The present disclosure relates to a distance measurement device for and a distance measurement method of calculating the distance from the distance measurement device to a distance measurement target, and a radar device including the distance measurement device.
Among distance measurement devices, there is a distance measurement device (referred to as “conventional distance measurement device” hereinafter) which includes an FFT converter to perform a fast Fourier transform (FFT) on a digital signal showing interference light between reflected light which is received from a distance measurement target by applying part of frequency swept light to the distance measurement target and reference light which is the remaining part of the frequency swept light, and which calculates the distance from the distance measurement device to the distance measurement target on the basis of a signal after the FFT by the FFT converter.
Incidentally, there is a millimeter wave radar device which includes a zoom FFT converter to perform a zoom FFT on a digital signal (for example, refer to Patent Literature 1). The zoom FFT converter thins out part of the digital signal, and performs an FFT on the digital signal after the thinning out.
Patent Literature 1: JP 2003-43139 A
In the conventional distance measurement device, an increase in the number of sampling points of the FFT in the FFT converter makes it possible to improve the accuracy of the calculation of distance as the frequency resolution is improved. However, it is difficult to increase the number of sampling points of the FFT without limitation. Therefore, the conventional distance measurement device has a problem that, since it does not acquire a desired frequency resolution, it cannot provide desired accuracy of the calculation of distance.
There is a case in which the application of the zoom FFT converter disclosed in Patent Literature 1 to a conventional distance measurement device increases the frequency resolution even in the case where the number of sampling points is the same as those in the conventional distance measurement device. However, since the zoom FFT converter thins out part of the digital signal, it sometimes leads to a situation where a spurious signal is generated or where a desired signal is buried in noise. Under such a situation where a spurious signal is generated or a desired signal is buried in noise, there is a case in which the distance cannot be calculated even though the frequency resolution is improved, and the above-mentioned problem cannot be solved.
The present disclosure is made in order to solve the above-mentioned problem, and it is therefore an object of the present disclosure to provide a distance measurement device and a distance measurement method capable of improving the accuracy of the calculation of distance compared to the conventional distance measurement device even though the number of sampling points is the same as those in the conventional distance measurement device.
A distance measurement device according to present disclosure includes; processing circuitry to divide a digital signal into N digital signals (N is an integer equal to or greater than 2), the digital signal showing interference light between reflected light which is received from a distance measurement target by applying part of frequency swept light whose frequency varies with time to the distance measurement target, and to reference light which is the remaining part of the frequency swept light; to shift a frequency of each of the N digital signals after distribution by shift amounts that are different from each other; to perform a Fourier transform on each of the N digital signals after frequency shift; and to determine a frequency component related to the distance measurement target, out of a plurality of frequency components contained in all of N signals after the Fourier transform, to determine a shift amount related to a signal after the Fourier transform which includes the determined frequency component, out of a plurality of shift amounts which are used for the shift of the frequency, and to calculate the distance from the distance measurement device to the distance measurement target from the sum of the frequency of the determined frequency component and the determined shift amount.
According to the present disclosure, the accuracy of the calculation of distance can be improved compared to the conventional distance measurement device even though the number of sampling points is the same as those in the conventional distance measurement device.
Hereinafter, in order to explain the present disclosure in greater detail, embodiments of the present disclosure will be described with reference to the accompanying drawings.
The radar device shown in
The optical transmission and reception unit 1 applies part of frequency swept light whose frequency varies with time to a distance measurement target, and, after that, receives reflected light which is the frequency swept light reflected by the distance measurement target.
The optical transmission and reception unit 1 outputs a digital signal f(t) showing interference light between the reflected light and reference light which is the remaining part of the frequency swept light to the distance measurement device 2. “t” is a time.
The optical transmission and reception unit 1 includes a frequency swept light source 11, an optical branching unit 12, a sensor head unit 15, an optical interferometer 17, an optical detector 18 and an analog to digital converter (referred to as an “A/D converter” hereinafter) 19.
The frequency swept light source 11 outputs the frequency swept light whose frequency varies with time to the optical branching unit 12.
The frequency of the frequency swept light varies from a minimum frequency fmin to a maximum frequency fmax with time. When the frequency of the frequency swept light reaches the maximum frequency fmax, the frequency of the frequency swept light temporarily returns to the minimum frequency fmin, and, after that, varies from the minimum frequency fmin to the maximum frequency fmax again.
The optical branching unit 12 includes an optical coupler 13 and a circulator 14.
The optical coupler 13 divides the frequency swept light outputted from the frequency swept light source 11 into irradiation light and the reference light.
The optical coupler 13 outputs the irradiation light to the circulator 14, and outputs the reference light to the optical interferometer 17.
The circulator 14 outputs the irradiation light outputted from the optical coupler 13 to a condensing optical element 16 of the sensor head unit 15.
The circulator 14 outputs reflected light outputted from the condensing optical element 16 to the optical interferometer 17.
The sensor head unit 15 includes the condensing optical element 16.
The condensing optical element 16 is implemented by, for example, two aspheric lenses.
The condensing optical element 16 condenses the irradiation light outputted from the circulator 14 to the distance measurement target.
More specifically, a previous-stage aspheric lens, out of the two aspheric lenses which the condensing optical element 16 includes, converts the irradiation light outputted from the circulator 14 into collimated light.
By condensing the collimated light after the conversion by the previous-stage aspheric lens, a next-stage aspheric lens applies the light to the distance measurement target.
Further, the condensing optical element 16 condenses light reflected from the distance measurement target, and outputs the reflected light to the circulator 14.
The optical interferometer 17 generates interference light between the reflected light outputted from the circulator 14 and the reference light outputted from the optical coupler 13, and outputs the interference light to the optical detector 18.
The optical detector 18 detects the interference light outputted from the optical interferometer 17, and converts the interference light into an electric signal.
The optical detector 18 outputs the electric signal to the A/D converter 19.
The A/D converter 19 converts the analog electric signal outputted from the optical detector 18 from an analog signal into a digital signal f(t), and outputs the digital signal f(t) to the distance measurement device 2.
The distance measurement device 2 shown in
The signal division unit 21 is implemented by, for example, a signal division circuit 31 shown in
The signal division unit 21 divides the digital signal f(t) outputted from the optical transmission and reception unit 1 into N signals. N is an integer equal to or greater than 2.
The signal division unit 21 outputs the N digital signals f(t) to the frequency shift unit 22.
The frequency shift unit 22 is implemented by, for example, a frequency shift circuit 32 shown in
The frequency shift unit 22 includes N frequency shift processing units 23-1 to 23-N.
The frequency shift unit 22 shifts the frequency of each of the N digital signals after the distribution by the signal division unit 21 by shift amounts that are different from each other.
The frequency shift unit 22 outputs N digital signals f(t)×exp(jω1t) to f(t)×exp(jωNt) after the frequency shift to the Fourier transform unit 24.
The frequency shift processing unit 23-1 shifts the frequency of the digital signal f(t) outputted from the optical transmission and reception unit 1 by a shift amount Δf1, and outputs a digital signal f(t)×exp(jω1t) after the frequency shift to a Fourier transform processing unit 25-1 of the Fourier transform unit 24. ω1 is an angular frequency which is the multiplication of the shift amount Δf1 by 2π.
In the distance measurement device 2 shown in
Therefore, the distance measurement device 2 does not need to include the frequency shift processing unit 23-1, and the optical transmission and reception unit 1 and the Fourier transform processing unit 24-1 may be connected directly.
However, the case of the shift amount Δf1=0 is an example, and there may be a case of the shift amount Δf1≠0. In the case where the shift amount Δf1≠0, the distance measurement device 2 needs to include the frequency shift processing unit 23-1.
The frequency shift processing unit 23-2 shifts the frequency of the digital signal f(t) outputted from the optical transmission and reception unit 1 by a shift amount Δf2, and outputs a digital signal f(t)×exp(jω2t) after the frequency shift to a Fourier transform processing unit 25-2 of the Fourier transform unit 24. ω2 is an angular frequency which is the multiplication of the shift amount Δf2 by 2π.
The frequency shift processing unit 23-3 shifts the frequency of the digital signal f(t) outputted from the optical transmission and reception unit 1 by a shift amount Δf3, and outputs a digital signal f(t)×exp(jω3t) after the frequency shift to a Fourier transform processing unit 25-3 of the Fourier transform unit 24. ω3 is an angular frequency which is the multiplication of the shift amount Δf3 by 2π.
The frequency shift processing unit 23-N shifts the frequency of the digital signal f(t) outputted from the optical transmission and reception unit 1 by a shift amount ΔfN, and outputs a digital signal f(t)×exp(jωNt) after the frequency shift to a Fourier transform processing unit 25-N of the Fourier transform unit 24. ωN is an angular frequency which is the multiplication of the shift amount ΔfN by 2π, wherein
Δf1<Δf2<Δf3< . . . <ΔfN.
The Fourier transform unit 24 is implemented by, for example, a Fourier transform circuit 33 shown in
The Fourier transform unit 24 includes the N Fourier transform processing units 25-1 to 25-N.
The Fourier transform unit 24 performs a Fourier transform on each of the N digital signals f(t)×exp(jωnt) (n=1, . . . , N) after the frequency shift by the frequency shift unit 22.
The Fourier transform unit 24 outputs N signals F1(f) to FN(f) after the Fourier transform to the distance calculation unit 26. f is the frequency.
The Fourier transform processing unit 25-1 performs a Fourier transform on the digital signal f(t)×exp(jω1t) after the frequency shift by the frequency shift processing unit 23-1.
The Fourier transform processing unit 25-1 outputs the signal F1(f) after the Fourier transform to the distance calculation unit 26.
The Fourier transform processing unit 25-2 performs a Fourier transform on the digital signal f(t)×exp(jω2t) after the frequency shift by the frequency shift processing unit 23-2.
The Fourier transform processing unit 25-2 outputs the signal F2(f) after the Fourier transform to the distance calculation unit 26.
The Fourier transform processing unit 25-3 performs a Fourier transform on the digital signal f(t)×exp(jω3t) after the frequency shift by the frequency shift processing unit 23-3.
The Fourier transform processing unit 25-3 outputs the signal F3(f) after the Fourier transform to the distance calculation unit 26.
The Fourier transform processing unit 25-N performs a Fourier transform on the digital signal f(t)×exp(jωNt) after the frequency shift by the frequency shift processing unit 23-N.
The Fourier transform processing unit 25-N outputs the signal FN(f) after the Fourier transform to the distance calculation unit 26.
The distance calculation unit 26 is implemented by, for example, a distance calculation circuit 34 shown in
The distance calculation unit 26 includes a frequency component determination unit 27, a shift amount determination unit 28 and a distance calculation processing unit 29.
The distance calculation unit 26 determines a frequency component FC(fT) related to the distance measurement target, out of a plurality of frequency components contained in all of the N signals F1(f) to FN(f) after the Fourier transforms by the Fourier transform unit 24.
The distance calculation unit 26 determines a shift amount Δfn related to the signal Fn(f) after the Fourier transform which includes the determined frequency component FC(fT), out of the plurality of shift amounts Δf1 to ΔfN which are used by the frequency shift unit 22 for the shift of the frequency.
The distance calculation unit 26 calculates the distance L from the distance measurement device 2 to the distance measurement target from the sum of the frequency fT of the determined frequency component FC(fT) and the determined shift is amount Δfn.
The frequency component determination unit 27 determines the frequency component FC(fT) related to the distance measurement target, out of the plurality of frequency components contained in all of the N signals F1(f) to FN(f) after the Fourier transforms by the Fourier transform processing units 25-1 to 25-N.
The frequency component determination unit 27 outputs the frequency component FC(fT) related to the distance measurement target to the shift amount determination unit 28, and outputs the frequency fT of the determined frequency component FC(fT) to the distance calculation processing unit 29.
The shift amount determination unit 28 determines the shift amount Δfn related to the signal Fn(f) after the Fourier transform which includes the frequency component FC(fT) determined by the frequency component determination unit 27, out of the plurality of shift amounts Δf1 to ΔfN which are used by the frequency shift processing units 23-1 to 23-N for the shift of the frequency.
The shift amount determination unit 28 outputs the determined shift amount Δfn to the distance calculation processing unit 29.
The distance calculation processing unit 29 calculates the sum of the frequency fT of the frequency component FC(fT) determined by the frequency component determination unit 27, and the shift amount Δfn determined by the shift amount determination unit 28.
The distance calculation processing unit 29 calculates the distance L from the distance measurement device 2 to the distance measurement target from the sum (fT+Δfn) of the frequency fT of the frequency component FC(fT) and the shift amount Δfn.
In
Each of the following circuits: the signal division circuit 31, the frequency shift circuit 32, the Fourier transform circuit 33 and the distance calculation circuit 34 is, for example, a single circuit, a composite circuit, a programmable processor, a parallel programmable processor, an application specific integrated circuit (ASIC), a field-programmable gate array (FPGA), or a combination of these circuits.
The components of the distance measurement device 2 are not limited to ones each implemented by hardware for exclusive use, and the distance measurement device 2 may be implemented by software, firmware, or a combination of software and firmware.
The software or the firmware is stored as a program in a memory of a computer. The computer refers to hardware that executes a program, and is, for example, a central processing unit (CPU), a central processing device, a processing device, an arithmetic device, a microprocessor, a microcomputer, a processor, or a digital signal processor (DSP).
In the case where the distance measurement device 2 is implemented by software, firmware, or the like, a program for causing the computer to perform processing procedures performed in the signal division unit 21, the frequency shift unit 22, the Fourier transform unit 24 and the distance calculation unit 26 is stored in a memory 41. A processor 42 of the computer executes the program stored in the memory 41.
Further, in
Next, the operation of the radar device shown in
First, the frequency swept light source 11 of the optical transmission and reception unit 1 outputs the frequency swept light whose frequency varies with time to the optical coupler 13 of the optical branching unit 12, as shown in
When receiving the frequency swept light from the frequency swept light source 11, the optical coupler 13 divides the frequency swept light into irradiation light and reference light.
The optical coupler 13 outputs the irradiation light to the circulator 14, and outputs the reference light to the optical interferometer 17.
When receiving the irradiation light from the optical coupler 13, the circulator 14 outputs the irradiation light to the condensing optical element 16 of the sensor head unit 15.
When receiving the irradiation light from the circulator 14, the condensing optical element 16 condenses the irradiation light to the distance measurement target.
The condensing optical element 16 also condenses light reflected from the distance measurement target, and outputs the reflected light to the circulator 14.
When receiving the reflected light from the condensing optical element 16, the circulator 14 outputs the reflected light to the optical interferometer 17.
The optical interferometer 17 generates interference light between the reflected light outputted from the circulator 14 and the reference light outputted from the optical coupler 13.
The optical interferometer 17 outputs the interference light to the optical detector 18.
The optical detector 18 detects the interference light outputted from the optical interferometer 17, and converts the interference light into an electric signal.
The optical detector 18 outputs the electric signal to the A/D converter 19.
When receiving the electric signal from the optical detector 18, the A/D converter 19 converts the analog electric signal into a digital signal f(t).
The A/D converter 19 outputs the digital signal f(t) to the distance measurement device 2.
The distance measurement device 2 calculates the distance L from the distance measurement device 2 to the distance measurement target on the basis of the digital signal f(t) outputted from the optical transmission and reception unit 1.
Hereinafter, the operation of the distance measurement device 2 will be described concretely.
When receiving the digital signal f(t) from the optical transmission and reception unit 1, the signal division unit 21 divides the digital signal f(t) into N digital signals (step ST1 of
The signal division unit 21 outputs the N digital signals f(t) to the frequency shift unit 22.
The frequency shift unit 22 shifts the frequency of each of the N digital signals f(t) after the distribution by the signal division unit 21 by shift amounts that are different from each other (step ST2 of
More specifically, when receiving the digital signal f(t) from the optical transmission and reception unit 1, the frequency shift processing unit 23-n (n=1, . . . , N) is of the frequency shift unit 22 shifts the frequency of the digital signal f(t) by the shift amount Δfn, wherein Δf1<Δf2<Δf3< . . . <ΔfN.
The frequency shift processing unit 23-n outputs the digital signal f(t)×exp(jωnt) after the frequency shift to the Fourier transform processing unit 25-n of the Fourier transform unit 24.
The plurality of shift amounts Δf1 to ΔfN may be stored in an internal memory of the frequency shift processing unit 23-n, or they may be given from the outside of the distance measurement device 2.
In the distance measurement device 2 shown in
Δf1, Δf2, Δf1, . . . , ΔfN are expressed as shown by, for example, the following equations (1).
In the equations (1), R is the frequency resolution of the signal Fn(f) after the Fourier transform by the Fourier transform processing unit 25-n.
f1,max is the frequency of the maximum frequency component FC1,max out of the plurality of frequency components FC1 contained in the signal F1(f) after the Fourier transform by the Fourier transform processing unit 25-1.
The frequency resolution of the shift amounts Δf1 to ΔfN is set in accordance with the frequency resolution R of the signal Fn(f) after the Fourier transform, as shown in the equations (1). More specifically, the frequency resolution of the shift amounts Δf1 to ΔfN is set in accordance with the distance measurement resolution of the distance measurement target.
ωn is an angular frequency which is the multiplication of the shift amount Δfn by 2π.
It is necessary to make the angular frequency ωn smaller than the ratio of the sampling rate of the digital signal fit) and the number of sampling points of the FFT in the Fourier transform processing unit 25-n.
For example, in the case where the sampling rate is 1 [GSa/s], the number of sampling points of the FFT is 4,096, and N=64, the Fourier transform processing unit 25-n can calculate a peak frequency, which will be mentioned later, with the frequency resolution R of 244.1 [kHz]. Note that 244.1 [kHz]=1 [GSa/s]/4,096. Therefore, when the angular frequency is ωn=(244.1/64)×2π=3.8 [kHz]2π, the Fourier transform processing unit 25-n can calculate the peak frequency with the same frequency resolution as that in a Fourier transform processing unit whose number of sampling points of the FFT is 262,144.
When the number of sampling points of the FFT is 262,144, the frequency resolution R is 3.8 [kHz]=1 [GSa's]/262,144.
In contrast, when the number of sampling points of the FFT is 4,096, the frequency resolution R is 244.1 [kHz]=1 [GSa/s]/4,096.
For example, when the number of sampling points of the FFT is 4,096, the frequency shift unit 22 shifts the frequencies of the plurality of digital signals, respectively, by the plurality of frequency shift amounts which are mutually different by 3.8 [kHz]. When the Fourier transform unit 24 which will be mentioned later then performs an FFT on each of the digital signals after the frequency shift, the amplitude values of frequency components are acquired with the frequency resolution R of 244.1 [kHz]. There is a tendency that the closer the relationship between a frequency is component and the distance from the distance measurement device 2 to the distance measurement target is, the larger amplitude value the frequency component has.
Therefore, when the distance calculation unit 26 which will be mentioned later acquires the frequency shift amount and the peak frequency when the amplitude value of the frequency component is the largest, out of all the FFT results, the distance from the distance measurement device 2 to the distance measurement target can be acquired with the same frequency resolution R as that when the number of sampling points of the FFT is 262,144.
The Fourier transform unit 24 performs a Fourier transform on each of the N digital signals f(t)×exp(jω1t) to f(t)×exp(jωNt) after the frequency shift by the frequency shift unit 22 (step ST3 of
More specifically, the Fourier transform processing unit 25-n (n=1 . . . , N) of the Fourier transform unit 24 performs a Fourier transform on the digital signal f(t)×exp(jωnt) after the frequency shift by the frequency shift processing unit 23-1.
The Fourier transform processing unit 25-n outputs a signal Fn(f) after the Fourier transform to the distance calculation unit 26.
The frequency component determination unit 27 of the distance calculation unit 26 acquires the signals F1(f) to FN(f) after the Fourier transforms from the Fourier transform processing units 25-1 to 25-N.
The frequency component determination unit 27 compares the plurality of frequency components contained in all of the signals F1(f) to FN(f) after the Fourier transforms by the Fourier transform processing units 25-1 to 25-N with one another, thereby extracting the maximum frequency component FCn,max out of the plurality of frequency components (step ST4 of
FC1,max is the maximum frequency component out of the plurality of frequency components FC1 contained in the signal F1(f) after the Fourier transform.
FC2,max is the maximum frequency component out of the plurality of frequency components FC2 contained in the signal F2(f) after the Fourier transform.
FCn,max is the maximum frequency component out of the plurality of frequency components FCN contained in the signal FN(f) after the Fourier transform.
In
In the example of
The frequency component determination unit 27 outputs the extracted maximum frequency component FCn,max, as the frequency component FC(fT) related to the distance measurement target, to the shift amount determination unit 28.
Further, the frequency component determination unit 27 outputs the peak frequency fT which is the frequency of the maximum frequency component FCn,max to the distance calculation processing unit 29.
In the radar device shown in
The shift amount determination unit 28 acquires the frequency component FC(fT) related to the distance measurement target from the frequency component determination unit 27.
The shift amount determination unit 28 determines the shift amount Δfn related to the signal Fn(f) after the Fourier transform which includes the frequency component FC(fT), out of the plurality of shift amounts Δf1 to MN which are used by the frequency shift processing units 23-1 to 23-N for the shift of the frequency (step ST5 of
The plurality of shift amounts Δf1 to ΔfN may be stored in an internal memory of the shift amount determination unit 28, or may be given from the outside of the distance measurement device 2.
The shift amount determination unit 28 outputs the determined shift amount Δfn to the distance calculation processing unit 29.
The distance calculation processing unit 29 acquires the peak frequency fT which is the frequency of the maximum frequency component FCn,max from the frequency component determination unit 27, and acquires the shift amount Δfn from the shift amount determination unit 28.
The distance calculation processing unit 29 calculates the sum Σf of the peak frequency fT and the shift amount Δfn, as shown in the following equation (2) (step ST6 of
Σf=fT+Δfn (2)
The distance calculation processing unit 29 calculates the distance L from the distance measurement device 2 to the distance measurement target from the sum Σf of the peak frequency fT and the shift amount Δfn, as shown in the following equation (3) (step ST7 of
L=Σf×k (3)
In the equation (3), k is a coefficient related to a light sensing condition in the optical transmission and reception unit 1. The coefficient k may be stored in an internal memory of the distance calculation processing unit 29, or may be given from the outside of the distance measurement device 2.
The distance calculation processing unit 29 outputs the calculated distance L to the outside.
In above-mentioned Embodiment 1, the distance measurement device 2 is configured to include: the signal division unit 21 to divide a digital signal into N digital signals (N is an integer equal to or greater than 2), the digital signal showing interference light between reflected light which is received from a distance measurement target by applying part of frequency swept light whose frequency varies with time to the distance measurement target, and reference light which is the remaining part of the frequency swept light; the frequency shift unit 22 to shift a frequency of each of the N digital signals after distribution by the signal division unit 21 by shift amounts that are different from each other; the Fourier transform unit 24 to perform a Fourier transform on each of the N digital signals after frequency shift by the frequency shift unit 22; and the distance calculation unit 26 to determine a frequency component related to the distance measurement target, out of a plurality of frequency components contained in all of N signals after the Fourier transform by the Fourier transform unit 24, to determine a shift amount related to a signal after the Fourier transform which includes the determined frequency component, out of a plurality of shift amounts which are used by the frequency shift unit 22 for the shift of the frequency, and to calculate the distance from the distance measurement device 2 to the distance measurement target from the sum of the frequency of the determined frequency component and the determined shift amount. Therefore, the distance measurement device 2 can improve the accuracy of the calculation of the distance compared to the conventional distance measurement device even in the case where the number of sampling points is the same as that in the conventional distance measurement device.
In the Embodiment 2, a distance measurement device 2 which includes a calculator 51 instead of the signal division unit 21, the frequency shift unit 22 and the Fourier transform unit 24 will be described.
The radar device shown in
The distance measurement device 2 includes the calculator 51, a data storage unit 52 and a distance calculation unit 26.
The calculator 51 is implemented by, for example, a calculation circuit 61 shown in
The calculator 51 acquires a digital signal f(t) showing interference light from the optical transmission and reception unit 1.
The calculator 51 shifts N times the frequency of the digital signal f(t) by shift amounts Δfn (n=1, . . . , N) that are different from each other.
The calculator 51 performs a Fourier transform on each digital signal f(t)×exp(jωnt) after the frequency shift.
The calculator 51 outputs a signal Fn(f) after the Fourier transform to the data storage unit 52.
The processes of the calculator 51 are shown in the radar device shown in
The data storage unit 52 is implemented by, for example, a data storage circuit 62 shown in
The data storage unit 52 stores the signals F1(f) to FN(f) after the Fourier transform which are outputted from the calculator 51.
In
Here, the data storage circuit 62 is, for example, a non-volatile or volatile semiconductor memory, such as a random access memory (RAM), a read only memory (ROM), a flash memory, an erasable programmable read only memory (EPROM), or an electrically erasable programmable read only memory (EEPROM), a magnetic disc, a flexible disc, an optical disc, a compact disc, a mini disc, or a digital versatile disc (DVD).
Each of the following circuits: the calculation circuit 61 and the distance calculation circuit 34 is, for example, a single circuit, a composite circuit, a programmable processor, a parallel programmable processor, an ASIC, an FPGA or a combination of these circuits.
The components of the distance measurement device 2 are not limited to ones each implemented by hardware for exclusive use, and the distance measurement device 2 may be implemented by software, firmware, or a combination of software and firmware.
In the case where the distance measurement device 2 is implemented by software, firmware, or the like, the data storage unit 52 is configured on a memory 41 shown in
Further, in
Next, the operation of the radar device shown in
Since the radar device is the same as the radar device shown in
The calculator 51 acquires the digital signal f(t) showing the interference light from the optical transmission and reception unit 1.
The calculator 51 shifts N times the frequency of the digital signal f(t) by the shift amounts Δfn (n=1, . . . , N) that are different from each other.
More specifically, the calculator 51 shifts the frequency of the digital signal f(t) by the shift amounts Δfn (n=1, . . . , N) that are different from each other by serially performing the frequency shifting process N times.
In the radar device shown in
The digital signals f(t)×exp(jω1t) to f(t)×exp(jωNt) after the frequency shift which are acquired by the calculator 51 are the same as the digital signals f(t)×exp(jω1t) to f(t)×exp(jωNt) after the frequency shift which are acquired by the frequency shift processing units 23-1 to 23-N.
The calculator 51 performs a Fourier transform on each of the digital signals f(t)×exp(jωnt) after the frequency shift.
More specifically, the calculator 51 performs a Fourier transform on each of the digital signals f(t)×exp(jωnt) (n=1, . . . , N) after the frequency shift by serially performing the Fourier transform process N times.
In the radar device shown in
The signals F1(f) to FN(f) after the Fourier transforms which are acquired by the calculator 51 are the same as the signals F1(f) to FN(f) after the Fourier transforms which are acquired by the Fourier transform processing units 25-1 to 25-N.
The calculator 51 outputs the signals F1(f) to FN(f) after the Fourier transforms to the data storage unit 52.
The data storage unit 52 stores the signals F1(f) to FN(f) after the Fourier transforms which are outputted from the calculator 51.
The distance calculation unit 26 acquires the N signals F1(f) to FN(f) after the Fourier transforms from the data storage unit 52.
The distance calculation unit 26 calculates the distance L from the distance measurement device 2 to a distance measurement target from the N signals F1(f) to FN(f) after the Fourier transforms by using the method described in the Embodiment 1.
In the radar device shown in
It is to be understood that an arbitrary combination of the above-mentioned is embodiments can be made, various changes can be made in an arbitrary component according to any one of the above-mentioned embodiments, or an arbitrary component according to any one of the above-mentioned embodiments can be omitted.
The present disclosure is suitable for a distance measurement device for and a distance measurement method of performing a distance measurement on a distance measurement target.
The present disclosure is suitable for a radar device including the distance measurement device.
1: Optical transmission and reception unit (Optical transmitter and receiver), 2: Distance measurement device, 11: Frequency swept light source, 12: Optical branching unit, 13; Optical coupler, 14: Circulator, 15: Sensor head unit, 16: Condensing optical element, 17: Optical interferometer, 18: Optical detector. 19: A/D converter, 21: Signal division unit, 22: Frequency shift unit, 23-1 to 23-N: Frequency shift processing unit, 24: Fourier transform unit, 25-1 to 25-N: Fourier transform processing unit, 26: Distance calculation unit, 31: Signal division circuit, 32: Frequency shift circuit, 33: Fourier transform circuit. 34: Distance calculation circuit, 41: Memory, 42: Processor, 51: Calculator, 52: Data storage unit, 61: Calculation circuit, and 62: Data storage circuit.
This application is a Continuation of PCT International Application No. PCT/JP2020/029917, filed on Aug. 5, 2020, all of which is hereby expressly incorporated by reference into the present application.
Number | Date | Country | |
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Parent | PCT/JP2020/029917 | Aug 2020 | US |
Child | 18083934 | US |