When the amplitude (absolute value) Z of the target data exceeds the threshold Th, the amplitude limiter 162 limits the amplitude (absolute value) Z of the target data to the threshold Th or less. That is, the values of the I signal I [n + M] and the Q signal Q [n + M] for the n + Mth target data are replaced with Th / Z · I [n + M] and Th / Z · Q [n + M], respectively.

  As a result, the phase as a complex signal remains as it is, and only the amplitude (absolute value) is limited to the threshold value Th or less. Therefore, the interference removal unit 16 can remove the interference signal without affecting the pulse compression processing in the subsequent filter unit 17. Note that the interference removal unit 16 may be arranged at a subsequent stage of the filter unit 17. However, when the pulse width of the interference signal is shorter than the pulse width of the transmission signal, if the filter unit 17 performs pulse compression, the interference signal is expanded in the time direction, so that the interference removal effect may be reduced. is there. Therefore, it is preferable that the interference removal unit 16 is disposed in front of the filter unit 17. Further, the interference removal unit 16 may be arranged in front of the beam forming unit 15. However, in general, the number of reception signals after beam formation (number in the detection direction) is smaller than the number of reception signals before beam formation (the number of ultrasonic transducers 100). Therefore, it is preferable that the interference removing unit 16 is arranged at the subsequent stage of the beam forming unit 15. Thereby, the amount of calculation can be reduced.

  In this example, the threshold calculation unit 161 calculates the threshold from the M data immediately before the target data. For example, the M amplitude data string (r [n−1], r [ n],..., r [n + M−2]). Further, the threshold value need not be calculated using all of the M amplitude data strings. For example, out of eight amplitude data strings (r [n], r [n + 1],..., R [n + 7]), the amplitude data string (r [n], r [n + 2],..., r [n + 6]), that is, the threshold value may be calculated using four pieces of data.

  Further, for example, as shown in FIG. 4B, the threshold value may be calculated using M pieces of amplitude data of a plurality of data (on the side far from the own device) after the target data. Alternatively, as shown in FIG. 4C, a plurality of data before and after the target data may be used. In order to use data that is later in time than the target data, a memory that holds a reception signal in one transmission / reception operation is provided, and a threshold value is calculated in a state where the reception signal is held.

  The time length of the M pieces of data may be any length, but is preferably longer than the time width of the interference signal and shorter than the time width of the detection signal. That is, the time length of the M data is preferably longer than the pulse width of the transmission signal of the fish finder 2 and shorter than the pulse width of the transmission signal of the scanning sonar 1. If the time length of the M data is shorter than the pulse width of the transmission signal of the fish finder 2, the interference signal may not be removed. If the time length is longer than the pulse width of the transmission signal, the scanning sonar In some cases, even echoes from ultrasonic waves output from 1 are removed. Accordingly, the time length of the M data is longer than the pulse width of the transmission signal of the fish detector 2 and shorter than the pulse width of the transmission signal of the scanning sonar 1, so that it is reflected by the object such as the fish school and received. Interference can be appropriately removed without removing the echo that has been made.

  As described above, the scanning sonar 1 calculates the threshold values of a plurality of data adjacent to the target data in order for each target data in the data string for each detection direction in the received signal, for example, a plurality of times. Even when the interference signal is received at the same timing in the transmission / reception operation, only the interference signal can be appropriately removed.

  In addition, when performing a TVG process, if an interference signal having a short period is input at a similar level, the level of interference may increase as the distance increases as compared to the level of the reflected wave from the object. However, since the scanning sonar 1 calculates a threshold value using a plurality of adjacent data in order for each target data, only the interference signal can be appropriately removed even when TVG processing is performed.

  Next, FIG. 5A is a diagram for explaining an application example of the threshold value calculation method. The threshold value calculation unit 161 according to the application example divides M data (amplitude data string) immediately before the target data into a plurality of groups, with a predetermined number of continuous data as one group, and the amplitude ( The threshold value is calculated based on (absolute value). In this example, the threshold value calculation unit 161 has a first group of amplitude data strings (r [n], r [n + 1],..., R) each consisting of four pieces of data for the amplitude r [n + 12] of the target data. [N + 3]), the second group of amplitude data strings (r [n + 4], r [n + 5],..., R [n + 7]), and the third group of amplitude data strings (r [n + 8], r [n + 9]). ],..., R [n + 11]). Then, the threshold calculation unit 161 obtains the average value of the first group of amplitude data strings, the average value of the second group of amplitude data strings, and the average value of the third group of amplitude data strings. The threshold calculation unit 161 selects the minimum average value obtained for each group. Finally, the threshold value calculation unit 161 sets a value obtained by multiplying the selected minimum value by a predetermined coefficient C (for example, C = 3) as the threshold value Th. However, the minimum value may be adopted as a threshold as it is, may be a mode in which a predetermined constant is added to the minimum value, or a mode in which a predetermined constant is added to a value obtained by multiplying the minimum value by a predetermined coefficient. Also good. Moreover, in each group, it is good also as an aspect calculated based on not only an average value but a median value or mode value etc., for example.

  As a result, even when the interference signal is input with a very large amplitude in one detection direction, the interference removal unit 16 can appropriately remove the interference without the threshold value becoming too large. For example, when the target data is a part of the interference signal, the third group closest to the target data may include the interference signal, and the average value may increase. Even in this case, since the average value in the other group does not become too large, the finally calculated threshold value does not become too large.

  Even when the data is divided into a plurality of groups, for example, as shown in FIG. 5B, the M data after the target data (the far side from the own device) may be divided into a plurality of groups. Good. Alternatively, as shown in FIG. 5C, a plurality of data temporally before and after the target data may be used and divided into a plurality of groups. However, in the example of FIG. 5C, the target data r [n + 6] is excluded from the threshold calculation target in the data string of the second group.

  Further, in the above example, the threshold calculation unit 161 has shown an example in which the data used for threshold calculation is twelve, and is divided into three groups each consisting of four data. However, the data used for threshold calculation The number is not limited to this example, and the number of data constituting each group is not limited to four. For example, 24 data may be divided into 3 groups each consisting of 8 data. Further, the number of groups is not limited to three, and may be divided into two groups, or may be further divided into a large number (for example, five) groups. Furthermore, the criterion for selecting one from the average value of each group is not limited to the minimum value. For example, the median value may be selected from the average values of each group, or the second largest value among the average values of each group may be selected.

  Next, FIG. 6 is a diagram illustrating the effect of the interference removal processing. FIG. 6A is a graph showing a data string when TVG processing is performed without performing interference removal processing. FIG. 6A is a graph when TVG processing is performed after performing interference removal processing. It is a graph which shows a data sequence. In any graph, the horizontal axis represents distance, and the vertical axis represents amplitude (absolute value). The data strings shown in FIGS. 6 (A) and 6 (B) are the straight lines shown in FIGS. 3 (A) and 3 (B) (echo images of the school of fish displayed on the upper right side of the screen in the figure). Corresponds to the data string in the detection direction of the straight line passing through.

  As shown in FIGS. 6A and 6B, the interference removal processing of the interference removal unit 16 reduces the data level corresponding to the interference without reducing the data level corresponding to the echo of the school of fish. Can be made.

  In the present embodiment, the scanning sonar 1 is shown as the detection device, and the interference signal is the transmission signal of the fish finder 2. However, the interference removal unit 16 is not limited to the example provided in the scanning sonar 1. For example, when comparing a solid-state radar using a semiconductor element and a radar using a magnetron, the pulse width of the transmission signal of the radar using the magnetron is shorter than the pulse width of the transmission signal of the solid-state radar. Further, the amplitude of the transmission signal of the radar using the magnetron is larger than the amplitude of the transmission signal of the solid-state radar. Therefore, even in a solid-state radar that transmits an electromagnetic wave detection signal, it is possible to appropriately remove an interference signal from a radar using a magnetron by applying the interference removal processing of the interference removal unit 16 described in the present embodiment. Can do. Further, when a plurality of fish detector transducers are installed on the bottom of a ship, the interference removal processing of the interference removal unit 16 can be applied even when the transmission signals of each fish detector have different pulse widths. it can.

  The configuration of the interference removal unit 16 shown in the present embodiment is a software (program) executed by the detection device in a detection device that transmits a detection signal and receives a reflected wave from the object as a reception signal. Can also be realized.

DESCRIPTION OF SYMBOLS 1 ... Scanning sonar 2 ... Fish detector 10 ... Transmitter / receiver 11 ... Transmission / reception switch 12 ... Transmitter 13 ... A / D conversion part 14 ... Quadrature detection part 15 ... Beam forming part 16 ... Interference removal part 17 ... Filter part 18 ... Video signal generator 20 ... Receiver 30 ... Display device 60 ... Beam 100 ... Ultrasonic transducer 150 ... Housing 161 ... Threshold calculator 162 ... Amplitude limiter

Claims (10)

A transducer for receiving a detection signal transmitted radially, the reflected wave from the object at a certain timing,
A beam forming unit that generates a data sequence of received signals for each detection direction based on the reflected wave;
In one detection direction each data sequence of the received signal, and sequentially for each object data, a threshold calculation unit for calculating a threshold value based on the amplitude of a plurality of data in the data string to be close to the target data,
In order for each target data, the threshold value calculated by the threshold value calculation unit is compared with the amplitude of the target data, and when the amplitude of the target data exceeds the threshold value, the amplitude limit that limits the amplitude of the target data And
A detection device comprising: The detection device according to claim 1,
The threshold value calculation unit calculates the threshold value for each target data in turn based on amplitudes of a plurality of data temporally before the target data or a plurality of data temporally after the target data. Detecting device. The detection device according to claim 1,
The threshold value calculation unit calculates the threshold value for each target data in turn based on the amplitudes of a plurality of data temporally preceding and following the target data. The detection device according to any one of claims 1 to 3,
The threshold calculation unit, detection unit and calculates the threshold value based on the average value of the amplitude of a plurality of data proximate to the target data. The detection device according to any one of claims 1 to 4,
The threshold calculation unit divides a plurality of data close to the target data into a plurality of groups, with a predetermined number of continuous data as one group,
In each group, sounding apparatus and calculates the threshold value based on the amplitude value of a predetermined number of data. The detection device according to any one of claims 1 to 5,
The time length of the plurality of data used for the calculation of the threshold is longer than the time width of the interference signal and shorter than the time width of the detection signal. The detection device according to any one of claims 1 to 6,
And a filter unit that performs Jo Tokoro filtering,
The detection apparatus according to claim 1, wherein the threshold value calculation unit and the amplitude limiting unit are arranged in a stage subsequent to the beam forming unit and in front of the filter unit. The detection device according to any one of claims 1 to 7,
An orthogonal detector for converting the received signal into a complex signal;
The threshold calculation unit calculates the threshold based on the amplitude of the complex signal,
The amplitude limiter compares the threshold calculated based on the amplitude of the complex signal with the amplitude of the target data in the complex signal, and when the amplitude of the target data exceeds the threshold, A detection device that limits an amplitude while maintaining a phase of a complex signal. Transmits detection signals radially at a certain timing, receives reflected waves from the object,
Generate a data sequence of received signals for each detection direction based on the reflected wave,
In one detection direction each data sequence of the received signal, and sequentially for each object data, calculates a threshold value based on the amplitude of a plurality of data in the data string to be close to the target data,
Sequentially for each object data, a threshold which issued calculated and compared, the amplitude of the target data, when the amplitude of the target data is above the threshold, that limits the amplitude of the target data,
Detection wherein a call. Sends a detection signal to the radially at a certain timing, a process of receiving a reflected wave from the object,
Processing for generating a data string of received signals for each detection direction based on the reflected wave;
In one detection direction each data sequence of the received signal of the processing sequentially for each object data, calculates a threshold value based on the amplitude of a plurality of data in the data string to be close to the target data,
Sequentially for each object data, a threshold which issued calculated and compared, the amplitude of the target data, when the amplitude of the target data is above the threshold, the process of limiting the amplitude of the target data,
Is executed by a detection device.

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