WO2012020530A1 - レーダイメージング装置、イメージング方法及びそのプログラム - Google Patents
レーダイメージング装置、イメージング方法及びそのプログラム Download PDFInfo
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- WO2012020530A1 WO2012020530A1 PCT/JP2011/003657 JP2011003657W WO2012020530A1 WO 2012020530 A1 WO2012020530 A1 WO 2012020530A1 JP 2011003657 W JP2011003657 W JP 2011003657W WO 2012020530 A1 WO2012020530 A1 WO 2012020530A1
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S13/00—Systems using the reflection or reradiation of radio waves, e.g. radar systems; Analogous systems using reflection or reradiation of waves whose nature or wavelength is irrelevant or unspecified
- G01S13/02—Systems using reflection of radio waves, e.g. primary radar systems; Analogous systems
- G01S13/06—Systems determining position data of a target
- G01S13/08—Systems for measuring distance only
- G01S13/10—Systems for measuring distance only using transmission of interrupted, pulse modulated waves
- G01S13/26—Systems for measuring distance only using transmission of interrupted, pulse modulated waves wherein the transmitted pulses use a frequency- or phase-modulated carrier wave
- G01S13/28—Systems for measuring distance only using transmission of interrupted, pulse modulated waves wherein the transmitted pulses use a frequency- or phase-modulated carrier wave with time compression of received pulses
- G01S13/284—Systems for measuring distance only using transmission of interrupted, pulse modulated waves wherein the transmitted pulses use a frequency- or phase-modulated carrier wave with time compression of received pulses using coded pulses
- G01S13/288—Systems for measuring distance only using transmission of interrupted, pulse modulated waves wherein the transmitted pulses use a frequency- or phase-modulated carrier wave with time compression of received pulses using coded pulses phase modulated
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S13/00—Systems using the reflection or reradiation of radio waves, e.g. radar systems; Analogous systems using reflection or reradiation of waves whose nature or wavelength is irrelevant or unspecified
- G01S13/02—Systems using reflection of radio waves, e.g. primary radar systems; Analogous systems
- G01S13/50—Systems of measurement based on relative movement of target
- G01S13/58—Velocity or trajectory determination systems; Sense-of-movement determination systems
- G01S13/64—Velocity measuring systems using range gates
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S13/00—Systems using the reflection or reradiation of radio waves, e.g. radar systems; Analogous systems using reflection or reradiation of waves whose nature or wavelength is irrelevant or unspecified
- G01S13/88—Radar or analogous systems specially adapted for specific applications
- G01S13/89—Radar or analogous systems specially adapted for specific applications for mapping or imaging
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S3/00—Direction-finders for determining the direction from which infrasonic, sonic, ultrasonic, or electromagnetic waves, or particle emission, not having a directional significance, are being received
- G01S3/02—Direction-finders for determining the direction from which infrasonic, sonic, ultrasonic, or electromagnetic waves, or particle emission, not having a directional significance, are being received using radio waves
- G01S3/14—Systems for determining direction or deviation from predetermined direction
- G01S3/46—Systems for determining direction or deviation from predetermined direction using antennas spaced apart and measuring phase or time difference between signals therefrom, i.e. path-difference systems
- G01S3/48—Systems for determining direction or deviation from predetermined direction using antennas spaced apart and measuring phase or time difference between signals therefrom, i.e. path-difference systems the waves arriving at the antennas being continuous or intermittent and the phase difference of signals derived therefrom being measured
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- G—PHYSICS
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- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S7/00—Details of systems according to groups G01S13/00, G01S15/00, G01S17/00
- G01S7/02—Details of systems according to groups G01S13/00, G01S15/00, G01S17/00 of systems according to group G01S13/00
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- G01S7/285—Receivers
- G01S7/288—Coherent receivers
- G01S7/2886—Coherent receivers using I/Q processing
Definitions
- the present invention relates to a radar imaging apparatus, an imaging method, and the like that detect a transmission signal by radiating a transmission signal and receiving a reflected wave of the transmission signal reflected from a target object.
- a phased array radar system obtains information on the shape of an object by scanning by changing the phase of a large number of receivers (transmitters) and controlling the directivity and direction of radio waves.
- the imaging using such a radar has a problem that the system becomes large or the system becomes complicated, resulting in an expensive system.
- DDOA Doppler arrival direction estimation method
- FIG. 16 shows the configuration of a conventional radar apparatus.
- the radar apparatus 901 shown in FIG. 16 includes a transmitter 910, receivers 920 and 930, a transmission antenna 911, and reception antennas 912 and 913.
- the radar apparatus 901 sets the targets 931 to 933 as detection targets.
- the radar apparatus 901 emits a detection radio wave having a certain frequency from the transmitter 910, and receives radio waves reflected from the targets 931 to 933 by the receivers 920 and 930.
- the frequency of the reflected wave received by the receivers 920 and 930 is relative to the frequency of the detection radio wave radiated from the transmitting antenna 911.
- the frequency is shifted by the frequency corresponding to the visual line direction speed.
- the line-of-sight direction speed of each of the targets 931 to 933 can be detected from the shifted frequency.
- the “line-of-sight speed” is a speed component along the direction from the radar device 901 to the target among the speeds of the targets 931 to 933.
- it refers to the relative velocity components of the targets 931 to 933 with respect to the radar device 901.
- the line-of-sight speed of the targets 931 to 933 is the speed from the radar device 901 to the targets 931 to 933.
- V1f, V2f, and Vif are the speeds decomposed along the direction.
- the radar apparatus 901 detects the visual line direction velocities V1f, V2f, and Vif of the targets 931 to 933 from the frequencies of the reflected waves received by the receivers 920 and 930 with respect to the frequency of the detection radio wave.
- the radar apparatus 901 there are two receiving systems including a receiving antenna and a receiver corresponding to the receiving antenna. Further, the respective receiving antennas 912 and 913 are arranged at different locations.
- the distance from each target 931 to 933 to the receiving antenna 912 and the distance from the target 931 to 933 to the receiving antenna 913 are different from each other.
- the direction of the targets 931 to 933 can be detected.
- the principle of direction detection will be specifically described.
- the target 933 is located closer to the receiving antenna 913 than the receiving antenna 912, so that the reflected wave from the target 933 arrives at the receiving antenna 913 earlier than the receiving antenna 912.
- the phase of the reflected wave received by the receiving antenna 912 is delayed from the phase of the reflected wave received by the receiving antenna 913.
- the target 933 is in the direction of ⁇ i from the front of the reception antenna 912 and the reception antenna 913 and the two reception antennas 912 and 913 are arranged at a distance d, the reflected wave received by the reception antenna 912 is reflected.
- phase difference between the reflected wave received by the receiving antenna 913 is expressed by Equation 1. Note that the phase of the reflected wave received by the receiving antenna 912 is ⁇ 1, the phase of the reflected wave received by the receiving antenna 913 is ⁇ 2, and the wavelength of the detection radio wave emitted from the transmitting antenna 911 is ⁇ .
- Equation 1 By transforming Equation 1, the following Equation 2 is obtained, and the direction ⁇ of the target 933 can be detected from the phase difference ⁇ 2- ⁇ 1 of the reflected waves received by the two receiving antennas 912 and 913.
- DOA direction-of-arrival
- the conventional radar apparatus 901 shown in FIG. 16 detects both the phase and the Doppler frequency, thereby enabling identification of a plurality of targets and detecting the direction and speed of each target. be able to.
- the radar apparatus 901 has two receiving antennas 912 and 913 and can detect only one-dimensional direction. For example, in addition to a straight line including the receiving antenna 912 and the receiving antenna 913, another receiving antenna is provided. By arranging, horizontal / vertical two-dimensional directions can be detected.
- Such a radar device 901 can detect a human body by utilizing, for example, each movement of a human body differently for human body detection. Specifically, since the head, hand, and leg move at different speeds relative to the torso, it is possible to detect the human body from the direction and speed.
- the conventional non-patent document 1 has a problem that DOA becomes unstable when the Doppler frequency is close. This is because the radar apparatus identifies each object at the Doppler frequency, so that an object moving at the same line-of-sight speed relative to the radar apparatus cannot be identified as a different object. Therefore, the direction of arrival cannot be identified. In other words, it is necessary that all objects within the irradiation range of the detection radio wave have different Doppler frequencies, that is, move at different gaze direction velocities.
- the conventional radar apparatus is affected by it and cannot detect the target.
- the conventional radar apparatus has a configuration that is weak against interference of other systems.
- the resolution of the Doppler frequency is determined according to the reciprocal of the analysis time, it takes a long time to analyze the Doppler frequency when detecting a target for each search range. Thereby, there exists a subject that processing time becomes long. As the processing time becomes longer in this way, the direction of the moving target may not be detected.
- Patent Document 1 Even if the configuration of Patent Document 1 is applied to a configuration for detecting the Doppler frequency, it takes a long time to analyze the Doppler frequency in the same manner, so that the processing time becomes long. That is, the direction of the moving target may not be detected.
- An object of the present invention is to solve the above-mentioned conventional problems, and to provide a radar imaging apparatus and an imaging method capable of improving the function of detecting the direction of a moving target by shortening the processing time.
- a radar imaging apparatus includes a transmission unit that generates a transmission signal by spreading a carrier wave using a transmission spreading code, a transmission antenna that radiates the transmission signal as a radiated wave, and the radiated wave includes A plurality of receiving antennas that receive reflected waves reflected by an object and the transmission within a scanning period for scanning N (N is an integer of 2 or more) search ranges having different distances from the radar imaging apparatus.
- a delay code generator that repeats scanning processing for sequentially generating N delay codes corresponding to the distance and having the same code as the spreading code over an M (M is an integer of 2 or more) scanning period; and the plurality of receptions A plurality of despreading units respectively corresponding to the antennas, each despreading a reflected wave received by the corresponding receiving antenna using the N delay codes in sequence, and A detection signal Rij corresponding to the reflected wave received by the corresponding receiving antenna by orthogonally detecting the reflected wave despread by the corresponding despreading unit using the carrier wave, each corresponding to the spreading unit.
- each of the plurality of detectors is associated with a delay time and a scanning period in the delay code generator.
- a Doppler frequency component and a phase and intensity corresponding to the Doppler frequency component are detected corresponding to each of the plurality of detection units, and each of the detected plurality of detection units corresponds to the detected Doppler frequency component.
- a direction estimating unit that calculates a phase difference between the plurality of detection units from the phase, and detects an arrival direction of the reflected wave in each search range from the calculated phase difference.
- the detection signal Rij which is the result of sweeping a plurality of delay times, is stored in the storage unit.
- the radar imaging apparatus performs Doppler frequency discrimination processing on the detection signals Ri1 to RiM having the same distance from the radar imaging apparatus.
- the radar imaging apparatus compares the detection signal Rij with a simple configuration in which the Doppler frequency is discriminated without going through the storage unit, and the delay time setting is changed each time the processing is completed. The time required for sweeping the distance range can be shortened while obtaining the resolution of the Doppler frequency discrimination process. Therefore, the radar imaging apparatus can improve the function of estimating the direction of the moving target.
- the radar imaging apparatus is a detection range in which the distance from the radar imaging apparatus is an area that is not less than k (k is an integer of 0 or more) times and not more than k + 1 times the distance determined by the code speed of the spreading code. It is possible to process the detection signal Rij corresponding to the reflected wave for each search range defined as Therefore, even if an object having the same gaze direction velocity exists outside the search range, the radar imaging apparatus is not affected by the reflected wave from the object, and the frequency of the reflected wave from the detection range. Can be discriminated. That is, when there is an object moving in the detection range, the radar imaging apparatus reflects a reflected wave from the object in the detection range even if an object having the same gaze direction velocity exists outside the detection range.
- the Doppler frequency that is the difference frequency between the carrier wave and the carrier wave can be detected.
- the radar imaging apparatus uses a code-modulated signal as a transmission signal, it is possible to identify the signal generated by the code even if there is an influence of radio waves emitted from other radar systems. It is. That is, the radar imaging apparatus can reduce the influence of other radar systems. As a result, the possibility that the DOA becomes indefinite due to the influence of an object having a close Doppler frequency or interference from another system is greatly reduced, so that the radar imaging apparatus can detect the direction of the object with a simple configuration in a short time.
- the direction estimation unit may estimate the arrival direction of the reflected wave including the Doppler frequency component whose intensity detected by the Doppler frequency detection unit is equal to or greater than a predetermined first threshold as the direction of the object.
- the radar imaging apparatus can estimate the direction of the object. Specifically, the radar imaging apparatus uses the phase difference between the receiving antennas and the physical distance between the receiving antennas for the Doppler frequency at which the intensity is equal to or greater than a predetermined first threshold, to determine the direction of the object. I can know.
- the distance in the search range where the Doppler frequency component in which the intensity detected by the Doppler frequency detection unit is equal to or greater than the predetermined first threshold is detected is estimated as the distance from the radar imaging apparatus to the object.
- a distance estimation unit may be provided.
- a signal received by the receiving antenna is generated by a delay code generation unit and despread with a delay code having a predetermined delay time with respect to the transmission spread code. Therefore, only when the round-trip delay time when the signal is radiated from the transmitting antenna and then reflected by the object and propagates to the receiving antenna matches the delay time of the delay code, it corresponds to the line-of-sight speed of the object.
- the carrier wave subjected to the Doppler frequency shift is reproduced.
- the Doppler frequency detection unit outputs a Doppler frequency corresponding to the line-of-sight movement speed.
- the Doppler frequency detector Hardly contributes. Therefore, when any of the Doppler frequencies of the Doppler frequency detection unit has an intensity equal to or higher than the predetermined first threshold value in a certain delay time, it is determined that the object exists at a distance where the electromagnetic wave travels in half the delay time. be able to.
- the direction estimation unit further includes a line-of-sight direction that is a speed at which the object is viewed from the radar imaging apparatus from a Doppler frequency component whose intensity detected by the Doppler frequency detection unit is equal to or greater than the predetermined first threshold.
- the speed may be estimated.
- the radar imaging apparatus can estimate the gaze direction velocity of the object, so that advanced judgment such as predicting the approach of the object is possible.
- the N delay codes have different delay times with respect to the transmission spreading code, and the delay time is an integral multiple of a bit time which is a time for giving one bit of the transmission spreading code. Also good.
- the delay code generation unit it is possible to detect all objects within a specific distance range as long as the reflected wave reflected by the object has an intensity that can be identified by the Doppler frequency detection unit.
- the configuration can be realized.
- the delay time is any one of K (K is an integer) times to K + N ⁇ 1 times the bit time, and the scanning processing is performed from K times to K + N ⁇ 1 times the bit time.
- the N delay codes may be generated by sequentially increasing the bit time, or by sequentially decreasing the delay time from K + N ⁇ 1 times to K times the bit time.
- the configuration of the delay code generator can be further simplified, and interference between a plurality of search ranges can be suppressed.
- the distance estimation unit identifies the peak intensity at which the intensity is maximum from the distribution of the intensity of the Doppler frequency component with respect to the delay time for each Doppler frequency component detected by the Doppler frequency detection unit, and identifies the identified peak Intensity, intensity for the peak time that is shorter than the delay time corresponding to the specified peak intensity by the bit time, and intensity for the delay time that is longer by the bit time than the delay time corresponding to the specified peak intensity
- the distance from the radar imaging apparatus to the object may be estimated by performing interpolation using the post-peak intensity and using a distance smaller than the distance corresponding to the bit time as a resolution.
- the radar imaging apparatus can detect the direction of the extracted object with high resolution with a resolution finer than the length of the search range.
- the assumed maximum value of the gaze direction velocity which is the velocity at which the object is viewed from the radar imaging apparatus, is vmax, and the resolvable resolution of the gaze direction velocity is vres.
- the code rate CR of the spreading code and the delay code preferably satisfies CR ⁇ 2 ⁇ f0 ⁇ vres / vmax.
- the radar imaging apparatus can reduce an error when detecting the distance of the object with a resolution finer than the length of the search range.
- the radar imaging apparatus further includes a control unit that controls a first operation mode in which the delay code generation unit repeats the scanning process M times and a second operation mode in which the same delay code is repeatedly generated,
- the control unit determines whether there is a Doppler frequency component whose intensity detected by the Doppler frequency detection unit is equal to or higher than a predetermined second threshold, and is equal to or higher than the predetermined second threshold.
- the mode is switched to the second operation mode.
- the delay code generation unit detects a Doppler frequency component that is equal to or greater than the predetermined second threshold.
- the delay code corresponding to the search range is generated repeatedly, and the storage unit performs detection that has been despread and detected using the delay code corresponding to the search range.
- the Doppler frequency detection unit does not store a signal, and the Doppler frequency detection unit performs frequency analysis by sampling a detection signal that is not stored in the storage unit at a cycle shorter than the scanning period, thereby achieving a Doppler frequency that is equal to or higher than the predetermined second threshold value.
- the phase and intensity of the Doppler frequency component in the search range where the component is detected may be detected again.
- the radar imaging apparatus can improve the direction accuracy and the distance accuracy for the observation target.
- the observation time of the detection signal required for the Doppler frequency detection unit to perform the frequency analysis is equal to the time required for repeating the scanning period M times.
- the radar imaging apparatus accurately detects the resolution of the speed when determining the existence of the object for all the search ranges and the object in the search range in which the Doppler frequency component that is equal to or higher than the predetermined second threshold is detected. Since the resolution of the speed when detecting the direction and the distance can be made equal, deterioration of the speed resolution can be suppressed.
- the predetermined second threshold value is preferably a value such that the search range in which the intensity is determined to be equal to or greater than the predetermined second threshold value is N ⁇ 2 or less.
- the time required to analyze the Doppler frequency for the entire search range via the storage unit and the time required to analyze the Doppler frequency for any search range out of the entire search range without using the storage unit It becomes equal to time. Therefore, the processing time of the entire radar imaging apparatus can be shortened as compared with a simple configuration in which the Doppler frequency is discriminated without going through the storage unit and the setting of the delay time is changed each time the processing is completed.
- the present invention can be realized not only as a radar imaging apparatus including such a characteristic processing unit, but also as an imaging method using the characteristic processing included in the radar imaging apparatus as a step. .
- the present invention can also be realized as a program for causing a signal processor in the radar imaging apparatus to execute characteristic steps included in such an imaging method. Further, it may be realized as a recording medium such as a computer-readable CD-ROM (Compact Disc-Read Only Memory) in which the program is recorded, or information, data, or a signal indicating the program. These programs, information, data, and signals may be distributed via a communication network such as the Internet.
- a communication network such as the Internet.
- FIG. 1 is a block diagram showing a configuration of a radar apparatus according to Embodiment 1 of the present invention.
- FIG. 2 is a block diagram showing a detailed configuration of the transmission unit of the radar apparatus according to Embodiment 1 of the present invention.
- FIG. 3 is a block diagram showing a detailed configuration of the receiving unit of the radar apparatus according to Embodiment 1 of the present invention.
- FIG. 4 is a diagram for explaining delay time control by the control unit of the radar apparatus according to Embodiment 1 of the present invention.
- FIG. 5 is a diagram showing the configuration of the signal storage unit of the radar apparatus according to Embodiment 1 of the present invention.
- FIG. 6A is a diagram showing the order in which complex baseband signals are stored in the signal storage unit of the radar apparatus according to Embodiment 1 of the present invention.
- FIG. 6B is a diagram illustrating a state in which a complex baseband signal is read from the signal storage unit of the radar apparatus according to Embodiment 1 of the present invention.
- FIG. 7 is a diagram showing a configuration of a Doppler frequency discriminating unit and a structure of input / output signals of the radar apparatus according to Embodiment 1 of the present invention.
- FIG. 8 is a diagram showing a structure of an output signal of the object detection unit of the radar apparatus according to Embodiment 1 of the present invention.
- FIG. 9 is a flowchart showing the operation of the radar apparatus according to Embodiment 1 of the present invention.
- FIG. 10 is a flowchart showing a detailed operation of the baseband signal write processing of FIG. 9 in the first embodiment of the present invention.
- FIG. 11A is a diagram showing output signal strengths of specific Doppler frequency components of the Doppler frequency discriminating unit of the radar apparatus according to Embodiment 1 of the present invention.
- FIG. 11B is a diagram showing the relationship between the signal strength ratio of adjacent range gates and the distance offset value in Embodiment 1 of the present invention.
- FIG. 12 is a diagram illustrating a configuration of a control unit and a signal processing unit of the radar apparatus according to Embodiment 2 of the present invention.
- FIG. 13 is a flowchart showing the operation of the radar apparatus according to Embodiment 2 of the present invention.
- FIG. 14 is a flowchart showing specific operations in the first operation mode of the radar apparatus according to Embodiment 2 of the present invention.
- FIG. 15 is a flowchart showing specific operations in the second operation mode of the radar apparatus according to Embodiment 2 of the present invention.
- FIG. 16 is a block diagram showing a configuration of a conventional radar apparatus.
- FIG. 1 is a block diagram showing a configuration of a radar apparatus 100 according to the first embodiment.
- FIG. 1 also shows targets (objects) 200a and 200b that are targets to be detected by the radar apparatus 100.
- the radar apparatus 100 is a radar imaging apparatus according to the present invention, and has a function of detecting the sight-line direction speed and direction of the targets 200a and 200b and a function of measuring a distance to the targets 200a and 200b using a spreading code.
- the radar apparatus 100 includes an oscillator 101, distributors 102a and 102b, a spread code generation unit 103a, a delay code generation unit 103b, a transmission unit 104, a transmission antenna 105, and reception antennas 106a and 106b.
- the targets 200a and 200b are referred to as targets 200 when there is no particular need to distinguish them.
- the radar apparatus 100 is assumed to be stationary. Hereinafter, each configuration will be described in detail.
- the oscillator 101 generates a local oscillation signal (also called a carrier wave) LO having a frequency of f0.
- a local oscillation signal also called a carrier wave
- LO a frequency band of 60 GHz
- the oscillator 101 may be configured to directly generate the frequency f0 of the carrier wave LO, or may be configured to generate the carrier wave LO of the desired frequency f0 by multiplying an externally generated signal.
- the distributors 102a and 102b distribute two input signals to output two signals having the same frequency as the input signal.
- the distributor 102a distributes the carrier wave LO generated by the oscillator 101 to generate two signals having the same frequency f0 as the carrier wave LO, and transmits one of the two signals to the transmission unit 104. The other is output to the distributor 102b.
- the distributor 102b distributes the signal input from the distributor 102a, thereby generating two signals having the same frequency as the input signal, that is, the same frequency f0 as the carrier wave LO.
- One of the two signals is output to the receiving unit 107a and the other is output to the receiving unit 107b. That is, the distributors 102a and 102b output the carrier wave LO having the frequency f0 generated by the oscillator 101 to the transmission unit 104 and the reception units 107a and 107b.
- the spread code generator 103a generates a spread code used for spectrum spreading.
- the spreading code is, for example, a spreading code (hereinafter referred to as M1) of an M-sequence code having a bit rate of 250 Mbps. Note that the spreading code M1 generated by the spreading code generator 103a corresponds to the transmission spreading code of the present invention.
- the spread code generation unit 103a is, for example, a digital circuit, and for example, sequentially extracts a spread code stored in a storage device (not shown) provided outside the spread code generation unit 103a, or spread code A spreading code is sequentially generated based on a rule (for example, a formula) stored inside or outside the generating unit 103a.
- Spreading code generating section 103a outputs the generated spreading code to transmitting section 104.
- the delay code generator 103b generates a delay code having a delay time (hereinafter referred to as M2) for the spreading code M1.
- the delay code generation unit 103b has the same code as the transmission code M1 within a scanning period for scanning N (N is an integer of 2 or more) range gates having different distances from the radar apparatus 100.
- a range scan operation (also referred to as a scanning process) for sequentially generating N delay codes M2 corresponding to the distance from the radar apparatus 100 of N range gates is performed by M (M is an integer equal to or greater than 2). Repeat over a period.
- the delay code generation unit 103b generates a delay code M2, which is a code delayed from the spreading code M1 by a delay time C2 instructed from the control unit 110. Further, the control unit 110 instructs the delay code C1 to the spreading code generation unit 103a.
- This delay time C1 is, for example, zero.
- the delay time C2 is the delay time of the time waveform of the delay code M2 with respect to the time waveform of the spread code M1, and when the delay time C2 is zero, the time waveform of the spread code M1 and the time waveform of the delay code M2 are If the delay time C2 is not zero, the time waveform of the delay code M2 is a waveform obtained by delaying the time waveform of the spread code M1 by the delay time C2.
- the delay code generation unit 103b is, for example, a digital circuit.
- This delay code generation unit 103b delays the code stored in the storage device provided outside the spread code generation unit 103a referred to by the spread code generation unit 103a with respect to the spread code M1 in accordance with the instruction of the control unit 110.
- the delay code M2 is generated by sequentially taking out in a manner.
- the delay code generator 103b generates a delay code by generating the same code as the spread code M1 in a manner delayed with respect to the spread code M1, based on the same formula used to generate the spread code M1.
- M2 is generated sequentially.
- the transmission unit 104 generates a transmission signal (hereinafter referred to as RF OUT) by spreading the local oscillation signal LO (carrier wave) using the spread code M1 generated by the spread code generation unit 103a.
- RF OUT a transmission signal
- the transmission unit 104 is realized as a configuration as illustrated in FIG. 2, and the transmission signal RF is obtained by amplifying the spreading mixer 141 that multiplies the carrier wave LO and the spreading code M1 and the carrier LO that is spread by the spreading mixer 141.
- an amplifier 142 for generating OUT For example, the amplifier 142 amplifies the carrier wave LO spread by the diffusion mixer 141 to an appropriate level in order to set the radio wave radiated from the radar apparatus 100 to an appropriate level determined by law and regulation.
- the transmission antenna 105 radiates the transmission signal RF OUT generated by the transmission unit 104 as a radiated wave (hereinafter referred to as rad_w).
- the radiated wave rad_w radiated from the transmitting antenna 105 is reflected by the target 200 and received by the receiving antennas 106a and 106b as reflected waves (hereinafter referred to as ref_w).
- the receiving antennas 106a and 106b output the received reflected wave ref_w to the corresponding receiving units 107a and 107b as input signals (hereinafter referred to as RF IN).
- RF IN input signals
- the reflected wave ref_w received by the receiving antenna 106a is input to the receiving unit 107a as the input signal RF IN.
- the reflected wave ref_w received by the receiving antenna 106b is input to the receiving unit 107b as the input signal RF IN.
- the receiving unit 107a despreads the reflected wave ref_w received by the receiving antenna 106a using the delay code M2 generated by the delay code generating unit 103b. Furthermore, the receiving unit 107a generates an in-phase signal (Ia) and a quadrature signal (Qa) by performing quadrature demodulation (also referred to as quadrature detection) on the despread reflected wave ref_w using the carrier wave LO.
- This in-phase signal (Ia) is a signal corresponding to the phase component in phase with the carrier wave LO of the reflected wave ref_w despread by the receiving unit 107a.
- the quadrature signal (Qa) is a signal corresponding to a phase component orthogonal to the carrier wave LO of the reflected wave ref_w despread by the receiving unit 107a.
- These in-phase signal (Ia) and quadrature signal (Qa) constitute a first complex baseband signal BBa corresponding to the intensity and phase of the reflected wave ref_w received by the receiving antenna 106a.
- the receiving unit 107b despreads the reflected wave ref_w received by the receiving antenna 106b using the delay code M2 generated by the delay code generating unit 103b. Further, the reception unit 107b generates an in-phase signal (Ib) and a quadrature signal (Qb) by performing quadrature demodulation on the despread reflected wave ref_w using the carrier wave LO.
- This in-phase signal (Ib) is a signal corresponding to a phase component in phase with the carrier wave LO of the reflected wave ref_w despread by the receiving unit 107b.
- the quadrature signal (Qb) is a signal corresponding to a phase component orthogonal to the carrier wave LO of the reflected wave ref_w despread by the receiving unit 107b.
- These in-phase signal (Ib) and quadrature signal (Qb) constitute a second complex baseband signal BBb corresponding to the intensity and phase of the reflected wave ref_w received by the receiving antenna 106b.
- the receiving unit 107b has the same configuration as the receiving unit 107a.
- the in-phase signal (Ia) and the in-phase signal (Ib) are converted into the in-phase signal (I), the quadrature signal (Qa) and the quadrature signal (Qb) are converted into the quadrature signal (Q), the first complex baseband signal BBa,
- the two complex baseband signal BBb may be described as the complex baseband signal BB. Further, it may be simply referred to as a baseband signal.
- the receiving unit 107 includes a reception amplifier 175, a despreading mixer 171, distributors 172a and 172b, demodulation mixers 173a and 173b, and a phase shifter 174.
- the reception amplifier 175 is an amplifier that amplifies the signal received by the reception antenna 106. That is, the reception amplifier 175 amplifies the input signal RF IN.
- the reception amplifier 175 is an amplifier that amplifies a weak reception signal (synonymous with the input signal RF IN), and is particularly a low-noise amplifier that is carefully designed to minimize noise newly added by the amplifier itself. desirable.
- the reception amplifier 175 amplifies the intensity of the received signal while maintaining the maximum intensity ratio of the input signal with respect to newly added noise at the output section thereof, thereby minimizing the influence of noise generated in the subsequent circuit. Suppress.
- the despreading mixer 171 corresponds to the despreading unit of the present invention, and despreads the reflected wave ref_w received by the receiving antenna 106a or the receiving antenna 106b using the delay code M2 delayed with respect to the spreading code M1. .
- the input signal RF amplified by the receiving amplifier 175 despread IN. This despread signal is referred to as a “despread wave”.
- the frequency of the despread wave output at this time is a frequency at which the frequency f0 of the carrier wave LO supplied to the transmission unit 104 is subjected to Doppler shift due to the line-of-sight speed of the target 200.
- Distributor 172a distributes the input signal, like distributors 102a and 102b, and outputs a signal having the same frequency as the input signal. Specifically, the distributor 172a distributes the despread wave generated by the despreading mixer 171 and outputs one distributed despread wave to the demodulation mixer 173a, and the other despread wave distributed. Is output to the demodulating mixer 173b. Similarly, the distributor 172b distributes the input carrier wave LO, outputs the distributed carrier wave LO to the demodulation mixer 173a, and outputs the distributed carrier wave LO to the phase shifter 174. The phase shifter 174 shifts the phase of the input carrier wave LO by 90 ° and outputs it. That is, the phase of the carrier wave LO input to the demodulation mixer 173a and the phase of the carrier wave LO input to the demodulation mixer 173b are different by 90 °.
- the demodulating mixers 173a and 173b correspond to the detection unit of the present invention, and demodulate the despread waves distributed by the distributor 172a using the carrier wave LO, and perform the in-phase signal (I) and the quadrature signal (Q).
- the demodulation mixer 173b demodulates the despread wave distributed by the distributor 172a using the carrier wave LO whose phase is shifted by 90 ° by the phase shifter 174, thereby generating an orthogonal signal (Q).
- the frequency of the complex baseband signal BB has a difference frequency between the frequency of the input signal RFIN of the receiving unit 107 and the frequency f0 of the carrier wave LO. That is, the reflected wave ref_w having a round-trip delay time that matches the delay time of the delay code M2 with respect to the spread code M1 input to the reception antenna 106 is received by the receiving unit 107 and the line-of-sight direction of the target 200 that generated the reflected wave ref_w It is converted into a baseband signal BB which is a low frequency signal having a Doppler frequency determined by the speed.
- the reflected wave ref_w having a round-trip delay time that does not match the delay time of the delay code M2 with respect to the spread code M1 input to the reception antenna 106 is spread over a wide band with a center frequency of zero by the reception unit 107. Converted to a signal. A signal having a center frequency of zero and spread over a wide band hardly contributes to a low-frequency signal component in the range of the Doppler frequency that can be normally generated.
- the radar apparatus 100 processes only the signal component in the range of the Doppler frequency that can be normally generated, the radar apparatus 100 has a code rate of M1 and M2 before and after the distance defined by the delay time of the delay code M2 with respect to the spread code M1. Only the reflected wave ref_w from the target 200 located in a specific distance range (hereinafter referred to as a range gate) having a defined length can be selectively detected.
- a range gate Only the reflected wave ref_w from the target 200 located in a specific distance range (hereinafter referred to as a range gate) having a defined length can be selectively detected.
- Xf0 / c 22.2 kHz.
- the radar apparatus 100 selectively detects only targets existing in a section 60 cm before and after the distance corresponding to the delay time. be able to. For example, when the delay time is 12 ns, the distance corresponding to the delay time 12 ns is 180 cm. Further, the radar apparatus 100 can selectively detect only the target 200 existing in a section whose distance from the radar apparatus 100 is 120 cm or more and 240 cm or less.
- the detection range of the target 200 depends on the autocorrelation characteristic of the spreading code M1.
- the target affects the range gate adjacent to the range gate including the distance corresponding to the delay time.
- it can be selectively detected separately from the targets located in other range gates.
- the first complex baseband signal BBa generated by the receiving unit 107a has one or more frequency components fk (k is 1) of the Doppler frequency by the target 200 in the detection range corresponding to the delay time of the delay code M2 with respect to the spreading code M1.
- the above integer is a superimposed signal.
- Each frequency component fk has a phase ⁇ k and an amplitude Ak. Therefore, the first complex baseband signal BBa is not affected by the Doppler frequency by the target 200 outside the detection range corresponding to the delay time of M2 with respect to the spread code M1.
- the amplitude Ak corresponds to the strength, and the larger the amplitude Ak is, the higher the strength is.
- Control unit 110 The control unit 110 sets the delay time of the delay code M2 generated by the delay code generation unit 103b in a predetermined order with respect to the spreading code M1 generated by the spreading code generation unit 103a.
- the control unit 110 determines a delay time corresponding to each range gate, and instructs the delay code generation unit 103b to determine the delay time.
- the control unit 110 sequentially sets the delay time of the delay code M2 with respect to the spread code M1, thereby sweeping the center position of the range gate so as to cover the entire target detection range (hereinafter referred to as a range scan operation). ). Further, the controller 110 controls the delay time so that the time series waveform of the reflected wave ref_w can be acquired for all the range gates by repeating the range scan operation.
- FIG. 4 is a diagram for explaining delay time control by the control unit 110.
- the length of the range gate is 0.6 m
- the detection range is 0.6 ⁇ N [m].
- the spreading code M1 generated by the spreading code generator 103a has a bit length L that can be set as a value larger than N, and the spreading code generator 103a repeatedly generates the spreading code M1.
- the bit length L of the spread code M1 can reduce the ratio of signals outside the range gate leaking into the range gate by setting L to a large value. However, as a result, the measurement time becomes longer. What is necessary is just to consider and decide.
- the control unit 110 sets the delay code M2 for the spreading code M1 so that the delay code M2 shifts in ascending order from 0 to N-1 chips with respect to the spreading code M1. Control the delay time.
- control unit 110 sets the delay time so that the delay code M2 shifts in ascending order from 0 to N ⁇ 1 chips with respect to the spread code M1, and then the shift of the delay code M2 with respect to the spread code M1 is 0 chip again.
- the above operation is repeated by setting a delay time such that
- the delay time of the delay code M2 with respect to the spreading code M1 corresponds to the distance from the radar apparatus 100 corresponding to the delay time. Therefore, by setting the control unit 110 so that the delay times of the delay codes M2 generated by the delay code generation unit 103b are sequentially shifted, the radar apparatus 100 can have N range gates with different distances from the radar apparatus 100. Each target can be detected. That is, when the deviation of the delay code M2 with respect to the spreading code M1 is 0 chip, the target of the first range gate can be detected, and when the deviation of the delay code M2 with respect to the spreading code M1 is i-1 chip (1 ⁇ i ⁇ N) The target of the i-th range gate can be detected.
- a range scan operation also referred to as a scanning process
- a period required for performing one range scan operation is a scan period. That's it.
- the controller 110 repeats the range scan operation over the M scan period.
- the i-th range gate may be described as a range gate number i
- the j-th range scan operation as a range scan number j.
- the delay code M2 generated by the delay code generation unit 103b by the control of the delay time by the control unit 110 as described above is the same code as the spreading code M1, and has a different delay time from the spreading code M1.
- N codes. Specifically, the N delay codes M2 are codes obtained by sequentially shifting the spreading code M1 bit by bit of the spreading code M1, as shown in FIG.
- the delay code M2 is a code that is sequentially shifted by a predetermined time with respect to the spreading code M1.
- the predetermined time is a bit time which is a time for giving one bit of the spread code M1. For example, when the code rate CR of the spread code M1 is 250 Mbps (sometimes referred to as cps), the predetermined time is 4 ns. That is, the N delay codes M2 are codes obtained by shifting the spread code M1 by 4 ns.
- the distance of the range gate from the radar apparatus 100 is a distance from the radar apparatus 100 to any one point included in the range gate, and preferably a distance to the midpoint of the range gate.
- the distance of the third range gate from the radar apparatus 100 is preferably 1 in which the distance from the radar apparatus 100 of the third range gate is closer. .5 m and 1.8 m which is the midpoint between the third range gate and 2.1 m, which is closer to the radar apparatus 100.
- the signal processing unit 108 is, for example, a DSP (Digital Signal Processor).
- the signal processing unit 108 includes a first complex baseband signal BBa composed of the in-phase signal (Ia) and the quadrature signal (Qa) generated by the receiving unit 107a, and the in-phase signal ( Ib) and the second complex baseband signal BBb composed of the quadrature signal (Qb).
- the signal processing unit 108 includes signal storage units 181a and 181b, Doppler frequency discrimination units 182a and 182b, an arrival direction calculation unit 183, an object detection unit 184, and a memory control unit 185.
- the control unit 110 sequentially sets the time series waveform of the first complex baseband signal BBa composed of the in-phase signal (Ia) and the quadrature signal (Qa) generated by the receiving unit 107a.
- the range gate number assigned to identify each range gate is stored in association with it.
- the signal storage unit 181b stores the time series waveform of the second complex baseband signal BBb composed of the in-phase signal (Ib) and the quadrature signal (Qb) generated by the receiving unit 107b in association with the range gate number. .
- the signal storage unit 181b has the same configuration as the signal storage unit 181a.
- the signal storage unit 181a and the signal storage unit 181b correspond to the storage unit of the present invention.
- the configuration of the signal storage units 181a and 181b will be described as the signal storage unit 181 with reference to FIG.
- the signal storage unit 181 stores, for each range scan, a complex baseband signal BB composed of the in-phase signal (I) and the quadrature signal (Q) for each range gate corresponding to the delay time set by the control unit 110.
- the signal storage unit 181 is configured as a memory circuit that stores a two-dimensional array of (N ⁇ M) elements, which is a combination of N range gate numbers and M range scan numbers.
- Each element can store the in-phase signal (I) and the quadrature signal (Q). That is, the signal storage unit 181 holds the in-phase signal (I) and the quadrature signal (Q) in association with the range gate corresponding to the delay time in the delay code generation unit 103b and the range scan.
- the signal storage unit 181 stores the complex baseband signal BB generated by each of the reception unit 107a and the reception unit 107b in association with the delay time in the delay code generation unit 103b and the range scan number.
- the memory control unit 185 controls writing and reading of the complex baseband signal BB composed of the in-phase signal (I) and the quadrature signal (Q) to the signal storage unit 181.
- FIG. 6A shows how the complex baseband signal is stored in the signal storage unit 181. That is, FIG. 6A shows how the memory control unit 185 writes the complex baseband signal output from the receiving unit 107.
- the horizontal axis indicates the range gate number (1, 2, 3,... N)
- the vertical axis indicates the sweep number (1, 2, 3,... M).
- the sweep number is synonymous with the range scan number.
- the complex baseband signal in the i-th (1 ⁇ i ⁇ N) and j-th (1 ⁇ j ⁇ M) range scan is referred to as Rij.
- the memory control unit 185 switches the complex baseband signal BB (in-phase signal (I) to the storage position of the signal storage unit 181 corresponding to the switched range gate number and range scan number every time the control unit 110 switches the range gate. ) And quadrature signal (Q)). Note that the storage locations corresponding to the range gate number and the range scan number may be determined in advance or dynamically allocated.
- the memory control unit 185 sequentially changes the storage location while advancing the range scan number by one every time one range scan is completed. In other words, after the in-phase signal (I) and the quadrature signal (Q) of N elements corresponding to the N number of range gate numbers of the jth range scan number are written in the signal storage unit 181, the j + 1th range scan is completed. The numbered in-phase signal (I) and quadrature signal (Q) are written in the signal storage unit 181. Accordingly, the signal storage unit 181 stores the time-series complex baseband signal BB including the time-series in-phase signal (I) and the quadrature signal (Q) for all the range gates.
- the memory control unit 185 stores the old baseband signal stored in the storage location corresponding to the current range gate number and range scan number. Overwrite BB.
- the latest baseband signal BB that is continuous in the range scan direction, that is, time series is stored.
- the latest range scan number is stored as a time-series discontinuous point. It is preferable to provide a place (not shown).
- FIG. 6B shows how the complex baseband signal stored in the signal storage unit 181 is read out. That is, the state of reading of the complex baseband signal by the memory control unit 185 is shown.
- the memory control unit 185 sequentially reads out M baseband signals BB corresponding to the same range gate and different range scans from the signal storage unit 181. Note that the memory control unit 185 may read M baseband signals stored corresponding to the same range gate number and different range scan numbers after all (N ⁇ M) elements are stored. Then, when the baseband signal corresponding to the Mth range scan number of a certain range gate number is stored, M baseband signals corresponding to the range gate number may be read out.
- the memory control unit 185 corresponds to the N delay codes generated by the delay code generation unit 103b and has the same range as the distance to the N range gates having different distances from the radar apparatus 100.
- Baseband signals R1j to RNj which are N baseband signals BB corresponding to the scan are repeatedly written in the signal storage unit 181 by M range scans.
- the memory control unit 185 sequentially reads a set of baseband signals Ri1 to RiM, which are M baseband signals corresponding to different range scans with the same range gate, from the signal storage unit 181.
- the M baseband signals Ri1 to RiM corresponding to the range scans with the same and different range gates read by the memory control unit 185 are subjected to frequency analysis by the Doppler frequency discriminating units 182a and 182b.
- the radar apparatus 100 includes a signal storage unit 181a provided corresponding to the reception unit 107a and a signal storage unit 181b provided corresponding to the reception unit 107b.
- the radar apparatus 100 may have one storage device, and different areas of the storage device may be used as the signal storage unit 181a corresponding to the reception unit 107a and the signal storage unit 181b corresponding to the reception unit 107b.
- Doppler frequency discriminators 182a and 182b discriminate the complex baseband signal for each frequency component, and output the phase and intensity of the received signal for each Doppler frequency component.
- Each of the Doppler frequency discriminating units 182a and 182b corresponds to the Doppler frequency detecting unit of the present invention, and performs frequency analysis on M baseband signals Ri1 to RiM having the same range gate number read by the memory control unit 185.
- the Doppler frequency component which is the difference between the frequency f0 of the reflected wave ref_w and the frequency f0 of the carrier wave LO in each range gate, and the phase and intensity corresponding to the Doppler frequency component are detected by the detecting unit of the receiving unit 107a and Detection is performed corresponding to each of the reception units 107b.
- the Doppler frequency discriminating units 182a and 182b and the structure of their input / output signals will be described. Since the Doppler frequency discriminating unit 182a and the Doppler frequency discriminating unit 182b have the same configuration, the Doppler frequency discriminating unit 182 will be described here.
- the input signals of the Doppler frequency discriminating units 182a and 182b are complex baseband signals BB (complex baseband signals Rij) stored in the corresponding signal storage units 181.
- the interior of the Doppler frequency discriminating unit 182 includes a fast Fourier transformer (Fast Fourier Transform, FFT) independent for each range gate.
- FFT fast Fourier transformer
- the received signal is temporarily stored in the signal storage unit 181, so that the time scan of the time series signal necessary for obtaining the desired frequency resolution in the Doppler frequency discriminating unit is performed within the time range. It becomes possible to embed actions. Therefore, this configuration does not use a signal storage unit, but simply connects the receiving unit and the Doppler frequency discriminating unit directly, waits for the completion of execution of the Doppler frequency discrimination processing, and then sequentially switches the range gate. Time can be greatly reduced.
- 25 ms is required from the time when the baseband signal Ri1 of the i-th range gate is sampled during the first range scan to the time when the baseband signal RiM of the i-th range gate is sampled during the M-th range scan. It is.
- the observation distance range detection range of the radar apparatus 100
- the length of the range gate is 0.6 m
- the memory control unit 185 samples the baseband signal Rij of the i-th range gate in the j-th range scan, and then samples the i-th range gate in the j + 1-th range scan. Baseband signals other than the i-th range gate can be sampled until the baseband signal Rij + 1 is sampled.
- the baseband signals of different range gates can be sampled during the observation time of 25 ms required for one range gate, the observation time of all the range gates is also 25 ms, and observations are made for the number of range gates. You can save time. That is, the signal processing in the Doppler frequency discriminating unit 182a and the Doppler frequency discriminating unit 182b can be performed 34 times faster.
- the Doppler frequency discriminating units 182a and 182b may use an algorithm other than the fast Fourier transform and only need to be able to calculate the intensity and phase frequency spectrum from the time series waveform of the complex baseband signal.
- the Doppler frequency discriminating units 182a and 182b may use an algorithm such as discrete cosine transform or wavelet transform.
- the Doppler frequency discriminating unit 182 analyzes the frequency of the M baseband signals Ri1 to RiM having the same range gate number read by the memory control unit 185, thereby the reflected wave ref_w in each range gate.
- the Doppler frequency component which is the frequency component of the difference between the frequency and the frequency f0 of the carrier wave LO, and the phase and intensity corresponding to the Doppler frequency component correspond to the detection unit of the reception unit 107a and the detection unit of the reception unit 107b, respectively. To detect.
- the Doppler frequency component obtained by frequency analysis by the Doppler frequency discriminating unit 182 includes P frequency bands.
- the P frequency bands are designated by Doppler frequency numbers 1 to P. That is, the output signal from the Doppler frequency discriminating unit 182 is an intensity signal and a phase signal associated with the range gate number and the Doppler frequency number.
- the object detection unit 184 corresponds to the distance estimation unit of the present invention, and the range gate from the radar apparatus 100 of the range gate in which the Doppler frequency component whose intensity detected by the Doppler frequency discrimination units 182a and 182b is equal to or greater than a predetermined threshold is detected.
- the distance is estimated as the distance from the radar apparatus 100 to the target 200. That is, the object detection unit 184 uses the intensity signal output of the Doppler frequency discriminating units 182a and 182b, determines that the target exists in the range gate having an intensity signal output of a certain level or more in the intensity signal output of any Doppler frequency, The signal strength at the Doppler frequency of the range gate is calculated.
- the reflected wave ref_w received by the receiving antennas 106a and 106b is generated by the delay code generator 103b and despread by the delay code M2 having a predetermined delay time with respect to the transmission code M1. Therefore, only when the round-trip delay time when the signal is radiated from the transmitting antenna 105 and then reflected by the target and propagates to the receiving antennas 106a and 106b matches the delay time of the delay code M2, the line of sight of the target A carrier wave LO that has undergone a Doppler frequency shift corresponding to the direction velocity is reproduced.
- the Doppler frequency corresponding to the line-of-sight movement speed is output by the Doppler frequency discriminating units 182a and 182b.
- the Doppler frequency discriminating units 182a and 182b have a Doppler frequency equal to or higher than a predetermined threshold in a certain delay time, it is determined that the target exists at a distance that the electromagnetic wave travels in half the delay time. can do.
- the object detection unit 184 uses the same Doppler frequency number of the intensity signal output from the Doppler frequency discriminator 182a and the intensity signal output from the Doppler frequency discriminator 182b. It is determined that the target exists when both the intensity a, which is the intensity signal of the Doppler frequency discriminating unit 182a, and the intensity b, which is the intensity signal of the Doppler frequency discriminating unit 182b, are equal to or higher than a certain level. According to this method, the probability of erroneous presence determination is reduced, but the target detection rate is also reduced.
- the object detection unit 184 determines that the target exists when either the intensity a or the intensity b is equal to or higher than a certain level. According to this method, the detection probability of the target can be increased, but the probability of erroneous presence determination is also increased.
- any of the above methods may be used as a method for determining the presence of the target depending on the application.
- the object detection unit 184 may use an average value of the intensity a and the intensity b as the intensity used for the determination of the presence of the target, or may use a higher intensity as a representative value. Those having a low strength may be used as representative values. Further, the object detection unit 184 may use any one of these methods depending on the application.
- the presence determination of the object in the range gate corresponding to the delay time of interest is performed in consideration of the values of the intensity a and the intensity b in the range gate existing in a certain distance range from the range gate corresponding to the delay time of interest. May be.
- Such a determination method is useful when detecting a person or a vehicle with a background of an object that continuously exists within a certain distance range, such as road surface reflection.
- the object detection unit 184 outputs a signal indicating the range gate where the target exists and a signal indicating the Doppler frequency to the arrival direction calculation unit 183. Then, the object detection unit 184 stores the direction of each target calculated by the arrival direction calculation unit 183 in association with the Doppler frequency and the range gate of each target.
- the arrival direction calculation unit 183 corresponds to the direction estimation unit of the present invention, and targets the arrival direction of the reflected wave ref_w including the Doppler frequency component whose intensity is equal to or higher than a predetermined threshold detected by the Doppler frequency discrimination units 182a and 182b. Estimate the direction. That is, the direction-of-arrival calculation unit 183 determines the phase detected by the Doppler frequency discriminating unit 182a and the phase detected by the Doppler frequency discriminating unit 182b at the range gate and Doppler frequency determined by the object detection unit 184 to exist. From the difference, the arrival direction of the reflected wave ref_w having the Doppler frequency of the range gate is estimated, and the estimation result is output to the object detection unit 184.
- the phase difference between the receiving antenna 106a and the receiving antenna 106b and the physical distance between the receiving antenna 106a and the receiving antenna 106b are used. To know the direction of the target.
- FIG. 8 is a diagram for explaining a signal structure resulting from the above processing. Specifically, FIG. 8 is data including the intensity signal detected by the Doppler frequency discriminators 182 a and 182 b and the arrival direction estimated by the arrival direction calculation unit 183, which is held in the object detection unit 184. It is a figure which shows a certain signal.
- the object detection unit 184 holds an intensity signal and an arrival direction corresponding to the range gate number and the Doppler frequency number. At this time, the combination of the range gate and the Doppler frequency where it is not determined that an object exists does not make sense because the direction of arrival has not been calculated.
- the object detection unit 184 may output the data illustrated in FIG. 8 to the outside of the radar apparatus 100.
- the radar apparatus 100 calculates the intensity signal and the arrival direction corresponding to all the range gates and Doppler frequencies by setting the signal intensity (threshold value) that is a reference for the presence determination of the object to zero. May be.
- the purpose of use of the output signal in such a case is to determine the presence or direction of the target with respect to the very weak reflected signal ref_w that is difficult to determine the presence of the target, for example, by performing statistical processing. Conceivable.
- FIG. 9 is a flowchart showing the operation of the radar apparatus 100.
- the memory control unit 185 sequentially writes N baseband signals in the same scanning period in the signal storage units 181a and 181b (step S101). That is, N baseband signals R1j to RNj having the same range scan number and different range gate numbers are sequentially written in the signal storage units 181a and 181b.
- FIG. 10 is a detailed operation flowchart of step S101 in FIG.
- the spreading code generator 103a generates the spreading code M1 at the timing indicated by the controller 110 (step S201).
- the delay code generation unit 103b generates the delay code M2 with a delay time instructed by the control unit 110. Specifically, the delay code generator 103b generates a delay code M1 corresponding to the first range gate (for example, the first range gate) (step S202).
- the transmission unit 104 despreads the carrier wave LO using the spread code M1 generated by the spread code generation unit 103a, thereby generating a transmission signal RF OUT.
- the transmission antenna 105 radiates the transmission signal RF OUT generated by the transmission unit 104 as a radiation wave rad_w (step S203).
- the receiving antennas 106a and 106b receive the reflected wave ref_w reflected by the target 200 (step S204).
- the received reflected wave ref_w is despread and orthogonally demodulated by the receiving units 107a and 107b, and is output to the signal processing unit 108 as a baseband signal Rij.
- the memory control unit 185 writes the baseband signal Rij output from the receiving units 107a and 107b into the signal storage units 181a and 181b (step S205). Specifically, the memory control unit 185 writes the baseband signal Rij output from the reception unit 107a in the signal storage unit 181a in association with the range gate number and the range scan number, and outputs from the reception unit 107b. The baseband signal Rij is written into the signal storage unit 181b.
- the memory control unit 185 determines whether or not the writing of the baseband signals R1j to RNj for all the range gates has been completed (step S206). If the writing has not been completed (No in step S206), the delay code generation unit 103b generates a delay code M2 for the next range gate (step S207), and returns to step S203.
- step S206 when the writing of the baseband signal Rij for all the range gates has been completed (Yes in step S206), the writing process of the baseband signal is completed.
- the memory control unit 185 determines whether or not the writing of the baseband signal to the signal storage units 181a and 181b is completed for the entire scanning period (step S102). That is, the memory control unit 185 determines whether or not the Mth range scan is completed. If not completed (No in step S102), the process returns to the baseband signal writing process (step S101).
- the memory control unit 185 causes the M baseband signals Ri1 to RiM in the scanning periods having the same range gate and different from each other. Are read sequentially (step S103).
- the Doppler frequency discriminating unit 182a and the Doppler frequency discriminating unit 182b perform frequency analysis on the M baseband signals Ri1 to RiM read from the signal storage units 181a and 181b by the memory control unit 185 for each range gate. That is, the Doppler frequency discriminating unit 182a and the Doppler frequency discriminating unit 182b discriminate the Doppler frequency (Step S104).
- the arrival direction calculation unit 183 estimates the arrival direction of the reflected wave ref_w (step S105).
- the radar apparatus 100 includes the transmission unit 104 that generates the transmission signal RF OUT by spreading the carrier wave LO using the spread code M1, and the transmission signal RF OUT as the radiation wave rad_w.
- Radiating transmitting antenna 105, receiving antenna 106a and receiving antenna 106b for receiving reflected wave ref_w from which radiated wave rad_w is reflected by object 200, and N range gates having different distances from radar device 100 are scanned.
- a delay code generation unit 103b that repeats a range scan that sequentially generates N delay codes M2 that are the same code as the spread code M1 and have different distances from the radar apparatus 100 within the scan period, over the M range scan period;
- N delay codes M2 are sequentially used to respectively correspond to a plurality of despreading mixers 171 that despread the reflected wave ref_w received by the corresponding receiving antenna, and a plurality of despreading mixers 171, each of which corresponds to a carrier wave LO.
- signal storage units 181a and 181b that store the number of delay codes M2 corresponding to the N delay codes M2 in the delay code generation unit 103b.
- the N baseband signals R1j to RNj corresponding to different distances and one scanning period are repeatedly written in the M range scan to the signal storage unit 181a and the signal storage unit 181b, and the distances from the radar apparatus 100 are the same and different from each other.
- a memory control unit 185 that sequentially reads a set of M baseband signals Ri1 to RiM corresponding to the signal storage unit 181a and the signal storage unit 181b, and M bases that have the same distance read by the memory control unit 185
- a plurality of detections of a Doppler frequency component that is a frequency component of a difference between the reflected wave ref_w and the carrier wave LO in each range gate, and a phase and intensity corresponding to the Doppler frequency component are performed.
- Doppler frequency discriminating section to detect corresponding to each section 182a and the Doppler frequency discriminating unit 182b, and the phase difference between the plurality of detection units is calculated from the phases corresponding to the detected plurality of detection units, and the arrival direction of the reflected wave ref_w at each range gate from the calculated phase difference
- a direction-of-arrival calculation unit 183 that estimates the direction of the target 200 by detecting.
- the baseband signal Rij which is the result of the range scan of a plurality of delay times, is stored in the signal storage units 181a and 181b. Further, the radar apparatus 100 performs Doppler frequency discrimination processing for each range gate for the baseband signals Ri1 to RiM having the same delay time. Therefore, compared with a configuration in which Doppler frequency discrimination processing is performed on the baseband signals Ri1 to RiM without using the signal storage units 181a and 181b, and the setting of the delay time is changed every time the Doppler frequency discrimination processing is completed. The radar apparatus 100 can shorten the time required to detect the target in the detection range. Therefore, the radar apparatus 100 can improve the function of detecting the direction of the moving target.
- radar apparatus 100 is surrounded by k (k is an integer equal to or greater than 0) times the distance determined from the code speed of spreading code M1 and k + 1 times the distance from radar apparatus 100.
- a baseband signal corresponding to the reflected wave ref_w is processed for each range gate defined as a detection range that is a region to be transmitted. Therefore, even when the target having the same line-of-sight speed exists outside the range gate, the radar apparatus 100 is not affected by the reflected wave ref_w from the target, and the reflected wave ref_w from the range gate is not affected. Can discriminate frequencies.
- the radar apparatus 100 reflects a reflected wave from the target at the range gate even when a range gate having the same line-of-sight speed exists outside the range gate.
- a Doppler frequency that is a difference frequency between ref_w and the carrier wave LO can be detected.
- the radar apparatus 100 uses M-sequence codes as the spreading code M1 and the delay code M2.
- the cross-correlation between the spreading code M1 and delay code M2 using the M-sequence code and other signals is small.
- the radar apparatus 100 can identify the signal emitted from the radar apparatus 100 by the code even when there is an influence of a radio wave emitted from another radar system or the like. That is, the radar apparatus 100 can reduce the influence of other radar systems.
- the possibility that the DOA becomes indefinite due to the influence of a target having a close Doppler frequency or another system is greatly reduced, and the radar apparatus 100 can detect the direction of the object in a short time with a simple configuration.
- the delay code generation unit 103b be configured to generate a code M2 delayed with respect to the spread code M1, with a bit time corresponding to one bit of the spread code M1 as a unit.
- the N delay codes M2 have different delay times with respect to the transmission code M1, and the delay time is an integral multiple of the bit time which is a time for giving one bit of the transmission code M1.
- Such a configuration is the most efficient configuration for detecting all the objects existing in a specific distance range as long as the reflected signal intensity has a receivable intensity. That is, using a time shorter than the bit time as a unit is not preferable because the number of range gates increases and the load of signal processing increases. In addition, using a time longer than the bit time as a unit is not preferable because range gates do not continue and a plurality of distance ranges in which an object cannot be detected are generated. On the other hand, using the bit time as a unit is preferable because the configuration of the delay code generation unit 103b can be simplified. That is, the spread code generation unit 103a and the delay code generation unit 103b can be configured using a synchronization circuit having a bit time as a clock cycle.
- the delay code generator 103b generates a code M2 delayed with respect to the spread code M1 in units of bit time corresponding to one bit of the spread code M1, thereby simplifying the configuration of the delay code generator 103b.
- the signal processing unit 108 has an intensity capable of identifying the reflected wave ref_w reflected by the target, it is possible to realize a configuration that can detect all objects within a specific distance range.
- the control unit 110 controls the delay time sequentially set in the delay code generation unit 103b so as to monotonously increase or monotonously decrease with respect to the setting order so that the corresponding range gates are continuous.
- the delay time is any one of K times (K is an integer) to K + N ⁇ 1 times the bit time of the transmission code M1, and the control unit 110 reduces the delay time from K times the bit time in the scanning process.
- the influence of the transient response of the received signal by the range scan operation affects the range gates before and after the range gate detecting the object, the influence is adjacent to the distance. Because it covers only the specified range, there is no practical problem.
- the delay time sequentially set by the control unit 110 in the delay code generation unit 103b is controlled in such a manner that the corresponding range gates do not continue, the influence of the transient response of the received signal is the distance at which the object exists. It occurs in isolation at different positions. This increases the possibility of causing an erroneous result as if a target is present at that position, which is not preferable.
- the configuration of the delay code generator 103b can be further simplified, and interference between a plurality of range gates can be further reduced. Can be suppressed.
- an object can be detected in a three-dimensional space by arranging receiving antennas at three vertexes of a right triangle. That is, the direction of arrival in the plane including the first base line formed by the two antennas is obtained between the two antennas by the procedure described above. Then, another two antennas are selected so as to constitute a second baseline orthogonal to the first baseline, and the arrival direction of the object within the plane including the second baseline is determined according to the procedure described above. Is estimated. Then, by integrating these results, the direction of the object can be detected three-dimensionally. Furthermore, the detection result and the distance information of the target object can be used to detect the target object in a three-dimensional space.
- the radar apparatus may use three or more antennas. By increasing the number of antennas, it is possible to obtain the direction of arrival of one object in duplicate and average them, thereby suppressing the influence of noise. In addition, by arranging a plurality of antennas at unequal intervals, it becomes possible to eliminate arrival direction uncertainty that may occur due to the relationship between the interval between the antennas and the wavelength of the transmission wave.
- the object detection unit 184 can detect the target position discretely in units of range gates, but the object detection unit 184 further includes the spreading code M1 and the delay code M2.
- the range gate length RG c / (2 ⁇ CR) calculated using the speed of light c may be determined in more detail, that is, the detailed location in the range gate may be obtained.
- the radar apparatus is substantially the same as the radar apparatus 100 according to the first embodiment, but the Doppler with respect to the delay time for each Doppler frequency detected by the object detection unit 184 by the Doppler frequency discrimination units 182a and 182b. From the intensity distribution of the frequency, the peak intensity where the intensity is maximum is identified, the identified peak intensity, and the intensity before peak that is the intensity for the delay time shorter by the bit time than the delay time corresponding to the identified peak intensity are identified. By interpolating using the post-peak intensity, which is the intensity for the delay time that is later by the bit time than the delay time corresponding to the peak intensity, the distance from the distance corresponding to the bit time is set as the resolution, and the target from the radar device. The point to estimate the distance to is different.
- the object detection unit 184 obtains a peak where the intensity is maximum from the change of the intensity value with respect to the range gate number for each Doppler frequency. Then, the object detection unit 184 extracts, for each peak, a peak Pb having a high intensity among the peak intensity Pa and the intensity of the range gate before and after the peak intensity Pa.
- the object detection unit 184 obtains the detailed distance of the target object using R1, R2, P1, and P2.
- FIG. 11A is a diagram showing the signal intensity with respect to the range gate at a specific Doppler frequency. As an example, FIG. 11A shows a case where there is one intensity peak. In addition, the horizontal axis of FIG. 11A is the range gate number. FIG. 11A also shows the distance from the corresponding radar device when the length of the range gate is 0.6 m.
- This intensity change is caused by the delay code M2 with respect to the round-trip propagation delay time (synonymous with the round-trip delay time) until the transmission signal RF OUT modulated by the spreading code M1 is reflected by the target and received by the receiving antennas 106a and 106b.
- This correlation waveform is obtained when the delay time is changed with the bit time of the code as a unit. Therefore, when the offset value of the target distance is considered with reference to an intermediate position between R1 and R2, the ratio of P1 and P2 is calculated as shown in FIG. 11B from the autocorrelation characteristics of the code.
- the object detection unit 184 obtains the target distance offset value Roff from the measured values of P1 and P2, and obtains the detailed target distance as (RG1 + RG2) / 2 + Roff. That is, the distance from the radar apparatus corresponding to the true peak intensity P0 of the intensity distribution shown in FIG. 11A is obtained.
- P1 and P2 may be affected by the transient response of the received signal due to the range scan operation to the adjacent range gate in addition to the autocorrelation characteristics of the code, it is shown in FIG. 11B. It is desirable to measure the curved line in advance by placing a reflector in front of the radar apparatus.
- each range gate corresponds to the delay time of the delay code M2 with respect to the spreading code M1
- FIG. 11A shows a specific Doppler frequency. This is synonymous with the signal strength with respect to the delay time of the delay code M2.
- the distance interval corresponding to each of the adjacent range gate numbers corresponds to a bit time which is a time for giving one bit of the spread code M1.
- the object detection unit 184 uses the Doppler frequency component intensity corresponding to the delay time of the delay code M2 for the spreading code M1 for each Doppler frequency detected by the Doppler frequency discrimination units 182a and 182b. Find a distribution. Then, the object detection unit 184 identifies the peak intensity Pa at which the intensity is maximized from the distribution, and determines a bit based on the identified peak intensity Pa and the delay time of the delay code M2 corresponding to the identified peak intensity Pa.
- the object detection unit 184 can estimate the distance from the radar device to the target by using a distance smaller than the range gate length that is a distance corresponding to the bit time as a resolution.
- the object detection unit 184 can detect the direction of the target with high accuracy with a resolution finer than the length of the range gate.
- the detailed distance to the target is obtained using the strengths of the two adjacent range gates, but the detailed distance can be obtained using the strengths of more range gates. Thereby, the accuracy of the distance can be improved when the transient response is affected beyond the range of the range gate adjacent to the range gate that gives the intensity peak.
- the code rates CR of the transmission code M1 and the delay code M2 are expressed as follows: It is desirable to satisfy 3.
- Embodiment 2 Next, a radar apparatus according to Embodiment 2 will be described.
- the radar apparatus is substantially the same as the radar apparatus 100 according to the first embodiment, but further, the same delay code as the first operation mode in which the delay code generation unit 103b repeats the scanning process M times. And a control unit that controls the second operation mode in which M2 is repeatedly generated.
- the control unit performs Doppler in which the intensity detected by the Doppler frequency discriminating units 182a and 182b is equal to or greater than a predetermined second threshold value. It is determined whether or not there is a frequency component, and when it is determined that there is a Doppler frequency component that is equal to or greater than a predetermined second threshold, the operation mode is switched to the second operation mode.
- the delay code generation unit 103b The delay code M2 corresponding to the range gate in which the Doppler frequency component equal to or greater than the second threshold is detected is repeatedly generated, and the signal storage units 181a and 181 are generated. Does not store the detection signal despread and detected using the delay code corresponding to the range gate, and the Doppler frequency discriminating units 182a and 182b detect the detection signals not stored in the signal storage units 181a and 181b from the scanning period. In addition, the phase and intensity of the Doppler frequency component in the range gate in which the Doppler frequency component that is equal to or higher than the predetermined second threshold is detected again by sampling and frequency analysis in a short cycle.
- FIG. 12 is a block diagram showing the configuration of the control unit and the signal processing unit in the second embodiment, and other parts of the radar apparatus that are not shown are the same as those in FIG.
- the radar apparatus according to the second embodiment uses a control unit 210 instead of the control unit 110 in FIG. 1 and a signal processing unit 208 instead of the signal processing unit 108.
- the same symbols are used for the same components as in FIG.
- the signal processing unit 208 is further provided with switches 286a, 286b, 286c and 286d, and down-sampling units 287a and 287b, compared with the signal processing unit 108.
- the signal processing unit 208 includes an object detection unit 284 instead of the object detection unit 184, and outputs an extraction range gate signal R ′ to the control unit 210.
- the switch 286a selectively connects the receiving unit 107a and one of the signal storage unit 181a and the downsampling unit 287b.
- the switch 286b selectively connects the reception unit 107b and one of the signal storage unit 181b and the downsampling unit 287b.
- the switch 286c selectively connects one of the signal storage unit 181a and the downsampling unit 287a to the Doppler frequency discriminating unit 182a.
- the switch 286d selectively connects one of the signal storage unit 181b and the downsampling unit 287b to the Doppler frequency discriminating unit 182b.
- switches 286a to 286d are switched at the same timing according to the switch control signal S output from the control unit 210.
- the switch 286a connects the receiving unit 107a and the signal storage unit 181a, that is, when the upper path in the figure is turned on
- the switch 286b connects the receiving unit 107a and the signal storage unit 181b.
- the switch 286c connects the signal storage unit 181a and the Doppler frequency discriminating unit 182a
- the switch 286d connects the signal storage unit 181b and the Doppler frequency discriminating unit 182b.
- the down-samplers 287a and 287b are P: 1 down-samplers, and are composed of a low-pass filter that makes the frequency band 1 / P and a decimation processor that extracts one sample for every P samples. ing. With this processing, the noise energy included in the output signals of the down-samplers 287a and 287b is reduced to 1 / P of the input signal. That is, the signal-to-noise ratio is improved P times.
- the complex baseband signal BB stored in the signal storage unit 181 is converted into a digital value by AD conversion at the input side of the complex baseband signal BB of the signal processing unit 208.
- the sampling frequency of AD conversion is the first sampling frequency determined according to the frequency obtained by multiplying the sampling frequency of fast Fourier transform by the number of range gates.
- the sampling frequency of the fast Fourier transform is determined from the maximum value of the Doppler frequency analyzed by the Doppler frequency discriminating units 182a and 182b.
- an input signal having a frequency component higher than the Nyquist frequency defined as a half of the sampling frequency returns to the Nyquist frequency or less after AD conversion, and is equal to or less than the Nyquist frequency included in the AD conversion input signal.
- Noise that cannot be separated is generated by adding to the frequency component (referred to as aliasing). Therefore, it is preferable to sufficiently suppress the frequency component equal to or higher than the Nyquist frequency by providing a low-pass filter at the input portion of AD conversion. This low-pass filter is called an anti-aliasing filter.
- the Nyquist frequency in AD conversion is set high and the antialiasing filter is cut.
- Design high off-frequency That is, the input signal for AD conversion is designed to have a wide frequency band and a high first sampling frequency.
- the down-samplers 287a and 287b sample the baseband signal BB at a cycle shorter than the scan period of the first operation mode.
- the downsampling units 287a and 287b sample at the same period as the first sampling frequency in the first operation mode.
- a common anti-aliasing filter can be used in the first operation mode and the second operation mode.
- the down-sampling units 287a and 287b limit the frequency band of the digital signal after AD conversion inside the down-sampling units 287a and 287b with a low-pass filter.
- the down-samplers 287a and 287b extract one sample for every P samples obtained as the output signals.
- the sampling frequency is converted to 1 / P. Therefore, the low-pass filters inside the down-samplers 287a and 287b are designed so that aliasing does not occur with respect to the converted sampling frequency. Specifically, the cut-off frequency of the low-pass filter is designed to be lower than the Nyquist frequency corresponding to the sampling rate after down-sampling. Thereby, the noise of the baseband signal downsampled by the downsampling units 287a and 287b can be reduced.
- the accuracy of the intensity and phase for each Doppler frequency discriminated by the Doppler frequency discriminating units 182a and 182b is improved.
- the control unit 210 is different from the control unit 110 in the first embodiment in that the extraction range gate signal R ′ is further input from the signal processing unit 208 and the switch control signal S is output to the switches 286a to 286d. .
- the control unit 210 further controls a first mode in which the delay code generation unit 103b repeats the scanning process M times and a second operation mode in which the same delay code M2 is repeatedly generated.
- the first operation mode it is determined whether or not there is a Doppler frequency component whose intensity detected by the Doppler frequency discriminators 182a and 182b is equal to or greater than a predetermined threshold, and there is a Doppler frequency component that is equal to or greater than the predetermined threshold.
- the radar apparatus according to the present embodiment operates in the same manner as the radar apparatus 100 according to the first embodiment, and thus detailed description thereof is omitted.
- the controller 210 delays the delay time corresponding to the range gate in which the Doppler frequency at which the intensity detected by the Doppler frequency discriminators 182a and 182b is equal to or greater than a predetermined threshold in the first operation mode is detected.
- a delay code corresponding to the range gate is repeatedly generated.
- the control unit 210 connects the switches 286a and 286c to the down sample unit 287a side and connects the switches 286b and 286d to the down sample unit 287b side by the switch control signal S.
- the signal storage units 181a and 181b do not store the complex baseband signal BB.
- the Doppler frequency discriminating units 182a and 182b sample the baseband signal BB that is not stored in the signal storage units 181a and 181b at a cycle shorter than the scanning period and perform frequency analysis. As a result, the Doppler frequency discriminating units 182a and 182b detect the phase and intensity of the Doppler frequency component in the range gate where the Doppler frequency component that is equal to or higher than the predetermined threshold is detected.
- FIG. 13 is a flowchart showing the operation of the radar apparatus according to the present embodiment.
- the radar apparatus operates in the first operation mode (step S301).
- a specific operation in the first operation mode is shown in FIG.
- control unit 210 sets the switches 286a, 286b, 286c, and 286d on the signal storage units 181a and 181b side (step S401).
- the memory control unit 185 stores the received signals obtained by performing the range scan M times for all the N range gates covering the distance range to be observed in the signal storage units 181a and 181b. That is, the memory control unit 185 writes the N baseband signals R1j to RNj in the same scanning period in the signal storage units 181a and 181b (step S402). Thereafter, the memory control unit 185 determines whether or not the writing of the baseband signal is completed for the entire scanning period (step S403). If not completed (No in step S403), the memory control unit 185 returns to the baseband signal writing process (step S402).
- the memory control unit 185 causes the M baseband signals Ri1 to RiM of the scanning periods having the same range gate and different from each other. Are read sequentially (step S404).
- the Doppler frequency discriminating unit 182a and the Doppler frequency discriminating unit 182b perform frequency analysis on the M baseband signals Ri1 to RiM read from the signal storage units 181a and 181b by the memory control unit 185 for each range gate. That is, the Doppler frequency discriminating unit 182a and the Doppler frequency discriminating unit 182b discriminate the Doppler frequency (Step S405).
- steps S402 to S405 are the same as steps S101 to S104 described with reference to FIG.
- the object detection unit 284 specifies the range gate where the target exists. In other words, the object detection unit 284 determines whether there is a Doppler frequency at which an intensity that is equal to or greater than a predetermined threshold is detected (step S302). In the processing so far, the radar apparatus obtains the direction of the target by performing the same processing as in the first embodiment.
- step S302 When it is determined by the object detection unit 284 that there is a Doppler frequency at which an intensity equal to or greater than a predetermined threshold is detected (Yes in step S302), the radar apparatus operates in the second operation mode (step S303). On the other hand, when it is determined that there is no Doppler frequency at which the intensity equal to or greater than the predetermined threshold is detected (No in step S302), the radar apparatus ends the process.
- FIG. 15 is a flowchart showing in detail the operation in the second operation mode (step S303).
- control unit 210 sets the switches 286a, 286b, 286c, and 286d on the down sample unit 287a and 287b side (step S501).
- Step S502 the control unit 210 generates a delay code M2 corresponding to the range gate Ri ′.
- the transmission antenna 105 radiates the transmission signal RF OUT generated by the transmission unit 104 as a radiated wave rad_w (step S503).
- the reflected waves ref_w reflected by the target 200 are received by the receiving antennas 106a and 106b (step S504), and the received reflected waves ref_w are despread and orthogonally demodulated by the receiving units 107a and 107b, and then baseband.
- a signal is output to the signal processing unit 208.
- the switches 286a, 286b, 286c, and 286d are set on the down-sampling units 287a and 287b, so that the baseband signal input to the signal processing unit 208 is input to the down-sampling units 287a and 287b.
- the baseband signals input to the down-samplers 287a and 287b are down-sampled and then output to the Doppler frequency discriminators 182a and 182b. That is, in the second operation mode, the Doppler frequency discriminating units 182a and 182b discriminate the Doppler frequency of the down-sampled baseband signal (Step S505).
- the arrival direction calculation unit 183 estimates the arrival direction of the reflected wave ref_w (step S506).
- the control unit 210 determines whether or not the arrival direction estimation has been completed for all of the range gates Ri ′ in which the Doppler frequency components having the intensity equal to or greater than the predetermined threshold detected in Step S302 are detected (Step S302). In S507), if completed (Yes in Step S507), the operation in the second operation mode is terminated.
- control unit 210 determines the delay code corresponding to the next range gate among the range gates Ri ′ in which the Doppler frequency component having an intensity equal to or greater than the predetermined threshold is detected. M2 is generated (step S508), and the above radiation processing (step S503) and subsequent steps are repeated.
- the control unit 210 fixes the range gate for each of the range gates Ri ′ in which the Doppler frequency components having an intensity equal to or greater than a predetermined threshold are detected.
- the control unit 210 provides the output signals of the downsampling units 287a and 287b to the Doppler frequency discriminating units 182a and 182b, respectively.
- the Doppler frequency discriminating units 182a and 182b execute Doppler frequency discrimination processing, and output the signal strength to the object detection unit 284 and the phase to the arrival direction calculation unit 183.
- the object detection unit 284 updates the arrival direction information corresponding to the currently set range gate according to the output signal of the arrival direction calculation unit 183.
- the calculation result of the arrival direction calculation unit 183 is a highly accurate calculation result with few errors because the noise energy is reduced by the down-sampling units 287a and 287b. Therefore, the radar apparatus can estimate the arrival direction with high accuracy for the extracted target.
- the range gate extraction points may include the range gate that gives the peak value of the correlation waveform described in the first embodiment and the range gate adjacent to the peak.
- the detailed distance of the target can be obtained by the procedure shown in the modification of the first embodiment.
- the noise is reduced by the effect of the downsampling units 287a and 287b, a more accurate result can be obtained.
- the radar apparatus returns to the first step and repeats this.
- the number of range gates Ri ′ in which Doppler frequency components having an intensity equal to or greater than a predetermined threshold are detected is two points or less than the total number N of range gates. That is, it is desirable that the predetermined threshold value in step S302 be a value such that the number of range gates Ri ′ whose strength is determined to be equal to or greater than the threshold value is equal to or less than N ⁇ 2.
- the predetermined threshold value in step S302 be a value such that the number of range gates Ri ′ whose strength is determined to be equal to or greater than the threshold value is equal to or less than N ⁇ 2.
- the object when the object is to observe a distant target in detail, it may be extracted from a distant target.
- the time for executing the Doppler frequency discrimination processing for all the range gates via the signal storage units 181a and 181 and the down-sampling unit 287a for any one of the range gates The time for executing the Doppler frequency discrimination process via 287b is equal. Therefore, the processing time of the entire radar apparatus can be shortened by this procedure as compared with the case where all the N range gates are always processed via the downsample units 287a and 287b.
- observation time of the baseband signal required for the frequency analysis by the Doppler frequency discriminators 182a and 182b in the second operation mode may be equal to the time required for repeating the scanning period M times.
- the speed resolution can be made equal to each other, so that deterioration of the speed resolution can be suppressed.
- the radar apparatus is substantially the same as the radar apparatus 100 according to the first embodiment, but is the same as the first operation mode in which the delay code generation unit 103b repeats the scanning process M times.
- the control unit 210 controls the second operation mode in which the delay code M2 is repeatedly generated.
- the intensity detected by the Doppler frequency discriminators 182a and 182b is equal to or greater than a predetermined threshold value. Is determined, and when it is determined that there is a Doppler frequency component that is equal to or greater than a predetermined threshold, the operation mode is switched to the second operation mode.
- the delay code generation unit 103b The delay code M2 corresponding to the range gate Ri ′ in which the Doppler frequency component equal to or higher than the predetermined threshold is detected is repeatedly generated, and the signal storage unit 181 is generated. And 181b do not store the detection signal despread and detected using the delay code corresponding to the range gate Ri ′, and the Doppler frequency discrimination units 182a and 182b do not store the detection signals stored in the signal storage units 181a and 181b.
- the Doppler frequency discrimination units 182a and 182b do not store the detection signals stored in the signal storage units 181a and 181b.
- the radar apparatus according to the present embodiment can measure the distance and direction of the target with higher accuracy than the radar apparatus 100 according to the first embodiment.
- the present invention may be realized not only as the above-described radar apparatus but also as a method for processing a baseband signal (also referred to as a detection signal) of the radar apparatus.
- the present invention may be realized as a program for causing a signal processor in the radar apparatus to execute this method.
- the above radar device may be specifically configured as a computer system including a microprocessor, a ROM, a RAM, a hard disk drive, a display unit, a keyboard, a mouse, and the like.
- a computer program is stored in the RAM or hard disk drive.
- Each device achieves its functions by the microprocessor operating according to the computer program.
- the computer program is configured by combining a plurality of instruction codes indicating instructions for the computer in order to achieve a predetermined function.
- the present invention provides a computer-readable non-volatile recording medium such as a flexible disk, hard disk, CD-ROM, MO, DVD, DVD-ROM, DVD-RAM, BD (Blu-ray Disc ( (Registered trademark)), or recorded in a semiconductor memory or the like. Further, the present invention may be digital signals recorded on these nonvolatile recording media.
- the computer program or the digital signal may be transmitted via an electric communication line, a wireless or wired communication line, a network represented by the Internet, a data broadcast, or the like.
- an M-sequence code is used as the spreading code M1 and the delay code M2.
- a Gold code combining the M-sequence codes may be used.
- the radar apparatus may be provided with a function for estimating the shape of the target and applied as a radar imaging apparatus.
- the radar apparatus is stationary, but may be moving.
- the radar apparatus may further estimate the visual direction speed of the target.
- the direction-of-arrival calculation unit 183 further estimates the gaze direction velocity, which is the velocity at which the target is viewed from the radar device, from the Doppler frequency component whose intensity detected by the Doppler frequency discriminating unit is equal to or greater than a predetermined threshold. May be.
- the radar apparatus can estimate the line-of-sight direction velocity of the target, so that advanced judgment such as prediction of the approach of the target is possible.
- the radar apparatus 100 calculates the distance from the radar apparatus 100 of the range gate where the Doppler frequency component in which the intensity detected by the Doppler frequency discriminating units 182a and 182b is equal to or greater than a predetermined threshold is detected.
- the distance from the radar apparatus 100 to the target 200 is estimated.
- This threshold value may be a constant value regardless of the distance from the radar apparatus 100, and is evaluated in units of electric power in consideration of the fact that the intensity of the reflected signal decreases due to propagation loss according to the distance from the radar apparatus 100.
- the threshold value of the intensity may be a value that decreases with the fourth power of the distance. That is, this threshold value may be a constant value regardless of the range gate, or may be a value that becomes smaller by the fourth power of the distance corresponding to the range gate.
- the radar apparatus switches to the second operation mode when it is determined that there is a Doppler frequency component that is equal to or higher than a predetermined threshold in the first operation mode.
- this threshold value may be a constant value regardless of the distance from the radar apparatus, or may be a value that decreases with the fourth power of the distance from the radar apparatus.
- the radar apparatus may lengthen the spread code range gate as the line-of-sight speed of the target 200 detected by the object detection unit 184 increases. In other words, the radar apparatus may decrease the code speed of the spread code M1 as the line-of-sight speed of the target 200 increases. Accordingly, the line-of-sight speed and direction of the target 200 can be detected by the object detection unit 184 and the arrival direction calculation unit 183 without lowering the distance measurement accuracy.
- the transmitter 104 and the receivers 107a and 107b are configured to distribute the carrier wave LO from the oscillator 101 by the distributors 102a and 102b, and the receivers 107a and 107b are directly demodulated at the same frequency f0 as the carrier wave LO.
- the conversion method is adopted, the present invention is not limited to this configuration. If a means for converting to a baseband signal is provided, another configuration that can be conceived by those skilled in the art may be used, and in this case, the effect of the present invention can be exhibited.
- a code-modulated wave may be used as a method for separating the range gate.
- the receiving units 107a and 107b may use despreading using a delayed code, a superheterodyne method, a Low-IF method, or the like. Needless to say, coherent reception with phase synchronization among a plurality of antennas is necessary in the idea of the present invention in which the direction of an object is estimated using a phase difference between antennas.
- the M delay codes M2 generated by the delay code generation unit 103b are codes that are sequentially shifted bit by bit with respect to the transmission code M1, but the present invention is not limited to this.
- the delay code M2 may be a code that is randomly shifted from the transmission code M1 by an integer multiple of 1 bit.
- the radar device can be realized as an on-vehicle radar device mounted on a vehicle.
- the radar device of the present invention can be used as a device for avoiding danger mounted on various devices such as automobiles, ships, airplanes, and robots, and a device for detecting a suspicious person in a security system.
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Abstract
Description
図1は、実施の形態1に係るレーダ装置100の構成を示すブロック図である。なお、図1には、レーダ装置100が検知する対象であるターゲット(対象物)200a及び200bも併せて図示されている。
発振器101は、周波数がf0の局部発振信号(搬送波とも言う)LOを生成する。搬送波LOの周波数f0としては、例えば60GHzの周波数帯を使用する。なお、発振器101は、搬送波LOの周波数f0を直接生成する構成であっても、外部で生成された信号を逓倍することにより所望の周波数f0の搬送波LOを生成する構成であってもよい。
分配器102a及び102bは、入力信号を分配することで、入力信号と同一の周波数を有する2つの信号を出力する。具体的には、分配器102aは、発振器101で生成された搬送波LOを分配することで、搬送波LOと同一の周波数f0を有する2つの信号を生成し、当該2つの信号の一方を送信部104に、他方を分配器102bに出力する。一方、分配器102bは、分配器102aから入力された信号を分配することで、当該入力された信号と同一の周波数、つまり搬送波LOと同一の周波数f0を有する2つの信号を生成し、当該2つの信号の一方を受信部107aに、他方を受信部107bに出力する。つまり、分配器102a及び102bは、送信部104、受信部107a及び107bに、発振器101で生成された、周波数f0の搬送波LOを出力する。
拡散符号発生部103aは、スペクトラム拡散に使用する拡散符号を発生する。拡散符号は、例えばビットレート250MbpsのM系列符号の拡散符号(以下、M1と言う)である。なお、拡散符号発生部103aにより発生される拡散符号M1は、本発明の送信拡散符号に相当する。
送信部104は、拡散符号発生部103aで発生された拡散符号M1を用いて、局部発振信号LO(搬送波)を拡散することで、送信信号(以下、RF OUTと言う)を生成する。例えば、送信部104は、図2に示すような構成として実現され、搬送波LOと拡散符号M1とを乗算する拡散ミキサ141と、拡散ミキサ141で拡散された搬送波LOを増幅することにより送信信号RF OUTを生成する増幅器142とを備える。増幅器142は、例えば、レーダ装置100から放射される電波を法規制により定められた適切なレベルに設定するために、拡散ミキサ141で拡散された搬送波LOを当該適切なレベルに増幅する。
図1において、送信アンテナ105は、送信部104で生成された送信信号RF OUTを放射波(以下、rad_wと言う)として放射する。
受信アンテナ106a及び106bは、受信した反射波ref_wを入力信号(以下、RF INと言う)として対応する受信部107a及び107bへ出力する。言い換えると、受信アンテナ106aで受信された反射波ref_wは、受信部107aに入力信号RF INとして入力される。一方、受信アンテナ106bで受信された反射波ref_wは、受信部107bに入力信号RF INとして入力される。
受信部107aは、遅延符号発生部103bで発生された遅延符号M2を用いて、受信アンテナ106aで受信された反射波ref_wを逆拡散する。さらに、受信部107aは、逆拡散した反射波ref_wを搬送波LOを用いて直交復調(直交検波とも言う)することで、同相信号(Ia)及び直交信号(Qa)を生成する。この同相信号(Ia)は、受信部107aで逆拡散された反射波ref_wの、搬送波LOと同相の位相成分に対応する信号である。一方、直交信号(Qa)は、受信部107aで逆拡散された反射波ref_wの、搬送波LOと直交する位相成分に対応する信号である。これら同相信号(Ia)及び直交信号(Qa)は、受信アンテナ106aで受信された反射波ref_wの強度及び位相に対応する第1複素ベースバンド信号BBaを構成する。
INを逆拡散する。この逆拡散された信号を、「被逆拡散波」と呼ぶ。
制御部110は、拡散符号発生部103aが発生する拡散符号M1に対し、遅延符号発生部103bが発生する遅延符号M2の遅延時間をあらかじめ決められた順で設定する。この制御部110は、各レンジゲートに対応する遅延時間を決定し、当該遅延時間を遅延符号発生部103bに指示する。
信号処理部108は、例えばDSP(Digital Signal Processor)である。この信号処理部108は、受信部107aで生成された同相信号(Ia)及び直交信号(Qa)から構成される第1複素ベースバンド信号BBaと、受信部107bで生成された同相信号(Ib)及び直交信号(Qb)から構成される第2複素ベースバンド信号BBbとを信号処理する。また、信号処理部108は、信号記憶部181a及び181bと、ドップラ周波数弁別部182a及び182bと、到来方向計算部183と、物体検出部184と、メモリ制御部185とを備える。
また、実施の形態1の構成において、物体検出部184はレンジゲートを単位として離散的にターゲットの存在位置を検出することができるが、さらに物体検出部184は、拡散符号M1及び遅延符号M2の符号速度CRに対し、光速cを用いて計算されるレンジゲートの長さRG=c/(2×CR)よりも詳細に、すなわち、レンジゲートの中の詳細な存在位置を求めてもよい。
次に、実施の形態2に係るレーダ装置について説明する。
101 発振器
102a、102b、172a、172b 分配器
103a 拡散符号発生部
103b 遅延符号発生部
104 送信部
105、911 送信アンテナ
106、106a、106b、912、913 受信アンテナ
107a、107b、107 受信部
108、208 信号処理部
110、210 制御部
141 拡散ミキサ
142 増幅器
171 逆拡散ミキサ
173a、173b 復調ミキサ
174 移相器
175 受信アンプ
181、181a、181b 信号記憶部
182、182a、182b ドップラ周波数弁別部
183 到来方向計算部
184、284 物体検出部
185 メモリ制御部
200、200a、200b、931~933、 ターゲット
287a、287b ダウンサンプル部
286a、286b、286c、286d スイッチ
910 送信器
920、930 受信器
rad_w 放射波
ref_w 反射波
Claims (13)
- レーダイメージング装置であって、
送信拡散符号を用いて搬送波を拡散することで送信信号を生成する送信部と、
前記送信信号を放射波として放射する送信アンテナと、
前記放射波が物体により反射された反射波を受信する複数の受信アンテナと、
前記レーダイメージング装置からの距離が異なるN(Nは2以上の整数)個の探索レンジを走査するための走査期間内に、前記送信拡散符号と同一の符号であって前記距離に対応するN個の遅延符号を順次発生する走査処理を、M(Mは2以上の整数)走査期間にわたって繰り返す遅延符号発生部と、
前記複数の受信アンテナにそれぞれ対応し、各々が、前記N個の遅延符号を順次用いて対応する受信アンテナで受信された反射波を逆拡散する複数の逆拡散部と、
前記複数の逆拡散部にそれぞれ対応し、各々が、前記搬送波を用いて対応する逆拡散部で逆拡散された反射波を直交検波することにより、対応する受信アンテナで受信された反射波に応じた検波信号Rij(iは1からNの整数、jは1からMの整数)を生成する複数の検波部と、
前記遅延符号発生部における遅延時間及び走査期間に対応づけて、前記複数の検波部のそれぞれで生成された検波信号Rijを記憶する記憶部と、
前記遅延符号発生部における前記N個の遅延符号に対応する互いに異なる前記距離及び1つの走査期間に対応するN個の前記検波信号R1j~RNjを前記記憶部に前記M走査期間繰り返し書き込み、前記距離が同一かつ互いに異なる走査期間に対応するM個の検波信号Ri1~RiMの組を前記記憶部から順次読み出す記憶制御部と、
前記記憶制御部により読み出された前記距離が同一のM個の検波信号Ri1~RiMを周波数分析することによって、各探索レンジにおける前記反射波と前記搬送波との差分の周波数成分であるドップラ周波数成分と、当該ドップラ周波数成分に対応する位相及び強度を、前記複数の検波部のそれぞれに対応して検出するドップラ周波数検出部と、
検出された前記複数の検波部のそれぞれに対応する位相から前記複数の検波部間の位相差を算出し、算出した位相差から各探索レンジにおける前記反射波の到来方向を検出することにより前記物体の方向を推定する方向推定部とを備える
レーダイメージング装置。 - 前記方向推定部は、前記ドップラ周波数検出部で検出された強度が所定の第1閾値以上となるドップラ周波数成分を含む前記反射波の到来方向を前記物体の方向と推定する
請求項1記載のレーダイメージング装置。 - さらに、前記ドップラ周波数検出部で検出された強度が前記所定の第1閾値以上となるドップラ周波数成分が検出された探索レンジの前記距離を、前記レーダイメージング装置から前記物体までの距離として推定する距離推定部を備える
請求項2記載のレーダイメージング装置。 - 前記方向推定部は、さらに、前記ドップラ周波数検出部で検出された強度が前記所定の第1閾値以上となるドップラ周波数成分から、前記レーダイメージング装置から前記物体を見た速度である視線方向速度を推定する
請求項2又は3記載のレーダイメージング装置。 - 前記N個の遅延符号は、前記送信拡散符号に対して互いに異なる遅延時間を有し、
前記遅延時間は、前記送信拡散符号の1ビットを与える時間であるビット時間の整数倍である
請求項1~4のいずれか1項に記載のレーダイメージング装置。 - 前記遅延時間は、前記ビット時間のK(Kは整数)倍からK+N-1倍のいずれかであり、
前記走査処理は、前記遅延時間を前記ビット時間のK倍からK+N-1倍まで前記ビット時間ずつ順次増加させる、又は、前記遅延時間を前記ビット時間のK+N-1倍からK倍まで前記ビット時間ずつ順次減少させることにより、前記N個の遅延符号を発生する
請求項5記載のレーダイメージング装置。 - 前記距離推定部は、
前記ドップラ周波数検出部で検出されたドップラ周波数成分毎の前記遅延時間に対する当該ドップラ周波数成分の強度の分布から、強度が極大となるピーク強度を特定し、
特定したピーク強度と、特定したピーク強度に対応する遅延時間より前記ビット時間だけ短い遅延時間に対する強度であるピーク前強度と、特定したピーク強度に対応する遅延時間より前記ビット時間だけ長い遅延時間に対する強度であるピーク後強度とを用いて補間処理することにより、前記ビット時間に対応する距離よりも小さい距離を分解能として、前記レーダイメージング装置から前記物体までの距離を推定する
請求項5又は6記載のレーダイメージング装置。 - 前記搬送波の周波数をf0、前記レーダイメージング装置から前記物体を見た速度である視線方向速度の想定される最大値をvmax、前記視線方向速度の検出可能な分解能をvresとすると、前記送信拡散符号及び前記遅延符号の符号速度CRは、
CR≦2×f0×vres/vmax
を満たす
請求項1~6のいずれか1項に記載のレーダイメージング装置。 - 前記レーダイメージング装置は、さらに、
前記遅延符号発生部が前記走査処理をM回繰り返す第1動作モードと、同一の遅延符号を繰り返し発生する第2動作モードとを制御する制御部を備え、
前記制御部は、
前記第1動作モードにおいて、前記ドップラ周波数検出部で検出された強度が所定の第2閾値以上となるドップラ周波数成分があるか否かを判断し、前記所定の第2閾値以上となるドップラ周波数成分があると判断した場合に前記第2動作モードに切り替え、
前記第2動作モードにおいて、
前記遅延符号発生部は、前記所定の第2閾値以上となるドップラ周波数成分が検出された探索レンジに対応する前記遅延符号を繰り返し発生し、
前記記憶部は、当該探索レンジに対応する前記遅延符号を用いて逆拡散及び検波された検波信号を記憶せず、
前記ドップラ周波数検出部は、前記記憶部に記憶されない検波信号を前記走査期間よりも短い周期でサンプリングして周波数分析することによって、前記所定の第2閾値以上となるドップラ周波数成分が検出された探索レンジにおける当該ドップラ周波数成分の位相及び強度を再度検出する
請求項1~7のいずれか1項に記載のレーダイメージング装置。 - 前記第2動作モードにおいて、前記ドップラ周波数検出部が前記周波数分析するために要した前記検波信号の観測時間は、前記走査期間をM回繰り返すために要した時間と同等である
請求項9記載のレーダイメージング装置。 - 前記所定の第2閾値は、前記強度が前記所定の第2閾値以上であると判断される前記探索レンジがN-2個以下となるような値である
請求項9又は10記載のレーダイメージング装置。 - 送信拡散符号を用いて搬送波を拡散することで送信信号を生成する送信部と、前記送信信号を放射波として放射する送信アンテナと、前記放射波が物体により反射された反射波を受信する複数の受信アンテナと、前記レーダイメージング装置からの距離が異なるN(Nは2以上の整数)個の探索レンジを走査するための走査期間内に前記送信拡散符号と同一の符号であって前記距離に対応するN個の遅延符号を順次発生する走査処理を、M(Mは2以上の整数)走査期間にわたって繰り返す遅延符号発生部と、前記複数の受信アンテナにそれぞれ対応し、各々が、前記N個の遅延符号を順次用いて対応する受信アンテナで受信された反射波を逆拡散する複数の逆拡散部と、前記複数の逆拡散部にそれぞれ対応し、各々が、前記搬送波を用いて対応する逆拡散部で逆拡散された反射波を直交検波することにより、対応する受信アンテナで受信された反射波に応じた検波信号Rij(iは1からNの整数、jは1からMの整数)を生成する複数の検波部とを備えるレーダイメージング装置のためのイメージング方法であって、
前記遅延符号発生部における前記N個の遅延符号に対応する互いに異なる前記距離及び1つの走査期間に対応するN個の前記検波信号R1j~RNjを記憶部に前記M走査期間繰り返し書き込む書き込みステップと、
前記書き込みステップで書き込まれた前記記憶部から、前記距離が同一かつ互いに異なる走査期間に対応するM個の検波信号Ri1~RiMの組を順次読み出す読み出しステップと、
読み出された前記距離が同一のM個の検波信号Ri1~RiMを周波数分析することによって、各探索レンジにおける前記反射波と前記搬送波との差分の周波数成分であるドップラ周波数成分と、当該ドップラ周波数成分に対応する位相及び強度を、前記複数の受信アンテナのそれぞれに対応して検出するドップラ周波数検出ステップと、
検出された前記複数の受信アンテナのそれぞれに対応する位相から前記複数の受信アンテナ間の位相差を算出し、算出した位相差から各探索レンジにおける前記反射波の到来方向を検出することにより前記物体の方向を推定する方向推定ステップとを含む
イメージング方法。 - 請求項12記載のイメージング方法を前記レーダイメージング装置内の信号処理プロセッサに実行させるためのプログラム。
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WO2024185715A1 (ja) * | 2023-03-07 | 2024-09-12 | 京セラ株式会社 | 電子機器、電子機器の制御方法、及びプログラム |
Also Published As
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US8686894B2 (en) | 2014-04-01 |
CN102763001A (zh) | 2012-10-31 |
JP4977806B2 (ja) | 2012-07-18 |
US20120293359A1 (en) | 2012-11-22 |
JPWO2012020530A1 (ja) | 2013-10-28 |
CN102763001B (zh) | 2014-08-20 |
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